Easergy P5
Schneider Electric
User Manual Easergy P5 Communication P5 EN M 33A Easergy P5
User Manual
Communication 07/2020
Version: P5/EN M/33A
www.se.com
Legal Information
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As standards, specifications, and designs change from time to time, information contained in this guide may be subject to change without notice.
To the extent permitted by applicable law, no responsibility or liability is assumed by Schneider Electric and its subsidiaries for any errors or omissions in the informational content of this material or consequences arising out of or resulting from the use of the information contained herein.
Table of Contents
P5/EN M/33A
Safety information and password protection ..........................................5 Introduction ..................................................................................................6
Protocols used and data exchanged ............................................................6 Architecture ...............................................................................................7
Serial network architecture ....................................................................7 Ethernet network architectures...............................................................7 Communication ports ................................................................................10 Ethernet communication slot................................................................10 Serial communication slot....................................................................13 Port hardening configuration ................................................................13
Communication protocols ........................................................................14
IEC 61850 communication ........................................................................14 Presentation .......................................................................................14 Capability ...........................................................................................14 Configuration of IEC 61850 communication ..........................................15 Configuration of GOOSE communication ..............................................28 GOOSE performance ..........................................................................31 Conformance statements ....................................................................31
DNP3 ......................................................................................................32 Presentation .......................................................................................32 Function description ............................................................................32 Device profile document ......................................................................35 Implementation table...........................................................................37 Supported function codes ....................................................................39 Configuration parameters ....................................................................41 Data configuration...............................................................................43 Data model of DNP3 ...........................................................................46
IEC 60870-5-101 ......................................................................................48 Presentation .......................................................................................48 IEC 60870-5-101 configuration ............................................................48 Data model of IEC 60870-5-101 ...........................................................55
IEC 60870-5-103 ......................................................................................57 Presentation .......................................................................................57 IEC 60870-5-103 configuration ............................................................58 Data model of IEC 60870-5-103 ...........................................................67
Modbus slave...........................................................................................90 Presentation .......................................................................................90 Function description ............................................................................90 Modbus serial RTU mode configuration ................................................92 Modbus TCP mode configuration .........................................................93 Events ...............................................................................................95 Clock synchronisation .........................................................................96 Scaling ............................................................................................... 96 Read exception status.........................................................................98 Read device identification....................................................................99 Data model of Modbus ........................................................................99
Modbus master ...................................................................................... 145 Function description .......................................................................... 145
3
Main configuration parameters........................................................... 145 Modbus master analog inputs ............................................................ 146 Modbus master digital inputs ............................................................. 147 Modbus master digital outputs ........................................................... 147 Measurements.................................................................................. 148 Modbus master names configuration .................................................. 149 EtherNet/IP ............................................................................................ 151 Presentation ..................................................................................... 151 Function description .......................................................................... 153 EtherNet/IP main configuration .......................................................... 157 Data point configuration..................................................................... 159 Generating an EDS File with eSetup Easergy Pro ............................... 160 Data model of EtherNet/IP ................................................................. 160 Redundancy protocols ............................................................................ 189 Parallel Redundancy Protocol (PRP) .................................................. 189 High-availability Seamless Redundancy (HSR) ................................... 192 Rapid Spanning Tree Protocol (RSTP) ............................................... 195 Generic functions for all redundant Ethernet modules .......................... 196 Precision Time Protocol (PTP) ................................................................. 197 Introduction to the PTP standards ...................................................... 197 PTP implementation.......................................................................... 197 Simple Network Time Protocol (SNTP) ..................................................... 198
Client IP address filter ............................................................................ 199
Scope .................................................................................................... 199 Rules..................................................................................................... 199 Configuration parameters........................................................................ 200 Process ................................................................................................. 201
Secure communication with the eSetup Easergy Pro via the Ethernet interface.................................................................................... 202 Revision history ....................................................................................... 203 Appendix 1: Abbreviation....................................................................... 204 Appendix 2: IEC 61850 Edition 1 conformance statement ............... 206 Appendix 3: IEC 61850 Edition 2 conformance statement ............... 263
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P5/EN M/33A
Safety information and password protection
Safety information and password protection
Important information
Read these instructions carefully and look at the equipment to become familiar with the device before trying to install, operate, service or maintain it. The following special messages may appear throughout this manual or on the equipment to warn of potential hazards or to call attention to information that clarifies or simplifies a procedure.
The addition of this symbol to a "Danger" or "Warning" safety label indicates that an electrical hazard exists which will result in death or serious injury if the instructions are not followed.
This is the safety alert symbol. It is used to alert you to potential personal injury hazards. Obey all safety messages that follow this symbol to avoid possible injury or death.
DANGER
DANGER indicates an imminently hazardous situation which, if not avoided, will result in death or serious injury. Failure to follow these instructions will result in death or serious injury.
WARNING
WARNING indicates a potentially hazardous situation which, if not avoided, can result in death or serious injury. Failure to follow these instructions can result in death, serious injury, or equipment damage.
CAUTION
CAUTION indicates a potentially hazardous situation which, if not avoided, can result in minor or moderate injury, or equipment damage. Failure to follow these instructions can result in injury or equipment damage.
NOTICE
NOTICE is used to address practices not related to physical injury. Failure to follow these instructions can result in equipment damage.
User qualification
Electrical equipment should be installed, operated, serviced, and maintained only by trained and qualified personnel. No responsibility is assumed by Schneider Electric for any consequences arising out of the use of this material. A qualified person is one who has skills and knowledge related to the construction, installation, and operation of electrical equipment and has received safety training to recognise and avoid the hazards involved.
Use the password protection feature in order to protect untrained person interacting with the Easergy P5 protection relay.
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5
Introduction
Introduction
Protocols used and data exchanged
The Easergy P5 protection relays have been designed for easy data exchange and integration in any system architecture with serial links (daisy chain) or Ethernet.
The protocols used for exchange of data on the Easergy P5 protection relay are as follows:
· IEC 61850 · DNP3 · IEC 60870-5-101 · IEC 60870-5-103 · EtherNet/IP · Modbus slave · Modbus master The data types that can be exchanged through these protocols are listed:
Port Protocol
Real time data Measurement Alarms and status Controls Time-stamped events Logged data Disturbance records Sequence of event record files Device management Setting group change Settings
Ethernet IEC 61850 EtherNet/IP sFTP
DNP3 Modbus slave
GetSet
Port Protocol
Real time data Measurement Alarms and status Controls Time-stamped events Logged data Disturbance records Sequence of event record files Device management Setting group change Settings
Serial DNP3
Modbus slave
Modbus master
IEC
IEC
608705103 608705101
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Introduction
Architecture
Serial network architecture
This architecture allows the connection of HMI/SCADA to a set of Easergy P5 protection relays using a multi-drop serial communication link with master-slave communication.
SCADA
Serial link
Termination module
F0198
Ethernet network architectures
This architecture allows the connection of a set of Easergy P5 protection relays directly on an Ethernet network.
NOTE: It is possible to mix any three of four Ethernet protocols, including the IEC 61850 protocol, on the same Ethernet network. This allows to use the Generic Object Oriented Substation Event (GOOSE) messages between relays together with another protocol for communication to Supervisory Control and Data Acquisition (SCADA).
It is also possible to connect Easergy P5 protection relays to more than one control system, using the same Ethernet communication port with one of the chosen protocols.
Easergy P5 protection relays handle the IEC 61850 station bus, in compliance with standards IEC 61850-6, 7-1, 7-2, 7-3, 7-4 and 8-1 Edition 1 or Edition 2, according to configuration.
Other supported protocols: · Secured File Transfer Protocol (sFTP) for file transfer · Simple Network Management Protocol (SNMP) for network management · Simple Network Time Protocol (SNTP) for time synchronization · Secured Hypertext Transfer Protocol (HTTPS) for Web HMI · GetSet, which is an ASCII protocol used by eSetup Easergy Pro, which is secured by TLS
SCADA
Ethernet switch
Ethernet switch
Ethernet switch
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F0199
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Introduction
Connections
The Easergy P5 protection relays can be connected to an Ethernet switch using: · 10/100BASE-T copper wire (radial connection). · 100BASE-FX multi-mode fibre optic (radial or ring connection).
To optimise system performance, Schneider Electric recommends: · to build a fault-tolerant communications backbone by implementing a fibre optic ring · to use IEC 61850 compatible managed switches · to use VLANs for prioritized messages · to configure meaningful destination MAC address and APPID to enable network filtering · to minimize the content of GOOSE datasets
Parallel Redundancy Protocol (PRP)
The principle of Parallel Redundancy Protocol (PRP) is to transmit frames in parallel on two independent network infrastructures: A and B. The receiving device is in charge of discarding the second (redundant) frame once it is received. PRP provides a 0 ms recovery time in case of a communication failure, but this quality is achieved at the cost of a double communication network.
SCADA
Network A
Network B
F0200
High-availability Seamless Redundancy (HSR)
High-availability Seamless Redundancy (HSR) is typically used in ring architectures. Frames are transmitted on the ring on both directions and the receiving device discards the redundant frames. HSR provides a 0 ms recovery time and is a cheaper alternative compared to PRP.
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Introduction
SCCAADDAA
F0201
Rapid Spanning Tree Protocol (RSTP)
The principle of Rapid Spanning Tree Protocol (RSTP) is to virtually switch off all links that are not necessary at a given time, changing the meshed topology into a tree topology. The main advantage of RSTP is that it is widespread, and works on any network topology. On the other hand, RSTP may take a considerable time to reconfigure the network in case of a network failure, which may exceed the requirements of automations.
SCADA
Ethernet switch
Ethernet switch
Ethernet switch
Ethernet switch
F0415
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Communication ports
Introduction
Ethernet communication slot
The Ethernet communication slot can accommodate one of the following options:
· Dual port copper (RJ45) Ethernet module with RSTP redundancy management.
· Dual port fibre optic (multimode glass fibre) Ethernet module with RSTP redundancy management.
· Dual port fibre optic (multimode glass fibre) Ethernet module with PRP/HSR advanced redundancy management (this option is a double width module which spans over the serial slot space and is therefore not compatible with the use of a serial communication module).
Communication module
1 Ethernet module (Slot M)
1 Ethernet module (Slot L)
2 Ethernet modules (Slot M, Slot L)
1 PRP/HSR module (Slot M and N)
1 PRP/HSR module, 1 Ethernet module (Slot M and N, Slot L)
IP selection RSTP = 1 IP1 IP3 IP1, IP3 IP1 IP1, IP3
RSTP = 0 IP1, IP2
IP1, IP2, IP3
Each IP address includes network number and host number. For example, when IP = 192.168.1.21, the network number is 192.168.1 and the host number is 21. The network number of IP1, IP2 and IP3 shall not be the same for Easergy P5 communication configuration. For example, IP1 = 192.168.1.21, IP2 = 192.168.2.31 and IP3 = 192.168.10.31 are workable, while IP1 = 192.168.1.21 and IP2 = 192.168.1.31 are incorrect.
Ethernet port configuration
The parameters for the port can be set from the front panel, from the COMMUNICATION menu of eSetup Easergy Pro, or from the Web HMI. Up to 3 different protocols can be used simultaneously, using the same IP address and MAC address but different IP port numbers.
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Introduction
Table 1 - Ethernet protocol 1 configuration parameters
Parameter
Value
Ethernet port protocol None
ModBusTcps
DNP3
IEC-61850
EthernetIP
IP port for protocol 1
Set protocol default IP port
Default
IP address selection IP1 IP2 IP3
Description Select the protocol of the Ethernet port
Set the IP port number of the protocol 1 Select the default IP port number: 502 for ModBus Tcps 20000 for DNP3 102 for IEC 61850 44818 for EthernetIP Choose the Ethernet module to be used 1
Note Set
Set Set
Set
Set = an editable parameter (password needed)
1. IP1/IP2 means to select the Ethernet module to be used on Slot M; IP3 means to select the Ethernet module to be used on Slot L. If Slot M is used as RSTP mode or PRP/HSR module is selected, then IP2 is invisible.
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Introduction
Table 2 - Ethernet port configuration parameters
Parameter
Value
MAC address
IP Address Network mask Gateway
n.n.n.n n.n.n.n n.n.n.n
Ethernet port 1 status Link on /
Ethernet port 2 status
Link off Link on /
Enable HTTPS server
Link off Yes / No
IP address selection
NTP server NTP server (Backup)
IP1 IP2 IP3 n.n.n.n n.n.n.n
IP address selection
TCP keep alive interval
IP1 IP2 IP3 0 - 20 s
Description Display the MAC address IP address Network mask Gateway IP address Display the link status of Ethernet Port 1
Note
Set Set Set
Display the link status of Ethernet Port 2
If this option is enabled, HTTP server can be Set used
Choose the Ethernet module to be used 2
Set
Network time protocol server
Set
Network time protocol server to be used if
Set
NTP server does not respond
Choose the Ethernet module to be used 2
Set
TCP keepalive interval in seconds
Set3
If Ethernet module with PRP/HSR is selected, then additional parameters are shown.
Table 3 - Additional Ethernet port configuration parameters for channel redundancy
Parameter FPGA version
Value
Get mode Mode Switch
PRP / HSR
Description
Display the Field Programmable Gate Array (FPGA) version of the Ethernet module
Display the used protocol
Switch the protocol to be used
Note Set
2. IP1/IP2 means to select the Ethernet module to be used on Slot M; IP3 means to select the Ethernet module to be used on Slot L. If Slot M is used as RSTP mode or PRP/HSR module is selected, then IP2 is invisible.
3. Keepalive: The Keepalive parameter sets the time in seconds between two keepalive packets which are sent from the IED. The setting range for this parameter is between zero (0) and 20 seconds; with the exception that zero (0) means actually 120 seconds (2 minutes). The purpose of a keep alive's packet is to send a probe packet to a connected client for checking the status of the TCP-connection when no other packet is being sent, e.g. the client does not poll data from the IED. If the keepalive packet is not acknowledged, then the IED will close the TCP connection. The Connection must be restarted from the client side.
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Introduction
Serial communication slot
The Serial communication slot can accommodate one of the following options: · RS-485 (two and four wires) serial communication module, with RJ45 connection · Fibre optic serial communication module
Serial port configuration
The parameters for the remote port can be set from the front panel or via protocol, using COMMUNICATION menu of eSetup Easergy Pro or Web HMI. Only one serial port can be used and one serial communication protocol can be selected.
Table 4 - Serial port configuration parameters
Parameter Remote port protocol
Value
None ModBusSlv IEC-103 MdbsMstr DNP3 IEC-101
Description Select the protocol of the serial port
Note Set
Port hardening configuration
It is possible to disable a communication port either via the front panel or via protocol, using COMMUNICATION menu of eSetup Easergy Pro or Web HMI with the correct access rights. This allows the user to take control of the physical ports limiting the exposure of ports to only those that are needed.
Figure 1 - Port hardening configuration parameters (depending on the communication modules used)
P5/EN M/33A
If the ports or the protocols on Ethernet module are disabled or enabled, then a reboot is needed.
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Communication protocols
Communication protocols
NOTICE
CYBER SECURITY HAZARD
· Except for the private GetSet protocol via secured communication (SSH), the device does not have the capability to transmit data encrypted using the following protocols: IEC 61850, DNP3 over Ethernet, Modbus slave over Ethernet, EtherNet/IP, Modbus slave serial, Modbus master serial, DNP3 serial, IEC 60870-5-103 serial, IEC 60870-5-101 serial, IEEE 1588 and SNTP.
· If other users gained access to your network, transmitted information can be disclosed or be subject to tampering.
· For transmitting data over an internal network, physically or logically segment the network. The access to the internal network needs to be restricted by using standard controls, such as firewalls, and other relevant features supported by your device, such as IPTable whitelisting.
· For transmitting data over an external network, encrypt protocol transmissions over all external connections using an encrypted tunnel, TLS wrapper or a similar solution.
Failure to follow these instructions can increase the risk of unauthorized access.
IEC 61850 communication
Presentation
IEC 61850 is a series of standards for communication networks and systems of power utility automation. Easergy P5 protection relays, used as a server, can be connected to an IEC 61850 station bus according to Edition 1 and Edition 2 of:
· IEC 61850-6
· IEC 61850-7-1 to 7-4
· IEC 61850-8-1
Based on the Ethernet protocol, the IEC 61850 communication standard helps to ensure:
· High communication speeds and versatile communication architectures
· Interoperability between manufacturers
Capability
Easergy P5 protection relays provide a built-in solution for demanding IEC 61850 applications:
· IEC 61850 logical nodes and configurable data sets to fit the needs of the Edge control system/SCADA system
· Peer-to-peer communication capabilities on Easergy P5 protection relays using GOOSE messages to enhance the protection and control system without the need of additional wiring
· Up to 8 simultaneous IEC 61850 client-server associations
The IEC 61850 protocol can be used to read/write static data from/to the Easergy P5 protection relays, to receive events, to send controls, and to receive/send GOOSE messages to other relays.
The IEC 61850 server interface is capable of:
· Configurable pre-defined data sets
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Communication protocols
· Dynamic data sets created by clients, which can be assigned to Buffered and Unbuffered Report Control Blocks
· Reporting function with Buffered and Unbuffered Report Control Blocks · Supported control models:
Status-only Direct control with normal security Direct control with enhanced security Select before operate with normal security Select before operate with enhanced security · Supported horizontal communication with GOOSE Configurable GOOSE publisher data sets Configurable filters for GOOSE subscriber inputs (i.e. MAC Address,
APPID....) · Sending and receiving analogue or binary values over GOOSE · Setting modification
Editing a setting value in the setting group Changing the active setting group
Setting groups are selectable using the Setting Group Control Block class, (SGCB). The Active Setting Group can be selected using the Relay/LLN0. SP.SGCB.ActSG data attribute in Logical Device `Relay'. · File transfer Extracting disturbance records from Easergy P5 relays by file transfer, as ASCII format COMTRADE files All disturbance record files are accessible from the folder /COMTRADE/ DR. Deleting files in the /COMTRADE/DR folder is not supported.
Configuration of IEC 61850 communication
Configuration tools
The Easergy P5 protection relays IEC 61850 solution can be configured with: · eSetup Easergy Pro used as a setting and operating software to help ensure straightforward configuration and to send IEC 61850 configuration to Easergy P5 protection relays · CET850 software used as a configuration tool to adapt the communication profile of Easergy P5 protection relays to the precise needs of the system
Configuration files
The IEC 61850 configuration process uses and generates several types of System Configuration description Language (SCL) files; a selection is introduced here:
· ICD - IED (Intelligent Electronic Device) Capability Description An ICD file exists for each type of Easergy P5 protection relay. It describes the data model and communication services available in the referred-to Easergy P5 device model. ICD files are provided in a library together with the CET850 configuration tool, and are used as template models in the configuration process. The ICD files can be obtained from the ICD folder under eSetup EasergyPro or generated by the "Export ICD/SCL file" command by eSetup EasergyPro.
· IID - Instantiated IED Description The IID file describes the project-specific configuration of a single IED in a system.
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Communication protocols
It is used as an exchange file between the CET850 configuration tool and other IEC 61850 system configuration tools to exchange the configuration data of a single IED instantiated specifically for a project. · CID - Configured IED Description For every configured Easergy P5 protection relays there is a CID file which describes the IEC 61850 configuration of the device. A CID file is created by the IED configuration tools. The CID file is then loaded into the device to configure it. · SCD - System Configuration Description An SCD file contains the configuration data for the IEC 61850 system including the communication configuration settings for all related IEC 61850 devices.
eSetup Easergy Pro for IEC 61850 configuration
The Easergy P5 protection relays setting and operating software, eSetup Easergy Pro, is used to create and to send IEC 61850 configuration to the Easergy P5 protection relay. eSetup Easergy Pro is used to:
1. Get the information from Easergy P5 protection relays connected to the IEC 61850 network. This can be done automatically by the eSetup Easergy Pro polling the network to find connected devices (with IP address and port number).
2. Import a CID file to the Easergy P5 relay through eSetup Easergy Pro (see eSetup Easergy Pro user manual). NOTE: The CID file name shall not include any whitespace or non-latin characters.
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2
IEC 61850 main configuration
The IEC 61850 protocol is activated by setting it as the port protocol for an Ethernet port on the device. This setting can be found by navigating to the COMMUNICATION menu.
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Table 5 - IEC 61850 main configuration parameters
Parameter Edition Control model
Size of array Active connections Client x
Description
IEC 61850 standard edition to be used (1 or 2), Edition 2 is the default.
Selects the control model to be used with the controllable Objects.
· Status-only (StatusOnly) · Direct control with normal security (DirNorSec) · Select before operate with normal security (SBONorSec) · Direct control with enhanced security (DirEnhSec) · Select before operate with enhanced security
(SBOEnhSec)
Number of elements in the arrays used to transfer the harmonics.
The number of active connections.
The IP addresses of the clients.
Note Set Set
Set
IEC 61850 measurement configuration
The IEC 61850 measurement configuration of deadband values (primary values) and unit multiplier settings can be found by navigating to the COMMUNICATION menu and IEC 61850 measurement configuration view in the eSetup Easergy Pro or Web HMI.
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Communication protocols
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The table below shows the configuration parameters which can be defined for each individual measurement:
Table 6 - IEC 61850 measurement configuration parameters
Parameter 4
Energy ... Virtual A18
Integration time
Unit multiplier
Description Deadband of the measurements
Deadband integration time Set the unit multiplier of deadband values
Note Set
Set Set
There are two variants of the deadband calculation: absolute deadband and integrated deadband. When absolute deadband is selected, set the integration time to zero.
NOTE: Setting the values too low may result in unnecessary traffic or nuisance.
When integrated deadband is selected, the formula to check whether the value is changed is decided by the calculation method as follows:
abs (value2 value1) × (t2 t1) > Dead band value × Integration time
Here value2 means the current value, value1 means the last report value; t2 means the current time, t1 means the time of the last report value changed. The unit for t2, t1 and Integration time are all milliseconds.
A short example: If the Current I deadband value is set to 5 A, and the Integration time set to 0 (absolute deadband), the change condition will be satisfied when the value changes by more than 5 A from the previously reported value. If, on the other hand, the Integration time is set to 1, the change condition will be satisfied for instance, if the signal value changes by more than 5 A from the previously reported value and remains as such for one second.
In case there are several changes during the time period set (report buffer time > 0), the integration time is not considered and the analogue value of the pending previous event is overwritten. The behavior can be found in the "PIXIT Details" section in the Conformance Statement documents appended to the end of this manual. Mechanism on second internal data change notification of the same analogue data value within buffer period (see IEC 61850-7-2 Ed.1 §14.2.2.9 and IEC 61850-7-2 Ed.2 §17.2.2.9 respectively): Replace analogue value in pending report.
IEC 61850 generic events
Regardless from the modelling of information in IEC 61850-7-4, generic events can be configured via navigating to the COMMUNICATION menu and IEC 61850 generic events view in the eSetup Easergy Pro or Web HMI. This provides means to map any events (i.e. protection trip, digital input change, port hardening change, ...) of the relay to maximum 8 indication data objects of the P5EVTGGIO1 logical node of the IEC 61850 interface. The status of the indication data object is determined by ON and OFF events set for the corresponding index.
4. These parameters can be set for each type of measurement.
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Communication protocols
Table 7 - IEC 61850 generic events
Parameter Ind idx ON event channel ON event code OFF event channel OFF event code
Description Index of the LN P5EVTGGIO1 indication Channel number of the ON event Event code of state ON Channel number of the OFF event Event code of state OFF
Note
Set Set Set Set
The above screenshot features an example, where the status of Virtual Input 1 (event channel 69) is mapped to the generic events table. If the value of Virtual Input 1 is changed, then the value stored in the IEC 61850 address P5EVTGGIO1.Ind1.stVal indicates the current value of the Virtual Input 1. If only an "ON event" is defined for an indication then the transition to OFF state is generated automatically after reporting the ON state (momentary ON state). And the same applies if only an "OFF event" is defined for an indication (momentary OFF state).
GOOSE configuration
The publisher configuration GoCB 1-4 and subscriber configuration can be found by navigating to the COMMUNICATION menu and GOOSE configuration view in eSetup Easergy Pro or Web HMI.
Table 8 - GOOSE configuration parameters
Parameter
Description
Publisher configuration GCB x
Enable
Enable/disable the publishing of data defined by GCB x.
Name of selected dataset
Needs commissioning
Display the name of the dataset associated to the GCB x.
A flag which can be used to indicate that some change has been done in the configuration and a new commissioning is needed.
Note
Set Set Set
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Table 8 - GOOSE configuration parameters (Continued)
Parameter
Description
Fixed length GOOSE
Disable/enable sending the GOOSE messages in flexible or fixed format (fixed length is a feature defined by Edition 2).
Subscriber configuration
Min supervision time
Minimum timeout for indicating invalid status of GOOSE network inputs due to no incoming GOOSE messages (exceeded supervision time or time allowed to live from the last GOOSE message, whichever is greater).
Note Set
Set
GOOSE subscriber: data points
The GOOSE subscriber 128 binary data and 8 analog data can be monitored by navigating to the COMMUNICATION menu and GOOSE Subscriber: data points view in eSetup Easergy Pro or Web HMI.
Table 9 - GOOSE subscriber: data points
Parameter GOOSE NI Global Error Network input
Value Status VAI Unit
Description
Global error status of the GOOSE subscription
Index of the GOOSE data points. Input data can be binary or analogue. Binary NIs can be used as inputs for the user-defined logic blocks or as control inputs in the other functions of the relay (e.g. the output matrix).
Data value received in the GOOSE data packet
Status of the GOOSE data (NO DATA / OLD / OK)
Unit of the incoming analogue data
NI = Network Input
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Communication protocols
CET850 for IEC 61850 configuration
IEC 61850 configuration software CET850 is used to create, display, modify or optimise an IEC 61850 configuration.
template library
.icd
.cid .iid .icd 1 11
1
3 2
CET850
5 2 .scd
62
2 4
.icd .iid
.cid
user customised ICD
eSetup Easergy Pro
CET850 can be used to:
· Create an IEC 61850 configuration using an ICD, SCD, IID or CID file as an input.
· Edit an existing CID, SCD, IID or user-customised ICD file to modify its contents by :
Adding or removing Easergy P5 protection relays, in case of SCD
Displaying the configuration
Modifying communication parameter values
Optimising configuration by creating or modifying datasets and Report Control Blocks
Configuring or optimising the GOOSE communication by creating or modifying the GOOSE messages publication and subscription
· Generate a user-customised ICD file using an Easergy P5 protection relays IED template from the factory ICD library.
· Generate a CID file for storing the configuration of one device which can then be uploaded to the Easergy P5 protection relays using eSetup Easergy Pro.
· Generate SCD file for storing the configuration of an IEC 61850 system which can then be used by other IEC 61850 configuration tools.
· Generate an IID file for storing the specific configuration of an instantiated IED which can then be used by other IEC 61850 system configuration tools.
Graphical SCL editor
CET850 is a graphical tool that enables to browse an SCL file using a tree view that displays the content of the file in a hierarchical format.
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Tree view The following main sections are displayed in the tree view:
· Header and history The Header section identifies the SCL configuration file and its version.
· Communication This section contains the definition of all sub-networks defined in the IEC 61850 system, with the list of the connected IEDs. Both Client/Server and peer-to-peer communication access points are displayed.
· List of IEDs This section contains the definition of all IEDs defined in the IEC 61850 system. Each IED is displayed with all its contents: Logical Devices (LD) Logical Nodes (LN) Datasets (DS) Report Control Blocks (RCB) GOOSE Control Blocks (GoCB) GOOSE subscription
Property view When an item is selected in the tree view, the property view displays details of the selected item. The user can activate editing operations from the tool bar and contextual menu. There are also specific dialogue interfaces to guide you.
Device configuration
Adding and removing a device in an IEC 61850 system consists of making the change in the associated SCD file.
Adding an IED CET850 enables the addition of an IED to an IEC 61850 system using its ICD description file, or the addition of a device already defined by a CID file. A specific dialog interface requests a name for the IED and then its description. The description is provided from an ICD file, a CID file or from an IID file. Procedure:
· Create a new SCL file for a substation system (e.g. My Substation.scd). · From the tree view, select the SCL root element · In the menu bar or in the contextual menu, click Add > IED · Set the IED Identification and optionally the address parameters according to
the following descriptions
23
Communication protocols
· Click OK to validate the operation IED identification:
· ICD/CID file Select the IEC 61850 description of the IED to add to an ICD or a CID. The user can select a device from a library or an other device with an external ICD file.
· IED name Assign a name to the IED. The name of the IED must be unique in the IEC 61850 system. Its length is restricted to a maximum of 64 characters, and consists of alphanumeric and underscore (_) characters, beginning with a letter. It must not inclued a space character.
· IED description This is a free ASCII string where the user can write comments about the device.
Address:
Address parameters are set to connect to the IED in the communication network. Connecting the IED can be done at this stage or later using the Add > Connected Access Point menu.
Removing an IED
An IED can be removed from an SCD file. This function is available when an IED is selected in the tree view. After confirming that the IED is to be deleted, the tree view and the content of the SCD file are updated.
Connecting a device in IEC 61850
An IEC 61850 IED uses an Access Point (AP) to communicate. This AP is connected to a subnetwork. CET850 provides the following set of functions to manage the communication architecture of an IEC 61850 System:
· Adding or removing a Subnet to the system · Adding or removing an Access Point on a Subnet
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IED configuration
The configuration of an IED described in an ICD, CID or SCD file can be modified so that its communication profile and behavior are adjusted to the needs of the system. Refer to the CET850 user manual for more information.
Create, modify or delete a dataset
With Easergy P5 protection relays, a dataset is a collection of references to Data Attributes (DA) grouped together to increase communication efficiency for reports and GOOSE messages.
Datasets can be modified by the user and new dataset can be added, depending on the capabilities of the IED.
Any data produced by Easergy P5 protection relays may be referred-to in a dataset to be sent via a GOOSE message. Nevertheless, only data from the following types are applicable for GOOSE communication between Easergy P5 protection relays: Single Point Status (SPS), Double Point Status (DPS), Double Point Control (DPC), Complex Measured Value (CMV), and Measured Value (MV).
CET850 provides an easy way to create or edit a dataset inside LLN0. When creating a dataset, CET850 prompts the user for its name and description. A specific dialog interface allows the user to select which data is to be added to, or removed from the dataset.
The available data that can be selected is displayed in a hierarchical tree with collapse and expand facilities, from their host Logical Node down to the data attributes. Individual and multiple selections are possible.
After completing the definition of the dataset in the dialog interface, the changes to the dataset are reflected in the current SCL file and the CET850 display is updated: A newly created dataset is displayed in the tree view; a deleted dataset is removed from the tree view. The content of the dataset is updated in the property view.
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Modify Report Control Block (RCB)
Easergy P5 protection relays provide up to 16 buffered and 8 unbuffered RCBs inside LLN0.
CET850 provides a specific dialog interface for creating or modifying a Report Control Block. When creating an RCB, CET850 prompts the user for the name and description of the RCB. A specific dialog interface allows the user to select the dataset to be associated with the RCB and to define all settings concerning the report generation.
The most common trigger options for an RCB instance are:
· Data Change : the Report is triggered by changes to the value of the data which are referenced in the dataset
· Quality Change: the Report is triggered by changes to the quality of the data which are referenced in the dataset
· Integrity: the Report is triggered periodically, according to an Integrity period specified
Modify GOOSE Control Block (GoCB)
The GOOSE message service is an efficient real-time communication service for peer-to-peer exchanges between IEDs.
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A GOOSE Control Block (GoCB) manages how information referenced in a dataset is transmitted in a GOOSE message. A GoCB can only be created inside the Logical Node 0 (LLN0). The Easergy P5 protection relay provides up to 4 GoCBs.
CET850 provides a specific dialog interface for modifying a GOOSE Control Block. A specific dialog interface allows the user to select the dataset whose referenced information shall be transmitted as a GOOSE message. Then, the user needs to enter the settings for publishing the GOOSE message.
This includes:
· Multicast MAC address to which the GOOSE message is transmitted to
· Time for the first retransmission of the GOOSE message (the fastest retransmission is after 4 ms)
· Maximum retransmission interval (heartbeat cycle time)
After completing the definition of the GoCB in the dialog interface, the changes to the GoCB are reflected in the current SCL file and the CET850 display is updated: A newly created GoCB is displayed in the tree view; a deleted GoCB is removed from the tree view. The GoCB settings are displayed in the property view.
Subscribe to GOOSE messages and assign GOOSE inputs
The capability of the Easergy P5 protection relay to receive GOOSE messages is defined in the ICD file. If GOOSE messages are to be subscribed to, a GOOSE Receive element is defined at the beginning of the IED section, in the tree view displayed by CET850.
Editing the GOOSE Receive element allows the user to: · Select the GOOSE messages and the data to which the IED subscribes · Assign the subscribed data to Easergy P5 protection relays GOOSE inputs
CET850 provides a specific dialog interface to edit the GOOSE Receive. The dialog is organized in two parts:
· GOOSE message and data subscription · GOOSE Inputs assignment Refer to Configuring the subscriber side, page 29 for a detailed description.
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Communication protocols
Generating, editing, validating of an SCL file
Generating CID files
When an SCD file is opened in the tool, CET850 can generate the CID file of a specific IED or all the CID files for all IEDs defined in the SCD file.
Generating a CID file is available when an IED is selected from the tree view and if this IED is connected to a subnet. A specific dialog interface box asks the user to enter the location and the name of the output CID file. By default, the name of the CID file is based on the name of the IED.
Generating all CID files is available if the SCD file includes at least one IED that is connected to a subnet. A specific dialog interface box asks the user to enter the location of the output CID files. The name of each CID file is based on the name of the IED.
Editing CID files
CET850 allows the editing of an existing CID file. This CID file is an advanced configuration file generated during a previous use of CET850, or a standard configuration file generated by eSetup Easergy Pro.
Validating SCL files
The validate function includes two kinds of verification: · Verification of the structure and content of the SCL file The System Configuration description Language is based on Extensible Markup Language (XML). The structure and the content of an SCL file is fully specified by the IEC 61850 standard using an XML Schema (XSD files). CET850 is delivered with the set of XSD files defined by the IEC 61850 standard. Using the XercesTM parser, CET850 checks the validity of SCL files against the IEC 61850 XML Schema. · Verification of the consistency of the GOOSE communication. The following checks are made: The dataset defined for a GOOSE messages meets a specific size constraint. The data sent by a publishing IED is consistent with the data expected and subscribed by the subscribing IED.
CET850 provides two ways to validate an SCL file: · Schema validation · Check XML syntax at file saving
Automatic validation is enabled or disabled using a specific option in the CET850 User Preferences.
Configuration of GOOSE communication
To configure the GOOSE communication, the following software are used: · CET850 software to configure GOOSE communication in the IEC 61850 system · eSetup Easergy Pro software to assign GOOSE Inputs to Easergy P5 protection relays control and monitoring functions for the precise needs of the system
Configuring GOOSE communication involves first configuring the publisher that sends the messages and then configuring the subscriber that receives the message. The GOOSE communication configuration is saved in an SCD file.
Configuring the GOOSE publisher side
To configure the GOOSE publisher side, the user needs to:
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· Create a dataset (refer to IED configuration, page 25. ) · Configure a GOOSE Control Block to define the publishing of the data
referenced in the dataset as a GOOSE message on the communication network Any dataset may be attached to a GOOSE Control Block, provided its size is compatible with the size of one Ethernet frame. When creating a dataset, CET850 calculates the size of the dataset and informs the user if it is GOOSE compatible or not. When creating a GOOSE Control Block, CET850 allows the selection of GOOSE compatible datasets only.
Configuring the subscriber side
Procedure
1. Select from the published GOOSE messages which Data Attributes (DAs)/ Data Objects (DOs) the device shall subscribe to.
2. Assign subscribed DAs/DOs to GOOSE network inputs. The Easergy P5 protection relay provides 128 digital GOOSE inputs and 8 analogue GOOSE inputs that can be used by control logic functions.
Assignment table
The subscribed DAs are assigned to Easergy P5 protection relays GOOSE network inputs in an assignment table. The assignment table gives in rows the list of all the subscribed DAs and in columns the list of the Easergy P5 protection relays GOOSE network inputs to which the DAs can be assigned/de-assigned. Assignment/de-assignment is done by selecting the appropriate cells in the table. Several DAs can be assigned to the same GOOSE network input. In this case, Easergy P5 protection relays apply a wired-OR logic operation to these DAs.
The below figure shows the assignment of subscribed DAs to Easergy P5 protection relays GOOSE digital network inputs.
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Communication protocols
The below figure shows the assignment of subscribed DAs to Easergy P5 protection relays GOOSE analog inputs.
GOOSE matrix
All Easergy P5 protection relays GOOSE network inputs NI 1-128 can be mapped to NI or Vitual inputs VI 1-20 in COMMUNICATION menu and GOOSE matrix view in eSetup Easergy Pro or Web HMI.
Using the GOOSE matrix the user is able to map the GOOSE network inputs to Virtual inputs which can be processed by the relay applications. The same network input can be mapped to more than one Virtual input and it is also possible to map more than one GOOSE network input to the same Virtual input. Easergy Pro P5 protection relays apply a wired-OR logic operation on these mappings.
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GOOSE performance
According to IEC 61850-5 and IEC 61850-10 Edition 2, the GOOSE performance of Easergy P5 protection relays is compliant with Class P2 (< 10 ms). For more information, visit www.se.com.
Conformance statements
This manual includes, in its appendix, two conformance statement documents that describe the conformity to IEC 61850 edition 1 and IEC 61850 edition 2. They do not describe the standard itself, but indicate the choices that have been made when implementing the standard in the Easergy P5 protection relay, in terms of services, modeling, exceptions, extensions and adaptations.
The conformance statement documents are: · Conformance Statement with IEC 61850 Edition 1 (Appendix 2) · Conformance Statement with IEC 61850 Edition 2 (Appendix 3)
Each conformance statement document is made up of the following chapters: · Protocol Implementation Conformance Statement (PICS): Describes choices made in protocol implementation. · Model Implementation Conformance Statement (MICS): Describes how the information model is implemented. · Protocol Implementation Extra Information for Testing (PIXIT): Gives any additional implementation specific information not found in the previous standardized documents. Despite the name, this information is useful for operation of the devices. · Tissues Conformance Statement (TICS): Describes which Technical Issues (TISSUES) are considered in the device implementation.
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DNP3
Communication protocols
Presentation
DNP3 communication enables Easergy P5 protection relay units to be connected to a supervisor or other device featuring a DNP3 communication channel.
Communication is based on the master/slave principle: · Easergy P5 protection relay is always a slave device. · The master is the supervisor, which is another device.
The DNP3 protocol specifies the coding of data and the rules for exchanging this data between a slave device and a master device (supervision and control device or RTU). DNP3 is an open (non-proprietary) protocol, which can be implemented by any communicating device without any restrictions.
The DNP3 protocol was developed from the basic standards prepared by IEC Technical Committee 57 (Power systems management and associated communications).
DNP3 was chosen by IEEE Task Force C.2 as the IEEE Recommendation for communication between RTUs and IEDs.
For more information on the Intelligent Electronic Device protocol can be obtained from the DNP3 User Group (www.dnp.org).
The following data types from the DNP3 protocol are supported: · Binary input · Binary input change · Double-bit input · Binary output · Analog input · Counter
Easergy P5 protection relays also support the division of data into classes.
Function description
Transmission mode
Easergy P5 protection relays can communicate using DNP, in two transmission modes:
· Serial port mode · TCP/IP mode The maximum number of clients for DNP3 is 8. The client and master can be connected by either: · a serial port connection · a TCP connection via an Ethernet port The Easergy P5 protection relays can be configured to support the serial port mode and TCP/IP mode together at the same time and work at maximum 3 IP addresses.
Status polling
Easergy P5 protection relays allow the polling of current status values on master request with class 0.
The contents of binary input for polling, group number and variation number are configurable.
The function code for polling is 1 [READ].
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Status reporting
Easergy P5 protection relays allow the reporting of data change events which are derived from:
· Polled value status change · Control command status change The status to be reported is configurable. The event class can be configured as class 1, class 2 or class 3. Status report entries are stored in a circular buffer with access provided to the most recent ones. It is possible for a master to query the availability of status reports, in order that the master can determine whether it is necessary to read the available status reports from the slave. Easergy P5 protection relays may be configured to support unsolicited responses.
Measurement polling
Easergy P5 protection relays support the polling of static measurement values on master request with class 0. The list of measurement values for polling, group number and variation number are configurable. The function code for polling is 1[READ]. The data type of each measurement value is configurable.
Measurement event polling (Reporting)
Easergy P5 protection relays support the polling of measurements event values on master request. The list of measurement event values for polling is configurable. The function code for polling is 1[READ]. The data type of each measurement event value is configurable. The deadband values for managing measurement events reported by Easergy P5 protection relays are configurable.
Remote control
Easergy P5 protection relays support both remote control command requests and polling command status requests from a master. Remote control command requests can be used with data types: binary output. The remote control commands supported are listed below:
· Select · Operate · Direct operate · Direct operate with no ACK Both DC (Direct Control) and SBO (Select Before Operate) control models are supported. The DNP3 checks whether the point to be controlled has been configured only. DNP3 doesn't check whether the value is correct or not. Easergy P5 protections relays implement an SBO timeout of 60s. Easergy P5 protection relays send response frame to client according to the real control command response.
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Counter management
Easergy P5 protection relays support the polling of counter values on master request.
The list of the counter values for polling is configurable.
The function code for polling is 1[READ].
General interrogation
The general interrogation functions for Easergy P5 protection relays mean to poll class 0 data for DNP3 master. When Easergy P5 protection relays receive the general interrogation command from DNP3 master, the Easergy P5 protection relays report all the point's static data values (except for the point's class is not assigned to one of the four classes) in one frame or multi-frame. Generally, the group number 60 and variation number 1 is used for general interrogation for all profiles.
Time synchronisation
The time of Easergy P5 protection relays corresponds to Universal Coordinated Time (UTC).
Easergy P5 protection relays support time synchronization command requests and the polling of current date and time information from a DNP3 master.
It's possible for master to verify the correctness of system time.
The function code for actioning the time synchronization command is 2 [WRITE].
The function code for polling the current date and time information is 1 [READ].
The time synchronization procedure for TCP and serial is different.
Easergy P5 protection relays do not retry time synchronization messages at either the Application or Data Link layers for these application layer function codes.
· DELAY_MEASURE request from master and corresponding response (RESPONSE function code) from outstation
· WRITE requests from master with an Absolute Time object, group 50, variation 1
· WRITE requests from master with a Last Recorded Time object, group 50, variation 3
When Easergy P5 protection relays detect that the time synchronization request has not been received within the configured timeout, the IIN1.4 [NEED_TIME] bit is set in the response message. The master must send the time synchronization request after receiving a response with this bit set.
Application identifier
The application identifier uses the function code 16[INITIALIZE_APPL], 17 [START_APPL], 18[STOP_APPL]. When Easergy P5 protection relays receive a request related with application identifier, nothing internally is performed.
Cold restart and warm restart
When an Easergy P5 relay receives a cold or warm restart request, it immediately triggers the cold/warm restart sequence. A response frame containing the Delay Time DNP3 object, with a value of 10 seconds is generated. The response indicates the time when the relay will be available again. Hence during this period the Easergy P5 relay does not respond to requests from the DNP3 client.
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IED file extraction
The Easergy P5 protection relay supports IED file extraction, which can be used to transfer the disturbance record file to clients. The file operations of the Easergy P5 protection relay include:
· Open file · Close file · Get file/folder information · Read file · Abort file · Delete file File authentication is not supported. The Easergy P5 can only have one file open at a time.
The file operations above can act on the folder '/COMTRADE' and all its subfolders.
Device profile document
DNP 3.0
Device Profile Document
Vendor Name: Schneider Electric Device Name: Easergy P5 Protection Relay
Highest DNP Level Supported: For Requests: Level 2 For Responses: Level 2
Device Function: Master
Slave
Notable objects, functions, and/or qualifiers supported in addition to the Highest DNP Levels Supported (the complete list is described in the DNP Implementation table):
Maximum Data Link Frame Size (octets): Transmitted: 292 Received: 292
Maximum Application Fragment Size (octets): Transmitted: 2048 Received: 2048
Maximum Data Link Re-tries:
None Fixed Configurable from 0 to 255
Maximum Application Layer Re-tries:
None Configurable
Requires Data Link Layer Confirmation:
Never Always Sometimes Configurable with confirmation type selector, default NO ACK
Requires Application Layer Confirmation:
Never Always Sometimes When reporting Event Data (Slave devices only) When sending multi-fragment responses (Slave devices only) Sometimes Configurable as: "Only when reporting event data", or "When reporting event data or multi-fragment messages."
Timeouts while waiting for:
Data Link Confirm: Complete Appl. Fragment: Application Confirm: Complete Appl. Response:
None None
None None
Fixed at Fixed at Fixed at Fixed at
Variable Variable Variable Variable
Configurable Configurable
Configurable Configurable
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DNP 3.0
Device Profile Document Vendor Name: Schneider Electric Device Name: Easergy P5 Protection Relay
Sends/Executes Control Operations:
WRITE Binary Outputs SELECT/OPERATE DIRECT OPERATE DIRECT OPERATE NO ACK
Never Never Never Never
Count > 1 Pulse On Pulse Off Latch On Latch Off
Never Never Never Never Never
Queue Clear Queue
Never Never
Reports Binary Input Change Events when no specific variation requested:
Never Only time-tagged Only non-time-tagged Configurable to send one or the other
Sends Unsolicited Responses:
Never Configuration
Only certain Objects Sometimes ENABLE/DISABLE UNSOLICITED Function codes supported
Default Counter Object/Variation:
No Counters Reported Configurable Default Object: 20 Default Variation : 1 Point-by-point list attached
Sends Multi-Fragment Responses: Yes
No Configuration
Sequential File Transfer Support:
Append File Mode Custom Status Code Strings Permissions Field File Events Assigned to Class File Events Send Immediately Multiple Blocks in a Fragment Max Number of Files Open
Yes Yes Yes Yes Yes Yes 1
Always Always Always Always
Sometimes Sometimes Sometimes Sometimes
Configurable Configurable Configurable Configurable
Always Always Always Always Always
Sometimes Sometimes Sometimes Sometimes Sometimes
Configurable Configurable Configurable Configurable Configurable
Never Never
Sometimes Sometimes
Configurable Configurable
Reports time-tagged Binary Input Change Events when no specific variation requested:
Never Binary Input Change With Time
Binary Input Change With Relative Time Configurable
Sends Static Data in Unsolicited Responses: Never
When Device Restarts When Status Flags Change
No other options are permitted.
Counters Roll Over at: No Counters Reported Configurable
16 Bits, but roll-over bits not used 32 Bits Other Value:____ Point-by-point list attached
No No
No No
No No
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Implementation table
DNP Object Group and Variation
Group Var Num Num
Description
1
0 Binary Input Any Variation
1
1 Binary Input Packed format
1
2 Binary Input With flags
2
0 Binary Input Event Any Variation
2
1 Binary Input Event Without time
2
2 Binary Input Event With absolute time
3
0 Double-bit Binary Input Any Variation
3
1 Double-bit Binary Input Packed format
3
2 Double-bit Binary Input With flags
4
0 Double-bit Binary Input Any Variation
4
1
Double-bit Binary Input Event Without time
4
2
Double-bit Binary Input Event With absolute time
10
0 Binary Output Any Variation
10
2 Binary Output Output status with flags
12
1
Binary Command Control relay output block (CROB)
20
0 Counter Any Variation
20
1 Counter 32-bit with flag
20
2 Counter 16-bit with flag
20
5 Counter 32-bit without flag
20
6 Counter 16-bit without flag
Request
(Master may issue
Outstation parses)
Function Codes (dec)
Qualifier Codes (hex)
1 (read)
00, 01 (start-stop) 06 (no range, or all)
1 (read)
00, 01 (start-stop) 06 (no range, or all)
1 (read)
00, 01 (start-stop) 06 (no range, or all)
1 (read)
06 (no range, or all) 07, 08 (limited qty)
1 (read)
06 (no range, or all) 07, 08 (limited qty)
1 (read)
06 (no range, or all) 07, 08 (limited qty)
1 (read)
00, 01, 06
Response
(Master parses
Outstation may issue)
Function Codes (dec)
Qualifier Codes (dec)
129 (response) 00, 01, 17,28 129 (response) 00, 01, 17,28
129 (response) 17, 28 (index)
130 (unsol. resp)
129 (response) 17, 28 (index)
130 (unsol. resp)
1 (read)
00, 01, 06
129 (response) 00, 01, 17, 28
1 (read)
00, 01, 06
129 (response) 00, 01, 17, 28
1 (read)
1 (read)
1 (read)
1 (read)
3 (select) 4 (operate) 5 (direct op) 6 (dir. op, no ack) 1 (read) 1 (read) 1 (read) 1 (read) 1 (read)
00, 01, 06 06 (no range, or all) 07, 08 (limited qty) 06 (no range, or all) 07, 08 (limited qty) 00, 01, 06 00, 01, 06
00, 01, 17, 28
00, 01, 06 00, 01, 06 00, 01, 06 00, 01, 06 00, 01, 06
129 (response) 17, 28 (index)
130 (unsol. resp) 129 (response)
17, 28 (index) 130 (unsol. resp)
129 (response) 00, 01, 17, 28
129 (response) 00, 01, 17, 28
129 (response) 129 (response) 129 (response) 129 (response)
00, 01, 17, 28 00, 01, 17, 28 00, 01, 17, 28 00, 01, 17, 28
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DNP Object Group and Variation
Group Var Num Num
Description
30
0 Analog Input Any Variation
30
1 Analog Input 32-bit with flag
30
2 Analog Input 16-bit with flag
30
3 Analog Input 32-bit without flag
30
4 Analog Input 16-bit without flag
30
5 Analog Input Short float
32
0 Analog Input Event Any Variation
32
1 Analog Input Event 32-bit without time
32
2 Analog Input Event 16-bit without time
32
3 Analog Input Event 32-bit with time
32
4 Analog Input Event 16-bit with time
32
5 Short Float Ana. Change Ev. without Time
50
0 Time and Date
50
1 Time and Date Absolute time
52
2 Time Delay Fine
60
0 Class Objects Class 0, 1, 2, 3
60
1 Class Objects Class 0 data
60
2 Class Objects Class 1 data
60
3 Class Objects Class 2 data
60
4 Class Objects Class 3 data
70
3 File Command Object -initiate Open
or Delete operations
70
4 File Command Status Objectt
70
5 File Transport Object
70
6 File Transport Status Object
70
7 File Description Object
80
1 Internal Indications Packed format
90
1 Application Identifier
No Object (function code only)
No Object (function code only)
Request
(Master may issue
Outstation parses)
Function Codes (dec)
Qualifier Codes (hex)
1 (read)
06 (no range,or all)
1 (read)
00, 01, 06
1 (read)
00, 01, 06
1 (read)
00, 01, 06
1 (read)
00, 01, 06
1 (read)
00, 01, 06
1 (read)
06 (no range, or all) 07, 08 (limited qty)
1 (read)
06 (no range, or all) 07, 08 (limited qty)
1 (read)
06 (no range, or all) 07, 08 (limited qty)
1 (read)
06 (no range, or all) 07, 08 (limited qty)
1 (read)
06 (no range, or all) 07, 08 (limited qty)
6, 7, 8 1
1 (read) 1 (read) 2 (write) 23 1 (read) 1 (read) 1 (read)
1 (read)
1 (read)
25, 27
06, 07, 08 06, 07, 08 07, 08 07 06 06 (no range,or all) 06 (no range, or all) 07, 08 (limited qty) 06 (no range, or all) 07, 08 (limited qty) 06 (no range, or all) 07, 08 (limited qty) 5b
26, 30
5b
1
5b
28 2 (write)
16, 17, 18 13 (cold restart) 14 (warm restart)
5b 00 (start-stop) index=7 0
Response
(Master parses
Outstation may issue)
Function Codes (dec)
Qualifier Codes (dec)
129 (response) 129 (response) 129 (response) 129 (response) 129 (response)
00, 01, 17, 28 00, 01, 17, 28 00, 01, 17, 28 00, 01, 17, 28 00, 01, 17, 28
129 (response) 17, 28 (index)
130 (unsol. resp)
129 (response) 17, 28 (index)
130 (unsol. resp)
129 (response) 17, 28 (index)
130 (unsol. resp)
129 (response) 17, 28 (index)
130 (unsol. resp)
129 (response) 17, 28 (index)
130 (unsol. resp)
129 (response) 17, 28
129 (response) 17, 28
129 (response) 129 (response)
07 (limited qty) (qty = 1)
129, 130
5b
129, 130
5b
129, 130
5b
129, 130
5b
129
129
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Supported function codes
The table below is the application layer function codes that DNP3 slave supported.
Code
Function
Transfer function codes
0 Confirm
1 Read
2 Write Control function codes
3 Select
4 Operate
5 Direct operate
6 Direct operate Freeze function codes
7 Immediate freeze
8 Immediate freeze
9 Freeze and clear
Freeze and clear
10
-NO ACK
11 Freeze with time
Freeze with time
12
-NO ACK
Description
Supported
Message fragment confirmation
Yes
No response
Request objects from outstation
Yes
Response with requested objects
Store specified objects to outstation
Yes
Respond with status of operation
Select output point of outstation
Yes
Respond with status of control point
Set output that has previously selected
Yes
Respond with status of control point
Set output directly
Yes
Respond with status of control point
Set output directly
Yes
No response
Copy specified objects to freeze buffer
No
Respond with status of operation
Copy specified objects to freeze buffer
No
No respond
Copy specified objects to freeze buffer and clear objects
No
Respond with status of operation
Copy specified objects to freeze buffer and clear objects
No
No respond
Copy specified objects to freeze buffer at specified time
No
Respond with status of operation
Copy specified objects to freeze buffer at specified time
No
No respond
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Code
Function
Application control function codes
Description
13 Cold restart 14 Warm restart 16 Initialize application
Perform desired reset sequence Respond with a time object Perform desired partial reset operation Respond with a time object Ready the specified application to run Respond with status of operation
17 Start application 18 Stop application
Start the specified application to run Respond with status of operation Stop the specified application to run Respond with status of operation
Configuration function codes
19 Save configuration
Save configuration Respond with status of operation
Enable unsolicited messages 20 Enable unsolicited messages
Respond with status of operation
Disable unsolicited messages 21 Disable unsolicited messages
Respond with status of operation
22 Assign class
Assign specified objects to a class Respond with status of operation
Time synchronization function codes
23 Delay measurement
Perform propagation delay measurement
24 Record current time File transfer
For LAN networks only
25 Open file
26 Close file
27 Delete file
28 get file information
29 Authenticate file
30 Abort file
31 Activate configuration
Response function codes
0 Confirm
Message fragment confirmation
129 Response
Response to request message
130 Unsolicited message
Spontaneous message without request
Communication protocols
Supported
Yes Yes No Yes Yes
No Yes Yes No
Yes No
Yes Yes Yes Yes No Yes No
Yes Yes Yes
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Configuration parameters
Parameter
Bit rate
Parity Wire number Poll line Frame Gap
Value
Description
1200, 4800, 9600,
19200, 38400,
The communication speed, bits per second.
57600, 115200 bps
None, Even, Odd The type of parity bit used.
2, 4
The wires number for serial port.
False, True
Polarized line.
10...500
Specifies the amount of time (calculated by bits) to determine that a frame has been completed.
Slave unit
1...65519
Master unit
1...65534
Linklayer Confirmation Timeout
0 ms 1...65535 ms
Linklayer Retry Count Appl.layer Confirmation Timeout
1...255 0...65535 ms
Appl.layer
EvOnly
Confirmation Mode Double-Bit Input Support
ClockSync Mode
All
No Yes
0 1...64000 s
Float precision
No
enable flag Deadband calculation method
Deadband integrating time Unsolicited resp. mode
Yes Disabled Fixed Integrated 1...200 s
Disabled +Empty&Ena +Empty Enabled
The address of the device (slave address).
The address of the master.
Link layer confirmation disabled. Timeout for link layer confirmation.
Link layer retries if Link layer confirmation is enabled.
Timeout for application layer confirmation.
Confirmation requested for application layer messages containing event information only. Confirmation requested for all application layer messages. Double-Bit input is not supported. Double-Bit input is supported.
Clock synchronisation is requested only at startup. Interval for clock synchronisation request. Integer variation carries values with same precision as float variation. (i.e. voltage 230.4 V as integer: 2304, as float: 2304.0) Float variation has bigger precision than integer variation. (i.e. voltage 230.4V as integer: 230, as float: 230.4) No deadband, no AI events generated. An Event is generated when the AI value change exceeds given deadband. Integrating deadband used.
Integrating time setting used when the Deadband calculation method is Integrated.
Unsolicited responses not in use. Unsolicited response enabled, empty UR sent first, waiting for Enable UR from master. Unsolicited response enabled, empty UR sent first, not waiting for master Enable UR before proceeding. Unsolicited response enabled, starts sending UR's directly.
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Parameter Unsolicited resp. event delay Unsolocited resp. event count
Value 0...200 s
1...10
Description Unsolicited responses are delayed by this amount of seconds from first event.
Unsolicited responses are delayed until this many events are available. Used together with previous parameter.
Unsolicited resp. max event cnt Collision avoidance enable flag Collision avoidance fixed delay Collision avoidance
slots number
1...100 No, Yes 1...200 s 1...255
Maximum number of events in one unsolicited response.
Collision avoidance off/on.
Delay setting used in next parameter. Number of bus access slots available for random bus access. If the line is busy, the slave waits for: fixed delay + random (slots), after the bus becomes idle before accessing the bus.
File Handle timeout
Range: 1 to 3600 second
Timeout for no activity references a file handle to close the file and send a File Transport Status Object (group 70 var 6) using a status code value of file handle expired (0x02).
Range: 1 to 3600 second. Default 60 s.
Default Variation BI
1, 2
Default Variation BI 1, 2
event
Default Variation BO 2
Default Variation DBI 1, 2
Default Variation DBI 1, 2
event
Default Variation Counter
1...6
Default Variation AI
1...5
Default Variation AI event
1...5
1: Single-bit packed. 2: Single-bit with flag. 1: Without time. 2: With absolute time.
2: Binary output status.
1: Without flag. 2: With flag. 1: Without time. 2: With absolute time. 1: 32-bit with flag. 2: 16-bit with flag. 3: Not supported. 4: Not supported. 5. 32-bit without flag. 6: 16-bit without flag. 1: 32-bit with flag. 2: 16-bit with flag. 3. 32-bit without flag. 4: 16-bit without flag. 5: Single precision, floating point without time. 1: 32-bit without time. 2: 16-bit without time. 3: 32-bit with time. 4: 16-bit with time. 5: Single precision, floating point without time.
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Data configuration
In Easergy P5 protection relays, data is mapped to five different categories: · Binary inputs (BI) · Double-bit inputs (DBI) · Analog inputs (AI) · Counters (CNTRS) · Binary outputs (BO)
The configuration of these is described in the following subsections.
Binary inputs
Binary inputs are found in the DNP3: data points BI view of COMMUNICATION menu in eSetup Easergy Pro or Web HMI.
Table 10 - DNP3 data points BI
Parameter Index Class UR
Item
Description The index of the data item in the list. Which class the data point belongs to. (Class 1, 2 or 3).
Controls whether changes in the value of the data point generates unsolicited responses or not. The data point.
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Double-bit inputs
DNP3: data points DBI view of COMMUNICATION menu contains the configuration of Double-bit Inputs.
The configuration of these points is analogous to that of Binary Inputs, see DNP3 data points BI, page 43.
Analog inputs
Analog inputs are configured in the DNP3: data points AI view of COMMUNICATION menu.
Table 11 - DNP3 data points AI
Parameter Index Class UR
Deadband
Item
Description
The index of the data item in the list. Which class the data point belongs to. (Class 1, 2 or 3).
Controls whether changes in the value of the data point generates unsolicited responses or not.
The amount of change in value needed before a change is registered. The range of this setting is 1...4200000000.
The data point.
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Counters
The configuration of counters is found in the DNP3: data points CNTRS view of COMMUNICATION menu.
Binary outputs
Binary outputs are found in the DNP3: data points BO view of COMMUNICATION menu.
The structure of this configuration table is simple: only an index for the data items (data points) and an Item field, which determines which data point if found at the corresponding index. The data points are edited by clicking on an element in the Item column and selecting the desired output.
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Data model of DNP3
Communication protocols
The default Binary Inputs, Double-bit Inputs, Analog Inputs, Counts and Binary Outputs of Easergy P5 protection relays pre-configured in DNP3 can be found in following tables.
Binary inputs
Default Index Default Class
0
1
1
1
2
1
3
1
4
1
5
1
6
1
7
1
8
1
9
1
10
1
11
1
12
1
13
1
14
1
15
1
16
1
17
1
18
1
19
1
Item
DI1 DI2 DI3 DI4 Setting group 1 Setting group 2 Setting group 3 Setting group 4 Logic1 Logic2 Logic3 Logic4 Logic5 Logic6 VI1 VI2 VI3 VI4 VI5 VI6
Double-bit inputs
Default Index Default Class
0
1
1
1
2
1
3
1
4
1
5
1
6
1
7
1
Item
Object1 Object2 Object3 Object4 Object5 Object6 Object7 Object8
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Analog inputs
Default Index 0 1 2 3 4 5 6 7
Default Class 2 2 2 2 2 2 2 2
Item
PS1 value PS2 value PS3 value PS4 value PS5 value PS6 value PS7 value PS8 value
Counters
Default Index Item
0
DI1
1
DI2
2
DI3
3
DI4
Binary outputs
Default Index Item
0
Object1
1
Object2
2
Object3
3
Object4
4
Object5
5
Object6
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IEC 60870-5-101
Communication protocols
Presentation
IEC 60870-5-101 is an accompanying standard for the standards in the IEC 60870-5 series. It defines communication between protection devices and the various devices in a control system (supervisor or RTU) in a substation.
Easergy P5 protection relays using IEC 60870-5-101 work as controlled outstation (slave) units in unbalanced mode. Supported application functions include:
· Process data transmission · Event transmission · Command transmission · General interrogation
· Clock synchronization · Transmission of integrated totals · Acquisition of transmission delay The IEC 60870-5-101 communication in Easergy P5 protection relays is only command and event driven. Therefore only Class 1 data is reported. Class 2 is not be used.
Class 1 data is handled in the following priority order: · Command responses · Events (binary events, analog events, counter value change events) The event buffer size of IEC 60870-5-101 is 250. · General Interrogation data
Chronology between events and requested data are always maintained. For lists of default data mappings in Easergy P5 protection relays, refer to Data model of IEC 60870-5-101, page 55.
IEC 60870-5-101 configuration
This section explains how to configure Easergy P5 protection relays to use the IEC 60870-5-101 protocol.
General configuration
The IEC 60870-5-101 protocol is activated by setting it as the port protocol for a serial port on the device. This setting can be found by navigating to the COMMUNICATION menu and Protocol configuration view in the eSetup Easergy Pro or Web HMI.
The IEC 60870-5-101 protocol is activated on the Remote port as follows:
NOTE: Setting a protocol to any port requires a reboot of the device for the changes to take effect. eSetup Easergy Pro will prompt for a reboot.
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Once the protocol has been activated, it can be configured. This is done with eSetup Easergy Pro in the IEC 60870-5-101 main config view. All values shown are defaults.
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Table 12 - IEC 60870-5-101 main configuration parameters
Parameter Bit rate Parity WireNum PolLine FrameGap
Link layer address Link layer address size ASDU address ASDU address size IO address size Cause of transmission size Time tag format
Measurements format
Deadband enable flag
Deadband cycle
Value 1200, 2400, 4800, 9600, 19200, 38400, 57600, 115200 bps None, Even, Odd 2, 4 False, True 10...500
1 byte: 1...254 2 bytes: 1...65534 1 or 2 bytes 1 byte: 1...254 2 bytes: 1...65534 1 or 2 bytes 2 or 3 bytes 1 byte
Short, Full
Scaled, Normalised, Float
On, Off
100...10000 ms
Description
Communication speed
Parity used for serial communication
Number of wire connection
Polarity of the wire connection
Specifies the amount of time (calculated by bits) to use to determine that a frame has been completed
Device address
Size of the device address
Address of data segment on the same device address
Size of the ASDU
Size of Information Object address
Size of the code for the reason why a message is sent
Determines the time tag format: 3-octet time tag of 7- octet time tag
Determines the data format for measurements, float, normalised or scaled values
Enabling of deadband measurements and event generation
The interval of deadband calculations
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Data configuration
Data and commands are mapped to six different tables: Single point information (SPI), Double point information (DPI), Analog inputs (AI), Analog events (AE), Integrated totals (IT) and Commands (CMD). The settings for these categories are described in the following subsections.
Single and double point information
Single point information (SPI) objects are one-bit data items (range 0...1). Double point information objects are two-bit data items (range 0...3). Default SPI and DPI mapping are shown in figures below.
A description of the column elements for SPI and DPI objects is given in the table.
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NOTE: Information object address (Index) 1 is reserved for an SPI object: Class 1 buffer overflow indication (BOV1).
Table 13 - SPI and DPI mapping table
Parameter Index GI
Event
Item
Description
Information object address
Determines whether the object is included in response to General Interrogation request message (Enabled/Disabled)
Determines whether change events for the object are put into Class 1 buffer (Enabled/Disabled)
The data item which is configured on the row (for instance, DI1)
Analog inputs
Analog inputs are measurement values that are float, scaled or normalised. Scaling is done according to the scaling settings found under the list item Modbus and IEC 60870-5-101 specific scalings in eSetup Easergy Pro or Web HMI (it applies to IEC 60870-5-101 if the protocol is configured to use scaled values). When using float for measurement values, no scalling is needed.
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NOTE: Measurement values have no time tags when read upon request. Change events (based on deadband supervision) are sent with time tags with cause of transmission spontaneous in Class 1. The time tag format is determined by the interface configuration (general time tag format selection parameter).
Table 14 - AI mapping table
Parameter Index GI Event Deadband Max
Item
Description
Information object address
Determines whether the object is included in response to General Interrogation request message (Enabled/Disabled)
Determines whether change events for the object are put into Class 1 buffer (Enabled/Disabled)
Deadband value for change supervision and change event generation (valid only if Event is Enabled).
Maximum value for defining the value range as Max...+Max. This range is transformed to the range -1...+1 if the protocol measurement format is set to "Normalised"
The data item which is configured on the row
Analog events
These analog values are fault event and are sent with time tags. The values are float, normalised or scaled measured values. A part of the default data mapping is shown in following figure.
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Table 15 - AE mapping table
Parameter Index Event
Item
Description
Information object address
Determines whether change events for the object are put into Class 1 buffer (Enabled/Disabled)
The data item which is configured on the row
Integrated totals
Integrated totals are energy and pulse counter values. the following figure is a part of the mapping table in eSetup Easergy Pro.
Table 16 - Integrated totals mapping table
Parameter
Index
CI Counter Interrogation
Item
Description Information object address Determines whether the object is included in responses to Counter Interrogation messages (Enabled/Disabled)
The data item which is configured on the row
Command items
The commands are divided into two categories: Select Before Operate and Direct Operate.
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Table 17 - Description of command items
Parameter Index Item
Description Information object address The data item which is configured on the row
Scaling
Measured values that transferred as signed integers of 16 bits are in the range: 215 ··· 215 1 = 32768 ··· 32767. Thus values that exceed this range are scaled in order to be successfully sent over an IEC 101 data link.
The scaling is determined by the float value of corresponding specific scalings. It is common to use scaling factors with base ten (0.100,1.000,10.000, 100.000...). In such cases, only the decimals are removed from the original measurements and such values are easy to read and rescale to actual values on the client side after transmission. Different settings for scaling can be used for the power-, power factor-, tan phi-, voltage- and frequency scaling. These settings for scaling can be set by navigating to the Modbus and IEC 60870-5-101 specific scalings view in the COMMUNICATION menu in eSetup Easergy Pro or Web HMI.
A short example: The frequency is internally (in the Easergy P5 protection relays) stored as an integer value which also holds three decimal places, that is, 50.000 Hz is represented as 50000. This is a value too large to be represented with 16 bits (signed integer). However, frequency is multipled by default scaled value 0.1, enabling it to be sent over the data line.
Thus, the value on the receiving side (the scaled value) is:
valueScaled = k valueInternal = 0.1 50000 = 5000 NOTE: It is highly recommended to scale values so that they are kept in the interval 0 32768 to avoid overflow.
Normalisation
When using normalisation for measured values, the normalised value is calculated using the Max parameter, which determines the range for the data (- Max ... + Max).
An example:
The frequency is internally (in the Easergy P5 protection relays) stored as an integer value which also holds three decimal places, that is, 50.000 Hz is represented as 50000. If normalisation is activated and the Max value set to 100000, the value sent over the data link is (in the ideal case):
value Normalised = valueInternal/Max = 50000/100000 = 0.5
Currently, however, the scaling is also performed before normalisation. This means that the scaling is always active.
The equation is therefore:
value Normalised = valueScaled/Max = 0.1 x 50000/100000 = 0.05
Float
When using Float for measured values, no scaling will be used. An example: 50.000 Hz is represented as 50, just use the raw value to transfer.
Event buffer size
The event buffer size is defined as 250. That means IEC 60870-5-101 can store maximum 250 events internally.
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Data model of IEC 60870-5-101
The default Single Point Information, Double Point Information, Analog Inputs, Analog Events, Intergrated Totals and Command of Easergy P5 protection relays pre-configured in IEC 60870-5-101 can be found in following tables.
Default single and double point information
Table 18 - Single point information
Default Index 2 3 4 5 6 7 8 9 10 11 12 13 14 15
Item DI1 DI2 DI3 DI4 Setting group 1 Setting group 2 Setting group 3 Setting group 4 Logic1 Logic2 Logic3 Logic4 Logic5 Logic6
Table 19 - Double point information
Default Index 4097 4098 4099 4100 4101 4102 4103 4104
Item Object1 Object2 Object3 Object4 Object5 Object6 Object7 Object8
Analog inputs
Default Index 16385 16386 16387 16388 16389 16390 16391 16392
Deadband 1.000 1.000 1.000 1.000 1.000 1.000 1.000 1.000
Max 1000 1000 1000 1000 1000 1000 1000 1000
Item PS1 value PS2 value PS3 value PS4 value PS5 value PS6 value PS7 value PS8 value
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Analog events
Default Index 18433 18434 18435 18436 18437 18438 18439 18440
Item PS1 value PS2 value PS3 value PS4 value PS5 value PS6 value PS7 value PS8 value
Integrated totals
Default Index 20481 20482 20483 20484
Item DI1 DI2 DI3 DI4
Default command
Table 20 - Select Before Operate table
Default 34817 34818 34819 34820 34821 34822
Item Object1 Object2 Object3 Object4 Object5 Object6
Table 21 - Digital Output table
Default Index 32769 32770 32771 32772 32773 32774 32775 32776 32777 32778
Item Setting group 1 Setting group 2 Setting group 3 Setting group 4 Object1 Object2 Object3 Object4 Object5 Object6
Communication protocols
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IEC 60870-5-103
Presentation
IEC 60870-5-103 is an accompanying standard for the standards in the IEC 60870-5 series. It defines communication between protection devices and the various devices in a control system (supervisor or RTU) in a substation.
The unbalanced transmission mode of the protocol is used, and the device functions as a secondary station (slave) in the communication. Data is transferred to the primary system using the "data acquisition by polling" principle.
The Easergy P5 protection relay supports the following IEC 61870-5-103 application functions:
· Data acquisition by polling · General initialization · Station initialization · General interrogation · Clock synchronization · Command transmission · Transmission of disturbance data · Read and write setting data The following functions are not supported: · Generic services · Test mode · Blocking in monitoring direction The following ASDU (Application Service Data Unit) types are used in communication from the Easergy P5 protection relays: · ASDU 1: Time tagged message · ASDU 3: Measurands I · ASDU 4: Time-tagged measurands with relative time · ASDU 5: Identification message · ASDU 6: Time synchronization · ASDU 8: Termination of general interrogation · ASDU 9: Measurands II Easergy P5 protection relays accept: · ASDU 6: Time synchronization · ASDU 7: Initiation of general interrogation · ASDU 20: General command The ASDUs from 23 to 31 are used for disturbance data transmission.
The ASDU 140, ASDU 144, ASDU 17, ASDU 201, ASDU 169, ASDU 49 are used to write and read setting data.
The ASDU 135, which is related with SPA-bus, is not supported.
The data in a message frame is identified by: · Type identification · Function type (TYP) · Information number (INF)
For more information on the IEC 60870-5-103 protocol, visit www.iec.ch.
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IEC 60870-5-103 configuration
This section explains how to configure Easergy P5 protection relays to use the IEC 60870-5-103 protocol.
General configuration
The IEC 60870-5-103 protocol is activated by setting it as the port protocol for a serial port on the device. This setting can be found by navigating to the COMMUNICATION menu and Protocol configuration view in the eSetup Easergy Pro or Web HMI. IEC 60870-5-103 protocol is activated on the Remote port.
NOTE: Setting a protocol to any port will require a reboot of the device for the changes to take effect. eSetup Easergy Pro will prompt for a reboot. Once the protocol has been activated, it can be configured. This is done with eSetup Easergy Pro in the IEC 60870-5-103 main config view. All values shown are defaults.
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Table 22 - IEC 60870-5-103 main configuration parameters
Parameter IEC-103 slave number Speed of transmission
Wire number Poll line Frame Gap (bits)
Value
1 ... 254
1200, 2400, 4800, 9600, 19200, 38400, 57600, 115200 bps
2, 4
False, True
10 ... 500
Measure sending interval
ASDU6 response time mode
200 ... 10000 ms Sync;
Sync + Proc;
Msg;
Msg + Proc
Include start and restart
On, Off
Description
A unique address within the system setup
Communication speed
Number of wire connection
Polarity of the wire connection
Specifies the amount of time (calculated by bits) to use to determine that a frame has been completed
Minimum measurement response interval
The time in the slave's response = the master's time.
