Emerson Process Management Electric Co Oxygen Equipment 8732 Users Manual Rosemount Integral Mount Or Remote Magnetic Flowmeter System With FOUNDATION™ Fieldbus

8732 1b4bce95-7a2e-4629-9fff-5d964ab26a98 Emerson Process Management Oxygen Equipment 8732 User Guide |

2015-02-06

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www.rosemount.com
Reference Manual
00809-0100-4663, Rev BA
January 2010
Rosemount 8732
Integral Mount or Remote Mount Magnetic
Flowmeter System with FOUNDATION fieldbus
Reference Manual
00809-0100-4663, Rev BA
January 2010 Rosemount 8732
www.rosemount.com
Integral Mount or Remote Mount
Magnetic Flowmeter System with
FOUNDATION fieldbus
NOTICE
Read this manual before working with the product. For personal and system safety, and for
optimum product performance, make sure you thoroughly understand the contents before
installing, using, or maintaining this product.
Rosemount Inc. has two toll-free assistance numbers:
Customer Central
Technical support, quoting, and order-related questions.
United States - 1-800-999-9307 (7:00 am to 7:00 pm CST)
Asia Pacific- 65 777 8211
Europe/ Middle East/ Africa - 49 (8153) 9390
North American Response Center
Equipment service needs.
1-800-654-7768 (24 hours—includes Canada)
Outside of these areas, contact your local Rosemount representative.
The products described in this document are NOT designed for nuclear-qualified
applications. Using non-nuclear qualified products in applications that require
nuclear-qualified hardware or products may cause inaccurate readings.
For information on Rosemount nuclear-qualified products, contact your local Rosemount
Sales Representative.
Reference Manual
00809-0100-4663, Rev BA
January 2010
TOC-1
Rosemount 8732
SECTION 1
Introduction System Description. . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . .1-1
Safety Messages . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . .1-2
Service Support . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . .1-2
SECTION 2
Installation Safety Messages . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . .2-1
Transmitter Symbols. . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . .2-2
Pre-Installation . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . .2-2
Mechanical Considerations. . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . .2-2
Environmental Considerations . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . .2-3
Installation Procedures . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . .2-3
Mount the Transmitter . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . .2-3
Identify Options and Configurations . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . .2-4
Hardware Switches . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . .2-4
Conduit Ports and Connections. . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . .2-5
Conduit Cables . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . .2-6
Electrical Considerations. . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . .2-6
Installation Category . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . .2-7
Overcurrent Protection . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . .2-7
Connect Transmitter Power. . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . .2-7
Connect FOUNDATION fieldbus Wiring . . . . . . . . . . . . . . . . . . . . . . . . . . . . . .2-8
Transmitter Communication Input . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . .2-8
Power Conditioning . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . .2-8
Field Wiring . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . .2-8
Transmitter Wiring Connection . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . .2-9
Sensor Connections . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . .2-11
Rosemount Sensors . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . .2-11
Transmitter to Sensor Wiring. . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . .2-11
Conduit Cables . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . .2-12
Sensor to Remote Mount Transmitter Connections . . . . . . . . . . . . . . . . . .2-13
SECTION 3
Configuration Introduction. . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . .3-1
Local Operator Interface. . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . .3-1
Basic Features . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . .3-1
Data Entry . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . .3-2
LOI Examples . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . .3-2
Table Value Example . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . .3-3
Select Value Example . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . .3-3
Display Lock . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . .3-3
Start Totalizer . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . .3-3
Stop Totalizer . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . .3-3
Reset Totalizer . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . .3-3
Diagnostic Messages . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . .3-5
Review. . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . .3-5
Process Variables. . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . .3-5
PV - Primary Variable . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . .3-6
