Operating Manual For 500A/102A/152A/202A Power Supply Pmn 83493001
User Manual: pmn
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Page Count: 60
- CHAPTER 1 INTRODUCTION
- CHAPTER 2 SPECIFICATIONS
- 2.1 AVERAGE CHARGING RATE
- 2.2 PEAK CHARGING RATE
- 2.3 NUMBER OF MODELS IN SERIES
- 2.4 STANDARD VOLTAGE RANGES
- 2.5 POLARITY
- 2.6 HIGH VOLTAGE ASSEMBLY
- 2.7 INPUT CONNECTOR
- 2.8 INPUT CHART
- 2.9 POWER FACTOR
- 2.10 EFFICIENCY
- 2.11 STORED ENERGY
- 2.12 STABILITY
- 2.13 PULSE TO PULSE REPEATABILITY
- 2.14 TEMPERATURE COEFFICIENT
- 2.15 AMBIENT TEMPERATURE
- 2.16 HUMIDITY
- 2.17 PROTECTION
- 2.18 AGENCY APPROVALS
- 2.19 TRANSIENT LINE PROTECTION
- 2.20 ESD
- 2.21 NOTE FOR PFC UNITS
- 2.22 ACCESSORIES
- 2.23 OPTIONS
- 2.24 ORIENTATION
- CHAPTER 3 INSTALLATION
- CHAPTER 4 OPERATION
- CHAPTER 5 APPLICATIONS
- CHAPTER 6 MAINTENANCE AND CALIBRATION
- EXXON Univolt N 61B MSDS - 86001018.pdf
Page: 83-000-006 Rev D
TDK-Lambda
MANUFACTURER'S PRODUCT DECLARATION
INTENDED PURPOSE (USE)
The Power Supplies described by this manual are defined by TDK-Lambda Americas Inc.
as a component for use in the composition of an apparatus as defined in Article 1 (1) of
the EMC Directive (89/336/EEC). These products, as individual components, do not
perform in themselves a direct function for the user of the end product. They are not
intended to be placed on the market with a direct function to a final user! As such, the
products described by this manual are not subject to the provisions of the EMC Directive
(89/336/EEC, with amendment 92/31/EEC).
The products described by this manual are intended for incorporation into a final product
by a professional assembler. It is the responsibility of the assembler to ensure that the
final apparatus or system incorporating our products complies with all relevant EMC
standards for that final product.
OPERATING ENVIRONMENT
The operating environment as defined by TDK-Lambda Americas Inc., for the products
described by this manual is stated as follows:
The Power Supplies described by this manual are intended for use in a protected
industrial environment or in proximity to industrial power installations. These locations are
often referred to as industrial locations containing establishments that are not connected
to the low voltage public mains network.
Industrial locations are characterized by the existence of one or more of the following
conditions:
1) industrial, scientific and medical (ISM) apparatus are present;
2) heavy inductive or capacitive loads are frequently switched;
3) currents and associated magnetic fields are high;
4) location supplied by their own transformer.
These components are not intended for connection to a public mains network, but are
intended to be connected to a power network supplied from a high or medium-voltage
transformer dedicated for the supply of an installation feeding manufacturing or similar
operations. They are suitable for use in all establishments other than domestic and those
directly connected to a low voltage power supply network which supplies buildings used
for domestic purposes.
Page: 83-000-007 Rev E
TDK-Lambda
Description of symbols used in product labeling
SYMBOL PUBLICATION DESCRIPTION
EC Council
Directive 93/68/EEC
European Community
Conformity Assessment
Product Mark
IEC 348 Attention, consult
Accompanying documents
IEC 60417-1-5036 Dangerous voltage
IEC 60417-1-5019 Protective earth
(e.g. power line earth ground)
IEC 60417-1-5017 Functional earth
(e.g. chassis ground)
IEC 60417-1-5134 Electrostatic Discharge
(ESD) Sensitive Device
Page: 83-000-011 Rev K
ELECTRICAL STANDARDS
All company primary standards are either certified or are traceable to certification by the
National Institute of Standards and Technology.
CLAIM FOR DAMAGE IN SHIPMENT
This instrument received comprehensive mechanical and electrical inspection before
shipment. Immediately upon receipt from the carrier, and before operation, this instrument
should be inspected visually for damage caused in shipment. If such inspection reveals
damage in any way, a claim should be filed with the carrier. A full report of damage should
be obtained by the claim agent and this report should be forwarded to us. We will then
provide a disposition of the equipment and arrange for repair or replacement.
When referring to this equipment, always include the model and serial numbers.
The “WARRANTY”, “CLAIM FOR DAMAGE IN SHIPMENT”, and “RETURNING
EQUIPMENT” information applies to equipment purchased directly from TDK-
Lambda Americas Inc. End users receiving equipment from a third party should
consult the appropriate service organization for assistance with these issues.
RETURNING EQUIPMENT
Before returning any equipment to the factory, the following steps shall be taken.
1.
Notify TDK-Lambda Americas Inc. at 732-918-6888 or follow the instructions at
www.US.TDK-Lambda.com/HP/service.htm. Give a full description of the difficulty
including the model and serial number of the unit in question. Upon receipt of this
information, we will assign a Return Material Authorization (RMA) number and
provide shipping instructions.
2.
The customer shall prepay shipping charges. Equipment returned to us must be
packed in a manner to reach us without damage. The shipping container must be
marked with the RMA number in an area approximate to the shipping label with
numbers that are easy to read. All returned units that do not show the RMA number
on the outside of the container will be refused.
If the equipment is repaired within the warranty agreement, than TDK-Lambda
Americas Inc. shall pay for the return shipping to the customer.
3.
For non-warranty repairs, we will submit a cost estimate for your approval prior to
proceeding. The customer shall pay return shipping charges.
MECHANICAL INSTALLATION
Most power supplies are heavy and, when rack mounted, they should be supported by
rails along the sides of the supply from front to rear. The rails must adequately support the
unit and not block airflow. Do not support the power supply from the front panel only.