The time in the slave's response = the master's time + internal processing time (standard).
The time in the slave's response = the slave's time at the moment when the clock sync message arrived.
The time in the slave's response = the slave's time at the moment when the clock sync message arrived + internal processing time.
Table 23 - IEC 60870-5-103 disturbance recorder parameter
Parameter
Enable record info message
Record samples in message
Record reading timeout
Fault number of active record
Value On, Off
1 ... 25
10 ... 10000 s (not editable)
Tags read position
(not editable)
Active channel
(not editable)
Channel read position
(not editable)
Description
Enable record information messages
Record samples in one message
Record reading timeout
The fault number of the current record. This is a number which is given by Easergy P5 protection relays, incrementally and is what identifies faults.
Tags are indications of change in the value of digital data. The current tag read position shows which such item is being read.
"Channel" refers to the channels in Easergy P5 protection relays Disturbance recorder, which can be found in the DISTURBANCE RECORDER view in eSetup Easergy Pro. The active channel indicates which channel is being read.
A channel contains sampled analog values. The current read position indicates which of these entries in the active channel is being read.
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Data configuration
The data points available through the IEC 60870-5-103 protocol interface in Easergy P5 protection relays can be configured in the IEC 60870-5-103: Data config view. It is divided into two categories, Digital data points (1-bit values) and Analog data points.
Digital data
The parameters, by which digital data points are defined, are explained below. In order to change the value of an existing data item, click on the row. This brings up an item configuration window, in which the parameters can be set. Pressing Save in the window will save the item set, pressing Remove will remove the item from the list and pressing Cancel will close the popup window without making any changes to the digital item configuration.
In order to add new items to the list, press the ADD Item row furthest down in the list. Doing so will add a new item at the end of the list. New items will be set to Digital Input 1 by default. The new item is configured as explained in the previous paragraph.
Table 24 - Description of digital data configuration parameters
Parameter Index FUN INF GI
EVENT CONTROL Item
Description
Index of the data item in the list Function type
Information number Item included in General Interrogation (Enabled/Disabled) and data acquisition by polling
Events enabled for change of item value (Enabled/Disabled)
Item value can be set by command (Enabled/Disabled)
The data item which is configured on the row (for instance, Digital Input 1)
NOTE: Changes will not take effect if they are not explicitly written to the device using the Write changes to device button in eSetup Easergy Pro. This will require a reboot.
NOTE: The read command for digital data according to FUN and INF is not supported. If the GI parameter is disabled, the item value will not be included in response message by GI command. The value changing event is reported only by polling command.
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Analog data
The parameters, by which analog data points are defined, are explained below. In order to change the value of an existing data item, click on the row. This brings up an item configuration window, in which the parameters can be set. Pressing Save in the window will save the item set, pressing Remove will remove the item from the list and pressing Cancel will close the popup window without making any changes to the analog item configuration.
In order to add new items to the list, press the ADD Item row furthest down in the list. Doing so will add a new item at the end of the list. The new item is configured as explained in the previous paragraph.
Table 25 - Description of analog data configuration parameters
Parameter Index FUN INF ASDU
Items
Description
Index of the data item in the list
Function type
Information number
Application service data unit to be used to send the data item: ASDU 3.1: analog data 1 value ASDU 3.2: analog data 2 values ASDU 3.3: analog data 4 values ASDU 3.4: analog data 2 values ASDU 4: analog data floating point value ASDU 9: analog data 9 values
The data item which is configured on the row
NOTE: Changes will not take effect if they are not explicitly written to the device using the Write changes to device button in eSetup Easergy Pro. This will require a reboot.
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Measurement data
Analog measurements are transferred in two different formats, as integers and as floating point values. The value format depends on the application message type, ASDU. The following ASDU types are available for measurement values:
Table 26 - ASDU types for measurement values
ASDU 3.1 3.2 3.3 3.4 9 4
Number of measurements in one message 1 2 4 2 9 1
Format Integer
Float
Integer value scaling
Integer scaled values in ASDU 3.x and 9 are transferred in 12 bit + sign integer format. The raw 12 bit values (-4096 ... +4095) are relative to 2.4 x nominal values. The following table shows the scaling for different measurements. The values of scaling settings can be found in the SCALING view in eSetup Easergy Pro.
NOTE: Integer RTD value is specially relative to 0.24 x nominal values (32768).
Table 27 - Integer scaled values
Type Current Residual current
Voltage Residual voltage Power Other
Measurement
IL1 ... IL3 loCalc Ir Irvs VL1...VL3 U12...U13 Ur
P, Q, S
DI counters PF, Cos Phi
Scaling 2.4 × IN
2.4 × IrN 2.4 × IrvsN 2.4 × UN
2.4 × UrN 2.4 × IN × UN × 3 1:1 2.4:1
An example: The device transfers phase 1 current, IL1, with ASDU 3.1. The scaling setting is as follows: CT primary = 500 A. The measured value M = 321 A. Thus, the value sent, B = M ×(4096/(2.4×500))= 321 ×(4096/(2.4×500))= 1095 The protocol master receives the value: B = 1095 OVF (Overflow bit in frame): No Valid: Yes This value is converted back to the measured value: M = B ×((2.4 × 500)/4096) = 1095 × ((2.4 × 500)/4096) = 320.8 321 A
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An example:
The device transfers phase 1 current, IL1, with ASDU 3.1.
The scaling setting is as follows: CT primary = 500 A.
The measured value M = 1321 A.
Thus, the value sent, B = M × (4096/(2.4 × 500))= 1321 × (4096/(2.4 × 500)) = 4509, is too large a value to fit into twelve bits. Thus, the value is sent as B = 4095 (the largest value that can be sent with twelve bits) and the OVF (Overflow flag) set.
The protocol master receives the value: B = 4095
OVF (Overflow bit in frame): Yes
Valid: Yes
This value is converted back to the measured value: M 2.4 × 500 A, so M 1200 A
Floating point values
Values transferred in ASDU 4 need not be scaled. Most of the measurements are sent as primary scaled values, but some values can be sent as per unit (PU) values. This setting can be changed via the local panel on the Easergy P5 protection relays.
Measurement Fault current I> Fault current I>> Fault current I>>> Fault reactance Exported energy Exported reactive energy
Format PU or A PU or A PU or A MWh Mvarh
Write and read setting data
ASDU types description
These are the ASDU types available: · ASDU 140 in the control direction setting read request · ASDU 143 in the control direction setting write request (8 bits) · ASDU 144 in the control direction setting write request (16 bits) · ASDU 201 in the control direction setting write request (32 bits) · ASDU 49 in the monitor direction reject setting read/write request (8 bits) · ASDU 168 in the monitor direction answer to setting read/write request (8 bits) · ASDU 17 in the monitor direction answer to setting read/write request (16 bits) · ASDU 169 in the monitor direction answer to setting read/write request (32 bits)
P5/EN M/33A
63
Communication protocols
ASDU 140 (8CH): Control Direction Table 28 - ASDU 140 for IEC 60870-5-103 setting
Type identification Variable Struct. Qualifier Cause of Transmission Device address Function byte (FUN) Information number (INF)
8CH (Read protection parameter) 81H 14H Common address of ASDU Parameter y-Value Parameter x-Value
ASDU 143 (8FH): Control Direction Table 29 - ASDU 143 for IEC 60870-5-103 setting
Type identification Variable Struct. Qualifier Cause of transmission Device address Function byte (FUN) Information number (INF) Value byte
8FH (Write analog protection parameter) 81H 14H Common address of ASDU Parameter y-Value Parameter x-Value byte
ASDU 144 (90H): Control Direction Table 30 - ASDU 144 for IEC 60870-5-103 setting
Type identification Variable Struct. Qualifier Cause of transmission Device address Function byte (FUN) Information number (INF) Value low-byte Value high-byte
90H (Write analog protection parameter) 81H 14H Common address of ASDU Parameter y-Value Parameter x-Value word (low) word (high)
ASDU 201 (C9H): Control Direction Table 31 - ASDU 201 for IEC 60870-5-103 setting
Type identification Variable Struct. Qualifier Cause of transmission Device address Function byte (FUN) Information number (INF) Byte 1 Byte 2 Byte 3 Byte 4
C9H (Write analog protection parameter) 81H 14H Common address of ASDU Parameter y-Value Parameter x-Value Low word (low) Low word (high) High word (low) High word (high)
64
P5/EN M/33A
Communication protocols
Type identification 49 (31H): Monitor direction Table 32 - ASDU 49 for IEC 60870-5-103 setting
Type identification Variable Struct. Qualifier Cause of transmission Device address Function byte (FUN) Information number (INF) Value low-byte Value high-byte TT (Time tag)
31H (Analog protection signal) 81H 15H Common address of ASDU Parameter y-Value Parameter x-Value MW (low) MW (high) ms low ms high IV 0 m m m m m m SU 0 h h h h h
Reject the read request or write request with special Fun and INF values as below.
Special values Function byte (FUN) = 7FH and Information number (INF) = FFH shall be used as a negative response on a command message ("Rejection telegram"): in this case MW contains the error code, so the cause of rejection.
The list of causes of rejection possibly used is as follows:
Cause of rejection 80H 00H 80H 07H 80H 08H 80H 09H 80H 30H
Meaning OK Unknown parameter address Wrong data Wrong frame data length Wrong data in message
ASDU 168 (A8H): Monitor direction Table 33 - ASDU 168 for IEC 60870-5-103 setting
Type identification Variable Struct. Qualifier Cause of transmission (COT) Device address Function byte (FUN) Information number (INF) Byte 1 TT (Time tag)
A8H (Analog protection parameter) 81H 14H Common address of ASDU Parameter y-Value Parameter x-Value byte ms low ms high IV 0 m m m m m m SU 0 h h h h h
P5/EN M/33A
65
Communication protocols
ASDU 17 (11H): Monitor direction Table 34 - ASDU 17 for IEC 60870-5-103 setting
Type identification Variable Struct. Qualifier Cause of Transmission Device address Function byte (FUN) Information number (INF) Value low-byte Value high-byte TT (Time tag)
11H (Analog protection parameter) 81H 14H Common address of ASDU Parameter y-Value Parameter x-Value word (low) word (high) ms low ms high IV 0 m m m m m m SU 0 h h h h h
ASDU 169 (A9H): Monitor direction Table 35 - ASDU 169 for IEC 60870-5-103 setting
Type identification Variable Struct. Qualifier Cause of transmission (COT) Device address Function byte (FUN) Information number (INF) Byte 1 Byte 2 Byte 3 Byte 4 TT (Time tag)
A9H (Analog protection parameter) 81H 14H Common address of ASDU Parameter y-Value Parameter x-Value Low word (low) Low word (high) High word (low) High word (high) ms low ms high IV 0 m m m m m m SU 0 h h h h h
COT Meaning (Cause of Transmission): In a response to a write command only: = 14H - Positive acknowledge to a read/write command. = 15H - Negative acknowledge to a write command. (All the frame structure may be changed according to last design.)
Setting data addressing
All setting data are addressed by y-Value (FUN) / x-Value (INF) corresponding to each protection and item.
The list of setting parameters displayed on eSetup Easergy Pro for each function are not editable. The user can select setting items by using the parameters FUN, INF and ASDU (for writing different types). Each item's FUN and INF can't been changed. The Master uses ASDU140 for all value types' reading requests.
66
P5/EN M/33A
Communication protocols
Figure 2 - IEC 60870-5-103 setting data points
Table 36 - IEC 60870-5-103 setting parameters
Parameter Item FUN INF ASDU
Description
Db item
Function type(y-Value)
Information number(x-Value)
Application service data unit to be used to send the data item:
ASDU 140: read request for master ASDU 143: write 8 bits type request for master ASDU 144: write 16 bits type request for master ASDU 201: write 32 bits type request for master
Data model of IEC 60870-5-103
The default digital and analog data of Easergy P5 protection relays preconfigured in IEC 60870-5-103 can be found in following tables.
Default digital configuration
Defaut Index
FUN
INF
000
55
161
001
55
162
002
55
163
003
55
164
004
55
181
005
55
182
006
55
183
007
55
184
008
55
185
Item CB Open_DI1 CB Close_DI2 Digital input 3 External trip_DI4 Object1 state Object2 state Object3 state Object4 state Object5 state
P5/EN M/33A
67
Defaut Index 009 010 011 012 013 014 015 016 017 018 019 020 021 022 023 024 025 026 027 028 029 030 031 032 033 034 035 036 037 038 039 040 041 042 043 044 045 046 047 048 049
FUN 55 55 55 160 160 160 160 160 160 160 160 160 160 160 160 160 160 160 160 160 160 160 160 160 160 55 55 55 55 160 160 160 160 160 160 160 160 160 160 160 160
Communication protocols
INF
Item
186
Object6 state
187
Object7 state
188
Object8 state
20
Logic output 1 on
21
Logic output 2 on
22
Logic output 3 on
23
Logic output 4 on
24
Logic output 5 on
25
Logic output 6 on
26
Logic output 7 on
27
Logic output 8 on
28
Logic output 9 on
29
Logic output 10 on
130
Virtual input 1
131
Virtual input 2
132
Virtual input 3
133
Virtual input 4
134
Virtual input 5
135
Virtual input 6
136
Virtual input 7
137
Virtual input 8
138
Virtual input 9
139
Virtual input 10
140
CB Fail 1 Trip On
141
CB Fail 2 Trip On
23
Setting group 1
24
Setting group 2
25
Setting group 3
26
Setting group 4
103
Prg1 start
105
Prg1 trip
98
Prg2 start
100
Prg2 trip
99
Prg3 start
101
Prg3 trip
180
Prg4 start
181
Prg4 trip
69
Prg5 start
70
Prg5 trip
71
Prg6 start
19
Prg6 trip
68
P5/EN M/33A
Communication protocols
Default analog configuration parameters
Default Index
FUN
INF
050
160
65
ASDU 4
Item Frequency
Name
ARC setting items I>int. pick-up value Io>int. pick-up value Arc stage 1 enabled Arc stage 2 enabled Arc stage 3 enabled Arc stage 4 enabled Arc stage 5 enabled Arc stage 6 enabled Arc stage 7 enabled Arc stage 8 enabled Stage 1 Mode Stage 2 Mode Stage 3 Mode Stage 4 Mode Stage 5 Mode Stage 6 Mode Stage 7 Mode Stage 8 Mode Trip 1 delay [x1ms] Trip 2 delay [x1ms] Trip 3 delay [x1ms] Trip 4 delay [x1ms] Trip 5 delay [x1ms] Trip 6 delay [x1ms] Trip 7 delay [x1ms] Trip 8 delay [x1ms] Min. hold time [x1ms] Min. hold time2 [x1ms] Min. hold time3 [x1ms] Min. hold time4 [x1ms] Min. hold time5 [x1ms]
FUN
1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1
1
1
1
Setting data
The setting values that can be configured in IEC 60870-5-103 on the Easergy P5 protection relay is listed in the table below:
INF ASDU
Scaling
P5U20 LPCT/LPVT
P5U20
P5V20
P5F30
P5M30
0
201 1.00 xIn = 100
1
201 1.00 xIn = 100
2
143 Off=0;On=1
3
143 Off=0;On=1
4
143 Off=0;On=1
5
143 Off=0;On=1
6
143 Off=0;On=1
7
143 Off=0;On=1
8
143 Off=0;On=1
9
143 Off=0;On=1
10
143 Light=0;Light&Current=1
11
143 Light=0;Light&Current=1
12
143 Light=0;Light&Current=1
13
143 Light=0;Light&Current=1
14
143 Light=0;Light&Current=1
15
143 Light=0;Light&Current=1
16
143 Light=0;Light&Current=1
17
143 Light=0;Light&Current=1
18
143 1 = 1
19
143 1 = 1
20
143 1 = 1
21
143 1 = 1
22
143 1 = 1
23
143 1 = 1
24
143 1 = 1
25
143 1 = 1
26
201 1 = 1
27
201 1 = 1
28
201 1 = 1
29
201 1 = 1
30
201 1 = 1
P5/EN M/33A
69
Communication protocols
Name
FUN
Min. hold time6 [x1ms]
1
Min. hold time7 [x1ms]
1
Min. hold time8 [x1ms]
1
Inrush setting
Enable for Inrush
2
Max inrush current
2
Pickup for 2nd harmonic
2
OverCurrent I> setting
Enable for I>
3
Pick-up value
3
Delay curve family
3
Delay type
3
Operation delay
3
Inv. time coefficient
3
Reset time
3
Inrush status for I>
3
SOL use by I>
3
SOL Operation delay
3
SOL Inv. time coefficient
3
CLPU status for I>
3
CLPU Pick-up value
3
CLPU Operation delay
3
CLPU Inv. time coefficient
3
Include harmonics
3
Reset type
3
OverCurrent I>> setting
Enable for I>>
4
Pick-up value
4
Delay curve family
4
Delay type
4
Operation delay
4
Inv. time coefficient
4
Inrush status for I>>
4
INF ASDU
Scaling
31
201 1 = 1
32
201 1 = 1
33
201 1 = 1
0
143 Off=0;On=1
1
201 1.00 xIn = 100
2
201 1 % = 1
0
143 Off=0;On=1
1...4 201 1.00 xIn = 100
DT=0;IEC=1;IEEE=2;
5...8
143 IEEE2=3;Others=4;
Prg1=5;Prg2=6;Prg3=7
9...12
DT=0;NI=1;VI=2;EI=3; LTI=4;LTEI=5;LTVI=6; 143 MI=7;STI=8;STEI=9; CO8=10;RI=11;RXIDG= 12
13...16 201 1.00 s = 100
17...20 201 1.000 = 1000 21...24 201 1.00 s = 100 25...28 143 Off=0;On=1
29...32 143 Off=0;On=1
33...36 201 1.00 s = 100
37...40 201 1.000 = 1000
41...44 143 Off=0;On=1 45...48 201 1.00 xIn = 100
49...52 201 1.00 s = 100
53...56 201 1.000 = 1000
57
143 Off=0;On=1
58...61 143 DT=0;IDMT=1
0
143 Off=0;On=1
1...4 201 1.00 xIn = 100
DT=0;IEC=1;IEEE=2;
5...8
143 IEEE2=3;Others=4;
Prg1=5;Prg2=6;Prg3=7
9...12
DT=0;NI=1;VI=2;EI=3; LTI=4;LTEI=5;LTVI=6; 143 MI=7;STI=8;STEI=9; CO8=10;RI=11;RXIDG= 12
13...16 201 1.00 s = 100
17...20 201 1.000 = 1000 21...24 143 Off=0;On=1
P5U20 LPCT/LPVT
P5U20
P5V20
P5F30 P5M30
70
P5/EN M/33A
Communication protocols
Name
FUN INF ASDU
Scaling
SOL use by I>>
4
SOL Operation delay
4
SOL Inv. time coefficient
4
CLPU status for I>>
4
CLPU Pick-up value
4
CLPU Operation delay
4
CLPU Inv. time coefficient
4
Include harmonics
4
Reset type
4
Reset time
4
OverCurrent I>>> setting
Enable for I>>>
5
Pick-up value
5
Operation delay
5
Inrush status for I>>>
5
SOL use by I>>>
5
SOL Operation delay
5
CLPU status for I>>>
5
CLPU Pick-up value
5
CLPU Operation delay
5
SOTF setting
Enable for SOTF
6
Pick-up value
6
Dead line detection delay
6
SOTF active Timer
6
Dead line detection input
6
I> setting
Enable for I>
7
Pick-up value
7
Direction mode
7
Angle offset
7
Delay curve family
7
Delay type
7
25...28 143 Off=0;On=1 29...32 201 1.00 s = 100 33...36 201 1.000 = 1000 37...40 143 Off=0;On=1 41...44 201 1.00 xIn = 100 45...48 201 1.00 s = 100
49...52 201 1.000 = 1000
53
143 Off=0;On=1
54...57 143 DT=0;IDMT=1
58...61 201 1.00 s = 100
0
143 Off=0;On=1
1...4 201 1.00 xIn = 100
5...8 201 1.00 s = 100
9...12 143 Off=0;On=1
13...16 143 Off=0;On=1
17...20 201 1.00 s = 100
21...24 143 Off=0;On=1
25...28 201 1.00 xIn = 100
29...32 201 1.00 s = 100
0
143 Off=0;On=1
1
201 1.00 xIn = 100
2
201 1.00 s = 100
3
201 1.00 s = 100
4
144 Value 5
0
143 Off=0;On=1
1...4 201 1.00 xIn = 100
5...8
143
Dir+Backup=0;Undir=1; Dir=2
9...12 144 1 ° = 1
DT=0;IEC=1;IEEE=2;
13...16 143 IEEE2=3;Others=4; Prg1=5;Prg2=6;Prg3=7
DT=0;NI=1;VI=2;EI=3; 17...20 143 LTI=4;LTEI=5;LTVI=6;
MI=7;STI=8;STEI=9;
P5U20 LPCT/LPVT
P5U20
P5V20
P5F30
P5M30
5. DI1=1;DI2=2;...;DI19=19;DI20=20;Arc1=25;Arc2=26;BI=27;VI1=29;VI2=30;VI3=31;VI4=32;DO1(B)=33;DO2(B)=34;DO3(B)=35; Watchdog=36;SF=37;SF=38;...;SF=40;SF=41;BO=42;DO1(C)=43;DO2(C)=44;DO3(C)=45;DO4(C)=46;LedAl=49;LedTr=50;LedA=51; LedB=52;LedC=53;LedDR=54;VO1=55;VO2=56;...;DI39=83;DI40=84;F1=85;F2=86;...;F6=90;F7=91;DO1(D)=97;DO2(D)=98;DO3(D) =99;SF=100;DO1(E)=101;DO2(E)=102;NI1=129;NI2=130;...;NI63=191;NI64=192;POC1=193;POC2=194;...;POC15=207;POC16=208; VI5=225;VI6=226;...;VI19=239;VI20=240;VO7=257;VO8=258;...;VO19=269;VO20=270;NI65=289;NI66=290;...;NI127=351;NI128=352
P5/EN M/33A
71
Communication protocols
Name
Operation delay Inv. time coefficient Reset time Inrush status for I> SOL status for I> SOL Operation delay SOL Inv. time coefficient CLPU status for I> CLPU Pick-up value CLPU Operation delay CLPU Inv. time coefficient Reset type I>> setting Enable for I>> Pick-up value
Direction mode Angle offset
Delay curve family
Delay type
Operation delay Inv. time coefficient Reset time Inrush status for I>> SOL status for I>> SOL Operation delay SOL Inv. time coefficient CLPU status for I>> CLPU Pick-up value CLPU Operation delay CLPU Inv. time coefficient Reset type I>>> setting Enable for I>>> Pick-up value
FUN
7 7 7 7 7 7 7 7 7 7 7 7
8 8 8 8
8
8
8 8 8 8 8 8 8 8 8 8 8 8
9 9
INF ASDU
Scaling
CO8=10;RI=11;RXIDG= 12 21...24 201 1.00 s = 100 25...28 201 1.000 = 1000 29...32 201 1.00 s = 100 33...36 143 Off=0;On=1 37...40 143 Off=0;On=1 41...44 201 1.00 s = 100
45...48 201 1.000 = 1000
49...52 143 Off=0;On=1 53...56 201 1.00 xIn = 100
57...60 201 1.00 s = 100
61...64 201 1.000 = 1000 65...68 143 DT=0;IDMT=1
0
143 Off=0;On=1
1...4 201 1.00 xIn = 100
5...8
143
Dir+Backup=0;Undir=1; Dir=2
9...12 144 1 ° = 1
DT=0;IEC=1;IEEE=2;
13...16 143 IEEE2=3;Others=4; Prg1=5;Prg2=6;Prg3=7
DT=0;NI=1;VI=2;EI=3; LTI=4;LTEI=5;LTVI=6; 17...20 143 MI=7;STI=8;STEI=9; CO8=10;RI=11;RXIDG= 12
21...24 201 1.00 s = 100
25...28 201 1.000 = 1000 29...32 201 1.00 s = 100
33...36 143 Off=0;On=1
37...40 143 Off=0;On=1
41...44 201 1.00 s = 100
45...48 201 1.000 = 1000
49...52 143 Off=0;On=1 53...56 201 1.00 xIn = 100
57...60 201 1.00 s = 100
61...64 201 1.000 = 1000 65...68 143 DT=0;IDMT=1
0
143 Off=0;On=1
1...4 201 1.00 xIn = 100
P5U20 LPCT/LPVT
P5U20
P5V20
P5F30 P5M30
72
P5/EN M/33A
Communication protocols
Name
Direction mode
Angle offset Operation delay Inrush status for I>>> SOL status for I>>> SOL Operation delay CLPU status for I>>> CLPU Pick-up value CLPU Operation delay I>>>> setting Enable for I>>>> Pick-up value
Direction mode
Angle offset Operation delay Inrush status for I>>>> SOL status for I>>>> SOL Operation delay CLPU status for I>>>> CLPU Pick-up value CLPU Operation delay P< setting Enable for P< Pick-up value Operation delay P<< setting Enable for P<< Pick-up value Operation delay I< setting Enable for I< Pick-up value Operation delay I2>I1 setting Enable for I2/I1> Pick-up value Operation delay
FUN INF ASDU
Scaling
9
5...8
143
Dir+Backup=0;Undir=1; Dir=2
9
9...12 144 1 ° = 1
9 13...16 201 1.00 s = 100
9 17...20 143 Off=0;On=1
9 21...24 143 Off=0;On=1 9 25...28 201 1.00 s = 100
9 29...32 143 Off=0;On=1
9 33...36 201 1.00 xIn = 100
9 37...40 201 1.00 s = 100
10
0
143 Off=0;On=1
10
1...4 201 1.00 xIn = 100
10
5...8
143
Dir+Backup=0;Undir=1; Dir=2
10 9...12 144 1 ° = 1
10 13...16 201 1.00 s = 100
10 17...20 143 Off=0;On=1
10 21...24 143 Off=0;On=1 10 25...28 201 1.00 s = 100 10 29...32 143 Off=0;On=1 10 33...36 201 1.00 xIn = 100 10 37...40 201 1.00 s = 100
11
0
143 Off=0;On=1
11
1...4 201 1 %Sn = 1
11
5...8 201 1.0 s = 10
12
0
143 Off=0;On=1
12
1...4 201 1 %Sn = 1
12
5...8 201 1.0 s = 10
13
0
143 Off=0;On=1
13
1...4 201 1.00 %In = 100
13
5...8 201 1.0 s = 10
14
0
143 Off=0;On=1
14
1...4 201 1 % = 1
14
5...8 201 1.00 s = 100
P5U20 LPCT/LPVT
P5U20
P5V20
P5F30
P5M30
P5/EN M/33A
73
Communication protocols
Name
I2> setting Enable for I2> Pick-up value
Delay curve family
Delay type
Operation delay Inv. time coefficient Reset type Reset time Ist> setting Enable for Ist> Delay type Motor start time Ilr> setting Enable for Ilr> Pick-up value Delay type Operation delay N> setting Enable for N> Max motor Hot starts Max motor cold starts Min time between motor starts Reference period Hot Status Limit Motor T> setting Enable for Motor T> Basic current setting Max permissive I factor Heating time constant Time constant for motor starting Cooling time constant Unbalance factor Thermal alarm value Reserve time thermal alarm Temperature based mode
FUN
16 16 16
16
16 16 16 16
17 17 17
18 18 18 18
19 19 19 19 19 19
20 20 20 20 20 20 20 20 20 20
INF ASDU
Scaling
0
143 Off=0;On=1
1...4 201 1.00 xIn = 100
DT=0;IEC=1;IEEE=2;
5...8
143 IEEE2=3;Others=4;
Prg1=5;Prg2=6;Prg3=7
9...12
DT=0;NI=1;VI=2;EI=3; LTI=4;LTEI=5;LTVI=6; 143 MI=7;STI=8;STEI=9; CO8=10;RI=11;RXIDG= 12
13...16 201 1.00 s = 100
17...20 201 1.000 = 1000 21...24 143 DT=0;IDMT=1
25...28 201 1.00 s = 100
0
143 Off=0;On=1
1
143 DT=0;INV=1
2
201 1.0 s = 10
0
143 Off=0;On=1
1
201 1.0 % = 10
2
143 DT=0;INV=1
3
201 1.0 s = 10
0
143 Off=0;On=1
1
201 1 = 1
2
201 1 = 1
3
201 1.0 min = 10
4
201 1.0 min = 10
5
201 1.0 % = 10
0
143 Off=0;On=1
1...4 201 1.00 xIn = 100
5...8 201 1.00 = 100
9...12 201 1.0 min = 10
13...16 201 1.0 min = 10 17...20 201 1.0 min = 10 21...24 201 1.0 = 10 25...28 201 1 % = 1 29...32 201 1.0 min = 10
33...36 143 Current=0;Ambient=1
P5U20 LPCT/LPVT
P5U20
P5V20
P5F30 P5M30
74
P5/EN M/33A
Communication protocols
Name
Nominal ambient temp Max object temperature Alarm temperature Min ambient temperature Default ambient temperature Feeder T> setting
Enable for feeder T> Basic current setting Max permissive I factor Heating time constant Thermal alarm value Reserve time thermal alarm Temperature based mode Nominal ambient temp Max object temperature Alarm temperature Min ambient temperature Default ambient temperature Io> setting
Enable for Io> Pick-up value
Delay curve family
Delay type
Operation delay Inv. time coefficient Network earthing Reset time Inrush status for Io> SOL use for Io> SOL Operation delay SOL Inv. time coefficient CLPU status for Io> CLPU Pick-up value
FUN 20 20 20 20 20
21 21 21 21 21 21 21 21 21 21 21 21
22 22 22
22
22 22 22 22 22 22 22 22 22 22
INF ASDU
Scaling
37...40 144 1 °C = 1 / 1 °F = 1
41...44 144 1 °C = 1 / 1 °F = 1 45...48 144 1 °C = 1 / 1 °F = 1 49...52 144 1 °C = 1 / 1 °F = 1
53...56 144 1 °C = 1 / 1 °F = 1
0
143 Off=0;On=1
1...4 201 1.00 xIn = 100
5...8 201 1.00 = 100
9...12 201 1.0 min = 10 13...16 201 1 % = 1 17...20 201 1.0 min = 10
21...24 143 Current=0;Ambient=1
25...28 144 1 °C = 1 / 1 °F = 1
29...32 144 1 °C = 1 / 1 °F = 1 33...36 144 1 °C = 1 / 1 °F = 1 37...40 144 1 °C = 1 / 1 °F = 1
41...44 144 1 °C = 1 / 1 °F = 1
0
143 Off=0;On=1
1...4
201 1.000 pu = 1000
DT=0;IEC=1;IEEE=2;
5...8
143 IEEE2=3;Others=4;
Prg1=5;Prg2=6;Prg3=7
9...12
DT=0;NI=1;VI=2;EI=3; LTI=4;LTEI=5;LTVI=6; 143 MI=7;STI=8;STEI=9; CO8=10;RI=11;RXIDG= 12
13...16 201 1.00 s = 100
17...20 201 1.000 = 1000 21...24 143 Res=0;Cap=1
25...28 201 1.00 s = 100 29...32 143 Off=0;On=1
33...36 143 Off=0;On=1
37...40 201 1.00 s = 100
41...44 201 1.000 = 1000
45...48 143 Off=0;On=1 49...52 201 1.00 xIn = 100
P5U20 LPCT/LPVT
P5U20
P5V20
P5F30
P5M30
P5/EN M/33A
75
Communication protocols
Name
CLPU Operation delay CLPU Inv. time coefficient Reset type Enable faulty phase detection Phase currents change limit Io>> setting Enable for Io>> Pick-up value
Delay curve family
Delay type
Operation delay Inv. time coefficient Network earthing Inrush status for Io>> SOL use for Io>> SOL Operation delay SOL Inv. time coefficient CLPU status for Io>> CLPU Pick-up value CLPU Operation delay CLPU Inv. time coefficient Reset type Reset time Enable faulty phase detection Phase currents change limit Io>>> setting Enable for Io>>> Pick-up value Operation delay Network earthing Inrush status for Io>>> SOL use for Io>>> SOL Operation delay CLPU status for Io>>>
FUN 22 22 22 22 22
23 23 23
23
23 23 23 23 23 23 23 23 23 23 23 23 23 23 23
24 24 24 24 24 24 24 24
INF ASDU
Scaling
53...56 201 1.00 s = 100
57...60 201 1.000 = 1000
61...64 143 DT=0;IDMT=1
65
143 Off=0;On=1
66
143 1 % = 1
0
143 Off=0;On=1
1...4
201 1.00 pu = 100
DT=0;IEC=1;IEEE=2;
5...8
143 IEEE2=3;Others=4;
Prg1=5;Prg2=6;Prg3=7
9...12
DT=0;NI=1;VI=2;EI=3; LTI=4;LTEI=5;LTVI=6; 143 MI=7;STI=8;STEI=9; CO8=10;RI=11;RXIDG= 12
13...16 201 1.00 s = 100
17...20 201 1.000 = 1000 21...24 143 Res=0;Cap=1
25...28 143 Off=0;On=1
29...32 143 Off=0;On=1
33...36 201 1.00 s = 100
37...40 201 1.000 = 1000
41...44 143 Off=0;On=1 45...48 201 1.00 xIn = 100
49...52 201 1.00 s = 100
53...56 201 1.000 = 1000
57...60 143 DT=0;IDMT=1 61...64 201 1.00 s = 100
65
143 Off=0;On=1
66
143 1 % = 1
0 1...4 5...8 9...12
143 Off=0;On=1 201 1.00 pu = 100 201 1.00 s = 100 143 Res=0;Cap=1
13...16 143 Off=0;On=1
17...20 143 Off=0;On=1 21...24 201 1.00 s = 100
25...28 143 Off=0;On=1
P5U20 LPCT/LPVT
P5U20
P5V20
P5F30
P5M30
76
P5/EN M/33A
Communication protocols
Name
CLPU Pick-up value CLPU Operation delay Enable faulty phase detection Phase currents change limit Io>>>> setting Enable for Io>>>> Pick-up value Operation delay Network earthing Inrush status for Io>>>> SOL use for Io>>>> SOL Operation delay CLPU status for Io>>>> CLPU Pick-up value CLPU Operation delay Enable faulty phase detection Phase currents change limit Io>>>>> setting Enable for Io>>>>> Pick-up value Operation delay Io> setting Enable for Io>
Direction mode
Char ctrl. in ResCap mode
Pick-up value Uo setting for Io> stage Angle offset Pick up sector size
Delay curve family
Delay type
FUN INF ASDU
Scaling
24 29...32 201 1.00 xIn = 100
24 33...36 201 1.00 s = 100
24
37
143 Off=0;On=1
24
38
143 1 % = 1
P5U20 LPCT/LPVT
P5U20
P5V20
P5F30
P5M30
25
0
143 Off=0;On=1
25
1...4
201 1.00 pu = 100
25
5...8 201 1.00 s = 100
25
9...12 143 Res=0;Cap=1
25 13...16 143 Off=0;On=1
25 17...20 143 Off=0;On=1 25 21...24 201 1.00 s = 100
25 25...28 143 Off=0;On=1
25 29...32 201 1.00 xIn = 100
25 33...36 201 1.00 s = 100
25
37
143 Off=0;On=1
25
38
143 1 % = 1
26
0
143 Off=0;On=1
26
1...4
201 1.00 pu = 100
26
5...8 201 1.00 s = 100
27
0
143 Off=0;On=1
27
1...4
143
ResCap=0;Sector=1; Undir=2
Res=0;Cap=1;DI1=2;
DI2=3;...;DI19=20;DI20=
21;Arc1=26;Arc2=27;BI=
27
5...8 143 28;VI1=30;VI2=31;VI3=
32;VI4=33;DI21=66;
DI22=67;...;DI31=76;
DI32=77
27
9...12 201 1.000 pu = 1000
27 13...16 201 1.0 % = 10
27 17...20 144 1 ° = 1
27 21...24 144 1 ±° = 1
DT=0;IEC=1;IEEE=2;
27 25...28 143 IEEE2=3;Others=4;
Prg1=5;Prg2=6;Prg3=7
DT=0;NI=1;VI=2;EI=3;
LTI=4;LTEI=5;LTVI=6;
27 29...32 143 MI=7;STI=8;STEI=9;
CO8=10;RI=11;RXIDG=
12
P5/EN M/33A
77
Communication protocols
Name Operation delay Inv. time coefficient Reset type Reset time Io>> setting Enable for Io>> Direction mode
Char ctrl. in ResCap mode
Pick-up value Uo setting for Io>> stage Angle offset Pick up sector size
Delay curve family
Delay type
Operation delay Inv. time coefficient Reset type Reset time Io>>>setting Enable for Io>>> Direction mode
Char ctrl. in ResCap mode
Pick-up value Uo setting for Io>>> stage Angle offset Pick up sector size
Delay curve family
Delay type
FUN 27 27 27 27
28 28
28
28 28 28 28 28
28
28 28 28 28
29 29
29
29 29 29 29 29
29
INF ASDU
Scaling
33...36 201 1.00 s = 100 37...40 201 1.000 = 1000 41...44 143 DT=0;IDMT=1 45...48 201 1.00 s = 100
P5U20 LPCT/LPVT
P5U20
P5V20
P5F30
P5M30
0
143 Off=0;On=1
1...4
143
ResCap=0;Sector=1; Undir=2
Res=0;Cap=1;DI1=2;
DI2=3;...;DI19=20;DI20=
21;Arc1=26;Arc2=27;BI=
5...8 143 28;VI1=30;VI2=31;VI3=
32;VI4=33;DI21=66;
DI22=67;...;DI31=76;
DI32=77
9...12 201 1.000 pu = 1000
13...16 201 1.0 % = 10
17...20 144 1 ° = 1
21...24 144 1 ±° = 1
DT=0;IEC=1;IEEE=2;
25...28 143 IEEE2=3;Others=4;
Prg1=5;Prg2=6;Prg3=7
DT=0;NI=1;VI=2;EI=3;
LTI=4;LTEI=5;LTVI=6;
29...32 143 MI=7;STI=8;STEI=9;
CO8=10;RI=11;RXIDG=
12
33...36 201 1.00 s = 100
37...40 201 1.000 = 1000
41...44 143 DT=0;IDMT=1
45...48 201 1.00 s = 100
0
143 Off=0;On=1
1...4
143
ResCap=0;Sector=1; Undir=2
Res=0;Cap=1;DI1=2;
DI2=3;...;DI19=20;DI20=
21;Arc1=26;Arc2=27;BI=
5...8 143 28;VI1=30;VI2=31;VI3=
32;VI4=33;DI21=66;
DI22=67;...;DI31=76;
DI32=77
9...12 201 1.000 pu = 1000
13...16 201 1.0 % = 10
17...20 144 1 ° = 1
21...24 144 1 ±° = 1
DT=0;IEC=1;IEEE=2;
25...28 143 IEEE2=3;Others=4;
Prg1=5;Prg2=6;Prg3=7
DT=0;NI=1;VI=2;EI=3;
LTI=4;LTEI=5;LTVI=6;
29...32 143 MI=7;STI=8;STEI=9;
CO8=10;RI=11;RXIDG=
12
78
P5/EN M/33A
Communication protocols
Name Operation delay Inv. time coefficient Reset type Reset time IoUo> setting Enable for IoUo> Direction mode
Inhibit ctrl.
Timer instant delay ctrl.
Pick-up value Uo pick-up value Pick-up sector size Operation delay SOL Mode SOL Operation delay Memory Mode Uo pick-up value Memory time Reset time IoUo>> setting Enable for IoUo>> Direction mode
Input for inhibit control
Timer instant delay ctrl.
Pick-up value Uo pick-up value Pick up sector size Operation delay
FUN INF ASDU
Scaling
29 33...36 201 1.00 s = 100 29 37...40 201 1.000 = 1000 29 41...44 143 DT=0;IDMT=1 29 45...48 201 1.00 s = 100
P5U20 LPCT/LPVT
P5U20
P5V20
P5F30
P5M30
30
0
143 Off=0;On=1
30
1...4 143 Forward=0;Reverse=1
DI1=1;DI2=2;...;DI19=19;
DI20=20;Arc1=25;Arc2=
26;BI=27;VI1=29;VI2=
30
5...8
143
30;VI3=31;VI4=32;DI21= 65;DI22=66;...;DI39=83;
DI40=84;VI5=225;VI6=
226;...;VI19=239;VI20=
240
DI1=1;DI2=2;...;DI19=19;
DI20=20;Arc1=25;Arc2=
30
9...12
143
26;BI=27;VI1=29;VI2= 30;VI3=31;VI4=32;DI21=
65;DI22=66;...;DI31=75;
DI32=76
30 13...16 201 1.00 %Pno = 100
30 17...20 201 1.0 % = 10
30 21...24 144 1 ±° = 1
30 25...28 201 1.00 s = 100
30 29...32 143 Off=0;On=1
30 33...36 201 1.00 s = 100
30
37...40
143
None=0;Voltage=1; Time=2;Both=3
30 41...44 201 1.0 % = 10
30 45...48 201 1.00 s = 100
30
49
201 1.00 s = 100
31
0
143 Off=0;On=1
31
1...4 143 Forward=0;Reverse=1
DI1=1;DI2=2;...;DI19=19;
DI20=20;Arc1=25;Arc2=
26;BI=27;VI1=29;VI2=
31
5...8
143
30;VI3=31;VI4=32;DI21= 65;DI22=66;...;DI39=83;
DI40=84;VI5=225;VI6=
226;...;VI19=239;VI20=
240
DI1=1;DI2=2;...;DI19=19;
DI20=20;Arc1=25;Arc2=
26;BI=27;VI1=29;VI2=
31
9...12
143
30;VI3=31;VI4=32;DI21= 65;DI22=66;...;DI39=83;
DI40=84;VI5=225;VI6=
226;...;VI19=239;VI20=
240
31 13...16 201 1.00 %Pno = 100
31 17...20 201 1.0 % = 10
31 21...24 144 1 ±° = 1
31 25...28 201 1.00 s = 100
P5/EN M/33A
79
Name
SOL Mode SOL Operation delay
Memory Mode
Uo memory value Memory time Reset time U> setting Enable for U> Pick-up value Operation delay Reset time Hysteresis U>> setting Enable for U>> Pick-up value Operation delay Hysteresis U>>> setting Enable for U>>> Pick-up value Operation delay Hysteresis U< setting Enable for U< Pick-up value Operation delay Reset time Hysteresis U<< setting Enable for U<< Pick-up value Operation delay Hysteresis U<<< setting Enable for U<<< Pick-up value Operation delay Hysteresis U1< setting Enable for U1< Pick-up value
FUN INF ASDU
Scaling
31 29...32 143 Off=0;On=1
31 33...36 201 1.00 s = 100
31
37...40
143
None=0;Voltage=1; Time=2;Both=3
31 41...44 201 1.0 % = 10
31 45...48 201 1.00 s = 100
31
49
201 1.00 s = 100
32
0
143 Off=0;On=1
32
1...4 201 1.0 %Un = 10
32
5...8 201 1.00 s = 100
32
9
201 1.00 s = 100
32
10
201 1.0 % = 10
33
0
143 Off=0;On=1
33
1...4 201 1.0 %Un = 10
33
5...8 201 1.00 s = 100
33
9
201 1.0 % = 10
34
0
143 Off=0;On=1
34
1...4 201 1.0 %Un = 10
34
5...8 201 1.00 s = 100
34
9
201 1.0 % = 10
35
0
143 Off=0;On=1
35
1...4 201 1.0 %Un = 10
35
5...8 201 1.00 s = 100
35
9
201 1.00 s = 100
35
10
201 1.0 % = 10
36
0
143 Off=0;On=1
36
1...4 201 1.0 %Un = 10
36
5...8 201 1.00 s = 100
36
9
201 1.0 % = 10
37
0
143 Off=0;On=1
37
1...4 201 1.0 %Un = 10
37
5...8 201 1.00 s = 100
37
9
201 1.0 % = 10
38
0
143 Off=0;On=1
38
1...4 201 1 %Vn = 1
Communication protocols
P5U20 LPCT/LPVT
P5U20
P5V20
P5F30
P5M30
80
P5/EN M/33A
Communication protocols
Name
Operation delay Low voltage blocking U1<< setting Enable for U1<< Pick-up value Operation delay Low voltage blocking Uo> setting Enable for Uo> Pick-up value Operation delay Reset time Uo>> setting Enable for Uo>> Pick-up value Operation delay Reset time Uo>>> setting Enable for Uo>>> Pick-up value Operation delay Reset time fX setting Enable for fX Pick-up value Operation delay Low voltage blocking fXX setting Enable for fXX Pick-up value Operation delay Low voltage blocking f< setting Enable for f< Pick-up value Operation delay Low voltage blocking f<< setting Enable for f<< Pick-up value Operation delay Low voltage blocking
FUN 38 38
39 39 39 39
40 40 40 40
41 41 41 41
42 42 42 42
43 43 43 43
44 44 44 44
45 45 45 45
46 46 46 46
INF ASDU
Scaling
5...8 201 1.00 s = 100
9
201 1.0 %Un = 10
0
143 Off=0;On=1
1...4 201 1 %Vn = 1
5...8 201 1.00 s = 100
9
201 1.0 %Un = 10
0 1...4 5...8 9...12
143 Off=0;On=1 201 1 % = 1 201 1.00 s = 100 201 1.00 s = 100
0 1...4 5...8 9...12
143 Off=0;On=1 201 1 % = 1 201 1.00 s = 100 201 1.00 s = 100
0 1...4 5...8 9...12
143 Off=0;On=1 201 1 % = 1 201 1.00 s = 100 201 1.00 s = 100
0
143 Off=0;On=1
1...4 201 50.00 Hz = 5000
5...8 201 1.00 s = 100
9
201 1.0 %Un = 10
0
143 Off=0;On=1
1...4 201 50.00 Hz = 5000
5...8 201 1.00 s = 100
9
201 1.0 %Un = 10
0
143 Off=0;On=1
1...4 201 50.00 Hz = 5000
5...8 201 1.00 s = 100
9
201 1.0 %Un = 10
0
143 Off=0;On=1
1...4 201 50.00 Hz = 5000
5...8 201 1.00 s = 100
9
201 1.0 %Un = 10
P5/EN M/33A
P5U20 LPCT/LPVT
P5U20
P5V20
P5F30
P5M30
81
Communication protocols
Name
CBFail setting Enable for CB fail Enable CBF timer1 Timer1 Operation Delay Enable CBF timer2 Timer2 Operation Delay Noncurrent CBF reset mode
Ext. CBF reset mode
I< current set Io< current set Io'< current set Ih5> setting Enable for Ih5> Pick-up value Operation delay CT setting Enable for CT supervision
CTS Operate mode
CTS reset input Operation delay Residual current > Residual voltage < VT setting Enable for VTS U2> setting I2< setting Operation delay VTS output reset
DI for MCB position
Io'> setting Enable for Io'>
FUN
47 47 47 47 47 47 47 47 47 47
49 49 49
50 50 50 50 50 50
51 51 51 51 51 51
52
INF ASDU
Scaling
P5U20 LPCT/LPVT
P5U20
P5V20
P5F30
P5M30
0
143 Off=0;On=1
1
143 Off=0;On=1
2
201 1.00 s = 100
3
143 Off=0;On=1
4
201 1.00 s = 100
5
143
I<Only=0;PoleDead=1; ProtRst=2
6
143
I<Only=0;PoleDead=1; ProtRst=2
7
201 1.00 xIn = 100
8
201 1.000 pu = 1000
9
201 1.000 pu = 1000
0
143 Off=0;On=1
1
201 1 % = 1
2
201 1.00 s = 100
0
143 Off=0;On=1
1
143
3I only=0;I0&U0=1;Both= 2
2
144 Value 6
3
201 1.00 s = 100
4
201 1.00 xIn = 100
5
201 1.0 %Un = 10
0
143 Off=0;On=1
1
201 1.0 %Vn = 10
2
201 1.00 xIn = 100
3
201 1.00 s = 100
4
144 Value 7
5
144
DI1=1;DI2=2;...;DI39=39; DI40=40
0
143 Off=0;On=1
6. DI1=1;DI2=2;...;DI19=19;DI20=20;Arc1=25;Arc2=26;BI=27;VI1=29;VI2=30;VI3=31;VI4=32;DO1(B)=33;DO2(B)=34;DO3(B)=35; Watchdog=36;SF=37;SF=38;SF=39;SF=40;SF=41;BO=42;DO1(C)=43;DO2(C)=44;DO3(C)=45;DO4(C)=46;LedAl=49;LedTr=50;LedA= 51;LedB=52;LedC=53;LedDR=54;VO1=55;VO2=56;...;VO5=59;VO6=60;DI21=65;DI22=66;...;DI39=83;DI40=84;F1=85;F2=86;...;F6= 90;F7=91;DO1(D)=97;DO2(D)=98;DO3(D)=99;SF=100;DO1(E)=101;DO2(E)=102;NI1=129;NI2=130;...;NI63=191;NI64=192;POC1= 193;POC2=194;...;POC15=207;POC16=208;VI5=225;VI6=226;...;VI19=239;VI20=240;VO7=257;VO8=258;...;VO19=269;VO20=270; NI65=289;NI66=290;...;NI127=351;NI128=352
7. DI1=1;DI2=2;...;DI19=19;DI20=20;Arc1=25;Arc2=26;BI=27;VI1=29;VI2=30;VI3=31;VI4=32;DO1(B)=33;DO2(B)=34;DO3(B)=35; Watchdog=36;SF=37;SF=38;SF=39;SF=40;SF=41;BO=42;DO1(C)=43;DO2(C)=44;DO3(C)=45;DO4(C)=46;LedAl=49;LedTr=50;LedA= 51;LedB=52;LedC=53;LedDR=54;VO1=55;VO2=56;...;VO5=59;VO6=60;DI21=65;DI22=66;...;DI39=83;DI40=84;F1=85;F2=86;...;F7= 91;DO1(D)=97;DO2(D)=98;DO3(D)=99;SF=100;DO1(E)=101;DO2(E)=102;NI1=129;NI2=130;...;NI63=191;NI64=192;POC1=193; POC2=194;...;POC15=207;POC16=208;VI5=225;VI6=226;...;VI19=239;VI20=240;VO7=257;VO8=258;...;VO19=269;VO20=270;NI65= 289;NI66=290;...;NI127=351;NI128=352
82
P5/EN M/33A
Communication protocols
Name Pick-up value
Delay curve family
Delay type
Operation delay Inv. time coefficient Network grounding Reset time Inrush status for Io'> SOL status for Io'> SOL Operation delay SOL Inv. time coefficient CLPU status for Io'> CLPU Pick-up value CLPU Operation delay CLPU Inv. time coefficient Reset type Enable faulty phase detection Phase currents change limit Io'>> setting Enable for Io'>> Pick-up value
Delay curve family
Delay type
Operation delay Inv. time coefficient Network earthing Inrush status for Io'>> SOL status for Io'>> SOL Operation delay SOL Inv. time coefficient CLPU status for Io'>> CLPU Pick-up value CLPU Operation delay
FUN 52 52
52
52 52 52 52 52 52 52 52 52 52 52 52 52 52 52
53 53 53
53
53 53 53 53 53 53 53 53 53 53
INF ASDU
Scaling
1...4
201 1.000 pu = 1000
DT=0;IEC=1;IEEE=2;
5...8
143 IEEE2=3;Others=4;
Prg1=5;Prg2=6;Prg3=7
9...12
DT=0;NI=1;VI=2;EI=3; LTI=4;LTEI=5;LTVI=6; 143 MI=7;STI=8;STEI=9; CO8=10;RI=11;RXIDG= 12
13...16 201 1.00 s = 100
17...20 201 1.000 = 1000 21...24 143 Res=0;Cap=1
25...28 201 1.00 s = 100 29...32 143 Off=0;On=1
33...36 143 Off=0;On=1
37...40 201 1.00 s = 100
41...44 201 1.000 = 1000
45...48 143 Off=0;On=1 49...52 201 1.00 xIn = 100
53...56 201 1.00 s = 100
57...60 201 1.000 = 1000
61...64 143 DT=0;IDMT=1
65
143 Off=0;On=1
66
143 1 % = 1
0
143 Off=0;On=1
1...4
201 1.000 pu = 1000
DT=0;IEC=1;IEEE=2;
5...8
143 IEEE2=3;Others=4;
Prg1=5;Prg2=6;Prg3=7
9...12
DT=0;NI=1;VI=2;EI=3; LTI=4;LTEI=5;LTVI=6; 143 MI=7;STI=8;STEI=9; CO8=10;RI=11;RXIDG= 12
13...16 201 1.00 s = 100
17...20 201 1.000 = 1000 21...24 143 Res=0;Cap=1
25...28 143 Off=0;On=1
29...32 143 Off=0;On=1
33...36 201 1.00 s = 100
37...40 201 1.000 = 1000
41...44 143 Off=0;On=1 45...48 201 1.00 xIn = 100
49...52 201 1.00 s = 100
P5U20 LPCT/LPVT
P5U20
P5V20
P5F30
P5M30
P5/EN M/33A
83
Communication protocols
Name
CLPU Inv. time coefficient Reset type Reset time Enable faulty phase detection Phase currents change limit Io'>>> setting Enable for Io'>>> Pick-up value Operation delay Network grounding Inrush status for Io'>>> SOL status for Io'>>> SOL Operation delay CLPU status for Io'>>> CLPU Pick-up value CLPU Operation delay Enable faulty phase detection Phase currents change limit Uc> setting Enable for Uc> Pick-up value Operation delay df/dt> setting Enable for df/dt>
Direction of change
Pick-up value Operation delay Low voltage blocking df/dt>> setting Enable for df/dt>>
Direction of change
Pick-up value Operation delay Low voltage blocking IoInt> setting Enable for IoInt> Direction mode
FUN 53 53 53 53 53
54 54 54 54 54 54 54 54 54 54 54 54
55 55 55
56 56 56 56 56
57 57 57 57 57
58 58
INF ASDU
Scaling
53...56 201 1.000 = 1000
57...60 143 DT=0;IDMT=1 61...64 201 1.00 s = 100
65
143 Off=0;On=1
66
143 1 % = 1
0 1...4 5...8 9...12
143 Off=0;On=1 201 1.000 pu = 1000 201 1.00 s = 100 143 Res=0;Cap=1
13...16 143 Off=0;On=1
17...20 143 Off=0;On=1 21...24 201 1.00 s = 100
25...28 143 Off=0;On=1
29...32 201 1.00 xIn = 100
33...36 201 1.00 s = 100
37
143 Off=0;On=1
38
143 1 % = 1
0
143 Off=0;On=1
1...4 201 1.00 xUcLN = 100
5...8 201 1.0 s = 10
0 1...4 5...8 9...12 13
143 Off=0;On=1
143
Negative=0;Positive=1; Either=2
201 1.0 Hz/s = 10
201 1.00 s = 100
201 1.0 %Un = 10
0 1...4 5...8 9...12 13
143 Off=0;On=1
143
Negative=0;Positive=1; Either=2
201 1.0 Hz/s = 10
201 1.00 s = 100
201 1.0 %Un = 10
0
143 Off=0;On=1
1...4 143 Forward=0;Reverse=1
P5U20 LPCT/LPVT
P5U20
P5V20
P5F30
P5M30
84
P5/EN M/33A
Communication protocols
Name
FUN INF ASDU
Scaling
Uo pick-up value
58
Operation delay
58
Min number of peaks
58
Reset delay
58
Intermittent time
58
Feeder Fault Locator setting
Pick-up value
59
Triggering digital input
59
Line reactance/unit
59
Earth factor
59
Earth factor angle
59
Event enabling
59
Average voltage limit
59
Io limit
59
DI timeout
59
Release timeout
59
Synchro-check 1 setting
Enable for Synchro check 1
60
CB object 1
60
CB object 2
60
Input for selecting Object2
60
Inhibit closing unselected CB
60
Synchronization mode
60
Voltage check mode
60
CB closing time
60
Bypass DI
60
Bypass
60
Ok pulse length
60
Udead limit setting
60
Ulive limit setting
60
5...8 201 1 % = 1
9...12 201 1.00 s = 100
13...16 143 1 = 1
17...20 201 1.00 s = 100
21
201 1.00 s = 100
0
201 1.00 xIn = 100
1
144 Value 8
2
201 1.000 ohm = 1000
3
201 1.000 = 1000
4
144 1 ° = 1
5
143 Off=0;On=1
6
201 1.0 %Un = 10
7
201 1.00 xIn = 100
8
201 1.00 s = 100
9
201 1.00 s = 100
0
143 Off=0;On=1
Object 1=1;Object 2=2;
1
143 Object 3=3;Object 4=4;
Object 5=5;Object 6=6
Object 1=1;Object 2=2;
2
143 Object 3=3;Object 4=4;
Object 5=5;Object 6=6
3
144 Value 8
4
143 Off=0;On=1
5
143 Off=0;Async=1;Sync=2
DD=1;DL=2;LD=3;DD/
6
143 DL=4;DD/LD=5;DL/LD=
6;DD/DL/LD=7
7
201 1.00 s = 100
8
144 Value 9
9
143 1 = 1
10
144 1 ms = 1
11...14 201 1.0 %Un = 10
15...18 201 1.0 %Un = 10
P5U20 LPCT/LPVT
P5U20
P5V20
P5F30
P5M30
8. DI1=1;DI2=2;...;DI19=19;DI20=20;Arc1=25;Arc2=26;BI=27;VI1=29;VI2=30;VI3=31;VI4=32;DO1(B)=33;DO2(B)=34;DO3(B)=35; Watchdog=36;SF=37;SF=38;SF=39;SF=40;SF=41;BO=42;DO1(C)=43;DO2(C)=44;DO3(C)=45;DO4(C)=46;LedAl=49;LedTr=50;LedA= 51;LedB=52;LedC=53;LedDR=54;VO1=55;VO2=56;...;VO5=59;VO6=60;DI21=65;DI22=66;...;DI39=83;DI40=84;F1=85;F2=86;...;F6= 90;F7=91;DO1(D)=97;DO2(D)=98;DO3(D)=99;SF=100;DO1(E)=101;DO2(E)=102;NI1=129;NI2=130;...;NI63=191;NI64=192;POC1= 193;POC2=194;...;POC15=207;POC16=208;VI5=225;VI6=226;...;VI19=239;VI20=240;VO7=257;VO8=258;...;VO19=269;VO20=270; NI65=289;NI66=290;...;NI127=351;NI128=352
9. DI1=1;DI2=2;...;DI19=19;DI20=20;Arc1=25;Arc2=26;BI=27;VI1=29;VI2=30;VI3=31;VI4=32;DO1(B)=33;DO2(B)=34;DO3(B)=35; Watchdog=36;SF=37;SF=38;SF=39;SF=40;SF=41;BO=42;DO1(C)=43;DO2(C)=44;DO3(C)=45;DO4(C)=46;LedAl=49;LedTr=50;LedA= 51;LedB=52;LedC=53;LedDR=54;VO1=55;VO2=56;VO3=57;VO4=58;VO5=59;VO6=60;DI21=65;DI22=66;...;DI39=83;DI40=84;F1=85; F2=86;...;F6=90;F7=91;DO1(D)=97;DO2(D)=98;DO3(D)=99;SF=100;DO1(E)=101;DO2(E)=102;NI1=129;NI2=130;...;NI63=191;NI64= 192;POC1=193;POC2=194;...;POC15=207;POC16=208;VI5=225;VI6=226;...;VI19=239;VI20=240;VO7=257;VO8=258;...;VO19=269; VO20=270;NI65=289;NI66=290;...;NI127=351;NI128=352
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85
Communication protocols
Name
FUN
Frequency difference 60
Voltage difference
60
Phase angle difference
60
Request timeout
60
CB Monitoring setting
Enable for CB monitoring
61
Alarm level
61
Limit for operation left 61
High limit (primary value)
61
Motor status
Motor status
62
Nom motor start current
62
Motor start detection current
62
Motor start detection mode
62
Enable motor speed detection
62
Motor speed input DI
62
Rated motor speed n
62
Pulse per rotation
62
Zero speed confirm time
62
SOL setting
Enable for SOL
63
SOL signal number
63
CB Trip Clearing time 63
Admittance E/F Io/Uo> setting
Enable for Io/Uo>
64
Io input
64
Uo pick-up value
64
Correction angle
64
Admittance E/F Io/Uo> YN>
Enable for YN>
65
Pick-up value
65
Input for inhibit control
65
Operation delay
65
INF ASDU
Scaling
19...22 201 50.00 Hz = 5000 23...26 201 1.0 %Un = 10
27...30 144 1 ° = 1
31...34 201 1.0 s = 10
P5U20 LPCT/LPVT
P5U20
0
143 Off=0;On=1
1...2 201 1.00 kA = 100 3...4 201 1000 = 1000
5...8 201 1.0 kA = 10
0
143 Off=0;On=1
1
201 1.00 xIn = 100
2
201 1.00 xIn = 100
3
143
CBPos=0;Current=1; CBPos&Cur=2
4
143 Off=0;On=1
5
144
Slot C DI1=0;Slot D DI1= 1;Slot E DI1=2
6
201 1 rpm = 1
7
201 1 = 1
8
201 1 s = 1
0
143 Off=0;On=1
1
143 1=0;2=1
2
201 1.00 s = 100
0
143 Off=0;On=1
1
143
Io=0;Io CSH=1;Iocalc=2; Io'=3
2...5 201 1.0 % = 10
6...9 144 1 ° = 1
0 1...4
5...8
9...12
143 Off=0;On=1
201 1.0 Yn% = 10
DI1=1;DI2=2;...;DI19=19;
DI20=20;Arc1=25;Arc2=
26;BI=27;VI1=29;VI2=
143
30;VI3=31;VI4=32;DI21= 65;DI22=66;...;DI39=83;
DI40=84;VI5=225;VI6=
226;...;VI19=239;VI20=
240
201 1.00 s = 100
P5V20
P5F30 P5M30
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P5/EN M/33A
Communication protocols
Name Reset time SOL Mode
FUN INF ASDU
Scaling
65 13...16 201 1.00 s = 100 65 17...20 143 Off=0;On=1
P5U20 LPCT/LPVT
SOL Operation delay
65 21...24 201 1.00 s = 100
Admittance E/F Io/Uo> GN>
Enable for GN>
66
Pick-up value
66
0
143 Off=0;On=1
1...4 201 1.0 Gn% = 10
Input for inhibit control
Direction mode Operation delay
DI1=1;DI2=2;...;DI19=19;
DI20=20;Arc1=25;Arc2=
26;BI=27;VI1=29;VI2=
66
5...8
143
30;VI3=31;VI4=32;DI21= 65;DI22=66;...;DI39=83;
DI40=84;VI5=225;VI6=
226;...;VI19=239;VI20=
240
66
9...12
143
Undir=0;Forward=1; Reverse=2
66 13...16 201 1.00 s = 100
Reset time SOL Mode
66 17...20 201 1.00 s = 100 66 21...24 143 Off=0;On=1
SOL Operation delay
66 25...28 201 1.00 s = 100
Admittance E/F Io/Uo> BN>
Enable for BN>
67
0
143 Off=0;On=1
Pick-up value
67
1...4 201 1.0 Bn% = 10
Input for inhibit control
Direction mode Operation delay
DI1=1;DI2=2;...;DI19=19;
DI20=20;Arc1=25;Arc2=
26;BI=27;VI1=29;VI2=
67
5...8
143
30;VI3=31;VI4=32;DI21= 65;DI22=66;...;DI39=83;
DI40=84;VI5=225;VI6=
226;...;VI19=239;VI20=
240
67
9...12
143
Undir=0;Forward=1; Reverse=2
67 13...16 201 1.00 s = 100
Reset time SOL Mode
67 17...20 201 1.00 s = 100 67 21...24 143 Off=0;On=1
SOL Operation delay
67 25...28 201 1.00 s = 100
Admittance E/F Io/Uo>> setting
Enable for Io/Uo>>
68
0
143 Off=0;On=1
Io input Uo pick-up value
68
1
143
Io=0;Io CSH=1;Iocalc=2; Io'=3
68
2...5 201 1.0 % = 10
Angle correction
68
6...9 144 1 ° = 1
Admittance E/F Io/Uo> YN>>
Enable for YN>>
69
0
143 Off=0;On=1
Pick-up value
69
1...4 201 1.0 Yn% = 10
Input for inhibit control
DI1=1;DI2=2;...;DI19=19;
DI20=20;Arc1=25;Arc2=
26;BI=27;VI1=29;VI2=
69
5...8
143
30;VI3=31;VI4=32;DI21= 65;DI22=66;...;DI39=83;
DI40=84;VI5=225;VI6=
226;...;VI19=239;VI20=
240
P5U20
P5V20
P5F30
P5M30
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Communication protocols
Name
FUN
Operation delay
69
Reset time
69
SOL Mode
69
SOL Operation delay
69
Admittance E/F Io/Uo>> GN>
Enable for GN>>
70
Pick-up value
70
Input for inhibit control
70
Direction mode
70
Operation delay
70
Reset time
70
SOL Mode
70
SOL Operation delay
70
Admittance E/F Io/Uo>> BN>
Enable for BN>>
71
Pick-up value
71
Input for inhibit control
71
Direction mode
71
Operation delay
71
Reset time
71
SOL Mode
71
SOL Operation delay
71
U2> setting
Enable for U2>
72
VTS Operating Mode 72
Pick-up value
72
Delay type
72
Operation delay
72
Reset time
72
U2>> setting
Enable for U2>>
73
VTS Operating Mode 73
Pick-up value
73
INF ASDU
Scaling
9...12 201 1.00 s = 100 13...16 201 1.00 s = 100 17...20 143 Off=0;On=1 21...24 201 1.00 s = 100
P5U20 LPCT/LPVT
P5U20
0
143 Off=0;On=1
1...4 201 1.0 Gn% = 10
5...8 9...12
DI1=1;DI2=2;...;DI19=19;
DI20=20;Arc1=25;Arc2=
26;BI=27;VI1=29;VI2=
143
30;VI3=31;VI4=32;DI21= 65;DI22=66;...;DI39=83;
DI40=84;VI5=225;VI6=
226;...;VI19=239;VI20=
240
143
Undir=0;Forward=1; Reverse=2
13...16 201 1.00 s = 100
17...20 201 1.00 s = 100 21...24 143 Off=0;On=1
25...28 201 1.00 s = 100
0
143 Off=0;On=1
1...4 201 1.0 Bn% = 10
5...8 9...12
DI1=1;DI2=2;...;DI19=19;
DI20=20;Arc1=25;Arc2=
26;BI=27;VI1=29;VI2=
143
30;VI3=31;VI4=32;DI21= 65;DI22=66;...;DI39=83;
DI40=84;VI5=225;VI6=
226;...;VI19=239;VI20=
240
143
Undir=0;Forward=1; Reverse=2
13...16 201 1.00 s = 100
17...20 201 1.00 s = 100
21...24 143 Off=0;On=1
25...28 201 1.00 s = 100
0
143 Off=0;On=1
1...4
143
NO ACTION=0; BLOCKING=1
5...8 201 1.0 %Un = 10
9...12 143 DT=0;INV=1
13...16 201 1.00 s = 100
17...20 201 1.00 s = 100
0
143 Off=0;On=1
1...4
143
NO ACTION=0; BLOCKING=1
5...8 201 1.0 %Un = 10
P5V20
P5F30 P5M30
88
P5/EN M/33A
Communication protocols
Name
FUN INF ASDU
Scaling
Delay type
73
Operation delay
73
Reset time
73
Motor overspeed >
Enable for >
74
Pick-up value
74
Operation delay
74
Motor overspeed >>
Enable for >
75
Pick-up value
75
Operation delay
75
Motor underspeed
Enable for <<
76
Pick-up value
76
Operation delay
76
Motor underspeed <
Enable for <<
77
Pick-up value
77
Operation delay
77
Motor Anti-backspin ABS
Enable motor antibackspin
78
Measured Zero Speed Mode
78
Zero speed external mode
78
Zero speed input DI
78
Anti-backspin Time
78
Cold load pick-up CLPU
Enable for CLPU
79
Idle current
79
Pickup current
79
CLPU dead time
79
CLPU time delay
79
9...12 143 DT=0;INV=1 13...16 201 1.00 s = 100 17...20 201 1.00 s = 100
0
143 Off=0;On=1
1
201 1 %n = 1
2
201 1 s = 1
0
143 Off=0;On=1
1
201 1 %n = 1
2
201 1 s = 1
0
143 Off=0;On=1
1
201 1 %n = 1
2
201 1 s = 1
0
143 Off=0;On=1
1
201 1 %n = 1
2
201 1 s = 1
0
143 Off=0;On=1
1
143 Off=0;On=1
2
143 Off=0;On=1
3
144 Value 10
4
201 1 s = 1
0
143 Off=0;On=1
1
201 1.00 xIn = 100
2
201 1.00 xIn = 100
3
201 1.00 s = 100
4
201 1.00 s = 100
P5U20 LPCT/LPVT
P5U20
P5V20
P5F30
P5M30
10. DI1=1;DI2=2;...;DI19=19;DI20=20;Arc1=25;Arc2=26;BI=27;VI1=29;VI2=30;VI3=31;VI4=32;DO1(B)=33;DO2(B)=34;DO3(B)=35; Watchdog=36;SF=37;SF=38;SF=39;SF=40;SF=41;BO=42;DO1(C)=43;DO2(C)=44;DO3(C)=45;DO4(C)=46;LedAl=49;LedTr=50;LedA= 51;LedB=52;LedC=53;LedDR=54;VO1=55;VO2=56;VO3=57;VO4=58;VO5=59;VO6=60;DI21=65;DI22=66;...;DI39=83;DI40=84;F1=85; F2=86;...;F6=90;F7=91;DO1(D)=97;DO2(D)=98;DO3(D)=99;SF=100;DO1(E)=101;DO2(E)=102;NI1=129;NI2=130;...;NI63=191;NI64= 192;POC1=193;POC2=194;...;POC16=208;VI5=225;VI6=226;...;VI19=239;VI20=240;VO7=257;VO8=258;...;VO19=269;VO20=270; NI65=289;NI66=290;...;NI127=351;NI128=352
P5/EN M/33A
89
Modbus slave
Communication protocols
Presentation
The Modbus interface is a master/slave protocol defined by the Modbus organization.
For more information on the Modbus protocol, visit www.modbus.org.
It is used to exchange information between a master and one or more slave units, identified by a number. It implements request-reply dialog, where requests are always initiated by the master. Modbus exists in ASCII and binary (RTU mode) formats. Data is exchanged in the form of 16-bit words (also called registers) or simply bits. Each piece of information (bit or register) has a 16-bit address. Modbus is a data-transmission protocol in charge of communication using serial link or Ethernet links.
Modbus TCP/IP offers the same functionality as Modbus over a serial link, as well as compatibility with multi-master architectures.
The Easergy P5 protection relay is considered in Modbus communication as a slave only. The maximum number of Modbus slaves in the device is 2.
Function description
The Modbus slave can communicate with masters using either of two transmission modes:
· Serial RTU mode · TCP/IP mode The Modbus slave can communicate with the master through the serial port and Ethernet port at the same time.
The Modbus slave can be configured to work at max. 3 IP addresses.
The maximal number of clients for Modbus slave is 8. The client and master can be connected by either:
· a serial port connection · a TCP connection via an Ethernet port The Modbus slave supports the following functions and services: · Binary status · Measurement values · Remote control · Time synchronization · Event record · Diagnostics
Modbus protocol data unit
Every Modbus request or response frame includes a Modbus PDU (protocol data unit) made up of 2 fields.
· Function code (1 byte): indicates the type of request (1 to 127) · Data (0 to n bytes): depends on the function code The function codes in the reply and in the request are identical.
Function codes
The function codes listed in the table below are supported.
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Communication protocols
Table 37 - Modbus function codes
Function Codes 03 04 06 07 11 08 11 11 16 23 43/14
Address Space Read Holding Registers Read Input Registers Write single register Read Exception Status Diagnostic Get Comm Event Counter Write multiple registers Read/Write multiple registers Read Device Identification
The following function codes are not supported, as the binary status value are treated as register and there is no area for them.
· 1 - Read coils · 2 - Read discrete inputs · 5 - Write single coil · 15 - Write multiple coils The sub-function of diagnostic supported are listing below: · 0 - Return Query Data (Only the first two bytes' data are returned) · 1 - Restart Communications Option · 2 - Return Diagnostic Register (always zero) · 4 - Force Listen Only Mode
Modbus serial link frames
All the frames exchanged have the same structure, made up of 3 parts: · Slave address (1 byte): from 1 to 247 (0 for broadcasting) · Modbus PDU: as previously described · Check (2 bytes): CRC16 used to check frame integrity
The slave addresses in the reply and in the request are identical. The maximum size of a frame is 256 bytes.
Synchronization of exchanges
Any character that is received after a silence of more than 3.5 characters is considered as the beginning of a new frame. A minimum silence of 3.5 characters is always observed between two frames.
A slave disregards all frames: · Received with a physical error for 1 or more characters (format error, parity error, etc.) · With an incorrect CRC16 result · For which it is not the recipient.
The slave addresses in the reply and in the request are identical.
The maximum size of a frame is 256 bytes.
11. This function code is only available for serial communication.
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Communication protocols
Broadcasting
The master can also address all slaves using the conventional address 0. This type of exchange is called broadcasting. Slaves do not respond to broadcast messages. As a result, only messages that do not require the transmission of data by the slaves can be broadcast.
Response time
The communication coupler response time (Tr) is less than 15 ms, including a 3character silence (approximately 3 ms at 9600 bauds). This time is given with the following parameters:
· 9600 bauds · Format: 8 bits, odd parity, 1 stop bit
Modbus serial RTU mode configuration
The Modbus RTU protocol is activated by selecting the 'ModBusSlv' option for the 'Remote port protocol' of the Easergy P5 protection relay serial port. This setting can be found by navigating to the Protocol configuration view in the COMMUNICATION menu in eSetup Easergy Pro. The following figures show how to enable the Modbus protocol on the Remote port of an Easergy P5 protection relay.