PV -% Range. . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . .3-6
PV - Analog Output . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . .3-6
Totalizer Setup . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . .3-6
Pulse Output . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . .3-7
Table of Contents
Reference Manual
00809-0100-4663, Rev BA
January 2010
Rosemount 8732
TOC-2
Basic Setup . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 3-7
Tag . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 3-7
Flow Units. . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 3-7
Line Size. . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 3-9
PV URV (Upper Range Value) . . . . . . . . . . . . . . . . . . . . . . . . . . . 3-10
PV LRV (Lower Range Value) . . . . . . . . . . . . . . . . . . . . . . . . . . . 3-10
Calibration Number. . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 3-11
PV Damping . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 3-11
SECTION 4
Operation Introduction . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 4-1
Diagnostics . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 4-1
Diagnostic Controls . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 4-1
Basic Diagnostics . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 4-2
Advanced Diagnostics . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 4-3
Diagnostic Variables. . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 4-8
Trims. . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 4-9
Status . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 4-11
Advanced Configuration . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 4-12
Detailed Setup . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 4-12
Additional Parameters . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 4-12
Display Language. . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 4-13
Signal Processing. . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 4-13
Device Info . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 4-15
Mode . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 4-17
Block Mode: Target . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 4-18
Block Mode: Actual. . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 4-18
Block Mode: Permitted . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 4-18
Block Mode: Normal . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 4-18
SECTION 5
Sensor Installation Safety Messages . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 5-1
Sensor Handling . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 5-3
Sensor Mounting . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 5-4
Upstream/Downstream
Piping . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 5-4
Sensor Orientation . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 5-4
Flow Direction. . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 5-6
Installation (Flanged Sensor). . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 5-7
Gaskets . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 5-7
Flange Bolts . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 5-7
Installation
(Wafer Sensor) . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 5-10
Gaskets . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 5-10
Flange Bolts . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 5-11
Installation
(Sanitary Sensor). . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 5-12
Gaskets . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 5-12
Alignment and Bolting. . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 5-12
Grounding . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 5-12
Process Leak Protection (Optional). . . . . . . . . . . . . . . . . . . . . . . . . . 5-16
Standard Housing Configuration . . . . . . . . . . . . . . . . . . . . . . . . . 5-16
Relief Valves. . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 5-17
Process Leak Containment . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 5-17
Reference Manual
00809-0100-4663, Rev BA
January 2010
TOC-3
Rosemount 8732
SECTION 6
Maintenance and
Troubleshooting
Safety Information . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 6-1
Installation Check and Guide. . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 6-2
Diagnostic Messages. . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 6-3
Transmitter Troubleshooting . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 6-5
Quick Troubleshooting. . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 6-7
Step 1: Wiring Errors . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 6-7
Step 2: Process Noise . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 6-7
Step 3: Installed Sensor Tests . . . . . . . . . . . . . . . . . . . . . . . . . . . . 6-7
Step 4: Uninstalled Sensor Tests . . . . . . . . . . . . . . . . . . . . . . . . . . 6-9
APPENDIX A
Reference Data Functional Specifications. . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . .A-1
Foundation fieldbus Specifications . . . . . . . . . . . . . . . . . . . . . . . . . .A-4
Performance Specifications. . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . .A-5