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TABLE OF CONTENTS
CHAPTER 1 INTRODUCTION ........................................................................................................................ 1
1.1 DESCRIPTION ....................................................................................................................................... 1
CHAPTER 2 SPECIFICATIONS ..................................................................................................................... 2
2.1 AVERAGE CHARGING RATE ............................................................................................................... 2
2.2 PEAK CHARGING RATE ....................................................................................................................... 2
2.3 NUMBER OF MODELS IN SERIES ....................................................................................................... 2
2.4 STANDARD VOLTAGE RANGES .......................................................................................................... 2
2.4.1 LINEARITY ...................................................................................................................................... 2
2.4.2 ACCURACY .................................................................................................................................... 2
2.5 POLARITY .............................................................................................................................................. 2
2.6 HIGH VOLTAGE ASSEMBLY ................................................................................................................ 2
2.7 INPUT CONNECTOR ............................................................................................................................. 2
2.8 INPUT CHART ....................................................................................................................................... 2
2.9 POWER FACTOR .................................................................................................................................. 3
2.10 EFFICIENCY ........................................................................................................................................ 3
2.11 STORED ENERGY .............................................................................................................................. 3
2.12 STABILITY ........................................................................................................................................... 3
2.13 PULSE TO PULSE REPEATABILITY .................................................................................................. 3
2.14 TEMPERATURE COEFFICIENT ......................................................................................................... 3
2.15 AMBIENT TEMPERATURE ................................................................................................................. 3
2.16 HUMIDITY ............................................................................................................................................ 3
2.17 PROTECTION ...................................................................................................................................... 3
2.18 AGENCY APPROVALS ....................................................................................................................... 3
2.19 TRANSIENT LINE PROTECTION ........................................................................................................ 3
2.20 ESD ...................................................................................................................................................... 3
2.21 NOTE FOR PFC UNITS ....................................................................................................................... 3
2.22 ACCESSORIES ................................................................................................................................... 4
2.23 OPTIONS ............................................................................................................................................. 4
2.23.1 Suffix –LH ...................................................................................................................................... 4
2.23.2 SUFFIX –EN ................................................................................................................................. 4
2.23.3 Suffix -5V ....................................................................................................................................... 4
2.23.4 Suffix –LP ...................................................................................................................................... 4
2.23.5 SUFFIX -110 ................................................................................................................................. 4
2.24 ORIENTATION ..................................................................................................................................... 4
CHAPTER 3 INSTALLATION ......................................................................................................................... 9
3.1 INITIAL INSPECTION ............................................................................................................................ 9
3.2 MOUNTING AND COOLING REQUIREMENTS .................................................................................... 9
3.3 INPUT AC POWER ................................................................................................................................ 9
3.4 POWER CORD SPECIFICATION: ....................................................................................................... 10
3.5 CONNECTING HIGH VOLTAGE OUTPUT .......................................................................................... 11
3.6 GROUNDING THE PRODUCT ............................................................................................................ 12
3.6.1 GROUNDING OF INPUT LINE ..................................................................................................... 12
3.6.2 OUTPUT GROUND CONNECTION ............................................................................................. 12
3.6.3 FOR UNITS WITH O/P VOLTAGE ≤ 6kV ..................................................................................... 12
3.6.4 FOR UNITS WITH O/P VOLTAGE > 6kV: .................................................................................... 12
CHAPTER 4 OPERATION ............................................................................................................................ 13
4.1 REMOTE CONTROL ............................................................................................................................ 13
4.2 OUT-OF-BOX-INSPECTION ............................................................................................................... 15
4.2.1 VISUAL INSPECTION .................................................................................................................. 15
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4.2.2 ELECTRICAL INSPECTION ......................................................................................................... 15
4.3 CONTACTING TDK-LAMBDA AMERICAS CUSTOMER SERVICE ................................................... 16
CHAPTER 5 APPLICATIONS ....................................................................................................................... 17
5.1 DETERMINING CAPACITOR CHARGE TIME..................................................................................... 17
5.2 VOLTAGE REVERSAL ........................................................................................................................ 17
5.3 PARALLELING UNITS ......................................................................................................................... 18
5.4 MEASURING HIGH VOLTAGES ......................................................................................................... 19
5.5 DETERMINING AC LINE CURRENT ................................................................................................... 20
5.6 CONTINUOUS HV DC OPERATION (CONSTANT VOLTAGE) .......................................................... 20
5.7 LONG CHARGE TIME WITH POWER FACTOR CORRECTED (PFC) UNITS ................................... 21
CHAPTER 6 MAINTENANCE AND CALIBRATION .................................................................................... 22
6.1 SAFETY PRECAUTIONS..................................................................................................................... 22
6.2 MAINTENANCE ................................................................................................................................... 22
6.3 CALIBRATION ..................................................................................................................................... 22
LIST OF FIGURES
Figure 1-1 500A/102A/152A/202A Block Diagram ......................................................................... 1
Figure 2-1 Mechanical Dimensions for 500A, 102A, 152A Outputs up to 6KV ............................... 5
Figure 2-2 Mechanical Dimensions for 500A, 102A, 152A Outputs from 7KV to 40KV .................. 6
Figure 2-3 Mechanical Dimensions for 202A Outputs up to 6KV ................................................... 7
Figure 2-4 Mechanical Dimensions for 202A Outputs from 7KV to 40KV ...................................... 8
Figure 3-1 Input AC Power Connection NON-PFC Version ......................................................... 10
Figure 3-2 Input AC Power Connection, PFC Version ................................................................. 10
Figure 3-3 Output Ground Connection ........................................................................................ 12
Figure 4-1 Example of Interface Connection ............................................................................... 14
Figure 5-1 Output Voltage Waveform ......................................................................................... 17
Figure 5-2 Output Current Measurement .................................................................................... 17
Figure 5-3 HV Bias Measurements ............................................................................................. 20
TABLES
Table 2-1: High Voltage Cable ...................................................................................................... 2
Table 2-2: Input Voltage Chart ...................................................................................................... 2
Table 2-3 Power Factor ................................................................................................................ 3
Table 4-1 Control Interface Connection for Standard 500A/102A/152A/202A Series .................. 13
Table 5-1 Output Capacitance ................................................................................................... 18
83-493-001 Rev. P
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Control
&
Aux. Power
INPUT/POWER PFC / Fuses
Inrush Limit
High Freq.
Resonant
Inverter
Step-up
Transformer
HV Rect.
HV Filter
HV OUTPUT
CHAPTER 1 INTRODUCTION
1.1 DESCRIPTION
The Series 500A/102A/152A/202A are High Voltage Switching Power Supplies designed
specifically for charging capacitors in laser systems and other pulsed power applications.
The 500A provides 500 J/s. the 102A is 1000 J/s, 152A is 1,500 J/s, and the 202A
provides 2000 J/s of average power and can be paralleled indefinitely for higher total
system power. TDK-Lambda Americas Inc. also offers the 402 Series, 802 Series, and
303 Series rated at 4,000, 8,000 and 30,000 J/s respectively.
The 500A/102A/152A/202A power supplies incorporate a new high-frequency IGBT
parallel resonant inverter topology for efficient generation of the output power. A high-
performance control module precisely regulates the output voltage, automatically
compensating for line, load, temperature, and rep rate variations. Normal external fault
conditions such as line dropout open or short circuit load, HV arc and over-temperature
will not damage the unit. The latest development in the parallel resonant inverter
topology and control circuitry also drastically improves pulse-to-pulse repeatability by
reducing the ripple or “bucket effect” even at very high pulse repetition frequencies. The
output voltages of the 500A/102A/152A/202A supplies are fully adjustable over each
range.
Figure 1-1 500A/102A/152A/202A Block Diagram
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CHAPTER 2 SPECIFICATIONS
2.1 AVERAGE CHARGING RATE
500J/s, 1000J/s, 1500J/s, 2000J/s at rated Output Voltage
2.2 PEAK CHARGING RATE
550J/s, 1100J/s, 1650J/s, 2200J/s at rated Output Voltage
2.3 NUMBER OF MODELS IN SERIES
12 Standard (others at extra cost)
2.4 STANDARD VOLTAGE RANGES
1kV, 1.5kV, 2kV, 3kV, 4kV, 5kV, 5kV, 10kV, 15kV, 20kV, 30kV and 40kV. All models
continuously variable from 0 to 100% of rated output voltage.
2.4.1 LINEARITY
Linear to within 1% of full scale.
2.4.2 ACCURACY
1% of rated.
2.5 POLARITY
Available as fixed Positive or Negative
2.6 HIGH VOLTAGE ASSEMBLY
Insulating Medium/Cable
Voltage
Medium
Output Cable
1kV to 6kV
Air
Coax. RG59
10kV to 40kV
Oil
12 AWG, HV Silicon
Table 2-1: High Voltage Cable
2.7 INPUT CONNECTOR
VDE, UL approved.
2.8 INPUT CHART
Input Voltage selective by Terminal block position
Input Voltage (VAC)
Current (No PFC)
Current (PFC)
Nameplate
Range
Design
Range
500A
102A
152A
500A
102A
152A
202A
230
50/60Hz
180-253
50/60Hz
5A
10A
14.5A
3.5A
6.6A
10A
13.5
115
50/60Hz
90-140
50/60Hz
10A
20A
N/A
7A
N/A
N/A
N/A
*Note: Input current ratings given are maximum when output Repetition Rate is
=>10Hz Consult Factory if model used at less than 10Hz.
Table 2-2: Input Voltage Chart
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2.9 POWER FACTOR
Non PFC
PFC
All models
0.65
0.98
Table 2-3 Power Factor
2.10 EFFICIENCY
Better than 85%
2.11 STORED ENERGY
Less than 0.3 Joules all models
2.12 STABILITY
0.2% per hour after 1 hour warm up
2.13 PULSE TO PULSE REPEATABILITY
±0.2% to 300Hz. For higher repetition rates, consult factory
2.14 TEMPERATURE COEFFICIENT
100ppm per ºC
2.15 AMBIENT TEMPERATURE
Storage -40 to +85ºC. Operating -20 to +45ºC
2.16 HUMIDITY
90%, non-condensing
2.17 PROTECTION
The power supply is protected against Open Circuits, Short Circuits, Overloads and Arcs
2.18 AGENCY APPROVALS
The 500A, 102A, 152A power supplies are safety approved by UL to UL 60601-1:
1990+A1+A2: 1995. All of the standard supplies with output voltages between 1kV and
40kV with or without active PFC are certified UL to meet the safety requirements of
UL60601-1 with the following exceptions.