The protocol can also be enabled via the front panel or Web HMI. Once the protocol has been activated, it can be configured. This is done in the Modbus main configuration view of the COMMUNICATION menu. In the Modbus main configuration view, the Modbus Slave Address (or number), the bit rate, the parity of the connection, the wire number and polling line can be set. The frame gap is fixed.
Figure 3 - Modbus slave main configuration
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Communication protocols
Table 38 - Modbus slave main configuration parameters
Parameter Slave number Speed of transmission
Parity Number of wires Poll line activation Frame Gap
Value
1...247 1200, 2400, 4800, 9600, 19200, 38400, 57600, 115200 bps
None, Even, Odd
2, 4
False, True
Description
The Modbus slave address.
The communication speed, bits per second.
The type of parity bit used.
The number of wire connection.
The polarity of the wire connection.
Specifies the amount of time (calculated by bits) to use to determine that a frame has been completed. For Modbus RTU this value is fixed at 38 bits.
NOTE: The parity and bit rate are set to the same value on all devices connected to the same data link.
Modbus TCP mode configuration
Modbus TCP (or Modbus TCP/IP) is simply the Modbus RTU protocol with a TCP interface that runs on Ethernet. TCP/IP refers to the Transmission Control Protocol and Internet Protocol which provide the transmission medium for Modbus TCP/IP messaging. In practice, Modbus TCP embeds a standard Modbus data frame into a TCP frame.
One advantage over serial Modbus (RTU or ASCII) is that the number of nodes is not limited to 247 on one data link, since the addressing of nodes is done with the Internet Protocol. Furthermore, several devices can be connected to one IP address, provided the appropriate equipment is used (some Modbus TCP-toModbus RTU bridge). These devices are differentiated from each other with a Unit Identifier, in the TCP frame, which corresponds to the Slave ID. The range of the Unit Identifier is also 1-247. In Easergy P5 protection relays the Modbus Slave ID corresponds to the Unit Identifier when Modbus TCP is used, see Modbus slave main configuration, page 92.
The Modbus TCP protocol is activated by first configuring the Ethernet port settings. First, the IP address, Subnet mask and Gateway are set, and require a static IP address to be configured. This is considered before connecting a relay to an existing network, so that no conflicts emerge.
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Communication protocols
Once these settings have been configured, one of the Ethernet port protocol selections can be set to "ModBusTCPs" (Modbus TCP, slave). Before the protocol is activated, a device reboot is required.
NOTE: There are two TCP port instances "Ethernet Protocol 1" and "Ethernet Protocol 2", that is, two independent sockets for two different protocols. The default TCP IP port for Modbus TCP is 502.
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Events
Data access, such as reading and writing to holding registers, event reading, clock synchronisation and scaling work, with the addition that clock synchronisation also can be done by using Simple Network Time Protocol (SNTP). This requires a NTP server, the address of which is set in the Protocol configuration view in eSetup Easergy Pro or Web HMI.
The event buffer of Easergy P5 protection relays can be read via the Modbus Protocol. This is done by reading one event at a time, from holding registers 2101...2105. The event registers contain the latest event, and are cleared when they are read. The registers are then updated to contain the following event from the event buffer. A description of the registers is shown in the table.
Table 39 - Description of events in holding registers
Holding Register 2101 2102
2103
2104
2105
Content
Event code
Event timestamp Bits 15-6 = milliseconds Bits 5-0 = seconds
Event timestamp Upper byte = minute Lower byte = hour
Event timestamp Upper byte = day Lower byte = month
Event timestamp, year
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Communication protocols
Clock synchronisation
The internal clock of Easergy P5 protection relays can be synchronised via the Modbus protocol. Note this is not a native feature of the Modbus protocol. Therefore, this is an Easergy P5 protection relay specific feature. The accuracy of the clock synchronisation is in the scale of a few hundred milliseconds.
The clock can be synchronised either completely (all fields: seconds, minutes, hours, days, month and year) or by synchronising only the minutes, which in turn will set the seconds and milliseconds to zero.
An example of how minute synchronisation can be done: when the reference clock (the clock which is assumed to be correct) is exactly seven minutes past (any hour), a minute synchronisation is performed. The result will be that the internal clock of the Easergy P5 protection relays will be set to HH:07:00.000 ("Hours: Minutes:Seconds.Milliseconds") "HH" will not be changed.
These two ways of synchronising the clock are denoted "Set RTC", where "RTC" stands for "Real-Time Clock" and "Synchronise Minutes" in the data map. The holding register address of the minute synchronisation is 2502.
The holding registers allocated to the Set RTC synchronisation are:
Table 40 - Description of holding registers allocated to Set RTC synchronisation
Holding Register 2504 2505
2506
2507
Content
Lower byte: seconds, milliseconds will be zero
Upper byte: minutes Lower byte: hours
Upper byte: day Lower byte: month
Year
Scaling
Since the Modbus registers are 16 bits in size, they can directly represent 2^16 = 65535 different values, which might not be enough to describe the values of some physical quantity such as voltage or power. Thus, values transmitted over a Modbus data link are scaled to account for this.
The scaling is determined by the float value of the corresponding specific scalings. After multiplication by a scaling value, only the decimals are removed from the original measurements, and such values are easy to read and rescale to actual values on the client side after transmission.
These settings for scaling can be set by navigating to the Modbus and IEC 608705-101 specific scalings view in the COMMUNICATION menu in eSetup Easergy Pro or Web HMI.
A short example: The frequency is internally (in the Easergy P5 protection relays) stored as an integer value which also holds three decimal places, that is, 50.000 Hz is represented as 50000. This is a value too large to be represented with 16 bits (signed integer). However, frequency is multipled by default scaled value 0.1, enabling it to be sent over Modbus.
Thus, the value on the receiving side (the Modbus value) will be:
valueModbus = k valueInternal = 0.1 50000 = 5000
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Scaling can be checked in eSetup Easergy Pro by viewing the Scaling column for each register in the Modbus slave COMMUNICATION menu.
NOTE: It is highly recommended to scale values so that they are kept in the interval 0 32000 to avoid overflow. The Modbus scaling address can be found in the Modbus specific scalings view in the COMMUNICATION menu in eSetup Easergy Pro or Web HMI.
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Communication protocols
The following table shows the different values of Voltage scaling, and the values to be filled in the frame. When the client reads a 2 register value for voltage scaling, it needs to combine these 2 values together and convert them to a float 32 value.
For example, when voltage scaling value is 0.001, the values 0x126f and 0x3A83 will be merged to 4 bytes value 0x3A83126F.
Table 41 - Voltage scaling values
Voltage scaling
1.0000 0.0010 1000.0000 500.0000
IEEE 754 / Float32
0x3F800000 0x3A83126F 0x447A0000 0x43FA0000
Value in address 10007 0x0000 0x126F 0x0000 0x0000
Value in address 10008 0x3F80 0x3A83 0x447A 0x43FA
Read exception status
This function code 7 is used to read the contents of eight exception status. Eight bits make up one byte.
The following table shows the status supported:
Table 42 - Read exception status
Bit
Status
Description
0
Test Mode
If test mode is not in normal, set bit 0.
1
Time Synchronization If the synchronizing source is internal, set bit 1.
2
New Event
If a new event is generated, set bit 2.
3
Hardware Status
If the hardware has problem, set bit 3.
4...7
Reserved
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Read device identification
Both basic and regular device identification are supported though function code 43 and 14. The Modbus slave will respond with the exception code 3 if receive the unsupported category.
Table 43 - Read device identification
Object ID 0x00 0x01
Object Name VendorName ProductCode
0x02 0x03 0x04
0x05 0x06
MajorMinorRevision VendorUrl ProductName (product range) ModelName
UserApplicationName
Value Schneider Electric If P5U20: 16700 If P5V20: 16701 If P5M30: 16702 If P5F30: 16703 If P5U20 LPCT/LPVT: 16707 11 chars, e.g. 001.300.003 http://www.se.com Easergy P5
P5U20 / P5V20 / P5F30 / P5M30 / P5U20 LPCT/LPVT depending on type If P5U20: Universal current protection If P5V20: Voltage and Frequency protection If P5F30: Directional Feeder and Transformer protection If P5M30: Motor protection If P5U20 LPCT/LPVT: Universal current protection with LPCT/LPVT
Data model of Modbus Scalings
Add. 1001 1002 1003 1004
1005
1006 1007 1008 1009
Name
Read Write
CT primary CT secondary
1
0
1
0
Nominal current (In)
1
0
LPCT rated primary current (Ipr)
1
0
Current factor
1
0
Earth CT primary
1
0
Earth CT secondary 1
0
Io primary CSH rate 1
0
Io secondary
1
0
FC
Scalling
Setting for Scalling
3 1A=1 3 1A=1 3 1.00 A = 100
LPCT/VT scaling
3 1A=1
0.25=0;0.5=1;1=
2;1.25=3;1.33=
4;2=5;2.5=6;3.2=
3
7;4=8;5=9;6.3= 10;6.66=11;10=
12;16=13;20=
14;25=15;31.5=
16
3 1A=1
3 1.0 A = 10
3 1A=1
3 1.0 A = 10
P5 U20 P5 P5 P5 P5 LPCT U20 V20 F30 M30 LPVT
P5/EN M/33A
99
Communication protocols
Add.
1010 1011 1012 1013 1014 1015 1016 1017 1018
1019 1020 1021 1022 1023 1024
1025 1026 1027 1028 1029 1030 1031 1032 1033 1034 1035 1036
Name
Read Write
Earth fault input (CSH)
1
0
Earth CT' primary
1
0
Earth CT' secondary
1
0
VT primary / Rated voltage
1
0
Nominal voltage (Un)
1
0
LPVT or VT rated primary voltage
1
0
VT secondary
1
0
VTy secondary
1
0
VTo primary
1
0
VTo secondary
1
0
Voltage factor
1
0
Phase Rotation
1
0
Voltage measurement mode
1
0
Nominal frequency
1
0
Power direction
1
0
Number of
connected phase
1
0
CT
VL1 magnitude correction
1
0
VL2 magnitude correction
1
0
VL3 magnitude correction
1
0
VL1 Angle correction
1
0
VL2 Angle correction
1
0
VL3 Angle correction
1
0
VL1y magnitude correction
1
0
VL1y Angle correction
1
0
VL2y magnitude correction
1
0
VL2y Angle correction
1
0
VT type
1
0
FC
Scalling
Setting for Scalling
3 1.0 A = 10
3 1A=1
3 1.0 A = 10
3 1000 V = 1000
VT primary scaling
3 1.00 V = 100
LPVT/VT scaling
3 1000 V = 1000
LPVT/VT scaling
3 1V=1
3 1V=1 3 1000 V = 1000
VTo primary scaling
3 1.000 V = 100
VTo secondary scaling
3 1.000 = 1000 3 1-2-3=0;1-3-2=1
3 Value 12
3 50 Hz = 50
3
Outgoing=0; Incoming=1
3 I1/I2/I3=0;I1/I3=1
3 1.000 = 10000
3 1.000 = 10000
3 1.000 = 10000
3 1.000 ° = 10000
3 1.000 ° = 10000
3 1.000 ° = 10000
3 1.000 = 10000
3 1.000 ° = 10000
3 1.000 = 10000
3 1.000 ° = 10000
3
VT+Adapter=0; LPVT=1
LPCT/VT scaling LPCT/VT scaling LPCT/VT scaling
LPCT/VT scaling
LPCT/VT scaling
P5 U20 P5 P5 P5 P5 LPCT U20 V20 F30 M30 LPVT
12. 2LL+Uo=0;3LN=1;1LL+Uo/LLy=2;2LL/LLy=3;LL/LLy/LLz=4;1LL=5;1LN=6;3LL=8;3LN/LNy=9;3LN/LLy=10;2LL+Uo/LNy=11;2LL+Uo +LLy=12;3LN+Uo=13;LL+Uo/y/z=14;LN+Uo/y/z=15;LL/LLy=16;3LN/2LNy=17
100
P5/EN M/33A
Communication protocols
Add.
Name
Read Write FC
Scalling
1037 VT secondary
1
0
3 1V=1
1038
VL1 adapter mag correction
1
0
3 1.000 = 1000
1039
VL2 adapter mag correction
1
0
3 1.000 = 1000
1040
VL3 adapter mag correction
1
0
3 1.000 = 1000
1041 VTy secondary
1
0
3 1V=1
1042
VL1y adapter mag correction
1
0
3 1.000 = 1000
1044 VTo secondary
1
0
3 1V=1
1045
Uo adapter mag correction
1
0
3 1.000 = 1000
Setting for Scalling
LPCT/VT scaling LPCT/VT scaling LPCT/VT scaling
LPCT/VT scaling
LPCT/VT scaling
P5 U20 P5 P5 P5 P5 LPCT U20 V20 F30 M30 LPVT
Read and command
Add.
Name
Read Write FC
Scalling
2001 Alive indicator
1
2006
Digital Inputs 01...16
1
2007
Digital Inputs 17...32
1
2008
Digital Inputs 33...40
1
2042 Object1 state
1
2043 Object2 state
1
2044 Object3 state
1
2045 Object4 state
1
2046 Object5 state
1
2047 Object6 state
1
2048 Object7 state
1
2049 Object8 state
1
2057 Run hours/10^0
1
2058 Run hours/10^4
1
2059
Engine running (in seconds)
1
2060 Start counter
1
2101... 2105
Events
1
2301 Mode of use
1
2302 Remote/Local State 1
0
3 1=1
0
3 1=1
0
3 1=1
0
3 1=1
0
3
Open=0;Close=1; Undef=2
0
3
Open=0;Close=1; Undef=2
0
3
Open=0;Close=1; Undef=2
0
3
Open=0;Close=1; Undef=2
0
3
Open=0;Close=1; Undef=2
0
3
Open=0;Close=1; Undef=2
0
3
Open=0;Close=1; Undef=2
0
3
Open=0;Close=1; Undef=2
0
3 1=1
0
3 1=1
1
3, 6 1 s = 1
1
3, 6 1 = 1
0
3 1=1
0
3
Normal=0;Test=1; Test Block=2
0
3
REMOTE=0; LOCAL=1
Setting for Scalling
P5 U20 P5 P5 P5 P5 LPCT U20 V20 F30 M30 LPVT
P5/EN M/33A
101
Communication protocols
Add.
Name
Read Write FC
Scalling
2303
Port 1 status (Slot M)
1
0
3
Link off=0; Link on=1
2304
Port 2 status (Slot M)
1
0
3
Link off=0; Link on=1
2305
Port 1 status (Slot L)
1
0
3
Link off=0; Link on=1
2306
Port 2 status (Slot L)
1
0
3
Link off=0; Link on=1
2307
Port 1 status (Slot M&N)
1
0
3
Link off=0; Link on=1
2308
Port 2 status (Slot M&N)
1
0
3
Link off=0; Link on=1
2351 External AI1
1
0
3 Value 13
2352 External AI2
1
0
3 Value 13
2353 External AI3
1
0
3 Value 13
2354 External AI4
1
0
3 Value 13
2355 External AI5
1
0
3 Value 13
2356 External AI6
1
0
3 Value 13
2357 External AI7
1
0
3 Value 13
2358 External AI8
1
0
3 Value 13
2359 External AI9
1
0
3 Value 13
2360 External AI10
1
0
3 Value 13
2361 External AI11
1
0
3 Value 13
2362 External AI12
1
0
3 Value 13
2363 External AI13
1
0
3 Value 13
2364 External AI14
1
0
3 Value 13
2365 External AI15
1
0
3 Value 13
2366 External AI16
1
0
3 Value 13
2367 External AI17
1
0
3 Value 13
2368 External AI18
1
0
3 Value 13
2369 External AI19
1
0
3 Value 13
2370 External AI20
1
0
3 Value 13
Setting for Scalling
P5 U20 P5 P5 P5 P5 LPCT U20 V20 F30 M30 LPVT
External AI scaling
External AI scaling
External AI scaling
External AI scaling
External AI scaling
External AI scaling
External AI scaling
External AI scaling
External AI scaling
External AI scaling
External AI scaling
External AI scaling
External AI scaling
External AI scaling
External AI scaling
External AI scaling
External AI scaling
External AI scaling
External AI scaling
External AI scaling
13. 1 °C = 1 / 1 F = 1 / 1 K = 1 / 1 V/A = 1 / 1 mA = 1 / 1 Ohm = 1 / 1 A = 1 / 1 V = 1 / 1 kW = 1 / 1 kVA = 1 / 1 kvar = 1 / 1 - = 1
102
P5/EN M/33A
Communication protocols
Add.
Name
2371 External AI21 2372 External AI22 2373 External AI23 2374 External AI24 2375 External AI25 2376 External AI26 2377 External AI27 2378 External AI28 2379 External AI29 2380 External AI30 2381 External AI31 2382 External AI32 2383 External AI33 2384 External AI34 2385 External AI35 2386 External AI36 2387 External AI37 2388 External AI38 2389 External AI39 2390 External AI40 2391 External AI41 2392 External AI42 2393 External AI43 2394 External AI44 2395 External AI45 2396 External AI46
Read Write FC
Scalling
1
0
3 Value 14
1
0
3 Value 14
1
0
3 Value 14
1
0
3 Value 14
1
0
3 Value 14
1
0
3 Value 14
1
0
3 Value 14
1
0
3 Value 14
1
0
3 Value 14
1
0
3 Value 14
1
0
3 Value 14
1
0
3 Value 14
1
0
3 Value 14
1
0
3 Value 14
1
0
3 Value 14
1
0
3 Value 14
1
0
3 Value 14
1
0
3 Value 14
1
0
3 Value 14
1
0
3 Value 14
1
0
3 Value 14
1
0
3 Value 14
1
0
3 Value 14
1
0
3 Value 14
1
0
3 Value 14
1
0
3 Value 14
Setting for Scalling
External AI scaling
External AI scaling
External AI scaling
External AI scaling
External AI scaling
External AI scaling
External AI scaling
External AI scaling
External AI scaling
External AI scaling
External AI scaling
External AI scaling
External AI scaling
External AI scaling
External AI scaling
External AI scaling
External AI scaling
External AI scaling
External AI scaling
External AI scaling
External AI scaling
External AI scaling
External AI scaling
External AI scaling
External AI scaling
External AI scaling
P5 U20 P5 P5 P5 P5 LPCT U20 V20 F30 M30 LPVT
14. 1 °C = 1 / 1 F = 1 / 1 K = 1 / 1 V/A = 1 / 1 mA = 1 / 1 Ohm = 1 / 1 A = 1 / 1 V = 1 / 1 kW = 1 / 1 kVA = 1 / 1 kvar = 1 / 1 - = 1
P5/EN M/33A
103
Add.
Name
2397 External AI47
2398 External AI48
2399 External AI49
2400 External AI50
2401 External AI51
2402 External AI52
2403 External AI53
2404 External AI54
2405 External AI55
2406 External AI56
2407 External AI57
2408 External AI58
2409 External AI59
2410 External AI60
2411 External AI61
2412 External AI62
2413 External AI63
2414 External AI64
2415 2416 2417 2418 2419 2420 2421 2422 2423 2424 2425 2426 2427
External DI1 External DI2 External DI3 External DI4 External DI5 External DI6 External DI7 External DI8 External DI9 External DI10 External DI11 External DI12 External DI13
Read Write FC
Scalling
1
0
3 Value 15
1
0
3 Value 15
1
0
3 Value 15
1
0
3 Value 15
1
0
3 Value 15
1
0
3 Value 15
1
0
3 Value 15
1
0
3 Value 15
1
0
3 Value 15
1
0
3 Value 15
1
0
3 Value 15
1
0
3 Value 15
1
0
3 Value 15
1
0
3 Value 15
1
0
3 Value 15
1
0
3 Value 15
1
0
3 Value 15
1
0
3 Value 15
1
0
3 1=1
1
0
3 1=1
1
0
3 1=1
1
0
3 1=1
1
0
3 1=1
1
0
3 1=1
1
0
3 1=1
1
0
3 1=1
1
0
3 1=1
1
0
3 1=1
1
0
3 1=1
1
0
3 1=1
1
0
3 1=1
Communication protocols
Setting for Scalling
External AI scaling
External AI scaling
External AI scaling
External AI scaling
External AI scaling
External AI scaling
External AI scaling
External AI scaling
External AI scaling
External AI scaling
External AI scaling
External AI scaling
External AI scaling
External AI scaling
External AI scaling
External AI scaling
External AI scaling
External AI scaling
P5 U20 P5 P5 P5 P5 LPCT U20 V20 F30 M30 LPVT
15. 1 °C = 1 / 1 F = 1 / 1 K = 1 / 1 V/A = 1 / 1 mA = 1 / 1 Ohm = 1 / 1 A = 1 / 1 V = 1 / 1 kW = 1 / 1 kVA = 1 / 1 kvar = 1 / 1 - = 1
104
P5/EN M/33A
Communication protocols
Add.
Name
Read Write FC
Scalling
2428 External DI14
1
2429 External DI15
1
2430 External DI16
1
2431 External DI17
1
2432 External DI18
1
2501 Release latches
1
2502
Synchronize minutes
1
2504...- Set Real Time 2507 Clock (RTC)
0
2508
Open select object 1
1
2509
Close select object 1
1
2510
Execute operation Object1
0
2511
Max ctrl pulse length of Object1
1
2512
Open select object 2
1
2513
Close select object 2
1
2514
Execute operation Object2
0
2515
Max ctrl pulse length of Object2
1
2516
Cancel selected operation
0
2517
Open select object 3
1
2518
Close select object 3
1
2519
Execute operation Object3
0
2520
Max ctrl pulse length of Object3
1
2521
Open select object 4
1
2522
Close select object 4
1
2523
Execute operation Object4
0
2524
Max ctrl pulse length of Object4
1
2525
Open select object 5
1
2526
Close select object 5
1
2527
Execute operation Object5
0
0
3 1=1
0
3 1=1
0
3 1=1
0
3 1=1
0
3 1=1
1
3, 6 Release=1
1
3, 6 1 = 1
1
6 1=1
1
3, 6 1 = 1
1
3, 6 1 = 1
1
6 1=1
1
3, 6 1.00 s = 100
1
3, 6 1 = 1
1
3, 6 1 = 1
1
6 1=1
1
3, 6 1.00 s = 100
1
6 1=1
1
3, 6 1 = 1
1
3, 6 1 = 1
1
6 1=1
1
3, 6 1.00 s = 100
1
3, 6 1 = 1
1
3, 6 1 = 1
1
6 1=1
1
3, 6 1.00 s = 100
1
3, 6 1 = 1
1
3, 6 1 = 1
1
6 1=1
Setting for Scalling
P5 U20 P5 P5 P5 P5 LPCT U20 V20 F30 M30 LPVT
Max control pulse length scaling
Max control pulse length scaling
Max control pulse length scaling
Max control pulse length scaling
P5/EN M/33A
105
Communication protocols
Add.
2528 2529 2530 2531 2532 2534 2536
Name
Read Write FC
Scalling
Setting for Scalling
Max ctrl pulse length of Object5
1
Open select object 6
1
Close select object 6
1
Execute operation Object6
0
Max ctrl pulse length of Object6
1
Set. group common change
1
Clear min/max/ demand
1
1
3, 6 1.00 s = 100
1
3, 6 1 = 1
Max control pulse length scaling
1
3, 6 1 = 1
1
6 1=1
1
3, 6 1.00 s = 100
Max control pulse length scaling
1
3, 6 1=0;2=1;3=2;4=3
1
3, 6 Clear=1
P5 U20 P5 P5 P5 P5 LPCT U20 V20 F30 M30 LPVT
Measurement
Add.
Name
Read Write FC
Scalling
3001
Positive sequence I1
1
3002
Negative sequence I2
1
3003 Current ratio I2/I1
1
3004
Current phase sequence
1
3005 Phase current THD
1
3006
Phase current IL1 THD
1
3007
Phase current IL2 THD
1
3008
Phase current IL3 THD
1
3009 Phase current IL
1
3010 Min. of IL1 IL2 IL3
1
3011 Max. of IL1 IL2 IL3
1
3012
Phase current ILRMS
1
3015
Phase current IL1RMS
1
3016
Phase current IL2RMS
1
3017
Phase current IL3RMS
1
3019
Ambient temperature
1
3020
Phase current IL1da demand
1
3021
Phase current IL2da demand
1
3022
Phase current IL3da demand
1
0
3 1A=1
0
3 1A=1
0
3 1.0 % = 10
0
3
??=0;OK=1; Reverse=2
0
3 1.0 % = 10
0
3 1.0 % = 10
0
3 1.0 % = 10
0
3 1.0 % = 10
0
3 1A=1
0
3 1A=1
0
3 1A=1
0
3 1A=1
0
3 1A=1
0
3 1A=1
0
3 1A=1
0
3, 6 1 °C = 1 / 1 °F = 1
0
3 1A=1
0
3 1A=1
0
3 1A=1
Setting for Scalling
P5 U20 P5 P5 P5 P5 LPCT U20 V20 F30 M30 LPVT
106
P5/EN M/33A
Communication protocols
Add.
3031 3032 3033 3034 3035 3036 3037 3038 3039 3040 3041 3042 3043 3044 3045
3048
3049
3050
3058 3059 3060 3061 3062 3063 3066 3067 3068
Name
Read Write
Positive sequence U1
1
0
Negative sequence U2
1
0
Voltage U2/U1
1
0
Voltage phase sequence
1
0
Voltage THD
1
0
Phase-Earth VL1 THD
1
0
Phase-Earth VL2 THD
1
0
Phase-Earth VL3 THD
1
0
Average PhasePhase voltage
1
0
Min of Phase-Phase voltages
1
0
Max of PhasePhase voltages
1
0
Average PhaseEarth voltage
1
0
Min. of Phase-Earth voltages
1
0
Max. of PhaseEarth voltages
1
0
RMS average voltage
1
0
Phase-Phase
voltage U12RMS / Phase-Earth
1
0
voltage VL1RMS
Phase-Phase
voltage U23RMS / Phase-Earth
1
0
voltage VL2RMS
Phase-Earth
voltage VL3RMS / Phase-Phase
1
0
voltage U12yRMS
Cos
1
0
Tangent
1
0
Power angle
1
0
RMS active power
1
0
RMS reactive power 1
0
RMS apparent power
1
0
Active power demand
Reactive power demand
1
0
1
0
Apparent power demand
1
0
FC
Scalling
3 1000 V = 1000
3 1000 V = 1000
3 1.0 % = 10
3
??=0;OK=1; Reverse=2
3 1.0 % = 10
3 1.0 % = 10
3 1.0 % = 10
3 1.0 % = 10
3 1000 V = 1000
3 1000 V = 1000
3 1000 V = 1000
3 1000 V = 1000
3 1000 V = 1000
3 1000 V = 1000
3 1000 V = 1000
3 1000 V = 1000
Setting for Scalling
Voltage scaling
Voltage scaling
P5 U20 P5 P5 P5 P5 LPCT U20 V20 F30 M30 LPVT
Voltage scaling
Voltage scaling
Voltage scaling
Voltage scaling
Voltage scaling
Voltage scaling
Voltage scaling
Voltage scaling
3 1000 V = 1000
Voltage scaling
3 1000 V = 1000
Voltage scaling
3 1.00 = 100
PF and cos scaling
3 1.000 = 1000
Tan scaling
3 1°=1
3 1000 kW = 1000 Power scaling
3 1000 kVAr = 1000 Power scaling
3 1000 kVA = 1000 Power scaling
3 1000 kW = 1000 Power scaling
3 1000 kVAr = 1000 Power scaling
3 1000 kVA = 1000 Power scaling
P5/EN M/33A
107
Communication protocols
Add.
3069 3071 3072 3073 3081 3082 3083 3084 3085 3086 3087 3088 3089 3090 3091 3092 3101 3102 3103 3111 3112 3113 3207 3208 3209 3210 3211 3212 3213
Name
Read Write
Power factor demand
1
0
RMS active power demand
1
0
RMS reactive power demand
1
0
RMS apparent power demand
1
0
Phase L1 active power
1
0
Phase L2 active power
1
0
Phase L3 active power
1
0
Phase L1 reactive power
1
0
Phase L2 reactive power
1
0
Phase L3 reactive power
1
0
Phase L1 apparent power
1
0
Phase L2 apparent power
1
0
Phase L3 apparent power
1
0
Cos of phase L1
1
0
Cos of phase L2
1
0
Cos of phase L3
1
0
Frequency fy
1
0
Phase-to-Phase voltage U12y
Phase angle difference
1
0
1
0
Frequency fz
1
0
Phase-to-Phase voltage U12z
1
0
Phase angle difference
1
0
Earth fault calculated
1
0
Io CSH residual current
1
0
Phase current IL1
1
0
Phase current IL2
1
0
Phase current IL3
1
0
Io residual current
1
0
Io' residual current
1
0
FC
Scalling
3 1.00 = 100 3 1000 kW = 1000
Setting for Scalling
PF and cos scaling
P5 U20 P5 P5 P5 P5 LPCT U20 V20 F30 M30 LPVT
Power scaling
3 1000 kVAr = 1000 Power scaling
3 1000 kVA = 1000 Power scaling
3 1000 kW = 1000 Power scaling
3 1000 kW = 1000 Power scaling
3 1000 kW = 1000 Power scaling
3 1000 kVAr = 1000 Power scaling
3 1000 kVAr = 1000 Power scaling
3 1000 kVAr = 1000 Power scaling
3 1000 kVA = 1000 Power scaling
3 1000 kVA = 1000 Power scaling
3 1000 kVA = 1000 Power scaling
3 1.00 = 100
PF and cos scaling
3 1.00 = 100
PF and cos scaling
3 1.00 = 100
PF and cos scaling
3
50.000 Hz = 5000
Frequency scaling
3 1000 V = 1000
Voltage scaling
3 1 ° = 10
-
3
50.000 Hz = 5000
Frequency scaling
3 1000 V = 1000
Voltage scaling
3 1°=1
-
3 1.00 A = 100
Io scaling
3 1.00 A = 100
Io scaling (CSH)
3 1A=1
3 1A=1
3 1A=1
3 1.00 A = 100
Io scaling
3 1.000 A = 1000
Io' scaling
108
P5/EN M/33A
Communication protocols
Add.
Name
Read Write
3214 3215 3216 3217 3218 3219 3220
Phase-to-Phase voltage U12
Phase-to-Phase voltage U23
Phase-to-Phase voltage U31
Phase-to-earth voltage VL1
Phase-to-earth voltage VL2
Phase-to-earth voltage VL3
Residual voltage
1
0
1
0
1
0
1
0
1
0
1
0
1
0
3221 Frequency
1
0
3222 3223 3224
Active power Reactive power Apparent power
1
0
1
0
1
0
3225 Power factor
1
0
3226 Energy Eexp
1
0
3227 Eexp/10^4
1
0
3228 Eexp/10^8
1
0
3229 Energy EqExp
1
0
3230 EqExp/10^4
1
0
3231 EqExp/10^8
1
0
3232 Energy Eimp
1
0
3233 Eimp/10^4
1
0
3234 Eimp/10^8
1
0
3235 Energy EqImp
1
0
3236 EqImp/10^4
1
0
3237 EqImp/10^8
1
0
3238 Tangent
1
0
3239 Phase current IL
1
0
3240
Average PhasePhase voltage
1
0
Average Phase3241 Earth voltage
1
0
3256... 3271
Harmonics of IL1
1
0
3276... 3291
Harmonics of IL2
1
0
3296... 3311
Harmonics of IL3
1
0
3316... Harmonics of U12 / 3331 Harmonics of VL1
1
0
3336... Harmonics of U23 / 3351 Harmonics of VL2
1
0
FC
Scalling
3 1000 V = 1000
Setting for Scalling
Voltage scaling
P5 U20 P5 P5 P5 P5 LPCT U20 V20 F30 M30 LPVT
3 1000 V = 1000
Voltage scaling
3 1000 V = 1000
Voltage scaling
3 1000 V = 1000
Voltage scaling
3 1000 V = 1000
Voltage scaling
3 1000 V = 1000
Voltage scaling
3 1.0 % = 10
3
50.000 Hz = 5000
Frequency scaling
3 1000 kW = 1000 Power scaling
3 1000 kVAr = 1000 Power scaling
3 1000 kVA = 1000 Power scaling
3 1.00 = 100
PF and cos scaling
3 1=1
3 10^4 = 1
3 10^8 = 1
3 1=1
3 10^4 = 1
3 10^8 = 1
3 1=1
3 10^4 = 1
3 10^8 = 1
3 1=1
3 10^4 = 1
3 10^8 = 1
3 1.000 = 1000
Tan scaling
3 1A=1
3 1000 V = 1000
Voltage scaling
3 1000 V = 1000
Voltage scaling
3 1%=1
3 1%=1
3 1%=1
3 1%=1
3 1%=1
P5/EN M/33A
109
Communication protocols
Add.
Name
Read Write FC
Scalling
Setting for Scalling
3356... Harmonics of VL3 / 3371 Harmonics of U12y
1
3381 Temperature 1
1
3382 Temperature 2
1
3383 Temperature 3
1
3384 Temperature 4
1
3385 Temperature 5
1
3386 Temperature 6
1
3387 Temperature 7
1
3388 Temperature 8
1
3389 Temperature 9
1
3390 Temperature 10
1
3391 Temperature 11
1
3392 Temperature 12
1
3393 Temperature 13
1
3394 Temperature 14
1
3395 Temperature 15
1
3396 Temperature 16
1
3410 Last fault current
1
3411 I> fault value
1
3412 I>> fault value
1
3413 I>>> fault value
1
3415 Fault reactance
1
3416 Algorithm condition
1
3417 Fault value >
1
3418 Fault value >>
1
3419 Fault value <
1
3420 Fault value <<
1
3430 Last fault Io current
1
3431 Io> fault value
1
3432 Io>> fault value
1
0
3 1%=1
0
3 1 °C = 1 / 1 °F = 1
0
3 1 °C = 1 / 1 °F = 1
0
3 1 °C = 1 / 1 °F = 1
0
3 1 °C = 1 / 1 °F = 1
0
3 1 °C = 1 / 1 °F = 1
0
3 1 °C = 1 / 1 °F = 1
0
3 1 °C = 1 / 1 °F = 1
0
3 1 °C = 1 / 1 °F = 1
0
3 1 °C = 1 / 1 °F = 1
0
3 1 °C = 1 / 1 °F = 1
0
3 1 °C = 1 / 1 °F = 1
0
3 1 °C = 1 / 1 °F = 1
0
3 1 °C = 1 / 1 °F = 1
0
3 1 °C = 1 / 1 °F = 1
0
3 1 °C = 1 / 1 °F = 1
0
3 1 °C = 1 / 1 °F = 1
1
3, 6
1.00 xIn = 100 / 1.00 A = 100
Fault value scaling
0
3
1.00 xIn = 100 / 1.00 A = 100
Fault value scaling
0
3
1.00 xIn = 100 / 1.00 A = 100
Fault value scaling
0
3
1.00 xIn = 100 / 1.00 A = 100
Fault value scaling
0
3 1.00 ohm = 100
OK=0;NegX=1;
BigX=2;Long
fault=3;No DI=4;
No pre-fault=5;No
post-fault=6;
0
3 ShrtFlt=7;
PreUns=8;
FltUns=9;
PostUns=10;
Blocked=11;Off=
12
0
3
1.0 %n = 10 / 1 rpm = 1
0
3
1.0 %n = 10 / 1 rpm = 1
0
3
1.0 %n = 10 / 1 rpm = 1
0
3
1.0 %n = 10 / 1 rpm = 1
0
3
1.00 pu = 100 / 1.00 A = 100
Fault value scaling
0
3
1.00 pu = 100 / 1.00 A = 100
Fault value scaling
0
3
1.00 pu = 100 / 1.00 A = 100
Fault value scaling
P5 U20 P5 P5 P5 P5 LPCT U20 V20 F30 M30 LPVT
110
P5/EN M/33A
Communication protocols
Add.
3433 3434 3435 3436 3437 3438 3439 3440 3441 3442 3443 3444 3445 3446 3447 3448 3449 3452 3453 3454 3455 3456
Name
Read Write
Io>>> fault value
1
0
Io>>>> fault value
1
0
Io>>>>> fault value
1
0
Last fault Io> current
1
0
Io> fault value
1
0
Io>> fault value
1
0
Io>>> fault value
1
0
SOTF fault value
1
0
Uo> fault value
1
0
Uo>> fault value
1
0
Uo>>> fault value
1
0
Io'> fault value
1
0
Io'>> fault value
1
0
Io'>>> fault value
1
0
IoUo> fault value
1
0
IoUo>> fault value
1
0
I2> fault value Cold load pickup Inrush detection
1
0
1
0
1
0
df/dt> fault value
1
0
df/dt>> fault value
1
0
Motor speed
1
0
FC
Scalling
Setting for Scalling
3
1.00 pu = 100 / 1.00 A = 100
Fault value scaling
3
1.00 pu = 100 / 1.00 A = 100
Fault value scaling
3
1.00 pu = 100 / 1.00 A = 100
Fault value scaling
3
1.00 pu = 100 / 1.00 A = 100
Fault value scaling
3
1.00 pu = 100 / 1.00 A = 100
Fault value scaling
3
1.00 pu = 100 / 1.00 A = 100
Fault value scaling
3
1.00 pu = 100 / 1.00 A = 100
Fault value scaling
3
1.00 xIn = 100 / 1.00 A = 100
Fault value scaling
3 1.0 % = 10
Fault value scaling
3 1.0 % = 10
Fault value scaling
3 1.0 % = 10
Fault value scaling
3
1.000 pu = 1000 / Fault value
1.000 A = 1000
scaling
3
1.000 pu = 1000 / Fault value
1.000 A = 1000
scaling
3
1.000 pu = 1000 / Fault value
1.000 A = 1000
scaling
3
1.00 %Pno = 100 Fault value
/ 1 kW = 1
scaling
3
1.00 %Pno = 100 Fault value
/ 1 kW = 1
scaling
3
1.00 xIn = 100 / 1.00 A = 100
Fault value scaling
3
Start=1;Timeout= 2
3
Start=1;Timeout= 2
3 1.00 Hz/s = 100
Fault value scaling
3 1.00 Hz/s = 100
Fault value scaling
3 1 rpm = 1
P5 U20 P5 P5 P5 P5 LPCT U20 V20 F30 M30 LPVT
Add.
Name
3501 3502 3503
DI1 counter DI2 counter DI3 counter
Statistics and virtual Input/Output
Read Write FC
Scalling
1
1
3, 6 1 = 1
1
1
3, 6 1 = 1
1
1
3, 6 1 = 1
Setting for Scalling
P5 U20 P5 P5 P5 P5 LPCT U20 V20 F30 M30 LPVT
P5/EN M/33A
111
Add.
Name
Read Write FC
Scalling
3504 DI4 counter
1
3505 DI5 counter
1
3506 DI6 counter
1
3507 DI7 counter
1
3508 DI8 counter
1
3509 DI9 counter
1
3510 DI10 counter
1
3511 DI11 counter
1
3512 DI12 counter
1
3513 DI13 counter
1
3514 DI14 counter
1
3515 DI15 counter
1
3516 DI16 counter
1
3517 DI17 counter
1
3518 DI18 counter
1
3519 DI19 counter
1
3520 DI20 counter
1
3521 DI21 counter
1
3522 DI22 counter
1
3523 DI23 counter
1
3524 DI24 counter
1
3525 DI25 counter
1
3526 DI26 counter
1
3527 DI27 counter
1
3528 DI28 counter
1
3529 DI29 counter
1
3530 DI30 counter
1
3531 DI31 counter
1
3532 DI32 counter
1
3533 DI33 counter
1
3534 DI34 counter
1
3535 DI35 counter
1
3536 DI36 counter
1
3537 DI37 counter
1
3538 DI38 counter
1
3539 DI39 counter
1
3540 DI40 counter
1
3571 Shot1 start counter
1
3572 Shot2 start counter
1
3573 Shot3 start counter
1
3574 Shot4 start counter
1
1
3, 6 1 = 1
1
3, 6 1 = 1
1
3, 6 1 = 1
1
3, 6 1 = 1
1
3, 6 1 = 1
1
3, 6 1 = 1
1
3, 6 1 = 1
1
3, 6 1 = 1
1
3, 6 1 = 1
1
3, 6 1 = 1
1
3, 6 1 = 1
1
3, 6 1 = 1
1
3, 6 1 = 1
1
3, 6 1 = 1
1
3, 6 1 = 1
1
3, 6 1 = 1
1
3, 6 1 = 1
1
3, 6 1 = 1
1
3, 6 1 = 1
1
3, 6 1 = 1
1
3, 6 1 = 1
1
3, 6 1 = 1
1
3, 6 1 = 1
1
3, 6 1 = 1
1
3, 6 1 = 1
1
3, 6 1 = 1
1
3, 6 1 = 1
1
3, 6 1 = 1
1
3, 6 1 = 1
1
3, 6 1 = 1
1
3, 6 1 = 1
1
3, 6 1 = 1
1
3, 6 1 = 1
1
3, 6 1 = 1
1
3, 6 1 = 1
1
3, 6 1 = 1
1
3, 6 1 = 1
1
3, 6 1 = 1
1
3, 6 1 = 1
1
3, 6 1 = 1
1
3, 6 1 = 1
Communication protocols
Setting for Scalling
P5 U20 P5 P5 P5 P5 LPCT U20 V20 F30 M30 LPVT
112
P5/EN M/33A
Communication protocols
Add.
Name
Read Write FC
Scalling
3575 Shot5 start counter
1
3576 AR start counter
1
3577 AR fail counter
1
3578 AR shot number
1
3579
Direct trip AR request
1
3580 Recloser locked
1
3581 Recloser running
1
3582 Final trip
1
3583 Auto-Recloser on
1
3611 Motor starting
1
3612 Motor running
1
3613 Voltage interrupt
1
3614 Voltage status
1
3615 Timer 1 status
1
3616 Timer 2 status
1
3617 Timer 3 status
1
3618 Timer 4 status
1
3619
CB monitoring alarm 1
1
3620
CB monitoring alarm 2
1
3621
Logic output status 1...8
1
3622
Logic output status 9...16
1
3623
Logic output status 17...20
1
3626
Virtual outputs 1...10
1
3627
Virtual outputs 11...20
1
3631 Sync1 request
1
3632 Sync1 OK
1
3633 Bypass
1
3634 Sync1 fail
1
3657 Virtual input 1
1
3658 Virtual input 2
1
3659 Virtual input 3
1
3660 Virtual input 4
1
3661 Virtual input 5
1
3662 Virtual input 6
1
3663 Virtual input 7
1
1
3, 6 1 = 1
1
3, 6 1 = 1
1
3, 6 1 = 1
0
3 1;2;3;4;5;END=6
0
3 1=1
0
3 1=1
0
3 1=1
0
3 1=1
0
3 1=1
0
3 1=1
0
3 1=1
0
3 Low=0;ok=1
OK=0;Low=1;
High=2;Low/
0
3 High=3;(OK)=4;
(Low)=5;(High)
=6;(Low)/High=7
1
3, 6 0=1;1=2
1
3, 6 0=1;1=2
1
3, 6 0=1;1=2
1
3, 6 0=1;1=2
0
3 1=1
0
3 1=1
0
3 1=1
0
3 1=1
0
3 1=1
0
3 1=1
0
3 1=1
0
3 1=1
0
3 1=1
1
3, 6 1 = 1
0
3 1=1
1
3, 6 0;1
1
3, 6 0;1
1
3, 6 0;1
1
3, 6 0;1
1
3, 6 0;1
1
3, 6 0;1
1
3, 6 0;1
Setting for Scalling
P5 U20 P5 P5 P5 P5 LPCT U20 V20 F30 M30 LPVT
P5/EN M/33A
113
Add.
Name
3664 3665 3666 3667 3668 3669 3670 3671 3672 3673 3674 3675 3676
Virtual input 8 Virtual input 9 Virtual input 10 Virtual input 11 Virtual input 12 Virtual input 13 Virtual input 14 Virtual input 15 Virtual input 16 Virtual input 17 Virtual input 18 Virtual input 19 Virtual input 20
Read Write FC
Scalling
1
1
3, 6 0;1
1
1
3, 6 0;1
1
1
3, 6 0;1
1
1
3, 6 0;1
1
1
3, 6 0;1
1
1
3, 6 0;1
1
1
3, 6 0;1
1
1
3, 6 0;1
1
1
3, 6 0;1
1
1
3, 6 0;1
1
1
3, 6 0;1
1
1
3, 6 0;1
1
1
3, 6 0;1
Communication protocols
Setting for Scalling
P5 U20 P5 P5 P5 P5 LPCT U20 V20 F30 M30 LPVT
Minimum value, maximum value, ARC and circuit breaker
Add.
4001 4002 4003 4004 4005 4006 4007 4008 4009 4010 4011 4012 4013 4014 4015 4016
Name
Read Write
Minimum frequency 1
1
Minimum active power
1
1
Minimum react. power
1
1
Minimum apparent power
1
1
Min power factor
1
1
Minimum of Io
1
1
Minimum of Io'
1
1
Demand Minimum active power
1
1
Demand minimum reactive power
1
1
Demand Minimum apparent power
1
1
Demand minimum power factor
1
1
RMS Demand mini active power
1
1
RMS Demand min reactive power
1
1
RMS Demand mini apparent power
1
1
Minimum of IL1
1
1
Minimum of IL2
1
1
FC
Scalling
Setting for Scalling
3, 6
50.000 Hz = 5000
Frequency scaling
P5 U20 P5 P5 P5 P5 LPCT U20 V20 F30 M30 LPVT
3, 6 1000 kW = 1000 Power scaling
3, 6 1000 kVAr = 1000 Power scaling
3, 6 1000 kVA = 1000 Power scaling
3, 6 1.000 = 1000 3, 6 1.0 % = 10 3, 6 1.0 % = 10
PF and cos scaling
Io scaling
Io' scaling
3, 6 1000 kW = 1000 Power scaling
3, 6 1000 kVAr = 1000 Power scaling
3, 6 1000 kVA = 1000 Power scaling
3, 6 1.000 = 1000
PF and cos scaling
3, 6 1000 kW = 1000 Power scaling
3, 6 1000 kVAr = 1000 Power scaling
3, 6 1000 kVA = 1000 Power scaling
3, 6 1 A = 1 3, 6 1 A = 1
114
P5/EN M/33A
Communication protocols
Add. 4017 4018 4019 4020 4021 4022 4023 4024 4025 4026 4027 4028 4030 4031 4032
4033
4034
4035
4101 4102 4103 4104 4105 4106 4107 4108 4109
Name
Read Write
Minimum of IL3
1
1
RMS minimum of IL1
1
1
RMS minimum of IL2
1
1
RMS minimum of IL3
1
1
Demand Minimum of IL1
1
1
Demand Minimum of IL2
1
1
Demand Minimum of IL3
1
1
RMS Demand minimum of IL1
1
1
RMS Demand minimum of IL2
1
1
RMS Demand minimum of IL3
1
1
Minimum of EF current
1
1
Minimum of Uo
1
1
Minimum of U12
1
1
Minimum of U23
1
1
Minimum of U31
1
1
Minimum U12 RMS
voltage / Minimum
1
1
VL1 RMS voltage
Minimum U23 RMS
voltage / Minimum
1
1
VL2 RMS voltage
Minimum VL3 RMS
voltage / Minimum
1
1
U12y RMS voltage
Maximum frequency
1
1
Maximum active power
1
1
Maximum react. power
1
1
Maximum apparent power
1
1
Max power factor
1
1
Maximum of Io
1
1
Maximum of Io'
1
1
Demand Maximum active power
1
1
Demand maximum reactive power
1
1
FC
Scalling
3, 6 1 A = 1 3, 6 1 A = 1 3, 6 1 A = 1 3, 6 1 A = 1 3, 6 1 A = 1 3, 6 1 A = 1 3, 6 1 A = 1 3, 6 1 A = 1 3, 6 1 A = 1 3, 6 1 A = 1 3, 6 1.0 pu = 10 3, 6 1.0 % = 10 3, 6 1000 V = 1000 3, 6 1000 V = 1000 3, 6 1000 V = 1000
3, 6 1000 V = 1000
Setting for Scalling
P5 U20 P5 P5 P5 P5 LPCT U20 V20 F30 M30 LPVT
Io scaling (CSH)
Voltage scaling
Voltage scaling
Voltage scaling
Voltage scaling
Voltage scaling
3, 6 1000 V = 1000
Voltage scaling
3, 6 1000 V = 1000
Voltage scaling
3, 6
50.000 Hz = 5000
Frequency scaling
3, 6 1000 kW = 1000 Power scaling
3, 6 1000 kVAr = 1000 Power scaling
3, 6 1000 kVA = 1000 Power scaling
3, 6 1.000 = 1000 3, 6 1.0 % = 10 3, 6 1.0 % = 10
PF and cos scaling
Io scaling
Io' scaling
3, 6 1000 kW = 1000 Power scaling
3, 6 1000 kVAr = 1000 Power scaling
P5/EN M/33A
115
Communication protocols
Add.
4110 4111 4112 4113 4114 4115 4116 4117 4118 4119 4120 4121 4122 4123 4124 4125 4126 4127 4128 4130 4131 4132
4133
4134
4135 4299 4300 4301
Name
Read Write
Demand Maximum apparent power
1
1
Demand maximum power factor
1
1
RMS Demand Max active power
1
1
RMS Demand max reactive power
1
1
RMS Demand Max apparent power
1
1
Maximum of IL1
1
1
Maximum of IL2
1
1
Maximum of IL3
1
1
RMS maximum of IL1
1
1
RMS maximum of IL2
1
1
RMS maximum of IL3
1
1
Demand Maximum of IL1
1
1
Demand Maximum of IL2
1
1
Demand Maximum of IL3
1
1
RMS Demand maximum of IL1
1
1
RMS Demand maximum of IL2
1
1
RMS Demand maximum of IL3
1
1
Maximum of EF current
1
1
Maximum of Uo
1
1
Maximum of U12
1
1
Maximum of U23
1
1
Maximum of U31
1
1
Maximum U12 RMS
voltage / Maximum
1
1
VL1 RMS voltage
Maximum U23 RMS
voltage / Maximum
1
1
VL2 RMS voltage /
Maximum VL3 RMS
voltage / Maximum
1
1
U12y RMS voltage
Arc Io state
Arc I state
Clear I/O units' registers
1
0
1
0
1
1
P5
FC
Scalling
Setting for Scalling
U20 P5 P5 P5 P5 LPCT U20 V20 F30 M30
LPVT
3, 6 1000 kVA = 1000 Power scaling
3, 6 1.000 = 1000
PF and cos scaling
3, 6 1000 kW = 1000 Power scaling
3, 6 1000 kVAr = 1000 Power scaling
3, 6 1000 kVA = 1000 Power scaling
3, 6 1 A = 1
3, 6 1 A = 1
3, 6 1 A = 1
3, 6 1 A = 1
3, 6 1 A = 1
3, 6 1 A = 1
3, 6 1 A = 1
3, 6 1 A = 1
3, 6 1 A = 1
3, 6 1 A = 1
3, 6 1 A = 1
3, 6 1 A = 1
3, 6 1.0 pu = 10
Io scaling (CSH)
3, 6 1.0 % = 10
Voltage scaling
3, 6 1000 V = 1000
Voltage scaling
3, 6 1000 V = 1000
Voltage scaling
3, 6 1000 V = 1000
Voltage scaling
3, 6 1000 V = 1000
Voltage scaling
3, 6 1000 V = 1000
Voltage scaling
3, 6 1000 V = 1000
Voltage scaling
3 1=1 3 1=1
3, 6 Clear=1
116
P5/EN M/33A
Communication protocols
Add.
Name
4302 4303
Release all latches Arc Stages
4304... 4309
Arc sensor status
4351... 4355
4349
4356... 4359
Low limit (primary value)
Minimum CB trip cmd. Time
High limit (xIn)
4360... Sum of broken 4361 current IL11
4362... Sum of broken 4363 current IL12
4364... Sum of broken 4365 current IL13
4366... Sum of broken 4367 current IL14
4368... Sum of broken 4369 current IL15
4370... IL1 broken current 4374 counter
4375... Sum of broken 4376 current IL21
4377... Sum of broken 4378 current IL22
4379... Sum of broken 4380 current IL23
4381... Sum of broken 4382 current IL24
4383... Sum of broken 4384 current IL25
4385... IL2 broken current 4389 counter
4390... Sum of broken 4391 current IL31
4392... Sum of broken 4393 current IL32
4394... Sum of broken 4395 current IL33
4396... Sum of broken 4397 current IL34
4398... Sum of broken 4399 current IL35
Read Write
1
1
1
0
1
0
1
0
1
1
1
0
1
0
1
0
1
0
1
0
1
0
1
0
1
0
1
0
1
0
1
0
1
0
1
0
1
0
1
0
1
0
1
0
1
0
FC
Scalling
Setting for Scalling
3, 6 Release=1
3 1=1
OK=1;Active=2;
3
Not conn=3;Shrt circ=4;Daylight=5;
Not Inst.=6;Null=0
3 1.0 kA = 10
3.6 1.0s = 1
3 1.00 xIn = 100
neighbouring two 3 register combine
to a float32 value
neighbouring two 3 register combine
to a float32 value
neighbouring two 3 register combine
to a float32 value
neighbouring two 3 register combine
to a float32 value
neighbouring two 3 register combine
to a float32 value
3 1000 = 1000
CB open count scaling
neighbouring two 3 register combine
to a float32 value
neighbouring two 3 register combine
to a float32 value
neighbouring two 3 register combine
to a float32 value
neighbouring two 3 register combine
to a float32 value
neighbouring two 3 register combine
to a float32 value
3 1000 = 1000
CB open count scaling
neighbouring two 3 register combine
to a float32 value
neighbouring two 3 register combine
to a float32 value
neighbouring two 3 register combine
to a float32 value
neighbouring two 3 register combine
to a float32 value
neighbouring two 3 register combine
to a float32 value
P5 U20 P5 P5 P5 P5 LPCT U20 V20 F30 M30 LPVT
P5/EN M/33A
117
Communication protocols
Add.
Name
4400... IL3 broken current 4404 counter
4405... Cumul. broken 4406 current IL1
4407... Cumul. broken 4408 current IL2
4409... Cumul. broken 4410 current IL3
4411 CB Open Counter
4412
Protection Trip counter
4413 Rack out counter
4414... 4453
4455... 4494
4496... 4535
CB opening time
CB Closing time
Spring Charging times
4536... 4538
Alarm1
4539... 4541
Alarm2
Read Write
1
0
1
0
1
0
1
0
1
0
1
0
1
0
1
0
1
0
1
0
1
0
1
0
FC
Scalling
Setting for Scalling
3 1000 = 1000
CB open count scaling
neighbouring two 3 register combine
to a float32 value
neighbouring two 3 register combine
to a float32 value
neighbouring two 3 register combine
to a float32 value
3 1=1
CB open count scaling
3 1000 = 1000
CB open count scaling
3 1000 = 1000
CB open count scaling
P5 U20 P5 P5 LPCT U20 V20 LPVT
P5 P5 F30 M30
3 1=1
3 1=1
3 1=1 3 1000 = 1000 3 1000 = 1000
Limit for oper. left scaling
Limit for oper. left scaling
Settings
Add.
Name
Read Write FC
Scalling
ARC setting items:
5001 I>int. pick-up value
1
5002 Io>int. pick-up value 1
5003 Arc stage 1 enabled 1
5004 Arc stage 2 enabled 1
5005 Arc stage 3 enabled 1
5006 Arc stage 4 enabled 1
5007 Arc stage 5 enabled 1
5008 Arc stage 6 enabled 1
5009 Arc stage 7 enabled 1
5010 Arc stage 8 enabled 1
5011 Stage 1 Mode
1
5012 Stage 2 Mode
1
5013 Stage 3 Mode
1
5014 Stage 4 Mode
1
1
3, 6 1.00 xIn = 100
1
3, 6 1.00 xIn = 100
1
3, 6 Off=0;On=1
1
3, 6 Off=0;On=1
1
3, 6 Off=0;On=1
1
3, 6 Off=0;On=1
1
3, 6 Off=0;On=1
1
3, 6 Off=0;On=1
1
3, 6 Off=0;On=1
1
3, 6 Off=0;On=1
1
3, 6
Light=0; Light&Current=1
1
3, 6
Light=0; Light&Current=1
1
3, 6
Light=0; Light&Current=1
1
3, 6
Light=0; Light&Current=1
Setting for Scalling
P5 U20 P5 P5 P5 P5 LPCT U20 V20 F30 M30 LPVT
118
P5/EN M/33A
Communication protocols
Add.
Name
Read Write
5015 Stage 5 Mode
1
1
5016 Stage 6 Mode
1
1
5017 Stage 7 Mode
1
1
5018 Stage 8 Mode
1
1
5019 Trip 1 delay [x1ms]
1
1
5020 Trip 2 delay [x1ms]
1
1
5021 Trip 3 delay [x1ms]
1
1
5022 Trip 4 delay [x1ms]
1
1
5023 Trip 5 delay [x1ms]
1
1
5024 Trip 6 delay [x1ms]
1
1
5025 Trip 7 delay [x1ms]
1
1
5026 Trip 8 delay [x1ms]
1
1
5027
Min. hold time [x1ms]
1
1
5028
Min. hold time2 [x1ms]
1
1
5029
Min. hold time3 [x1ms]
1
1
5030
Min. hold time4 [x1ms]
1
1
5031
Min. hold time5 [x1ms]
1
1
5032
Min. hold time6 [x1ms]
1
1
5033
Min. hold time7 [x1ms]
1
1
5034
Min. hold time8 [x1ms]
1
1
Inrush setting
5101 Enable for Inrush
1
1
5102 Max inrush current
1
1
5103
Pickup for 2nd harmonic
1
1
OverCurrent I> setting
5151
5152... 5155
Enable for I> Pick-up value
1
1
1
1
5156... 5159
Delay curve family
1
1
5160... 5163
Delay type
1
1
FC
Scalling
3, 6
Light=0; Light&Current=1
3, 6
Light=0; Light&Current=1
3, 6
Light=0; Light&Current=1
3, 6
Light=0; Light&Current=1
3, 6 1 = 1
3, 6 1 = 1
3, 6 1 = 1
3, 6 1 = 1
3, 6 1 = 1
3, 6 1 = 1
3, 6 1 = 1
3, 6 1 = 1
3, 6 1 = 1
3, 6 1 = 1
3, 6 1 = 1
3, 6 1 = 1
3, 6 1 = 1
3, 6 1 = 1
3, 6 1 = 1
3, 6 1 = 1
3, 6 Off=0;On=1 3, 6 1.00 xIn = 100 3, 6 1 % = 1
3, 6 Off=0;On=1
3, 6 1.00 xIn = 100
DT=0;IEC=1;
3, 6
IEEE=2;IEEE2=3; Others=4;Prg1=5;
Prg2=6;Prg3=7
DT=0;NI=1;VI=2;
EI=3;LTI=4;LTEI=
3, 6
5;LTVI=6;MI=7; STI=8;STEI=9;
CO8=10;RI=11;
RXIDG=12
Setting for Scalling
P5 U20 P5 P5 P5 P5 LPCT U20 V20 F30 M30 LPVT
P5/EN M/33A
119
Communication protocols
Add.
Name
Read Write
5164... 5167
Operation delay
1
1
5168... 5171
Inv. time coefficient
1
1
5172... 5175
Reset time
1
1
5176... 5179
Inrush status for I>
1
1
5180... 5183
SOL use by I>
1
1
5184... SOL Operation 5187 delay
1
1
5188... SOL Inv. time 5191 coefficient
1
1
5192... 5195
CLPU status for I>
1
1
5196... 5199
CLPU pick-up value
1
1
5200... CLPU operation 5203 delay
1
1
5204... CLPU Inv. time 5207 coefficient
1
1
5208 Include harmonics
1
1
5209... 5212
Reset type
1
1
OverCurrent I>> setting
5251
5252... 5255
Enable for I>> Pick-up value
1
1
1
1
5256... 5259
Delay curve family
1
1
5260... 5263
Delay type
1
1
5264... 5267
Operation delay
1
1
5268... 5271
Inv. time coefficient
1
1
5272... 5275
Inrush status for I>>
1
1
5276... 5279
SOL use by I>>
1
1
5280... SOL Operation 5283 delay
1
1
5284... SOL Inv. time 5287 coefficient
1
1
5288... 5291
CLPU status for I>>
1
1
5292... 5295
CLPU pick-up value
1
1
5296... CLPU Operation 5299 delay
1
1
FC
Scalling
3, 6 1.00 s = 100 3, 6 1.000 = 1000 3, 6 1.00 s = 100 3, 6 Off=0;On=1 3, 6 Off=0;On=1 3, 6 1.00 s = 100 3, 6 1.000 = 1000 3, 6 Off=0;On=1 3, 6 1.00 xIn = 100 3, 6 1.00 s = 100 3, 6 1.000 = 1000 3, 6 Off=0;On=1 3, 6 DT=0;IDMT=1
3, 6 Off=0;On=1
3, 6 1.00 xIn = 100
DT=0;IEC=1;
3, 6
IEEE=2;IEEE2=3; Others=4;Prg1=5;
Prg2=6;Prg3=7
DT=0;NI=1;VI=2;
EI=3;LTI=4;LTEI=
3, 6
5;LTVI=6;MI=7; STI=8;STEI=9;
CO8=10;RI=11;
RXIDG=12
3, 6 1.00 s = 100
3, 6 1.000 = 1000
3, 6 Off=0;On=1
3, 6 Off=0;On=1
3, 6 1.00 s = 100
3, 6 1.000 = 1000
3, 6 Off=0;On=1
3, 6 1.00 xIn = 100
3, 6 1.00 s = 100
Setting for Scalling
P5 U20 P5 P5 P5 P5 LPCT U20 V20 F30 M30 LPVT
120
P5/EN M/33A
Communication protocols
Add.
Name
Read Write
5300... CLPU Inv. time 5303 coefficient
1
1
5304 Include harmonics
1
1
5305... 5308
Reset type
1
1
5309... 5312
Reset time
1
1
OverCurrent I>>> setting
5351 Enable for I>>>
1
1
5352... 5355
Pick-up value
1
1
5356... 5359
Operation delay
1
1
5360... Inrush status for 5363 I>>>
1
1
5364... 5367
SOL use by I>>>
1
1
5368... SOL Operation 5371 delay
1
1
5372... CLPU status for 5375 I>>>
1
1
5376... 5379
CLPU pick-up value
1
1
5380... CLPU Operation 5383 delay
1
1
SOTF setting
5401 Enable for SOTF
1
1
5402 Pick-up value
1
1
5403
Dead line detection delay
1
1
5404 SOTF active Timer
1
1
5405
Dead line detection input
1
1
I> setting
5411 Enable for I>
1
1
5412... 5415
5416... 5419
5420... 5423
Pick-up value Direction mode Angle offset
1
1
1
1
1
1
5424... 5427
Delay curve family
1
1
5428... 5431
Delay type
1
1
FC
Scalling
3, 6 1.000 = 1000 3, 6 Off=0;On=1 3, 6 DT=0;IDMT=1 3, 6 1.00 s = 100
3, 6 Off=0;On=1 3, 6 1.00 xIn = 100 3, 6 1.00 s = 100 3, 6 Off=0;On=1 3, 6 Off=0;On=1 3, 6 1.00 s = 100 3, 6 Off=0;On=1 3, 6 1.00 xIn = 100 3, 6 1.00 s = 100
3, 6 Off=0;On=1 3, 6 1.00 xIn = 100 3, 6 1.00 s = 100 3, 6 1.00 s = 100 3, 6 Value 16
3, 6 Off=0;On=1
3, 6 1.00 xIn = 100
3, 6
Dir+Backup=0; Undir=1;Dir=2
3, 6 1 ° = 1
DT=0;IEC=1;
3, 6
IEEE=2;IEEE2=3; Others=4;Prg1=5;
Prg2=6;Prg3=7
DT=0;NI=1;VI=2;
3, 6
EI=3;LTI=4;LTEI= 5;LTVI=6;MI=7;
STI=8;STEI=9;
Setting for Scalling
P5 U20 P5 P5 P5 P5 LPCT U20 V20 F30 M30 LPVT
16. DI1=1;DI2=2;...;DI19=19;DI20=20;Arc1=25;Arc2=26;BI=27;VI1=29;VI2=30;VI3=31;VI4=32;DO1(B)=33;DO2(B)=34;DO3(B)=35; Watchdog=36;SF=37;SF=38;SF=39;SF=40;SF=41;BO=42;DO1(C)=43;DO2(C)=44;DO3(C)=45;DO4(C)=46;LedAl=49;LedTr=50;LedA= 51;LedB=52;LedC=53;LedDR=54;VO1=55;VO2=56;...;VO5=59;VO6=60;DI21=65;DI22=66;...;DI39=83;DI40=84;F1=85;F2=86;...;F6= 90;F7=91;DO1(D)=97;DO2(D)=98;DO3(D)=99;SF=100;DO1(E)=101;DO2(E)=102;NI1=129;NI2=130;...;NI63=191;NI64=192;POC1= 193;POC2=194;...;POC15=207;POC16=208;VI5=225;VI6=226;...;VI19=239;VI20=240;VO7=257;VO8=258;...;VO19=269;VO20=270; NI65=289;NI66=290;...;NI127=351;NI128=352
P5/EN M/33A
121
Communication protocols
Add.
Name
Read Write
5432... 5435
Operation delay
1
1
5436... 5439
Inv. time coefficient
1
1
5440... 5443
Reset time
1
1
5444... 5447
Inrush status for I>
1
1
5448... 5451
SOL status for I>
1
1
5452... SOL Operation 5455 delay
1
1
5456... SOL Inv. time 5459 coefficient
1
1
5460... 5463
CLPU status for I>
1
1
5464... 5467
CLPU pick-up value
1
1
5468... CLPU Operation 5471 delay
1
1
5472... CLPU Inv. time 5475 coefficient
5476... Reset type 5479
I>> setting
1
1
1
1
5481 Enable for I>>
1
1
5482... 5485
Pick-up value
1
1
5486... 5489
Direction mode
1
1
5490... 5493
Angle offset
1
1
5494... 5497
Delay curve family
1
1
5498... 5501
Delay type
1
1
5502... 5505
Operation delay
1
1
5506... 5509
Inv. time coefficient
1
1
5510... 5513
Reset time
1
1
5514... Inrush status for 5517 I>>
1
1
5518... 5521
SOL status for I>>
1
1
5522... SOL Operation 5525 delay
1
1
5526... SOL Inv. time 5529 coefficient
1
1
FC
Scalling
CO8=10;RI=11; RXIDG=12 3, 6 1.00 s = 100 3, 6 1.000 = 1000 3, 6 1.00 s = 100 3, 6 Off=0;On=1 3, 6 Off=0;On=1 3, 6 1.00 s = 100 3, 6 1.000 = 1000 3, 6 Off=0;On=1 3, 6 1.00 xIn = 100 3, 6 1.00 s = 100 3, 6 1.000 = 1000 3, 6 DT=0;IDMT=1
3, 6 Off=0;On=1
3, 6 1.00 xIn = 100
3, 6
Dir+Backup=0; Undir=1;Dir=2
3, 6 1 ° = 1
DT=0;IEC=1;
3, 6
IEEE=2;IEEE2=3; Others=4;Prg1=5;
Prg2=6;Prg3=7
DT=0;NI=1;VI=2;
EI=3;LTI=4;LTEI=
3, 6
5;LTVI=6;MI=7; STI=8;STEI=9;
CO8=10;RI=11;
RXIDG=12
3, 6 1.00 s = 100
3, 6 1.000 = 1000
3, 6 1.00 s = 100
3, 6 Off=0;On=1
3, 6 Off=0;On=1
3, 6 1.00 s = 100
3, 6 1.000 = 1000
Setting for Scalling
P5 U20 P5 P5 P5 P5 LPCT U20 V20 F30 M30 LPVT
122
P5/EN M/33A
Communication protocols
Add.
Name
Read Write FC
Scalling
5530... CLPU status for 5533 I>>
1
5534... 5537
CLPU Pick-up value
1
5538... CLPU Operation 5541 delay
1
5542... CLPU Inv. time 5545 coefficient
1
5546... 5549
Reset type
1
I>>> setting
5551 Enable for I>>>
1
5552... 5555
Pick-up value
1
5556... 5559
Direction mode
1
5560... 5563
Angle offset
1
5564... 5567
Operation delay
1
5568... Inrush status for 5571 I>>>
1
5572... SOL status for 5575 I>>>
1
5576... SOL Operation 5579 delay
1
5580... CLPU status for 5583 I>>>
1
5584... 5587
CLPU Pick-up value
1
5588... CLPU Operation 5591 delay
1
I>>>> setting
5601 Enable for I>>>>
1
5602... 5605
Pick-up value
1
5606... 5609
Direction mode
1
5610... 5613
Angle offset
1
5614... 5617
Operation delay
1
5618... Inrush status for 5621 I>>>>
1
5622... SOL status for 5625 I>>>>
1
5626... SOL Operation 5629 delay
1
5630... CLPU status for 5633 I>>>>
1
5634... 5637
CLPU Pick-up value
1
5638... CLPU Operation 5641 delay
1
1
3, 6 Off=0;On=1
1
3, 6 1.00 xIn = 100
1
3, 6 1.00 s = 100
1
3, 6 1.000 = 1000
1
3, 6 DT=0;IDMT=1
1
3, 6 Off=0;On=1
1
3, 6 1.00 xIn = 100
1
3, 6
Dir+Backup=0; Undir=1;Dir=2
1
3, 6 1 ° = 1
1
3, 6 1.00 s = 100
1
3, 6 Off=0;On=1
1
3, 6 Off=0;On=1
1
3, 6 1.00 s = 100
1
3, 6 Off=0;On=1
1
3, 6 1.00 xIn = 100
1
3, 6 1.00 s = 100
1
3, 6 Off=0;On=1
1
3, 6 1.00 xIn = 100
1
3, 6
Dir+Backup=0; Undir=1;Dir=2
1
3, 6 1 ° = 1
1
3, 6 1.00 s = 100
1
3, 6 Off=0;On=1
1
3, 6 Off=0;On=1
1
3, 6 1.00 s = 100
1
3, 6 Off=0;On=1
1
3, 6 1.00 xIn = 100
1
3, 6 1.00 s = 100
Setting for Scalling
P5 U20 P5 P5 P5 P5 LPCT U20 V20 F30 M30 LPVT
P5/EN M/33A
123
Communication protocols
Add.
Name
Read Write
P< setting
5651 Enable for P<
5652... 5655
Pick-up value
5656... 5659
Operation delay
P<< setting
5701 Enable for P<<
5702... 5705
Pick-up value
5706... 5709
Operation delay
I< setting
5751 Enable for I<
5752... 5755
Pick-up value
5756... 5759
Operation delay
I2>I1 setting
5801 Enable for I2/I1>
5802... 5805
Pick-up value
5806... 5809
Operation delay
I2> setting
5901
5902... 5905
Enable for I2> Pick-up value
1
1
1
1
1
1
1
1
1
1
1
1
1
1
1
1
1
1
1
1
1
1
1
1
1
1
1
1
5906... 5909
Delay curve family
1
1
5910... 5913
Delay type
1
1
5914... 5917
Operation delay
1
1
5918... 5921
Inv. time coefficient
1
1
5922... 5925
Reset type
1
1
5926... 5929
Reset time
1
1
Ist> setting
5951 5952
Enable for Ist> Delay type
1
1
1
1
5953 Motor start time Ilr> setting
1
1
6001 Enable for Ilr>
1
1
FC
Scalling
3, 6 Off=0;On=1 3, 6 1 %Sn = 1 3, 6 1.0 s = 10
3, 6 Off=0;On=1 3, 6 1 %Sn = 1 3, 6 1.0 s = 10
3, 6 Off=0;On=1 3, 6 1.00 %In = 100 3, 6 1.0 s = 10
3, 6 Off=0;On=1 3, 6 1 % = 1 3, 6 1.00 s = 100
3, 6 Off=0;On=1
3, 6 1.00 xIn = 100
DT=0;IEC=1;
3, 6
IEEE=2;IEEE2=3; Others=4;Prg1=5;
Prg2=6;Prg3=7
DT=0;NI=1;VI=2;
EI=3;LTI=4;LTEI=
3, 6
5;LTVI=6;MI=7; STI=8;STEI=9;
CO8=10;RI=11;
RXIDG=12
3, 6 1.00 s = 100
3, 6 1.000 = 1000
3, 6 DT=0;IDMT=1
3, 6 1.00 s = 100
3, 6 Off=0;On=1 3, 6 DT=0;INV=1 3, 6 1.0 s = 10
3, 6 Off=0;On=1
Setting for Scalling
P5 U20 P5 P5 P5 P5 LPCT U20 V20 F30 M30 LPVT
124
P5/EN M/33A
Communication protocols
Add.