Physical Specifications . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . .A-7
APPENDIX B
Approval Information Product Certifications. . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . .B-1
Approved Manufacturing Locations . . . . . . . . . . . . . . . . . . . . . . . . . . .B-1
European Directive Information . . . . . . . . . . . . . . . . . . . . . . . . . . . . . .B-1
ATEX Directive . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . .B-1
European Pressure Equipment Directive (PED) (97/23/EC) . . . . .B-1
Electro Magnetic Compatibility (EMC) (2004/108/EC) . . . . . . . . . .B-2
Low Voltage Directive (93/68/EEC) . . . . . . . . . . . . . . . . . . . . . . . .B-2
Low Voltage Directive (2006/95/EC) . . . . . . . . . . . . . . . . . . . . . . .B-2
Other important guidelines . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . .B-2
IECEx Scheme . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . .B-2
Hazardous Locations Product Approvals Offering. . . . . . . . . . . . . . . .B-3
Hazardous Location Certifications. . . . . . . . . . . . . . . . . . . . . . . . . . . . B-5
Transmitter Approval Information . . . . . . . . . . . . . . . . . . . . . . . . . .B-5
APPENDIX C
Diagnostics Diagnostic Availability . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . .C-1
Licensing and Enabling . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . .C-2
Licensing the 8732 Diagnostics . . . . . . . . . . . . . . . . . . . . . . . . . . .C-2
Tunable Empty Pipe Detection . . . . . . . . . . . . . . . . . . . . . . . . . . . . . .C-2
Tunable Empty Pipe Parameters . . . . . . . . . . . . . . . . . . . . . . . . . .C-2
Optimizing Tunable Empty Pipe . . . . . . . . . . . . . . . . . . . . . . . . . . .C-3
Troubleshooting Empty Pipe . . . . . . . . . . . . . . . . . . . . . . . . . . . . .C-4
Ground/Wiring Fault Detection . . . . . . . . . . . . . . . . . . . . . . . . . . . . . .C-4
Ground/Wiring Fault Parameters . . . . . . . . . . . . . . . . . . . . . . . . . .C-4
Troubleshooting Ground/Wiring Fault. . . . . . . . . . . . . . . . . . . . . . .C-5
Ground/Wiring Fault Functionality . . . . . . . . . . . . . . . . . . . . . . . . .C-5
High Process Noise Detection. . . . . . . . . . . . . . . . . . . . . . . . . . . . . . .C-5
High Process Noise Parameters . . . . . . . . . . . . . . . . . . . . . . . . . .C-6
Troubleshooting High Process Noise . . . . . . . . . . . . . . . . . . . . . . .C-6
High Process Noise Functionality. . . . . . . . . . . . . . . . . . . . . . . . . .C-7
8714i Meter Verification. . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . .C-8
Sensor Signature Parameters . . . . . . . . . . . . . . . . . . . . . . . . . . . .C-8
8714i Meter Verification Test Parameters . . . . . . . . . . . . . . . . . . .C-9
8714i Meter Verification Test Results Parameters . . . . . . . . . . . .C-10
Optimizing the 8714i Meter Verification . . . . . . . . . . . . . . . . . . . .C-13
Troubleshooting the 8714i Meter Verification Test. . . . . . . . . . . .C-14
8714i Meter Verification Functionality. . . . . . . . . . . . . . . . . . . . . .C-14
Rosemount Magnetic Flowmeter Calibration Verification Report . . .C-16
Reference Manual
00809-0100-4663, Rev BA
January 2010
Rosemount 8732
TOC-4
APPENDIX D
Digital Signal Processing Safety Messages . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . D-1
Warnings . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . D-1
Procedures . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . D-2
Auto Zero . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . D-2
Signal Processing. . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . D-2
APPENDIX E
Universal Sensor Wiring
Diagrams
Rosemount Sensors . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . E-3
Rosemount 8705/8707/8711/8721 Sensors to
Rosemount 8732 Transmitter . . . . . . . . . . . . . . . . . . . . . . . . . . . . . E-3
Rosemount 8701 Sensor to Rosemount 8732 Transmitter . . . . . . E-4
Connecting Sensors of Other Manufacturers . . . . . . . . . . . . . . . . . E-5
Brooks Sensors . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . E-6
Model 5000 Sensor to Rosemount 8732 Transmitter. . . . . . . . . . . E-6
Model 7400 Sensor to Rosemount 8732 Transmitter. . . . . . . . . . . E-7
Endress And Hauser Sensors . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . E-8
Endress and Hauser Sensor to Rosemount 8732 Transmitter. . . . E-8
Fischer And Porter Sensors. . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . E-9
Model 10D1418 Sensor to Rosemount 8732 Transmitter . . . . . . . E-9
Model 10D1419 Sensor to Rosemount 8732 Transmitter . . . . . . E-10
Model 10D1430 Sensor (Remote) to
Rosemount 8732 Transmitter . . . . . . . . . . . . . . . . . . . . . . . . . . . . E-11
Model 10D1430 Sensor (Integral) to
Rosemount 8732 Transmitter . . . . . . . . . . . . . . . . . . . . . . . . . . . . E-12
Model 10D1465 and Model 10D1475 Sensors (Integral) to
8732 Transmitter . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . E-13
Fischer and Porter Sensor to Rosemount 8732 Transmitter . . . .E-14
Foxboro Sensors . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . .E-15
Series 1800 Sensor to Rosemount 8732 Transmitter . . . . . . . . .E-15
Series 1800 (Version 2) Sensor to