1. Conducted RFI to be assessed in the installed application.
2. IEC601-1 approved isolation transformer is required to meet leakage current.
2.19 TRANSIENT LINE PROTECTION
Meets requirements of IEC 801-4, 801-5
2.20 ESD
All Remote Control Functions meet requirements of IEC 801-2
2.21 NOTE FOR PFC UNITS
When High Voltage is enabled by using either the “HV Enable” Line or deactivation of
the “Inhibit” Line the power supply will reach normal operation mode (and therefore all
other published specifications) within 50ms.
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2.22 ACCESSORIES
• Detachable 8 foot (2.4 meter) HV Cable
• 15 pin “D” plug mating control connector
• Operating Manual
2.23 OPTIONS
2.23.1 Suffix –LH
“Low Inhibit” - A +10 to 15 volt (high) signal will allow power supply operation.
A 0 to +1.5 volt (low) signal will inhibit the supply.
2.23.2 SUFFIX –EN
“Low Enable” - A +10 to 15 volt (high) signal will disable power supply
operation. A 0 to +1.5 volt (low) signal will enable the supply.
2.23.3 Suffix -5V
0 to +5 volt voltage (0 to full-scale output) programming. For controlling the
unit VPROGRAM is 0-5V (remote pin 5). The value for VPEAK is 0-5.5V
(remote pin 7) and the value for VANALOG is 0-5.5V (remote pin 8).
2.23.4 Suffix –LP
Latching overload protection.
2.23.5 SUFFIX -110
100 to 120 VAC input option (availability limited).
2.24 ORIENTATION
Power supplies >6kV with a oil-filled H.V. section must be operated in an upright
position. i.e., with the mounting bracket parallel to the ground plane.
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Figure 2-1 Mechanical Dimensions for 500A, 102A, 152A Outputs up to 6kV
(for grounding instructions see SECTION 3.6)
83-493-001 Rev. P
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Figure 2-2 Mechanical Dimensions for 500A, 102A, 152A Outputs from 7kV to 40kV
(for grounding instructions see SECTION 3.6)
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Figure 2-3 Mechanical Dimensions for 202A Outputs up to 6kV
(for grounding instructions see SECTION 3.6)
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Figure 2-4 Mechanical Dimensions for 202A Outputs from 7kV to 40kV
(for grounding instruction see SECTION 3.6)
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CHAPTER 3 INSTALLATION
3.1 INITIAL INSPECTION
The shipping container contains the following items: power supply, HV output cable,
male 15-pin “D” remote control mating connector, mounting bracket and operator’s
manual. Examine the items immediately for damage. Locate the serial number label on
the end of the power supply and verify the model number, the input voltage rating and
the output voltage rating and polarity. In the event of any damage promptly notify the
transportation company and the TDK-Lambda Americas Inc. Customer Service
Department.
3.2 MOUNTING AND COOLING REQUIREMENTS
The power supply can be mounted by the chassis support brackets (see Figure 2-1, 2-2,
2-3 and 2-4 for details). The mounting brackets are attached to the supply using the four
PHMS 8-32NC X 0.250 screws included. Using longer screws may internal components
to ground, causing permanent damage to power supply. The power supply can also
operate on a bench or table top. Power supplies above 6kV with an oil-filled H.V. section
must be operated in an upright position i.e. mounting bracket parallel to ground plane. In
all cases adequate clearances must be provided for proper air flow and cable bends.
Keep the minimum HV cable bend radius greater than 4 inches (102mm) to minimize
stress on the insulation and at least 4 inches (102mm) of clearance at the inlet of the
power supply and 2 inches (51mm) at the sides.
When operating in an enclosed system, care must be taken to ensure the ambient inlet
air to the power supply does not exceed the maximum operating temperature of 45ºC.
3.3 INPUT AC POWER
Proper grounding from the input AC power is required to reduce the risk of electric
shock. The metal chassis of the power supply is grounded through the green earthing
wire at the input AC power terminal block. A protective ground connection by way of the
grounding conductor in the input terminal is essential for safe operation. Use extreme
caution when connecting input AC power and never apply the incorrect input power.
The PFC version and version without PFC should be connected as explained in the
following 2 paragraphs.
A. Version with no PFC.
For this version, the supply may be connected to either 115VAC for 230VAC input
voltage (See table 2.2 for availability). These connections are shown in Figure 3-1.
For 115VAC connect the input line wires to L1 and COM terminals.
For 230VAC connect the input wires to L2 and COM terminals.
B. Version with PFC.
The PFC version connection is shown in Figure 3-2. Connect the input voltage line wires
to L2 and COM terminals.
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Figure 3-1 Input AC Power Connection NON-PFC Version
Figure 3-2 Input AC Power Connection, PFC Version
The 500A, 102A, 152A power supplies are safety approved by UL to UL60601-1. An
IEC601-1 approved isolation transformer is required to meet leakage current.
3.4 POWER CORD SPECIFICATION:
Use wire with minimum .064 inches (1.6mm) diameter and 600 V insulation.
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3.5 CONNECTING HIGH VOLTAGE OUTPUT
POTENTIAL LETHAL VOLTAGE
Ensure that the power supply is off and disconnected from the input power and never
operate the power supply without a load capacitor. Make sure that all load capacitors are
discharged and shorted to ground before making any connections. TDK-Lambda
Americas Inc. recommends the use of safety dump switches in high voltage discharge
circuits.
Never handle the HV cable during operation.
This power supply is designed to operate with a capacitive load. Operation of the
power supply without an external load capacitor may result in damage to internal
circuitry.
Always use the HV connector and cable provided with the power supply or an equivalent
substitute provided by TDK-Lambda Americas Inc. Fully insert the connector end of the
HV cable and tighten the locking nut only “hand tight”.
NOTE: When operating above 20kV and/or 200 Hz rep. rate, ensure that silicone
grease (such as Dow Corning DC-4) is applied to the HV cable before insertion into the
HV connector. This displaces the air in the connector and reduces long term corona
damage.
Keep the HV cable bend radius greater than 4 inches (102mm) to minimize stress on the
insulation. Keep the HV cable as distant as possible from the input power and the input
control signals.
Some peak current will flow out of the power supply during discharge and return through
the HV return and system chassis. This current comes from voltage reversal in under
damped systems and from normal discharge of filter and cable capacitance. The path for
this current should not parallel control signal returns since the resulting voltages could
interfere with normal system operation. The currents developed with voltage reversal at
high rep. rates, could damage the power supply. A resistor in series with the HV output
can be added to limit this current to an acceptable level. Refer to Section 5.2, Page 16 or
the TDK-Lambda High Power online application notes for more information.
The oil-filled HV assembly should not be opened. The oil and components have been
specially cleaned and vacuum impregnated at the factory and the assembly hermetically
sealed. Opening the assembly will compromise performance and void the warranty.
Tanks must only be serviced at TDK-Lambda Americas Inc.
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3.6 GROUNDING THE PRODUCT
3.6.1 GROUNDING OF INPUT LINE
The supply is grounded through the ground terminal of the input connector. A protective
ground connection by the way of the grounding conductor in the input terminal is
essential for safe operation.
3.6.2 OUTPUT GROUND CONNECTION
It is important that there be a ground connecting the supply to the load as shown in
Figure 3-3.
Figure 3-3 Output Ground Connection
3.6.3 FOR UNITS WITH O/P VOLTAGE ≤ 6kV
The ground connection is made via the shield of the RG59 coaxial HV output cable
provided with the supply.