Name
Read Write
6002 6003 6004
Pick-up value Delay type Operation delay
1
1
1
1
1
1
N> setting
6051 Enable for N>
1
1
6052
Max motor Hot starts
1
1
6053
Max motor cold starts
1
1
6054
Min time between motor starts
1
1
6055 Reference period
1
1
6056 Hot Status Limit Motor T°> setting
1
1
6101 Enable for Motor T> 1
1
6102... Basic current 6105 setting
1
1
6106... Max permissive I 6109 factor
1
1
6110... Heating time 6113 constant
1
1
6114... Time constant for 6117 motor starting
1
1
6118... Cooling time 6121 constant
1
1
6130... 6133
Unbalance factor
1
1
6134... Thermal alarm 6137 value
1
1
6138... Reserve time 6141 thermal alarm
1
1
6142... Temperature based 6145 mode
1
1
6146... Nominal ambient 6149 temp
1
1
6150... Max object 6153 temperature
1
1
6154... 6157
Alarm temperature
1
1
6158... Min ambient 6161 temperature
1
1
6162... Default ambient 6165 temperature
Feeder T°> setting
1
1
6201
Enable for feeder T>
1
1
6202... Basic current 6205 setting
1
1
6206... Max permissive I 6209 factor
1
1
6210... Heating time 6213 constant
1
1
FC
Scalling
3, 6 1.0 % = 10 3, 6 DT=0;INV=1 3, 6 1.0 s = 10
3, 6 Off=0;On=1 3, 6 1 = 1 3, 6 1 = 1 3, 6 1.0 min = 10 3, 6 1.0 min = 10 3, 6 1.0 % = 10
3, 6 Off=0;On=1 3, 6 1.00 xIn = 100
3, 6 1.00 = 100 3, 6 1.0 min = 10
3, 6 1.0 min = 10
3, 6 1.0 min = 10 3, 6 1.0 = 10 3, 6 1 % = 1
3, 6 1.0 min = 10
3, 6
Current=0; Ambient=1
3, 6 1 °C = 1 / 1 °F = 1
3, 6 1 °C = 1 / 1 °F = 1
3, 6 1 °C = 1 / 1 °F = 1
3, 6 1 °C = 1 / 1 °F = 1
3, 6 1 °C = 1 / 1 °F = 1
3, 6 Off=0;On=1 3, 6 1.00 xIn = 100 3, 6 1.00 = 100 3, 6 1.0 min = 10
Setting for Scalling
P5 U20 P5 P5 P5 P5 LPCT U20 V20 F30 M30 LPVT
P5/EN M/33A
125
Communication protocols
Add.
Name
Read Write
6214... Thermal alarm 6217 value
1
1
6218... Reserve time 6221 thermal alarm
1
1
6222... Temperature based 6225 mode
1
1
6226... Nominal ambient 6229 temp
1
1
6230... Max object 6233 temperature
1
1
6234... 6237
Alarm temperature
1
1
6238... Min ambient 6241 temperature
1
1
6242... Default ambient 6245 temperature
Io> setting
1
1
6261
6262... 6265
Enable for Io> Pick-up value
1
1
1
1
6266... 6269
Delay curve family
1
1
6270... 6273
Delay type
1
1
6274... 6277
Operation delay
1
1
6278... 6281
Inv. time coefficient
1
1
6282... 6285
Network earthing
1
1
6286... 6289
Reset time
1
1
6291... 6294
Inrush status for Io>
1
1
6295... 6298
SOL use for Io>
1
1
6299... SOL Operation 6302 delay
1
1
6303... SOL Inv. time 6306 coefficient
1
1
6307... 6310
CLPU status for Io>
1
1
6311... 6314
CLPU Pick-up value
1
1
6315... CLPU Operation 6318 delay
1
1
6319... CLPU Inv. time 6322 coefficient
1
1
6323... 6326
Reset type
1
1
6327
Enable faulty phase detection
1
1
FC
Scalling
3, 6 1 % = 1
3, 6 1.0 min = 10
3, 6
Current=0; Ambient=1
3, 6 1 °C = 1 / 1 °F = 1
3, 6 1 °C = 1 / 1 °F = 1
3, 6 1 °C = 1 / 1 °F = 1
3, 6 1 °C = 1 / 1 °F = 1
3, 6 1 °C = 1 / 1 °F = 1
3, 6 Off=0;On=1
3, 6 1.000 pu = 1000
DT=0;IEC=1;
3, 6
IEEE=2;IEEE2=3; Others=4;Prg1=5;
Prg2=6;Prg3=7
DT=0;NI=1;VI=2;
EI=3;LTI=4;LTEI=
3, 6
5;LTVI=6;MI=7; STI=8;STEI=9;
CO8=10;RI=11;
RXIDG=12
3, 6 1.00 s = 100
3, 6 1.000 = 1000
3, 6 Res=0;Cap=1
3, 6 1.00 s = 100 3, 6 Off=0;On=1
3, 6 Off=0;On=1
3, 6 1.00 s = 100
3, 6 1.000 = 1000 3, 6 Off=0;On=1
3, 6 1.00 xIn = 100
3, 6 1.00 s = 100
3, 6 1.000 = 1000 3, 6 DT=0;IDMT=1
3, 6 Off=0;On=1
Setting for Scalling
P5 U20 P5 P5 P5 P5 LPCT U20 V20 F30 M30 LPVT
126
P5/EN M/33A
Communication protocols
Add.
Name
Read Write
6328
Phase currents change limit
Io>> setting
6331
6332... 6335
Enable for Io>> Pick-up value
1
1
1
1
1
1
6336... 6339
Delay curve family
1
1
6340... 6343
Delay type
1
1
6344... 6347
Operation delay
1
1
6348... 6351
Inv. time coefficient
1
1
6352... 6355
Network earthing
1
1
6356... Inrush status for 6359 Io>>
1
1
6360... 6363
SOL use for Io>>
1
1
6364... SOL Operation 6367 delay
1
1
6368... SOL Inv. time 6371 coefficient
1
1
6372... CLPU status for 6375 Io>>
1
1
6376... 6379
CLPU Pick-up value
1
1
6380... CLPU Operation 6383 delay
1
1
6384... CLPU Inv. time 6387 coefficient
1
1
6388... 6391
Reset type
1
1
6392... 6395
Reset time
1
1
6396
Enable faulty phase detection
1
1
6397
Phase currents change limit
1
1
Io>>> setting
6401 Enable for Io>>>
1
1
6402... 6405
Pick-up value
1
1
6406... 6409
Operation delay
1
1
6410... 6413
Network earthing
1
1
6414... Inrush status for 6417 Io>>>
1
1
FC
Scalling
3, 6 1 % = 1
3, 6 Off=0;On=1
3, 6 1.00 pu = 100
DT=0;IEC=1;
3, 6
IEEE=2;IEEE2=3; Others=4;Prg1=5;
Prg2=6;Prg3=7
DT=0;NI=1;VI=2;
EI=3;LTI=4;LTEI=
3, 6
5;LTVI=6;MI=7; STI=8;STEI=9;
CO8=10;RI=11;
RXIDG=12
3, 6 1.00 s = 100
3, 6 1.000 = 1000
3, 6 Res=0;Cap=1
3, 6 Off=0;On=1
3, 6 Off=0;On=1
3, 6 1.00 s = 100
3, 6 1.000 = 1000 3, 6 Off=0;On=1
3, 6 1.00 xIn = 100
3, 6 1.00 s = 100
3, 6 1.000 = 1000 3, 6 DT=0;IDMT=1
3, 6 1.00 s = 100
3, 6 Off=0;On=1
3, 6 1 % = 1
3, 6 Off=0;On=1 3, 6 1.00 pu = 100 3, 6 1.00 s = 100 3, 6 Res=0;Cap=1 3, 6 Off=0;On=1
Setting for Scalling
P5 U20 P5 P5 P5 P5 LPCT U20 V20 F30 M30 LPVT
P5/EN M/33A
127
Communication protocols
Add.
Name
Read Write
6418... 6421
SOL use for Io>>>
1
1
6422... SOL Operation 6425 delay
1
1
6426... CLPU status for 6429 Io>>>
1
1
6430... 6433
CLPU Pick-up value
1
1
6434... CLPU Operation 6437 delay
1
1
6438
Enable faulty phase detection
1
1
6439
Phase currents change limit
1
1
Io>>>> setting
6451 Enable for Io>>>>
1
1
6452... 6455
Pick-up value
1
1
6456... 6459
Operation delay
1
1
6460... 6463
Network earthing
1
1
6464... Inrush status for 6467 Io>>>>
1
1
6468... 6471
SOL use for Io>>>>
1
1
6472... SOL Operation 6475 delay
1
1
6476... CLPU status for 6479 Io>>>>
1
1
6480... 6483
CLPU Pick-up value
1
1
6484... CLPU Operation 6487 delay
1
1
6488
Enable faulty phase detection
1
1
6489
Phase currents change limit
1
1
Io>>>>> setting
6501 Enable for Io>>>>>
1
1
6502... 6505
Pick-up value
6506... 6509
Operation delay
Io> setting
1
1
1
1
6551 Enable for Io>
1
1
6552... 6555
Direction mode
1
1
6556... Char ctrl. in ResCap 6559 mode
1
1
FC
Scalling
3, 6 Off=0;On=1 3, 6 1.00 s = 100 3, 6 Off=0;On=1 3, 6 1.00 xIn = 100 3, 6 1.00 s = 100 3, 6 Off=0;On=1 3, 6 1 % = 1
3, 6 Off=0;On=1 3, 6 1.00 pu = 100 3, 6 1.00 s = 100 3, 6 Res=0;Cap=1 3, 6 Off=0;On=1 3, 6 Off=0;On=1 3, 6 1.00 s = 100 3, 6 Off=0;On=1 3, 6 1.00 xIn = 100 3, 6 1.00 s = 100 3, 6 Off=0;On=1 3, 6 1 % = 1
3, 6 Off=0;On=1 3, 6 1.00 pu = 100 3, 6 1.00 s = 100
3, 6 Off=0;On=1
3, 6
ResCap=0; Sector=1;Undir=2
Res=0;Cap=1;
DI1=2;DI2=3;...;
DI19=20;DI20=
3, 6
21;Arc1=26; Arc2=27;BI=28;
VI1=30;VI2=31;
VI3=32;VI4=33;
DI21=66;DI22=
Setting for Scalling
P5 U20 P5 P5 P5 P5 LPCT U20 V20 F30 M30 LPVT
128
P5/EN M/33A
Communication protocols
Add.
Name
Read Write
6560... 6563
Pick-up value
1
1
6564... Uo setting for Io> 6567 stage
1
1
6568... 6571
Angle offset
1
1
6572... 6575
Pick up sector size
1
1
6576... 6579
Delay curve family
1
1
6580... 6583
Delay type
1
1
6584... 6587
Operation delay
1
1
6588... 6591
Inv. time coefficient
1
1
6592... 6595
Reset type
1
1
6596... 6599
Reset time
1
1
Io>> setting
6601 Enable for Io>>
1
1
6602... 6605
Direction mode
1
1
6606... Char ctrl. in ResCap 6609 mode
1
1
6610... 6613
Pick-up value
1
1
6614... Uo setting for Io>> 6617 stage
1
1
6618... 6621
Angle offset
1
1
6622... 6625
Pick up sector size
1
1
6626... 6629
Delay curve family
1
1
6630... 6633
Delay type
6634... 6637
Operation delay
1
1
1
1
FC
Scalling
67;...;DI31=76; DI32=77
3, 6 1.000 pu = 1000
3, 6 1.0 % = 10
3, 6 1 ° = 1
3, 6 1 ±° = 1
DT=0;IEC=1;
3, 6
IEEE=2;IEEE2=3; Others=4;Prg1=5;
Prg2=6;Prg3=7
DT=0;NI=1;VI=2;
EI=3;LTI=4;LTEI=
3, 6
5;LTVI=6;MI=7; STI=8;STEI=9;
CO8=10;RI=11;
RXIDG=12
3, 6 1.00 s = 100
3, 6 1.000 = 1000
3, 6 DT=0;IDMT=1
3, 6 1.00 s = 100
3, 6 Off=0;On=1
3, 6
ResCap=0; Sector=1;Undir=2
Res=0;Cap=1;
DI1=2;DI2=3;...;
DI19=20;DI20=
21;Arc1=26;
3, 6
Arc2=27;BI=28; VI1=30;VI2=31;
VI3=32;VI4=33;
DI21=66;DI22=
67;...;DI31=76;
DI32=77
3, 6 1.000 pu = 1000
3, 6 1.0 % = 10
3, 6 1 ° = 1
3, 6 1 ±° = 1
DT=0;IEC=1;
3, 6
IEEE=2;IEEE2=3; Others=4;Prg1=5;
Prg2=6;Prg3=7
DT=0;NI=1;VI=2;
EI=3;LTI=4;LTEI=
3, 6
5;LTVI=6;MI=7; STI=8;STEI=9;
CO8=10;RI=11;
RXIDG=12
3, 6 1.00 s = 100
Setting for Scalling
P5 U20 P5 P5 P5 P5 LPCT U20 V20 F30 M30 LPVT
P5/EN M/33A
129
Communication protocols
Add.
Name
Read Write
6638... 6641
Inv. time coefficient
1
1
6642... 6645
Reset type
1
1
6646... 6649
Reset time
1
1
Io>>> setting
6651 Enable for Io>>>
1
1
6652... 6655
Direction mode
1
1
6656... Char ctrl. in ResCap 6659 mode
1
1
6660... 6663
Pick-up value
1
1
6664... Uo setting for 6667 Io>>> stage
1
1
6668... 6671
Angle offset
1
1
6672... 6675
Pick up sector size
1
1
6676... 6679
Delay curve family
1
1
6680... 6683
Delay type
1
1
6684... 6687
Operation delay
1
1
6688... 6691
Inv. time coefficient
1
1
6692... 6695
Reset type
1
1
6696... 6699
Reset time
1
1
IoUo> setting
6701 Enable for IoUo>
1
1
6702... 6705
Direction mode
1
1
6706... 6709
Inhibit ctrl.
1
1
FC
Scalling
3, 6 1.000 = 1000 3, 6 DT=0;IDMT=1 3, 6 1.00 s = 100
3, 6 Off=0;On=1
3, 6
ResCap=0; Sector=1;Undir=2
Res=0;Cap=1;
DI1=2;DI2=3;...;
DI19=20;DI20=
21;Arc1=26;
3, 6
Arc2=27;BI=28; VI1=30;VI2=31;
VI3=32;VI4=33;
DI21=66;DI22=
67;...;DI31=76;
DI32=77
3, 6 1.000 pu = 1000
3, 6 1.0 % = 10
3, 6 1 ° = 1
3, 6 1 ±° = 1
DT=0;IEC=1;
3, 6
IEEE=2;IEEE2=3; Others=4;Prg1=5;
Prg2=6;Prg3=7
DT=0;NI=1;VI=2;
EI=3;LTI=4;LTEI=
3, 6
5;LTVI=6;MI=7; STI=8;STEI=9;
CO8=10;RI=11;
RXIDG=12
3, 6 1.00 s = 100
3, 6 1.000 = 1000 3, 6 DT=0;IDMT=1
3, 6 1.00 s = 100
3, 6 Off=0;On=1
3, 6
Forward=0; Reverse=1
DI1=1;DI2=2;...;
DI19=19;DI20=
20;Arc1=25;
Arc2=26;BI=27;
VI1=29;VI2=30;
3, 6
VI3=31;VI4=32; DI21=65;DI22=
66;...;DI39=83;
DI40=84;VI5=
225;VI6=226;...;
VI19=239;VI20=
240
Setting for Scalling
P5 U20 P5 P5 P5 P5 LPCT U20 V20 F30 M30 LPVT
130
P5/EN M/33A
Communication protocols
Add.
Name
Read Write
6710... Timer instant delay 6713 ctrl.
1
1
6714... 6717
Pick-up value
1
1
6718... 6721
Uo pick-up value
1
1
6722... 6725
Pick-up sector size
1
1
6726... 6729
Operation delay
1
1
6730... 6733
SOL Mode
1
1
6734... SOL Operation 6737 delay
1
1
6738... 6741
Memory Mode
6742... 6745
Uo pick-up value
6746... 6749
Memory time
6750 Reset time
IoUo>> setting
1
1
1
1
1
1
1
1
6751 Enable for IoUo>>
1
1
6752... 6755
Direction mode
1
1
6756... Input for inhibit 6759 control
1
1
6760... Timer instant delay 6763 ctrl.
1
1
6764... 6767
Pick-up value
1
1
6768... 6771
Uo pick-up value
1
1
6772... 6775
Pick up sector size
1
1
6776... 6779
Operation delay
1
1
P5
FC
Scalling
Setting for Scalling
U20 P5 P5 P5 P5 LPCT U20 V20 F30 M30
LPVT
DI1=1;DI2=2;...; DI19=19;DI20= 20;Arc1=25; Arc2=26;BI=27; 3, 6 VI1=29;VI2=30; VI3=31;VI4=32; DI21=65;DI22= 66;...;DI31=75; DI32=76
3, 6
1.00 %Pno = 100
Pick-up value scaling
3, 6 1.0 % = 10
3, 6 1 ±° = 1
3, 6 1.00 s = 100
3, 6 Off=0;On=1
3, 6 1.00 s = 100
3, 6
None=0;Voltage= 1;Time=2;Both=3
3, 6 1.0 % = 10
3, 6 1.00 s = 100 3, 6 1.00 s = 100
3, 6 Off=0;On=1
3, 6
Forward=0; Reverse=1
DI1=1;DI2=2;...;
DI19=19;DI20=
20;Arc1=25;
Arc2=26;BI=27;
VI1=29;VI2=30;
3, 6
VI3=31;VI4=32; DI21=65;DI22=
66;...;DI39=83;
DI40=84;VI5=
225;VI6=226;...;
VI19=239;VI20=
240
DI1=1;DI2=2;...;
DI19=19;DI20=
20;Arc1=25;
Arc2=26;BI=27;
VI1=29;VI2=30;
3, 6
VI3=31;VI4=32; DI21=65;DI22=
66;...;DI39=83;
DI40=84;VI5=
225;VI6=226;...;
VI19=239;VI20=
240
3, 6
1.00 %Pno = 100
Pick-up value scaling
3, 6 1.0 % = 10
3, 6 1 ±° = 1
3, 6 1.00 s = 100
P5/EN M/33A
131
Communication protocols
Add.
Name
6780... 6783
6784... 6787
SOL Mode
SOL Operation delay
6788... 6791
Memory Mode
6792... 6795
Uo memory value
6796... 6799
Memory time
6800 Reset time
U> setting
6801 Enable for U>
6802... 6805
Pick-up value
6806... 6809
Operation delay
6810 Reset time
6811 Hysteresis
U>> setting
6851
6852... 6855
6856... 6859
6860
Enable for U>> Pick-up value Operation delay Hysteresis
U>>> setting
6901 Enable for U>>>
6902... 6905
Pick-up value
6906... 6909
Operation delay
6910 Hysteresis
U< setting
6951 Enable for U<
6952... 6955
Pick-up value
6956... 6959
Operation delay
6960 Reset time
6961 Hysteresis
U<< setting
7001 Enable for U<<
7002... 7005
Pick-up value
7006... 7009
Operation delay
7010 Hysteresis
U<<< setting
Read Write FC
Scalling
1
1
3, 6 Off=0;On=1
Setting for Scalling
P5 U20 P5 P5 P5 P5 LPCT U20 V20 F30 M30 LPVT
1
1
3, 6 1.00 s = 100
1
1
3, 6
None=0;Voltage= 1;Time=2;Both=3
1
1
3, 6 1.0 % = 10
1
1
3, 6 1.00 s = 100
1
1
3, 6 1.00 s = 100
1
1
3, 6 Off=0;On=1
1
1
3, 6 1.0 %Un = 10
1
1
3, 6 1.00 s = 100
1
1
3, 6 1.00 s = 100
1
1
3, 6 1.0 % = 10
1
1
3, 6 Off=0;On=1
1
1
3, 6 1.0 %Un = 10
1
1
3, 6 1.00 s = 100
1
1
3, 6 1.0 % = 10
1
1
3, 6 Off=0;On=1
1
1
3, 6 1.0 %Un = 10
1
1
3, 6 1.00 s = 100
1
1
3, 6 1.0 % = 10
1
1
3, 6 Off=0;On=1
1
1
3, 6 1.0 %Un = 10
1
1
3, 6 1.00 s = 100
1
1
3, 6 1.00 s = 100
1
1
3, 6 1.0 % = 10
1
1
3, 6 Off=0;On=1
1
1
3, 6 1.0 %Un = 10
1
1
3, 6 1.00 s = 100
1
1
3, 6 1.0 % = 10
132
P5/EN M/33A
Communication protocols
Add.
Name
Read Write FC
Scalling
7051 Enable for U<<<
1
7052... 7055
Pick-up value
1
7056... 7059
Operation delay
1
7060 Hysteresis
1
U1< setting
7101 Enable for U1<
1
7102... 7105
Pick-up value
1
7106... 7109
Operation delay
1
7110
Low voltage blocking
1
U1<< setting
7151 Enable for U1<<
1
7152... 7155
Pick-up value
1
7156... 7159
Operation delay
1
7160
Low voltage blocking
1
Uo> setting
7201 Enable for Uo>
1
7202... 7205
Pick-up value
1
7206... 7209
Operation delay
1
7210... 7213
Reset time
1
Uo>> setting
7251 Enable for Uo>>
1
7252... 7255
Pick-up value
1
7256... 7259
Operation delay
1
7260... 7263
Reset time
1
Uo>>> setting
7301 Enable for Uo>>>
1
7302... 7305
Pick-up value
1
7306... 7309
Operation delay
1
7310... 7313
Reset time
1
fX setting
7351 Enable for fX
1
7352... 7355
Pick-up value
1
7356... 7359
Operation delay
1
1
3, 6 Off=0;On=1
1
3, 6 1.0 %Un = 10
1
3, 6 1.00 s = 100
1
3, 6 1.0 % = 10
1
3, 6 Off=0;On=1
1
3, 6 1 %Vn = 1
1
3, 6 1.00 s = 100
1
3, 6 1.0 %Un = 10
1
3, 6 Off=0;On=1
1
3, 6 1 %Vn = 1
1
3, 6 1.00 s = 100
1
3, 6 1.0 %Un = 10
1
3, 6 Off=0;On=1
1
3, 6 1 % = 1
1
3, 6 1.00 s = 100
1
3, 6 1.00 s = 100
1
3, 6 Off=0;On=1
1
3, 6 1 % = 1
1
3, 6 1.00 s = 100
1
3, 6 1.00 s = 100
1
3, 6 Off=0;On=1
1
3, 6 1 % = 1
1
3, 6 1.00 s = 100
1
3, 6 1.00 s = 100
1
3, 6 Off=0;On=1
1
3, 6 50.00 Hz = 5000
1
3, 6 1.00 s = 100
Setting for Scalling
P5 U20 P5 P5 P5 P5 LPCT U20 V20 F30 M30 LPVT
P5/EN M/33A
133
Communication protocols
Add.
Name
Read Write FC
Scalling
7360
Low voltage blocking
1
fXX setting
7401 Enable for fXX
1
7402... 7405
Pick-up value
1
7406... 7409
Operation delay
1
7410
Low voltage blocking
1
f< setting
7451 Enable for f<
1
7452... 7455
Pick-up value
1
7456... 7459
Operation delay
1
7460
Low voltage blocking
1
f<< setting
7501 Enable for f<<
1
7502... 7505
Pick-up value
1
7506... 7509
Operation delay
1
7510
Low voltage blocking
1
CBFail setting
7551 Enable for CB fail
1
7552 Enable CBF timer1
1
7553
Timer1 Operation Delay
1
7554 Enable CBF timer2
1
7555
Timer2 Operation Delay
1
7556
Noncurrent CBF reset mode
1
7557
Ext. CBF reset mode
1
7558 I< current set
1
7559 Io< current set
1
7560 Io'< current set
1
Ih5> setting
7651 Enable for Ih5>
1
7652 Pick-up value
1
7653 Operation delay
1
CT setting
7701
Enable for CT supervision
1
1
3, 6 1.0 %Un = 10
1
3, 6 Off=0;On=1
1
3, 6 50.00 Hz = 5000
1
3, 6 1.00 s = 100
1
3, 6 1.0 %Un = 10
1
3, 6 Off=0;On=1
1
3, 6 50.00 Hz = 5000
1
3, 6 1.00 s = 100
1
3, 6 1.0 %Un = 10
1
3, 6 Off=0;On=1
1
3, 6 50.00 Hz = 5000
1
3, 6 1.00 s = 100
1
3, 6 1.0 %Un = 10
1
3, 6 Off=0;On=1
1
3, 6 Off=0;On=1
1
3, 6 1.00 s = 100
1
3, 6 Off=0;On=1
1
3, 6 1.00 s = 100
I<Only=0;
1
3, 6 PoleDead=1;
ProtRst=2
I<Only=0;
1
3, 6 PoleDead=1;
ProtRst=2
1
3, 6 1.00 xIn = 100
1
3, 6 1.000 pu = 1000
1
3, 6 1.000 pu = 1000
1
3, 6 Off=0;On=1
1
3, 6 1 % = 1
1
3, 6 1.00 s = 100
1
3, 6 Off=0;On=1
Setting for Scalling
P5 U20 P5 P5 P5 P5 LPCT U20 V20 F30 M30 LPVT
134
P5/EN M/33A
Communication protocols
Add.
Name
Read Write
7702 CTS Operate mode
1
1
7703 7704
CTS reset input Operation delay
1
1
1
1
7721 Residual current >
1
1
7722 Residual voltage <
1
1
VT setting
7751 7752 7753
Enable for VTS U2> setting I2< setting
1
1
1
1
1
1
7754 Operation delay
1
1
7755 VTS output reset
1
1
DI for MCB position 7756
1
1
Io'> setting
7761
7762... 7765
Enable for Io'> Pick-up value
1
1
1
1
7766... 7769
Delay curve family
1
1
7770... 7773
Delay type
1
1
7774... 7777
Operation delay
1
1
7778... 7781
Inv. time coefficient
1
1
7782... 7785
Network grounding
1
1
7786... 7789
Reset time
1
1
7791... Inrush status for 7794 Io'>
1
1
7795... 7798
SOL status for Io'>
1
1
7799... SOL Operation 7802 delay
1
1
7803... SOL Inv. time 7806 coefficient
1
1
FC
Scalling
3, 6
3I only=0;I0&U0= 1;Both=2
3, 6 Value 17
3, 6 1.00 s = 100
3, 6 1.00 xIn = 100
3, 6 1.0 %Un = 10
Setting for Scalling
P5 U20 P5 P5 P5 P5 LPCT U20 V20 F30 M30 LPVT
3, 6 Off=0;On=1
3, 6 1.0 %Vn = 10
3, 6 1.00 xIn = 100
3, 6 1.00 s = 100
Operate delay scaling
3, 6 Value 18
3, 6
DI1=1;DI2=2;...; DI39=39;DI40=40
3, 6 Off=0;On=1
3, 6 1.000 pu = 1000
DT=0;IEC=1;
3, 6
IEEE=2;IEEE2=3; Others=4;Prg1=5;
Prg2=6;Prg3=7
DT=0;NI=1;VI=2;
EI=3;LTI=4;LTEI=
3, 6
5;LTVI=6;MI=7; STI=8;STEI=9;
CO8=10;RI=11;
RXIDG=12
3, 6 1.00 s = 100
3, 6 1.000 = 1000
3, 6 Res=0;Cap=1
3, 6 1.00 s = 100 3, 6 Off=0;On=1
3, 6 Off=0;On=1
3, 6 1.00 s = 100
3, 6 1.000 = 1000
17. DI1=1;DI2=2;...;DI19=19;DI20=20;Arc1=25;Arc2=26;BI=27;VI1=29;VI2=30;VI3=31;VI4=32;DO1(B)=33;DO2(B)=34;DO3(B)=35; Watchdog=36;SF=37;SF=38;SF=39;SF=40;SF=41;BO=42;DO1(C)=43;DO2(C)=44;DO3(C)=45;DO4(C)=46;LedAl=49;LedTr=50;LedA= 51;LedB=52;LedC=53;LedDR=54;VO1=55;VO2=56;...;VO5=59;VO6=60;DI21=65;DI22=66;...;DI39=83;DI40=84;F1=85;F2=86;...;F6= 90;F7=91;DO1(D)=97;DO2(D)=98;DO3(D)=99;SF=100;DO1(E)=101;DO2(E)=102;NI1=129;NI2=130;...;NI63=191;NI64=192;POC1= 193;POC2=194;...;POC15=207;POC16=208;VI5=225;VI6=226;...;VI19=239;VI20=240;VO7=257;VO8=258;...;VO19=269;VO20=270; NI65=289;NI66=290;...;NI127=351;NI128=352
18. DI1=1;DI2=2;...;DI19=19;DI20=20;Arc1=25;Arc2=26;BI=27;VI1=29;VI2=30;VI3=31;VI4=32;DO1(B)=33;DO2(B)=34;DO3(B)=35; Watchdog=36;SF=37;SF=38;SF=39;SF=40;SF=41;BO=42;DO1(C)=43;DO2(C)=44;DO3(C)=45;DO4(C)=46;LedAl=49;LedTr=50;LedA= 51;LedB=52;LedC=53;LedDR=54;VO1=55;VO2=56;...;VO5=59;VO6=60;DI21=65;DI22=66;...;DI39=83;DI40=84;F1=85;F2=86;...;F6= 90;F7=91;DO1(D)=97;DO2(D)=98;DO3(D)=99;SF=100;DO1(E)=101;DO2(E)=102;NI1=129;NI2=130;...;NI127=351;NI128=352
P5/EN M/33A
135
Communication protocols
Add.
Name
Read Write
7807... 7810
CLPU status for Io'>
1
1
7811... 7814
CLPU Pick-up value
1
1
7815... CLPU Operation 7818 delay
1
1
7819... CLPU Inv. time 7822 coefficient
1
1
7823... 7826
Reset type
1
1
7827
Enable faulty phase detection
1
1
7828
Phase currents change limit
1
1
Io'>> setting
7831
7832... 7835
Enable for Io'>> Pick-up value
1
1
1
1
7836... 7839
Delay curve family
1
1
7840... 7843
Delay type
1
1
7844... 7847
Operation delay
1
1
7848... 7851
Inv. time coefficient
1
1
7852... 7855
Network earthing
1
1
7856... Inrush status for 7859 Io'>>
1
1
7860... 7863
SOL status for Io'>>
1
1
7864... SOL Operation 7867 delay
1
1
7868... SOL Inv. time 7871 coefficient
1
1
7872... CLPU status for 7875 Io'>>
1
1
7876... 7879
CLPU Pick-up value
1
1
7880... CLPU Operation 7883 delay
1
1
7884... CLPU Inv. time 7887 coefficient
1
1
7888... 7891
Reset type
1
1
7892... 7895
Reset time
1
1
7896
Enable faulty phase detection
1
1
7897
Phase currents change limit
1
1
FC
Scalling
3, 6 Off=0;On=1 3, 6 1.00 xIn = 100 3, 6 1.00 s = 100 3, 6 1.000 = 1000 3, 6 DT=0;IDMT=1 3, 6 Off=0;On=1 3, 6 1 % = 1
3, 6 Off=0;On=1
3, 6 1.000 pu = 1000
DT=0;IEC=1;
3, 6
IEEE=2;IEEE2=3; Others=4;Prg1=5;
Prg2=6;Prg3=7
DT=0;NI=1;VI=2;
EI=3;LTI=4;LTEI=
3, 6
5;LTVI=6;MI=7; STI=8;STEI=9;
CO8=10;RI=11;
RXIDG=12
3, 6 1.00 s = 100
3, 6 1.000 = 1000
3, 6 Res=0;Cap=1
3, 6 Off=0;On=1
3, 6 Off=0;On=1
3, 6 1.00 s = 100
3, 6 1.000 = 1000 3, 6 Off=0;On=1
3, 6 1.00 xIn = 100
3, 6 1.00 s = 100
3, 6 1.000 = 1000 3, 6 DT=0;IDMT=1
3, 6 1.00 s = 100
3, 6 Off=0;On=1
3, 6 1 % = 1
Setting for Scalling
P5 U20 P5 P5 P5 P5 LPCT U20 V20 F30 M30 LPVT
136
P5/EN M/33A
Communication protocols
Add.
Name
Read Write
Io'>>> setting
7901 Enable for Io'>>>
1
1
7902... 7905
Pick-up value
1
1
7906... 7909
Operation delay
1
1
7910... 7913
Network grounding
1
1
7914... Inrush status for 7917 Io'>>>
1
1
7918... SOL status for 7921 Io'>>>
1
1
7922... SOL Operation 7925 delay
1
1
7926... CLPU status for 7929 Io'>>>
1
1
7930... 7933
CLPU Pick-up value
1
1
7934... CLPU Operation 7937 delay
1
1
7938
Enable faulty phase detection
1
1
7939
Phase currents change limit
1
1
Uc> setting
7951 Enable for Uc>
7952... 7955
Pick-up value
7956... 7959
Operation delay
df/dt> setting
1
1
1
1
1
1
8001 Enable for df/dt>
1
1
8002... 8005
Direction of change
1
1
8006... 8009
8010... 8013
8014
Pick-up value
Operation delay
Low voltage blocking
1
1
1
1
1
1
df/dt>> setting
8051 Enable for df/dt>>
1
1
8052... 8055
Direction of change
1
1
8056... 8059
Pick-up value
8060... 8063
Operation delay
8064
Low voltage blocking
IoInt> setting
1
1
1
1
1
1
FC
Scalling
3, 6 Off=0;On=1 3, 6 1.000 pu = 1000 3, 6 1.00 s = 100 3, 6 Res=0;Cap=1 3, 6 Off=0;On=1 3, 6 Off=0;On=1 3, 6 1.00 s = 100 3, 6 Off=0;On=1 3, 6 1.00 xIn = 100 3, 6 1.00 s = 100 3, 6 Off=0;On=1 3, 6 1 % = 1
3, 6 Off=0;On=1 3, 6 1.00 xUcLN = 100 3, 6 1.0 s = 10
3, 6 Off=0;On=1 Negative=0;
3, 6 Positive=1; Either=2
3, 6 1.0 Hz/s = 10 3, 6 1.00 s = 100 3, 6 1.0 %Un = 10
3, 6 Off=0;On=1 Negative=0;
3, 6 Positive=1; Either=2
3, 6 1.0 Hz/s = 10 3, 6 1.00 s = 100 3, 6 1.0 %Un = 10
Setting for Scalling
P5 U20 P5 P5 P5 P5 LPCT U20 V20 F30 M30 LPVT
P5/EN M/33A
137
Communication protocols
Add.
Name
Read Write
8101 Enable for IoInt>
1
1
8102... 8105
8106... 8109
8110... 8113
8114... 8117
Direction mode
Uo pick-up value
Operation delay Min number of peaks
1
1
1
1
1
1
1
1
8118... 8121
Reset delay
1
1
8122 Intermittent time
1
1
Feeder Fault Locator setting
8152 Pick-up value
1
1
8153
Triggering digital input
1
1
8154 Line reactance/unit
1
1
8155 Earth factor
1
1
8156 Earth factor angle
1
1
8157 Event enabling
1
1
8158 8159
Average voltage limit
Io limit
1
1
1
1
8160 DI timeout
1
1
8161 Release timeout
1
1
Synchro-check 1 setting
8201
Enable for Synchro check 1
1
1
8202 CB object 1
1
1
8203 CB object 2
1
1
8204
Input for selecting Object2
1
1
8205
Inhibit closing unselected CB
1
1
8206
Synchronization mode
1
1
8207
Voltage check mode
1
1
FC
Scalling
3, 6 Off=0;On=1
3, 6
Forward=0; Reverse=1
3, 6 1 % = 1
3, 6 1.00 s = 100
3, 6 1 = 1
3, 6 1.00 s = 100 3, 6 1.00 s = 100
3, 6 1.00 xIn = 100
3, 6 Value 19 3, 6 1.000 ohm = 1000 3, 6 1.000 = 1000 3, 6 1 ° = 1 3, 6 Off=0;On=1 3, 6 1.0 %Un = 10 3, 6 1.00 xIn = 100 3, 6 1.00 s = 100 3, 6 1.00 s = 100
3, 6 Off=0;On=1
Object 1=1;Object
3, 6
2=2;Object 3=3; Object 4=4;Object
5=5;Object 6=6
Object 1=1;Object
3, 6
2=2;Object 3=3; Object 4=4;Object
5=5;Object 6=6
3, 6 Value 19
3, 6 Off=0;On=1
3, 6
Off=0;Async=1; Sync=2
DD=1;DL=2;LD=
3, 6
3;DD/DL=4;DD/ LD=5;DL/LD=6;
DD/DL/LD=7
Setting for Scalling
P5 U20 P5 P5 P5 P5 LPCT U20 V20 F30 M30 LPVT
19. DI1=1;DI2=2;...;DI19=19;DI20=20;Arc1=25;Arc2=26;BI=27;VI1=29;VI2=30;VI3=31;VI4=32;DO1(B)=33;DO2(B)=34;DO3(B)=35; Watchdog=36;SF=37;SF=38;SF=39;SF=40;SF=41;BO=42;DO1(C)=43;DO2(C)=44;DO3(C)=45;DO4(C)=46;LedAl=49;LedTr=50;LedA= 51;LedB=52;LedC=53;LedDR=54;VO1=55;VO2=56;...;VO5=59;VO6=60;DI21=65;DI22=66;...;DI39=83;DI40=84;F1=85;F2=86;...;F6= 90;F7=91;DO1(D)=97;DO2(D)=98;DO3(D)=99;SF=100;DO1(E)=101;DO2(E)=102;NI1=129;NI2=130;...;NI127=351;NI128=352
138
P5/EN M/33A
Communication protocols
Add.
Name
Read Write
8208 CB closing time
1
1
8209 8210 8211
Bypass DI Bypass Ok pulse length
1
1
1
1
1
1
8212... 8215
Udead limit setting
1
1
8216... 8219
Ulive limit setting
1
1
8220... Frequency 8223 difference
1
1
8224... 8227
Voltage difference
1
1
8228... Phase angle 8231 difference
1
1
8232... 8235
Request timeout
1
1
CB Monitoring setting
8251
Enable for CB monitoring
1
1
8252... 8253
Alarm level
1
1
8254... Limit for operation 8255 left
1
1
8261... High limit (primary 8264 value)
1
1
Motor status setting
8301 Motor status
1
1
8302
Nom motor start current
1
1
8303
Motor start detection current
1
1
8304
Motor start detection mode
1
1
8305
Enable motor speed detection
1
1
8306
Motor speed input DI
1
1
8307
Rated motor speed n
1
1
8308 Pulse per rotation
1
1
8309
Zero speed confirm time
1
1
SOL setting
8351 Enable for SOL
1
1
8352 SOL signal number
1
1
FC
Scalling
3, 6 1.00 s = 100 3, 6 Value 20 3, 6 1 = 1 3, 6 1 ms = 1 3, 6 1.0 %Un = 10 3, 6 1.0 %Un = 10 3, 6 50.00 Hz = 5000 3, 6 1.0 %Un = 10 3, 6 1 ° = 1 3, 6 1.0 s = 10
Setting for Scalling
P5 U20 P5 P5 P5 P5 LPCT U20 V20 F30 M30 LPVT
3, 6 Off=0;On=1
3, 6 1.00 kA = 100
3, 6 1000 = 1000
Limit for oper. left scaling
3, 6 1.0 kA = 10
3, 6 Off=0;On=1
3, 6 1.00 xIn = 100
3, 6 1.00 xIn = 100
CB Position=0; 3, 6 Current=1;
CB&Current=2
3, 6 Off=0;On=1
Slot C DI1=0;Slot 3, 6 D DI1=1;Slot E
DI1=2
3, 6 1 rpm = 1
3, 6 1 = 1
3, 6 1 s = 1
3, 6 off=0;On=1 3, 6 1=0;2=1
20. DI1=1;DI2=2;...;DI19=19;DI20=20;Arc1=25;Arc2=26;BI=27;VI1=29;VI2=30;VI3=31;VI4=32;DO1(B)=33;DO2(B)=34;DO3(B)=35; Watchdog=36;SF=37;SF=38;SF=39;SF=40;SF=41;BO=42;DO1(C)=43;DO2(C)=44;DO3(C)=45;DO4(C)=46;LedAl=49;LedTr=50;LedA= 51;LedB=52;LedC=53;LedDR=54;VO1=55;VO2=56;...;VO5=59;VO6=60;DI21=65;DI22=66;...;DI39=83;DI40=84;F1=85;F2=86;...;F6= 90;F7=91;DO1(D)=97;DO2(D)=98;DO3(D)=99;SF=100;DO1(E)=101;DO2(E)=102;NI1=129;NI2=130;...;NI63=191;NI64=192;POC1= 193;POC2=194;...;POC15=207;POC16=208;VI5=225;VI6=226;...;VI19=239;VI20=240;VO7=257;VO8=258;...;VO19=269;VO20=270; NI65=289;NI66=290;...;NI127=351;NI128=352
P5/EN M/33A
139
Communication protocols
Add.
Name
8353
CB Trip Clearing time
Admittance E/F Io/Uo> setting
8361 Enable for Io/Uo>
8362 Io input
8363... 8366
8367... 8370
Uo pick-up value Correction angle
Admittance E/F Io/Uo> YN>
8371 Enable for YN>
8373... 8376
Pick-up value
8377... Input for inhibit 8380 control
8381... 8384
Operation delay
8385... 8388
8389... 8392
Reset time SOL Mode
8393... SOL Operation 8396 delay
Admittance E/F Io/Uo> GN>
8411 Enable for GN>
8413... 8416
Pick-up value
8417... Input for inhibit 8420 control
8421... 8424
Direction mode
8425... 8428
8429... 8432
8433... 8436
8437... 8440
Operation delay
Reset time
SOL Mode SOL Operation delay
Read Write
1
1
1
1
1
1
1
1
1
1
1
1
1
1
1
1
1
1
1
1
1
1
1
1
1
1
1
1
1
1
1
1
1
1
1
1
1
1
1
1
FC
Scalling
3, 6 1.00 s = 100
3, 6 Off=0;On=1
3, 6
Io=0;Io CSH=1; Iocalc=2;Io'=3
3, 6 1.0 % = 10
3, 6 1 ° = 1
3, 6 Off=0;On=1
3, 6 1.0 Yn% = 10
DI1=1;DI2=2;...;
DI19=19;DI20=
20;Arc1=25;
Arc2=26;BI=27;
VI1=29;VI2=30;
3, 6
VI3=31;VI4=32; DI21=65;DI22=
66;...;DI39=83;
DI40=84;VI5=
225;VI6=226;...;
VI19=239;VI20=
240
3, 6 1.00 s = 100
3, 6 1.00 s = 100 3, 6 Off=0;On=1
3, 6 1.00 s = 100
3, 6 Off=0;On=1
3, 6 1.0 Gn% = 10
DI1=1;DI2=2;...;
DI19=19;DI20=
20;Arc1=25;
Arc2=26;BI=27;
VI1=29;VI2=30;
3, 6
VI3=31;VI4=32; DI21=65;DI22=
66;...;DI39=83;
DI40=84;VI5=
225;VI6=226;...;
VI19=239;VI20=
240
Undir=0; 3, 6 Forward=1;
Reverse=2
3, 6 1.00 s = 100
3, 6 1.00 s = 100
3, 6 Off=0;On=1
3, 6 1.00 s = 100
Setting for Scalling
P5 U20 P5 P5 P5 P5 LPCT U20 V20 F30 M30 LPVT
Pick-up value scaling
Pick-up value scaling
140
P5/EN M/33A
Communication protocols
Add.
Name
Read Write
Admittance E/F Io/Uo> BN>
8461 Enable for BN>
8463... 8466
Pick-up value
1
1
1
1
8467... Input for inhibit 8470 control
1
1
8471... 8474
Direction mode
1
1
8475... 8478
8479... 8482
8483... 8486
8487... 8490
Operation delay
Reset time
SOL Mode SOL Operation delay
1
1
1
1
1
1
1
1
Admittance E/F Io/Uo>> setting
8511 Enable for Io/Uo>>
1
1
8512 Io input
1
1
8513... 8516
Uo pick-up value
1
1
8517... 8520
Angle correction
1
1
Admittance E/F Io/Uo>> YN>
8521 Enable for YN>>
1
1
8523... 8526
Pick-up value
1
1
8527... Input for inhibit 8530 control
1
1
8531... 8534
Operation delay
1
1
8535... 8538
Reset time
1
1
8539... 8542
SOL Mode
1
1
8543... SOL Operation 8546 delay
1
1
Admittance E/F Io/Uo>> GN>
FC
Scalling
3, 6 Off=0;On=1
3, 6 1.0 Bn% = 10
DI1=1;DI2=2;...;
DI19=19;DI20=
20;Arc1=25;
Arc2=26;BI=27;
VI1=29;VI2=30;
3, 6
VI3=31;VI4=32; DI21=65;DI22=
66;...;DI39=83;
DI40=84;VI5=
225;VI6=226;...;
VI19=239;VI20=
240
Undir=0; 3, 6 Forward=1;
Reverse=2
3, 6 1.00 s = 100
3, 6 1.00 s = 100
3, 6 Off=0;On=1
3, 6 1.00 s = 100
3, 6 Off=0;On=1
3, 6
Io=0;Io CSH=1; Iocalc=2;Io'=3
3, 6 1.0 % = 10
3, 6 1 ° = 1
3, 6 Off=0;On=1
3, 6 1.0 Yn% = 10
DI1=1;DI2=2;...;
DI19=19;DI20=
20;Arc1=25;
Arc2=26;BI=27;
VI1=29;VI2=30;
3, 6
VI3=31;VI4=32; DI21=65;DI22=
66;...;DI39=83;
DI40=84;VI5=
225;VI6=226;...;
VI19=239;VI20=
240
3, 6 1.00 s = 100
3, 6 1.00 s = 100
3, 6 Off=0;On=1
3, 6 1.00 s = 100
Setting for Scalling
P5 U20 P5 P5 P5 P5 LPCT U20 V20 F30 M30 LPVT
Pick-up value scaling
Pick-up value scaling
P5/EN M/33A
141
Communication protocols
Add.
Name
8561 Enable for GN>>
8563... 8566
Pick-up value
8567... Input for inhibit 8570 control
8571... 8574
Direction mode
8575... 8578
Operation delay
8579... 8582
Reset time
8583... 8586
8587... 8590
SOL Mode
SOL Operation delay
Admittance E/F Io/Uo>> BN>
8611 Enable for BN>>
8613... 8616
Pick-up value
8617... Input for inhibit 8620 control
8621... 8624
Direction mode
8625... 8628
8629... 8632
8633... 8636
8637... 8640
Operation delay
Reset time
SOL Mode SOL Operation delay
U2> setting
8661 Enable for U2>
8662... 8665
8666... 8669
8670... 8673
VTS Operating Mode Pick-up value
Delay type
Read Write
1
1
1
1
1
1
1
1
1
1
FC
Scalling
3, 6 Off=0;On=1
3, 6 1.0 Gn% = 10
DI1=1;DI2=2;...;
DI19=19;DI20=
20;Arc1=25;
Arc2=26;BI=27;
VI1=29;VI2=30;
3, 6
VI3=31;VI4=32; DI21=65;DI22=
66;...;DI39=83;
DI40=84;VI5=
225;VI6=226;...;
VI19=239;VI20=
240
Undir=0; 3, 6 Forward=1;
Reverse=2
3, 6 1.00 s = 100
Setting for Scalling
P5 U20 P5 P5 P5 P5 LPCT U20 V20 F30 M30 LPVT
Pick-up value scaling
1
1
3, 6 1.00 s = 100
1
1
3, 6 Off=0;On=1
1
1
3, 6 1.00 s = 100
1
1
3, 6 Off=0;On=1
1
1
3, 6 1.0 Bn% = 10
Pick-up value scaling
DI1=1;DI2=2;...;
DI19=19;DI20=
20;Arc1=25;
Arc2=26;BI=27;
VI1=29;VI2=30;
1
1
3, 6
VI3=31;VI4=32; DI21=65;DI22=
66;...;DI39=83;
DI40=84;VI5=
225;VI6=226;...;
VI19=239;VI20=
240
Undir=0;
1
1
3, 6 Forward=1;
Reverse=2
1
1
3, 6 1.00 s = 100
1
1
3, 6 1.00 s = 100
1
1
3, 6 Off=0;On=1
1
1
3, 6 1.00 s = 100
1
1
3, 6 Off=0;On=1
1
1
3, 6
NO ACTION=0; BLOCKING=1
1
1
3, 6 1.0 %Un = 10
1
1
3, 6 DT=0;INV=1
142
P5/EN M/33A
Communication protocols
Add.
Name
Read Write FC
Scalling
8674... 8677
Operation delay
1
8678... 8681
Reset time
1
U2>> setting
8701 Enable for U2>>
1
8702... VTS Operating 8705 Mode
1
8706... 8709
Pick-up value
1
8710... 8713
Delay type
1
8714... 8717
Operation delay
1
8718... 8721
Reset time
1
Motor overspeed >
8751 Enable for >
1
8752 Pick-up value
1
8753 Operation delay
1
Motor overspeed >>
8801 Enable for >>
1
8802 Pick-up value
1
8803 Operation delay
1
Motor underspeed <
8851 Enable for <
1
8852 Pick-up value
1
8853 Operation delay
1
Motor underspeed <<
8901 Enable for <<
1
8902 Pick-up value
1
8903 Operation delay
1
Motor Anti-backspin (ABS)
8951
Enable motor antibackspin
1
8952
Measured Zero Speed Mode
1
8953
Zero speed external mode
1
8954 Zero speed input DI 1
8955 Anti-backspin Time
1
Cold load pick-up CLPU
9001 Enable for CLPU
1
1
3, 6 1.00 s = 100
1
3, 6 1.00 s = 100
1
3, 6 Off=0;On=1
1
3, 6
NO ACTION=0; BLOCKING=1
1
3, 6 1.0 %Un = 10
1
3, 6 DT=0;INV=1
1
3, 6 1.00 s = 100
1
3, 6 1.00 s = 100
1
3, 6 Off=0;On=1
1
3, 6 1 %n = 1
1
3, 6 1 s = 1
1
3, 6 Off=0;On=1
1
3, 6 1 %n = 1
1
3, 6 1 s = 1
1
3, 6 Off=0;On=1
1
3, 6 1 %n = 1
1
3, 6 1 s = 1
1
3, 6 Off=0;On=1
1
3, 6 1 %n = 1
1
3, 6 1 s = 1
1
3, 6 Off=0;On=1
1
3, 6 Off=0;On=1
1
3, 6 Off=0;On=1
1
3, 6 Value 21
1
3, 6 1 s = 1
1
3, 6 Off=0;On=1
Setting for Scalling
P5 U20 P5 P5 P5 P5 LPCT U20 V20 F30 M30 LPVT
21. DI1=1;DI2=2;...;DI19=19;DI20=20;Arc1=25;Arc2=26;BI=27;VI1=29;VI2=30;VI3=31;VI4=32;DO1(B)=33;DO2(B)=34;DO3(B)=35; Watchdog=36;SF=37;SF=38;SF=39;SF=40;SF=41;BO=42;DO1(C)=43;DO2(C)=44;DO3(C)=45;DO4(C)=46;LedAl=49;LedTr=50;LedA= 51;LedB=52;LedC=53;LedDR=54;VO1=55;VO2=56;...;VO5=59;VO6=60;DI21=65;DI22=66;...;DI39=83;DI40=84;F1=85;F2=86;...;F6= 90;F7=91;DO1(D)=97;DO2(D)=98;DO3(D)=99;SF=100;DO1(E)=101;DO2(E)=102;NI1=129;NI2=130;...;NI127=351;NI128=352
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Add.
Name
Read Write FC
Scalling
9002 9003
Idle current Pickup current
1
1
3, 6 1.00 xIn = 100
1
1
3, 6 1.00 xIn = 100
9004 CLPU dead time
1
1
3, 6 1.00 s = 100
9005 CLPU time delay
1
1
3, 6 1.00 s = 100
Setting for Scalling
CLPU dead time scaling
P5 U20 P5 P5 P5 P5 LPCT U20 V20 F30 M30 LPVT
Specific scalings
Add.
Name
Read Write
P5U20 LPCT LPVT
P5U20
P5V20
P5F30
P5M30
10001...10002 Power scaling
1
0
10003...10004 PF and cos scaling
1
0
10005...10006 Tan scaling
1
0
10007...10008 Voltage scaling
1
0
10009...10010 VT primary scaling
1
0
10011...10012 Frequency scaling
1
0
10013...10014 VTo secondary scaling
1
0
10015...10016 Io scaling
1
0
10017...10018 Io' scaling
1
0
10019...10020 CLPU dead time scaling
1
0
10021...10022 Limit for oper.left scaling
1
0
10025...10026 CB open count scaling
1
0
10027...10028 Operate delay scaling
1
0
10029...10030 Pick-up value scaling
1
0
10031...10032 Fault value scaling
1
0
10033...10034 Max control pulse length scaling
1
0
10035...10036 LPCT/VT scaling
1
0
10037...10038 External AI scaling
1
0
10039...10040 Io scaling (CSH)
1
0
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Modbus master
External analog inputs and digital inputs or outputs can be added to the Easergy P5 protection relay via external Modbus I/O. This protocol is based on Modbus RTU master and RS-485 bus structure. User can configure and read external AI/ DI/DO through eSetup Easergy Pro. User can also read these external AI/DI/DO through the HMI.
Function description
The Easergy P5 protection relay supports application functions include: · Modbus master: analog inputs and alarms · Modbus master: digital inputs · Modbus master: digital outputs · Modbus master: DO matrix · Modbus master: names config
Main configuration parameters
The picture and table below explain how to configure an Easergy P5 protection relay to use the Modbus master protocol.
Figure 4 - Modbus master main configuration view
Table 44 - Modbus master main configuration parameters
Parameter External I/O speed transm
Parity
Value
1200, 2400, 4800, 9600, 19200, 38400, 57600, 115200
None, Even, Odd
Description The communication speed, bits per second
The type of parity bit used
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Modbus master analog inputs
Find the "Modbus master: analog inputs" and "Modbus master: analog input alarm" menus in eSetup Easergy Pro. Up to 64 points of External AI can be configured. All External AI can be read through HMI control / ExtAI.
Figure 5 - Modbus master: analog inputs menu
Figure 6 - Modbus master: analog inputs alarm menu
Refer to the table below for the proper values to the parameters "AI Enabled", "AI Unit", "AI slave address", "AI Modbus address", "AI register type" and "AI signed".
Table 45 - Modbus master: analog inputs configuration parameters
Parameter AI Enabled AI Unit
AI slave address AI Modbus address AI register type AI signed AI offset AI scale Alarm 1 pick-up value Alarm 2 pick-up value Alarm hysteresis
Value
On, Off
°C, F, K, V/A, mA, A, V, kW, kVA, kvar
1-247
1-9999
InputR, HoldingR
On, Off
-32768 - 32767
0.001-1000.000
float
float
0.0-10000.0
Description Enable or disable this AI. Unit of this AI
Modbus slave address Modbus register address AI Modbus register type Signed interger or Unsigned integer Offset of AI Meas Scale of AI Meas Threshold for this AI alarm1 Threshold for this AI alarm2 Hysteresis for alarms
Since holding registers are 16 bits in size, the external analog inputs menu give proper values to AI specific scaling. AI Meas is the product of the received value multiplied by the AI scale. The scaling is determined by the float value of AI scale. It is common to use scaling factors with base ten (0.100,1.000,10.000, 100.000...). In such cases, the original measurements only lose decimals and such values are easy to read and rescale to actual values on the client side after transmission.
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Modbus master digital inputs
Find the "Modbus master: digital inputs" menu on eSetup Easergy Pro. Up to 18 points of External DI can be configured. All External DI can be read through HMI control / ExtDI.
Figure 7 - Modbus master: digital inputs menu
Refer to the table below for a more detailed explanation on the values that can be assigned to the parameters of this menu.
Table 46 - Modbus master: digital inputs configuration parameters
Parameter DI Enabled DI slave address DI Modbus address DI register type
DI selected bit
Value
On, Off
1-247
1-9999
InputR, HoldingR, CoilS, InputS
1-16
Description Enable or disable this DI.60870-5-101 Modbus slave address Modbus register/coil address AI Modbus register type
Select DI bit for DI state
Modbus master digital outputs
Find the "Modbus master: digital outputs" menu on the eSetup Easergy Pro. Up to 16 points of External DO can be configured. All External DO can be read through HMI control / ExtDO.
Figure 8 - Modbus master: digital outputs menu
Refer to the table below for a more detailed explanation on the values that can be assigned to the parameters of this menu.
Table 47 - Modbus master: digital outputs configuration parameters
Parameter DO Enabled
DO slave address DO Modbus address
Value
On, Off 1-247 1-9999
Description Enable or disable this DO
Modbus slave address Modbus coil address
"Modbus master DO matrix is used to link protection Events (e.g. I> start, External AI alarm/trip, .....) or External DI states to DO.
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Figure 9 - Modbus master DO matrix
Communication protocols
Measurements
The external AI can be obtained by mimic through eSetup Easergy Pro or the HMI. Six or eight measurements can be shown in the main display of the Easergy P5 protection relay with small LCD screen or large one, respectively.
Figure 10 - External AI shown on the mimic screen in eSetup Easergy Pro
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Modbus master names configuration
The user can configure the labels and descriptions of Modbus master AI, DI and DO through eSetup Easergy Pro. Corresponding description in Mimic, Matrix and events log will be updated too. Figure 11 - The External AI names configuration view
Figure 12 - The External DI names configuration view
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EtherNet/IP
Presentation
P5/EN M/33A
The Easergy P5 protection relays support communication using EtherNet/IP protocol which is a part of Common Industrial Protocol (CIP) family. EtherNet/IP protocol is available with the optional inbuilt Ethernet port. The protocol can be used to read/write data from/to the Easergy P5 protection relays using request/ response communication or via cyclic messages transporting data assigned to assemblies (data sets).
Messaging
EtherNet/IP supports two modes of messaging, unconnected and connected messaging.
· Unconnected messaging refers to peer-to-peer communication, where opening and closing of connections is allowed via unconnected messaging. This is handled by the UnConnected Message Manager (UCMM). Messages are sent over TCP/IP.
· Connected messaging, on the other hand, is dedicated to a particular purpose, such as frequent explicit message transactions or real-time I/O data transfers. Connection resources are reserved and configured using communication services available via the UCMM. Messages are sent over TCIP/IP and User Datagram Protocol (UDP).
EtherNet/IP specifies a special encapsulation protocol to carry CIP messages over TCP/IP and UDP.
There are two types of connections, explicit and implicit. · Explicit connections refer to request-response connections which are general purpose connections. Explicit connections use TCP/IP and use either unconnected messaging via UCMM (one-time request/response) or Class 3 connections (cyclic request /response). · In implicit connections, only application data is contained within the messages. Implicit data may be polled, cyclic or Change of State (COS) messages. Implicit connections are either point-to-point (unicast) or one-tomany (multicast) connections. Implicit connections use UDP/IP.
Devices
There are two classes of devices in a CIP network, adapters and scanners. · Adapters are targets of real-time I/O data connection. Adapters cannot send or receive real-time data unless requested to do so by a scanner device. Adapters can exchange data using explicit messages with any class of devices but cannot originate a connection. · Scanners are originators of I/O data connection requests and originators or targets of explicit connection requests.
Objects
Objects in CIP (and thereby EtherNet/IP) are defined by: · A description a description of an object being specified. · A class code (Class ID) hexadecimal identifier assigned to each CIP object · Attributes data elements associated with the object. · Common services list of the common services defined for the object. · Object-specific Services the full specifications of any services unique to the object · Connections connections supported by the object. · Behaviour the relationship between attribute values and services.
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The CIP also includes an Object Library, which is a set of standardized objects that covers protocol objects such as the Identity Object, Assembly Object, etc. as well as Application Objects. The Object Library covers basic automation blocks and some more complex devices, including Digital Input, Digital Output, etc.
Figure 14 - CIP object model
Application Object(s) Assembly Object
Parameter Object
Identity Object
Message Router
Optional
I/O
Explicit Msg
Connection Manager or Connection Object
CIP Network
Required
Network Specific Link Object(s)
Table 48 - CIP object description
Object Connection object Message router
Assembly object
Identity object
Description
The CIP Communication Object manages and provides the runtime exchange of messages.
The Message Router Object provides a messaging connection point through which a Client may address a service to any object class or instance residing in the physical device. It routes explicit messages over requested paths.
The Assembly Object binds attributes of multiple objects, which in allows data to or from each of these objects to be sent or received over a single connection (like a data set). Assembly objects can be used to group input data (producing instance of an Assembly Object information transmitted to the network) or output data (consuming instance of an Assembly Object information received from the network). I/O connections are established between Assembly Object instances of the devices between inputs and outputs. Assembly object instances are accessible via explicit messaging.
Provides device identification and general information about the device, such as vendor identifier, product code, name, status, etc. The Identity Object shall be present in all CIP products.
Application Objects are based on the standard objects from the Object Library if possible, if not, vendors can define their own, private (vendor specific) Application Objects. CIP specifies the Class ID ranges for that purpose.
Table 49 - CIP Class ID ranges
Range (hexadecimal)
0x00...0x63
0x64...0xC7
Meaning
Open Vendor specific
Quantity
100 100
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Table 49 - CIP Class ID ranges (Continued)
Range (hexadecimal) 0xC8...0xEF 0xF0...0x2FF 0x300...0x4FF 0x500...0xFFFF
Meaning
Quantity
Reserved by CIP for future use 40
Open
528
Vendor specific
512
Reserved by CIP for future use 64256
Device profile
The series of application objects for Easergy P5 is known as the device profile. A large number of profiles for many device types have been defined. An example of a device profile is shown in Device profile, page 153.
EtherNet/IP main features
EtherNet/IP main features:
· Static data model:
2 standard objects (Overload and Control Supervisor)
2 private objects (one for digital data and one for analog data)
4 configuration objects for configuration of protection functions
· Two configurable assemblies (one producing and one consuming) with the maximum capacity of 128 bytes. Each configuration is described in an Electronic Data Sheet (EDS) file. Each EDS file that can be fed to any client supporting EDS files and can be generated at any time, all changes to EtherNet/IP configuration or to assemblies' content require generating of the new EDS file, see Generating an EDS File with eSetup Easergy Pro, page 160.
· Three types of communications are supported:
UCMM (one time request / response)
Class 3 connection (cyclic request / response)
Class 1 connection (cyclic IO messages containing assemblies' data)
Function description
EtherNet/IP protocol is available on Easergy P5 protection relays with an optional embedded Ethernet card. Easergy P5 protection relays with the EtherNet/IP protocol selected on the Ethernet port serves as an adapter which means that it is not able to initiate communication with other devices on the network.
Objects and messaging
The EtherNet/IP implementation on Easergy P5 protection relays supports all required standard objects with their required attributes. There is also a total of 10 application objects from which 8 are private. A list of Easergy P5 device objects and their classes is shown in the table below.
Table 50 - Device profile
Class 0x01 0x02 0x04 0x06
Object Identity Message Router Assembly Connection Manager
Object Category Protocol
Standard
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Table 50 - Device profile (Continued)
Class 0xF5 0xF6 0x29 0x2C 0x64 0x65 0x66 0x67 0x68 0x69 0x70 0x71
Object TCP/IP Interface Ethernet Link Control Supervisor Overload Digital Analog StgProtCurrent StgProtEF StgProtOther StgGeneral Analog2 Special
Object Category Application
Private (vendor specific)
The EtherNet/IP implementation in Easergy P5 protection relays supports three types of communication:
· Unconnected Explicit Requests and Responses used mainly for establishing explicit and I/O connections, but can also be used for one time requests to attributes of data model objects.
· Explicit Messaging (Class 3) connections these are strictly point-to-point connections used to cyclically query the adapter for some data or to cyclically write data to the adapter. Transmitted using TCP.
· I/O Messaging (Class 1) connections can be point-to-point or multicast. Used for very frequent exchange of process data. Easergy P5 protection relays support only cyclic I/O connections. Transmitted using UDP.
Connection limits:
· For Class 3 connections a maximum of six connections at the same time.
· For Class 1 connections only one connection at the same time.
Supported services
Easergy P5 protection relays support following services for objects: · GAA = Get Attribute All · GAS = Get Attribute Single · SAS = Set Attribute Single
GAS service is available for all attributes with the GET or GET (to access) | SET (to modify) access type and the SAS service is available for all attributes with the GET | SET or SET access type.
A list of Easergy P5 device services for objects is shown in the table below.
Table 51 - Supported services for objects
Class
0x01 0x02 0x04 0x06 0xF5
Object
Identity Message router Assembly Connection manager TCP/IP interface
Object Category Get GAA, GAS GAS GAA, GAS
Set SAS
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Table 51 - Supported services for objects (Continued)
Class
0xF6 0x29 0x2C 0x64 0x65 0x66 0x67 0x68 0x69 0x70 0x71
Object
Ethernet link Control supervisor Overload Digital Analog StgProtCurrent StgProtEF StgProtOther StgGeneral Analog2 Special
Object Category Get GAA, GAS GAS GAS GAS GAS GAS GAS GAS GAS GAS GAS
Set SAS SAS SAS SAS SAS SAS SAS SAS SAS SAS
I/O messaging assemblies
EtherNet/IP implementation on Easergy P5 protection relays includes a total of two producing assemblies (Tx, Target Originator) and two consuming assemblies (Rx, Target Originator); see table below.
Table 52 - Available assemblies
Instance no. 2 50 100 150
Type Producing Consuming Producing Consuming
Description Static Basic Output Image Static Basic Image Configurable Output Image (dynamic) Configurable Input Image (dynamic)
Additionally, a zero-length configuration assembly with instance number "199" is available.
Assemblies have to be configured during the device setup. Configuring assemblies involve selecting the producing and consuming instances to be used.
If dynamic assemblies (instance numbers 100 and 150) are used it is also needed to configure the contents of both assemblies. By default both assemblies are configured with one byte of data each. By default producing assembly is configured with "Control Supervisor Object" / "Faulted attribute" and consuming assembly with "Control Supervisor Object" / "FaultRst".
I/O connections with Easergy P5 protection relays are opened with the Requested Packet Interval (RPI) no less than 50 ms and not greater than 5 s. The default Value is 100 ms.
Electronic data sheet (EDS)
Every change to main configuration parameters or assemblies configuration requires a new EDS file to be generated (once all changes are made and the device is about to be used in the network).
Some of the configuration tools are capable of simplifying device configuration based on the EDS file. In the current implementation the EDS file can only be generated from eSetup Easergy Pro EDS file extraction over the EtherNet/IP network is not supported in the Easergy P5 protection relay.
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EDS file cannot be extracted from the Easergy P5 protection relay over the EtherNet/IP network, rather, it must be generated with eSetup Easergy Pro. This operation is explained in Generating an EDS File with eSetup Easergy Pro, page 160.
Events
Easergy P5 protection relay events are available under the following attributes of Digital Object (0x64)
· Attribute 118 Event code (bits 0-5: code, bits 6-15: channel)
· Attribute 119 Event milliseconds and seconds (bits 0-5: seconds, bits 6-15: milliseconds)
· Attribute 120 Event min and hour (bits 0-7: hour, bits 8-15: minutes)
· Attribute 121 Event day and month (bits 0-7: month, bits 8-15: day)
· Attribute 122 Event year
Events are read starting from the oldest one in the Event Buffer of the Easergy P5 protection relay. Events are read sequentially, the next event is read when the previous one is acknowledged. Acknowledgement is done by setting attribute 123 of the Digital Object (0x64) Event Ack. When all events have been read and the event buffer is thus empty, the attributes will contain zero-data (zeroes). This zerodata will automatically be replaced with the data of a new event when one is registered.
Reading of events is the same for all communication types. The Easergy P5 protection relay sends the oldest available event. The next oldest event will be read only after setting the Event Ack parameter (the one previously read is not available any more) or after the event buffer has been cleared and a new event is generated later on.
Fault codes
The table below contains a translation of Easergy P5 protection relay stages to EtherNet/IP Fault Codes.
Table 53 - EtherNet/IP fault code
EtherNet/IP fault code 20
21 26 27
29 31 51
52
54 55
73
Description CURRENT TRIP
THERMAL OVERLOAD PHASE UNBALANCE GROUND FAULT
UNDERLOAD STALL UNDERVOLTAGE
OVERVOLTAGE
PHASE REVERSAL FREQUENCY
START/HOURS EXCEED
Protection stage
Overcurrent I> Overcurrent I>> Overcurrent I>>>
Thermal Overload T>
Unbalance I2>
Earth Fault Io> Earth Fault Io>> Earth Fault Io>>> Earth Fault Io>>>>
Under Current Stage I<
Motor Startup Supervision Ist>
U< U<< U<<<
U> U>> U>>>
Unbalance I2>>
f< f<< f>< f>><<
Motor Restart Inhibition N>
ANSI 50/51
49 46 50N/51N
37 48 27
59
47 81U 81
66
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EtherNet/IP main configuration
The configuration of the EtherNet/IP settings is done in the EtherNet/IP main configuration view of the COMMUNICATION menu in eSetup Easergy Pro or Web HMI.
EtherNet/IP main configuration parameters are listed in the table below:
Table 54 - Description of the EtherNet/IP main configuration parameters
Parameter General Multicast IP Address Multicast TTL
Vendor ID Device Type Product Code
Major Revision
Minor Revision
Serial Number Product Name Auto/Manual Header Detection
I/O assembly instances in use
Producing Producing instance number Include Run/Idle Header (Producing) Producing Instance Size Consuming Consuming Instance Include Run/Idle Header (Consuming) Consuming Instance Size Configuration Configuration Instance Configuration Instance Size
Value
1100 165535 065535 1-65535 1127 1255 0-4294967295 32 chars Manual Auto (default) 2+50, (default) 100+150
11278 On/Off
[bytes]
11278 On/Off
[bytes]
11279 [bytes]
Description
Multicast IP address used for sending IO messages Time to live of the IO messages sent to multicast address Identification of Schneider Electric Indication of general type of product Identification of a particular product of an individual vendor Major revision of the item the Identity Object represents Minor revision of the item the Identity Object represents Serial number of device Human readable identification Include Run/Idle Header parameters are used to define whether Run/Idle Header is used. Run/Idle Headers are detected automatically Instance numbers of producing and consuming assemblies being used
Instance number of producing assembly (not directly editable) 22 Include or exclude Run/Idle Header in an outgoing IO messages
The size of the producing assembly (not directly editable) 23
Instance number of consuming assembly
Expect presence or absence of Run/Idle Header in an incoming IO messages
The size of the consuming assembly (not directly editable) 23
Instance number of configuration instance
The size of the consuming assembly (not directly editable) 23
22. Automatically updated according to the value of "I/O assembly instances in use" parameter. 23. Automatically updated as the assemblies are configured.
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Multicast IP
Multicast IP address is a parameter used by the device to send EtherNet/IP multicast packets, if requested to do so by the scanner. Multicast IP is a valid Class D IP address. In device there is only one possible I/O connection at a time and therefore only single Multicast IP is used.
Multicast IP parameter is ignored when scanner requested T O (target-tooriginator, i.e. adapter to scanner) communication to be point-to-point. The default value of this parameter is 239.0.0.1.
Multicast TTL
Multicast TTL value is used for the IP header Time-to-live field when sending EtherNet/IP multicast packets. This value is ignored for the unicast packets and TTL as configured for the TCP/IP stack is used instead. The default value of this parameter is 1 (the number of network hops over which the multicast packet is propagated datagrams limited to the local subnet).
Auto/Manual header detection
When this parameter is set to "Manual", user needs to define manually the presence of Run/Idle header in the I/O messaging. This is done by configuring parameters "Include Run/Idle Header" for more information, see Include Run/Idle header (producing), page 158 and Include Run/Idle header (consuming), page 158. When "Auto" is selected, Easergy P5 protection relays automatically detect whether Run/Idle header is used in the I/O messaging. The default value of this parameter is "Auto".
I/O assembly instances in use
Selection of producing and consuming instances to be used. The values of producing and consuming assemblies are available in the EDS file (see Generating an EDS File with eSetup Easergy Pro, page 160) and are used by the configuration tool as a reference path during I/O connection opening.
Every change to this parameter requires restarting the device and generation of a new EDS file.
Include Run/Idle header (producing)
An I/O connection can be established with or without the Run/Idle Header in the Target Originator direction (adapter to scanner). Including Run/Idle Header in the producing assembly adds additional 4 bytes to the beginning of the data part of an I/O message. Run bit is always set in the outgoing messages if Easergy P5 protection relays are configured to send I/O messages with the Run/Idle Header. Information about whether the Run/Idle Header is included in the outgoing messages is available in the EDS file and can be used by the eSetup Easergy Pro to properly establish communication.
Every change to this parameter requires generation of a new EDS file.
The default value of this parameter is "Off".
Include Run/Idle header (consuming)
An I/O connection can be established with or without the Run/Idle Header in the Target Originator direction (scanner to adapter). Setting this value to "On" inform the eSetup Easergy Pro that Easergy P5 protection relays expect the consuming assembly to contain additional 4 bytes of data. If the Run/Idle Header is included and the Run bit is set in the incoming I/O messages then Easergy P5 protection relays process received data, and if the Run bit is cleared then P5 device ignores received data. If the Run/Idle Header is not included in the
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incoming I/O messages then the received data is always processed. Information about whether the Run/Idle Header is expected in the incoming I/O messages is available in the EDS file and can be used by the eSetup Easergy Pro to properly establish communication.
Every change to this parameter requires generation of a new EDS file. The default value of this parameter is "On".
NOTE:
Changing of both "Include Run/Idle Header" parameters while the I/O connection is running is not allowed by Easergy P5 protection relays.
Data point configuration
Available data items, that is, the contents of the Producing Assembly and the Consuming Assembly can be viewed / configured in the following eSetup Easergy Pro menus:
· EtherNet/IP I/O 2+50 (static) · EtherNet/IP I/O 100+150 (dynamic) Assembly 2+50 is static, meaning user cannot make changes to the contents of assembly. Assembly 100+150 is dynamic, meaning user can select data items to the assembly by clicking on a row and selecting a desired data point. An example of this is shown in figure below.
Figure 15 - Configuration of the EtherNet/IP producing assembly
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Table 55 - Description of assembly configuration parameters table contents
Attribute Name Length Scaling Offset
Description Type and name of the data item Length of the data item in bytes The scaling used for the data item The offset of the data item in the assembly
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NOTE: Making changes to the assemblies will require a device reboot for the changes to take effect. A list of the set of available data items in EtherNet/IP, see Data model of EtherNet/IP, page 160.