Rosemount 8732 Transmitter . . . . . . . . . . . . . . . . . . . . . . . . . . . .E-16
Series 2800 Sensor to 8732 Transmitter . . . . . . . . . . . . . . . . . . .E-17
Foxboro Sensor to 8732 Transmitter. . . . . . . . . . . . . . . . . . . . . .E-18
Kent Veriflux VTC Sensor . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . .E-19
Veriflux VTC Sensor to 8732 Transmitter. . . . . . . . . . . . . . . . . . .E-19
Kent Sensors . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . .E-20
Kent Sensor to Rosemount 8732 Transmitter . . . . . . . . . . . . . . .E-20
Krohne Sensors. . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . .E-21
Krohne Sensor to Rosemount 8732 Transmitter . . . . . . . . . . . . .E-21
Taylor Sensors. . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . .E-22
Series 1100 Sensor to Rosemount 8732 Transmitter . . . . . . . . .E-22
Taylor Sensor to Rosemount 8732 Transmitter . . . . . . . . . . . . . .E-23
Yamatake Honeywell Sensors. . . . . . . . . . . . . . . . . . . . . . . . . . . . . .E-24
Yamatake Honeywell Sensor to Rosemount 8732 Transmitter . .E-24
Yokogawa Sensors . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . .E-25
Yokogawa Sensor to Rosemount 8732 Transmitter. . . . . . . . . . .E-25
Generic Manufacturer Sensors . . . . . . . . . . . . . . . . . . . . . . . . . . . . .E-26
Generic Manufacturer Sensor to Rosemount 8732 Transmitter. .E-26
Identify the Terminals . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . .E-26
Wiring Connections . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . .E-26
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January 2010
TOC-5
Rosemount 8732
APPENDIX F
Resource Block Definition. . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . F-1
Parameters and Descriptions . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . F-1
Resource Block Errors. . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . F-5
Modes . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . F-5
Alarm Detection . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . F-6
Status Handling . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . F-6
VCR . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . F-6
Troubleshooting. . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . F-6
APPENDIX G
Transducer Block Definition. . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . .G-1
Parameters and Descriptions . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . .G-2
Flow-Specific Block Configuration Values . . . . . . . . . . . . . . . . . . . . . .G-3
Transducer Block Errors . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . .G-4
Transducer Block Diagnostics . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . .G-5
Modes . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . .G-5
Alarm Detection . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . .G-5
Status Handling . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . .G-5
Troubleshooting. . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . .G-6
APPENDIX H
375 Field Communicator
Operation
HandHeld Communicator . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . .H-1
Connections and Hardware . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . .H-2
Basic Features. . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . .H-3
Action Keys. . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . .H-3
Alphanumeric and Shift Keys . . . . . . . . . . . . . . . . . . . . . . . . . . . . .H-4
Menus and Functions . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . .H-4
Main Menu . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . .H-5
Online Menu . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . .H-5
Diagnostic Messages . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . .H-6
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January 2010
Rosemount 8732
TOC-6
Reference Manual
00809-0100-4663, Rev BA
January 2010 Rosemount 8732
www.rosemount.com
Section 1 Introduction
System Description . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . page 1-1
Safety Messages . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . page 1-2
Service Support . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . page 1-2
SYSTEM DESCRIPTION The Rosemount® 8700 Series Magnetic Flowmeter System consists of a
sensor and transmitter, and measures volumetric flow rate by detecting the
velocity of a conductive liquid that passes through a magnetic field.
There are four Rosemount magnetic flowmeter sensors:
Flanged Rosemount 8705
Flanged High-Signal Rosemount 8707
Wafer-Style Rosemount 8711
Sanitary Rosemount 8721
There are two Rosemount magnetic flowmeter transmitters:
Rosemount 8712
Rosemount 8732
The sensor is installed in-line with process piping — either vertically or
horizontally. Coils located on opposite sides of the sensor create a magnetic
field. Electrodes located perpendicular to the coils make contact with the
process fluid. A conductive liquid moving through the magnetic field
generates a voltage at the two electrodes that is proportional to the flow
velocity.
The transmitter drives the coils to generate a magnetic field, and electronically
conditions the voltage detected by the electrodes to provide a flow signal. The
transmitter can be integrally or remotely mounted from the sensor.