3.6.4 FOR UNITS WITH O/P VOLTAGE > 6kV:
The ground connection between the load and the supply must be made with a separate
wire to the 8-32 UNC, ½ “long grounding stud provided on the supply.
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CHAPTER 4 OPERATION
4.1 REMOTE CONTROL
The Series 500A/102A/152A/202A is easily controlled through the remote connector on
the input panel of the unit. Only the ENABLE/RESET, V PROGRAM and GND signals
are required for operation. The remaining signals are provided for status monitoring and
fault diagnosis. A schematic diagram showing the suggested interface circuit is shown in
Figure 4-1. This table is for a standard configuration.
PIN SIGNAL NAME I/O DESCRIPTION
1 ENABLE/RESET INPUT
A high signal (+10 to 15V) with respect to
ground (pin 14) will enable the power supply.
Latching faults can be cleared by cycling this
switch. Ground or open disables the supply.
5 VPROGRAM INPUT A 0-10V signal with respect to ground at this pin
programs the output voltage proportionally from
zero to rated output. For a “-5V” option the unit
VPROGRAM is 0-5V.
7 VPEAK OUTPUT A 0-
10V signal with respect to ground
proportional to the peak of the output charging
voltage. Can be used to drive a meter displaying
peak output voltage. For a “-5V” option the value
for VPEAK is 0-5.5V.
8 VANALOG OUTPUT 0-
10V analog of output charging voltage
waveform. For a “-5V” option
the value for
VANALOG is 0-5.5V (remote pin 8).
10 INHIBIT INPUT A +10 TO 15V with respect to ground, disables
the unit. Open or ground allows operation. This
input can be used to disable charging during HV
switch recovery.
9, 11 +15V OUTPUT
15V regulated. Can be used or user
programming applications 20mA max.
14 GND OUTPUT Control circuit return. Also chassis/earth ground
15 INHIBIT LED OUTPUT INHIBIT LED displays the logical OR of all the
internal and external signals that prevent HV
output current, including EOC, EXTERNAL
INHIBIT, OVERLOAD, and any fault.
13 EOC LED OUTPUT Open collector. Indicates that the power supply
is reaching end-of-charge, i.e. the V PROGRAM
set point.
3, 6 SUMMARY
FAULT LED OUTPUT Open collector. Indicates an output overvoltage.
Temperature fault or low input voltage condition.
2 LOAD FAULT OUTPUT
Indicates a shorted O/P or a very large load
capacitor.
Table 4-1 Control Interface Connection for Standard 500A/102A/152A/202A Series
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Figure 4-1 Example of Interface Connection
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4.2 OUT-OF-BOX-INSPECTION
LETHAL VOLTAGES PRESENT
4.2.1 VISUAL INSPECTION
Prior to shipment, this instrument was inspected and found to be free of mechanical and
electrical defects. As soon as the unit is unpacked, inspect for any damage that may
have occurred in transit. Verify the following:
A. Confirm that there are no dents or scratches on the panel surfaces.
If any damage is found, follow the instructions in the "Returning Equipment"
instructions section of this manual.
4.2.2 ELECTRICAL INSPECTION
Before the power supply is installed in a system, verify that no internal damage occurred
during shipping. A simple preliminary electrical test should be performed. This test is
described below.
4.2.2.1 TEST 1
Purpose: Verify general overload operation.
1. With AC power "OFF" and disconnected, short the H.V. output by connecting the
center conductor of the output cable to its return shield (or ground). This dead short
forces the unit to generate full output current at zero voltage.
2. Set the output voltage control to zero. Connect the AC power to the unit. Turn the AC
power "ON".
3. Turn the he H.V. on and turn up the H.V. control until the power supply is generating
output current into the dead short. The power supply will intermittently turn on and off
indicating the "overload" condition. The unit should continue to cycle in this mode with a
1 sec. repetition rate indefinitely (500mS on and 500mS off). The power supply will go
into overload when max. current is drawn for more than half a second.
4. Turn off the H.V. and A.C. power.
This test indicates the inverter section is generating maximum current and the logic and
overload circuitry works correctly.
4.2.2.2 TEST 2
Purpose: Verify that the power supply generates maximum rated voltage, and the
regulation and feedback circuits are functioning.
1. With AC power OFF and disconnected, connect an appropriate load capacitor to the
power supply output cable.
2. Prepare to charge the capacitor. NOTE: Operating a 502A/102A/152A/202A power
supply into an open circuit (no load operation) will instantly damage the power supply's
H.V. output diodes. Make sure the load (capacitor) is connected and the H.V. output
cable is securely inserted and connected.
3. Turn the voltage control all the way down to zero, apply AC power and turn the HV
ON. By turning up the H.V. control knob the capacitor will charge to the programmed
voltage The power supply may be turned all the way up to its maximum output voltage
provided the load capacitor is sufficiently rated.
83-493-001 Rev. P
16
4. By turning the voltage control down or turning the H.V. OFF, the capacitor will "bleed"
down through the internal voltage divider resistors used for regulation feedback.
NOTE: An overload condition can occur if the INHIBIT signal is missing, allowing HV
switch to latch-up. It can also occur if the discharge rep. rate is too high to allow the
capacitor to fully charge to V PROGRAM.
Test #2 indicates the H.V. section is working correctly. Tests 1 and 2 generally indicate
the unit is functioning as designed. Although 100% power had not been generated,
these two tests give greater than 90% confidence that the unit is not damaged.
If any inconsistency from the above test procedure is noted, do not hesitate to call
Lambda Americas Customer Service for assistance. If equipped with an oil-filled tank
this assembly should not be opened unless. This oil filled tank has been hermetically
sealed at the factory. Opening the supply or the assembly will void the factory warranty,
and may compromise performance.
4.3 CONTACTING TDK-LAMBDA AMERICAS CUSTOMER SERVICE
When contacting customer service locate the product description, part number and serial
number from the label located on the rear of the unit, and have this information available.
Phone: (732) 922-9300 x 342 E-mail: hp.service@us.tdk-lambda.com
Fax: (732) 922-5403
Customer Service, or an approved Service Center, should be contacted if:
• The power supply is mechanically or electrically damaged.
• The power supply requires on-site calibration, or replacement warning decals.
• The customer has questions about a special application that is not described in this
manual.
Normally, the customer may NOT open any chassis covers that have a warranty seal.
Breaking a seal will void the warranty.
At the discretion of TDK-Lambda Americas, the customer may be granted permission to
break the warranty seal and open the chassis covers. Customer Service shall confirm
the permission by sending a replacement seal. Once the unit has been serviced, the
customer shall close the cover and apply the replacement seal adjacent to (not on top
of) the broken seal.
83-493-001 Rev. P
17
Peak Charge Rate = C - OUTPUT LOAD CAPACITOR
1
2
CV
2
T
C
V - PROGRAMMED OUTPUT VOLTAGE
Average Charge Rate = TC AND TP ARE SHOWN IN FIGURE
1
2
CV
2
T
p
VOLTAGE
TIME
Tc Tp
CHAPTER 5 APPLICATIONS
For clarification and further technical assistance specific to your applications, please
contact TDK-Lambda Americas Inc.
5.1 DETERMINING CAPACITOR CHARGE TIME
The ratings of these supplies are as follows: 500A – 500 J/s, 102A – 1000 J/s, 152A –
1500J/s, 202A-2000J/s average charge rate. Although the measure of Joules/sec
equates to Watts, Stored Energy per unit time is more convenient when working with
energy storage capacitors. The peak charge rate determines the capacitor charge time.
The average charge rate determines the total power delivered from the power supply. It
is possible to charge a capacitor at 1650 J/sec, but to discharge it at a low rep. rate
producing an average of 100 J/sec. The following formulas can be used to determine the
average and peak charge rate.
Figure 5-1 Output Voltage Waveform
5.2 VOLTAGE REVERSAL
When the capacitor or PFN is discharged, a high peak current may flow out of the power
supply as a result of voltage reversal. This occurs in a system which is under damped in
order to clear the high voltage switch after each pulse. The average value of this peak
current added to the normal output current may exceed the rating of the HV diodes in the
power supply. This current can be measured with a current transformer as shown in
Figure 5.2.