Generating an EDS File with eSetup Easergy Pro
Changes to main configuration parameters or the configuration of assemblies requires a new EDS file to be generated (once all changes are made and the device is about to be used in the network).
An EDS file can be generated with eSetup Easergy Pro or Web HMI in the COMMUNICATION menu. Selecting the option "Export EthernetIP EDS file..." will generate the EDS file and bring up a file browser window asking where to save the generated file. After clicking Save the generated EDS file will be stored at the selected location.
Figure 16 - Exporting an EDS file
Data model of EtherNet/IP
Class
Name
0x71 0x71 0x71 0x71 0x71 0x71 0x71
Special#001/1 byte padding
Special#002/2 bytes padding
Special#003/Requested packet interval time
Special#004/Controller Output Image 100 Size
Special#005/Controller Input Image 150 Size
Special#006/Controller Input Image 100 Size
Special#007/Controller Output Image 150 Size
Length Read
1
1
2
1
Write
Cont. mode
1
1
1
1
P5U20 LPCT LPVT
P5U20 P5V20 P5F30 P5M30
4
1
1
0
2
1
0
0
2
1
0
0
2
1
0
0
2
1
0
0
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Class
Name
Length
0x29 Control Supervisor#003/Run1
1
0x29 Control Supervisor#010/Faulted
1
0x29 Control Supervisor#011/Warning
1
0x29 Control Supervisor#012/FaultRst
1
0x29 Control Supervisor#013/Fault code
1
0x29
Control Supervisor#014/Warning code
1
0x29
Control Supervisor#022/ CycleCount
4
0x2C Overload#005/AvgCurrent
4
0x2C Overload#006/%PhImbal
1
0x2C Overload#007/%Thermal
1
0x2C Overload#008/CurrentL1
4
0x2C Overload#009/CurrentL2
4
0x2C Overload#010/CurrentL3
4
0x2C Overload#011/Earth-fault current
4
0x64 Digital#001/Digital inputs
4
0x64 Digital#002/Output relays
4
0x64 Digital#003/Alive indicator
2
0x64 Digital#004/Events
4
0x64 Digital#005/Remote/Local State
1
0x64
Digital#006/Cancel selected operation
1
0x64
Digital#007/OM_MB_ ResetLatches
1
0x64 Digital#008/Synchronize minutes
1
0x64 Digital#009/Object1 state
1
0x64 Digital#010/Object2 state
1
0x64 Digital#011/Object3 state
1
0x64 Digital#012/Object4 state
1
0x64 Digital#013/Object5 state
1
0x64 Digital#014/Object6 state
1
0x64 Digital#015/Object7 state
1
0x64 Digital#016/Object8 state
1
0x64 Digital#017/Open select Object1
1
0x64 Digital#018/Close select Object1
1
0x64
Digital#019/Execute operation Object1
1
0x64
Digital#020/Max ctrl pulse length of Object1
4
0x64 Digital#021/Open select Object2
1
0x64 Digital#022/Close select Object2
1
0x64
Digital#023/Execute operation Object2
1
0x64
Digital#024/Max ctrl pulse length of Object2
4
Read
1 1 1 0 1 1
1 1 1 1 1 1 1 1 1 1 1 1 1 0
1 1 1 1 1 1 1 1 1 1 1 1 0
1 1 1 0
1
Write
1 0 0 1 0 0
1 0 0 0 0 0 0 0 0 0 0 0 0 1
1 1 0 0 0 0 0 0 0 0 1 1 1
1 1 1 1
1
Cont. mode
1 1 1 1 1 1
1
1 1 1 1 1 1 1 1 1 1 1 1
1
1 1 1 1 1 1 1 1 1 1 1 1
1
1
1 1
1
1
P5U20 LPCT LPVT
P5U20
P5V20
P5F30
P5M30
P5/EN M/33A
161
Communication protocols
Class
Name
Length Read
0x64 Digital#025/Open select Object3
1
1
0x64 Digital#026/Close select Object3
1
1
0x64
Digital#027/Execute operation Object3
1
0
0x64
Digital#028/Max ctrl pulse length of Object3
4
1
0x64 Digital#029/Open select Object4
1
1
0x64 Digital#030/Close select Object4
1
1
0x64
Digital#031/Execute operation Object4
1
0
0x64
Digital#032/Max ctrl pulse length of Object4
4
1
0x64 Digital#033/Open select Object5
1
1
0x64 Digital#034/Close select Object5
1
1
0x64
Digital#035/Execute operation Object5
1
0
0x64
Digital#036/Max ctrl pulse length of Object5
4
1
0x64 Digital#037/Open select Object6
1
1
0x64 Digital#038/Close select Object6
1
1
0x64
Digital#039/Execute operation Object6
1
0
0x64
Digital#040/Max ctrl pulse length of Object6
4
1
0x64 Digital#041/DirectO1O
1
0
0x64 Digital#042/DirectO1C
1
0
0x64 Digital#043/DirectO2O
1
0
0x64 Digital#044/DirectO2C
1
0
0x64 Digital#045/DirectO3O
1
0
0x64 Digital#046/DirectO3C
1
0
0x64 Digital#047/DirectO4O
1
0
0x64 Digital#048/DirectO4C
1
0
0x64 Digital#049/DirectO5O
1
0
0x64 Digital#050/DirectO5C
1
0
0x64 Digital#051/DirectO6O
1
0
0x64 Digital#052/DirectO6C
1
0
0x64 Digital#053/Pos. sequence I1
4
1
0x64 Digital#054/Negative sequence I2
4
1
0x64 Digital#055/Current ratio I2/I1
4
1
0x64
Digital#056/Current phase sequence
1
1
0x64 Digital#057/Pos. sequence U1
4
1
0x64 Digital#058/Negative sequence U2
4
1
0x64 Digital#059/Voltage U2/U1
4
1
0x64
Digital#060/Voltage phase sequence
1
1
Write
Cont. mode
1
1
1
1
1
1
1
1
1
1
1
1
1
1
1
1
1
1
1
1
1
1
1
1
1
1
1
1
1
1
1
1
1
1
1
1
1
1
1
1
1
1
1
1
1
1
1
1
1
1
1
1
1
1
1
1
0
1
0
1
0
1
0
1
0
1
0
1
0
1
0
1
P5U20 LPCT LPVT
P5U20 P5V20 P5F30 P5M30
162
P5/EN M/33A
Communication protocols
Class
Name
0x64 0x64 0x64 0x64 0x64 0x64 0x64 0x64 0x64 0x64 0x64 0x64 0x64 0x64 0x64 0x64 0x64 0x64 0x64 0x64 0x64 0x64 0x64 0x64 0x64
0x64
0x64 0x64 0x64 0x64 0x64 0x64 0x64 0x64 0x64 0x64 0x64
0x64
Digital#061/Voltage interrupt Digital#062/Voltage status Digital#063/Clear min/max/ demand Digital#064/Pos. sequence I1' Digital#065/Negative sequence I2' Digital#066/Current I' -seq./+seq. Digital#067/Current I' phase seq. Digital#068/Shot1 start counter Digital#069/Shot2 start counter Digital#070/Shot3 start counter Digital#071/Shot4 start counter Digital#072/Shot5 start counter Digital#073/AR start counter Digital#074/AR fail counter Digital#075/AR shot number Digital#076/Direct trip AR request Digital#077/Recloser locked Digital#078/Recloser running Digital#079/Final trip Digital#080/Auto-Recloser on Digital#081/Timer 1 status Digital#082/Timer 2 status Digital#083/Timer 3 status Digital#084/Timer 4 status Digital#085/Logic output states 1...8 Digital#086/Logic output states 9...16 Digital#087/Logic output states 17...20 Digital#088/Stage start state Digital#089/Stage trip state Digital#090/N> alarm Digital#091/Motor start disabled Digital#092/Motor starting Digital#093/Motor running Digital#094/CB operation alarm 1 Digital#095/CB operation alarm 2 Digital#096/Alarm L1..L3 Digital#097/Fault L1..L3 Digital#098/SetGrp common change
Length Read
1
1
1
1
1
1
4
1
4
1
4
1
1
1
2
1
2
1
2
1
2
1
2
1
2
1
2
1
1
1
2
1
2
1
2
1
2
1
2
1
1
1
1
1
1
1
1
1
1
1
1
1
1
1
1
1
1
1
1
1
1
1
1
1
1
1
1
1
1
1
1
1
1
1
1
1
Write
0 0 1 1 1 0 0 1 1 1 1 1 1 1 0 0 0 0 0 0 1 1 1 1 0
0
0 0 0 0 0 0 0 0 0 0 0
1
Cont. mode
1 1
1
1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1
1
1
1
1 1 1 1 1 1 1 1 1 1
1
P5U20 LPCT LPVT
P5U20 P5V20
P5F30 P5M30
P5/EN M/33A
163
Communication protocols
Class
Name
Length Read
0x64 Digital#099/Sync1 request
1
1
0x64 Digital#100/Sync1 OK
1
1
0x64 Digital#101/Bypass
1
1
0x64 Digital#102/Sync1 fail
1
1
0x64 Digital#103/Phase angle difference
2
1
0x64 Digital#109/Virtual outputs
2
1
0x64 Digital#114/Engine running hours
4
1
0x64
Digital#115/Engine running (in seconds)
2
1
0x64 Digital#116/Start counter
2
1
0x64 Digital#117/Reset diagnostics
1
1
0x64 Digital#118/Event Code
2
1
0x64 Digital#119/Event Millisec And Sec
2
1
0x64 Digital#120/Event Min And Hour
2
1
0x64 Digital#121/Event Day And Month
2
1
0x64 Digital#122/Event Year
2
1
0x64 Digital#123/Event Ack
1
1
0x64 Digital#124/Device status
1
1
0x64 Digital#125/DI1 counter
2
1
0x64 Digital#126/DI2 counter
2
1
0x64 Digital#127/DI3 counter
2
1
0x64 Digital#128/DI4 counter
2
1
0x64 Digital#129/DI5 counter
2
1
0x64 Digital#130/DI6 counter
2
1
0x64 Digital#131/DI7 counter
2
1
0x64 Digital#132/DI8 counter
2
1
0x64 Digital#133/DI9 counter
2
1
0x64 Digital#134/DI10 counter
2
1
0x64 Digital#135/DI11 counter
2
1
0x64 Digital#136/DI12 counter
2
1
0x64 Digital#137/DI13 counter
2
1
0x64 Digital#138/DI14 counter
2
1
0x64 Digital#139/DI15 counter
2
1
0x64 Digital#140/DI16 counter
2
1
0x64 Digital#141/DI17 counter
2
1
0x64 Digital#142/DI18 counter
2
1
0x64 Digital#143/DI19 counter
2
1
0x64 Digital#144/DI20 counter
2
1
0x64 Digital#145/DI21 counter
2
1
0x64 Digital#146/DI22 counter
2
1
0x64 Digital#147/DI23 counter
2
1
Write
Cont. mode
0
1
0
1
1
1
0
1
0
1
0
1
1
1
1
1
1
1
1
1
0
1
0
1
0
1
0
1
0
1
1
1
0
1
1
1
1
1
1
1
1
1
1
1
1
1
1
1
1
1
1
1
1
1
1
1
1
1
1
1
1
1
1
1
1
1
1
1
1
1
1
1
1
1
1
1
1
1
1
1
P5U20 LPCT LPVT
P5U20 P5V20 P5F30 P5M30
164
P5/EN M/33A
Communication protocols
Class
Name
0x64 0x64 0x64 0x64 0x64 0x64 0x64 0x64 0x64 0x64 0x64 0x64 0x64 0x64 0x64 0x64 0x64 0x64 0x64 0x64 0x64 0x64 0x64 0x64 0x64 0x64 0x64 0x64 0x64 0x64 0x64 0x64 0x64 0x64 0x64 0x64 0x64 0x64 0x64 0x64 0x64
Digital#148/DI24 counter Digital#149/DI25 counter Digital#150/DI26 counter Digital#151/DI27 counter Digital#152/DI28 counter Digital#153/DI29 counter Digital#154/DI30 counter Digital#155/DI31 counter Digital#156/DI32 counter Digital#157/DI33 counter Digital#158/DI34 counter Digital#159/DI35 counter Digital#160/DI36 counter Digital#161/DI37 counter Digital#162/DI38 counter Digital#163/DI39 counter Digital#164/DI40 counter Digital#199/Virtual input 1 Digital#200/Virtual input 2 Digital#201/Virtual input 3 Digital#202/Virtual input 4 Digital#203/Virtual input 5 Digital#204/Virtual input 6 Digital#205/Virtual input 7 Digital#206/Virtual input 8 Digital#207/Virtual input 9 Digital#208/Virtual input 10 Digital#209/Virtual input 11 Digital#210/Virtual input 12 Digital#211/Virtual input 13 Digital#212/Virtual input 14 Digital#213/Virtual input 15 Digital#214/Virtual input 16 Digital#215/Virtual input 17 Digital#216/Virtual input 18 Digital#217/Virtual input 19 Digital#218/Virtual input 20 Digital#219/Virtual output 1 Digital#220/Virtual output 2 Digital#221/Virtual output 3 Digital#222/Virtual output 4
P5/EN M/33A
Length Read
2
1
2
1
2
1
2
1
2
1
2
1
2
1
2
1
2
1
2
1
2
1
2
1
2
1
2
1
2
1
2
1
2
1
1
1
1
1
1
1
1
1
1
1
1
1
1
1
1
1
1
1
1
1
1
1
1
1
1
1
1
1
1
1
1
1
1
1
1
1
1
1
1
1
1
1
1
1
1
1
1
1
Write
1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1
Cont. mode
1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1
P5U20 LPCT LPVT
P5U20 P5V20
P5F30 P5M30
165
Communication protocols
Class
Name
0x64 0x64 0x64 0x64 0x64 0x64 0x64 0x64 0x64 0x64 0x64 0x64 0x64 0x64 0x64 0x64 0x65 0x65 0x65 0x65 0x65 0x65 0x65 0x65 0x65 0x65
0x65
0x65
0x65
0x65 0x65 0x65 0x65 0x65
0x65
0x65
0x65
0x65
Digital#223/Virtual output 5 Digital#224/Virtual output 6 Digital#225/Virtual output 7 Digital#226/Virtual output 8 Digital#227/Virtual output 9 Digital#228/Virtual output 10 Digital#229/Virtual output 11 Digital#230/Virtual output 12 Digital#231/Virtual output 13 Digital#232/Virtual output 14 Digital#233/Virtual output 15 Digital#234/Virtual output 16 Digital#235/Virtual output 17 Digital#236/Virtual output 18 Digital#237/Virtual output 19 Digital#238/Virtual output 20 Analog#001/Phase current IL1 Analog#002/Phase current IL2 Analog#003/Phase current IL3 Analog#004/Frequency Analog#005/Io residual current Analog#006/Io' residual current Analog#007/Residual voltage Analog#008/Active power Analog#009/Reactive power Analog#010/Apparent power Analog#011/Phase-to-Phase voltage U12 Analog#012/Phase-to-Phase voltage U23 Analog#013/Phase-to-Phase voltage U31 Analog#014/Exported energy Analog#015/Imported energy Analog#016/Exp. reactive energy Analog#017/Imp. reactive energy Analog#018/Power factor Analog#019/Phase-to-earth voltage VL1 Analog#020/Phase-to-earth voltage VL2 Analog#021/Phase-to-earth voltage VL3 Analog#022/Tangent
Length Read
1
1
1
1
1
1
1
1
1
1
1
1
1
1
1
1
1
1
1
1
1
1
1
1
1
1
1
1
1
1
1
1
4
1
4
1
4
1
4
1
4
1
4
1
4
1
4
1
4
1
4
1
Write
Cont. mode
1
1
1
1
1
1
1
1
1
1
1
1
1
1
1
1
1
1
1
1
1
1
1
1
1
1
1
1
1
1
1
1
0
1
0
1
0
1
0
1
0
1
0
1
0
1
0
1
0
1
0
1
P5U20 LPCT LPVT
P5U20 P5V20 P5F30 P5M30
4
1
0
1
4
1
0
1
4
1
0
1
4
1
1
1
4
1
1
1
4
1
1
1
4
1
1
1
4
1
0
1
4
1
0
1
4
1
0
1
4
1
0
1
4
1
0
1
166
P5/EN M/33A
Communication protocols
Class
Name
0x65 0x65
0x65 0x65 0x65 0x65 0x65 0x65 0x65 0x65 0x65 0x65 0x65 0x65 0x65 0x65 0x65 0x65 0x65 0x65 0x65 0x65 0x65 0x65 0x65 0x65 0x65 0x65 0x65 0x65 0x65 0x65
0x65
0x65
Analog#023/Phase current IL
Analog#024/Average PhasePhase voltage
Analog#025/Average Phase-Earth voltage
Analog#026/Phase current THD
Analog#027/Phase current IL1 THD Analog#028/Phase current IL2 THD Analog#029/Phase current IL3 THD Analog#030/HARMONICS of IL1
Analog#031/HARMONICS of IL2
Analog#032/HARMONICS of IL3
Analog#033/Min. of IL1 IL2 IL3
Analog#034/Max. of IL1 IL2 IL3
Analog#035/Phase current ILRMS
Analog#036/Phase current IL1RMS
Analog#037/Phase current IL2RMS
Analog#038/Phase current IL3RMS
Analog#039/Temperature rise
Analog#040/Ambient temperature
Analog#041/Phase current IL1da demand
Analog#042/Phase current IL2da demand
Analog#043/Phase current IL3da demand
Analog#044/IoCalc demand
Analog#045/Io demand
Analog#046/Io' demand
Analog#047/Voltage THD
Analog#048/Phase-Earth VL1 THD Analog#049/Phase-Earth VL2 THD Analog#050/Phase-Earth VL3 THD Analog#051/Harmonics of VL1
Analog#052/Harmonics of VL2
Analog#053/Harmonics of VL3
Analog#054/Min of Phase-Phase voltages
Analog#055/Max of Phase-Phase voltages
Analog#056/Min. of Phase-Earth voltages
Length Read
4
1
4
1
4
1
4
1
4
1
4
1
4
1
4
1
4
1
4
1
4
1
4
1
4
1
4
1
4
1
4
1
4
1
2
1
4
1
4
1
4
1
4
1
4
1
4
1
4
1
4
1
4
1
4
1
4
1
4
1
4
1
4
1
4
1
4
1
Write
0 0
0 0 0 0 0 0 0 0 0 0 0 0 0 0 0 1 0 0 0 0 0 0 0 0 0 0 0 0 0 0
0
0
Cont. mode
1 1
1 1 1
1
1 1 1 1 1 1 1 1
1
1 1 1 1
1
1 1 1 1 1 1
1
1 1 1 1 1
1
1
P5U20 LPCT LPVT
P5U20 P5V20
P5F30 P5M30
P5/EN M/33A
167
Communication protocols
Class
Name
0x65 0x65 0x65 0x65 0x65 0x65 0x65 0x65 0x65 0x65 0x65 0x65 0x65 0x65 0x65 0x65 0x65 0x65 0x65 0x65 0x65 0x65 0x65 0x65 0x65 0x65 0x65 0x65 0x65 0x65 0x65
Analog#057/Max. of Phase-Earth voltages
Analog#058/RMS voltage mean
Analog#059/Phase-Earth voltage VL1RMS
Analog#060/Phase-Earth voltage VL2RMS
Analog#061/Phase-Earth voltage VL3RMS
Analog#062/Phase-Phase U12demand
Analog#063/Phase-Phase U23demand
Analog#064/Phase-Phase U31demand
Analog#065/Phase-Earth VL1demand
Analog#066/Phase-Earth VL2demand
Analog#067/Phase-Earth VL3demand
Analog#068/Cos
Analog#069/Cos of phase L1
Analog#070/Cos of phase L2
Analog#071/Cos of phase L3
Analog#072/Power angle
Analog#073/Phase L1 active power
Analog#074/Phase L2 active power
Analog#075/Phase L3 active power
Analog#076/Phase L1 reactive power
Analog#077/Phase L2 reactive power
Analog#078/Phase L3 reactive power
Analog#079/Phase L1 apparent power
Analog#080/Phase L2 apparent power
Analog#081/Phase L3 apparent power
Analog#082/RMS active power
Analog#083/RMS reactive power
Analog#084/RMS apparent power
Analog#085/Active power demand
Analog#086/Reactive power demand
Analog#087/Apparent power demand
Length Read
4
1
4
1
4
1
4
1
4
1
4
1
4
1
4
1
4
1
4
1
4
1
4
1
4
1
4
1
4
1
2
1
4
1
4
1
4
1
4
1
4
1
4
1
4
1
4
1
4
1
4
1
4
1
4
1
4
1
4
1
4
1
Write
Cont. mode
0
1
0
1
0
1
0
1
0
1
0
1
0
1
0
1
0
1
0
1
0
1
0
1
0
1
0
1
0
1
0
1
0
1
0
1
0
1
0
1
0
1
0
1
0
1
0
1
0
1
0
1
0
1
0
1
0
1
0
1
0
1
P5U20 LPCT LPVT
P5U20 P5V20 P5F30 P5M30
168
P5/EN M/33A
Communication protocols
Class
Name
Length Read
0x65 Analog#088/Power factor demand
4
1
0x65
Analog#089/RMS active power demand
4
1
0x65
Analog#090/RMS reactive power demand
4
1
0x65
Analog#091/RMS apparent power demand
4
1
0x65 Analog#092/Calculated Io
4
1
0x65 Analog#093/Fault current of I>
4
1
0x65 Analog#094/Fault current of I>>
4
1
0x65 Analog#095/Fault current of I>>>
4
1
0x65 Analog#096/Fault reactance
4
1
0x65 Analog#097/Frequency fy
4
1
0x65
Analog#098/Phase-to-Phase voltage U12y
4
1
0x65 Analog#099/Frequency fz
4
1
0x65
Analog#100/Phase-to-Phase voltage U12z
4
1
0x65
Analog#101/Phase angle difference
2
1
0x65 Analog#102/Minimum frequency
4
1
0x65
Analog#103/Minimum active power
4
1
0x65 Analog#104/Minimum react. power
4
1
0x65
Analog#105/Minimum apparent power
4
1
0x65 Analog#106/Min power factor
4
1
0x65 Analog#107/Minimum of Io
4
1
0x65 Analog#108/Minimum of Io'
4
1
0x65
Analog#109/Demand minimum active power
4
1
0x65
Analog#110/Demand minimum reactive power
4
1
0x65
Analog#111/Demand minimum apparent power
4
1
0x65
Analog#112/Demand minimum power factor
4
1
0x65
Analog#113/RMS Demand mini active power
4
1
0x65
Analog#114/RMS Demand min reactive power
4
1
0x65
Analog#115/RMS Demand mini apparent power
4
1
0x65 Analog#116/Minimum of IL1
4
1
0x65 Analog#117/Minimum of IL2
4
1
0x65 Analog#118/Minimum of IL3
4
1
0x65 Analog#119/RMS minimum of IL1
4
1
0x65 Analog#120/RMS minimum of IL2
4
1
Write
0 0 0 0 0 0 0 0 0 0 0 1 0
0 1 1 1 1 1 1 1 1
1
1
1
1
1
1 1 1 1 1 1
Cont. mode
1 1
1
1 1 1 1 1 1 1 1 1 1
1 1 1 1 1 1 1 1 1
1
1
1
1
1
1 1 1 1 1 1
P5U20 LPCT LPVT
P5U20 P5V20
P5F30 P5M30
P5/EN M/33A
169
Communication protocols
Class
Name
0x65 0x65 0x65 0x65 0x65 0x65 0x65 0x65 0x65 0x65 0x65 0x65
0x65
0x65 0x65 0x65 0x65 0x65
0x65
0x65
0x65
0x65
0x65
0x65 0x65 0x65 0x65 0x65 0x65 0x65 0x65 0x65
Analog#121/RMS minimum of IL3
Analog#122/Demand Minimum of IL1
Analog#123/Demand Minimum of IL2
Analog#124/Demand Minimum of IL3
Analog#125/RMS Demand minimum of IL1
Analog#126/RMS Demand minimum of IL2
Analog#127/RMS Demand minimum of IL3
Analog#128/Minimum of U12
Analog#129/Minimum of U23
Analog#130/Minimum of U31
Analog#131/Maximum frequency
Analog#132/Maximum active power
Analog#133/Maximum react. power
Analog#134/Maximum apparent power
Analog#135/Max power factor
Analog#136/Maximum of Io
Analog#137/Maximum of Io'
Analog#138/Demand Maximum active power
Analog#139/Demand maximum reactive power
Analog#140/Demand Maximum apparent power
Analog#141/Demand maximum power factor
Analog#142/RMS Demand max active power
Analog#143/RMS Demand max reactive power
Analog#144/RMS Demand max apparent power
Analog#145/Maximum of IL1
Analog#146/Maximum of IL2
Analog#147/Maximum of IL3
Analog#148/RMS maximum of IL1
Analog#149/RMS maximum of IL2
Analog#150/RMS maximum of IL3
Analog#151/Demand Maximum of IL1
Analog#152/Demand Maximum of IL2
Length Read
4
1
4
1
4
1
4
1
4
1
4
1
4
1
4
1
4
1
4
1
4
1
4
1
4
1
4
1
4
1
4
1
4
1
4
1
4
1
4
1
4
1
4
1
4
1
4
1
4
1
4
1
4
1
4
1
4
1
4
1
4
1
4
1
Write
Cont. mode
1
1
1
1
1
1
1
1
1
1
1
1
1
1
1
1
1
1
1
1
1
1
1
1
1
1
1
1
1
1
1
1
1
1
1
1
1
1
1
1
1
1
1
1
1
1
1
1
1
1
1
1
1
1
1
1
1
1
1
1
1
1
1
1
P5U20 LPCT LPVT
P5U20 P5V20 P5F30 P5M30
170
P5/EN M/33A
Communication protocols
Class
Name
Length Read
0x65
Analog#153/Demand Maximum of IL3
4
1
0x65
Analog#154/RMS Demand maximum of IL1
4
1
0x65
Analog#155/RMS Demand maximum of IL2
4
1
0x65
Analog#156/RMS Demand maximum of IL3
4
1
0x65 Analog#157/Maximum of U12
4
1
0x65 Analog#158/Maximum of U23
4
1
0x65 Analog#159/Maximum of U31
4
1
0x65
Analog#160/Z12 primary impedance
4
1
0x65
Analog#161/Z23 primary impedance
4
1
0x65
Analog#162/Z31 primary impedance
4
1
0x65
Analog#163/Z12 secondary impedance
4
1
0x65
Analog#164/Z23 secondary impedance
4
1
0x65
Analog#165/Z31 secondary impedance
4
1
0x65 Analog#166/Z12 angle
2
1
0x65 Analog#167/Z23 angle
2
1
0x65 Analog#168/Z31 angle
2
1
0x65 Analog#169/Phase current IL1'
4
1
0x65 Analog#170/Phase current IL2'
4
1
0x65 Analog#171/Phase current IL3'
4
1
0x65 Analog#172/IL1 difference
4
1
0x65 Analog#173/IL2 difference
4
1
0x65 Analog#174/IL3 difference
4
1
0x65 Analog#175/Phase current I' THD
4
1
0x65 Analog#176/I'L1 THD
4
1
0x65 Analog#177/I'L2 THD
4
1
0x65 Analog#178/I'L3 THD
4
1
0x65 Analog#179/HARMONICS of I'L1
4
1
0x65 Analog#180/HARMONICS of I'L2
4
1
0x65 Analog#181/HARMONICS of I'L3
4
1
0x65 Analog#182/Min. of I'L1 I'L2 I'L3
4
1
0x65 Analog#183/Max. of I'L1 I'L2 I'L3
4
1
0x65 Analog#184/Phase current I'LRMS
4
1
0x65 0x65 0x65
Analog#185/Phase current IL1'RMS
Analog#186/Phase current IL2'RMS
Analog#187/Phase current IL3'RMS
4
1
4
1
4
1
Write
1
1
1
1 1 1 1 0
0
0
0
0
0 0 0 0 1 1 1 1 1 1 0 0 0 0 0 0 0 0 0 0 1
1
1
Cont. mode
1
1
1
1 1 1 1 1
1
1
1
1
1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1
1
1
P5U20 LPCT LPVT
P5U20 P5V20
P5F30 P5M30
P5/EN M/33A
171
Communication protocols
Class
Name
Length Read
0x65 0x65
Analog#251/Io CSH residual current
Analog#252/Mode of use
4
1
2
1
0x66 StgProtCurrent#001/Enable for I>
1
1
0x66 StgProtCurrent#002/Group
1
1
0x66 StgProtCurrent#003/Pick-up value
4
1
0x66 StgProtCurrent#004/Pick-up value
4
1
0x66
StgProtCurrent#005/Delay curve family
1
1
0x66
StgProtCurrent#006/Delay curve family
1
1
0x66 StgProtCurrent#007/Delay type
1
1
0x66 StgProtCurrent#008/Delay type
1
1
0x66 0x66 0x66 0x66
StgProtCurrent#009/Inv. time coefficient
StgProtCurrent#010/Inv. time coefficient
StgProtCurrent#011/Include harmonics
StgProtCurrent#012/Constant A
4
1
4
1
1
1
4
1
0x66 StgProtCurrent#013/Constant B
4
1
0x66 StgProtCurrent#014/Constant C
4
1
0x66 StgProtCurrent#015/Constant D
4
1
0x66 StgProtCurrent#016/Constant E
4
1
0x66 StgProtCurrent#017/Enable for I>>
1
1
0x66 StgProtCurrent#018/Group
1
1
0x66 StgProtCurrent#019/Pick-up value
4
1
0x66 StgProtCurrent#020/Pick-up value
4
1
0x66
StgProtCurrent#021/Operation delay
4
1
0x66
StgProtCurrent#022/Operation delay
4
1
0x66 0x66
StgProtCurrent#023/Enable for I>>>
StgProtCurrent#024/Group
1
1
1
1
0x66 StgProtCurrent#025/Pick-up value
4
1
0x66 StgProtCurrent#026/Pick-up value
4
1
0x66
StgProtCurrent#027/Operation delay
4
1
0x66
StgProtCurrent#028/Operation delay
4
1
0x66 StgProtCurrent#029/Enable for I>
1
1
0x66 StgProtCurrent#030/Group
1
1
0x66 StgProtCurrent#031/Pick-up value
4
1
0x66 StgProtCurrent#032/Pick-up value
4
1
0x66
StgProtCurrent#033/Direction mode
1
1
Write
Cont. mode
0
1
0
1
1
0
0
0
1
0
1
0
1
0
1
0
1
0
1
0
1
0
1
0
1
0
1
0
1
0
1
0
1
0
1
0
1
0
0
0
1
0
1
0
1
0
1
0
1
0
0
0
1
0
1
0
1
0
1
0
1
0
0
0
1
0
1
0
1
0
P5U20 LPCT LPVT
P5U20 P5V20 P5F30 P5M30
172
P5/EN M/33A
Communication protocols
Class
Name
0x66 0x66 0x66 0x66
0x66 0x66 0x66 0x66
0x66 0x66 0x66 0x66 0x66 0x66 0x66 0x66 0x66 0x66 0x66
0x66 0x66 0x66 0x66
0x66 0x66 0x66 0x66
0x66 0x66 0x66 0x66 0x66 0x66 0x66 0x66
StgProtCurrent#034/Direction mode StgProtCurrent#035/Angle offset
StgProtCurrent#036/Angle offset
StgProtCurrent#037/Delay curve family
StgProtCurrent#038/Delay curve family
StgProtCurrent#039/Delay type
StgProtCurrent#040/Delay type
StgProtCurrent#041/Inv. time coefficient StgProtCurrent#042/Inv. time coefficient StgProtCurrent#043/Constant A
StgProtCurrent#044/Constant B
StgProtCurrent#045/Constant C
StgProtCurrent#046/Constant D
StgProtCurrent#047/Constant E
StgProtCurrent#048/Enable for I>>
StgProtCurrent#049/Group
StgProtCurrent#050/Pick-up value
StgProtCurrent#051/Pick-up value
StgProtCurrent#052/Direction mode StgProtCurrent#053/Direction mode StgProtCurrent#054/Angle offset
StgProtCurrent#055/Angle offset
StgProtCurrent#056/Delay curve family
StgProtCurrent#057/Delay curve family
StgProtCurrent#058/Delay type
StgProtCurrent#059/Delay type
StgProtCurrent#060/Inv. time coefficient StgProtCurrent#061/Inv. time coefficient StgProtCurrent#062/Constant A
StgProtCurrent#063/Constant B
StgProtCurrent#064/Constant C
StgProtCurrent#065/Constant D
StgProtCurrent#066/Constant E
StgProtCurrent#067/Enable for I>>>
StgProtCurrent#068/Group
Length Read
1
1
2
1
2
1
1
1
1
1
1
1
1
1
4
1
4
1
4
1
4
1
4
1
4
1
4
1
1
1
1
1
4
1
4
1
1
1
1
1
2
1
2
1
1
1
1
1
1
1
1
1
4
1
4
1
4
1
4
1
4
1
4
1
4
1
1
1
1
1
Write
1 1 1 1
1 1 1 1
1 1 1 1 1 1 1 0 1 1 1
1 1 1 1
1 1 1 1
1 1 1 1 1 1 1 0
Cont. mode
0 0 0 0
0 0 0 0
0 0 0 0 0 0 0 0 0 0 0
0 0 0 0
0 0 0 0
0 0 0 0 0 0 0 0
P5U20 LPCT LPVT
P5U20 P5V20
P5F30 P5M30
P5/EN M/33A
173
Communication protocols
Class
Name
Length Read
0x66 StgProtCurrent#069/Pick-up value
4
1
0x66 StgProtCurrent#070/Pick-up value
4
1
0x66
StgProtCurrent#071/Direction mode
1
1
0x66
StgProtCurrent#072/Direction mode
1
1
0x66 StgProtCurrent#073/Angle offset
2
1
0x66 StgProtCurrent#074/Angle offset
2
1
0x66
StgProtCurrent#075/Operation delay
4
1
0x66
StgProtCurrent#076/Operation delay
4
1
0x66
StgProtCurrent#077/Enable for I>>>>
1
1
0x66 StgProtCurrent#078/Group
1
1
0x66 StgProtCurrent#079/Pick-up value
4
1
0x66 StgProtCurrent#080/Pick-up value
4
1
0x66
StgProtCurrent#081/Direction mode
1
1
0x66
StgProtCurrent#082/Direction mode
1
1
0x66 StgProtCurrent#083/Angle offset
2
1
0x66 StgProtCurrent#084/Angle offset
2
1
0x66
StgProtCurrent#085/Operation delay
4
1
0x66
StgProtCurrent#086/Operation delay
4
1
0x66
StgProtCurrent#087/Enable for I2/ I1>
1
1
0x66 StgProtCurrent#088/Group
1
1
0x66
StgProtCurrent#089/Pick-up value K2
4
1
0x66
StgProtCurrent#090/Pick-up value K2
4
1
0x66
StgProtCurrent#093/Operation delay
4
1
0x66
StgProtCurrent#094/Operation delay
4
1
0x66 0x66 0x66 0x66 0x66
StgProtCurrent#095/Enable for I2>>
StgProtCurrent#096/Enable for Ist>
StgProtCurrent#097/Motor start detection current
StgProtCurrent#098/Nominal motor start current
StgProtCurrent#099/Delay type
1
1
1
1
4
1
4
1
1
1
0x66
StgProtCurrent#100/Motor start time
4
1
0x66 StgProtCurrent#101/Enable for N>
1
1
0x66
StgProtCurrent#102/Max motor starts/hour
4
1
Write
Cont. mode
1
0
1
0
1
0
1
0
1
0
1
0
1
0
1
0
1
0
0
0
1
0
1
0
1
0
1
0
1
0
1
0
1
0
1
0
1
0
0
0
1
0
1
0
1
0
1
0
1
0
1
0
1
0
1
0
1
0
1
0
1
0
1
0
P5U20 LPCT LPVT
P5U20 P5V20 P5F30 P5M30
174
P5/EN M/33A
Communication protocols
Class
Name
Length Read
0x66
StgProtCurrent#103/Min time between motor starts
4
1
0x66
StgProtCurrent#104/Alarm on event
1
1
0x66
StgProtCurrent#105/Alarm off event
1
1
0x66
StgProtCurrent#106/Motor start disabled
1
1
0x66
StgProtCurrent#107/Motor start enabled
1
1
0x66 StgProtCurrent#108/Enable for I<
1
1
0x66 StgProtCurrent#109/Group
1
1
0x66 StgProtCurrent#110/Pick-up value
4
1
0x66 StgProtCurrent#111/Pick-up value
4
1
0x66
StgProtCurrent#112/Operation delay
4
1
0x66
StgProtCurrent#113/Operation delay
4
1
0x66 StgProtCurrent#117/Enable for dI>
1
1
0x66
StgProtCurrent#118/dI> pick-up (Ibias < 0.5Ign)
4
1
0x66 StgProtCurrent#119/Slope1
4
1
0x66
StgProtCurrent#120/Ibias for start of slope 2
4
1
0x66 StgProtCurrent#121/Slope2
4
1
0x66
StgProtCurrent#122/dI> 2.harm. block enable
1
1
0x66
StgProtCurrent#123/dI> 2.harm. block limit
4
1
0x66
StgProtCurrent#124/Enable for dI>>
1
1
0x66 StgProtCurrent#125/Pick-up value
4
1
0x66 0x66
StgProtCurrent#126/Enable for I'2>
StgProtCurrent#127/Group
1
1
1
1
0x66 StgProtCurrent#128/Pick-up value
4
1
0x66 StgProtCurrent#129/Pick-up value
4
1
0x66 StgProtCurrent#130/Delay type
1
1
0x66 StgProtCurrent#131/Delay type
1
1
0x66
StgProtCurrent#132/Operation delay
4
1
0x66
StgProtCurrent#133/Operation delay
4
1
0x66 StgProtCurrent#134/Enable for I'>
1
1
0x66 StgProtCurrent#135/Group
1
1
0x66 StgProtCurrent#136/Pick-up value
4
1
0x66 StgProtCurrent#137/Pick-up value
4
1
0x66
StgProtCurrent#138/Delay curve family
1
1
Write
1 1 1 1 1 1 0 1 1 1
1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1
1 1 1 1 1 1
Cont. mode
0
0
0
0
0 0 0 0 0 0
0 0 0 0 0 0 0
0
0 0 0 0 0 0 0 0 0
0 0 0 0 0 0
P5U20 LPCT LPVT
P5U20 P5V20
P5F30 P5M30
P5/EN M/33A
175
Communication protocols
Class
Name
Length Read
0x66
StgProtCurrent#139/Delay curve family
1
1
0x66 StgProtCurrent#140/Delay type
1
1
0x66 StgProtCurrent#141/Delay type
1
1
0x66 0x66 0x66
StgProtCurrent#142/Inv. time coefficient
StgProtCurrent#143/Inv. time coefficient
StgProtCurrent#144/Constant A
4
1
4
1
4
1
0x66 StgProtCurrent#145/Constant B
4
1
0x66 StgProtCurrent#146/Constant C
4
1
0x66 StgProtCurrent#147/Constant D
4
1
0x66 StgProtCurrent#148/Constant E
4
1
0x66 0x66
StgProtCurrent#149/Enable for I'>>
StgProtCurrent#150/Group
1
1
1
1
0x66 StgProtCurrent#151/Pick-up value
4
1
0x66 StgProtCurrent#152/Pick-up value
4
1
0x66
StgProtCurrent#153/Operation delay
4
1
0x66
StgProtCurrent#154/Operation delay
4
1
0x67 StgProtEF#001/Enable for Io>
1
1
0x67 StgProtEF#002/Group
1
1
0x67 StgProtEF#003/Pick-up value
4
1
0x67 StgProtEF#004/Pick-up value
4
1
0x67 StgProtEF#005/Delay curve family
1
1
0x67 StgProtEF#006/Delay curve family
1
1
0x67 StgProtEF#007/Delay type
1
1
0x67 StgProtEF#008/Delay type
1
1
0x67 StgProtEF#009/Operation delay
4
1
0x67 StgProtEF#010/Operation delay
4
1
0x67 StgProtEF#012/Constant A
4
1
0x67 StgProtEF#013/Constant B
4
1
0x67 StgProtEF#014/Constant C
4
1
0x67 StgProtEF#015/Constant D
4
1
0x67 StgProtEF#016/Constant E
4
1
0x67 StgProtEF#017/Enable for Io>>
1
1
0x67 StgProtEF#018/Group
1
1
0x67 StgProtEF#019/Pick-up value
4
1
0x67 StgProtEF#020/Pick-up value
4
1
0x67 StgProtEF#021/Operation delay
4
1
0x67 StgProtEF#022/Operation delay
4
1
0x67 StgProtEF#023/Enable for Io>
1
1
Write
Cont. mode
1
0
1
0
1
0
1
0
1
0
1
0
1
0
1
0
1
0
1
0
1
0
1
0
1
0
1
0
1
0
1
0
1
0
0
0
1
0
1
0
1
0
1
0
1
0
1
0
1
0
1
0
1
0
1
0
1
0
1
0
1
0
1
0
0
0
1
0
1
0
1
0
1
0
1
0
P5U20 LPCT LPVT
P5U20 P5V20 P5F30 P5M30
176
P5/EN M/33A
Communication protocols
Class
Name
Length Read
0x67 StgProtEF#024/Group
1
1
0x67 StgProtEF#025/Direction mode
1
1
0x67 StgProtEF#026/Direction mode
1
1
0x67
StgProtEF#027/Char ctrl. in ResCap mode
1
1
0x67
StgProtEF#028/Char ctrl. in ResCap mode
1
1
0x67 StgProtEF#029/Pick-up value
4
1
0x67 StgProtEF#030/Pick-up value
4
1
0x67
StgProtEF#031/Uo setting for Io> stage
4
1
0x67
StgProtEF#032/Uo setting for Io> stage
4
1
0x67 StgProtEF#033/Angle offset
2
1
0x67 StgProtEF#034/Angle offset
2
1
0x67 StgProtEF#035/Pick up sector size
2
1
0x67 StgProtEF#036/Pick up sector size
2
1
0x67 StgProtEF#037/Delay curve family
1
1
0x67 StgProtEF#038/Delay curve family
1
1
0x67 StgProtEF#039/Delay type
1
1
0x67 StgProtEF#040/Delay type
1
1
0x67 StgProtEF#041/Operation delay
4
1
0x67 StgProtEF#042/Operation delay
4
1
0x67 StgProtEF#043/Constant A
4
1
0x67 StgProtEF#044/Constant B
4
1
0x67 StgProtEF#045/Constant C
4
1
0x67 StgProtEF#046/Constant D
4
1
0x67 StgProtEF#047/Constant E
4
1
0x67 StgProtEF#048/Enable for Io>>
1
1
0x67 StgProtEF#049/Group
1
1
0x67 StgProtEF#050/Direction mode
1
1
0x67 StgProtEF#051/Direction mode
1
1
0x67
StgProtEF#052/Char ctrl. in ResCap mode
1
1
0x67
StgProtEF#053/Char ctrl. in ResCap mode
1
1
0x67 StgProtEF#054/Pick-up value
4
1
0x67 StgProtEF#055/Pick-up value
4
1
0x67
StgProtEF#056/Uo setting for Io>> stage
4
1
0x67
StgProtEF#057/Uo setting for Io>> stage
4
1
0x67 StgProtEF#058/Angle offset
2
1
0x67 StgProtEF#059/Angle offset
2
1
0x67 StgProtEF#060/Pick up sector size
2
1
Write
0 1 1 1
1 1 1 1
1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 0 1 1 1
1 1 1 1
1 1 1 1
Cont. mode
0 0 0 0
0 0 0 0
0 0 0 0 0 0 0 0 0 0 0 0 0 0 0 0 0 0 0 0 0
0 0 0 0
0 0 0 0
P5U20 LPCT LPVT
P5U20 P5V20
P5F30 P5M30
P5/EN M/33A
177
Communication protocols
Class
Name
Length Read
0x67 StgProtEF#061/Pick up sector size
2
1
0x67 StgProtEF#062/Delay curve family
1
1
0x67 StgProtEF#063/Delay curve family
1
1
0x67 StgProtEF#064/Delay type
1
1
0x67 StgProtEF#065/Delay type
1
1
0x67 StgProtEF#066/Operation delay
4
1
0x67 StgProtEF#067/Operation delay
4
1
0x67 StgProtEF#068/Constant A
4
1
0x67 StgProtEF#069/Constant B
4
1
0x67 StgProtEF#070/Constant C
4
1
0x67 StgProtEF#071/Constant D
4
1
0x67 StgProtEF#072/Constant E
4
1
0x67 StgProtEF#073/Enable for Io>>>
1
1
0x67 StgProtEF#074/Group
1
1
0x67 StgProtEF#075/Pick-up value
4
1
0x67 StgProtEF#076/Pick-up value
4
1
0x67 StgProtEF#077/Operation delay
4
1
0x67 StgProtEF#078/Operation delay
4
1
0x67
StgProtEF#079/Compensation mode
1
1
0x67
StgProtEF#080/Compensation current
4
1
0x67
StgProtEF#081/Save unbalance current
1
1
0x67
StgProtEF#082/Saving unbal' event
1
1
0x67
StgProtEF#083/Unbal saved' event
1
1
0x67 StgProtEF#084/Enable for Io>>>>
1
1
0x67 StgProtEF#085/Group
1
1
0x67 StgProtEF#086/Pick-up value
4
1
0x67 StgProtEF#087/Pick-up value
4
1
0x67 StgProtEF#088/Operation delay
4
1
0x67 StgProtEF#089/Operation delay
4
1
0x67
StgProtEF#090/Compensation mode
1
1
0x67
StgProtEF#091/Compensation current
4
1
0x67
StgProtEF#092/Save unbalance current
1
1
0x67 StgProtEF#093/Max allowed faults
2
1
0x67
StgProtEF#094/Clear location counters
1
1
0x67
StgProtEF#095/Saving unbal' event
1
1
0x67
StgProtEF#096/Unbal saved' event
1
1
Write
Cont. mode
1
0
1
0
1
0
1
0
1
0
1
0
1
0
1
0
1
0
1
0
1
0
1
0
1
0
0
0
1
0
1
0
1
0
1
0
1
0
1
0
1
0
1
0
1
0
1
0
0
0
1
0
1
0
1
0
1
0
1
0
1
0
1
0
1
0
1
0
1
0
1
0
P5U20 LPCT LPVT
P5U20 P5V20 P5F30 P5M30
178
P5/EN M/33A
Communication protocols
Class
Name
Length Read
0x67 StgProtEF#097/Enable for IoInt>
1
1
0x67 StgProtEF#098/Group
1
1
0x67 StgProtEF#099/Uo pick-up
4
1
0x67 StgProtEF#100/Uo pick-up
4
1
0x67 StgProtEF#101/Operation delay
4
1
0x67 StgProtEF#102/Operation delay
4
1
0x67 StgProtEF#103/Intermittent time
4
1
0x67 StgProtEF#104/Enable for Uo>
1
1
0x67 StgProtEF#105/Group
1
1
0x67 StgProtEF#106/Pick-up value
4
1
0x67 StgProtEF#107/Pick-up value
4
1
0x67 StgProtEF#108/Operation delay
4
1
0x67 StgProtEF#109/Operation delay
4
1
0x67 StgProtEF#110/Enable for Uo>>
1
1
0x67 StgProtEF#111/Group
1
1
0x67 StgProtEF#112/Pick-up value
4
1
0x67 StgProtEF#113/Pick-up value
4
1
0x67 StgProtEF#114/Operation delay
4
1
0x67 StgProtEF#115/Operation delay
4
1
0x67 StgProtEF#116/Enable for ArcIo1>
1
1
0x67 StgProtEF#117/Pick-up value
4
1
0x67 StgProtEF#118/Arc inputs in use
1
1
0x67 StgProtEF#119/Enable for ArcIo2>
1
1
0x67 StgProtEF#120/Pick-up value
4
1
0x67 StgProtEF#121/Arc inputs in use
1
1
0x67 0x67
StgProtEF#122/Enable for Io>>>>>
StgProtEF#123/Group
1
1
1
1
0x67 StgProtEF#124/Pick-up value
4
1
0x67 StgProtEF#125/Pick-up value
4
1
0x67 StgProtEF#126/Operation delay
4
1
0x67 StgProtEF#127/Operation delay
4
1
0x67 StgProtEF#128/Enable for Io>>>
1
1
0x67 StgProtEF#129/Group
1
1
0x67 StgProtEF#130/Direction mode
1
1
0x67 StgProtEF#131/Direction mode
1
1
0x67
StgProtEF#132/Char ctrl. in ResCap mode
1
1
0x67
StgProtEF#133/Char ctrl. in ResCap mode
1
1
0x67 StgProtEF#134/Pick-up value
4
1
0x67 StgProtEF#135/Pick-up value
4
1
Write
1 0 1 1 1 1 1 1 0 1 1 1 1 1 0 1 1 1 1 1 1 1 1 1 1
1
0 1 1 1 1 1 0 1 1
1
1
1 1
Cont. mode
0 0 0 0 0 0 0 0 0 0 0 0 0 0 0 0 0 0 0 0 0 0 0 0 0
0
0 0 0 0 0 0 0 0 0
0
0
0 0
P5U20 LPCT LPVT
P5U20 P5V20
P5F30 P5M30
P5/EN M/33A
179
Communication protocols
Class
Name
Length Read
0x67
StgProtEF#136/Uo setting for Io>>> stage
4
1
0x67
StgProtEF#137/Uo setting for Io>>> stage
4
1
0x67 StgProtEF#138/Angle offset
2
1
0x67 StgProtEF#139/Angle offset
2
1
0x67 StgProtEF#140/Pick up sector size
2
1
0x67 StgProtEF#141/Pick up sector size
2
1
0x67 StgProtEF#142/Delay curve family
1
1
0x67 StgProtEF#143/Delay curve family
1
1
0x67 StgProtEF#144/Delay type
1
1
0x67 StgProtEF#145/Delay type
1
1
0x67 StgProtEF#146/Operation delay
4
1
0x67 StgProtEF#147/Operation delay
4
1
0x67 StgProtEF#148/Constant A
4
1
0x67 StgProtEF#149/Constant B
4
1
0x67 StgProtEF#150/Constant C
4
1
0x67 StgProtEF#151/Constant D
4
1
0x67 StgProtEF#152/Constant E
4
1
0x67 StgProtEF#153/Enable for Uo>>>
1
1
0x67 StgProtEF#154/Group
1
1
0x67 StgProtEF#155/Pick-up value
4
1
0x67 StgProtEF#156/Pick-up value
4
1
0x67 StgProtEF#157/Operation delay
4
1
0x67 StgProtEF#158/Operation delay
4
1
0x67 StgProtEF#159/Enable for Io'>
1
1
0x67 StgProtEF#160/Group
1
1
0x67 StgProtEF#161/Pick-up value
4
1
0x67 StgProtEF#162/Pick-up value
4
1
0x67 StgProtEF#163/Delay curve family
1
1
0x67 StgProtEF#164/Delay curve family
1
1
0x67 StgProtEF#165/Delay type
1
1
0x67 StgProtEF#166/Delay type
1
1
0x67 StgProtEF#167/Operation delay
4
1
0x67 StgProtEF#168/Operation delay
4
1
0x67 StgProtEF#169/Io' input
1
1
0x67 StgProtEF#171/Constant A
4
1
0x67 StgProtEF#172/Constant B
4
1
0x67 StgProtEF#173/Constant C
4
1
0x67 StgProtEF#174/Constant D
4
1
0x67 StgProtEF#175/Constant E
4
1
0x67 StgProtEF#176/Enable for Io'>>
1
1
Write
Cont. mode
1
0
1
0
1
0
1
0
1
0
1
0
1
0
1
0
1
0
1
0
1
0
1
0
1
0
1
0
1
0
1
0
1
0
1
0
0
0
1
0
1
0
1
0
1
0
1
0
0
0
1
0
1
0
1
0
1
0
1
0
1
0
1
0
1
0
1
0
1
0
1
0
1
0
1
0
1
0
1
0
P5U20 LPCT LPVT
P5U20 P5V20 P5F30 P5M30
180
P5/EN M/33A
Communication protocols
Class
Name
Length Read
0x67 StgProtEF#177/Group
1
1
0x67 StgProtEF#178/Pick-up value
4
1
0x67 StgProtEF#179/Pick-up value
4
1
0x67 StgProtEF#180/Operation delay
4
1
0x67 StgProtEF#181/Operation delay
4
1
0x67 StgProtEF#182/Io input
1
1
0x67 StgProtEF#183/Enable for Io'>>>
1
1
0x67 StgProtEF#184/Group
1
1
0x67 StgProtEF#185/Pick-up value
4
1
0x67 StgProtEF#186/Pick-up value
4
1
0x67 StgProtEF#187/Operation delay
4
1
0x67 StgProtEF#188/Operation delay
4
1
0x67 StgProtEF#189/Io input
1
1
0x67 StgProtEF#190/Enable for IoUo>
1
1
0x67 StgProtEF#191/Group
1
1
0x67 StgProtEF#192/Pick-up value
4
1
0x67 StgProtEF#193/Pick-up value
4
1
0x67 StgProtEF#194/Io input
1
1
0x67 StgProtEF#195/Reset time
4
1
0x67 StgProtEF#196/Operation delay
4
1
0x67 StgProtEF#197/Operation delay
4
1
0x67 StgProtEF#198/Direction mode
1
1
0x67 StgProtEF#199/Direction mode
1
1
0x67 StgProtEF#200/Pick up sector size
2
1
0x67 StgProtEF#201/Pick up sector size
2
1
0x67
StgProtEF#202/Timer instant delay ctrl.
1
1
0x67 StgProtEF#203/Enable for IoUo>>
1
1
0x67 StgProtEF#204/Group
1
1
0x67 StgProtEF#205/Pick-up value
4
1
0x67 StgProtEF#206/Pick-up value
4
1
0x67 StgProtEF#207/Io input
1
1
0x67 StgProtEF#208/Reset time
4
1
0x67 StgProtEF#209/Operation delay
4
1
0x67 StgProtEF#210/Operation delay
4
1
0x67 StgProtEF#211/Direction mode
1
1
0x67 StgProtEF#212/Direction mode
1
1
0x67 StgProtEF#213/Pick up sector size
2
1
0x67 StgProtEF#214/Pick up sector size
2
1
0x67
StgProtEF#215/Timer instant delay ctrl.
1
1
0x67 StgProtEF#216/Enable for I2>
1
1
Write
0 1 1 1 1 1 1 0 1 1 1 1 1 1 0 1 1 1 1 1 1 1 1 1 1
1
1 0 1 1 1 1 1 1 1 1 1 1
1
1
Cont. mode
0 0 0 0 0 0 0 0 0 0 0 0 0 0 0 0 0 0 0 0 0 0 0 0 0
0
0 0 0 0 0 0 0 0 0 0 0 0
0
0
P5U20 LPCT LPVT
P5U20 P5V20
P5F30 P5M30
P5/EN M/33A
181
Communication protocols
Class
Name
0x67 0x67 0x67 0x67 0x67 0x67 0x67 0x67 0x67 0x67 0x67 0x67 0x67 0x67 0x67 0x67 0x67 0x67 0x67 0x67 0x67 0x67 0x67 0x67 0x67 0x67 0x67 0x67 0x67 0x67 0x67 0x67 0x67 0x67 0x67 0x67 0x67 0x67 0x68 0x68 0x68
StgProtEF#217/Group StgProtEF#218/Pick-up value StgProtEF#219/Pick-up value StgProtEF#220/Delay curve family StgProtEF#221/Delay curve family StgProtEF#222/Delay type StgProtEF#223/Delay type StgProtEF#224/Operation delay StgProtEF#225/Operation delay StgProtEF#226/Enable for Arc I'> StgProtEF#227/Pick-up value StgProtEF#228/Arc inputs in use StgProtEF#229/Arc I state StgProtEF#230/Arc Io state StgProtEF#231/Arc stage 1 StgProtEF#232/Arc stage 2 StgProtEF#233/Arc stage 3 StgProtEF#234/Arc stage 4 StgProtEF#235/Arc stage 5 StgProtEF#236/Arc stage 6 StgProtEF#237/Arc stage 7 StgProtEF#238/Arc stage 8 StgProtEF#239/Temperature 1 StgProtEF#240/Temperature 2 StgProtEF#241/Temperature 3 StgProtEF#242/Temperature 4 StgProtEF#243/Temperature 5 StgProtEF#244/Temperature 6 StgProtEF#245/Temperature 7 StgProtEF#246/Temperature 8 StgProtEF#247/Temperature 9 StgProtEF#248/Temperature 10 StgProtEF#249/Temperature 11 StgProtEF#250/Temperature 12 StgProtEF#251/Temperature 13 StgProtEF#252/Temperature 14 StgProtEF#253/Temperature 15 StgProtEF#254/Temperature 16 StgProtOther#001/Enable for U> StgProtOther#002/Group StgProtOther#003/Pick-up value
Length
1 4 4 1 1 1 1 4 4 1 4 1 1 1 1 1 1 1 1 1 1 1 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 1 1 4
Read
1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1
Write
0 1 1 1 1 1 1 1 1 1 1 1 0 0 0 0 0 0 0 0 0 0 0 0 0 0 0 0 0 0 0 0 0 0 0 0 0 0 1 0 1
Cont. mode
0 0 0 0 0 0 0 0 0 0 0 0 0 0 0 0 0 0 0 0 0 0 0 0 0 0 0 0 0 0 0 0 0 0 0 0 0 0 0 0 0
P5U20 LPCT LPVT
P5U20 P5V20
P5F30 P5M30
182
P5/EN M/33A
Communication protocols
Class
Name
Length
0x68 StgProtOther#004/Pick-up value
4
0x68 StgProtOther#005/Operation delay
4
0x68 StgProtOther#006/Operation delay
4
0x68 StgProtOther#007/Reset time
4
0x68 StgProtOther#008/Hysteresis
4
0x68 StgProtOther#009/Enable for U>>
1
0x68 StgProtOther#010/Group
1
0x68 StgProtOther#011/Pick-up value
4
0x68 StgProtOther#012/Pick-up value
4
0x68 StgProtOther#013/Operation delay
4
0x68 StgProtOther#014/Operation delay
4
0x68 StgProtOther#015/Hysteresis
4
0x68
StgProtOther#016/Enable for U>>>
1
0x68 StgProtOther#017/Group
1
0x68 StgProtOther#018/Pick-up value
4
0x68 StgProtOther#019/Pick-up value
4
0x68 StgProtOther#020/Operation delay
4
0x68 StgProtOther#021/Operation delay
4
0x68 StgProtOther#022/Hysteresis
4
0x68 StgProtOther#023/Enable for U<
1
0x68 StgProtOther#024/Group
1
0x68 StgProtOther#025/Pick-up value
4
0x68 StgProtOther#026/Pick-up value
4
0x68 StgProtOther#027/Operation delay
4
0x68 StgProtOther#028/Operation delay
4
0x68
StgProtOther#029/Low voltage blocking
4
0x68
StgProtOther#030/Low voltage blocking
4
0x68 StgProtOther#031/Reset time
4
0x68 StgProtOther#032/Hysteresis
4
0x68 StgProtOther#033/Enable for U<<
1
0x68 StgProtOther#034/Group
1
0x68 StgProtOther#035/Pick-up value
4
0x68 StgProtOther#036/Pick-up value
4
0x68 StgProtOther#037/Operation delay
4
0x68 StgProtOther#038/Operation delay
4
0x68
StgProtOther#039/Low voltage blocking
4
0x68
StgProtOther#040/Low voltage blocking
4
0x68 StgProtOther#041/Hysteresis
4
Read
1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1
1
1
1 1 1 1 1 1 1 1
1
1
1
Write
1 1 1 1 1 1 0 1 1 1 1 1 1 0 1 1 1 1 1 1 0 1 1 1 1
0
0
1 1 1 0 1 1 1 1
0
0
1
Cont. mode
0 0 0 0 0 0 0 0 0 0 0 0 0 0 0 0 0 0 0 0 0 0 0 0 0
0
0
0 0 0 0 0 0 0 0
0
0
0
P5U20 LPCT LPVT
P5U20
P5V20
P5F30
P5M30
P5/EN M/33A
183
Communication protocols
Class
Name
Length
0x68
StgProtOther#042/Enable for U<<<
1
0x68 StgProtOther#043/Group
1
0x68 StgProtOther#044/Pick-up value
4
0x68 StgProtOther#045/Pick-up value
4
0x68 StgProtOther#046/Operation delay
4
0x68 StgProtOther#047/Operation delay
4
0x68
StgProtOther#048/Low voltage blocking
4
0x68
StgProtOther#049/Low voltage blocking
4
0x68 StgProtOther#050/Hysteresis
4
0x68 StgProtOther#051/Enable for fX
1
0x68 StgProtOther#052/Group
1
0x68 StgProtOther#053/Pick-up value
4
0x68 StgProtOther#054/Pick-up value
4
0x68 StgProtOther#055/Operation delay
4
0x68 StgProtOther#056/Operation delay
4
0x68
StgProtOther#057/Low voltage blocking
4
0x68 StgProtOther#058/Enable for fXX
1
0x68 StgProtOther#059/Group
1
0x68 StgProtOther#060/Pick-up value
4
0x68 StgProtOther#061/Pick-up value
4
0x68 StgProtOther#062/Operation delay
4
0x68 StgProtOther#063/Operation delay
4
0x68
StgProtOther#064/Low voltage blocking
4
0x68 StgProtOther#065/Enable for f<
1
0x68 StgProtOther#066/Group
1
0x68 StgProtOther#067/Pick-up value
4
0x68 StgProtOther#068/Pick-up value
4
0x68 StgProtOther#069/Operation delay
4
0x68 StgProtOther#070/Operation delay
4
0x68
StgProtOther#071/Low voltage blocking
4
0x68 StgProtOther#072/Enable for f<<
1
0x68 StgProtOther#073/Group
1
0x68 StgProtOther#074/Pick-up value
4
0x68 StgProtOther#075/Pick-up value
4
0x68 StgProtOther#076/Operation delay
4
0x68 StgProtOther#077/Operation delay
4
0x68
StgProtOther#078/Low voltage blocking
4
Read
1 1 1 1 1 1 1
1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1
Write
1 0 1 1 1 1 0
0 1 1 0 1 1 1 1 1 1 0 1 1 1 1 1 1 0 1 1 1 1 1 1 0 1 1 1 1 1
Cont. mode
0 0 0 0 0 0
0
0
0 0 0 0 0 0 0
0
0 0 0 0 0 0
0
0 0 0 0 0 0
0
0 0 0 0 0 0
0
P5U20 LPCT LPVT
P5U20 P5V20
P5F30 P5M30
184
P5/EN M/33A
Communication protocols
Class
Name
Length Read
0x68
StgProtOther#079/Enable for df/ dt>
1
1
0x68 StgProtOther#080/Group
1
1
0x68 StgProtOther#081/Pick-up value
4
1
0x68 StgProtOther#082/Pick-up value
4
1
0x68 StgProtOther#083/Operation delay
4
1
0x68 StgProtOther#084/Operation delay
4
1
0x68 StgProtOther#085/Minimum delay
4
1
0x68 StgProtOther#086/Minimum delay
4
1
0x68 StgProtOther#087/Enable for P<
1
1
0x68 StgProtOther#088/Group
1
1
0x68 StgProtOther#089/Pick-up value
4
1
0x68 StgProtOther#090/Pick-up value
4
1
0x68 StgProtOther#091/Operation delay
4
1
0x68 StgProtOther#092/Operation delay
4
1
0x68 StgProtOther#093/Enable for P<<
1
1
0x68 StgProtOther#094/Group
1
1
0x68 StgProtOther#095/Pick-up value
4
1
0x68 StgProtOther#096/Pick-up value
4
1
0x68 StgProtOther#097/Operation delay
4
1
0x68 StgProtOther#098/Operation delay
4
1
0x68 0x68
StgProtOther#099/Enable for feeder T>
StgProtOther#100/Group
1
1
1
1
0x68
StgProtOther#101/Maximum continuous current
4
1
0x68 StgProtOther#102/Alarm setting
4
1
0x68
StgProtOther#103/Time constant tau
2
1
0x68
StgProtOther#104/Rel. cooling time constant
4
1
0x68
StgProtOther#105/Max overload at +40°C
4
1
0x68
StgProtOther#106/Max overload at +70°C
4
1
0x68
StgProtOther#107/Ambient temperature
2
1
0x68
StgProtOther#108/Ambient temp. sensor
1
1
0x68
StgProtOther#109/Enable for CB fail
1
1
0x68
StgProtOther#110/Monitored Trip relay
1
1
0x68
StgProtOther#111/Timer1 Operation Delay
4
1
0x68
StgProtOther#112/Enable for SOTF
1
1
0x68 StgProtOther#113/Pick-up value
4
1
Write
1 0 1 1 1 1 1 1 1 0 1 1 1 1 1 0 1 1 1 1 1 0 1 1 1
0
0
0
0
0
1
1
1
1 1
Cont. mode
0 0 0 0 0 0 0 0 0 0 0 0 0 0 0 0 0 0 0 0 0 0 0 0 0
0
0
0
0
0
0
0
0
0 0
P5U20 LPCT LPVT
P5U20 P5V20
P5F30 P5M30
P5/EN M/33A
185
Communication protocols
Class
Name
Length Read
0x68 StgProtOther#114/Pick-up value
4
1
0x68
StgProtOther#115/Cold load pickup
1
1
0x68 StgProtOther#116/Inrush detection
1
1
0x68
StgProtOther#117/Enable for df/ dt>>
1
1
0x68 StgProtOther#118/Group
1
1
0x68 StgProtOther#119/Pick-up value
4
1
0x68 StgProtOther#120/Pick-up value
4
1
0x68 StgProtOther#121/Operation delay
4
1
0x68 StgProtOther#122/Operation delay
4
1
0x68 StgProtOther#123/Minimum delay
4
1
0x68 StgProtOther#124/Minimum delay
4
1
0x68 0x69
StgProtOther#125/Enable for Motor T>
StgGeneral#001/CT primary
1
1
4
1
0x69 StgGeneral#002/CT secondary
2
1
0x69 StgGeneral#003/Nominal input
2
1
0x69 StgGeneral#004/Earth CT primary
4
1
0x69
StgGeneral#005/Earth CT secondary
4
1
0x69 StgGeneral#006/Nominal Io1 input
4
1
0x69 StgGeneral#007/Earth CT' primary
4
1
0x69
StgGeneral#008/Earth CT' secondary
4
1
0x69 StgGeneral#009/Nominal Io' input
4
1
0x69 StgGeneral#010/VT primary
4
1
0x69 StgGeneral#011/VT secondary
2
1
0x69 StgGeneral#012/VTo secondary
4
1
0x69 0x69
StgGeneral#013/Motor nominal current
StgGeneral#021/Delay CT supervision
4
1
2
1
0x69 StgGeneral#022/VT supervisor
2
1
0x70 Analog2#001/Frequency
4
1
0x70 Analog2#002/Active power
4
1
0x70 Analog2#003/Reactive power
4
1
0x70 Analog2#004/Apparent power
4
1
0x70
Analog2#005/Phase-to-Phase voltage U12
4
1
0x70
Analog2#006/Phase-to-Phase voltage U23
4
1
0x70
Analog2#007/Phase-to-Phase voltage U31
4
1
0x70 Analog2#008/Power factor
4
1
0x70
Analog2#009/Phase-to-earth voltage VL1
4
1
Write
Cont. mode
1
0
0
0
0
0
1
0
0
0
1
0
1
0
1
0
1
0
1
0
1
0
1
0
1
0
0
0
0
0
1
0
0
0
0
0
1
0
0
0
0
0
1
0
1
0
1
0
1
0
1
0
1
0
0
1
0
1
0
1
0
1
0
1
0
1
0
1
0
1
0
1
P5U20 LPCT LPVT
P5U20 P5V20 P5F30 P5M30
186
P5/EN M/33A
Communication protocols
Class
Name
Length Read
0x70
Analog2#010/Phase-to-earth voltage VL2
4
1
0x70
Analog2#011/Phase-to-earth voltage VL3
4
1
0x70 Analog2#012/Tangent
4
1
0x70
Analog2#013/Average PhasePhase voltage
4
1
0x70
Analog2#014/Average PhaseEarth voltage
4
1
0x70 Analog2#015/Pos. sequence U1
4
1
0x70
Analog2#016/Negative sequence U2
4
1
0x70
Analog2#017/Min of Phase-Phase voltages
4
1
0x70
Analog2#018/Max of Phase-Phase voltages
4
1
0x70
Analog2#019/Min. of Phase-Earth voltages
4
1
0x70
Analog2#020/Max. of Phase-Earth voltages
4
1
0x70 Analog2#021/RMS voltage mean
4
1
0x70
Analog2#022/Phase-Earth voltage VL1RMS
4
1
0x70
Analog2#023/Phase-Earth voltage VL2RMS
4
1
0x70
Analog2#024/Phase-Earth voltage VL3RMS
4
1
0x70
Analog2#025/Phase-Phase U12demand
4
1
0x70
Analog2#026/Phase-Phase U23demand
4
1
0x70
Analog2#027/Phase-Phase U31demand
4
1
0x70
Analog2#028/Phase-Earth VL1demand
4
1
0x70
Analog2#029/Phase-Earth VL2demand
4
1
0x70
Analog2#030/Phase-Earth VL3demand
4
1
0x70 Analog2#031/Cos
4
1
0x70 Analog2#032/Cos of phase L1
4
1
0x70 Analog2#033/Cos of phase L2
4
1
0x70 Analog2#034/Cos of phase L3
4
1
0x70
Analog2#035/Phase L1 active power
4
1
0x70
Analog2#036/Phase L2 active power
4
1
0x70
Analog2#037/Phase L3 active power
4
1
0x70
Analog2#038/Phase L1 reactive power
4
1
0x70
Analog2#039/Phase L2 reactive power
4
1
Write
0 0 0 0 0 0 0 0 0 0 0 0 0 0 0 0 0 0 0 0 0 0 0 0 0 0 0 0 0 0
Cont. mode
1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1
P5U20 LPCT LPVT
P5U20 P5V20
P5F30 P5M30
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Class
Name
Length Read
0x70
Analog2#040/Phase L3 reactive power
4
1
0x70
Analog2#041/Phase L1 apparent power
4
1
0x70
Analog2#042/Phase L2 apparent power
4
1
0x70
Analog2#043/Phase L3 apparent power
4
1
0x70 Analog2#044/RMS active power
4
1
0x70 Analog2#045/RMS reactive power
4
1
0x70
Analog2#046/RMS apparent power
4
1
0x70
Analog2#047/Active power demand
4
1
0x70
Analog2#048/Reactive power demand
4
1
0x70
Analog2#049/Apparent power demand
4
1
0x70
Analog2#050/Power factor demand
4
1
0x70
Analog2#051/RMS active power demand
4
1
0x70
Analog2#052/RMS reactive power demand
4
1
0x70
Analog2#053/RMS apparent power demand
4
1
0x70 Analog2#054/Estimated time to trip
4
1
0x70 Analog2#055/Phase current IL1
4
1
0x70 Analog2#056/Phase current IL2
4
1
0x70 Analog2#057/Phase current IL3
4
1
0x70 Analog2#058/Pos. sequence I1
4
1
0x70
Analog2#059/Negative sequence I2
4
1
0x70 Analog2#060/Current ratio I2/I1
4
1
0x70 Analog2#061/Voltage U2/U1
4
1
0x70 Analog2#063/Estimated time to trip
4
1
Write
Cont. mode
0
1
0
1
0
1
0
1
0
1
0
1
0
1
0
1
0
1
0
1
0
1
0
1
0
1
0
1
0
1
0
1
0
1
0
1
0
1
0
1
0
1
0
1
0
1
P5U20 LPCT LPVT
P5U20 P5V20 P5F30 P5M30
188
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Redundancy protocols
There are three redundancy protocols available as options of Ethernet communication in Easergy P5 protection relays:
· PRP (Parallel Redundancy Protocol)
· HSR (High-availability Seamless Redundancy)
· RSTP (Rapid Spanning Tree Protocol)
Parallel Redundancy Protocol (PRP)
Introduction
The Parallel Redundancy Protocol used in the Easergy P5 protection relays is defined in Clause 4 of the IEC 62439-3 standard. The PRP is a "redundancy in the devices" method that provides bumpless switchover in case of network failure or reintegration. Furthermore, it provides the shortest Ethernet network reconfiguration time as network reconfiguration is seamless.
The Easergy P5 protection relay uses two independent Ethernet ports that operate in parallel on two independent networks. Each message is replicated and sent over both networks. The first network node that receives a message will process it, all later instances of the received message will be discarded. These details of replicating and discarding messages are controlled by the low-level PRP layer of the network architecture, so that the two networks are hidden from the higher level layers. Thus, PRP-based networks provide a high degree of robustness and resilience.
Easergy P5 protection relays support SNMP.
Essentially, a PRP network consists of a pair of similar Local Area Networks (LANs) which can be any topology (tree, ring or mesh). An example of a PRP network is shown in PRP redundancy network, page 190.
The key features of a PRP redundancy network include:
· Each of the two LANs can have one or more "Single Attached Nodes" (SANs). These are normally non-significant devices that are attached only to a single network. SANs can communicate with each other, but only if they are attached to the same LAN.
· Matched pairs of devices have an interface to each LAN, hence they are called "Dual Attached Nodes" (DANs). DANs having the PRP implemented are called "DANs with PRP implemented" (DANP).
· To make the network messages (also known as "frames") be transferred correctly to each device in both LANs, each DANP has to be configured with the same Media Access Control (MAC) code and Internet Protocol (IP) address for both of its ports. As a result, TCP/IP traffic will automatically communicate with both of the paired devices, so it will be unaware of any layer 2 redundancy or frame duplication issues.