This manual is designed to assist in the installation and operation of the
Rosemount 8732 Magnetic Flowmeter Transmitter and the Rosemount 8700
Series Magnetic Flowmeter Sensors.
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January 2010
Rosemount 8732
1-2
SAFETY MESSAGES Procedures and instructions in this manual may require special precautions to
ensure the safety of the personnel performing the operations. Refer to the
safety messages listed at the beginning of each section before performing
any operations.
SERVICE SUPPORT To expedite the return process outside the United States, contact the nearest
Rosemount representative.
Within the United States and Canada, call the North American Response
Center using the 800-654-RSMT (7768) toll-free number. The Response
Center, available 24 hours a day, will assist you with any needed information
or materials.
The center will ask for product model and serial numbers, and will provide a
Return Material Authorization (RMA) number. The center will also ask for the
name of the process material to which the product was last exposed.
Mishandling products exposed to a hazardous substance may result in death
or serious injury. If the product being returned was exposed to a hazardous
substance as defined by OSHA, a copy of the required Material Safety Data
Sheet (MSDS) for each hazardous substance identified must be included with
the returned goods.
The North American Response Center will detail the additional information
and procedures necessary to return goods exposed to hazardous
substances.
Attempting to install and operate the Rosemount 8705, 8707 High-Signal, 8711 or 8721
Magnetic Sensors with the Rosemount 8712 or 8732 Magnetic Flowmeter Transmitter
without reviewing the instructions contained in this manual could result in personal injury or
equipment damage.
See “Safety Messages” on page D-1 for complete warning information.
Reference Manual
00809-0100-4663, Rev BA
January 2010 Rosemount 8732
www.rosemount.com
Section 2 Installation
Safety Messages . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . page 2-1
Transmitter Symbols . . . . . . . . . . . . . . . . . . . . . . . . . . . . . page 2-2
Pre-Installation . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . page 2-2
Mechanical Considerations . . . . . . . . . . . . . . . . . . . . . . . . page 2-2
Environmental Considerations . . . . . . . . . . . . . . . . . . . . . page 2-3
Installation Procedures . . . . . . . . . . . . . . . . . . . . . . . . . . . page 2-3
Sensor Connections . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . page 2-11
This section covers the steps required to physically install the magnetic
flowmeter. Instructions and procedures in this section may require special
precautions to ensure the safety of the personnel performing the operations.
Please refer to the following safety messages before performing any
operation in this section.
SAFETY MESSAGES This symbol is used throughout this manual to indicate that special attention
to warning information is required.
Failure to follow these installation guidelines could result in death or serious injury:
Installation and servicing instructions are for use by qualified personnel only. Do not perform
any servicing other than that contained in the operating instructions, unless qualified. Verify
that the operating environment of the sensor and transmitter is consistent with the
appropriate hazardous area approval.
Do not connect a Rosemount 8732 to a non-Rosemount sensor that is located in an
explosive atmosphere.
Explosions could result in death or serious injury:
Installation of this transmitter in an explosive environment must be in accordance with the
appropriate local, national, and international standards, codes, and practices. Please review
the approvals section of the 8732 reference manual for any restrictions associated with a
safe installation.
Before connecting a handheld communicator in an explosive atmosphere, make sure the
instruments in the loop are installed in accordance with intrinsically safe or non-incendive
field wiring practices.
Electrical shock can result in death or serious injury
Avoid contact with the leads and terminals. High voltage that may be present on leads can
cause electrical shock.
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January 2010
Rosemount 8732
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TRANSMITTER
SYMBOLS Caution symbol — check product documentation for details
Protective conductor (grounding) terminal
PRE-INSTALLATION Before installing the Rosemount 8732 Magnetic Flowmeter Transmitter, there
are several pre-installation steps that should be completed to make the
installation process easier:
Identify the options and configurations that apply to your application
Set the hardware switches if necessary
Consider mechanical, electrical, and environmental requirements
MECHANICAL
CONSIDERATIONS The mounting site for the 8732 transmitter should provide enough room for
secure mounting, easy access to conduit ports, full opening of the transmitter
covers, and easy readability of the LOI screen (see Figure 2-1). The
transmitter should be mounted in a manner that prevents moisture in conduit
from collecting in the transmitter.