Figure 5-2 Output Current Measurement
TC and TP are shown in figure
Average Charge Rate =
83-493-001 Rev. P
18
A series terminating resistor (or series inductor or clamp diode) must be added as shown
if the average value of the peak current exceeds 110% of the normal output current.
When choosing Rs, ensure it can withstand the full output voltage across it as well as
the power dissipation caused by discharging Co (see Table 5.1) and Cc (20pF/ft) (65.62
pf/m) each cycle as well as conducting the normal output current. It’s power dissipation
can be calculated as Pd = (Io² Rs) + ½ (Co + Cc) V² (REP RATE).
Output Voltage Co
1-2.8kV 60nF
3kV-6kV 15nF
10-30kV 460pF
40kV 230pF
Table 5-1 Output Capacitance
5.3 PARALLELING UNITS
The 500A/102A/152A/202A power supplies are designed for simple parallel operation.
The input power and HV output should be connected directly together. The REMOTE
connectors on the input panel can also be connected directly together using a “daisy
chain” ribbon cable from the system controller. Each of the power supplies operate at the
same time with the total charge rate equal to the sum of each.
Sometimes when operating several units in parallel, the high total power generates noise
which interferes with the power supply control. This is usually due to the many
interconnecting control cables acting as an antenna picking up noise. The problem
usually appears as one or more of the power supplies shuts down when the output
voltage increases beyond a certain level. Dressing the control cables as short as
possible and close to ground or using shielded cables should help. In severe cases, it is
necessary to wrap the cables several times through high permeability ferrite cores at the
input panel of each unit.
The 500A/102A/152A/202A power supplies can also be used as an Isolated High
Voltage continuous DC power source by adding an external filter capacitor. The value of
the filter capacitor depends upon the value of the allowable output voltage ripple value.
For parallel operation into DC loads, please contact TDK-Lambda Americas Inc.
Customer Service Department. (See Section 5.6).
83-493-001 Rev. P
19
5.4 MEASURING HIGH VOLTAGES
A sample of the output voltage is available at the REMOTE connector. If it is desired to
measure the HV output externally, care must be taken to understand the accuracy of the
measurement.
When making a DC measurement, such as when the power supply is holding voltage on
a capacitor, any HV probe and DVM combination can be used. The Fluke 80K-40 probe
with any 10M input resistance DVM is adequate up to 40kV. Building a simple resistor
divider using appropriate HV resistors is also very straightforward. Keep in mind that all
HV resistors, including the one in the Fluke probe, exhibit a negative voltage coefficient,
changing by up to 4% from zero to max. voltage. De-rating the resistors and calibrating
at the operating point solves this problem.
The value of the resistor R1 and R2 (Figure 5.3) can be calculated as follows:
Vo
RR
R
V
Mx
21
2
+
=
where Vo is the High Voltage being measured.
Making a pulsed measurement with an oscilloscope requires a compensated HV probe
having a wide bandwidth. Simply connecting a DC probe, through the proper resistance,
into a scope yields a slow response only adequate for low rep. rate systems. As with DC
probes, the pulsed probe resistor voltage coefficient is a problem. In addition, damage to
the resistors can occur during pulsing due to high electric field gradients. Also, stray
capacitance to nearby objects can significantly alter the pulse response. For a high-
performance, shielded probe to 40KV use a Tektronix P6015 or Ross Engineering
VD60-8.3-A-K-LB.
Measurements accurate to better than 0.1% can be achieved using a bias technique.
For example, if a 40V signal (40kV divided by 1000) is to be measured accurately, the
minus input of the DVM would be biased up 40V. The original signal, with respect to
ground, is fed to the plus input of the DVM. The bias can be measured accurately for
absolute measurements, or relative measurements read directly as the line or load is
varied. In the same manner, an oscilloscope return can be biased for accurate peak
measurements during pulsing.
WARNING: EXTREME CAUTION MUST ALWAYS BE EXERCISED WHEN
TAKING ANY HIGH VOLTAGE MEASUREMENTS. IT SHOULD BE DONE ONLY
BY QUALIFIED PERSONNEL WHO ARE TRAINED IN THE SAFETY ASPECTS
OF WORKING WITH HIGH VOLTAGE.
83-493-001 Rev. P
20
Figure 5-3 HV Bias Measurements
5.5 DETERMINING AC LINE CURRENT
IL = Line current
P = Average output power
VL = Line voltage
PF = Power factor (.65 min)
EFF = 0.85
Ex: A 152A operating from 115V – 10% and delivering 1000W average.
AxIL5.179.0
)85.0)(65)(.115(
1000 ==
When charging very large capacitor banks requiring many seconds or minutes to reach
end-of-charge, the power supply will display a load fault and go into a 50% duty cycle
protection mode. If this feature is defeated and the power supply is allowed to charge for
an extended period, the peak output power, not the average power, must be used to
determine line current. (See Section 5.7).
5.6 CONTINUOUS HV DC OPERATION (CONSTANT VOLTAGE)
The 500A/102A/152A/202A supplies can be used as a constant voltage supply by the
addition of an external filter capacitor. The value of this capacitor will determine the
ripple voltage on the DC output.
))()(
max)(4.1
FsCoVo
Po
VPKPK =−∆
Where: Po max = Maximum output power in watts
Vo = Output voltage in volts
Co = Total output capacitance in microfarads
Fs = Lowest switching frequency (40KHz)
When operating as a DC supply care must be taken not to draw more than the J/sec
rating of the unit.
Also, if the filter capacitor is inadvertently shorted, it may ring which can damage the
supply (Section 5.2).
EFFPV
P
I
FL
L
X
=
83-493-001 Rev. P
21
5.7 LONG CHARGE TIME WITH POWER FACTOR CORRECTED (PFC) UNITS
It is advised that you consult the factory if this type of operation is required.
A special long charge programming adaptor is available for applications with charge
times greater than 500 milliseconds. Visit the TDK-Lambda High Power website or
contact customer service for details.
83-493-001 Rev. P
22
CHAPTER 6 MAINTENANCE AND CALIBRATION
6.1 SAFETY PRECAUTIONS
ONLY QUALIFIED PERSONNEL TRAINED IN THE SAFETY ASPECTS OF HIGH
VOLTAGE SHOULD PERFORM CALIBRATION.
The calibration steps described in this section require operation of the power supply with
the cover removed. Proceed with extreme caution as hazardous voltages are exposed
throughout the unit.
Safety glasses must be worn to prevent serious injury in the event of a component
failure (e.g., power transistors readily explode during fault conditions).
Because the power supply does not receive proper cooling with the cover removed, it
must be cooled by an external fan placed next to the supply to cool the inverter and HV
section (min. air flow 100 CFM (2.83 M3/min.)) when operating at full power. Operation
at full power with cover removed should be limited to less than five minutes.
6.2 MAINTENANCE
No maintenance is required under normal operating conditions. Occasional vacuum or
blow-out of the chassis may be required when operated in extremely dirty environments.
The oil-filled HV assembly must not be opened. The oil and components have been
specially cleaned and vacuum impregnated at the factory and the assembly hermetically
sealed. Opening assembly will compromise performance and void warranty. HV Tanks
must only be services at TDK-Lambda Americas Inc.
6.3 CALIBRATION
Calibration of the output voltage is accomplished with trim pot RP4 located on the control
board. This is the top PC board of the inverter assembly. RP4 is a 25 turn trim pot.
Slowly turn it clockwise to decrease the output voltage for a given VPROGRAM. Factory
set for 10V rated voltage for standard version. Refer to Sections 4.1 and 4.2 of product
specification for Linearity and Accuracy.