· A Redundancy Box is used when a single interface node has to be connected to both LANs. The RedBox can communicate with all other nodes. So far as other nodes are concerned, the RedBox behaves like a DAN, so an IED connected via a RedBox is also called a "Virtual DAN" (VDAN). The RedBox has its own unique IP address.
· The Easergy P5 protection relays have to be connected to the redundant Ethernet network as a Double Attached Node (DAN) using PRP (DAN using PRP is known as DANP).
· The redundant Ethernet interface can be made using an optical fibre connection with an LC connector type (Ethernet card dependent).
· The management of the PRP redundancy is transparent to the application data provided via the Ethernet interface.
· Disconnection of one of the LANs to the device does not cause any degradation to the application data over the Ethernet interface.
· Each supervision frame includes a sequence number as defined in the
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IEC 62439-3 specification. This is incremented for each supervision message and the value starts from zero following a system restart. · Received frames to provide supervision of the redundant network are not processed by Easergy P5 protection relays.
Figure 17 - PRP redundancy network
SAN (A1)
SAN (A2)
DANP (D2)
LAN A LAN B
Redundancy Box (RedBox)
VDAN
VDAN VDAN
DANP (D1)
SAN (B1)
SAN (B2)
Structure of a DANP
Easergy P5 protection relays working in PRP mode work as a DANP each within the overall network topology. Each DANP has two ports that operate in parallel. They are attached to the upper layers of the communications stack through the Link Redundancy Entity (LRE).
Figure 18 - Communication between two DANPs
Double Attached Node (DAN1)
Double Attached Node (DAN2)
Upper Layers Link Redundancy Entity (LRE)
Upper Layers Link Redundancy Entity (LRE)
Tx
Rx
Port A
Tx
Rx
Port B
Tx
Rx
Port A
Tx
Rx
Port B
LAN_A
LAN_B
The LRE has two main tasks: · Handling message frames · Management of redundancy
When an upper layer sends a frame to the LRE, the LRE replicates the frame and sends it through both its ports at nearly the same time. The two frames move through the two LANs with slightly different delays, ideally arriving at the destination node within a small time window.
When receiving frames, the LRE forwards the first frame it received to its upper layers and then discards the duplicate.
As both DANP nodes have the same MAC and IP addresses, this makes redundancy transparent to the upper layers. This allows the Address Resolution Protocol (ARP) to work in the same way as with a SAN. Accordingly, to the upper
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layers of a DANP, the LRE layer shows the same interface as the network adapter of a non-redundant adapter.
To manage redundancy, the LRE: · Adds a 32-bit Redundancy Check Tag (RCT) to each frame it sends · Removes the RCT from each frame it receives
Communication between SANs and DANs
A SAN can be connected to any LAN and can communicate with any other SAN on the same LAN or any DAN. However, a SAN which connected to one LAN can not communicate directly to a SAN which is connected to the other LAN.
A DAN is connected to both LANs and can communicate with any Redundancy Box (RedBox) or any other DANs or any SANs on either network. For communication purposes, a DAN "views" a SAN connected through a RedBox as a VDAN.
When a SAN generates a basic frame, it sends the frame only onto the LAN to which it is connected.
Main characteristics
· One VLAN tag supported · 128 publishers supported per receiver · Up to 100Mbit/s full duplex Ethernet · Dynamic frame memory allocation (page manager) · Configurable duplicate detection · Wishborne interface for configuration and status registers · CPU port interface -- Ethernet or Wishbone · Support for link-local protocols - CPU may send to specific ports only - CPU
knows receive port · Configurable frame memory and queue length · Duplicate detection with configurable size and aging time · MAC address filtering (8 filter masks for interlink, 6 for CPU) · Support for interfaces with or without Ethernet preamble According to the IEC/IEEE 8802-3, the Maximum Transmission Unit (MTU) (Ethernet maximum packet size) is: · 1518 bytes without VLAN and without PRP · 1522 bytes with VLAN and without PRP · 1524 bytes without VLAN and with PRP · 1528 bytes with VLAN and with PRP
NOTE: Check that the LAN switches setting for the MTU is at least 1528 bytes.
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PRP parameters
The redundant Ethernet standard (IEC 62439-3) defines several parameters for the PRP protocol; these being fixed according to the table below:
Table 56 - PRP parameter values
Parameter Supervision Frame Multicast Address Life Check Interval PRP Mode
Entry Forget Time
Node Reboot Interval
Value 01-15-4E-00-01-00
2 s +/- 100 ms Duplicate Discard 400 ms
500 ms
Description
Target MAC Address for multicast supervision frame.
Period between transmission of supervision frames.
This is normal PRP mode, Duplicate address will not be supported.
Duration that the received message Sequence number will be held to discard a duplicate message.
Duration following reboot for which no PRP frames will be transmitted.
High-availability Seamless Redundancy (HSR)
Introduction
The High-availability Seamless Redundancy Protocol used in the Easergy P5 protection relays is defined in Clause 5 of the IEC 62439-3 standard.
The HSR is a "redundancy in the devices" method that provides seamless switchover and recovery in case of a single communication failure or reintegration. HSR Ethernet redundancy method is independent of any industrial Ethernet protocol and typically used in a ring topology.
Easergy P5 protection relays provide two redundant Ethernet ports using HSR. The redundant Ethernet interface can be made using an optical fibre connection with an LC connector type. The management of the HSR redundancy is transparent to the application data provided via the Ethernet interface.
Disconnection of one of the Nodes to the device does not cause any degradation to the application data over the Ethernet interface.
Easergy P5 protection relays support SNMP.
An example of a HSR network is shown in HSR redundancy network, page 193.
The key features of a HSR redundancy network include:
· Nodes within the ring are restricted to be HSR-capable bridging nodes, thus avoiding the use of dedicated bridges.
· Singly Attached Nodes (SANs) such as laptops or printers cannot be attached directly to the ring, but need attachment through a RedBox.
· A simple HSR network consists of doubly attached bridging nodes, each having two ports, interconnected by full-duplex links.
· A source DANH (Double Attached Node with HSR implemented) sends a frame passed from its upper layers, prefixes it by an HSR tag to identify frame duplicates and sends the frame over each port.
· A destination DANH receives, in the fault-free state, two identical frames from each port within a certain interval, if it is a multicast frame, it instantaneously forwards it on the ring, removes the HSR tag of the first frame before passing it to its upper layers and discards any duplicate.
In particular, the node will not forward a frame that it injected into the ring. A destination node of a unicast frame does not forward a frame for which it is the only destination, except for testing.
· Easergy P5 protection relays have to be connected to the redundant Ethernet network as a Double Attached Node (DAN) using HSR (DANH).
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Figure 19 - HSR redundancy network
DANH (D1)
DANH (D2)
DANH (D3)
Redundancy Box (RedBox)
SAN (A1)
SAN (A2)
SAN (A3)
Redundancy Box (RedBox)
VDAN
VDAN VDAN
Structure of a DAN
Easergy P5 protection relays working in HSR Mode work as a DAN within the overall network topology. Each DAN has two ports that operate in parallel. The two HSR ports A and B are connected by the Link Redundancy Entity (LRE), which includes a switching matrix allowing to forward frames from one port to the other. The switching matrix allows cut-through bridging. The LRE presents to the higher layers the same interface as a standard Ethernet transceiver would do.
Figure 20 - Communication between two DANs (in HSR) Double Attached Node (DAN)
Upper Layers
LRE
Tx_B Rx_B
P5/EN M/33A
Tx_A Rx_A
Tx_B Rx_B
LAN_A
LAN_B
DAN node is operable in HSR-tagged forwarding mode, the DAN inserts the HSR tag on behalf of its host and forwards the ring traffic, except for frames sent by the node itself. Duplicate frames and frames where the node is the unicast destination are not forwarded.
Structure of a RedBox
The RedBox has a LRE that performs the duties of the HSR protocol, in particular:
· forwards the frames received from one HSR port to the other HSR port, unless the frame receives frames addressed to its own upper protocols
· prefixes the frames sent by its own upper layers with the corresponding HSR tag before sending two copies over its HSR ports
The switching logic is incorporated into the RedBox, so interlink becomes an internal connection. A simple RedBox is present in every node, since the LRE makes a transition to a single non-HSR host. In addition, it is usual to have more than one host in a node, since a port for maintenance often exists.
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Communication protocols
A node does not send over a port a frame that is a duplicate of a frame previously sent over that port in that same direction. For the purpose of Duplicate Discard, a frame is identified by:
· source MAC address · sequence number The Duplicate Discard method forgets an entry identified by <Source MAC Address><Sequence number> after a time EntryForgetTime.
Communication between SANs, DANs and RedBoxs
Singly Attached Nodes, for instance maintenance laptops or printers cannot be inserted directly into the ring since they have only one port and cannot interpret the HSR tag in the frames. SANs communicate with ring devices through a RedBox that acts as a proxy for the SANs attached to it.
A source DANH sends a frame passed from its upper layers, and prefixes it by an HSR tag to identify frame duplicates and sends the frame over both ports. Each supervision frame includes a sequence number as defined in the IEC 62439- 3 specification. This is incremented for each supervision message and the value starts from zero following a system restart.
A destination DANH receives, in the fault-free state, two identical frames from each port within a certain interval, if it is a multicast frame, it instantaneously forwards it on the ring, removes the HSR tag of the first frame before passing it to its upper layers ("D"- frame) and discards any duplicate.
Main characteristics
· One VLAN tag supported · Up to 128 devices supported · Up to 100Mbit/s full duplex Ethernet · Dynamic frame memory allocation (page manager) · Configurable duplicate detection · Wishbone interface for configuration and status registers · CPU port interface - Wishbone · Support for link-local protocols - CPU may send to specific ports only - CPU
knows receive port · Support for interfaces with or without Ethernet preamble · Configurable frame memory and queue length · Duplicate detection with configurable size and aging time · MAC address filtering (8 filter masks for interlink port, 6 for CPU port) · Support for interfaces with or without Ethernet preamble Limitations: · Number of devices on a same ring at 100 Mbit/s:
Each hop (devices or RedBox) not only carries its own messages but also all the other devices messages thus the bandwidth used is proportional to the number of device. The maximum number of hops is around 20 when the GOOSE messages are highly used or 40 if the number and importance of GOOSE messages is not high. · When Precision Time Protocol, according IEEE1588/IEC 61588 standard, is used: As the GPS receiver inaccuracy is 200 ns and as each hop (devices or RedBox) can add a 50 ns inaccuracy, the maximum number of hops is 16 if 1 s accuracy is required (PMU application or Process Bus).
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HSR parameters
The redundant Ethernet standard (IEC 62439-3) defines several parameters for the HSR protocol; these being fixed according to the table below:
Table 57 - HSR parameter values
Parameter Supervision Frame Multicast Address Life Check Interval HSR Mode
Entry Forget Time
Node Reboot Interval MulticastFilterSize
Value
Description
01-15-4E-00-01-00 2 s +/- 100 ms
Target MAC Address for multicast supervision frame
Period between transmission of supervision frames
Duplicate Discard
This is normal HSR mode, Duplicate address will not be supported.
400 ms
Duration that the received message Sequence number will be held to discard a duplicate message.
500 ms
Duration following reboot for which no PRP frames will be transmitted.
8 Interlink and 6 Nios Number of multicast addresses to be filtered CPU
Rapid Spanning Tree Protocol (RSTP) Introduction
RSTP is a standard used to quickly reconnect a network failure by finding an alternative path, allowing loop-free network topology.
Figure 21 - A redundant Ethernet star or ring circuit
Switch 1
Switch 2
Switch 1
Switch 2
Easergy P5 1
Easergy P5 2
Easergy P5 1
Easergy P5 2
Star connection with redundant ports managed by RSTP blocking function.
Ring connection managed by RSTP blocking function on upper switches and
IEDs interconnected directly.
Although RSTP can recover network failures quickly, the recovery time depends on the number of devices and the topology. The recovery time also depends on the time taken by the devices to determine the root bridge and compute the port roles (discarding, learning, forwarding). The devices do this by exchanging Bridge Protocol Data Units (BPDUs) containing information about bridge devices and root path costs. See the IEEE 802.1w standard for further information.
The RSTP solution is based on open standards. It is therefore compatible with other manufacturers' IEDs that use the RSTP protocol. The typical RSTP recovery time is less than 50 ms for 10 IEDs in a network but it increases with the network size. Due to this recovery time it is not recommended to use RSTP in automation systems where a high availability of GOOSE is essential.
Easergy P5 protection relays provide two redundant Ethernet ports using RSTP. The redundant Ethernet interface can be made using RJ45 or optical fibre connections of LC connector type. The management of the RSTP is transparent to the application data provided via the Ethernet interface. One of the missed node connections to the device does not cause any degradation to the application data over the Ethernet interface.
Easergy P5 protection relays support SNMP.
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RSTP parameters
Table 58 - RSTP parameter values
Parameter Enable for RSTP
Default Value
Yes
Bridge priority
32768
Hello Time
2s
Forward Delay 15 s
Max Age
20 s
Port1 Path Cost 200000
Port1 Priority
128
Port2 Path Cost 200000
Port2 Priority
128
Range
Description
Yes, No
0...65535 (step is 4096) 1...10 s 4...30 s 6...40 s
1...200000 0...255
1...200000 0...255
Enable/disable the use of RSTP protocol on the Ethernet port. (RSTP on Slot L can be enabled or disabled, while RSTP on Slot M is always enabled.)
Parameter used to define the RSTP root device for the network. If priorities of two or more devices are equal then the device with lowest MAC address is chosen as a root.
Setting defines how often RSTP frames (Hello BPDU) are sent.
Time needed for the port to change its state from blocking to forwarding.
The maximum age of the information transmitted by the Bridge when it is the Root Bridge.
Port Cost is related to transfer speed. This is determined according to RSTP specification.
When both Ethernet ports are set connected to the same network segment in such a case the port with worse priority (higher value) is disabled as a backup path for that segment.
Port Cost is related to transfer speed. This is determined according to RSTP specification.
When both Ethernet ports are set connected to the same network segment in such a case the port with worse priority (higher value) is disabled as a backup path for that segment.
The parameters for the RSTP protocol can be configured via:
· front panel
· Protocol configuration view of COMMUNICATION menu of eSetup Easergy Pro or Web HMI
Generic functions for all redundant Ethernet modules
· Ethernet 100Base Fx/Tx
The fibre optic ports are full duplex 100 Mbps LC connectors.
· Forwarding
The devices from the families Easergy P5 protection relays support store and forward mode. The switch forwards messages with known addresses to the appropriate port. The messages with unknown addresses, the broadcast messages and the multicast messages are forwarded out to all ports except the source port. Switches will not forward error packets, 802.3x pause frames or local packets.
NOTE: Forwarding is active when HSR or RSTP protocol is selected.
· Priority Tagging
802.1p priority tagging is enabled on all ports.
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Precision Time Protocol (PTP)
Precision Time Protocol (PTP) communication uses the IEEE 802.3 protocol. PTP communication is only available with PRP/HSR module. A Transparent Clock (TC) is supported on the HSR ring. PTP provides higher time accuracy (500 us).
Introduction to the PTP standards
A protocol is provided in this standard that enables precise synchronization of clocks in measurement and control systems implemented with technologies such as network communication, local computing, and distributed objects. The protocol is applicable to systems communicating via packet networks. Heterogeneous systems are enabled that include clocks of various inherent precision, resolution, and stability to synchronize. System wide synchronization accuracy and precision in the sub-microsecond range are supported with minimal network and local clock computing resources. Simple systems are installed and operated without requiring the management attention of users because the default behaviour of the protocol allows for it.
NOTE: Specific PTP compatible external equipment (switch, time synchronization source, etc.) are needed for Easergy P5 PTP protocols.
PTP implementation
PTP implementation is compliant with IEC 61850-9-3 and IEEE 1588v2/ IEC 61588. Peer-to-peer mode and Best Master Clock algorithm (BMCA) are supported.
Figure 22 - PTP configuration
P5/EN M/33A
Table 59 - PTP parameter values
Parameter
Value
Enable time protocol Yes, No
Domain number
0...255
Precision time state
Initial Faulty
Description
Note
Enable/disable PTP protocol.
Set
Define the permitted domain number of master
Set
clock. If the domainNumber in received PTP
message header is different from the configuration
parameter, the message will be rejected.
The state of PTP.
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Table 59 - PTP parameter values (Continued)
Parameter
Value
Description
Note
Precision time deviation Offset from master
Peer propagation delay Steps removed
Parent clock Id
Parent port number Parent clock class
Parent clock accuracy Parent clock variance Parent priority 1
Parent priority 2
Disabled Listening Pre_master Master Passive Uncalibrated Slave Unit: s
The last time deviation for PTP in s.
Unit: ns, s, ms or s Unit: ns, s, ms or s 0...255
xx-xx-xx-FFFE-xx-xx-xx 0...255 0...255
0...255
0...65535
0...255
0...255
The time difference between a master and a slave computed by the slave.
An estimate of the current one-way propagation delay on the link.
The number of communication paths traversed between the local clock and the grandmaster clock.
The parent clock id.
The number of parent port.
Parent clock attribute defining a clock's TAI traceability.
Parent clock attribute defining the accuracy of a clock.
Parent clock attribute defining the stability of a clock.
The parent priority 1 used in the execution of the best master clock algorithm.
The parent priority 2 used in the execution of the best master clock algorithm.
Simple Network Time Protocol (SNTP)
Simple Network Time Protocol is supported by the Easergy P5 protection relay and the Redundant Ethernet switch. SNTP is used to synchronize the clocks of computer systems over packet-switched, variable-latency data networks. A jitter buffer is used to reduce the effects of variable latency introduced by queuing in packet switched networks, helping to ensure a continuous data stream over the network.
The Easergy P5 protection relays receive the synchronization from the NTP server. This is done using the IP address of the NTP server entered into the Easergy P5 protection relays from the eSetup Easergy Pro or Web HMI.
Figure 23 - Configuring the NTP server
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Client IP address filter
Client IP address filter
The "Client IP Address List" is presented in the "Protocol configuration" section of the "COMMUNICATION" menu in eSetup Easergy Pro. When there is no Ethernet Card in slot L and slot M, this list is hidden. The Client IP address filter, when enabled, defines the exclusive list of IP addresses that are accepted by the Easergy P5 relay. Connections from IP addresses, not part of this list, are rejected.
Figure 24 - The Client IP address list view in the COMMUNICATION menu
Scope Rules
P5/EN M/33A
The "Client IP Address List" is also listed in the general menu of the HMI.
The client IP address filter feature is only implemented for legacy protocols through TCP/IP.
· Modbus TCP/IP · DNP3 TCP · EtherNet/IP
· The feature can be enabled or disabled by clicking "Enable for IP filter". Enabled: The Easergy P5 protection relay filters the client IP address as configured in the table. Disabled: Any client can connect to the Easergy P5 protection relay.
· This feature is common for the legacy protocols supported. · CIDR (Classless Inter-Domain Routing) notation is used to define IP
addresses range, e.g. 192.168.1.191/24, which means IP address 192.168.1.0 ~ 192.168.1.255 are all available. · More than 8 IP addresses ranges are allowed/configured. But dynamically no more than 8 connections are active.
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Client IP address filter
· Only the connection from these IP addresses which are configured in the "Client IP Address List" view can be accepted by the Easergy P5 protection relay.
· Any duplicated IP address is cleared and the "In use" flag is de-selected after clicking the "Implement New IP List" button. For example, if the 2nd and 5th IP address are both "192.168.1.191", then, when clicking the "Implement" button the 5th IP address will be changed to empty, and "in use" is not selected.
· The CIDR IP address range is only active if the 'in use flag' is selected.
· When the number of connections is less than the max. allowed number, the connection from any permitted IP address is accepted.
· When there are already max. clients connected, the first connection is closed if there is new client coming from the same available IP address, otherwise the oldest connection is closed if there is new connection from available client IP.
· The parameter modified takes effect immediately after clicking the "Implement New IP List" button, the Easergy P5 protection relay is not required to reboot. The consequence of applying the IP Filer list (clicking the "Implement New IP List" button) is defined as:
Firmware reads all configuration parameters
Check for duplicated IP addresses
If "Enable for IP Filter" is not selected, all existing connections will be kept, and the communication will be running as usual.
If "Enable for IP Filter" is selected, the connection, whose IP address is allowed (defined in the IP address list), will be kept, and the communication will be running as usual. And all other connections, whose IP addresses are forbidden (not defined in the IP address list), will be closed.
Configuration parameters
Table 60 - Client IP filter configuration parameters
Parameter Enable for IP filter
Value No/Yes
IP address
CIDR prefix In use
Null or available IP address
/1 .... /32
False/True
Implement New IP List
Description This flag indicates whether the client IP filter feature is supported or not. Available IP address to be filtered.
n-bits of CIDR prefix This flag indicates whether this CIDR notation IP address is filtered. Command to Implement New IP List
NOTE: There are 8 instances of "IP address", "CIDR prefix" and "In use" parameters.
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Process
The main sequence diagram is described as below for the condition that:
· The "Enable for IP filter" is Disable
· The "Enable for IP filter" is Enable and the client IP is configured in the filter list.
Figure 25 - Client IP filter
sd IP filter3
Client
1: socket connection() 1.2: ACK()
P5 1.1: accept()
2: get client's IP()
alt: max. 8 clients connected? (Yes)
3: check local connection list()
alt: This IP connected already?
(Yes)
4: Close previous connection() 4.1: ACK()
5: close the oldest connection()
(no)
5.1: ACK()
(no) ref
6: accept this new connection() 7: update local connection list() normal communication
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Secure communication with the eSetup Easergy Pro via the Ethernet interface
Secure communication with the eSetup Easergy Pro via the Ethernet interface
NOTE: The communication is done using port 22. Ensure this port is left unblocked on the network. When Easergy P5 protection relays and eSetup Easergy Pro are connected via the Ethernet interface, they will communicate securely using SSH (Secure Shell).
The benefits of secure communication are: · Help in the prevention of unwanted eavesdropping between eSetup Easergy Pro and the Easergy P5 protection relays. · Help in the prevention of modification of data between eSetup Easergy Pro and the Easergy P5 protection relays. · Ensure integrity of data. · Help to prevent replay of data at a later date.
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Revision history
Revision history
Version number P5/EN M/11A P5/EN M/22A
P5/EN M/33A
Description
Original edition Firmware version Release Firmware version Release All protocols DNP3 Modbus master IEC 60870-5-103
New feature Conformance statement Firmware version Release PTP Modbus
IEC 61850 All protocols Conformance statement
Release date
2019-5
V01 001.029 V01 200.008 Data point list updated
2019-11
File transfer function available Modbus master chapter available
Setting data configurable in IEC 60870-5-103 available
Client IP Address Filter chapter available
Conformance statement for IEC 61850 Edition 1 and 2 updated
V01
2020-07
300.103
Precision Time Protocol available
Modbus read exception status (FC=7) and read device identification (FC=43/14) available
File transfer and setting group available
Data point list updated
Conformance statement for IEC 61850 Edition 1 and 2 updated
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Appendix 1: Abbreviation
Appendix 1: Abbreviation
AP ARP ASDU CID
CIP COS DA DAN DANP DO DS FPGA GoCB GOOSE HTTPS
ICD
IED
IID
LAN LD LN LRE MAC MICS MTU NI PICS PIXIT
RCB RCT RedBox SAN
Access Point
Address Resolution Protocol
Application Service Data Unit
The Configured IED Description (file) is a file used to have communication between an IED configuration tool to an IED. It can be considered as an SCD file stripped down to what the concerned IED need to know and contains a mandatory communication section of the addressed IED.
Common Industrial Protocol
Change of State
Data Attribute
Double Attached Nodes
Double Attached Nodes implementing PRP
Data Object
Dateset
Field Programmable Gate Array
GOOSE Control Block
Generic Object Oriented Substation Event
Secured Hypertext Transfer Protocol (HTTPS) is an extension of the Hypertext Transfer Protocol (HTTP) to help to secure communication over a computer network.
The IED Capability Description (file) completely defines the capabilities of an IED. This file needs to be supplied by each manufacturer to make the complete system configuration. The file contains a single IED section, an optional communication section and an optional substation part which denotes the physical entities corresponding to the IED.
Intelligent Electronic Device This is a term used to describe microprocessor-based controllers of power system equipment. Common types of IEDs include protective relaying devices, load tap changer controllers, circuit breaker controllers, capacitor bank switches, recloser controllers, voltage regulators, etc.
The Instantiated IED Description (file) defines the configuration of one IED for a project and is used as data exchange format from the IED configurator to the system configurator. This file contains only the data for the IED being configured: one IED section, the communication section with the IED's communication parameters, the IED's data type templates, and, optionally, a substation section with the binding of functions (LNodes) to the single line diagram.
Local Area Network
Logical Device
Logical Node
Link Redundancy Entity
Media Access Control
Model Implementation Conformance Statement describes how the information model is implemented.
Maximum Transmission Unit
Network Input
Protocol Implementation Conformance Statement describes choices made in protocol implementation.
Protocol Implementation Extra Information for Testing gives any additional implementation specific information not found in the previous standardized documents.
Report Control Block
Redundancy Check Tag
Redundancy Box
Singly Attached Node
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Appendix 1: Abbreviation
SCADA SCD
SCL
sFTP SNMP SNTP SSH TICS UCMM UDP VDAN XML
Supervisory Control and Data Acquisition
The System (or Substation) Configuration Description is the file describing the complete power utility automation system details. It contains substation, communication, IED and Data type template sections. An SSD file and different ICD files contribute in making an SCD file.
The System Configuration description Language is the language and representation format specified by IEC 61850 for the configuration of electrical substation devices. This includes representation of modeled data and communication services specified by IEC 61850-7-X standard documents. The complete SCL representation and its details are specified in IEC 61850-6 standard document. It includes data representation for substation device entities; its associated functions represented as logical nodes, communication systems and capabilities. The complete representation of data as SCL enhances the different devices of a substation to exchange the SCL files and to have a complete interoperability.
Secured File Transfer Protocol (sFTP) is a network protocol that provides file access, file transfer, and file management over any reliable data stream.
Simple Network Management Protocol (SNMP) is an "Internetstandard protocol for managing devices on IP networks.
Simple Network Time Protocol (SNTP) is a less complex implementation of NTP, using the same protocol but without requiring the storage of state over extended periods of time.
Secure Shell (SSH) is a cryptographic network protocol for operating network services securely over network communication.
Tissues Conformance Statement describes how the device behaves regarding identified technica lissues.
UnConnected Message Manager
User Datagram Protocol
Virtual Double Attached Nodes
Extensible Markup Language
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Appendix 2: IEC 61850 Edition 1 conformance statement
Appendix 2: IEC 61850 Edition 1 conformance statement
Introduction
Document purpose
The purpose of this document is to specify the communication features of the Easergy P5 protection relays embedded IEC 61850 server implementation mapped to IEC 61850 Edition 1 standards.
The model implementation in Easergy P5 protection relays varies with the functional scope provided by the different device models.
The information provided here may be still the subject of changes due to planned further extensions in the supported IEC 61850 functionality.
Terms and abbreviations
Terms / abbreviations ACSI BDA DA DO FCD FCDA ID IED LD LN MSV RCB GoCB SCL SCSM XML GSSE GOOSE SCD ICD CID PICS MICS PIXIT TICS
Definitions
Abstract Communication Service Interfaces Basic Data Attribute (not structured) Data Attributes DATA in IEC 61850-7-2, data object type or instance Functionally Constrained Data Functionally Constrained Data Attribute Identifier Intelligent Electronic Device Logical Device Logical Node Multicast Sampled Value Report Control Block GOOSE Control Block or GSSE Control Block Substation Configuration description Language Specific Communication Service Mapping Extensible Markup Language Generic Substation State Event Generic Object Oriented Substation Event Substation Configuration Description IED Configuration Description Configured IED Description Protocol Implementation Conformance Statement Model Implementation Conformance Statement Protocol Implementation eXtra Information for Testing Tissue Implementation Conformance Statement
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Appendix 2: IEC 61850 Edition 1 conformance statement
PICS details
The PICS is based upon UCAIug PICS Template version 2.3, UCA International Users Group Testing Sub Committee, October 08, 2019.
The following ACSI conformance statements are used to provide an overview and details about following devices: P5U20, P5V20, P5F30, P5M30, with firmware version V01.
· ASCI basic conformance statement · ACSI models conformance statement · ACSI service conformance statement The statements specify the communication features mapped to IEC 61850-8-1 and IEC 61850-9-2, Edition 1.
ASCI basic conformance statement
The basic conformance statement is defined in the table below. Table 61 - Basic conformance statement
ClientServer roles
B11
Server side (of TWO-PARTY-
APPLICATION-ASSOCIATION)
Client /
Server /
Subscriber Publisher
Y
B12
Client side (of TWO-PARTY-
APPLICATION-ASSOCIATION)
SCSMs supported
B21
SCSM: IEC 61850-8-1 used
Y
B22
SCSM: IEC 61850-9-1 used
N
B23
SCSM: IEC 61850-9-2 used
N
B24
SCSM: other
N
Generic substation event model (GSE)
B31
Publisher side
Y
B32
Subscriber side
Y
Transmission of sampled value model (SVC)
B41
Publisher side
B42
Subscriber side
= not applicable
N N
Y = supported
N or empty = not supported
Value / Comments
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Appendix 2: IEC 61850 Edition 1 conformance statement
ASCI models conformance statement
The ACSI models conformance statement is defined in the table below. Table 62 - ASCI models conformance statement
Client /
Server /
Subscriber Publisher
If Server side (B11) and/or Client side (B12) is supported
M1
Logical device
Y
M2
Logical node
Y
M3
Data
Y
M4
Data set
Y
M5
Substitution
N
M6
Setting group control
Y
Reporting
M7
Buffered report control
Y
M7-1 sequence-number
Y
M7-2 report-time-stamp
Y
M7-3 reason-for-inclusion
Y
M7-4 data-set-name
Y
M7-5 data-reference
Y
M7-6 buffer-overflow
Y
M7-7 entryID
Y
M7-8 BufTm
Y
M7-9 IntgPd
Y
M7-10 GI
Y
M7-11 conf-revision
Y
M8
Unbuffered report
Y
control
M8-1 sequence-number
Y
M8-2 report-time-stamp
Y
M8-3 reason-for-inclusion
Y
M8-4 data-set-name
Y
M8-5 data-reference
Y
M8-6 BufTm
Y
M8-7 IntgPd
Y
M8-8 GI
Y
M8-9 conf-revision
Y
Logging
M9
Log control
N
Value / Comments
Only standard LN types defined in Part 7-4. Only standard object types defined in Part 7-3, 7-4.
Mandatory objects and attributes, selected optional objects and attributes.
Supported pre-defined persistent data sets, configurable via SCL. Supported dynamically created data sets (persistent and nonpersistent).
Data set members selection restricted to FC such as ST and MX.
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Appendix 2: IEC 61850 Edition 1 conformance statement
Table 62 - ASCI models conformance statement (Continued)
M9-1 IntgPd M10 Log Other M11 Control M17 File transfer M18 Application
association M19 GOOSE Control Block M20 Sampled Values
Control Block If GSE (B31/32) is supported
M12 GOOSE M13 GSSE If SVC (B41/B42) is supported M14 Multicast SVC M15 Unicast SVC For all IEDs M16 Time
Client /
Server /
Subscriber Publisher
N
N
Y Y Y
Y N
Y N
N N
Y
Y = service is supported N or empty = service is not supported
Value / Comments
Performance class T2 (100s accuracy)
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Appendix 2: IEC 61850 Edition 1 conformance statement
ASCI service conformance statement
The ACSI service conformance statement is defined in the table below (depending on the statements in ASCI basic conformance statement, page 207).
Table 63 - ASCI service conformance statement
Ed ASCI Service Conformance
AA: TP/MC
Server
S1
1,2 GetServerDirectory
TP
(LOGICAL-DEVICE)
Application association
S2
1,2 Associate
S3
1,2 Abort
S4
1,2 Release
Logical device
S5
1,2 LogicalDeviceDirectory TP
Logical node
S6
1,2 LogicalNodeDirectory TP
S7
1,2 GetAllDataValues
TP
Data
S8
1,2 GetDataValues
TP
S9
1,2 SetDataValues
TP
S10
1,2 GetDataDirectory
TP
S11
1,2 GetDataDefinition
TP
Data set
S12
1,2 GetDataSetValues
TP
S13
1,2 SetDataSetValues
TP
S14
1,2 CreateDataSet
TP
S15
1,2 DeleteDataSet
TP
S16
1,2 GetDataSetDirectory TP
Substitution
S17
1
SetDataValues
TP
Setting group control
S18
1,2 SelectActiveSG
TP
S19
1,2 SelectEditSG
TP
S20
1,2 SetSGValues
TP
S21
1,2 ConfirmEditSGValues TP
S22
1,2 GetSGValues
TP
S23
1,2 GetSGCBValues
TP
Reporting
Buffered report control block (BRCB)
S24
1,2 Report
TP
S24-1 1,2 data-change (dchg)
S24-2 1,2 qchg-change (qchg)
S24-3 1,2 data-update (dupd)
Client / Server / Comments Sub (C) Pub (S)
Y
Y Y Y
Y
Y Y
Y Y Y Y
Y N Y Y Y
N
Y Y Y Y Y Y
Y
Y
Y
Y
Accepted as TrgOpt,
but not functionally
supported by the IED
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Appendix 2: IEC 61850 Edition 1 conformance statement
Table 63 - ASCI service conformance statement (Continued)
Ed ASCI Service Conformance
AA: TP/MC
S25
1,2 GetBRCBValues
TP
S26
1,2 SetBRCBValues
TP
Unbuffered report control block (URCB)
S27
1,2 Report
TP
S27-1 1,2 data-change (dchg)
S27-2 1,2 qchg-change (qchg)
S27-3 1,2 data-update (dupd)
S28
1,2 GetURCBValues
TP
S29
1,2 SetURCBValues
TP
Logging
Log control block
S30
1,2 GetLCBValues
TP
S31
1,2 SetLCBValues
TP
Log
S32
1,2 QueryLogByTime
TP
S33
1,2 QueryLogAfter
TP
S34
1,2 GetLogStatusValues
TP
Generic substation event model (GSE)
S35
1,2 SendGOOSEMessage MC
GOOSE Control Block
S36
1,2 GetGoReference
TP
S37
1,2 GetGOOSEElement- TP
Number
S38
1,2 GetGoCBValues
TP
S39
1,2 SetGoCBValues
TP
GSSE (Ed2:61850-7-2 Annex C)
S40
1
SendGSSEMessage MC
GSSE Control Block
S41
1
GetGsReference
TP
S42
1
GetGSSEElement-
TP
Number
S43
1
GetGsCBValues
TP
S44
1
SetGsCBValues
TP
Transmission of sampled value model (SVC)
Multicast SV
S45
1,2 SendMSVMessage
MC
Multicast Sampled Values Control Block
S46
1,2 GetMSVCBValues
TP
S47
1,2 SetMSVCBValues
TP
Unicast SV
Client / Server / Comments Sub (C) Pub (S)
Y
Y
Y
Y
Y
Y
Accepted as TrgOpt,
but not functionally
supported by the IED
Y
Y
N N
N N N
Y
N N Y Y
N
N N N N
N
Use for 9-2LE or IEC
61869-9
N N
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Appendix 2: IEC 61850 Edition 1 conformance statement
Table 63 - ASCI service conformance statement (Continued)
Ed ASCI Service Conformance
AA: TP/MC
S48
1,2 SendUSVMessage
TP
Unicast Sampled Values Control Block
S49
1,2 GetUSVCBValues
TP
S50
1,2 SetUSVCBValues
TP
Control
S51
1,2
Select
S52
1,2 SelectWithValue
TP
S53
1,2 Cancel
TP
S54
1,2 Operate
TP
S55
1,2 CommandTermination TP
S56
1,2 TimeActivatedOperate TP
File Transfer
S57
1,2 GetFile
TP
S58
1,2 SetFile
TP
S59
1,2 DeleteFile
TP
S60
1,2 GetFileAttributeValues TP
S61
1,2 GetServerDirectory
TP
(FILE-SYSTEM)
Time
T1
1,2
Time resolution of internal clock
T2
1,2 Time accuracy of
internal clock
T3
1,2 Supported TimeStamp -
resolution
Client / Server / Comments Sub (C) Pub (S)
N
N N
Y Y Y Y Y N
Y N N Y Y
14
14 for IEEE1588,
10 for IRIG-B,
7 for SNTP and
protocols
T2
Performance class
T2 for IEEE1588,
T1 for IRIG-B,
T0 for SNTP and
protocols
20
Nearest value of 2-n
in seconds
(number 0 ... 24)
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Appendix 2: IEC 61850 Edition 1 conformance statement
MICS details
The MICS is based upon UCAIug MICS Template version 1.2, UCA International Users Group Testing Sub Committee, August 13, 2019.
This model implementation conformance statement is applicable for P5U20, P5V20, P5F30 and P5M30, with firmware version V01.
This MICS document specifies the modeling extensions compared to IEC 61850 Edition 1.
Clause Logical nodes list contains the list of implemented logical nodes.
Clause Logical node extensions describes the new and extended logical nodes (if any).
Clause Enum types extensions describes the new and extended enum types (if any).
Logical nodes list
The following table contains the list of logical nodes implemented in the device: Table 64 - Logical nodes implemented in the device
L: System Logical Nodes
P5U20
LPHD (Physical device information)
x
LLN0 (Logical node zero)
x
P: Logical Nodes for protection functions
PTRC (Protection trip conditioning)
x
PTOC (Time overcurrent)
x
PFRC (Rate of change frequency)
x
PIOC (Instantaneous overcurrent)
x
PTOF (Over frequency)
x
PTOV (Overvoltage)
x
PDOP (Directional overpower)
x
PTUC (Undercurrent)
x
PTTR (Thermal overload)
x
PTUF (Under frequency)
x
PTUV (Under voltage)
x
PMRI (Motor restart inhibition)
x
PMSS (Motor starting time supervision)
x
PTEF (Transient earth fault)
PADM (Admittance)
POVS (Motor overspeed)
x
PZSU (Motor underspeed)
x
PHAR (Harmonic restraint)
x
R: Logical nodes for protection related functions
RREC (Auto reclosing)
x
RDRE (Disturbance recorder)
x
RFLO (Fault locator)
P5V20
P5F30
P5M30
x
x
x
x
x
x
x
x
x
x
x
x
x
x
x
x
x
x
x
x
x
x
x
x
x
x
x
x
x
x
x
x
x
x
x
x
x
x
x
x
x
x
x
x
x
x
x
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Appendix 2: IEC 61850 Edition 1 conformance statement
Table 64 - Logical nodes implemented in the device (Continued)
RSYN (Synchronism-check)
P5U20
P5V20 x
G: Logical Nodes for generic references
GGIO (Generic process I/O)
x
x
GAPC (Generic automatic process control) x
x
M: Logical Nodes for metering and measurement
MMTR (Metering)
x
MMXU (Measurement)
x
x
MHAI (Harmonics)
x
x
C: Logical Nodes for control
CSWI (Switch controller)
x
x
T: Logical nodes for instrument transformers and sensors
TCTX (Current transformer)
x
TVTX (Voltage transformer)
x
x
P5F30 x
x x
x x x
x
x x
P5M30
x x
x x x
x
x x
Logical node extensions
The following table uses: · M: Data is mandatory in the IEC 61850-7-4. · O: Data is optional in the IEC 61850-7-4 and is used in the device. · C: Data is conditional in the IEC 61850-7-4 and is used in the device. · E: Data is an extension to the IEC 61850-7-4.
New logical nodes
Newly created logical nodes are listed in this clause, with lnNs attribute in the Name plate.
PADM Admittance This LN shall be used for protection admittance E/F Io/Uo.
Data object name
P5EFPADM1 P5EFPADM2
Common data class
Data Objects
Common Logical Node Information
Mod
INC
Beh
INS
Health
INS
NamPlt
LPL
Status Information YStr YOp
ACD ACT
GStr
ACD
PADM class Explanation
The name shall be composed of the class name, the LN-Prefix and LN-Instance-ID according to IEC 61850-7-2, Clause 22.
Mode Behaviour Health Name plate
YN start YN operate GN start
M/O/ Remarks C/E
E
M
Status-only
M M M
E E E
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Appendix 2: IEC 61850 Edition 1 conformance statement
Data object name
GOp BStr BOp Settings FunEna YFunEna GFunEna BFunEna UoStrVal CorAng YStrVal YOpDlTms YRsDlTms YSolMod YSlOpDlTms GStrVal GDirMod GOpDlTms GRsDlTms GSolMod GSlOpDlTms BStrVal BDirMod BOpDlTms BRsDlTms BSolMod BSlOpDlTms
Common data class ACT
ACD ACT
PADM class Explanation
GN operate BN start BN operate
SPG SPG SPG SPG ASG ASG ASG ASG ASG SPG ASG ASG ING ASG ASG SPG ASG ASG ING ASG ASG SPG ASG
Whole function enable YN function enable GN function enable BN function enable Uo pick-up value Correction angle YN pick-up value YN operate delay time YN reset time YN SOL mode YN SOL operate delay time GN pick-up value GN direction mode GN operate delay time GN reset time GN SOL mode GN SOL operate delay time BN pick-up value BN direction mode BN operate delay time BN reset time BN SOL mode BN SOL operate delay time
M/O/ Remarks C/E E E E
E E E E E E E E E E E E E E E E E E E E E E E
POVS Motor overspeed This LN shall be used for protection motor overspeed.
Data object name
P5MOTPOVS1 P5MOTPOVS2
Common data class
Data Objects
Common Logical Node Information
Mod
INC
Beh
INS
Health
INS
NamPlt
LPL
Status Information
POVS class Explanation
The name shall be composed of the class name, the LN-Prefix and LN-Instance-ID according to IEC 61850-7-2, Clause 22.
Mode Behaviour Health Name plate
M/O/ Remarks C/E
E
M
Status-only
M M M
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Appendix 2: IEC 61850 Edition 1 conformance statement
Data object name
Str Op Settings FunEna StrVal OpDlTms
Common data class
ACD
ACT
POVS class Explanation
Start Operate
SPG ASG ASG
Function enable Pick-up value Operate delay time
M/O/ Remarks C/E E E
E E E
TCTX Current transformer This LN shall be used for protection current transformer parameters.
Data object name P5ITCTX1
Common data class
Data Objects
Common Logical Node Information
Mod
INC
Beh
INS
Health
INS
NamPlt
LPL
Status Information
TCTX class Explanation
The name shall be composed of the class name, the LN-Prefix and LN-Instance-ID according to IEC 61850-7-2, Clause 22.
Mode Behaviour Health Name plate
M/O/ Remarks C/E
E
M
Status-only
M M M
Measured and metered values
Settings FunEna CTNum OpDlTmms PriPhs SecPhs
SPG ING ING ASG ASG
Function enable
E
Number of connected phase CT E
Operate delay time
E
CT primary
E
CT secondary
E
Data object name P5IOTCTX1
Common data class
Data Objects
Common Logical Node Information
Mod
INC
Beh
INS
Health
INS
NamPlt
LPL
Status Information
TCTX class Explanation
The name shall be composed of the class name, the LN-Prefix and LN-Instance-ID according to IEC 61850-7-2, Clause 22.
Mode Behaviour Health Name plate
M/O/ C/E E
M M M M
Remarks Status-only
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Appendix 2: IEC 61850 Edition 1 conformance statement
Data object name
Common data class
TCTX class Explanation
M/O/ Remarks C/E
Measured and metered values
Settings
PriNeut1
ASG
Io CT primary
E
PriNeut2
ASG
Io' CT primary
E
Data object name P5LPITCTX1
Common data class
TCTX class
Explanation
The name shall be composed of the class name, the LN-Prefix and LN-Instance-ID according to IEC 61850-7-2, Clause 22.
Data Objects
Common Logical Node Information
Mod
INC
Mode
Beh Health NamPlt
INS
Behaviour
INS
Health
LPL
Name plate
Status Information
M/O/ C/E E
M M M M
Remarks Status-only
Measured and metered values
ExtPri
MV
Rated ext. primary current In
E
Settings
FunEna
SPG
Function enable
E
OpDlTmms
ING
Operate delay time
E
NomPri
ASG
LPCT rated primary current
E
TVTX Voltage transformer This LN shall be used for protection voltage transformer parameters.
Data object name P5UTVTX1
Common data class
TVTX class
Explanation
The name shall be composed of the class name, the LN-Prefix and LN-Instance-ID according to IEC 61850-7-2, Clause 22.
Data Objects
Common Logical Node Information
Mod
INC
Mode
Beh Health NamPlt
INS
Behaviour
INS
Health
LPL
Name plate
Status Information
M/O/ C/E E
M M M M
Remarks Status-only
Measured and Metered Values
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Appendix 2: IEC 61850 Edition 1 conformance statement
Data object name
Common data class
TVTX class Explanation
M/O/ Remarks C/E
Settings
FunEna
SPG
Function enable
E
ImbAMinLev
ASG
I2 min. setting
E
ImbVMaxLev
ASG
U2 max. setting
E
OpDlTmms
ING
Operate delay time
E
PriPhs
ASG
VT primary
E
SecNeut
ASG
VTo secondary
E
SecPhs
ASG
VT secondary
E
Data object name P5LPUTVTX1
Common data class
TVTX class
Explanation
The name shall be composed of the class name, the LN-Prefix and LN-Instance-ID according to IEC 61850-7-2, Clause 22.
Data Objects
Common Logical Node Information
Mod
INC
Mode
Beh Health NamPlt
INS
Behaviour
INS
Health
LPL
Name plate
Status Information
M/O/ C/E E
M M M M
Remarks Status-only
Measured and Metered Values
ExtPri
MV
Settings
FunEna PhAMagCor
SPG ASG
PhBMagCor
ASG
PhCMagCor
ASG
PhAAngCor
ASG
PhBAngCor
ASG
PhCAngCor
ASG
VL1yMagCor
ASG
VL1yAngCor
ASG
VL2yMagCor
ASG
VL2yAngCor
ASG
VtTyp
ING
VtSecAdpt
ASG
PhAMagAdpt
ASG
PhBMagAdpt
ASG
PhCMagAdpt
ASG
Rated ext. primary current In
E
Function enable
E
VL1 magnitude correction
E
VL2 magnitude correction
E
VL3 magnitude correction
E
VL1 Angle correction
E
VL2 Angle correction
E
VL3 Angle correction
E
VL1y magnitude correction
E
VL1y Angle correction
E
VL2y magnitude correction
E
VL2y Angle correction
E
Primary VT type
E
VT secondary rated voltage
E
VL1 Adapt magnitude correction E
VL2 Adapt magnitude correction E
VL3 Adapt magnitude correction E
218
P5/EN M/33A
Appendix 2: IEC 61850 Edition 1 conformance statement
Data object name
VlSecAdpt VL1yMagAdt
Common data class
ASG
ASG
TVTX class Explanation
VTy secondary rated voltage VL1y Adapt magnitude correction
M/O/ C/E
E
E
Remarks
Data object name P5LPUTVTX2
Common data class
TVTX class
Explanation
The name shall be composed of the class name, the LN-Prefix and LN-Instance-ID according to IEC 61850-7-2, Clause 22.
Data Objects
Common Logical Node Information
Mod
INC
Mode
Beh Health NamPlt
INS
Behaviour
INS
Health
LPL
Name plate
Status Information
M/O/ C/E E
M M M M
Remarks Status-only
Measured and Metered Values
ExtPri
MV
Settings
FunEna NomPri
SPG ASG
PhAMagCor
ASG
PhBMagCor
ASG
PhCMagCor
ASG
PhAAngCor
ASG
PhBAngCor
ASG
PhCAngCor
ASG
VL1yMagCor
ASG
VL1yAngCor
ASG
VtTyp
ING
VtSecAdpt
ASG
PhAMagAdpt
ASG
PhBMagAdpt
ASG
PhCMagAdpt
ASG
VlSecAdpt
ASG
VL1yMagAdt
ASG
Rated ext. primary current In
E
Function enable
E
LPVT rated primary voltage
E
VL1 magnitude correction
E
VL2 magnitude correction
E
VL3 magnitude correction
E
VL1 Angle correction
E
VL2 Angle correction
E
VL3 Angle correction
E
VL1y magnitude correction
E
VL1y Angle correction
E
Primary VT type
E
VT secondary rated voltage
E
VL1 Adapt magnitude correction E
VL2 Adapt magnitude correction E
VL3 Adapt magnitude correction E
VTy secondary rated voltage
E
VL1y Adapt magnitude correction E
Data object name P5LPUTVTX3
Data Objects
Common data class
TVTX class
Explanation
The name shall be composed of the class name, the LN-Prefix and LN-Instance-ID according to IEC 61850-7-2, Clause 22.
M/O/ C/E
E
Remarks
P5/EN M/33A
219
Appendix 2: IEC 61850 Edition 1 conformance statement
TVTX class
Data object name
Common data class
Explanation
Common Logical Node Information
Mod
INC
Mode
Beh Health NamPlt
INS
Behaviour
INS
Health
LPL
Name plate
Status Information
M/O/ Remarks C/E
M
Status-only
M M M
Measured and Metered Values
ExtPri
MV
Settings
FunEna NomPri
SPG ASG
PhAMagCor
ASG
PhBMagCor
ASG
PhCMagCor
ASG
PhAAngCor
ASG
PhBAngCor
ASG
PhCAngCor
ASG
VtTyp
ING
VtSecAdpt
ASG
PhAMagAdpt
ASG
PhBMagAdpt
ASG
PhCMagAdpt
ASG
UoSecAdpt
ASG
UoMagAdt
ASG
Rated ext. primary current In
E
Function enable
E
LPVT rated primary voltage
E
VL1 magnitude correction
E
VL2 magnitude correction
E
VL3 magnitude correction
E
VL1 Angle correction
E
VL2 Angle correction
E
VL3 Angle correction
E
Primary VT type
E
VT secondary rated voltage
E
VL1 Adapt magnitude correction E
VL2 Adapt magnitude correction E
VL3 Adapt magnitude correction E
Uo secondary rated voltage
E
Uo Adapt magnitude correction
E
Data object name P5LPUTVTX4
Common data class
TVTX class
Explanation
The name shall be composed of the class name, the LN-Prefix and LN-Instance-ID according to IEC 61850-7-2, Clause 22.
Data Objects
Common Logical Node Information
Mod
INC
Mode
Beh Health NamPlt
INS
Behaviour
INS
Health
LPL
Name plate
Status Information
M/O/ C/E E
M M M M
Remarks Status-only
Measured and Metered Values
ExtPri
MV
Rated ext. primary current In
E
Settings
220
P5/EN M/33A
Appendix 2: IEC 61850 Edition 1 conformance statement
Data object name
FunEna NomPri PhAMagCor PhBMagCor PhCMagCor PhAAngCor PhBAngCor PhCAngCor VtTyp VtSecAdpt PhAMagAdpt PhBMagAdpt PhCMagAdpt
Common data class SPG ASG ASG ASG ASG ASG ASG ASG ING ASG ASG ASG ASG
TVTX class Explanation
Function enable LPVT rated primary voltage VL1 magnitude correction VL2 magnitude correction VL3 magnitude correction VL1 Angle correction VL2 Angle correction VL3 Angle correction Primary VT type VT secondary rated voltage VL1 Adapt magnitude correction VL2 Adapt magnitude correction VL3 Adapt magnitude correction
M/O/ C/E E E E E E E E E E E E E E
Remarks
Standardized and extended DO of logical node type
The following table presents a summary of the standardized and extended DO of each Logical Node Type.
LN Type: SE_GAPC_PS_EasergyP5_V001 Description: Generic automatic process control LN Class: GAPC
Data object name P5PSGAPC1...8
Common data class
GAPC class
Explanation
The name shall be composed of the class name, the LN-Prefix and LN-Instance-ID according to IEC 61850-7-2, Clause 22.
Data Objects
Common Logical Node Information
Mod
INC
Mode
Beh Health NamPlt
INS
Behaviour
INS
Health
LPL
Name plate
Status Information Str Op
ACD ACT
Start Operate
Settings
FunEna
SPG
Function enable
M/O/ C/E M
M M M M
M M
E
Remarks Status-only
LN Type: SE_GGIO_AR_EasergyP5FU_V001 Description: Generic process I/O LN Class: GGIO
P5/EN M/33A
221
Appendix 2: IEC 61850 Edition 1 conformance statement
Data object name P5ARGGIO1
Common data class
GGIO class
Explanation
The name shall be composed of the class name, the LN-Prefix and LN-Instance-ID according to IEC 61850-7-2, Clause 22.
Data Objects
Common Logical Node Information
Mod
INC
Mode
Beh Health NamPlt
INS
Behaviour
INS
Health
LPL
Name plate
Status Information Ind1
SPS
AR1 final trip
Ind2
SPS
AR2 final trip
Ind3
SPS
AR3 final trip
Ind4
SPS
AR4 final trip
Ind5
SPS
AR5 final trip
Ind6
SPS
AR6 final trip
Ind7
SPS
AR7 final trip
Ind8
SPS
AR8 final trip
Ind9
SPS
AR9 final trip
Ind10
SPS
AR10 final trip
Ind11
SPS
AR11 final trip
Ind12
SPS
AR12 final trip
Ind13
SPS
AR13 final trip
Ind14
SPS
AR14 final trip
Ind15
SPS
AR15 final trip
Ind16
SPS
AR16 final trip
Ind17
SPS
AR17 final trip
Ind18
SPS
AR18 final trip
Ind19
SPS
AR19 final trip
Settings
FunEna
SPG
Function enable
M/O/ C/E M
M M M M
O O O O O O O O O O O O O O O O O O O
E
Remarks Status-only
LN Type: SE_GGIO_CBWA_EasergyP5FMU_V002 Description: Generic process I/O LN Class: GGIO
Data object name P5CBWAGGIO1
Common data class
GGIO class
Explanation
The name shall be composed of the class name, the LN-Prefix and LN-Instance-ID according to IEC 61850-7-2, Clause 22.
Data Objects
Common Logical Node Information
Mod
INC
Mode
M/O/ C/E M
M
Remarks Status-only
222
P5/EN M/33A
Appendix 2: IEC 61850 Edition 1 conformance statement
Data object name
Beh Health NamPlt Status Information Ind1 Ind2 Alm1Phs1 Alm1Phs2 Alm1Phs3 Alm2Phs1 Alm2Phs2 Alm2Phs3 Settings FunEna CBOpenCnt RackOutCnt TripCnt AlmLev1 AlmLev2 LimOpNum1 LimOpNum2
Common data class INS INS LPL
SPS SPS INS INS INS INS INS INS
SPG ING ING ING ASG ASG ASG ASG
GGIO class Explanation
Behaviour Health Name plate
General indication (binary input) General indication (binary input) Alarm 1 of Phase 1 Alarm 1 of Phase 2 Alarm 1 of Phase 3 Alarm 2 of Phase 1 Alarm 2 of Phase 2 Alarm 2 of Phase 3
Function enable CB open counter Rack out counter Protection trip counter Alarm level 1 Alarm level 2 Limit for operate left 1 Limit for operate left 2
M/O/ C/E M
M
M
Remarks
O O E E E E E E
E E E E E E E E
LN Type: SE_MMXU_VECA_EasergyP5FMU_VSI_V001 Description: Measurement LN Class: MMXU
Data object name P5VECAMMXU1
Common data class
MMXU class
Explanation
The name shall be composed of the class name, the LN-Prefix and LN-Instance-ID according to IEC 61850-7-2, Clause 22.
Data Objects
Common Logical Node Information
Mod
INC
Mode
Beh Health NamPlt
INS
Behaviour
INS
Health
LPL
Name plate
Measured values
Hz
MV
Frequency
A
WYE
Phase currents (IL1, IL2, IL3)
Iovs
WYE
Residual current Io'
M/O/ C/E M
M M M M
O O E
Remarks Status-only
LN Type: SE_PDOP_REVP_EasergyP5FM_V002 Description: Directional overpower LN Class: PDOP
P5/EN M/33A
223
Appendix 2: IEC 61850 Edition 1 conformance statement
Data object name
P5REVPPDOP1 P5REVPPDOP2
Common data class
PDOP class
Explanation
The name shall be composed of the class name, the LN-Prefix and LN-Instance-ID according to IEC 61850-7-2, Clause 22.
Data Objects
Common Logical Node Information
Mod
INC
Mode
Beh Health NamPlt
INS
Behaviour
INS
Health
LPL
Name plate
Status Information Str Op
ACD ACT
Start Operate
Settings
FunEna StrVal
SPG ASG
Function enable Pick-up value
OpDlTms
ASG
Operate delay time
M/O/ C/E M
M M M M
M M
E O E
Remarks Status-only
LN Type: SE_PDOP_EF_EasergyP5FM_V002 Description: Directional overpower LN Class: PDOP
Data object name
P5EFPDOP1 P5EFPDOP2
Common data class
PDOP class
Explanation
The name shall be composed of the class name, the LN-Prefix and LN-Instance-ID according to IEC 61850-7-2, Clause 22.
Data Objects
Common Logical Node Information
Mod
INC
Mode
Beh Health NamPlt
INS
Behaviour
INS
Health
LPL
Name plate
Status Information Str Op
ACD ACT
Start Operate
Settings
FunEna DirMode StrVal
SPG ING ASG
Function enable Direction mode Pick-up value
UoStrVal
ASG
Uo setting
SctrStrVal
ASG
Pick up sector size
OpDlTms
ASG
Operate delay time
SolMod SolOpDlTms
SPG ASG
SOL Mode SOL operate delay time
M/O/ C/E M
M M M M
M M
E E M E E E E E
Remarks Status-only
224
P5/EN M/33A
Appendix 2: IEC 61850 Edition 1 conformance statement
Data object name
MemMod MmUoStrVal MemTms
Common data class ING
ASG
ASG
PDOP class Explanation
Memory Mode Uo setting Memory time
M/O/ C/E E
E
E
Remarks
LN Type: SE_PFRC_DFDT_EasergyP5FV_V002 SE_PFRC_DFDT_EasergyP5U_LPT_V002 Description: Rate of change of frequency LN Class: PFRC
Data object name
P5DFDTPFRC1 P5DFDTPFRC2 P5DFTLPFRC1 P5DFTLPFRC2 Data Objects
Common data class
PFRC class
Explanation
The name shall be composed of the class name, the LN-Prefix and LN-Instance-ID according to IEC 61850-7-2, Clause 22.
Common Logical Node Information
Mod
INC
Mode
Beh Health NamPlt
INS
Behaviour
INS
Health
LPL
Name plate
Status Information Str Op
ACD ACT
Start Operate
Settings
FunEna DirChg
SPG ING
Function enable Direction of change
StrVal
ASG
Pick-up value
OpDlTms
ASG
Operate delay time
M/O/ C/E M
M M M M
M M
E E O E
Remarks Status-only
LN Type: SE_PIOC_CBFP_EasergyP5FMU_V002 Description: Instantaneous overcurrent LN Class: PIOC
Data object name P5CBFPPIOC1
Common data class
PIOC class
Explanation
The name shall be composed of the class name, the LN-Prefix and LN-Instance-ID according to IEC 61850-7-2, Clause 22.
Data Objects
Common Logical Node Information
Mod
INC
Mode
Beh Health NamPlt
INS
Behaviour
INS
Health
LPL
Name plate
Status Information
M/O/ C/E M
M M M M
Remarks Status-only
P5/EN M/33A
225
Appendix 2: IEC 61850 Edition 1 conformance statement
Data object name
Str Op Settings FunEna NeutStrVal
PhsStrVal
Tm1DlTms Tm1Ena Tm2DlTms Tm2Ena
Common data class ACD ACT
SPG ASG
ASG
ASG SPG ASG SPG
PIOC class Explanation
Start Operate
M/O/ C/E
O
M
Remarks
Function enable
E
Undercurrent threshold for earth E fault current
Undercurrent threshold for phase E current
Timer1 operate delay time
E
Enable CBF timer1
E
Timer2 operate delay time
E
Enable CBF timer2
E
LN Type: SE_PIOC_CBFP_EasergyP5V_V002 Description: Instantaneous overcurrent LN Class: PIOC
Data object name P5CBFPPIOC2
Common data class
PIOC class
Explanation
The name shall be composed of the class name, the LN-Prefix and LN-Instance-ID according to IEC 61850-7-2, Clause 22.
Data Objects
Common Logical Node Information
Mod
INC
Mode
Beh Health NamPlt
INS
Behaviour
INS
Health
LPL
Name plate
Status Information Str Op
ACD ACT
Start Operate
Settings
FunEna Tm1DlTms
SPG ASG
Function enable Timer1 operate delay time
Tm1Ena Tm2DlTms
SPG ASG
Enable CBF timer1 Timer2 operate delay time
Tm2Ena
SPG
Enable CBF timer2
M/O/ C/E M
M M M M
O M
E E E E E
Remarks Status-only
LN Type: SE_PIOC_CBFP_EasergyP5FMU_VSI_V001 Description: Instantaneous overcurrent LN Class: PIOC
226
P5/EN M/33A
Appendix 2: IEC 61850 Edition 1 conformance statement
Data object name P5CBFPPIOC3
Common data class
PIOC class
Explanation
The name shall be composed of the class name, the LN-Prefix and LN-Instance-ID according to IEC 61850-7-2, Clause 22.
Data Objects
Common Logical Node Information
Mod
INC
Mode
Beh Health NamPlt
INS
Behaviour
INS
Health
LPL
Name plate
Status Information Str Op
ACD ACT
Start Operate
Settings
FunEna NeutStrVal
PhsStrVal
IovsStrVal Tm1DlTms
SPG ASG
ASG
ASG ASG
Function enable
Undercurrent threshold for earth fault current
Undercurrent threshold for phase current
Io'< current set
Timer1 operate delay time
Tm1Ena Tm2DlTms
SPG ASG
Enable CBF timer1 Timer2 operate delay time
Tm2Ena
SPG
Enable CBF timer2
M/O/ C/E M
M M M M
O M
E E E E E E E E
Remarks Status-only
LN Type: SE_PIOC_ARCM_EasergyP5FM_ARC_V001 Description: Instantaneous overcurrent LN Class: PIOC
Data object name P5ARCMPIOC1...8
Common data class
PIOC class
Explanation
The name shall be composed of the class name, the LN-Prefix and LN-Instance-ID according to IEC 61850-7-2, Clause 22.
Data Objects
Common Logical Node Information
Mod
INC
Mode
Beh Health NamPlt
INS
Behaviour
INS
Health
LPL
Name plate
Status Information Op
ACT
Operate
Settings
FunEna MinOpTmms
SPG ING
Function enable Min. hold time [x1ms]
M/O/ C/E M
M M M M
M
E E
Remarks Status-only
P5/EN M/33A
227
Appendix 2: IEC 61850 Edition 1 conformance statement
Data object name
OpDlTmms OpMode
Common data class
ING
ING
PIOC class Explanation
Trip X delay [x1ms] Arc stage X Mode
M/O/ C/E
E
E
Remarks
LN Type: SE_PIOC_CLP_EasergyP5FMU_V001 Description: Instantaneous overcurrent LN Class: PIOC
Data object name P5CLPPIOC1
Common data class
PIOC class
Explanation
The name shall be composed of the class name, the LN-Prefix and LN-Instance-ID according to IEC 61850-7-2, Clause 22.
Data Objects
Common Logical Node Information
Mod
INC
Mode
Beh Health NamPlt
INS
Behaviour
INS
Health
LPL
Name plate
Status Information Op
ACT
Operate
Settings
FunEna Idl StrVal
SPG ASG ASG
Function enable Idle current Pickup current
DeadTms MaxTms
ASG ASG
CLPU dead time Maximum time
M/O/ C/E M
M M M M
M
E E O E E
Remarks Status-only
LN Type: SE_PIOC_SOL_EasergyP5FMU_V001 Description: Instantaneous overcurrent LN Class: PIOC
Data object name P5SOLPIOC1
Common data class
PIOC class
Explanation
The name shall be composed of the class name, the LN-Prefix and LN-Instance-ID according to IEC 61850-7-2, Clause 22.
Data Objects
Common Logical Node Information
Mod
INC
Mode
Beh Health NamPlt
INS
Behaviour
INS
Health
LPL
Name plate
Status Information
Op
ACT
Operate
Oprt2
ACT
2nd Operate
Settings
M/O/ C/E M
M M M M
M E
Remarks Status-only
228
P5/EN M/33A
Appendix 2: IEC 61850 Edition 1 conformance statement
Data object name
FunEna SigNum CbClrTms
Common data class SPG ING
ASG
PIOC class Explanation
Function enable SOL signal number CB trip clearing time
M/O/ C/E E E
E
Remarks
LN Type: SE_PIOC_SOTF_EasergyP5FMU_V001 Description: Instantaneous overcurrent LN Class: PIOC
Data object name P5SOTFPIOC1
Common data class
PIOC class
Explanation
The name shall be composed of the class name, the LN-Prefix and LN-Instance-ID according to IEC 61850-7-2, Clause 22.
Data Objects
Common Logical Node Information
Mod
INC
Mode
Beh Health NamPlt
INS
Behaviour
INS
Health
LPL
Name plate
Status Information Op
ACT
Operate
Settings
FunEna StrVal
SPG ASG
Enable for SOTF Pick-up value
DetDlTms
ASG
Dead line detection delay
ActTmrTms
ASG
SOTF active Timer
M/O/ C/E M
M M M M
M
E O E E
Remarks Status-only
LN Type: SE_PMRI_MOTFST_EasergyP5MU_V003 Description: Motor restart inhibition LN Class: PMRI
Data object name P5FSTPMRI1
Common data class
PMRI class
Explanation
The name shall be composed of the class name, the LN-Prefix and LN-Instance-ID according to IEC 61850-7-2, Clause 22.
Data Objects
Common Logical Node Information
Mod
INC
Mode
Beh Health NamPlt
INS
Behaviour
INS
Health
LPL
Name plate
Status Information Op
ACT
Operate
StrInh Settings
SPS
Restart inhibited
M/O/ C/E M
M M M M
O O
Remarks Status-only
P5/EN M/33A
229
Appendix 2: IEC 61850 Edition 1 conformance statement
Data object name
MaxWrmStr
MinStrTmm HotSttsLmt FunEna MaxCldStr RefPrdTmm
Common data class ING
ASG ASG SPG ING ASG
PMRI class
Explanation
M/O/ C/E
Maximum warm starts, permissible O number of warm starts
Min time between motor starts
E
Hot Status Limit
E
Function enable
E
Max motor cold starts/hour
E
Reference period
E
Remarks
LN Type: SE_PMSS_STAL_EasergyP5MU_V001 Description: Motor starting time supervision LN Class: PMSS
Data object name P5STALPMSS1
Common data class
PMSS class
Explanation
The name shall be composed of the class name, the LN-Prefix and LN-Instance-ID according to IEC 61850-7-2, Clause 22.
M/O/ C/E
M
Data Objects
Common Logical Node Information
Mod
INC
Mode
M
Beh
INS
Behaviour
M
Health
INS
Health
M
NamPlt
LPL
Name plate
M
Status Information
Str
ACD
Start
O
Op
ACT
Operate
O
Settings
SetA
ASG
Current setting for motor start-up O
SetTms
ING
Time setting for motor start-up
O
MotStr
ASG
Motor startup (current pickup value O of motor starting)
FunEna
SPG
Function enable
E
TmACrv
CURVE
Characteristics for Ist>
E
Remarks Status-only
LN Type: SE_PMSS_MSPD_EasergyP5MU_V001 Description: Motor starting time supervision LN Class: PMSS
Data object name P5MSPDPMSS1
Common data class
PMSS class
Explanation
The name shall be composed of the class name, the LN-Prefix and LN-Instance-ID according to IEC 61850-7-2, Clause 22.
Data Objects
Common Logical Node Information
Mod
INC
Mode
Beh
INS
Behaviour
M/O/ C/E M
M M
Remarks Status-only
230
P5/EN M/33A
Appendix 2: IEC 61850 Edition 1 conformance statement
Data object name
Health NamPlt Status Information ZerSpdSt MotSpd Settings FunEna SpdIn RtdMotSpd PlsRot ZerSpdTms
Common data class INS LPL
SPS INS
SPG ING ASG ASG ASG
PMSS class Explanation
Health Name plate
Zero speed Motor speed
Function enable Motor speed input DI Rated motor speed Pulse per rotation Zero speed delay
M/O/ C/E
M
M
Remarks
E E
E E E E E
LN Type: SE_PMSS_MABS_EasergyP5MU_V001 Description: Motor starting time supervision LN Class: PMSS
Data object name P5MABSPMSS1
Common data class
PMSS class
Explanation
The name shall be composed of the class name, the LN-Prefix and LN-Instance-ID according to IEC 61850-7-2, Clause 22.
Data Objects
Common Logical Node Information
Mod
INC
Mode
Beh Health NamPlt
INS
Behaviour
INS
Health
LPL
Name plate
Status Information AbsAlm
SPS
Anti-backspin Alarm
Settings
FunEna MvMod
SPG SPG
Function enable Measured Zero Speed Mode
SwMod
SPG
Zero Speed Switch Mode
AbsTms
ASG
Anti-backspin Delay
M/O/ C/E M
M M M M
E
E E E E
Remarks Status-only
LN Type: SE_PMSS_51LR_EasergyP5MU_V001 Description: Motor starting time supervision LN Class: PMSS
Data object name P5LRPMSS1
Common data class
PMSS class
Explanation
The name shall be composed of the class name, the LN-Prefix and LN-Instance-ID according to IEC 61850-7-2, Clause 22.
Data Objects
Common Logical Node Information
M/O/ C/E
M
Remarks
P5/EN M/33A
231
Appendix 2: IEC 61850 Edition 1 conformance statement
Data object name
Mod Beh Health NamPlt Status Information Str Op Settings SetA FunEna DlTyp OpDlTms
Common data class INC INS INS LPL
ACD ACT
ASG SPG ING ASG
PMSS class Explanation
Mode Behaviour Health Name plate
Start Operate
Pick-up value Function enable Delay type Operate delay time
M/O/ C/E M
M M M
Remarks Status-only
O O
O E E E
LN Type: SE_PTEF_IO_EasergyP5F_V002 Description: Transient earth fault LN Class: PTEF
Data object name P5IOIOPTEF1
Common data class
PTEF class
Explanation
The name shall be composed of the class name, the LN-Prefix and LN-Instance-ID according to IEC 61850-7-2, Clause 22.
M/O/ C/E
M
Data Objects
Common Logical Node Information
Mod
INC
Mode
M
Beh
INS
Behaviour
M
Health
INS
Health
M
NamPlt
LPL
Name plate
M
Status Information
Str
ACD
Start
C
Op
ACT
Operate
C
Settings
FunEna
SPG
Function enable
E
DirMode
ING
Direction mode
E
GndStr
ASG
Uo pick-up
O
OpDlTms
ASG
Operate delay time
E
MinPeak
ING
Min number of peaks
E
RsDlTms
ASG
Reset delay
E
Condition C: at least one of the two status information (Str, Op) shall be used.
Remarks Status-only
LN Type: SE_PTOC_STRVAL_EasergyP5FMU_V002 Description: Time overcurrent LN Class: PTOC
232
P5/EN M/33A
Appendix 2: IEC 61850 Edition 1 conformance statement
Data object name P5HAR5PTOC1
Common data class
PTOC class
Explanation
The name shall be composed of the class name, the LN-Prefix and LN-Instance-ID according to IEC 61850-7-2, Clause 22.
Data Objects
Common Logical Node Information
Mod
INC
Mode
Beh Health NamPlt
INS
Behaviour
INS
Health
LPL
Name plate
Status Information Str Op
ACD ACT
Start Operate
Settings
StrVal OpDlTmms
ASG ING
Start value Operate delay time
FunEna
SPG
Function enable
M/O/ C/E M
M M M M
M M
O O E
Remarks Status-only
LN Type: SE_PTOC_UIBC_EasergyP5FMU_V002 Description: Time overcurrent LN Class: PTOC
Data object name P5UIBCPTOC1
Common data class
PTOC class
Explanation
The name shall be composed of the class name, the LN-Prefix and LN-Instance-ID according to IEC 61850-7-2, Clause 22.
Data Objects
Common Logical Node Information
Mod
INC
Mode
Beh Health NamPlt
INS
Behaviour
INS
Health
LPL
Name plate
Status Information Str Op
ACD ACT
Start Operate
Settings
FunEna StrVal OpDlTms
SPG ASG ASG
Function enable Start value Operate delay time
M/O/ C/E M
M M M M
M M
E O E
Remarks Status-only
LN Type: SE_PTOC_EasergyP5FMU_VSI_V002 Description: Time overcurrent LN Class: PTOC
P5/EN M/33A
233
Appendix 2: IEC 61850 Edition 1 conformance statement
Data object name
P5EFVSPTOC1 P5EFVSPTOC2
Common data class
PTOC class
Explanation
The name shall be composed of the class name, the LN-Prefix and LN-Instance-ID according to IEC 61850-7-2, Clause 22.
Data Objects
Common Logical Node Information
Mod
INC
Mode
Beh Health NamPlt
INS
Behaviour
INS
Health
LPL
Name plate
Status Information Str Op
ACD ACT
Start Operate
Settings
FunEna StrVal
SPG ASG
Function enable Pick-up value
DlCrvFmly
ING
Delay curve family
DlTyp
ING
Delay type
OpDlTms
ASG
Operate delay time
TmMult RsTyp
ASG ING
Inv. time coefficient Reset type
RsDlTms
ASG
Reset time
InrushStat SolStat SolOpDTms
SPG SPG ASG
Inrush status SOL status SOL operate delay time
SolTmMult ClpStat
ASG SPG
SOL Inv. time coefficient CLP status
ClpStrVal
ASG
CLP pick-up value
ClpOpDTms
ASG
CLP operate delay time
ClpTmMult
ASG
CLP Inv. time coefficient
NetGrd
ING
Network grounding
M/O/ C/E M
M M M M
M M
E O E E E O E E E E E E E E E E E
Remarks Status-only
LN Type: SE_PTOC_NORMAL_EasergyP5FMU_V002 Description: Time overcurrent LN Class: PTOC
Data object name
P5OCPTOC1 P5OCPTOC2
Common data class
PTOC class
Explanation
The name shall be composed of the class name, the LN-Prefix and LN-Instance-ID according to IEC 61850-7-2, Clause 22.
Data Objects
Common Logical Node Information
Mod
INC
Mode
Beh
INS
Behaviour
M/O/ C/E M
M M
Remarks Status-only
234
P5/EN M/33A
Appendix 2: IEC 61850 Edition 1 conformance statement
Data object name
Health NamPlt Status Information Str Op Settings FunEna StrVal DlCrvFmly DlTyp OpDlTms TmMult RsTyp RsDlTms InrushStat SolStat SolOpDTms SolTmMult ClpStat ClpStrVal ClpOpDTms ClpTmMult
Common data class INS LPL
ACD ACT
SPG ASG ING ING ASG ASG ING ASG SPG SPG ASG ASG SPG ASG ASG ASG
PTOC class Explanation
Health Name plate
Start Operate
Function enable Pick-up value Delay curve family Delay type Operate delay time Inv. time coefficient Reset type Reset time Inrush status SOL status SOL operate delay time SOL Inv. time coefficient CLP status CLP pick-up value CLP operate delay time CLP Inv. time coefficient
M/O/ C/E
M
M
Remarks
M M
E O E E E O E E E E E E E E E E
LN Type: SE_PTOC_EasergyP5FM_V002 Description: Time overcurrent LN Class: PTOC
Data object name
P5DEFPTOC1 P5DEFPTOC2 P5DEFPTOC3
Common data class
PTOC class
Explanation
The name shall be composed of the class name, the LN-Prefix and LN-Instance-ID according to IEC 61850-7-2, Clause 22.
Data Objects
Common Logical Node Information
Mod
INC
Mode
Beh Health NamPlt
INS
Behaviour
INS
Health
LPL
Name plate
Status Information Str Op
ACD ACT
Start Operate
Settings
FunEna DirMode
SPG ING
Function enable Direction mode
M/O/ C/E M
M M M M
M M
E E
Remarks Status-only
P5/EN M/33A
235
Appendix 2: IEC 61850 Edition 1 conformance statement
Data object name
StrVal UoStrVal AngOffset SctrStrVal DlCrvFmly DlTyp OpDlTms TmMult RsTyp RsDlTms
Common data class ASG ASG ASG ASG ING ING ASG ASG ING ASG
PTOC class Explanation
Pick-up value Uo setting Angle offset Pick up sector size Delay curve family Delay type Operate delay time Inv. time coefficient Reset type Reset time
M/O/ C/E O E E E E E E O E E
Remarks
LN Type: SE_PTOC_EasergyP5U_LPT_V002 Description: Time overcurrent LN Class: PTOC
Data object name
P5DOCLPTOC1 P5DOCLPTOC2
Common data class
PTOC class
Explanation
The name shall be composed of the class name, the LN-Prefix and LN-Instance-ID according to IEC 61850-7-2, Clause 22.
Data Objects
Common Logical Node Information
Mod
INC
Mode
Beh Health NamPlt
INS
Behaviour
INS
Health
LPL
Name plate
Status Information Str Op
ACD ACT
Start Operate
Settings
FunEna StrVal
SPG ASG
Function enable Pick-up value
DirMode AngOffset
ING ASG
Direction mode Angle offset
DlCrvFmly
ING
Delay curve family
DlTyp
ING
Delay type
OpDlTms
ASG
Operate delay time
TmMult RsTyp
ASG ING
Inv. time coefficient Reset type
RsDlTms InrushStat SolStat SolOpDTms
ASG SPG SPG ASG
Reset time Inrush status SOL status SOL operate delay time
M/O/ C/E M
M M M M
M M
E O E E E E E O E E E E E
Remarks Status-only
236
P5/EN M/33A
Appendix 2: IEC 61850 Edition 1 conformance statement
Data object name
SolTmMult ClpStat ClpStrVal ClpOpDTms ClpTmMult
Common data class ASG SPG ASG ASG ASG
PTOC class Explanation
SOL Inv. time coefficient CLP status CLP pick-up value CLP operate delay time CLP Inv. time coefficient
M/O/ C/E E E E E E
Remarks
LN Type: SE_PTOC_DOC2_EasergyP5U_LPT_V001 Description: Time overcurrent LN Class: PTOC
Data object name
P5DOCLPTOC3 P5DOCLPTOC4
Common data class
PTOC class
Explanation
The name shall be composed of the class name, the LN-Prefix and LN-Instance-ID according to IEC 61850-7-2, Clause 22.
Data Objects
Common Logical Node Information
Mod
INC
Mode
Beh Health NamPlt
INS
Behaviour
INS
Health
LPL
Name plate
Status Information Str Op
ACD ACT
Start Operate
Settings
FunEna StrVal
SPG ASG
Function enable Pick-up value
DirMode AngOffset
ING ASG
Direction mode Angle offset
OpDlTms
ASG
Operate delay time
InrushStat SolStat SolOpDTms
SPG SPG ASG
Inrush status SOL status SOL operate delay time
ClpStat
SPG
CLP status
ClpStrVal
ASG
CLP pick-up value
ClpOpDTms
ASG
CLP operate delay time
M/O/ C/E M
M M M M
M M
E O E E E E E E E E E
Remarks Status-only
LN Type: SE_PTOF_OFUF_EasergyP5FMV_V00V002/ SE_PTOF_OFUF_EasergyP5U_LPT_V002 Description: Overfrequency LN Class: PTOF
P5/EN M/33A
237
Appendix 2: IEC 61850 Edition 1 conformance statement
Data object name
P5OFUFPTOF1 P5OFUFPTOF2 P5LPTPTOF1 P5LPTPTOF2 Data Objects
Common data class
PTOF class
Explanation
The name shall be composed of the class name, the LN-Prefix and LN-Instance-ID according to IEC 61850-7-2, Clause 22.
Common Logical Node Information
Mod
INC
Mode
Beh Health NamPlt
INS
Behaviour
INS
Health
LPL
Name plate
Status Information Str Op
ACD ACT
Start Operate
Settings
FunEna StrVal
SPG ASG
Function enable Pick-up value
OpDlTms
ASG
Operate delay time
M/O/ C/E M
M M M M
M M
E O E
Remarks Status-only
LN Type: SE_PTOV_EasergyP5FMV_V002/ SE_PTOV_EasergyP5U_LPT_V001 Description: Overvoltage LN Class: PTOV
Data object name
P5OVPTOV1 P5OVPTOV2 P5OVPTOV3
P5OVLPTOV1 P5OVLPTOV2 P5OVLPTOV3
Data Objects
Common data class
PTOV class
Explanation
The name shall be composed of the class name, the LN-Prefix and LN-Instance-ID according to IEC 61850-7-2, Clause 22.
Common Logical Node Information
Mod
INC
Mode
Beh Health NamPlt
INS
Behaviour
INS
Health
LPL
Name plate
Status Information Str Op
ACD ACT
Start Operate
Settings
FunEna StrVal
SPG ASG
Function enable Pick-up value
OpDlTms
ASG
Operate delay time
M/O/ C/E M
M M M M
M O
E O E
Remarks Status-only
LN Type: SE_PTOV_UO_EasergyP5FMV_V001/ SE_PTOV_UO_EasergyP5U_LPT_V001 Description: Overvoltage
238
P5/EN M/33A
Appendix 2: IEC 61850 Edition 1 conformance statement
LN Class: PTOV
Data object name
P5UOPTOV1 P5UOPTOV2 P5UOPTOV3
P5UOLPTOV1 P5UOLPTOV2 P5UOLPTOV3
Data Objects
Common data class
PTOV class
Explanation
The name shall be composed of the class name, the LN-Prefix and LN-Instance-ID according to IEC 61850-7-2, Clause 22.
Common Logical Node Information
Mod
INC
Mode
Beh Health NamPlt
INS
Behaviour
INS
Health
LPL
Name plate
Status Information Str Op
ACD ACT
Start Operate
Settings
FunEna StrVal
SPG ASG
Function enable Pick-up value
OpDlTms
ASG
Operate delay time
RsDlTms
ASG
Reset time
M/O/ C/E M
M M M M
M O
E O E E
Remarks Status-only
LN Type: SE_PTOV_NEG_EasergyP5FMV_V001/ SE_PTOV_NEG_EasergyP5U_LPT_V001 Description: Overvoltage LN Class: PTOV
Data object name
P5NEGPTOV1 P5NEGPTOV2 P5NEGLPTOV1 P5NEGLPTOV2 Data Objects
Common data class
PTOV class
Explanation
The name shall be composed of the class name, the LN-Prefix and LN-Instance-ID according to IEC 61850-7-2, Clause 22.
Common Logical Node Information
Mod
INC
Mode
Beh Health NamPlt
INS
Behaviour
INS
Health
LPL
Name plate
Status Information Str Op
ACD ACT
Start Operate
Settings
FunEna OpMod
SPG ING
Function enable Operate mode
StrVal
ASG
Pick-up value
M/O/ C/E M
M M M M
M O
E E O
Remarks Status-only
P5/EN M/33A
239
Appendix 2: IEC 61850 Edition 1 conformance statement
Data object name
DlTyp OpDlTms RsDlTms
Common data class ING
ASG
ASG
PTOV class Explanation
Delay type Operate delay time Reset time
M/O/ C/E E
E
E
Remarks
LN Type: SE_PTOV_CAP_EasergyP5F_V001 Description: Overvoltage LN Class: PTOV
Data object name P5CAPPTOV1
Common data class
PTOV class
Explanation
The name shall be composed of the class name, the LN-Prefix and LN-Instance-ID according to IEC 61850-7-2, Clause 22.
Data Objects
Common Logical Node Information
Mod
INC
Mode
Beh Health NamPlt
INS
Behaviour
INS
Health
LPL
Name plate
Status Information Str Op
ACD ACT
Start Operate
Settings
FunEna
SPG
Function enable
StrVal
ASG
Pick-up value
CapOfPhs
ASG
L-N capacitance of one phase
RatUcLn
ASG
Rated L-N voltage UcLN
OpDlTms
ASG
Operate delay time
M/O/ C/E M
M M M M
M O
E O E E E
Remarks Status-only
LN Type: SE_PTTR_THF_EasergyP5FU_V002 Description: Thermal overload LN Class: PTTR
Data object name P5THFPTTR1
Common data class
PTTR class
Explanation
The name shall be composed of the class name, the LN-Prefix and LN-Instance-ID according to IEC 61850-7-2, Clause 22.
Data Objects
Common Logical Node Information
Mod
INC
Mode
Beh Health NamPlt
INS
Behaviour
INS
Health
LPL
Name plate
Status Information
M/O/ C/E M
M M M M
Remarks Status-only
240
P5/EN M/33A
Appendix 2: IEC 61850 Edition 1 conformance statement
Data object name
Op AlmThm Settings TmpMax AlmVal FunEna BasicCur FactorK HeaConsTmm RsvVal TmpMod TmpNom TmpAlrm TmpAmbMin TmpAmbDft
Common data class ACT SPS
ASG ASG SPS ASG ASG ASG ASG ING ASG ASG ASG ASG
PTTR class Explanation
Operate Thermal alarm
Max object temperature Thermal alarm value Function enable Basic current setting Factor k Heating time constant Reserve time thermal alarm Temperature based mode Nominal ambient temp Alarm temperature Min ambient temperature Default ambient temperature
M/O/ C/E
M
O
Remarks
O O E E E O E E E E E E
LN Type: SE_PTTR_THM_EasergyP5MU_V002 Description: Thermal overload LN Class: PTTR
Data object name P5THMPTTR1
Common data class
PTTR class
Explanation
The name shall be composed of the class name, the LN-Prefix and LN-Instance-ID according to IEC 61850-7-2, Clause 22.
Data Objects
Common Logical Node Information
Mod
INC
Mode
Beh Health NamPlt
INS
Behaviour
INS
Health
LPL
Name plate
Status Information Op
ACT
Operate
AlmThm Settings
SPS
Thermal alarm
TmpMax
ASG
Max object temperature
AlmVal FunEna BasicCur
ASG SPS ASG
Thermal alarm value Function enable Basic current setting
FactorK HeaConsTmm
ASG ASG
Factor k Heating time constant
ConsTmm
ASG
Time constant for motor starting
CooConsTmm
ASG
Cooling time constant
UnblFctr
ASG
Unbalance factor
M/O/ C/E M
M M M M
M O
O O E E E E E E E
Remarks Status-only
P5/EN M/33A
241
Appendix 2: IEC 61850 Edition 1 conformance statement
Data object name
RsvVal TmpMod TmpNom TmpAlrm TmpAmbMin TmpAmbDft
Common data class ASG ING ASG ASG ASG ASG
PTTR class Explanation
Reserve time thermal alarm Temperature based mode Nominal ambient temp Alarm temperature Min ambient temperature Default ambient temperature
M/O/ C/E E E E E E E
Remarks
LN Type: SE_PTUC_UC_EasergyP5MU_V002 Description: Undercurrent LN Class: PTUC
Data object name P5UCPTUC1
Common data class
PTUC class
Explanation
The name shall be composed of the class name, the LN-Prefix and LN-Instance-ID according to IEC 61850-7-2, Clause 22.
Data Objects
Common Logical Node Information
Mod
INC
Mode
Beh Health NamPlt
INS
Behaviour
INS
Health
LPL
Name plate
Status Information Str Op
ACD ACT
Start Operate
Settings
FunEna StrVal
SPG ASG
Function enable Pick-up value
OpDlTms
ASG
Operate delay time
M/O/ C/E M
M M M M
M M
E O E
Remarks Status-only
LN Type: SE_PTUF_UF_EasergyP5FMV_V002/SE_PTUF_UF_EasergyP5U_ LPT_V002 Description: Underfrequency LN Class: PTUF
Data object name
P5UFPTUF1 P5UFPTUF2 P5UFLPTUF1 P5UFLPTUF2 Data Objects
Common data class
PTUF class
Explanation
The name shall be composed of the class name, the LN-Prefix and LN-Instance-ID according to IEC 61850-7-2, Clause 22.
Common Logical Node Information
Mod
INC
Mode
Beh Health
INS
Behaviour
INS
Health
M/O/ C/E M
M M M
Remarks Status-only
242
P5/EN M/33A
Appendix 2: IEC 61850 Edition 1 conformance statement
Data object name
NamPlt Status Information Str Op Settings FunEna StrVal OpDlTms
Common data class LPL
ACD ACT
SPG ASG ASG
PTUF class Explanation Name plate
Start Operate
Function enable Pick-up value Operate delay time
M/O/ C/E
M
Remarks
M M
E O E
LN Type: SE_PTUV_UV_EasergyP5FMV_V002/ SE_PTUV_UV_EasergyP5U_LPT_V002 Description: Undervoltage LN Class: PTUV
Data object name
P5UVPTUV1 P5UVPTUV2 P5UVPTUV3
P5UVLPTUV1 P5UVLPTUV2 P5UVLPTUV3
Data Objects
Common data class
PTUV class
Explanation
The name shall be composed of the class name, the LN-Prefix and LN-Instance-ID according to IEC 61850-7-2, Clause 22.
Common Logical Node Information
Mod
INC
Mode
Beh Health NamPlt
INS
Behaviour
INS
Health
LPL
Name plate
Status Information Str Op
ACD ACT
Start Operate
Settings
FunEna StrVal
SPG ASG
Function enable Pick-up value
OpDlTms
ASG
Operate delay time
M/O/ C/E M
M M M M
M M
E O E
Remarks Status-only
LN Type: SE_PTUV_UVPS_EasergyP5MV_V002 Description: Undervoltage LN Class: PTUV
Data object name
P5UVPSPTUV1 P5UVPSPTUV2
Common data class
PTUV class
Explanation
The name shall be composed of the class name, the LN-Prefix and LN-Instance-ID according to IEC 61850-7-2, Clause 22.
Data Objects
Common Logical Node Information
Mod
INC
Mode
M/O/ C/E M
M
Remarks Status-only
P5/EN M/33A
243
Appendix 2: IEC 61850 Edition 1 conformance statement
Data object name
Beh Health NamPlt Status Information Str Op Settings FunEna StrVal OpDlTms
Common data class INS INS LPL
ACD ACT
SPG ASG ASG
PTUV class Explanation
Behaviour Health Name plate
Start Operate
Function enable Pick-up value Operate delay time
M/O/ C/E M
M
M
Remarks
M M
E O E
LN Type: SE_PZSU_EasergyP5MU_V001 Description: Motor underspeed LN Class: PZSU
Data object name P5MOTPZSU1
Common data class
PZSU class
Explanation
The name shall be composed of the class name, the LN-Prefix and LN-Instance-ID according to IEC 61850-7-2, Clause 22.
Data Objects
Common Logical Node Information
Mod
INC
Mode
Beh Health NamPlt
INS
Behaviour
INS
Health
LPL
Name plate
Status Information Str Op
ACD ACT
Start Operate
Settings
FunEna StrVal
SPG ASG
Function enable Pick-up value
OpDlTms
ASG
Operate delay time
M/O/ C/E M
M M M M
M M
E O E
Remarks Status-only
LN Type: SE_PHAR_ID_EasergyP5FMU_V001 Description: Harmonic restraint LN Class: PHAR
Data object name P5IDPHAR1
Common data class
PHAR class
Explanation
The name shall be composed of the class name, the LN-Prefix and LN-Instance-ID according to IEC 61850-7-2, Clause 22.
Data Objects
Common Logical Node Information
Mod
INC
Mode
M/O/ C/E M
M
Remarks Status-only
244
P5/EN M/33A
Appendix 2: IEC 61850 Edition 1 conformance statement
Data object name
Beh Health NamPlt Status Information Str
Common data class INS INS LPL
ACD
Settings FunEna StrVal CurBlkVal
SPG ASG ASG
PHAR class Explanation
Behaviour Health Name plate
Start (active when restraint is needed)
Function enable Pickup for 2nd harmonic Max inrush current
M/O/ C/E M
M
M
Remarks
M
E E E
Enum types extensions
New Enum types
Enum type ARCOpMode is one of new added types defined as below.
Value 0 1
Description Light Light and current
Remarks
Enum type DefDirMode is one of new added types defined as below.
Value 0 1 2
Description ResCap Sector Undir
Remarks
Enum type DocDirMode is one of new added types defined as below.
Value 0 1 2
Description Dir_Backup Undir Dir
Remarks
Enum type DlCrvFamily is one of new added types defined as below.
Value 0 1 2 3 4 5 6 7
Description DT IEC IEEE IEEE2 Others Prg1 Prg2 Prg3
Remarks
Enum type RsTyp is one of new added types defined as below.
P5/EN M/33A
245
Appendix 2: IEC 61850 Edition 1 conformance statement
Value 0 1
Description DT IDMT
Remarks
Enum type DlType is one of new added types defined as below.
Value 0 1 2 3 4 5 6 7 8 9 10 11 12 13
Description DT NI VI EI LTI LTEI LTVI MI STI STEI CO8 RI RXIDG --
Remarks
Enum type NetGrd is one of new added types defined as below.
Value 0 1
Description Res Cap
Remarks
Enum type NegOPMod is one of new added type defined as below.
Value 0 1
Description No_Action Blocking
Remarks
Enum type NegDITyp is one of new added type defined as below.
Value 0 1
Description DT INV
Remarks
Enum type StrMod is one of new added type defined as below.
Value 0 1 2
Description Negative Positive Either
Remarks
Enum type MemoryMode is one of new added types defined as below.
Value 0 1
Description None Voltage
Remarks
246
P5/EN M/33A
Appendix 2: IEC 61850 Edition 1 conformance statement
2
Time
3
Both
Enum type EfDirModeKind is one of new added type defined as below.
Value 0 1
Description Forward Reverse
Remarks
Enum type SlotDISelect is one of new added type defined as below.
Value 0 1 2
Description Slot_C_DI1 Slot_D_DI1 Slot_E_DI1
Remarks
Enum type VTTypeKind is one of new added type defined as below.
Value 0 1
Description VT LPVT
Remarks
Enum type TempModKind is one of new added type defined as below.
Value 0 1
Description Current Ambient
Remarks
Enum type PadmDirMod is one of new added type defined as below.
Value 0 1 2
Description Undir Forward Reverse
Remarks
Enum type SignalNum is one of new added type defined as below.
Value 0 1
Description 1 2
Remarks
Extended Enum types
Enum type SIUnitKind is extended by the following enumerations.
Value -1 -2 -3 -4 -5 -6
Quantity Rate of change of frequency Number of characters Baud Turbine inertia Sound pressure level Numerical tagging method
Unit name hertz per second characters characters per second kg square meter decibel per unit
Symbol Hz/s char Char/s kgm² dB pu
P5/EN M/33A
247
Appendix 2: IEC 61850 Edition 1 conformance statement
Value -7 -8 -9 -10 -11 -12
Quantity Percent Relative temperature Electric resistance Rotational speed Pulse per rotation time
Unit name percent degree Fahrenheit ohm (V/A) Revolutions per minute Pulse per rotation minute
Enum type AutoRecST is extended by the following enumerations.
Value -1 -2 -3 -4 -5 -6 -7 -8 -9 -10 -11 -12 -13
Symbol Reclaim Ready_Ext WaitOpen WaitClose Discrim Locked FinalTr CBFail Inhibit Blocked ExtOpen ExClose WaitSync
Symbol % °F V/A rmp /R min
248
P5/EN M/33A
Appendix 2: IEC 61850 Edition 1 conformance statement
PIXIT details
Introduction
This PIXIT is based upon UCAIug PIXIT Template version 15, UCA International Users Group Testing Sub Committee, October 22, 2019.
This document specifies the protocol implementation extra information for testing (PIXIT) of the IEC 61850 interface in P5U20, P5V20, P5F30 and P5M30, with firmware version V01.
Together with the PICS and MICS documents, the PIXIT document forms the basis for a conformance test according to IEC 61850-10. The PIXIT entries contain information which is not available in the PICS, MICS, TICS documents or SCL file.
Each chapter specifies the PIXIT for applicable ACSI service model as structured in IEC 61850-10. The "Ed" column indicates if the entry is applicable for IEC 61850 Edition 1 and/or Edition 2.
PIXIT for association model
The extra information for testing is given in the table below. Table 65 - Protocol implementation extra information for testing
ID
Ed
As1 1
As2 1,2 As3 1,2
As4 As5 1,2
As6 1,2 As7 1,2
Description
Value / Clarification
Maximum number of clients that
8
can set-up an association
simultaneously
TCP_KEEPALIVE value. The recommended range is 0...20s
Configurable: from 0 to 20s
Lost connection detection time
TCP_KEEPALIVE + 2s *10
Maximum 140s
(2s is retransmission interval of TCP Keep-alive message, 10 retransmissions) (0 means 120s)
Authentication is not supported yet
What association parameters are necessary for successful association
Transport selector Calling: N Called: Y
Session selector Calling: N Called: Y
Presentation selector Calling: N Called: Y
AP title Calling: N Called: N
AE qualifier Calling: N Called: N
If association parameters are necessary for association, describe the correct values.
Association parameters are configurable, default values are
Transport selector 1 Session selector 1 Presentation selector 1 AP title 1,1,1,999,1
AE qualifier 12
What is the maximum and minimum Max: 65535 bytes
MMS PDU size Min: In initiate request 1024 bytes
P5/EN M/33A
249
Appendix 2: IEC 61850 Edition 1 conformance statement
Table 65 - Protocol implementation extra information for testing (Continued)
ID
Ed
As8 1,2
As9 1,2
Description
What is the maximum start up time after a power supply interrupt
Does this device function only as test equipment?
(test equipment need not have a non-volatile configuration; but it cannot be part of the substation automation system)
Value / Clarification
P5 relay start-up time including the server function is at average 180s; it depends on the configuration size (number and types of logical nodes)
N
PIXIT for server model
ID
Ed Description
Value / Clarification
Sr1 1,2 Which analogue value (MX) quality bits are supported (can be set by server)
Validity: Y Good, N Invalid, N Reserved, N Questionable N Overflow N OutofRange N BadReference N Oscillatory N Failure N OldData N Inconsistent N Inaccurate
Source: Y Process N Substituted Y Test N OperatorBlocked
Sr2 1,2 Which status value (ST) quality bits Validity: are supported (can be set by server) Y Good, Y Invalid, N Reserved, Y Questionable N BadReference N Oscillatory N Failure N OldData N Inconsistent N Inaccurate
Source: Y Process N Substituted Y Test N OperatorBlocked
Sr3 -
What is the maximum number of data Deprecated object references in one GetDataValues request
Sr4 -
What is the maximum number of data Deprecated object references in one SetDataValues request
Sr5 1
Which Mode values are supported
On Y [On-]Blocked N Test Y Test/Blocked Y Off N
250
P5/EN M/33A
Appendix 2: IEC 61850 Edition 1 conformance statement
PIXIT for data set model
ID
Ed
Ds1
1
Ds2
1
Ds3
1
Description
What is the maximum number of data elements in one data set (compare ICD setting)
How many persistent data sets can be created by one or more clients
(this number includes predefined datasets)
How many non-persistent data sets can be created by one or more clients
Details 500 50
50
NOTE: Arrays are not supported in dataset.
PIXIT for setting group control model
ID
Ed
Sg1
1
Sg2
1,2
Sg3
1
Sg4
1
Sg5
1
Sg6
2
Description What is the number of supported setting groups for each logical device What is the effect of when and how the non-volatile storage is updated (compare IEC 61850-8-1 $16.2.4)
Can multiple clients edit the same setting group What happens if the association is lost while editing a setting group
Is EditSG value 0 allowed?
When ResvTms is not present how long is an edit setting group locked
Value / Clarification
4
When: CnfEdit set to TRUE successfully.
How: the setting value in edit buffer will be copied to the selected setting group, and then the new value will be updated to nonvolatile storage by setting engine.
N
The SE values changes are lost, the EditSG value will not change.
Y
Write a value of 0 to EditSG will cancel all the setting values in the Edit buffer.
Reserved forever except Cancel, Confirm or Disconnection.
PIXIT for reporting model
ID
Ed
Description
Details
Rp1
1
The supported trigger conditions
integrity
Y
(compare PICS)
data change
Y
quality change
Y
data update
Y
general interrogation
Y
Rp2
1
The supported optional fields are
sequence-number
Y
report-time-stamp
Y
reason-for-inclusion
Y
data-set-name
Y
P5/EN M/33A
251
Appendix 2: IEC 61850 Edition 1 conformance statement
ID
Rp3
Rp4 Rp5 Rp6 Rp7 Rp8 Rp9 Rp10 Rp11 Rp12 Rp13 Rp14
Ed
Description
Details
data-reference
Y
buffer-overflow (not
Y
applicable to URCB)
entryID (not applicable to Y URCB)
conf-rev
Y
segmentation
Y
1,2
Can the server send segmented
Y
reports?
(when not supported the device
shall refuse an association request
with a smaller than minimum PDU
size)
1,2
Mechanism on second internal data Send report immediately
change notification of the same
analogue data value within buffer
period (compare IEC 61850-7-2
$14.2.2.9)
1
Multi client URCB approach
Each URCB is visible to all clients
(compare IEC 61850-7-2 $14.2.1)
-
What is the format of EntryID
Deprecated
1,2
What is the buffer size for each
100k bytes per report control block
BRCB or how many reports can be
buffered
-
Pre-configured RCB attributes that Deprecated
are dynamic, compare SCL report
settings
1
May the reported data set contain:
- structured data objects?
Y
- data attributes? Y
1,2
What is the scan cycle for binary
5 milliseconds
events? Is this fixed, configurable or event-
Fixed
driven
1
Does the device support to pre-
N
assign a RCB to a specific client in
the SCL
2
After restart of the server is the
Fom the original configuration
value of ConfRev restored from the
original configuration or retained
prior to restart
1,2
Does the server accept any client to N
configure / enable a BRCB with
ResvTms=-1? What fields are used
to do the identification?
1,2
What is default value for BRCB.
Not support ResvTms.
ResvTms if client does not write or
ResvTms not exposed in the control
block (must be >= 0)
252
P5/EN M/33A
Appendix 2: IEC 61850 Edition 1 conformance statement
PIXIT for GOOSE publish model
ID
Ed
Gp1
1,2
Gp2
1
Gp3
1,2
Gp4
1,2
Gp5
1,2
Gp6
-
Gp7
1,2
Gp8
1
Gp9
1,2
Description
Value / Clarification
Can the test (Ed1) / simulation (Ed2) N flag in the published GOOSE be set
What is the behavior when the GOOSE publish configuration is incorrect
Published FCD supported common data classes / data types are
NdsCom=T DUT keeps GoEna=F
Common data classes: SPS, DPC, CMV, MV
Data types as single attributes: BOOLEAN, CODED ENUM, FLOAT32, QUALITY
Arrays are not supported.
What is the maximum value of TAL (maxTime)?
Is it fixed or configurable?
Maximum TAL = 120000 ms (double of maximum configurable slowest retransmission cycle 60000 ms)
Configurable by configuration tool
What is the fastest retransmission time?
Is it fixed or configurable?
4 ms
Retransmission scheme: First message upon data change, followed by 4, 10, 20, 40, 80, 160, 320, 640, 1280, 2500, 5000, 10000, 20000, 40000, 60000 and finally reaching the configured slow retransmission time).
TAL is set to value 2 times bigger than interval.
Can the GOOSE publish be turned on / off by using SetGoCBValues(GoEna)
Fixed Deprecated
What is initial GOOSE sqNum after
1
restart of the device
May the GOOSE data set contain: Y
- structured data objects (FCD) Y
- timestamp data attributes
Does Server or ICT refuse GOOSE
Y
payload dataset length greater than
SCSM supports?
P5/EN M/33A
253
PIXIT for GOOSE subscribe model
ID
Ed
Gs1
1,2
Gs2
1,2
Gs3
1,2
Gs4
1,2
Gs5
1,2
Gs6
1
Gs7
1
Gs8
1,2
254
Appendix 2: IEC 61850 Edition 1 conformance statement
Description
Value / Clarification
What elements of a subscribed GOOSE message are checked to decide the message is valid and the allData values are accepted? If yes, describe the conditions.
Notes:
· the VLAN tag may be removed by a ethernet switch and shall not be checked
· the simulation flag shall always be checked (Ed2)
· the ndsCom shall always be checked (Ed2)
Y destination MAC address (equal to configured)
Y APPID (equal to configured)
N gocbRef
N timeAllowedtoLive (see Remarks)
N datSet
Y goID (equal to configured, checking can be set off)
Nt
Y stNum (see Remarks)
N sqNum (see Remarks)
Y simulation/test (if true, values not passed to application, the application data will keep last received value when simulation/test was false, but status of the network input stays valid)
Y confRev (equal to configured)
Y ndsCom (if true, values not passed to application, the application data will keep last received value , and network inputs status is set to invalid as if message was never received)
Y numDatSetEntries (see Remarks)
When is a subscribed GOOSE marked as lost?
(TAL = time allowed to live value from the last received GOOSE message)
N out-of-order dataset members
Message does not arrive by TAL+1s
Internally in the relay there is a status indication to the application about GOOSE problem (data is marked as OLD if the message does not arrive prior to TAL+1s if TAL>1s or prior to 1s if TAL<1s).
What is the behavior when one or more subscribed GOOSE messages isn't received or syntactically incorrect (missing GOOSE)
The subsequently received GOOSE message is accepted even if the new state number is not equal to the incremented value of the previously received state number (it is enough that it is not equal to the last received state number).
What is the behavior when a subscribed GOOSE message is out-of-order
Message is treated as normal (it is assumed that previous messages have been lost).
What is the behavior when a subscribed GOOSE message is duplicated
Duplicated message is ignored
Does the device subscribe to GOOSE messages with/without the VLAN tag?
Y with the VLAN tag Y without the VLAN tag
May the GOOSE data Y set contain:
Y
- structured data objects?
- data attributes?
Subscribed FCD supported common data classes / data types are
Data classes: SPS, SPC, DPS, DPC, INS, INC, ENS, ENC, CMV, MV
Data types as single attributes: BOOLEAN, INT8, INT16, INT32, INT8U, INT16U, INT32U, ENUM, CODED ENUM, BITSTRING, FLOAT32
Arrays are not supported
P5/EN M/33A
Appendix 2: IEC 61850 Edition 1 conformance statement
ID
Ed
Gs9
1,2
Gs10
1,2
Gs11
1
Description
Value / Clarification
Are subscribed GOOSE with test=T (Ed1) / simulation=T (Ed2) accepted in test/ simulation mode
N - Test mode is not supported by the device
Max number of dataset Unlimited members
Is Fixed-length encoded Yes GOOSE supported
TAL = Time Allowed to Live
Remarks:
A GOOSE message will be accepted and processed by the subscriber in DUT:
· Even if it is received after expiration of the time allowed to live sent in the previous message,
· Even if the new state number is not equal to the incremented value of the previously received state number - it is enough that it is not equal to the last received state number,
· If the state number differs from the previously received state number, the sequence number is accepted with any value (if the state number is equal to the previously received state number, the message is treated as retransmission),
· Even if the received message contains a dataset of the size different than the size of the previously received dataset.
A GOOSE message will NOT be accepted by the subscriber in DUT if:
· Destination MAC address is not equal to configured one
· Protocol ID is not equal to 0x88B8
· APPID is not equal to configured one for any of the network inputs
· ConfRev is not equal to configured one for any of the network inputs
· goID is not equal to configured one for any of the network inputs
· state number is the same as in the previous message (is treated as retransmission)
· ndsCom bit is set to true in received message
Note for sGosN6h (out of order dataset)
Value from GOOSE message will be accepted even if the type is different than in previous message given that:
· Type is compatible with network input type i.e. for binary network inputs accepted types are: BOOLEAN, INTEGER and BITSTRIG, ENUM, CODED ENUM for analog network inputs accepted types are FLOAT32 and INTEGER
· In case of binary network input and types other than BOOLEAN as a value for processing bit selected in configuration will be taken from the received data in the message (by default it is bit 0)
· Value will not be accepted if data from the message is not containing configured bit (for example if bit 5 is configured and received data contains only 2 bits like stVal from DPC type)
Every network input can be associated via internal logic with one of 16 validity indications. If given network input is not received due to one of the reasons mentioned above this indication is activated. Validity flag for the network input will be activated also if next message with the value will not be received within the time indicated in time to live field contained in the previous message.
The value of numDatSetEntries from the header determines how many data entries from the message are processed. With numDatSetEntries = 0 no data entries are processed from the received message. If numDatSetEntries is lower than expected (source information for some network inputs is not processed or missing) those missing network inputs will be marked as invalid.
P5/EN M/33A
255
Appendix 2: IEC 61850 Edition 1 conformance statement
During device startup there can be more than one state transition of the GOOSE publisher dataset, since different parts of the relay application will start after GOOSE publisher.
When checking GoID, the APPID must not be the same as the APPID of other GOOSE.
PIXIT for GOOSE performance
ID
Ed
Gf1
1,2
Gf2
1,2
Gf3
1,2
Gf4
1
Description
Value / Clarification
Performance class
N/A
GOOSE ping-pong processing method
Scan cycle based
Application logic scan cycle (ms) Max. 3 ms for SPS, 10 ms for DPS
Min. 0 ms for SPS, 0 ms for DPS
Maximum number of data
500
attributes in GOOSE dataset
(value and quality has to be
counted as separate attributes)
PIXIT for control model
ID
Ed
Ct1
-
Ct2
1,2
Ct3
-
Ct4
-
Ct5
1
Ct6
-
Ct7
-
Ct8
1
256
Description
Value / Clarification
What control models are supported
(compare PICS)
DOns: Y SBOns: Y DOes: Y
Is the control model fixed, configurable and/or dynamic?
SBOes: Y
Configurable for CSWI class: All controllable objects Obj1 ... Obj6 under CSWI class are configured to use one and the same chosen control model. Objects Obj7 ... Obj8 under CSWI class have fixed control model status-only.
Fixed for GGIO: All controllable objects under GGIO class the control model is fixed: direct-with-normalsecurity.
Is TimeActivatedOperate
Deprecated
supported (compare PICS or
SCL)
Is "operate-many" supported N (compare sboClass)
Will the DUT activate the
N
control output when the test
attribute is set in the
SelectWithValue and/or
Operate request (when N
test procedure Ctl2 is
applicable)
What are the conditions for the time (T) attribute in the SelectWithValue and/or Operate request
Deprecated
Is pulse configuration supported (compare pulseConfig)
Deprecated
What is the behavior of the DUT when the check conditions are set
Is this behavior fixed, configurable, online changeable?
N synchrocheck
N interlock-check
DUT ignores the check value and the command is executed as usual
P5/EN M/33A
Appendix 2: IEC 61850 Edition 1 conformance statement
ID
Ed
Ct9
1,2
Ct10
1,2
Ct11
1,2
Ct12
1,2
Ct13
1,2
Ct14
1,2
Ct15
1,2
Description
Value / Clarification
Which additional cause diagnosis are supported
Fixed N Unknown Y Not-supported
Y Blocked-by-switching-hierarchy
N Select-failed
Y Invalid-position
Y Position-reached
N Step-limit
Y Blocked-by-Mode
N Blocked-by-process
N Blocked-by-interlocking
N Blocked-by-synchrocheck
Y Command-already-in-execution
N Blocked-by-health
N 1-of-n-control
N Abortion-by-cancel
Y Time-limit-over
N Abortion-by-trip
Y Object-not-selected
Y Parameter-change-in-execution
How to force a "test-not-ok" respond with SelectWithValue request?
Put device into local mode
How to force a "test-not-ok" Put device into local mode respond with Select request?
How to force a "test-not-ok" respond with Operate request?
DOns: Operate with orCat out of range SBOns: Operate without Select DOes: Operate with orCat out of range
SBOes: Operate without Select
Which origin categories are supported/accepted?
Y bay-control Y station-control
Y remote-control
Y automatic-bay
Y automatic-station
Y automatic-remote
Y maintenance
Y process
What happens if the orCat is not supported or invalid
DOns: Negative response SBOns: Negative response
DOes: Negative response (with additional cause diagnosis code value Not-supported)
SBOes: Negative response (with additional cause diagnosis code value Not-supported)
Does the IED accept a SelectWithValue/Operate with the same control value as the current status value?
DOns: N SBOns: N
P5/EN M/33A
257
Appendix 2: IEC 61850 Edition 1 conformance statement
ID
Ed
Description
Value / Clarification
Ct16
1
Ct17
1
Ct18
1
Ct19
-
Ct20
1,2
Ct21
1,2
Ct22
2
Ct23
1,2
Ct24
1,2
Ct25
1,2
Ct26
1,2
Ct27
2
Ct_ex1
Is this behavior configurable?
DOes: N Addcause: Position-reached SBOes: N Addcause: Position-reached
Configurable: N
Does the IED accept a select/operate on the same control object from 2 different clients at the same time?
Does the IED accept a Select/SelectWithValue from the same client when the control object is already selected (tissue 334)
DOns: Y (see Remarks) SBOns: N DOes: N SBOes: N SBOns: N SBOes: N
Is for SBOes the internal validation performed during the SelectWithValue and/or Operate step?
Y During SelectWithValue and during Operate
Can a control operation be blocked by Mod=Off or [On-] Blocked (compare PIXIT Sr5)
Deprecated
Does the IED support local / Y remote operation?
Does the IED send an InformationReport with LastApplError as part of the Operate response- for control with normal security?
SBOns: N DOns: N
How to force a "parameterchange-in-execution"
How many SBOns/SBOes control objects can be selected at the same time?
Does the DUT support any operate timeout > 0
SBOns: N/A SBOes: N/A SBOns: 1 SBOes: 1 N
When CDC=DPC is
Y
supported, is it possible to
have DPC (Controllable
Double Point) go to the
intermediate state? (00)
Name an enhanced security point (if any) with a finite operate timeout specify the timeout (in milliseconds)
Relay/Obj1CSWI1.Pos
Operate timeout can be configured by setting Configuration Tool, the range is 0.02 ... 600 s. For example: DOes: 10000 ms SBOes: 10000 ms
Does the IED support control DOns: Y
objects with external
signals?
SBOns: Y
DOes: Y
SBO Timeout
SBOes: Y 60 seconds
Remarks:
In DOns model: When two clients send Operate request within a very short interval (under 100 ms) then for processing the second command the object position is still unchanged due to the first command, thus both clients receive positive Operate response.
258
P5/EN M/33A
Appendix 2: IEC 61850 Edition 1 conformance statement
PIXIT for time synchronization
ID
Ed
Tm1
1
Tm2
1,2
Tm3
1,2
Tm4
1,2
Tm5
1
Tm6
-
Tm7
1
Tm8
1,2
Tm9
1,2
Description
Value / Clarification
What time quality bits are supported (may be set by the IED)
Y LeapSecondsKnown Y ClockFailure
Ed.2 requires all 3 bits
Y ClockNotSynchronized
Describe the behaviour when the time server(s) ceases to respond
What is the time server lost detection time
How long does it take to take over the new time from time server
Time is taken from internal RTC
The latency depends on measured drift of the internal clock. Usually it can take 400 seconds
Depends on time difference between internal and time server.
Max. 400 s is the waiting time to see Timestamp Quality transition to ClockNotSynchronised.
When is the time quality bit "Clock failure" set?
The time quality bit "Clock failure" is set to "one" when the P5 IED restarts from power up, or when the connection to time server is lost; the bit is reset to "zero" when the clock becomes synchronized.
All available time synchronization sources will affect the "Clock failure" bit. These time sources include SNTP and where applicable, IRIG-B.
When is the time quality bit "Clock not synchronized" set?
Note: For Ed2 and up, CNS is set according to PIXIT Tm2
The time quality bit "Clock not synchronized" is set to "one" when the P5 IED starts from power up, or when the connection to time server is lost; the bit is reset to "zero" when the clock becomes synchronized.
Is the timestamp of a binary event adjusted to the configured scan cycle?
All available time synchronization sources will affect the "Clock not synchronized" bit. These time sources include SNTP and where applicable, IRIG-B.
Deprecated
Does the device support time
Y
zone and daylight saving?
Which attributes of the SNTP response packet are validated?
N Leap indicator not equal to 3 N Mode is equal to SERVER
Y OriginateTimestamp is equal to value sent by the SNTP client as Transmit Timestamp
Y RX/TX timestamp fields are checked for reasonableness
Y SNTP version 3 or 4
Do the COMTRADE files have local time or UTC time
Is this configurable
N other Local N
P5/EN M/33A
259
PIXIT for file transfer model
ID
Ed
Ft1
1
Ft2
1,2
Ft3
1
Ft4
1,2
Ft5
1,2
Ft6
1
Ft7
1
Ft8
1,2
Ft9
1,2
Appendix 2: IEC 61850 Edition 1 conformance statement
Description
Value / Clarification
What is structure of files and directories
Where are the COMTRADE files stored
Are comtrade files zipped and what files are included in each zip file
Directory structure - COMTRADE - DR - TREND
COMTRADE files stored in folder / COMTRADE /DR Zipped; Each COMTRADE record includes 2 files: .cfg and .dat
Directory names are separated Separated by `/' from the file name by
The maximum file name size including path (recommended 64 chars)
Are directory/file name case sensitive Maximum file size for SetFile
255
Below are all the maximum sizes: - Full file name (including the directory path, suffix and separation characters): 255 - File name: 64 - File directory name: 32 - File name suffix: 3
Case sensitive
SetFile is not supported.
Is the requested file path
Y
included in the MMS
fileDirectory respond file name
Is the wild char supported MMS Y fileDirectory request
Is it allowed that 2 clients get a file at the same time
Which files can be deleted
N None
260
P5/EN M/33A
Appendix 2: IEC 61850 Edition 1 conformance statement
TICS details
Introduction
The TICS is based upon UCAIug TICS Template version 2.1, UCA International Users Group Testing Sub Committee, April 23, 2019.
This Tissues implementation conformance statement is applicable for Easergy P5U20, P5V20, P5F30, P5M30, with firmware version V01.
Implemented Tissues
During the October 2006 meeting IEC TC57 working group 10 decided that: · green Tissues with the category "IntOp" are mandatory for IEC 61850 Edition 1 · Tissues with the category "Ed.2" Tissues should not be implemented
The below tables give an overview of the applicable mandatory Tissues.
Table 66 - Tissues implementation conformance statement
Part
Tissue Description
Implemented by server
Supported by client
8-1
116
GetNameList with empty response?
Y
na
165
Improper Error Response for
Y
na
GetDataSetValues
183
GetNameList error handling
Y
na
246
Control negative response (SBOns) with na
na *
LastApplError
545
Skip file directories with no files
na
ni
7-4
252
AlmThm should have CDC SPS
Y
na
7-3
28
Definition of APC
na
na
54
Point def xVal, not cVal
na
na
55
Ineut = Ires ?
63
mag in CDC CMV
Y
ni
Y
na
65
Deadband calculation of a Vector and
na
na
trigger option
219
operTm in ACT
na
na
270 1199
WYE and DEL rms values BCR
Y
ni
Y
na
7-2
30
control parameter T
Y
na *
31
Typo
na
na *
32
Typo in syntax
na
na*
35
Typo Syntax Control time
na
na *
36
Syntax parameter DSet-Ref missing
na
na
37
Syntax GOOSE "T" type
Y
na
39
Add DstAddr to GoCB
Y
na
40
GOOSE Message "AppID" to "GoID"
Y
na
41
GsCB "AppID" to "GsID"
na
na
42
SV timestamp: "EntryTime" to
na
na
"TimeStamp"
43
Control "T" semantic
44
AddCause - Object not sel
na
na
Y
na
P5/EN M/33A
261
Appendix 2: IEC 61850 Edition 1 conformance statement
Table 66 - Tissues implementation conformance statement (Continued)
Part
Tissue Description
Implemented by server
Supported by client
45
Missing AddCauses
na
na
46
Synchro check cancel
na
na
47
"." in LD Name?
Y
na
49
BRCB TimeOfEntry (part of #453)
-
na *
50
LNName start with number?
Y
na
51
ARRAY [0..num] missing
Y
na *
52
Ambiguity GOOSE SqNum
Y
na
53
Add DstAddr to GsCB, SV
na
na
151
Name constraint for control blocks etc.
Y
na
166
DataRef attribute in Log
na
na *
185
Logging - Integrity period
na
na *
189
SV Format
na
na
190
BRCB: EntryId and TimeOfEntry (part of -
na *
#453)
191
BRCB: Integrity and buffering reports
-
na *
(part of #453)
278
EntryId not valid for a server (part of
-
na *
#453)
297
Sequence number
Y
na *
298
Type of SqNum
na
na *
305
Reporting with BufTm=0
na
na *
322
Write Configuration attribute of BRCBs na
na *
329
Reporting and BufOvl
na
na *
333
Enabling of an incomplete GoCB
na
na
335
Clearing of Bufovfl
na
na *
348
URCB class and report
na
na *
349
BRCB TimeOfEntry has two definitions na
na *
453
Reporting & Logging model revision
Y
na *
1281 Default for TrgPos.GI is TRUE
na
na *
6
1
Syntax
na
na
5
tExtensionAttributeNameEnum is
Y
ni
restricted
8
SIUnit enumeration for W
Y
na
10
Base type for bitstring usage
Y
na
17
DAI/SDI elements syntax
Y
na
169
Ordering of enum differs from 7-3
na
na
245
Attribute RptId in SCL
Y
na *
529
Replace sev - Unknown by unknown
na
na
NOTE: Tissue 49, 190, 191, 275 and 278 are part of tissue #453, all other technical tissues in the table are mandatory if applicable.
NOTE: Editorial tissues are marked as "na".
For detailed information on the individual Tissues, connect to the TISSUE database: www.tissues.iec61850.com
262
P5/EN M/33A
Appendix 3: IEC 61850 Edition 2 conformance statement
Appendix 3: IEC 61850 Edition 2 conformance statement
Introduction
Document purpose
The purpose of this document is to specify the communication features of the Easergy P5 protection relays embedded IEC 61850 server implementation mapped to IEC 61850 Edition 2 standards.
The model implementation in Easergy P5 protection relays varies with the functional scope provided by the different device models.
The information provided here may be still the subject of changes due to planned further extensions in the supported IEC 61850 functionality.
Terms and abbreviations
Terms / abbreviations ACSI BDA DA DO FCD FCDA ID IED LD LN MSV RCB GoCB SCL SCSM XML GSSE GOOSE SCD ICD CID PICS MICS PIXIT TICS
Definitions
Abstract Communication Service Interfaces Basic Data Attribute (not structured) Data Attributes DATA in IEC 61850-7-2, data object type or instance Functionally Constrained Data Functionally Constrained Data Attribute Identifier Intelligent Electronic Device Logical Device Logical Node Multicast Sampled Value Report Control Block GOOSE Control Block or GSSE Control Block System Configuration description Language Specific Communication Service Mapping Extensible Markup Language Generic Substation State Event Generic Object Oriented Substation Event Substation Configuration Description IED Configuration Description Configured IED Description Protocol Implementation Conformance Statement Model Implementation Conformance Statement Protocol Implementation eXtra Information for Testing Tissue Implementation Conformance Statement
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PICS details
Appendix 3: IEC 61850 Edition 2 conformance statement
The PICS is based upon UCAIug PICS Template version 2.3, UCA International Users Group Testing Sub Committee, October 08, 2019. The following ACSI conformance statements are used to provide an overview and details about following devices: P5U20, P5V20, P5F30, P5M30, with firmware version V01.
· ASCI basic conformance statement, · ACSI models conformance statement, · ACSI service conformance statement The statements specify the communication features mapped to IEC 61850-8-1 and IEC 61850-9-2, Edition 2.
ASCI basic conformance statement
The basic conformance statement is defined in the table below. Table 67 - Basic conformance statement
Client /
Server /
Subscriber Publisher
ClientServer roles
B11
Server side (of TWO-PARTY-
Y
APPLICATION-ASSOCIATION)
B12
Client side (of TWO-PARTY-
APPLICATION-ASSOCIATION)
SCSMs supported
B21
SCSM: IEC 61850-8-1 used
Y
B22
SCSM: IEC 61850-9-1 used
B23
SCSM: IEC 61850-9-2 used
N
B24
SCSM: other
N
Generic substation event model (GSE)
B31
Publisher side
Y
B32
Subscriber side
Y
Transmission of sampled value model (SVC)
B41
Publisher side
B42
Subscriber side
= not applicable
N N
Y = supported
N or empty = not supported
Value / Comments Deprecated in Ed.2
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Appendix 3: IEC 61850 Edition 2 conformance statement
ASCI models conformance statement
The ACSI models conformance statement is defined in the table below. Table 68 - ASCI models conformance statement
Client / Subscriber
If Server side (B11) and/or Client side (B12) supported
M1
Logical device
M2
Logical node
M3
Data
M4
Data set
M5
Substitution
M6
Setting group control
Reporting
M7
Buffered report control
M7-1 sequence-number
M7-2 report-time-stamp
M7-3 M7-4 M7-5 M7-6 M7-7
reason-for-inclusion data-set-name data-reference buffer-overflow entryID
M7-8 M7-9
BufTm IntgPd
M7-10 M7-11 M8
GI conf-revision Unbuffered report control
M8-1 sequence-number
M8-2 report-time-stamp
M8-3 M8-4 M8-5 M8-6 M8-7
reason-for-inclusion data-set-name data-reference BufTm IntgPd
M8-8 M8-9
GI conf-revision
Server / Value / Comments Publisher
Y
Y
Only standard LN types
defined in Part 7-4.
Y
Only standard object
types defined in Part 7-
3, 7-4.
Mandatory objects and attributes, selected optional objects and attributes.
Y
Supported pre-defined
persistent data sets,
configurable via SCL.
Supported dynamically
created data sets
(persistent and non-
persistent).
Data set members selection restricted to FC such as ST and MX.
N
Y
Y Y Y Y Y Y Y Y Y Y Y Y Y Y Y Y Y Y Y Y Y Y
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Appendix 3: IEC 61850 Edition 2 conformance statement
Table 68 - ASCI models conformance statement (Continued)
Logging
Client / Subscriber
M9
Log control
M9-1 IntgPd
M10
Log
Other M11 M17 M18
Control File transfer Application association
M19
GOOSE Control Block
M20
Sampled Values Control Block
If GSE (B31/32) is supported
M12
GOOSE
M13
GSSE
If SVC (B41/B42) is supported
M14
Multicast SVC
M15
Unicast SVC
For all IEDs
M16
Time
Y = service is supported N or empty = service is not supported
Server / Value / Comments Publisher
N N N
Y Y Y Y N
Y
N
Deprecated in Ed.2
N N
Y
Performance class T2
(100s accuracy)
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Appendix 3: IEC 61850 Edition 2 conformance statement
ASCI service conformance statement
The ACSI service conformance statement is defined in the table below (depending on the statements in ASCI basic conformance statement, page 264).
Table 69 - ASCI service conformance statement
Ed ASCI Service Conformance
AA: TP/MC
Server
S1
1,2 GetServerDirectory
TP
(LOGICAL-DEVICE)
Application association
S2
1,2 Associate
S3
1,2 Abort
S4
1,2 Release
Logical device
S5
1,2 LogicalDeviceDirectory TP
Logical node
S6
1,2 LogicalNodeDirectory TP
S7
1,2 GetAllDataValues
TP
Data
S8
1,2 GetDataValues
TP
S9
1,2 SetDataValues
TP
S10 1,2 GetDataDirectory
TP
S11
1,2 GetDataDefinition
TP
Data set
S12 1,2 GetDataSetValues
TP
S13 1,2 SetDataSetValues
TP
S14 1,2 CreateDataSet
TP
S15 1,2 DeleteDataSet
TP
S16 1,2 GetDataSetDirectory TP
Substitution
S17 1 SetDataValues
TP
Setting group control
S18 1,2 SelectActiveSG
TP
S19 1,2 SelectEditSG
TP
S20 1,2 SetEditSGValue
TP
S21 1,2 ConfirmEditSGValues TP
S22 1,2 GetEditSGValue
TP
S23 1,2 GetSGCBValues
TP
Reporting
Buffered report control block (BRCB)
S24 1,2 Report
TP
S24-1 1,2 data-change (dchg)
S24-2 1,2 qchg-change (qchg)
S24-3 1,2 data-update (dupd)
Client / Server / Comments Sub (C) Pub (S)
Y
Y Y Y
Y
Y Y
Y Y Y Y
Y
N
Deprecated in Ed.2
Y
Y
Y
N
Y Y Y Y Y Y
Y
Y
Y
Y
Accepted as
TrgOpt, but not
functionally
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Appendix 3: IEC 61850 Edition 2 conformance statement
Table 69 - ASCI service conformance statement (Continued)
Ed ASCI Service Conformance
AA: TP/MC
S25 1,2 GetBRCBValues
TP
S26 1,2 SetBRCBValues
TP
Unbuffered report control block (URCB)
S27 1,2 Report
TP
S27-1 1,2 data-change (dchg)
S27-2 1,2 qchg-change (qchg)
S27-3 1,2 data-update (dupd)
S28 1,2 GetURCBValues
TP
S29 1,2 SetURCBValues
TP
Logging
Log control block
S30 1,2 GetLCBValues
TP
S31 1,2 SetLCBValues
TP
Log
S32 1,2 QueryLogByTime
TP
S33 1,2 QueryLogAfter
TP
S34 1,2 GetLogStatusValues
TP
Generic substation event model (GSE)
S35 1,2 SendGOOSEMessage MC
GOOSE Control Block
S36 1,2 GetGoReference
TP
S37 1,2 GetGOOSEElement- TP Number
S38 1,2 GetGoCBValues
TP
S39 1,2 SetGoCBValues
TP
GSSE (Ed2:61850-7-2 Annex C)
S40
1
SendGSSEMessage
MC
GSSE Control Block
S41 1 GetGsReference
TP
S42 1 GetGSSEElementNum- TP ber
S43 1 GetGsCBValues
TP
S44 1 SetGsCBValues
TP
Transmission of sampled value model (SVC)
Multicast SV
S45 1,2 SendMSVMessage
MC
Multicast Sampled Values Control Block
S46 1,2 GetMSVCBValues
TP
Client / Sub (C)
Server / Comments Pub (S)
supported by the IED
Y
Y
Y
Y
Y
Y
Accepted as
TrgOpt, but not
functionally
supported by the
IED
Y
Y
N N
N N N
Y
N N
Y Y
N
Deprecated in Ed.2
N
Deprecated in Ed.2
N
Deprecated in Ed.2
N
Deprecated in Ed.2
N
Deprecated in Ed.2
N
Use for 9-2LE or
IEC 61869-9
N
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Appendix 3: IEC 61850 Edition 2 conformance statement
Table 69 - ASCI service conformance statement (Continued)
Ed ASCI Service Conformance
AA: TP/MC
S47 1,2 SetMSVCBValues
TP
Unicast SV
S48 1,2 SendUSVMessage
TP
Unicast Sampled Values Control Block
S49 1,2 GetUSVCBValues
TP
S50 1,2 SetUSVCBValues
TP
Control S51 1,2
Select
S52 1,2 SelectWithValue
TP
S53 1,2 Cancel
TP
S54 1,2 Operate
TP
S55 1,2 CommandTermination TP
S56 1,2 TimeActivatedOperate TP
File Transfer
S57 1,2 GetFile
TP
S58 1,2 SetFile
TP
S59 1,2 DeleteFile
TP
S60 1,2 GetFileAttributeValues TP
S61 1,2 GetServerDirectory
TP
(FILE-SYSTEM)
Time T1
1,2 Time resolution of internal clock
T2
1,2 Time accuracy of
internal clock
T3
1,2 Supported TimeStamp -
resolution
Client / Sub (C)
Server / Pub (S)
N
Comments
N
N N
Y Y Y Y Y N
Y N N Y Y
14
14 for IEEE1588,
10 for IRIG-B,
7 for SNTP and
protocols
T2
Performance class
T2 for IEEE1588,
T1 for IRIG-B,
T0 for SNTP and
protocols
20
Nearest value of 2-n
in seconds
(number 0 ... 24)
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MICS details
Logical nodes list
Appendix 3: IEC 61850 Edition 2 conformance statement
The MICS is based upon UCAIug MICS Template version 1.2, UCA International Users Group Testing Sub Committee, August 13, 2019.
This model implementation conformance statement is applicable for P5U20, P5V20, P5F30, P5M30, with firmware version V01.
This MICS document specifies the modeling extensions compared to IEC 61850 Edition 2.
Clause Logical nodes list contains the list of implemented logical nodes.
Clause Logical node extensions describes the new and extended logical nodes (if any).
Clause Enum types extensions describes the new and extended enum types (if any).
The following table contains the list of logical nodes implemented in the device: Table 70 - Logical nodes implemented in the device
L: System Logical Nodes LPHD (Physical device information) LLN0 (Logical node zero) P: Logical Nodes for protection functions PTRC (Protection trip conditioning) PTOC (Time overcurrent) PFRC (Rate of change frequency) PIOC (Instantaneous overcurrent) PTOF (Over frequency) PTOV (Overvoltage) PDOP (Directional overpower) PTUC (Undercurrent) PTTR (Thermal overload) PTUF (Under frequency) PTUV (Under voltage) PMRI (Motor restart inhibition) PMSS (Motor starting time supervision) PTEF (Transient earth fault) PADM (Admittance) POVS (Motor overspeed) PZSU (Motor underspeed) PHAR (Harmonic restraint) R: Logical nodes for protection related functions RREC (Auto reclosing) RDRE (Disturbance recorder) RFLO (Fault locator)
P5U20
x x
x x x x x x x x x x x x x
x x x
x x
P5V20 x x x x x x x
x x
x
P5F30 P5M30
x
x
x
x
x
x
x
x
x
x
x
x
x
x
x
x
x
x
x
x
x
x
x
x
x
x
x
x
x
x
x
x
x
x
x
x
x
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Appendix 3: IEC 61850 Edition 2 conformance statement
Table 70 - Logical nodes implemented in the device (Continued)
RSYN (Synchronism-check)
P5U20
G: Logical Nodes for generic references
GGIO (Generic process I/O)
x
GAPC (Generic automatic process control)
x
M: Logical Nodes for metering and measurement
MMTR (Metering)
x
MMXU (Measurement)
x
MHAI (Harmonics)
x
C: Logical Nodes for control
CSWI (Switch controller)
x
T: Logical nodes for instrument transformers and sensors
TCTX (Current transformer)
x
TVTX (Voltage transformer)
x
P5V20 x x x
x x x
x
P5F30 x
P5M30
x
x
x
x
x
x
x
x
x
x
x
x
x
x
x
x
Logical node extensions
The following table uses: · M: Data is mandatory in the IEC 61850-7-4. · O: Data is optional in the IEC 61850-7-4 and is used in the device. · C: Data is conditional in the IEC 61850-7-4 and is used in the device. · E: Data is an extension to the IEC 61850-7-4.
The condition below is available for all logical nodes in this chapter. Condition C1: Mod, Health and NamPlt shall be inherited by LLN0 of the root LD of a hierarchy as mandatory and by all other LN as optional.
New logical nodes
Newly created logical nodes are listed in this clause, with lnNs attribute in the Name plate.
PADM Admittance This LN shall be used for protection admittance E/F Io/Uo.
Data object name
P5EFPADM1 P5EFPADM2
Common data class
PADM class
Explanation
The name shall be composed of the class name, the LN-Prefix and LN-Instance-ID according to IEC 61850-7-2, Clause 22.
Data Objects
Common Logical Node Information
Mod
ENC
Mode
Beh Health NamPlt
ENS ENS LPL
Behaviour Health Name plate
Status Information YStr
ACD
YN start
M/O/ C/E E
C1 M C1 C1
E
Remarks Status-only
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Appendix 3: IEC 61850 Edition 2 conformance statement
Data object name
YOp GStr GOp BStr BOp Settings FunEna YFunEna GFunEna BFunEna UoStrVal CorAng YStrVal YOpDlTms YRsDlTms YSolMod YSlOpDlTms GStrVal GDirMod GOpDlTms GRsDlTms GSolMod GSlOpDlTms BStrVal BDirMod BOpDlTms BRsDlTms BSolMod BSlOpDlTms
Common data class ACT ACD ACT ACD ACT
SPG SPG SPG SPG ASG ASG ASG ASG ASG SPG ASG ASG ENG ASG ASG SPG ASG ASG ENG ASG ASG SPG ASG
PADM class Explanation
YN operate GN start GN operate BN start BN operate
Whole function enable YN function enable GN function enable BN function enable Uo pick-up value Correction angle YN pick-up value YN operate delay time YN reset time YN SOL mode YN SOL operate delay time GN pick-up value GN direction mode GN operate delay time GN reset time GN SOL mode GN SOL operate delay time BN pick-up value BN direction mode BN operate delay time BN reset time BN SOL mode BN SOL operate delay time
M/O/ C/E E
E E
E E
Remarks
E E E E E E E E E E E E E E E E E E E E E E E
POVS Motor overspeed This LN shall be used for protection motor overspeed.
Data object name
P5MOTPOVS1 P5MOTPOVS2
Common data class
POVS class
Explanation
The name shall be composed of the class name, the LN-Prefix and LN-Instance-ID according to IEC 61850-7-2, Clause 22.
M/O/ C/E
E
Data Objects
Common Logical Node Information
Mod
ENC
Mode
C1
Beh
ENS
Behaviour
M
Health
ENS
Health
C1
Remarks Status-only
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Data object name NamPlt
Common data class
LPL
Status Information Str Op
ACD ACT
Settings
FunEna StrVal
SPG ASG
OpDlTms
ASG
POVS class Explanation Name plate
Start Operate
Function enable Pick-up value Operate delay time
M/O/ C/E
C1
Remarks
E E
E E E
TCTX Current transformer This LN shall be used for protection current transformer parameters.
Data object name P5ITCTX1
Common data class
TCTX class
Explanation
M/O/ C/E
The name shall be composed of E the class name, the LN-Prefix and LN-Instance-ID according to IEC 61850-7-2, Clause 22.
Data Objects
Common Logical Node Information
Mod
ENC
Mode
C1
Beh
ENS
Behaviour
M
Health
ENS
Health
C1
NamPlt
LPL
Name plate
C1
Status Information
Remarks Status-only
Measured and metered values
Settings FunEna CTNum OpDlTmms PriPhs SecPhs
SPG ING ING ASG ASG
Function enable
E
Number of connected phase CT E
Operate delay time
O
CT primary
E
CT secondary
E
Data object name P5IOTCTX1
Common data class
TCTX class
Explanation
M/O/ C/E
The name shall be composed of E the class name, the LN-Prefix and LN-Instance-ID according to IEC 61850-7-2, Clause 22.
Data Objects
Common Logical Node Information
Mod
ENC
Mode
C1
Beh
ENS
Behaviour
M
Health
ENS
Health
C1
Remarks Status-only
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Appendix 3: IEC 61850 Edition 2 conformance statement
Data object name
NamPlt Status Information
Common data class
LPL
TCTX class Explanation
Name plate
M/O/ C/E
C1
Remarks
Measured and metered values
Settings
PriNeut1
ASG
Io CT primary
E
PriNeut2
ASG
Io' CT primary
E
Data object name P5LPITCTX1
Common data class
TCTX class
Explanation
M/O/ C/E
The name shall be composed of E the class name, the LN-Prefix and LN-Instance-ID according to IEC 61850-7-2, Clause 22.
Data Objects
Common Logical Node Information
Mod
ENC
Mode
C1
Beh
ENS
Behaviour
M
Health
ENS
Health
C1
NamPlt
LPL
Name plate
C1
Status Information
Remarks Status-only
Measured and metered values
ExtPri
MV
Rated ext. primary current In
E
Settings
FunEna
SPG
Function enable
E
OpDlTmms
ING
Operate delay time
E
NomPri
ASG
LPCT rated primary current
E
TVTX Voltage transformer This LN shall be used for protection voltage transformer parameters.
Data object name P5UTVTX1
Common data class
TVTX class
Explanation
The name shall be composed of the class name, the LN-Prefix and LN-Instance-ID according to IEC 61850-7-2, Clause 22.
M/O/ C/E
E
Data Objects
Common Logical Node Information
Mod
ENC
Mode
C1
Beh
ENS
Behaviour
M
Health
ENS
Health
C1
NamPlt
LPL
Name plate
C1
Status Information
Remarks Status-only
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Data object name
Common data class
TVTX class Explanation
M/O/ Remarks C/E
Measured and Metered Values
Settings
FunEna
SPG
Function enable
E
ImbAMinLev
ASG
I2 min. setting
E
ImbVMaxLev
ASG
U2 max. setting
E
OpDlTmms
ING
Operate delay time
E
PriPhs
ASG
VT primary
E
SecNeut
ASG
VTo secondary
E
SecPhs
ASG
VT secondary
E
Data object name P5LPUTVTX1
Common data class
TVTX class
Explanation
The name shall be composed of the class name, the LN-Prefix and LN-Instance-ID according to IEC 61850-7-2, Clause 22.
M/O/ C/E
E
Data Objects
Common Logical Node Information
Mod
ENC
Mode
C1
Beh
ENS
Behaviour
M
Health
ENS
Health
C1
NamPlt
LPL
Name plate
C1
Status Information
Remarks Status-only
Measured and Metered Values
ExtPri
MV
Settings
FunEna PhAMagCor
SPG ASG
PhBMagCor
ASG
PhCMagCor
ASG
PhAAngCor
ASG
PhBAngCor
ASG
PhCAngCor
ASG
VL1yMagCor
ASG
VL1yAngCor
ASG
VL2yMagCor
ASG
VL2yAngCor
ASG
VtTyp
ING
VtSecAdpt
ASG
PhAMagAdpt
ASG
Rated ext. primary current In
E
Function enable
E
VL1 magnitude correction
E
VL2 magnitude correction
E
VL3 magnitude correction
E
VL1 Angle correction
E
VL2 Angle correction
E
VL3 Angle correction
E
VL1y magnitude correction
E
VL1y Angle correction
E
VL2y magnitude correction
E
VL2y Angle correction
E
Primary VT type
E
VT secondary rated voltage
E
VL1 Adapt magnitude correction E
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Data object name
PhBMagAdpt PhCMagAdpt VlSecAdpt VL1yMagAdt
Common data class ASG
ASG
ASG ASG
TVTX class Explanation
VL2 Adapt magnitude correction VL3 Adapt magnitude correction VTy secondary rated voltage VL1y Adapt magnitude correction
M/O/ C/E E
E
E E
Remarks
Data object name P5LPUTVTX2
Common data class
TVTX class
Explanation
The name shall be composed of the class name, the LN-Prefix and LN-Instance-ID according to IEC 61850-7-2, Clause 22.
M/O/ C/E
E
Data Objects
Common Logical Node Information
Mod
ENC
Mode
C1
Beh
EINS
Behaviour
M
Health
ENS
Health
C1
NamPlt
LPL
Name plate
C1
Status Information
Remarks Status-only
Measured and Metered Values
ExtPri
MV
Settings
FunEna NomPri
SPG ASG
PhAMagCor
ASG
PhBMagCor
ASG
PhCMagCor
ASG
PhAAngCor
ASG
PhBAngCor
ASG
PhCAngCor
ASG
VL1yMagCor
ASG
VL1yAngCor
ASG
VtTyp
ING
VtSecAdpt
ASG
PhAMagAdpt
ASG
PhBMagAdpt
ASG
PhCMagAdpt
ASG
VlSecAdpt
ASG
VL1yMagAdt
ASG
Rated ext. primary current In
E
Function enable
E
LPVT rated primary voltage
E
VL1 magnitude correction
E
VL2 magnitude correction
E
VL3 magnitude correction
E
VL1 Angle correction
E
VL2 Angle correction
E
VL3 Angle correction
E
VL1y magnitude correction
E
VL1y Angle correction
E
Primary VT type
E
VT secondary rated voltage
E
VL1 Adapt magnitude correction E
VL2 Adapt magnitude correction E
VL3 Adapt magnitude correction E
VTy secondary rated voltage
E
VL1y Adapt magnitude correction E
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Appendix 3: IEC 61850 Edition 2 conformance statement
Data object name P5LPUTVTX3
Common data class
TVTX class
Explanation
The name shall be composed of the class name, the LN-Prefix and LN-Instance-ID according to IEC 61850-7-2, Clause 22.
M/O/ C/E
E
Remarks
Data Objects
Common Logical Node Information
Mod
ENC
Mode
C1 Status-only
Beh
ENS
Behaviour
M
Health
ENS
Health
C1
NamPlt
LPL
Name plate
C1
Status Information
Measured and Metered Values
ExtPri
MV
Settings
FunEna NomPri
SPG ASG
PhAMagCor
ASG
PhBMagCor
ASG
PhCMagCor
ASG
PhAAngCor
ASG
PhBAngCor
ASG
PhCAngCor
ASG
VtTyp
ING
VtSecAdpt
ASG
PhAMagAdpt
ASG
PhBMagAdpt
ASG
PhCMagAdpt
ASG
UoSecAdpt
ASG
UoMagAdt
ASG
Rated ext. primary current In
E
Function enable
E
LPVT rated primary voltage
E
VL1 magnitude correction
E
VL2 magnitude correction
E
VL3 magnitude correction
E
VL1 Angle correction
E
VL2 Angle correction
E
VL3 Angle correction
E
Primary VT type
E
VT secondary rated voltage
E
VL1 Adapt magnitude correction E
VL2 Adapt magnitude correction E
VL3 Adapt magnitude correction E
Uo secondary rated voltage
E
Uo Adapt magnitude correction
E
Data object name P5LPUTVTX4
Common data class
TVTX class
Explanation
The name shall be composed of the class name, the LN-Prefix and LN-Instance-ID according to IEC 61850-7-2, Clause 22.
M/O/ C/E
E
Remarks
Data Objects
Common Logical Node Information
Mod
ENC
Mode
C1 Status-only
Beh
ENS
Behaviour
M
Health
ENS
Health
C1
NamPlt
LPL
Name plate
C1
Status Information
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Appendix 3: IEC 61850 Edition 2 conformance statement
Data object name
Common data class
TVTX class Explanation
M/O/ Remarks C/E
Measured and Metered Values
ExtPri
MV
Settings
FunEna NomPri
SPG ASG
PhAMagCor
ASG
PhBMagCor
ASG
PhCMagCor
ASG
PhAAngCor
ASG
PhBAngCor
ASG
PhCAngCor
ASG
VtTyp
ING
VtSecAdpt
ASG
PhAMagAdpt
ASG
PhBMagAdpt
ASG
PhCMagAdpt
ASG
Rated ext. primary current In
E
Function enable
E
LPVT rated primary voltage
E
VL1 magnitude correction
E
VL2 magnitude correction
E
VL3 magnitude correction
E
VL1 Angle correction
E
VL2 Angle correction
E
VL3 Angle correction
E
Primary VT type
E
VT secondary rated voltage
E
VL1 Adapt magnitude correction E
VL2 Adapt magnitude correction E
VL3 Adapt magnitude correction E
Standardized and extended DO of logical node type
The following table presents a summary of the standardized and extended DO of each Logical Node Type.
LN Type: SE_GAPC_PS_EasergyP5_V001 Description: Generic automatic process control LN Class: GAPC
Data object name P5PSGAPC1...8
Common data class
GAPC class
Explanation
The name shall be composed of the class name, the LN-Prefix and LN-Instance-ID according to IEC 61850-7-2, Clause 22.
Data Objects
Common Logical Node Information
Mod
ENC
Mode
Beh Health NamPlt
ENS ENS LPL
Behaviour Health Name plate
Status Information Str Op
ACD ACT
Start Operate
Settings
FunEna
SPG
Function enable
M/O/ C/E M
C1 M C1 C1
O O
E
Remarks Status-only
LN Type: SE_GGIO_AR_EasergyP5FU_V001 Description: Generic process I/O
278
P5/EN M/33A
Appendix 3: IEC 61850 Edition 2 conformance statement
LN Class: GGIO
Data object name P5ARGGIO1
Common data class
GGIO class
Explanation
The name shall be composed of the class name, the LN-Prefix and LN-Instance-ID according to IEC 61850-7-2, Clause 22.