Product Name: UNIVOLT N 61 B
Revision Date: 16 Mar 2015
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SAFETY DATA SHEET
SECTION 1
PRODUCT AND COMPANY IDENTIFICATION
PRODUCT
Product Name: UNIVOLT N 61 B
Product Description: Base Oil and Additives
Product Code: 201580102520, 730846-00, 97P847
Intended Use: Electrical insulating oils
COMPANY IDENTIFICATION
Supplier: EXXON MOBIL CORPORATION
22777 Springwoods Village Parkway
Spring, TX. 77389 USA
24 Hour Health Emergency
609-737-4411
Transportation Emergency Phone
800-424-9300 or 703-527-3887 CHEMTREC
Product Technical Information
800-662-4525
MSDS Internet Address
http://www.exxon.com, http://www.mobil.com
SECTION 2
HAZARDS IDENTIFICATION
This material is hazardous according to regulatory guidelines (see (M)SDS Section 15).
CLASSIFICATION:
Aspiration toxicant: Category 1.
LABEL:
Pictogram:
Signal Word: Danger
Hazard Statements:
H304: May be fatal if swallowed and enters airways.
Precautionary Statements:
P273: Avoid release to the environment.P301 + P310: IF SWALLOWED: Immediately call a POISON CENTER or
doctor/physician. P331: Do NOT induce vomiting. P391: Collect spillage.P405: Store locked up.P501: Dispose
of contents and container in accordance with local regulations.
Other hazard information:
Product Name: UNIVOLT N 61 B
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______________________________________________________________________________________________________________________
HAZARD NOT OTHERWISE CLASSIFIED (HNOC): None as defined under 29 CFR 1910.1200.
PHYSICAL / CHEMICAL HAZARDS
No significant hazards.
HEALTH HAZARDS
Frequent or prolonged contact may defat and dry the skin, leading to discomfort and dermatitis. May be
irritating to the eyes, nose, throat, and lungs.
ENVIRONMENTAL HAZARDS
Expected to be toxic to aquatic organisms. May cause long-term adverse effects in the aquatic environment.
NFPA Hazard ID:
Health: 1
Flammability: 1
Reactivity: 0
HMIS Hazard ID:
Health: 1*
Flammability: 1
Reactivity: 0
NOTE: This material should not be used for any other purpose than the intended use in Section 1 without expert
advice. Health studies have shown that chemical exposure may cause potential human health risks which may vary
from person to person.
SECTION 3
COMPOSITION / INFORMATION ON INGREDIENTS
This material is defined as a mixture.
Hazardous Substance(s) or Complex Substance(s) required for disclosure
Name
CAS#
Concentration*
GHS Hazard Codes
2,6-DI-TERT-BUTYL-P-CRESOL
128-37-0
1 - < 5%
H400(M factor 1),
H410(M factor 1)
HYDROTREATED LIGHT NAPHTHENIC DISTILLATE
(PETROLEUM)
64742-53-6
90 - < 100%
H304
* All concentrations are percent by weight unless material is a gas. Gas concentrations are in percent by volume.
As per paragraph (i) of 29 CFR 1910.1200, formulation is considered a trade secret and specific chemical identity and
exact percentage (concentration) of composition may have been withheld. Specific chemical identity and exact
percentage composition will be provided to health professionals, employees, or designated representatives in
accordance with applicable provisions of paragraph (i).
SECTION 4
FIRST AID MEASURES
INHALATION
Remove from further exposure. For those providing assistance, avoid exposure to yourself or others. Use
adequate respiratory protection. If respiratory irritation, dizziness, nausea, or unconsciousness occurs, seek
immediate medical assistance. If breathing has stopped, assist ventilation with a mechanical device or use
mouth-to-mouth resuscitation.
SKIN CONTACT
Wash contact areas with soap and water. Remove contaminated clothing. Launder contaminated clothing
before reuse.
Product Name: UNIVOLT N 61 B
Revision Date: 16 Mar 2015
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EYE CONTACT
Flush thoroughly with water. If irritation occurs, get medical assistance.
INGESTION
Seek immediate medical attention. Do not induce vomiting.
NOTE TO PHYSICIAN
If ingested, material may be aspirated into the lungs and cause chemical pneumonitis. Treat appropriately.
SECTION 5
FIRE FIGHTING MEASURES
EXTINGUISHING MEDIA
Appropriate Extinguishing Media: Use water fog, foam, dry chemical or carbon dioxide (CO2) to extinguish
flames.
Inappropriate Extinguishing Media: Straight Streams of Water
FIRE FIGHTING
Fire Fighting Instructions: Evacuate area. Prevent runoff from fire control or dilution from entering streams,
sewers, or drinking water supply. Firefighters should use standard protective equipment and in enclosed
spaces, self-contained breathing apparatus (SCBA). Use water spray to cool fire exposed surfaces and to
protect personnel.
Hazardous Combustion Products: Aldehydes, Oxides of carbon, Sulfur oxides, Smoke, Fume, Incomplete
combustion products
FLAMMABILITY PROPERTIES
Flash Point [Method]: >145°C (293°F) [ASTM D-92]
Flammable Limits (Approximate volume % in air): LEL: N/D UEL: N/D
Autoignition Temperature: >315°C (599°F)
SECTION 6
ACCIDENTAL RELEASE MEASURES
NOTIFICATION PROCEDURES
In the event of a spill or accidental release, notify relevant authorities in accordance with all applicable
regulations. US regulations require reporting releases of this material to the environment which exceed the
applicable reportable quantity or oil spills which could reach any waterway including intermittent dry creeks. The
National Response Center can be reached at (800)424-8802.
PROTECTIVE MEASURES
Avoid contact with spilled material. Warn or evacuate occupants in surrounding and downwind areas if
required due to toxicity or flammability of the material. See Section 5 for fire fighting information. See the
Hazard Identification Section for Significant Hazards. See Section 4 for First Aid Advice. See Section 8 for
advice on the minimum requirements for personal protective equipment. Additional protective measures may be
necessary, depending on the specific circumstances and/or the expert judgment of the emergency responders.
For emergency responders: Respiratory protection: respiratory protection will be necessary only in special
cases, e.g., formation of mists. Half-face or full-face respirator with filter(s) for dust/organic vapor or Self
Contained Breathing Apparatus (SCBA) can be used depending on the size of spill and potential level of
Product Name: UNIVOLT N 61 B
Revision Date: 16 Mar 2015
Page 4 of 11
______________________________________________________________________________________________________________________
exposure. If the exposure cannot be completely characterized or an oxygen deficient atmosphere is possible
or anticipated, SCBA is recommended. Work gloves that are resistant to hydrocarbons are recommended.
Gloves made of polyvinyl acetate (PVA) are not water-resistant and are not suitable for emergency use.
Chemical goggles are recommended if splashes or contact with eyes is possible. Small spills: normal antistatic
work clothes are usually adequate. Large spills: full body suit of chemical resistant, antistatic material is
recommended.
SPILL MANAGEMENT
Land Spill: Stop leak if you can do it without risk. Recover by pumping or with suitable absorbent.
Water Spill: Stop leak if you can do it without risk. Confine the spill immediately with booms. Warn other
shipping. Remove from the surface by skimming or with suitable absorbents. Seek the advice of a specialist
before using dispersants.
Water spill and land spill recommendations are based on the most likely spill scenario for this material;
however, geographic conditions, wind, temperature, (and in the case of a water spill) wave and current direction
and speed may greatly influence the appropriate action to be taken. For this reason, local experts should be
consulted. Note: Local regulations may prescribe or limit action to be taken.
ENVIRONMENTAL PRECAUTIONS
Large Spills: Dike far ahead of liquid spill for later recovery and disposal. Prevent entry into waterways,
sewers, basements or confined areas.
SECTION 7
HANDLING AND STORAGE
HANDLING
Avoid contact with skin. Prevent small spills and leakage to avoid slip hazard. Material can accumulate static
charges which may cause an electrical spark (ignition source). When the material is handled in bulk, an
electrical spark could ignite any flammable vapors from liquids or residues that may be present (e.g., during
switch-loading operations). Use proper bonding and/or ground procedures. However, bonding and grounds
may not eliminate the hazard from static accumulation. Consult local applicable standards for guidance.