Data Objects
Common Logical Node Information
Mod
ENC
Mode
Beh Health NamPlt
ENS ENS LPL
Behaviour Health Name plate
Status Information Ind1
SPS
AR1 final trip
Ind2
SPS
AR2 final trip
Ind3
SPS
AR3 final trip
Ind4
SPS
AR4 final trip
Ind5
SPS
AR5 final trip
Ind6
SPS
AR6 final trip
Ind7
SPS
AR7 final trip
Ind8
SPS
AR8 final trip
Ind9
SPS
AR9 final trip
Ind10
SPS
AR10 final trip
Ind11
SPS
AR11 final trip
Ind12
SPS
AR12 final trip
Ind13
SPS
AR13 final trip
Ind14
SPS
AR14 final trip
Ind15
SPS
AR15 final trip
Ind16
SPS
AR16 final trip
Ind17
SPS
AR17 final trip
Ind18
SPS
AR18 final trip
Ind19
SPS
AR19 final trip
Settings
FunEna
SPG
Function enable
M/O/ C/E M
C1 M C1 C1
O O O O O O O O O O O O O O O O O O O
E
Remarks Status-only
LN Type: SE_GGIO_CBWA_EasergyP5FMU_V002 Description: Generic process I/O LN Class: GGIO
Data object name P5CBWAGGIO1
Common data class
GGIO class
Explanation
The name shall be composed of the class name, the LN-Prefix and LN-Instance-ID according to IEC 61850-7-2, Clause 22.
Data Objects
Common Logical Node Information
M/O/ C/E
M
Remarks
P5/EN M/33A
279
Appendix 3: IEC 61850 Edition 2 conformance statement
Data object name
Mod Beh Health NamPlt Status Information Ind1 Ind2 Alm1Phs1 Alm1Phs2 Alm1Phs3 Alm2Phs1 Alm2Phs2 Alm2Phs3 Settings FunEna CBOpenCnt RackOutCnt TripCnt AlmLev1 AlmLev2 LimOpNum1 LimOpNum2
Common data class ENC ENS ENS LPL
SPS SPS INS INS INS INS INS INS
SPG ING ING ING ASG ASG ASG ASG
GGIO class Explanation
Mode Behaviour Health Name plate
General indication (binary input) General indication (binary input) Alarm 1 of Phase 1 Alarm 1 of Phase 2 Alarm 1 of Phase 3 Alarm 2 of Phase 1 Alarm 2 of Phase 2 Alarm 2 of Phase 3
Function enable CB open counter Rack out counter Protection trip counter Alarm level 1 Alarm level 2 Limit for operate left 1 Limit for operate left 2
M/O/ C/E C1
M C1 C1
Remarks Status-only
O O E E E E E E
E E E E E E E E
LN Type: SE_MMXU_VECA_EasergyP5FMU_VSI_V001 Description: Measurement LN Class: MMXU
Data object name P5VECAMMXU1
Common data class
MMXU class
Explanation
The name shall be composed of the class name, the LN-Prefix and LN-Instance-ID according to IEC 61850-7-2, Clause 22.
Data Objects
Common Logical Node Information
Mod
ENC
Mode
Beh Health NamPlt
ENS ENS LPL
Behaviour Health Name plate
Measured values
Hz
MV
Frequency
A
WYE
Phase currents (IL1, IL2, IL3)
Iovs
WYE
Residual current Io'
M/O/ C/E M
C1 M C1 C1
O O E
Remarks Status-only
LN Type: SE_PDOP_REVP_EasergyP5FM_V002 Description: Directional overpower LN Class: PDOP
280
P5/EN M/33A
Appendix 3: IEC 61850 Edition 2 conformance statement
Data object name
P5REVPPDOP1 P5REVPPDOP2
Common data class
PDOP class
Explanation
The name shall be composed of the class name, the LN-Prefix and LN-Instance-ID according to IEC 61850-7-2, Clause 22.
Data Objects
Common Logical Node Information
Mod
ENC
Mode
Beh Health NamPlt
ENS ENS LPL
Behaviour Health Name plate
Status Information Str Op
ACD ACT
Start Operate
Settings
FunEna StrVal
SPG ASG
Function enable Pick-up value
OpDlTms
ASG
Operate delay time
M/O/ C/E M
C1 M C1 C1
M M
E O E
Remarks Status-only
LN Type: SE_PDOP_EF_EasergyP5FM_V002 Description: Directional overpower LN Class: PDOP
Data object name
P5EFPDOP1 P5EFPDOP2
Common data class
PDOP class
Explanation
The name shall be composed of the class name, the LN-Prefix and LN-Instance-ID according to IEC 61850-7-2, Clause 22.
Data Objects
Common Logical Node Information
Mod
ENC
Mode
Beh Health NamPlt
ENS ENS LPL
Behaviour Health Name plate
Status Information Str Op
ACD ACT
Start Operate
Settings
FunEna DirMode StrVal
SPG ENG ASG
Function enable Direction mode Pick-up value
UoStrVal
ASG
Uo setting
SctrStrVal
ASG
Pick up sector size
OpDlTms
ASG
Operate delay time
SolMod SolOpDlTms
SPG ASG
SOL Mode SOL operate delay time
M/O/ C/E M
C1 M C1 C1
M M
E E M E E E E E
Remarks Status-only
P5/EN M/33A
281
Appendix 3: IEC 61850 Edition 2 conformance statement
Data object name
MemMod MmUoStrVal MemTms
Common data class ENG
ASG
ASG
PDOP class Explanation
Memory Mode Uo setting Memory time
M/O/ C/E E
E
E
Remarks
LN Type: SE_PFRC_DFDT_EasergyP5FV_V002 SE_PFRC_DFDT_EasergyP5U_LPT_V002 Description: Rate of change of frequency LN Class: PFRC
Data object name
P5DFDTPFRC1 P5DFDTPFRC2 P5DFTLPFRC1 P5DFTLPFRC2 Data Objects
Common data class
PFRC class
Explanation
The name shall be composed of the class name, the LN-Prefix and LN-Instance-ID according to IEC 61850-7-2, Clause 22.
Common Logical Node Information
Mod
ENC
Mode
Beh Health NamPlt
ENS ENS LPL
Behaviour Health Name plate
Status Information Str Op
ACD ACT
Start Operate
Settings
FunEna DirChg
SPG ENG
Function enable Direction of change
StrVal
ASG
Pick-up value
OpDlTms
ASG
Operate delay time
M/O/ C/E M
C1 M C1 C1
M M
E E O E
Remarks Status-only
LN Type: SE_PIOC_CBFP_EasergyP5FMU_V002 Description: Instantaneous overcurrent LN Class: PIOC
Data object name P5CBFPPIOC1
Common data class
PIOC class
Explanation
The name shall be composed of the class name, the LN-Prefix and LN-Instance-ID according to IEC 61850-7-2, Clause 22.
Data Objects
Common Logical Node Information
Mod
ENC
Mode
Beh Health NamPlt
ENS ENS LPL
Behaviour Health Name plate
Status Information
M/O/ C/E M
C1 M C1 C1
Remarks Status-only
282
P5/EN M/33A
Appendix 3: IEC 61850 Edition 2 conformance statement
Data object name
Str Op Settings FunEna NeutStrVal
PhsStrVal
Tm1DlTms Tm1Ena Tm2DlTms Tm2Ena
Common data class ACD ACT
SPG ASG
ASG
ASG SPG ASG SPG
PIOC class Explanation
Start Operate
M/O/ C/E
O
M
Remarks
Function enable
E
Undercurrent threshold for earth
E
fault current
Undercurrent threshold for phase E current
Timer1 operate delay time
E
Enable CBF timer1
E
Timer2 operate delay time
E
Enable CBF timer2
E
LN Type: SE_PIOC_CBFP_EasergyP5V_V002 Description: Instantaneous overcurrent LN Class: PIOC
Data object name P5CBFPPIOC2
Common data class
PIOC class
Explanation
The name shall be composed of the class name, the LN-Prefix and LN-Instance-ID according to IEC 61850-7-2, Clause 22.
Data Objects
Common Logical Node Information
Mod
ENC
Mode
Beh Health NamPlt
ENS ENS LPL
Behaviour Health Name plate
Status Information Str Op
ACD ACT
Start Operate
Settings
FunEna Tm1DlTms
SPG ASG
Function enable Timer1 operate delay time
Tm1Ena Tm2DlTms
SPG ASG
Enable CBF timer1 Timer2 operate delay time
Tm2Ena
SPG
Enable CBF timer2
M/O/ C/E M
C1 M C1 C1
O M
E E E E E
Remarks Status-only
LN Type: SE_PIOC_CBFP_EasergyP5FMU_VSI_V001 Description: Instantaneous overcurrent LN Class: PIOC
P5/EN M/33A
283
Appendix 3: IEC 61850 Edition 2 conformance statement
Data object name P5CBFPPIOC3
Common data class
PIOC class
Explanation
The name shall be composed of the class name, the LN-Prefix and LN-Instance-ID according to IEC 61850-7-2, Clause 22.
Data Objects
Common Logical Node Information
Mod
ENC
Mode
Beh Health NamPlt
ENS ENS LPL
Behaviour Health Name plate
Status Information Str Op
ACD ACT
Start Operate
Settings
FunEna NeutStrVal
PhsStrVal
IovsStrVal Tm1DlTms
SPG ASG
ASG
ASG ASG
Function enable
Undercurrent threshold for earth fault current
Undercurrent threshold for phase current
Io'< current set
Timer1 operate delay time
Tm1Ena Tm2DlTms
SPG ASG
Enable CBF timer1 Timer2 operate delay time
Tm2Ena
SPG
Enable CBF timer2
M/O/ C/E M
C1 M C1 C1
O M
E E E E E E E E
Remarks Status-only
LN Type: SE_PIOC_ARCM_EasergyP5FM_ARC_V001 Description: Instantaneous overcurrent LN Class: PIOC
Data object name P5ARCMPIOC1...8
Common data class
PIOC class
Explanation
The name shall be composed of the class name, the LN-Prefix and LN-Instance-ID according to IEC 61850-7-2, Clause 22.
Data Objects
Common Logical Node Information
Mod
ENC
Mode
Beh Health NamPlt
ENS ENS LPL
Behaviour Health Name plate
Status Information Op
ACT
Operate
Settings
FunEna MinOpTmms
SPG ING
Function enable Min. hold time [x1ms]
M/O/ C/E M
C1 M C1 C1
M
E E
Remarks Status-only
284
P5/EN M/33A
Appendix 3: IEC 61850 Edition 2 conformance statement
Data object name
OpDlTmms OpMode
Common data class
ING
ENG
PIOC class Explanation
Trip X delay [x1ms] Arc stage X Mode
M/O/ C/E
E
E
Remarks
LN Type: SE_PIOC_CLP_EasergyP5FMU_V001 Description: Instantaneous overcurrent LN Class: PIOC
Data object name P5CLPPIOC1
Common data class
PIOC class
Explanation
The name shall be composed of the class name, the LN-Prefix and LN-Instance-ID according to IEC 61850-7-2, Clause 22.
Data Objects
Common Logical Node Information
Mod
ENC
Mode
Beh Health NamPlt
ENS ENS LPL
Behaviour Health Name plate
Status Information Op
ACT
Operate
Settings
FunEna Idl StrVal
SPG ASG ASG
Function enable Idle current Pickup current
DeadTms MaxTms
ASG ASG
CLPU dead time Maximum time
M/O/ C/E M
C1 M C1 C1
M
E E O E E
Remarks Status-only
LN Type: SE_PIOC_SOL_EasergyP5FMU_V001 Description: Instantaneous overcurrent LN Class: PIOC
Data object name P5SOLPIOC1
Common data class
PIOC class
Explanation
The name shall be composed of the class name, the LN-Prefix and LN-Instance-ID according to IEC 61850-7-2, Clause 22.
Data Objects
Common Logical Node Information
Mod
ENC
Mode
Beh Health NamPlt
ENS ENS LPL
Behaviour Health Name plate
Status Information
Op
ACT
Operate
Oprt2
ACT
2nd Operate
Settings
M/O/ C/E M
C1 M C1 C1
M E
Remarks Status-only
P5/EN M/33A
285
Appendix 3: IEC 61850 Edition 2 conformance statement
Data object name
FunEna SigNum CbClrTms
Common data class SPG ENG
ASG
PIOC class Explanation
Function enable SOL signal number CB trip clearing time
M/O/ C/E E E
E
Remarks
LN Type: SE_PIOC_SOTF_EasergyP5FMU_V001 Description: Instantaneous overcurrent LN Class: PIOC
Data object name P5SOTFPIOC1
Common data class
PIOC class
Explanation
The name shall be composed of the class name, the LN-Prefix and LN-Instance-ID according to IEC 61850-7-2, Clause 22.
Data Objects
Common Logical Node Information
Mod
ENC
Mode
Beh Health NamPlt
ENS ENS LPL
Behaviour Health Name plate
Status Information Op
ACT
Operate
Settings
FunEna StrVal
SPG ASG
Enable for SOTF Pick-up value
DetDlTms
ASG
Dead line detection delay
ActTmrTms
ASG
SOTF active Timer
M/O/ C/E M
C1 M C1 C1
M
E O E E
Remarks Status-only
LN Type: SE_PMRI_MOTFST_EasergyP5MU_V003 Description: Motor restart inhibition LN Class: PMRI
Data object name P5FSTPMRI1
Common data class
PMRI class
Explanation
The name shall be composed of the class name, the LN-Prefix and LN-Instance-ID according to IEC 61850-7-2, Clause 22.
Data Objects
Common Logical Node Information
Mod
ENC
Mode
Beh Health NamPlt
ENS ENS LPL
Behaviour Health Name plate
Status Information Op
ACT
Operate
StrInh Settings
SPS
Restart inhibited
M/O/ C/E M
C1 M C1 C1
O O
Remarks Status-only
286
P5/EN M/33A
Appendix 3: IEC 61850 Edition 2 conformance statement
Data object name
MaxWrmStr
MinStrTmm HotSttsLmt FunEna MaxCldStr RefPrdTmm
Common data class ING
ASG ASG SPG ING ASG
PMRI class
Explanation
M/O/ C/E
Maximum warm starts, permissible O number of warm starts
Min time between motor starts
E
Hot Status Limit
E
Function enable
E
Max motor cold starts/hour
E
Reference period
E
Remarks
LN Type: SE_PMSS_STAL_EasergyP5MU_V001 Description: Motor starting time supervision LN Class: PMSS
Data object name P5STALPMSS1
Common data class
PMSS class
Explanation
The name shall be composed of the class name, the LN-Prefix and LN-Instance-ID according to IEC 61850-7-2, Clause 22.
M/O/ C/E
M
Data Objects
Common Logical Node Information
Mod
ENC
Mode
C1
Beh
ENS
Behaviour
M
Health
ENS
Health
C1
NamPlt
LPL
Name plate
C1
Status Information
Str
ACD
Start
O
Op
ACT
Operate
O
Settings
SetA
ASG
Current setting for motor start-up O
SetTms
ING
Time setting for motor start-up
O
MotStr
ASG
Motor startup (current pickup value O of motor starting)
FunEna
SPG
Function enable
E
TmACrv
CURVE
Characteristics for Ist>
E
Remarks Status-only
LN Type: SE_PMSS_MSPD_EasergyP5MU_V001 Description: Motor starting time supervision LN Class: PMSS
Data object name P5MSPDPMSS1
Common data class
PMSS class
Explanation
The name shall be composed of the class name, the LN-Prefix and LN-Instance-ID according to IEC 61850-7-2, Clause 22.
Data Objects
Common Logical Node Information
Mod
ENC
Mode
Beh
ENS
Behaviour
M/O/ C/E M
C1 M
Remarks Status-only
P5/EN M/33A
287
Appendix 3: IEC 61850 Edition 2 conformance statement
Data object name
Health NamPlt Status Information ZerSpdSt MotSpd Settings FunEna SpdIn RtdMotSpd PlsRot ZerSpdTms
Common data class ENS LPL
SPS INS
SPG ENG ASG ASG ASG
PMSS class Explanation
Health Name plate
Zero speed Motor speed
Function enable Motor speed input DI Rated motor speed Pulse per rotation Zero speed delay
M/O/ C/E
C1
C1
Remarks
E E
E E E E E
LN Type: SE_PMSS_MABS_EasergyP5MU_V001 Description: Motor starting time supervision LN Class: PMSS
Data object name P5MABSPMSS1
Common data class
PMSS class
Explanation
The name shall be composed of the class name, the LN-Prefix and LN-Instance-ID according to IEC 61850-7-2, Clause 22.
Data Objects
Common Logical Node Information
Mod
ENC
Mode
Beh Health NamPlt
ENS ENS LPL
Behaviour Health Name plate
Status Information AbsAlm
SPS
Anti-backspin Alarm
Settings
FunEna MvMod
SPG SPG
Function enable Measured Zero Speed Mode
SwMod
SPG
Zero Speed Switch Mode
AbsTms
ASG
Anti-backspin Delay
M/O/ C/E M
C1 M C1 C1
E
E E E E
Remarks Status-only
LN Type: SE_PMSS_51LR_EasergyP5MU_V001 Description: Motor starting time supervision LN Class: PMSS
Data object name P5LRPMSS1
Common data class
PMSS class
Explanation
The name shall be composed of the class name, the LN-Prefix and LN-Instance-ID according to IEC 61850-7-2, Clause 22.
Data Objects
Common Logical Node Information
M/O/ C/E
M
Remarks
288
P5/EN M/33A
Appendix 3: IEC 61850 Edition 2 conformance statement
Data object name
Mod Beh Health NamPlt Status Information Str Op Settings SetA FunEna DlTyp OpDlTms
Common data class ENC ENS ENS LPL
ACD ACT
ASG SPG ENG ASG
PMSS class Explanation
Mode Behaviour Health Name plate
Start Operate
Pick-up value Function enable Delay type Operate delay time
M/O/ C/E C1
M C1 C1
Remarks Status-only
O O
O E E E
LN Type: SE_PTEF_IO_EasergyP5F_V002 Description: Transient earth fault LN Class: PTEF
Data object name P5IOIOPTEF1
Common data class
PTEF class
Explanation
The name shall be composed of the class name, the LN-Prefix and LN-Instance-ID according to IEC 61850-7-2, Clause 22.
M/O/ C/E
M
Data Objects
Common Logical Node Information
Mod
ENC
Mode
C1
Beh
ENS
Behaviour
M
Health
ENS
Health
C1
NamPlt
LPL
Name plate
C1
Status Information
Str
ACD
Start
C
Op
ACT
Operate
C
Settings
FunEna
SPG
Function enable
E
DirMode
ENG
Direction mode
E
GndStr
ASG
Uo pick-up
O
OpDlTms
ASG
Operate delay time
E
MinPeak
ING
Min number of peaks
E
RsDlTms
ASG
Reset delay
E
Condition C: at least one of the two status information (Str, Op) shall be used.
Remarks Status-only
LN Type: SE_PTOC_STRVAL_EasergyP5FMU_V002 Description: Time overcurrent LN Class: PTOC
P5/EN M/33A
289
Appendix 3: IEC 61850 Edition 2 conformance statement
Data object name P5HAR5PTOC1
Common data class
PTOC class
Explanation
The name shall be composed of the class name, the LN-Prefix and LN-Instance-ID according to IEC 61850-7-2, Clause 22.
Data Objects
Common Logical Node Information
Mod
ENC
Mode
Beh Health NamPlt
ENS ENS LPL
Behaviour Health Name plate
Status Information Str Op
ACD ACT
Start Operate
Settings
StrVal OpDlTmms
ASG ING
Start value Operate delay time
FunEna
SPG
Function enable
M/O/ C/E M
C1 M C1 C1
M M
O O E
Remarks Status-only
LN Type: SE_PTOC_UIBC_EasergyP5FMU_V002 Description: Time overcurrent LN Class: PTOC
Data object name P5UIBCPTOC1
Common data class
PTOC class
Explanation
The name shall be composed of the class name, the LN-Prefix and LN-Instance-ID according to IEC 61850-7-2, Clause 22.
Data Objects
Common Logical Node Information
Mod
ENC
Mode
Beh Health NamPlt
ENS ENS LPL
Behaviour Health Name plate
Status Information Str Op
ACD ACT
Start Operate
Settings
FunEna StrVal OpDlTms
SPG ASG ASG
Function enable Start value Operate delay time
M/O/ C/E M
C1 M C1 C1
M M
E O E
Remarks Status-only
LN Type: SE_PTOC_EasergyP5FMU_VSI_V002 Description: Time overcurrent LN Class: PTOC
290
P5/EN M/33A
Appendix 3: IEC 61850 Edition 2 conformance statement
Data object name
P5EFVSPTOC1 P5EFVSPTOC2
Common data class
PTOC class
Explanation
The name shall be composed of the class name, the LN-Prefix and LN-Instance-ID according to IEC 61850-7-2, Clause 22.
Data Objects
Common Logical Node Information
Mod
ENC
Mode
Beh Health NamPlt
ENS ENS LPL
Behaviour Health Name plate
Status Information Str Op
ACD ACT
Start Operate
Settings
FunEna StrVal
SPG ASG
Function enable Pick-up value
DlCrvFmly
ENG
Delay curve family
DlTyp
ENG
Delay type
OpDlTms
ASG
Operate delay time
TmMult RsTyp
ASG ENG
Inv. time coefficient Reset type
RsDlTms
ASG
Reset time
InrushStat SolStat SolOpDTms
SPG SPG ASG
Inrush status SOL status SOL operate delay time
SolTmMult ClpStat
ASG SPG
SOL Inv. time coefficient CLP status
ClpStrVal
ASG
CLP pick-up value
ClpOpDTms
ASG
CLP operate delay time
ClpTmMult
ASG
CLP Inv. time coefficient
NetGrd
ENG
Network grounding
M/O/ C/E M
C1 M C1 C1
M M
E O E E E O E E E E E E E E E E E
Remarks Status-only
LN Type: SE_PTOC_NORMAL_EasergyP5FMU_V002 Description: Time overcurrent LN Class: PTOC
Data object name
P5OCPTOC1 P5OCPTOC2
Common data class
PTOC class
Explanation
The name shall be composed of the class name, the LN-Prefix and LN-Instance-ID according to IEC 61850-7-2, Clause 22.
Data Objects
Common Logical Node Information
Mod
ENC
Mode
Beh
ENS
Behaviour
M/O/ C/E M
C1 M
Remarks Status-only
P5/EN M/33A
291
Appendix 3: IEC 61850 Edition 2 conformance statement
Data object name
Health NamPlt Status Information Str Op Settings FunEna StrVal DlCrvFmly DlTyp OpDlTms TmMult RsTyp RsDlTms InrushStat SolStat SolOpDTms SolTmMult ClpStat ClpStrVal ClpOpDTms ClpTmMult
Common data class ENS LPL
ACD ACT
SPG ASG ENG ENG ASG ASG ENG ASG SPG SPG ASG ASG SPG ASG ASG ASG
PTOC class Explanation
Health Name plate
Start Operate
Function enable Pick-up value Delay curve family Delay type Operate delay time Inv. time coefficient Reset type Reset time Inrush status SOL status SOL operate delay time SOL Inv. time coefficient CLP status CLP pick-up value CLP operate delay time CLP Inv. time coefficient
M/O/ C/E
C1
C1
Remarks
M M
E O E E E O E E E E E E E E E E
LN Type: SE_PTOC_EasergyP5FM_V002 Description: Time overcurrent LN Class: PTOC
Data object name
P5DEFPTOC1 P5DEFPTOC2 P5DEFPTOC3
Common data class
PTOC class
Explanation
The name shall be composed of the class name, the LN-Prefix and LN-Instance-ID according to IEC 61850-7-2, Clause 22.
Data Objects
Common Logical Node Information
Mod
ENC
Mode
Beh Health NamPlt
ENS ENS LPL
Behaviour Health Name plate
Status Information Str Op
ACD ACT
Start Operate
Settings
FunEna DirMode
SPG ENG
Function enable Direction mode
M/O/ C/E M
C1 M C1 C1
M M
E E
Remarks Status-only
292
P5/EN M/33A
Appendix 3: IEC 61850 Edition 2 conformance statement
Data object name
StrVal UoStrVal AngOffset SctrStrVal DlCrvFmly DlTyp OpDlTms TmMult RsTyp RsDlTms
Common data class ASG ASG ASG ASG ENG ENG ASG ASG ENG ASG
PTOC class Explanation
Pick-up value Uo setting Angle offset Pick up sector size Delay curve family Delay type Operate delay time Inv. time coefficient Reset type Reset time
M/O/ C/E O E E E E E E O E E
Remarks
LN Type: SE_PTOC_EasergyP5U_LPT_V002 Description: Time overcurrent LN Class: PTOC
Data object name
P5DOCLPTOC1 P5DOCLPTOC2
Common data class
PTOC class
Explanation
The name shall be composed of the class name, the LN-Prefix and LN-Instance-ID according to IEC 61850-7-2, Clause 22.
Data Objects
Common Logical Node Information
Mod
ENC
Mode
Beh Health NamPlt
ENS ENS LPL
Behaviour Health Name plate
Status Information Str Op
ACD ACT
Start Operate
Settings
FunEna StrVal
SPG ASG
Function enable Pick-up value
DirMode AngOffset
ENG ASG
Direction mode Angle offset
DlCrvFmly
ENG
Delay curve family
DlTyp
ENG
Delay type
OpDlTms
ASG
Operate delay time
TmMult RsTyp
ASG ENG
Inv. time coefficient Reset type
RsDlTms InrushStat SolStat SolOpDTms
ASG SPG SPG ASG
Reset time Inrush status SOL status SOL operate delay time
M/O/ C/E M
C1 M C1 C1
M M
E O E E E E E O E E E E E
Remarks Status-only
P5/EN M/33A
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Appendix 3: IEC 61850 Edition 2 conformance statement
Data object name
SolTmMult ClpStat ClpStrVal ClpOpDTms ClpTmMult
Common data class ASG SPG ASG ASG ASG
PTOC class Explanation
SOL Inv. time coefficient CLP status CLP pick-up value CLP operate delay time CLP Inv. time coefficient
M/O/ C/E E E E E E
Remarks
LN Type: SE_PTOC_DOC2_EasergyP5U_LPT_V001 Description: Time overcurrent LN Class: PTOC
Data object name
P5DOCLPTOC3 P5DOCLPTOC4
Common data class
PTOC class
Explanation
The name shall be composed of the class name, the LN-Prefix and LN-Instance-ID according to IEC 61850-7-2, Clause 22.
Data Objects
Common Logical Node Information
Mod
ENC
Mode
Beh Health NamPlt
ENS ENS LPL
Behaviour Health Name plate
Status Information Str Op
ACD ACT
Start Operate
Settings
FunEna StrVal
SPG ASG
Function enable Pick-up value
DirMode AngOffset
ENG ASG
Direction mode Angle offset
OpDlTms
ASG
Operate delay time
InrushStat SolStat SolOpDTms
SPG SPG ASG
Inrush status SOL status SOL operate delay time
ClpStat
SPG
CLP status
ClpStrVal
ASG
CLP pick-up value
ClpOpDTms
ASG
CLP operate delay time
M/O/ C/E M
C1 M C1 C1
M M
E O E E E E E E E E E
Remarks Status-only
LN Type: SE_PTOF_OFUF_EasergyP5FMV_V00V002/ SE_PTOF_OFUF_EasergyP5U_LPT_V002 Description: Overfrequency LN Class: PTOF
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Data object name
P5OFUFPTOF1 P5OFUFPTOF2 P5LPTPTOF1 P5LPTPTOF2 Data Objects
Common data class
PTOF class
Explanation
The name shall be composed of the class name, the LN-Prefix and LN-Instance-ID according to IEC 61850-7-2, Clause 22.
Common Logical Node Information
Mod
ENC
Mode
Beh Health NamPlt
ENS ENS LPL
Behaviour Health Name plate
Status Information Str Op
ACD ACT
Start Operate
Settings
FunEna StrVal
SPG ASG
Function enable Pick-up value
OpDlTms
ASG
Operate delay time
M/O/ C/E M
C1 M C1 C1
M M
E O E
Remarks Status-only
LN Type: SE_PTOV_EasergyP5FMV_V002/ SE_PTOV_EasergyP5U_LPT_V001 Description: Overvoltage LN Class: PTOV
Data object name
P5OVPTOV1 P5OVPTOV2 P5OVPTOV3
P5OVLPTOV1 P5OVLPTOV2 P5OVLPTOV3
Data Objects
Common data class
PTOV class
Explanation
The name shall be composed of the class name, the LN-Prefix and LN-Instance-ID according to IEC 61850-7-2, Clause 22.
Common Logical Node Information
Mod
ENC
Mode
Beh Health NamPlt
ENS ENS LPL
Behaviour Health Name plate
Status Information Str Op
ACD ACT
Start Operate
Settings
FunEna StrVal
SPG ASG
Function enable Pick-up value
OpDlTms
ASG
Operate delay time
M/O/ C/E M
C1 M C1 C1
M O
E O E
Remarks Status-only
LN Type: SE_PTOV_UO_EasergyP5FMV_V001/ SE_PTOV_UO_EasergyP5U_LPT_V001 Description: Overvoltage
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LN Class: PTOV
Data object name
P5UOPTOV1 P5UOPTOV2 P5UOPTOV3
P5UOLPTOV1 P5UOLPTOV2 P5UOLPTOV3
Data Objects
Common data class
PTOV class
Explanation
The name shall be composed of the class name, the LN-Prefix and LN-Instance-ID according to IEC 61850-7-2, Clause 22.
Common Logical Node Information
Mod
ENC
Mode
Beh Health NamPlt
ENS ENS LPL
Behaviour Health Name plate
Status Information Str Op
ACD ACT
Start Operate
Settings
FunEna StrVal
SPG ASG
Function enable Pick-up value
OpDlTms
ASG
Operate delay time
RsDlTms
ASG
Reset time
M/O/ C/E M
C1 M C1 C1
M O
E O E E
Remarks Status-only
LN Type: SE_PTOV_NEG_EasergyP5FMV_V001/ SE_PTOV_NEG_EasergyP5U_LPT_V001 Description: Overvoltage LN Class: PTOV
Data object name
P5NEGPTOV1 P5NEGPTOV2 P5NEGLPTOV1 P5NEGLPTOV2 Data Objects
Common data class
PTOV class
Explanation
The name shall be composed of the class name, the LN-Prefix and LN-Instance-ID according to IEC 61850-7-2, Clause 22.
Common Logical Node Information
Mod
ENC
Mode
Beh Health NamPlt
ENS ENS LPL
Behaviour Health Name plate
Status Information Str Op
ACD ACT
Start Operate
Settings
FunEna OpMod
SPG ENG
Function enable Operate mode
StrVal
ASG
Pick-up value
M/O/ C/E M
C1 M C1 C1
M O
E E O
Remarks Status-only
296
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Appendix 3: IEC 61850 Edition 2 conformance statement
Data object name
DlTyp OpDlTms RsDlTms
Common data class ENG
ASG
ASG
PTOV class Explanation
Delay type Operate delay time Reset time
M/O/ C/E E
E
E
Remarks
LN Type: SE_PTOV_CAP_EasergyP5F_V001 Description: Overvoltage LN Class: PTOV
Data object name P5CAPPTOV1
Common data class
PTOV class
Explanation
The name shall be composed of the class name, the LN-Prefix and LN-Instance-ID according to IEC 61850-7-2, Clause 22.
Data Objects
Common Logical Node Information
Mod
ENC
Mode
Beh Health NamPlt
ENS ENS LPL
Behaviour Health Name plate
Status Information Str Op
ACD ACT
Start Operate
Settings
FunEna
SPG
Function enable
StrVal
ASG
Pick-up value
CapOfPhs
ASG
L-N capacitance of one phase
RatUcLn
ASG
Rated L-N voltage UcLN
OpDlTms
ASG
Operate delay time
M/O/ C/E M
C1 M C1 C1
M O
E O E E E
Remarks Status-only
LN Type: SE_PTTR_THF_EasergyP5FU_V002 Description: Thermal overload LN Class: PTTR
Data object name P5THFPTTR1
Common data class
PTTR class
Explanation
The name shall be composed of the class name, the LN-Prefix and LN-Instance-ID according to IEC 61850-7-2, Clause 22.
Data Objects
Common Logical Node Information
Mod
ENC
Mode
Beh Health NamPlt
ENS ENS LPL
Behaviour Health Name plate
Status Information
M/O/ C/E M
C1 M C1 C1
Remarks Status-only
P5/EN M/33A
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Appendix 3: IEC 61850 Edition 2 conformance statement
Data object name
Op AlmThm Settings TmpMax AlmVal FunEna BasicCur FactorK HeaConsTmm RsvVal TmpMod TmpNom TmpAlrm TmpAmbMin TmpAmbDft
Common data class ACT SPS
ASG ASG SPS ASG ASG ASG ASG ENG ASG ASG ASG ASG
PTTR class Explanation
Operate Thermal alarm
Max object temperature Thermal alarm value Function enable Basic current setting Factor k Heating time constant Reserve time thermal alarm Temperature based mode Nominal ambient temp Alarm temperature Min ambient temperature Default ambient temperature
M/O/ C/E
M
O
Remarks
O O E E E O E E E E E E
LN Type: SE_PTTR_THM_EasergyP5MU_V002 Description: Thermal overload LN Class: PTTR
Data object name P5THMPTTR1
Common data class
PTTR class
Explanation
The name shall be composed of the class name, the LN-Prefix and LN-Instance-ID according to IEC 61850-7-2, Clause 22.
Data Objects
Common Logical Node Information
Mod
ENC
Mode
Beh Health NamPlt
ENS ENS LPL
Behaviour Health Name plate
Status Information Op
ACT
Operate
AlmThm Settings
SPS
Thermal alarm
TmpMax
ASG
Max object temperature
AlmVal FunEna BasicCur
ASG SPS ASG
Thermal alarm value Function enable Basic current setting
FactorK HeaConsTmm
ASG ASG
Factor k Heating time constant
ConsTmm
ASG
Time constant for motor starting
CooConsTmm
ASG
Cooling time constant
UnblFctr
ASG
Unbalance factor
M/O/ C/E M
C1 M C1 C1
M O
O O E E E E E E E
Remarks Status-only
298
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Appendix 3: IEC 61850 Edition 2 conformance statement
Data object name
RsvVal TmpMod TmpNom TmpAlrm TmpAmbMin TmpAmbDft
Common data class ASG ENG ASG ASG ASG ASG
PTTR class Explanation
Reserve time thermal alarm Temperature based mode Nominal ambient temp Alarm temperature Min ambient temperature Default ambient temperature
M/O/ C/E E E E E E E
Remarks
LN Type: SE_PTUC_UC_EasergyP5MU_V002 Description: Undercurrent LN Class: PTUC
Data object name P5UCPTUC1
Common data class
PTUC class
Explanation
The name shall be composed of the class name, the LN-Prefix and LN-Instance-ID according to IEC 61850-7-2, Clause 22.
Data Objects
Common Logical Node Information
Mod
ENC
Mode
Beh Health NamPlt
ENS ENS LPL
Behaviour Health Name plate
Status Information Str Op
ACD ACT
Start Operate
Settings
FunEna StrVal
SPG ASG
Function enable Pick-up value
OpDlTms
ASG
Operate delay time
M/O/ C/E M
C1 M C1 C1
M M
E O E
Remarks Status-only
LN Type: SE_PTUF_UF_EasergyP5FMV_V002/SE_PTUF_UF_EasergyP5U_ LPT_V002 Description: Underfrequency LN Class: PTUF
Data object name
P5UFPTUF1 P5UFPTUF2 P5UFLPTUF1 P5UFLPTUF2 Data Objects
Common data class
PTUF class
Explanation
The name shall be composed of the class name, the LN-Prefix and LN-Instance-ID according to IEC 61850-7-2, Clause 22.
Common Logical Node Information
Mod
ENC
Mode
Beh Health
ENS ENS
Behaviour Health
M/O/ C/E M
C1 M C1
Remarks Status-only
P5/EN M/33A
299
Appendix 3: IEC 61850 Edition 2 conformance statement
Data object name
NamPlt Status Information Str Op Settings FunEna StrVal OpDlTms
Common data class LPL
ACD ACT
SPG ASG ASG
PTUF class Explanation Name plate
Start Operate
Function enable Pick-up value Operate delay time
M/O/ C/E
C1
Remarks
M M
E O E
LN Type: SE_PTUV_UV_EasergyP5FMV_V002/ SE_PTUV_UV_EasergyP5U_LPT_V002 Description: Undervoltage LN Class: PTUV
Data object name
P5UVPTUV1 P5UVPTUV2 P5UVPTUV3
P5UVLPTUV1 P5UVLPTUV2 P5UVLPTUV3
Data Objects
Common data class
PTUV class
Explanation
The name shall be composed of the class name, the LN-Prefix and LN-Instance-ID according to IEC 61850-7-2, Clause 22.
Common Logical Node Information
Mod
ENC
Mode
Beh Health NamPlt
ENS ENS LPL
Behaviour Health Name plate
Status Information Str Op
ACD ACT
Start Operate
Settings
FunEna StrVal
SPG ASG
Function enable Pick-up value
OpDlTms
ASG
Operate delay time
M/O/ C/E M
C1 M C1 C1
M M
E O E
Remarks Status-only
LN Type: SE_PTUV_UVPS_EasergyP5MV_V002 Description: Undervoltage LN Class: PTUV
Data object name
P5UVPSPTUV1 P5UVPSPTUV2
Common data class
PTUV class
Explanation
The name shall be composed of the class name, the LN-Prefix and LN-Instance-ID according to IEC 61850-7-2, Clause 22.
Data Objects
Common Logical Node Information
Mod
ENC
Mode
M/O/ C/E M
C1
Remarks Status-only
300
P5/EN M/33A
Appendix 3: IEC 61850 Edition 2 conformance statement
Data object name
Beh Health NamPlt Status Information Str Op Settings FunEna StrVal OpDlTms
Common data class ENS ENS LPL
ACD ACT
SPG ASG ASG
PTUV class Explanation
Behaviour Health Name plate
Start Operate
Function enable Pick-up value Operate delay time
M/O/ C/E M
C1
C1
Remarks
M M
E O E
LN Type: SE_PZSU_EasergyP5MU_V001 Description: Motor underspeed LN Class: PZSU
Data object name P5MOTPZSU1
Common data class
PZSU class
Explanation
The name shall be composed of the class name, the LN-Prefix and LN-Instance-ID according to IEC 61850-7-2, Clause 22.
Data Objects
Common Logical Node Information
Mod
ENC
Mode
Beh Health NamPlt
ENS ENS LPL
Behaviour Health Name plate
Status Information Str Op
ACD ACT
Start Operate
Settings
FunEna StrVal
SPG ASG
Function enable Pick-up value
OpDlTms
ASG
Operate delay time
M/O/ C/E M
C1 M C1 C1
M M
E O E
Remarks Status-only
LN Type: SE_PHAR_ID_EasergyP5FMU_V001 Description: Harmonic restraint LN Class: PHAR
Data object name P5IDPHAR1
Common data class
PHAR class
Explanation
The name shall be composed of the class name, the LN-Prefix and LN-Instance-ID according to IEC 61850-7-2, Clause 22.
Data Objects
Common Logical Node Information
Mod
ENC
Mode
M/O/ C/E M
C1
Remarks Status-only
P5/EN M/33A
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Appendix 3: IEC 61850 Edition 2 conformance statement
Data object name
Beh Health NamPlt Status Information Str
Common data class ENS ENS LPL
ACD
Settings FunEna StrVal CurBlkVal
SPG ASG ASG
PHAR class Explanation
Behaviour Health Name plate
Start (active when restraint is needed)
Function enable Pickup for 2nd harmonic Max inrush current
M/O/ C/E M
C1
C1
Remarks
M
E E E
Enum types extensions
New Enum types
Enum type ARCOpMode is one of new added types defined as below.
Value 0 1
Description Light Light and current
Remarks
Enum type DefDirMode is one of new added types defined as below.
Value 0 1 2
Description ResCap Sector Undir
Remarks
Enum type DocDirMode is one of new added types defined as below.
Value 0 1 2
Description Dir_Backup Undir Dir
Remarks
Enum type DlCrvFamily is one of new added types defined as below.
Value 0 1 2 3 4 5 6 7
Description DT IEC IEEE IEEE2 Others Prg1 Prg2 Prg3
Remarks
Enum type RsTyp is one of new added types defined as below.
302
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Value 0 1
Description DT IDMT
Remarks
Enum type DlType is one of new added types defined as below.
Value 0 1 2 3 4 5 6 7 8 9 10 11 12 13
Description DT NI VI EI LTI LTEI LTVI MI STI STEI CO8 RI RXIDG --
Remarks
Enum type NetGrd is one of new added types defined as below.
Value 0 1
Description Res Cap
Remarks
Enum type NegOPMod is one of new added type defined as below.
Value 0 1
Description No_Action Blocking
Remarks
Enum type NegDITyp is one of new added type defined as below.
Value 0 1
Description DT INV
Remarks
Enum type StrMod is one of new added type defined as below.
Value 0 1 2
Description Negative Positive Either
Remarks
Enum type MemoryMode is one of new added types defined as below.
Value 0 1
Description None Voltage
Remarks
P5/EN M/33A
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Appendix 3: IEC 61850 Edition 2 conformance statement
2
Time
3
Both
Enum type EfDirModeKind is one of new added type defined as below.
Value 0 1
Description Forward Reverse
Remarks
Enum type SlotDISelect is one of new added type defined as below.
Value 0 1 2
Description Slot_C_DI1 Slot_D_DI1 Slot_E_DI1
Remarks
Enum type VTTypeKind is one of new added type defined as below.
Value 0 1
Description VT LPVT
Remarks
Enum type TempModKind is one of new added type defined as below.
Value 0 1
Description Current Ambient
Remarks
Enum type PadmDirMod is one of new added type defined as below.
Value 0 1 2
Description Undir Forward Reverse
Remarks
Enum type SignalNum is one of new added type defined as below.
Value 0 1
Description 1 2
Remarks
Extended Enum types
Enum type SIUnitKind is extended by the following enumerations.
Value -6 -7 -8 -9 -10 -11
Quantity Numerical tagging method Percent Relative temperature Electric resistance Rotational speed Pulse per rotation
Unit name per unit percent degree Fahrenheit ohm (V/A) Revolutions per minute Pulse per rotation
Symbol pu % °F V/A rmp /R
304
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Appendix 3: IEC 61850 Edition 2 conformance statement
Enum type AutoReclosingKind is extended by the following enumerations.
Value -1 -2 -3 -4 -5 -6 -7 -8 -9 -10 -11 -12 -13
Symbol Reclaim Ready_Ext WaitOpen WaitClose Discrim Locked FinalTr CBFail Inhibit Blocked ExtOpen ExClose WaitSync
P5/EN M/33A
305
PIXIT details
Appendix 3: IEC 61850 Edition 2 conformance statement
Introduction
This PIXIT is based upon UCAIug PIXIT Template version 15, UCA International Users Group Testing Sub Committee, October 22, 2019.
This document specifies the protocol implementation extra information for testing (PIXIT) of the IEC 61850 interface in P5U20, P5V20, P5F30, P5M30, with firmware version V01.
Together with the PICS and the MICS the PIXIT document forms the basis for a conformance test according to IEC 61850-10. The PIXIT entries contain information which is not available in the PICS, MICS, TICS documents or SCL file.
Each chapter specifies the PIXIT for applicable ACSI service model as structured in IEC 61850-10. The "Ed" column indicates if the entry is applicable for IEC 61850 Edition 1 and/or Edition 2.
PIXIT for documentation
ID
Ed
Do1
2
Description
How to expose required firmware versions not present in the data model
Value / Clarification
Information included in the ICD file and in the data model (LLN0.NamePlt. swRev)
PIXIT for association model
The extra information for testing is given in the table below. Table 71 - Protocol implementation extra information for testing
ID
Ed
As1
1
As2
1,2
As3
1,2
As4
-
As5
1,2
As6
1,2
Description Maximum number of clients that can set-up an association simultaneously TCP_KEEPALIVE value. The recommended range is 0...20s Lost connection detection time
Authentication is not supported yet What association parameters are necessary for successful association
If association parameters are necessary for association, describe the correct values. Association parameters are configurable, default values are
Value / Clarification 8
Configurable: from 0 to 20s
TCP_KEEPALIVE + 2s *10 Maximum 140s (2s is retransmission interval of TCP Keep-alive message, 10 retransmissions) (0 means 120s)
Transport selector Calling: N Called: Y Session selector Calling: N Called: Y Presentation selector Calling: N Called: Y AP title Calling: N Called: N AE qualifier Calling: N Called: N Transport selector 1 Session selector 1 Presentation selector 1 AP title 1,1,1,999,1
306
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Appendix 3: IEC 61850 Edition 2 conformance statement
Table 71 - Protocol implementation extra information for testing (Continued)
ID
Ed
Description
Value / Clarification
As7
1,2
As8
1,2
As9
1,2
AE qualifier 12
What is the maximum and minimum MMS PDU size
Max: 65535 bytes Min: In initiate request 1024 bytes
What is the maximum start up time after a power supply interrupt
P5 relay start-up time including the server function is at average 180s; it depends on the configuration size (number and types of logical nodes)
Does this device function only as N test equipment?
(test equipment need not have a non-volatile configuration; but it cannot be part of the substation automation system)
PIXIT for server model
ID
Ed
Sr1
1,2
Sr2
1,2
Sr3
-
Sr4
-
Sr5
1
Description
Value / Clarification
Which analogue value (MX) quality bits are supported (can be set by server)
Validity: Y Good, N Invalid, N Reserved, N Questionable N Overflow N OutofRange N BadReference N Oscillatory N Failure N OldData N Inconsistent N Inaccurate
Source: Y Process N Substituted Y Test N OperatorBlocked
Which status value (ST) quality bits are supported (can be set by server)
Validity: Y Good, Y Invalid, N Reserved, Y Questionable N BadReference N Oscillatory N Failure Y OldData N Inconsistent N Inaccurate
Source: Y Process N Substituted Y Test N OperatorBlocked
What is the maximum number of data object references in one GetDataValues request
Deprecated
What is the maximum number of data object references in one SetDataValues request
Deprecated
Which Mode values are supported
On Y [On-]Blocked N Test Y Test/Blocked Y Off N
P5/EN M/33A
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Appendix 3: IEC 61850 Edition 2 conformance statement
PIXIT for data set model
ID
Ed
Ds1
1
Ds2
1
Ds3
1
Description
Details
What is the maximum number of data
500
elements in one data set (compare ICD
setting)
How many persistent data sets can be created 50 by one or more clients (this number includes predefined data sets)
How many non-persistent data sets can be
50
created by one or more clients
NOTE: Arrays are not supported in dataset.
PIXIT for setting group control model
ID
Ed
Sg1
1
Sg2
1,2
Sg3
1
Sg4
1
Sg5
1
Sg6
2
Description What is the number of supported setting groups for each logical device What is the effect of when and how the non-volatile storage is updated (compare IEC 61850-8-1 $16.2.4)
Can multiple clients edit the same setting group What happens if the association is lost while editing a setting group
Is EditSG value 0 allowed
When ResvTms is not present how long is an edit setting group locked
Value / Clarification
4
When: CnfEdit set to TRUE successfully.
How: the setting value in edit buffer will be copied to the selected setting group, and then the new value will be updated to non-volatile storage by setting engine.
N
The SE values changes are lost, the EditSG value will not change.
Y
Write a value of 0 to EditSG will cancel all the setting values in the Edit buffer.
Reserved forever except Cancel, Confirm or Disconnection.
PIXIT for reporting model
ID
Ed
Rp1
1
Description
The supported trigger conditions (compare PICS)
Rp2
1
The supported optional fields are
Details
integrity
Y
data change
Y
quality change
Y
data update
Y
general interrogation
Y
sequence-number
Y
report-time-stamp
Y
reason-for-inclusion
Y
data-set-name
Y
data-reference
Y
buffer-overflow (not
Y
applicable to URCB)
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Appendix 3: IEC 61850 Edition 2 conformance statement
ID
Ed
Rp3
1,2
Rp4
1,2
Rp5
1
Rp6
-
Rp7
1,2
Rp8
-
Rp9
1
Rp10 1,2 Rp11 1 Rp12 2 Rp13 1,2
Rp14 2
Description
Details
entryID (not applicable to Y URCB)
conf-rev
Y
segmentation
Y
Can the server send segmented
Y
reports?
(when not supported the device shall
refuse an association request with a
smaller than minimum PDU size)
Mechanism on second internal data change notification of the same analogue data value within buffer period (compare IEC 61850-7-2 $14.2.2.9)
Send report immediately
Multi client URCB approach (compare IEC 61850-7-2 $14.2.1)
Each URCB is visible to all clients
What is the format of EntryID
Deprecated
What is the buffer size for each BRCB or 100k bytes per report control
how many reports can be buffered
block
Pre-configured RCB attributes that are dynamic, compare SCL report settings
Deprecated
May the reported data set contain:
- structured data objects?
Y
- data attributes?
Y
What is the scan cycle for binary
5 milliseconds
events?
Is this fixed, configurable or event-driven Fixed
Does the device support to pre-assign a N RCB to a specific client in the SCL
After restart of the server is the value of ConfRev restored from the original configuration or retained prior to restart
from the original configuration
Does the server accept any client to
N
configure / enable a BRCB with
ResvTms=-1? What fields are used to
do the identification?
When BRCB.ResvTms is exposed, what 1s
is default value for BRCB.ResvTms if
client does not write (must be > 0) or
1s
When BRCB.ResvTms is not exposed,
what is the internal reservation time
(must be >= 0)
P5/EN M/33A
309
PIXIT for GOOSE publish model
ID
Ed
Gp1
1,2
Gp2
1
Gp3
1,2
Gp4
1,2
Gp5
1,2
Gp6
-
Gp7
1,2
Gp8
1
Gp9
1,2
Appendix 3: IEC 61850 Edition 2 conformance statement
Description
Value / Clarification
Can the test (Ed1) / simulation (Ed2) flag in the published GOOSE be set
What is the behavior when the GOOSE publish configuration is incorrect
Published FCD supported common data classes / data types are
N
NdsCom=T DUT keeps GoEna=F
Common data classes: SPS, DPC, CMV, MV Data types as single attributes: BOOLEAN, CODED ENUM, FLOAT32, QUALITY
Arrays are not supported.
What is the maximum value of TAL (maxTime)
Is it fixed or configurable
Maximum TAL = 120000 ms (double of maximum configurable slowest retransmission cycle 60000 ms)
Configurable by configuration tool
What is the fastest retransmission time
Is it fixed or configurable
4 ms
Retransmission scheme: First message upon data change, followed by 4, 10, 20, 40, 80, 160, 320, 640, 1280, 2500, 5000, 10000, 20000, 40000, 60000 and finally reaching the configured slow retransmission time).
TAL is set to value 2 times bigger than interval.
Can the GOOSE publish be turned on / off by using SetGoCBValues(GoEna)
Fixed Deprecated
What is initial GOOSE sqNum 1 after restart of the device
May the GOOSE data set
contain:
Y
- structured data objects
(FCD)
Y
- timestamp data attributes
Does Server or ICT check
Y
GOOSE payload data set
length
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PIXIT for GOOSE subscribe model
ID
Ed
Gs1
1,2
Gs2
1,2
Gs3
1,2
Gs4
1,2
Gs5
1,2
Gs6
1
Gs7
1
Gs8
1,2
Gs9
1,2
Description
Value / Clarification
What elements of a subscribed GOOSE message are checked to decide the message is valid and the allData values are accepted? If yes, describe the conditions.
Notes:
· the VLAN tag may be removed by a ethernet switch and shall not be checked
· the simulation flag shall always be checked (Ed2)
Y destination MAC address (equal to configured)
Y APPID (equal to configured)
N gocbRef
N timeAllowedtoLive (see Remarks)
N datSet
Y goID (equal to configured, checking can be set off)
Nt
Y stNum (see Remarks)
N sqNum (see Remarks)
Y simulation/test (if true, values not passed to application, the application data will keep last received value when simulation/test was false, but status of the network input stays valid)
Y confRev (equal to configured)
Y ndsCom (if true, values not passed to application, the application data will keep last received value , and network inputs status is set to invalid as if message was never received)
Y numDatSetEntries (see Remarks)
When is a subscribed GOOSE marked as lost
(TAL = time allowed to live value from the last received GOOSE message)
N out-of-order dataset members
Message does not arrive by TAL+1s
Internally in the relay there is a status indication to the application about GOOSE problem (data is marked as OLD if the message does not arrive prior to TAL+1s if TAL>1s or prior to 1s if TAL<1s).
What is the behavior when one or more subscribed GOOSE messages isn't received or syntactically incorrect (missing GOOSE)
The subsequently received GOOSE message is accepted even if the new state number is not equal to the incremented value of the previously received state number (it is enough that it is not equal to the last received state number).
What is the behavior when a subscribed GOOSE message is outof-order
Message is treated as normal (it is assumed that previous messages have been lost).
What is the behavior when a subscribed GOOSE message is duplicated
Duplicated message is ignored
Does the device subscribe to GOOSE messages with/without the VLAN tag
Y with the VLAN tag Y without the VLAN tag
May the GOOSE data
Y
set contain:
Y
- structured data objects
- data attributes
Subscribed FCD supported common data classes / data types are
Data classes: SPS, SPC, DPS, DPC, INS, INC, ENS, ENC, CMV, MV
Data types as single attributes: BOOLEAN, INT8, INT16, INT32, INT8U, INT16U, INT32U, ENUM, CODED ENUM, BITSTRING, FLOAT32
Arrays are not supported
Are subscribed GOOSE N - Simulation mode is not supported by the
with test=T (Ed1) /
device
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Appendix 3: IEC 61850 Edition 2 conformance statement
ID
Ed
Gs10 1,2 Gs11 1
Description
simulation=T (Ed2) accepted in test/ simulation mode
Max number of dataset members
Is Fixed-length encoded GOOSE supported
Value / Clarification
Unlimited Y
TAL = Time Allowed to Live
Remarks:
A GOOSE message will be accepted and processed by the subscriber in DUT:
· Even if it is received after expiration of the time allowed to live sent in the previous message,
· Even if the new state number is not equal to the incremented value of the previously received state number - it is enough that it is not equal to the last received state number,
· If the state number differs from the previously received state number, the sequence number is accepted with any value (if the state number is equal to the previously received state number, the message is treated as retransmission),
· Even if the received message contains a dataset of the size different than the size of the previously received dataset.
A GOOSE message will NOT be accepted by the subscriber in DUT if:
· Destination MAC address is not equal to configured one
· Protocol ID is not equal to 0x88B8
· APPID is not equal to configured one for any of the network inputs
· ConfRev is not equal to configured one for any of the network inputs
· goID is not equal to configured one for any of the network inputs
· state number is the same as in the previous message (is treated as retransmission)
· ndsCom bit is set to true in received message
Note for sGosN6h (out of order dataset):
Value from GOOSE message will be accepted even if the type is different than in previous message given that:
· Type is compatible with network input type i.e. for binary network inputs accepted types are: BOOLEAN, INTEGER and BITSTRIG, ENUM, CODED ENUM for analog network inputs accepted types are FLOAT32 and INTEGER
· In case of binary network input and types other than BOOLEAN as a value for processing bit selected in configuration will be taken from the received data in the message (by default it is bit 0)
· Value will not be accepted if data from the message is not containing configured bit (for example if bit 5 is configured and received data contains only 2 bits like stVal from DPC type)
Every network input can be associated via internal logic with one of 16 validity indications. If given network input is not received due to one of the reasons mentioned above this indication is activated. Validity flag for the network input will be activated also if next message with the value will not be received within the time indicated in time to live field contained in the previous message.
The value of numDatSetEntries from the header determines how many data entries from the message are processed. With numDatSetEntries = 0 no data entries are processed from the received message. If numDatSetEntries is lower than expected (source information for some network inputs is not processed or missing) those missing network inputs will be marked as invalid.
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During device startup there can be more than one state transition of the GOOSE publisher dataset, since different parts of the relay application will start after GOOSE publisher.
When checking GoID, the APPID must not be the same as the APPID of other GOOSE.
PIXIT for GOOSE performance
ID
Ed
Gf1
1,2
Gf2
1,2
Gf3
1,2
Gf4
1
Description
Performance class
GOOSE ping-pong processing method Application logic scan cycle (ms)
Maximum number of data attributes in GOOSE dataset (value and quality has to be counted as separate attributes)
Value / Clarification P2 Scan cycle based
Max. Min. 500
3 ms for SPS, 10 ms for DPS 0 ms for SPS, 0 ms for DPS
PIXIT for control model
ID
Ed
Ct1
1
Ct2
1,2
P5/EN M/33A
Ct3
-
Ct4
-
Ct5
1
Ct6
-
Ct7
-
Ct8
1
Description
Value / Clarification
What control models are supported
(compare PICS)
DOns: Y SBOns: Y DOes: Y
Is the control model fixed, configurable and/ or dynamic?
SBOes: Y
Configurable for CSWI class: All controllable objects Obj1 ... Obj6 under CSWI class are configured to use one and the same chosen control model. Objects Obj7 ... Obj8 under CSWI class have fixed control model status-only.
Fixed for GGIO: All controllable objects under GGIO class the control model is fixed: direct-with-normalsecurity.
Is TimeActivatedOperate Deprecated supported (compare PICS or SCL)
Is "operate-many" supported (compare sboClass)
Deprecated
Will the DUT activate the N control output when the test attribute is set in the SelectWithValue and/or Operate request (when N test procedure Ctl2 is applicable)
What are the conditions for the time (T) attribute in the SelectWithValue and/or Operate request
Deprecated
Is pulse configuration supported (compare pulseConfig)
Deprecated
What is the behavior of the DUT when the check conditions are set
N synchrocheck
N interlock-check
DUT ignores the check value and the command is executed as usual
313
ID
Ed
Ct9
1,2
Ct10
1,2
Ct11
1,2
Ct12
1,2
Ct13
1,2
Appendix 3: IEC 61850 Edition 2 conformance statement
Description
Value / Clarification
Is this behavior fixed, configurable, online changeable?
Fixed
Which additional cause diagnosis are supported
N Unknown Y Not-supported
Y Blocked-by-switching-hierarchy
N Select-failed
Y Invalid-position
Y Position-reached
N Step-limit
Y Blocked-by-Mode
N Blocked-by-process
N Blocked-by-interlocking
N Blocked-by-synchrocheck
Y Command-already-in-execution
N Blocked-by-health
N 1-of-n-control
N Abortion-by-cancel
Y Time-limit-over
N Abortion-by-trip
Y Object-not-selected
Y Object-already-selected
N No-access-authority
N Ended-with-overshoot
N Abortion-due-to-deviation
N Abortion-by-communication-loss
N Blocked-by-command
N None
Y Inconsistent-parameters
Y Locked-by-other-client
N Parameter-change-in-execution
How to force a "test-notok" respond with SelectWithValue request?
Put device into local mode
How to force a "test-notok" respond with Select request?
Put device into local mode
How to force a "test-notok" respond with Operate request?
DOns: Operate with orCat out of range SBOns: Operate without Select DOes: Operate with orCat out of range
SBOes: Operate without Select
Which origin categories Y bay-control
are supported/accepted? Y station-control
Y remote-control
Y automatic-bay
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ID
Ed
Ct14
1,2
Ct15
1,2
Ct16
1
Ct17
1
Ct18
1
Ct19
-
Ct20
1,2
Ct21
1,2
Ct22
2
Ct23
1,2
Ct24
1,2
Description
Value / Clarification
Y automatic-station
Y automatic-remote
Y maintenance
Y process
What happens if the orCat is not supported or invalid
DOns: Negative response
SBOns: Negative response
DOes: Negative response (with additional cause diagnosis code value Not-supported)
SBOes: Negative response (with additional cause diagnosis code value Not-supported)
Does the IED accept a SelectWithValue/ Operate with the same control value as the current status value?
Is this behavior configurable?
DOns: N SBOns: N DOes: N Addcause: Position-reached SBOes: N Addcause: Position-reached Configurable: N
Does the IED accept a select/operate on the same control object from 2 different clients at the same time?
Does the IED accept a Select/SelectWithValue from the same client when the control object is already selected (tissue 334)
DOns: Y (see Remarks) SBOns: N DOes: N SBOes: N SBOns: N SBOes: N
Is for SBOes the internal validation performed during the SelectWithValue and/or Operate step?
Y During SelectWithValue and during Operate
Can a control operation be blocked by Mod=Off or [On-]Blocked (compare PIXIT Sr5)
Deprecated
Does the IED support
Y
local / remote operation?
Does the IED send an InformationReport with LastApplError as part of the Operate responsefor control with normal security?
SBOns: N DOns: N
How to force a "parameter-change-inexecution"
SBOns: N/A SBOes: N/A
How many SBOns/ SBOes control objects can be selected at the same time?
SBOns: 1 SBOes: 1
Can a controllable object Y be forced to keep its old state e.g. Internal Controllable Objects may not be accessible to force this, whereas a switch like Circuit Breaker outside the DUT can?
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Appendix 3: IEC 61850 Edition 2 conformance statement
ID
Ed
Ct25
1,2
Ct26
1,2
Ct27
2
Ct_ex1
Description
Value / Clarification
When CDC=DPC is
Y
supported, is it possible
to have DPC
(Controllable Double
Point) go to the
intermediate state? (00)
Name a DOes point (if any) with a finite operate timeout and specify the timeout (in milliseconds)
Does the IED support control objects with external signals?
Relay/Obj1CSWI1.Pos
Operate timeout can be configured by setting Configuration Tool, the range is 0.02 ... 600 s. For example: DOes: 10000 ms SBOes: 10000 ms
DOns: Y
SBOns: Y
DOes: Y
SBO Timeout
SBOes: Y 60 seconds
NOTE: In DOns model: When two clients send Operate request within a very short interval (under 100 ms) then for processing the second command the object position is still unchanged due to the first command, thus both clients receive positive Operate response.
PIXIT for time synchronization
ID
Ed
Tm1
1
Tm2
1,2
Tm3
1,2
Tm4
1,2
Tm5
1
Tm6
-
Description
Value / Clarification
What time quality bits are Y LeapSecondsKnown
supported (may be set
by the IED)
Y ClockFailure
Ed.2 requires all 3 bits
Y ClockNotSynchronized
Describe the behaviour when the time server(s) ceases to respond
What is the time server lost detection time
How long does it take to take over the new time from time server
Time is taken from internal RTC The latency depends on measured drift of the internal clock. Usually it can take 400 seconds
Depends on time difference between internal and time server. Max. 400 s is the waiting time to see Timestamp Quality transition to ClockNotSynchronised.
When is the time quality bit "Clock failure" set?
The time quality bit "Clock failure" is set to "one" when the P5 IED restarts from power up, or when the connection to time server is lost; the bit is reset to "zero" when the clock becomes synchronized.
All available time synchronization sources will affect the "Clock failure" bit. These time sources include SNTP and where applicable, IRIG-B.
When is the time quality bit "Clock not synchronized" set?
Note: For Ed2 and up, CNS is set according to PIXIT Tm2
The time quality bit "Clock not synchronized" is set to "one" when the P5 IED starts from power up, or when the connection to time server is lost; the bit is reset to "zero" when the clock becomes synchronized.
All available time synchronization sources will affect the "Clock not synchronized" bit. These time sources include SNTP and where applicable, IRIG-B.
Is the timestamp of a binary event adjusted to the configured scan cycle?
Deprecated
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ID
Ed
Tm7
1
Tm8
1,2
Tm9
1,2
Description
Value / Clarification
Does the device support Y time zone and daylight saving?
Which attributes of the SNTP response packet are validated?
N Leap indicator not equal to 3
N Mode is equal to SERVER
Y OriginateTimestamp is equal to value sent by the SNTP client as Transmit Timestamp
Y RX/TX timestamp fields are checked for reasonableness
Y SNTP version 3 or 4
Do the COMTRADE files have local time or UTC time
N other Local N
Is this configurable
PIXIT for file transfer model
ID
Ed
Ft1
1
Ft2
1,2
Ft3
1
Ft4
1,2
Ft5
1,2
Ft6
1
Ft7
1
Ft8
1,2
Ft9
1,2
Description
Value / Clarification
What is structure of files and directories
Where are the COMTRADE files stored
Are comtrade files zipped and what files are included in each zip file
Directory structure - COMTRADE - DR - TREND
COMTRADE files stored in folder / COMTRADE /DR Zipped; Each COMTRADE record includes 2 files: .cfg and .dat
Directory names are separated Separated by `/' from the file name by
The maximum file name size including path (recommended 64 chars)
Are directory/file name case sensitive Maximum file size for SetFile
255
Below are all the maximum sizes: - Full file name (including the directory path, suffix and separation characters): 255 - File name: 64 - File directory name: 32 - File name suffix: 3
Case sensitive
SetFile is not supported.
Is the requested file path
Y
included in the MMS
fileDirectory respond file name
Is the wild char supported MMS Y fileDirectory request
Is it allowed that 2 clients get a file at the same time
Which files can be deleted
N None
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TICS details
Appendix 3: IEC 61850 Edition 2 conformance statement
Introduction
The TICS is based upon UCAIug TICS Template version 2.1, UCA International Users Group Testing Sub Committee, April 23, 2019.
This document is applicable for P5U20, P5V20, P5F30 and P5M30, with firmware version V01.
Mandatory Edition 2 Tissues
The below tables give an overview of the applicable mandatory Tissues. The original TISSUE should be consulted for details of changes. Implemented by server: Y: means that the server has implemented the respective tissue ni: no impact on testing na: not applicable if the server does not support the corresponding ACSI service(s) Supported by client: Y: means that the client supports servers that have implemented the respective tissue ni: no impact on testing na: not applicable if the client does not support the corresponding ACSI service(s)
Table 72 - Tissues implementation conformance statement
Part 6 Tissue 658 663
668 687 719 721 768 779 788 789 804 806
807 823 824 825 845 853 855
Description
Tracking related features FCDA element cannot be a "functionally constrained logical node" Autotransformer modeling SGCB ResvTms ConfDataSet - maxAttributes definition is confusing Log element name bType VisString65 is missing Object references SICS S56 from optional to mandatory ConfLdName as services applies to both server and client valKind and IED versus System configuration Max length of log name inconsistent between IEC 61850-6 and IEC 61850-7-2 Need a way to indicate if "Owner" present in RCB ValKind for structured data attributes Short addresses on structured data attributes Floating point value SGCB ResvTms SBO and ProtNs Recursive SubFunction
Implemented Y/na na Y
na na Y na na na na na na na
Y na na na na Y na
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Appendix 3: IEC 61850 Edition 2 conformance statement
Table 72 - Tissues implementation conformance statement (Continued)
Part 6 Tissue 856 857 886 901 936 1147 1185
1284
1328 1395 1402 1415 1419 1444 1445 1450 1485
Description
VoltageLevel frequency and phases Function/SubFunction for ConductingEquipment Missing IEC 61850-8-1 P-types tServices as AP or as IED element SupSubscription parameter usage is difficult tServices - FileHandling not consistent with IEC 61850-7-2 Valkind value Conf for EX FC data valKind=Conf is allowed for dataNs SCSM mapping may require a communication section in an ICD file Limitation on the size of data type templates identifiers Client LN attributes ExtRef during engineering SICS-S110 IID import mandatory for Edition2 Support of ldName on other IEDs SICS I212 is now mandatory Need to support fixed and SCT controlled datasets ConfReportControl and a fixed ReportSettings OriginalSclXxx computation rules Need to supercede Tissue 1398 to clarify SCT behavior
Implemented Y/na na na na Y na Y na
Y
Y na na na Y na na Y na
Part 7-1 Tissue 828 948 1151
1396 1447 1457 1468 1491 1495
Part 7-2 Tissue 728 778 780 783 786 820 858 861 1050 1071
Description
Data model namespace revision IEC 61850-7-4:2007[A] Enumeration (string) values format Simulated GOOSE disappears after 1st appearance when LPHD.Sim = TRUE The use and configuration flow of LGOS and LSVS is unclear Restriction on ENUMtypes in SCL Multiple DOI nodes with the same name Re-use DO from other LN CmdBlk blocks itself GetVariableAccessAttributes error code
Implemented Y/na Y na na
na na na Y na Y
Description
BRCB: could PurgeBuf be set when RptEna = TRUE AddCause values add value not-supported What are unsupported trigger options at a control block TimOper Resp- ; add Authorization check AddCause values 26 and 27 are switched Mandatory ACSI services (use for PICS template) Typo in enumeration ServiceType Dchg of ConfRev attribute GTS Phycomaddr definition in SCL Length of DO name
Implemented Y/na Y na Y na Y Y na na Y Y
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319
Part 7-2 Tissue 1127 1202 1232 1242 1307 1428 1630
Part 7-3 Tissue 697 698 711
722 919 925 926 954 1078 1565 1578
Part 7-4 Tissue 671 674 676 677
679 680 681 682 683 685 686 694 696 712 713 714 715 716 724 725
Appendix 3: IEC 61850 Edition 2 conformance statement
Description
Missing owner attribute in BTS and UTS GI not optional EntryID needs clarification NTS definition Segmented report with Buffer overflow MTS and NTS should use svOptFlds Attributes in CDC=LTS do not match 8-1 definition
Description
Persistent command / PulseConfig Wrong case is BAC.dB attribute blkEna freeze data update while setting its quality to operaterBlocked Units for 'h' and 'min' not in UnitKind enumeration. Presence Condition for sVC Presence of i or f attribute - Problem with writing Presence Conditions within RangeConfig Data attributes with FC=CF should have trgOp=dchg CMV.t update if rangeAng changed db = 0 behaviour DataAttribute NameSpace content
Description
Mistake in definition of Mod & Beh CDC of ZRRC.LocSta is wrong Same data object name used with different CDC MotStr is used with different CDC in PMMS and SOPM LN classes Remove CycTrMod Enum SI unit for MHYD.Cndct Enum PIDAlg ANCR.ParColMod Enum QVVR.IntrDetMth Enum ParTraMod New annex H - enums types in XML Data object CmdBlk LSVS.St (Status of subscription) Interpretation of quality operatorBlocked DO Naming of time constants in FFIL Enums for ShOpCap and SwOpCap RBDR.ChNum1 TAXD text for condition ANCR.Auto Loc in LN A-group
Implemented Y/na Y Y Y N Y N Y
Implemented Y/na na na na
Y na na na na na Y N
Implemented Y/na na na na na
na na na na na na na na na na na na na na na na
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Part 7-4 Tissue 734 736 742 743 744 772 773 774 776 800 802 808 831 838 844 877 908 909 912 920 932 933 939 991
1007 1044 1077 1256 1331
1426 1456 1568
Description LLN0.OpTmh vs. LPHD.OpTmh
Implemented Y/na
na
PFSign
na
GAPC.Str, GAPC.Op and GAPC.StrVal
Y
CCGR.PmpCtl and CCGR.FanCtl
na
LN STMP, EEHealth and EEName
na
LPHD.PwrUp/PwrDn should be transient
na
Loc, LocKey and LocSta YPSH and YLTC
na
ITCI.LocKey
na
LPHD.OutOv/InOv and LCCH.OutOv/InOv
na
Misspelling in CSYN
na
CCGR and Harmonized control authority
na
Presence condition of ZMOT.DExt and new Dos
na
Setting of ConfRevNum in LGOS
na
Presence condition of ZMOT.DExt and new Dos
na
MFLK.PhPiMax, MFLK.PhPiLoFil, MFLK.PhPiRoot DEL->WYE na
QVUB -settings should be optional
na
ARIS.StrSeq transient
na
Remove ANCR.ColOpR and ColOpL
na
Clarification of PwrRtg/VARtg
na
Resetable Counter is NOT resetable
na
Rename AVCO.SptVol to AVCO.VolSpt
na
Presence of LCCH.RedFerCh and RedRxCnt
na
Change CDC for ANCR.FixCol
na
LGOS: GoCBRef (as well as LSVS.SvCBRef) should be
na
mandatory
PTRC as fault indicator - Update of description required
Y
TapChg in AVCO
na
Rename DOnames within LTIM
na
New DO for LTIM to set time "manually"
na
Mod, Beh and Health with q=TEST, client can't receive their
na
states
Add two DO for leap seconds in LTIM
na
Annex A and Mod/Beh/Health
na
ISAF.AlmReset ->transient
na
NOTE: Tissues 675, 735, 772, 775, 776, 878 are not relevant for conformance testing.
Part 8-1 Tissue 770 784 817 827
834
Description
GoID type mitmatch 18.1.1 and 18.1.2.5.2 Tracking of control (CTS) Fixed-length GOOSE float encoding Mandatory ACSI services (Part of IEC 61850-7-2 TISSUE resolution) File dir name length 64
Implemented Y/na Y na Y Y
na
P5/EN M/33A
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Appendix 3: IEC 61850 Edition 2 conformance statement
Part 8-1 Tissue 951 1040 1178 1324 1345 1441 1442 1453 1454
1500
1626
Description
Encoding of Owner attribute More associate error codes Select Response+ is non-null value The response- for DeleteNamedVariableList is not defined Fixed-length GOOSE ASN.1 length encoding Optonal fields in buffered reports Journal variableTag for ReasonCode Purge buffer on write to BRCB Reports can be transmitted before write (RptEna=true) is confirmed The response for DeleteNamedVariableList with a non-existent LN is not specified PICs For Information Report is incorrect
Implemented Y/na Y Y Y Y na Y na Y na
Y
na
For detailed information on the individual Tissues, connect to the TISSUE database: www.tissues.iec61850.com
322
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