Additional references include American Petroleum Institute 2003 (Protection Against Ignitions Arising out of
Static, Lightning and Stray Currents) or National Fire Protection Agency 77 (Recommended Practice on Static
Electricity) or CENELEC CLC/TR 50404 (Electrostatics - Code of practice for the avoidance of hazards due to
static electricity).
Static Accumulator: This material is a static accumulator.
STORAGE
The container choice, for example storage vessel, may effect static accumulation and dissipation. Do not store
in open or unlabelled containers.
SECTION 8
EXPOSURE CONTROLS / PERSONAL PROTECTION
EXPOSURE LIMIT VALUES
Exposure limits/standards (Note: Exposure limits are not additive)
Substance Name
Form
Limit / Standard
NOTE
Source
2,6-DI-TERT-BUTYL-P-CRESOL
Inhalable
fraction and
TWA
2 mg/m3
N/A
ACGIH
Product Name: UNIVOLT N 61 B
Revision Date: 16 Mar 2015
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vapor
HYDROTREATED LIGHT
NAPHTHENIC DISTILLATE
(PETROLEUM)
Mist.
TWA
5 mg/m3
N/A
OSHA Z1
HYDROTREATED LIGHT
NAPHTHENIC DISTILLATE
(PETROLEUM)
Inhalable
fraction.
TWA
5 mg/m3
N/A
ACGIH
HYDROTREATED LIGHT
NAPHTHENIC DISTILLATE
(PETROLEUM)
Mist.
TWA
5 mg/m3
N/A
ACGIH
Exposure limits/standards for materials that can be formed when handling this product: When mists/aerosols
can occur the following are recommended: 5 mg/m³ - ACGIH TLV (inhalable fraction), 5 mg/m³ - OSHA PEL.
NOTE: Limits/standards shown for guidance only. Follow applicable regulations.
No biological limits allocated.
ENGINEERING CONTROLS
The level of protection and types of controls necessary will vary depending upon potential exposure conditions.
Control measures to consider:
No special requirements under ordinary conditions of use and with adequate ventilation.
PERSONAL PROTECTION
Personal protective equipment selections vary based on potential exposure conditions such as applications,
handling practices, concentration and ventilation. Information on the selection of protective equipment for use
with this material, as provided below, is based upon intended, normal usage.
Respiratory Protection: If engineering controls do not maintain airborne contaminant concentrations at a
level which is adequate to protect worker health, an approved respirator may be appropriate. Respirator
selection, use, and maintenance must be in accordance with regulatory requirements, if applicable. Types of
respirators to be considered for this material include:
No special requirements under ordinary conditions of use and with adequate ventilation.
For high airborne concentrations, use an approved supplied-air respirator, operated in positive pressure mode.
Supplied air respirators with an escape bottle may be appropriate when oxygen levels are inadequate,
gas/vapor warning properties are poor, or if air purifying filter capacity/rating may be exceeded.
Hand Protection: Any specific glove information provided is based on published literature and glove
manufacturer data. Glove suitability and breakthrough time will differ depending on the specific use conditions.
Contact the glove manufacturer for specific advice on glove selection and breakthrough times for your use
conditions. Inspect and replace worn or damaged gloves. The types of gloves to be considered for this material
include: If prolonged or repeated contact is likely, chemical resistant gloves are recommended. If contact with
forearms is likely, wear gauntlet style gloves.
Eye Protection: If contact is likely, safety glasses with side shields are recommended.
Skin and Body Protection: Any specific clothing information provided is based on published literature or
manufacturer data. The types of clothing to be considered for this material include:
Product Name: UNIVOLT N 61 B
Revision Date: 16 Mar 2015
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If prolonged or repeated contact is likely, chemical, and oil resistant clothing is recommended.
Specific Hygiene Measures: Always observe good personal hygiene measures, such as washing after
handling the material and before eating, drinking, and/or smoking. Routinely wash work clothing and protective
equipment to remove contaminants. Discard contaminated clothing and footwear that cannot be cleaned.
Practice good housekeeping.
ENVIRONMENTAL CONTROLS
Comply with applicable environmental regulations limiting discharge to air, water and
soil. Protect the environment by applying appropriate control measures to prevent or limit
emissions.
SECTION 9
PHYSICAL AND CHEMICAL PROPERTIES
Note: Physical and chemical properties are provided for safety, health and environmental considerations only
and may not fully represent product specifications. Contact the Supplier for additional information.
GENERAL INFORMATION
Physical State: Liquid
Color: Pale Yellow
Odor: Characteristic
Odor Threshold: N/D
IMPORTANT HEALTH, SAFETY, AND ENVIRONMENTAL INFORMATION
Relative Density (at 15 °C): 0.883
Flammability (Solid, Gas): N/A
Flash Point [Method]: >145°C (293°F) [ASTM D-92]
Flammable Limits (Approximate volume % in air): LEL: N/D UEL: N/D
Autoignition Temperature: >315°C (599°F)
Boiling Point / Range: N/A
Decomposition Temperature: N/D
Vapor Density (Air = 1): > 5 at 101 kPa [Estimated]
Vapor Pressure: < 0.013 kPa (0.1 mm Hg) at 20 °C [Estimated]
Evaporation Rate (n-butyl acetate = 1): N/D
pH: N/A
Log Pow (n-Octanol/Water Partition Coefficient): > 6.5 [Estimated]
Solubility in Water: Negligible
Viscosity: 8.18 cSt (8.18 mm2/sec) at 40 °C | 2.18 cSt (2.18 mm2/sec) at 100°C
Oxidizing Properties: See Hazards Identification Section.
OTHER INFORMATION
Freezing Point: N/D
Melting Point: -55°C (-67°F)
Pour Point: -40°C (-40°F)
DMSO Extract (mineral oil only), IP-346: < 3 %wt
SECTION 10
STABILITY AND REACTIVITY
REACTIVITY: See sub-sections below.
Product Name: UNIVOLT N 61 B
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STABILITY: Material is stable under normal conditions.
CONDITIONS TO AVOID: Excessive heat. High energy sources of ignition.
MATERIALS TO AVOID: Strong oxidizers
HAZARDOUS DECOMPOSITION PRODUCTS: Material does not decompose at ambient temperatures.
POSSIBILITY OF HAZARDOUS REACTIONS: Hazardous polymerization will not occur.
SECTION 11
TOXICOLOGICAL INFORMATION
INFORMATION ON TOXICOLOGICAL EFFECTS
Hazard Class
Conclusion / Remarks
Inhalation
Acute Toxicity: No end point data for
material.
Minimally Toxic. Based on assessment of the components.
Irritation: No end point data for material.
Elevated temperatures or mechanical action may form vapors,
mist, or fumes which may be irritating to the eyes, nose, throat, or
lungs.
Ingestion
Acute Toxicity: No end point data for
material.
Minimally Toxic. Based on assessment of the components.
Skin
Acute Toxicity: No end point data for
material.
Minimally Toxic. Based on assessment of the components.
Skin Corrosion/Irritation: No end point data
for material.
May dry the skin leading to discomfort and dermatitis. Based on
assessment of the components.
Eye
Serious Eye Damage/Irritation: No end point
data for material.
May cause mild, short-lasting discomfort to eyes. Based on
assessment of the components.
Sensitization
Respiratory Sensitization: No end point data
for material.
Not expected to be a respiratory sensitizer.
Skin Sensitization: No end point data for
material.
Not expected to be a skin sensitizer. Based on assessment of the
components.
Aspiration: Data available.
May be fatal if swallowed and enters airways. Based on
physico-chemical properties of the material.
Germ Cell Mutagenicity: No end point data
for material.
Not expected to be a germ cell mutagen. Based on assessment of
the components.
Carcinogenicity: No end point data for
material.
Not expected to cause cancer. Based on assessment of the
components.
Reproductive Toxicity: No end point data
for material.
Not expected to be a reproductive toxicant. Based on assessment
of the components.
Lactation: No end point data for material.
Not expected to cause harm to breast-fed children.
Specific Target Organ Toxicity (STOT)
Single Exposure: No end point data for
material.
Not expected to cause organ damage from a single exposure.
Repeated Exposure: No end point data for
material.
Not expected to cause organ damage from prolonged or repeated
exposure. Based on assessment of the components.
TOXICITY FOR SUBSTANCES
Product Name: UNIVOLT N 61 B
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NAME
ACUTE TOXICITY
2,6-DI-TERT-BUTYL-P-CRESOL
Oral Lethality: LD50 0.89 g/kg (Rat)
OTHER INFORMATION
For the product itself:
Prolonged and/or repeated skin contact with low viscosity materials may defat the skin resulting in possible irritation and
dermatitis.
Small amounts of liquid aspirated into the lungs during ingestion or from vomiting may cause chemical pneumonitis or
pulmonary edema.
Contains:
Base oil severely refined: Not carcinogenic in animal studies. Representative material passes IP-346, Modified Ames
test, and/or other screening tests. Dermal and inhalation studies showed minimal effects; lung non-specific infiltration of
immune cells, oil deposition and minimal granuloma formation. Not sensitizing in test animals.
The following ingredients are cited on the lists below: None.
--REGULATORY LISTS SEARCHED--
1 = NTP CARC
3 = IARC 1
5 = IARC 2B
2 = NTP SUS
4 = IARC 2A
6 = OSHA CARC
SECTION 12
ECOLOGICAL INFORMATION
The information given is based on data available for the material, the components of the material, and similar materials.
ECOTOXICITY
Material -- Expected to be toxic to aquatic organisms. May cause long-term adverse effects in the aquatic
environment.
MOBILITY
Base oil component -- Low solubility and floats and is expected to migrate from water to the land.
Expected to partition to sediment and wastewater solids.
PERSISTENCE AND DEGRADABILITY
Biodegradation:
Base oil component -- Expected to be inherently biodegradable
BIOACCUMULATION POTENTIAL
Base oil component -- Has the potential to bioaccumulate, however metabolism or physical properties may
reduce the bioconcentration or limit bioavailability.
Product Name: UNIVOLT N 61 B
Revision Date: 16 Mar 2015
Page 9 of 11
______________________________________________________________________________________________________________________
SECTION 13
DISPOSAL CONSIDERATIONS
Disposal recommendations based on material as supplied. Disposal must be in accordance with current applicable
laws and regulations, and material characteristics at time of disposal.
DISPOSAL RECOMMENDATIONS
Product is suitable for burning in an enclosed controlled burner for fuel value or disposal by supervised
incineration at very high temperatures to prevent formation of undesirable combustion products. Protect the
environment. Dispose of used oil at designated sites. Minimize skin contact. Do not mix used oils with solvents,
brake fluids or coolants.
REGULATORY DISPOSAL INFORMATION
RCRA Information: The unused product, in our opinion, is not specifically listed by the EPA as a hazardous
waste (40 CFR, Part 261D), nor is it formulated to contain materials which are listed as hazardous wastes. It
does not exhibit the hazardous characteristics of ignitability, corrositivity or reactivity and is not formulated with
contaminants as determined by the Toxicity Characteristic Leaching Procedure (TCLP). However, used
product may be regulated.
Empty Container Warning Empty Container Warning (where applicable): Empty containers may contain residue and
can be dangerous. Do not attempt to refill or clean containers without proper instructions. Empty drums should be
completely drained and safely stored until appropriately reconditioned or disposed. Empty containers should be taken
for recycling, recovery, or disposal through suitably qualified or licensed contractor and in accordance with
governmental regulations. DO NOT PRESSURISE, CUT, WELD, BRAZE, SOLDER, DRILL, GRIND, OR EXPOSE
SUCH CONTAINERS TO HEAT, FLAME, SPARKS, STATIC ELECTRICITY, OR OTHER SOURCES OF IGNITION.
THEY MAY EXPLODE AND CAUSE INJURY OR DEATH.
SECTION 14
TRANSPORT INFORMATION
LAND (DOT): Not Regulated for Land Transport
LAND (TDG): Not Regulated for Land Transport
SEA (IMDG): Not Regulated for Sea Transport according to IMDG-Code
Marine Pollutant: No
AIR (IATA): Not Regulated for Air Transport
SECTION 15
REGULATORY INFORMATION
OSHA HAZARD COMMUNICATION STANDARD: This material is considered hazardous in accordance with OSHA
HazCom 2012, 29 CFR 1910.1200.
Product Name: UNIVOLT N 61 B
Revision Date: 16 Mar 2015
Page 10 of 11
______________________________________________________________________________________________________________________
Listed or exempt from listing/notification on the following chemical inventories: AICS, DSL, ENCS, IECSC,
KECI, PICCS, TSCA
EPCRA SECTION 302: This material contains no extremely hazardous substances.
SARA (311/312) REPORTABLE HAZARD CATEGORIES: Immediate Health. Delayed Health.
SARA (313) TOXIC RELEASE INVENTORY: This material contains no chemicals subject to the supplier notification
requirements of the SARA 313 Toxic Release Program.
The following ingredients are cited on the lists below:
Chemical Name
CAS Number
List Citations
2,6-DI-TERT-BUTYL-P-CRESOL
128-37-0
1, 13, 16, 17, 18
HYDROTREATED LIGHT
NAPHTHENIC DISTILLATE
(PETROLEUM)
64742-53-6
1, 4, 13, 17, 18
--REGULATORY LISTS SEARCHED--
1 = ACGIH ALL
6 = TSCA 5a2
11 = CA P65 REPRO
16 = MN RTK
2 = ACGIH A1
7 = TSCA 5e
12 = CA RTK
17 = NJ RTK
3 = ACGIH A2
8 = TSCA 6
13 = IL RTK
18 = PA RTK
4 = OSHA Z
9 = TSCA 12b
14 = LA RTK
19 = RI RTK
5 = TSCA 4
10 = CA P65 CARC
15 = MI 293
Code key: CARC=Carcinogen; REPRO=Reproductive
SECTION 16
OTHER INFORMATION
N/D = Not determined, N/A = Not applicable
KEY TO THE H-CODES CONTAINED IN SECTION 3 OF THIS DOCUMENT (for information only):
H304: May be fatal if swallowed and enters airways; Aspiration, Cat 1
H400: Very toxic to aquatic life; Acute Env Tox, Cat 1
H410: Very toxic to aquatic life with long lasting effects; Chronic Env Tox, Cat 1
THIS SAFETY DATA SHEET CONTAINS THE FOLLOWING REVISIONS:
Updates made in accordance with implementation of GHS requirements.
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The information and recommendations contained herein are, to the best of ExxonMobil's knowledge and belief, accurate
and reliable as of the date issued. You can contact ExxonMobil to insure that this document is the most current
available from ExxonMobil. The information and recommendations are offered for the user's consideration and
examination. It is the user's responsibility to satisfy itself that the product is suitable for the intended use. If buyer
repackages this product, it is the user's responsibility to insure proper health, safety and other necessary information is
Product Name: UNIVOLT N 61 B
Revision Date: 16 Mar 2015
Page 11 of 11
______________________________________________________________________________________________________________________
included with and/or on the container. Appropriate warnings and safe-handling procedures should be provided to
handlers and users. Alteration of this document is strictly prohibited. Except to the extent required by law,
re-publication or retransmission of this document, in whole or in part, is not permitted. The term, "ExxonMobil" is used
for convenience, and may include any one or more of ExxonMobil Chemical Company, Exxon Mobil Corporation, or any
affiliates in which they directly or indirectly hold any interest.
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Internal Use Only
MHC: 2A, 0B, 0, 0, 1, 1
PPEC: C
DGN: 2011629XUS (548632)
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Copyright 2002 Exxon Mobil Corporation, All rights reserved
01000721revF.sch-1 - Fri Nov 06 08:45:09 2015
GS 3/2/16
B Huhn 3/16/16
AEH
A Hague 3/21/16
A Hague 3/21/16
A Hague 3/21/16
A Hague 3/21/16
01000721revF.sch-2 - Fri Nov 06 08:45:10 2015