If the 8732 is mounted remotely from the sensor, it is not subject to limitations
that might apply to the sensor.
The sensor liner is vulnerable to handling damage. Never place anything through the sensor
for the purpose of lifting or gaining leverage. Liner damage can render the sensor useless.
To avoid possible damage to the sensor liner ends, do not use metallic or spiral-wound
gaskets. If frequent removal is anticipated, take precautions to protect the liner ends. Short
spool pieces attached to the sensor ends are often used for protection.
Correct flange bolt tightening is crucial for proper sensor operation and life. All bolts must be
tightened in the proper sequence to the specified torque limits. Failure to observe these
instructions could result in severe damage to the sensor lining and possible sensor
replacement.
Emerson Process Management can supply lining protectors to prevent liner damage during
removal, installation, and excessive bolt torquing.
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January 2010
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Rosemount 8732
Figure 2-1. Rosemount 8732 Dimensional Drawing
ENVIRONMENTAL
CONSIDERATIONS To ensure maximum transmitter life, avoid temperature extremes and
vibration. Typical problem areas include:
high-vibration lines with integrally mounted transmitters
warm-climate installations in direct sunlight
outdoor installations in cold climates.
Remote-mounted transmitters may be installed in the control room to protect
the electronics from a harsh environment and provides easy access for
configuration or service.
Rosemount 8732 transmitters require external power so there must be access
to a suitable power source.
INSTALLATION
PROCEDURES Rosemount 8732 installation includes both detailed mechanical and electrical
installation procedures.
Mount the Transmitter Remote-mounted transmitters may be mounted on a pipe up to two inches in
diameter or against a flat surface.
Pipe Mounting
To mount the transmitter on a pipe:
1. Attach the mounting bracket to the pipe using the mounting hardware.
2. Attach the 8732 to the mounting bracket using the mounting screws.
5.82
(148)
6.48 (165)
7.49 (190)
LOI Cover
4.97
(126)
8.81
(224)
3.00
(76)
3.07
(78)
4.97
(126)
1/2”-14 NPT Electrical
Conduit Connections
(2 places with a 3rd
optional)
1/2”-14 NPT Remote Junction
Box Conduit Connections (2
places)
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Rosemount 8732
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Surface Mounting
To surface mount the transmitter:
1. Attach the 8732 to the mounting location using the mounting screws.
Identify Options and
Configurations The standard application of the Rosemount 8732 includes a FOUNDATION
fieldbus output. Be sure to identify options and configurations that apply to
your situation, and keep a list of them nearby for consideration during the
installation and configuration procedures.
Hardware Switches The 8732 electronics board is equipped with two user-selectable hardware
switches. These switches set the Transmitter Security and Simulate Mode.
The standard configuration for these switches when shipped from the factory
are as follows:
Definitions of these switches and their functions are provided below. If you
determine that the settings must be changed, see below.
Transmitter Security
The security switch on the 8732 allows the user to lock out any configuration
changes attempted on the transmitter. No changes to the configuration are
allowed when the switch is in the ON position. The flow rate indication
function remains active at all times.
With the switch in the ON position, you may still access and review any of the
operating parameters and scroll through the available choices, but no actual
data changes are allowed. Transmitter security is set in the OFF position
when shipped from the factory.
Simulate Mode
The Simulate Mode switch is used in conjunction with the Analog Input (AI)
function block. The switch is used to enable flow measurement simulation. To
enable the simulate enable feature, the switch must transition from OFF to
ON after power is applied to the transmitter, preventing the transmitter from
being accidentally left in simulate mode. Simulate Mode is set in the OFF
position when shipped from the factory.
Changing Hardware Switch Settings
In most cases, it is not necessary to change the setting of the hardware
switches. If you need to change the switch settings, complete the steps
below:
NOTE
The hardware switches are located on the top side of the electronics board
and changing their settings requires opening the electronics housing. If
possible, carry out these procedures away from the plant environment in
order to protect the electronics.
Transmitter Security: OFF
Simulate Mode OFF
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Rosemount 8732
1. Disconnect power to the transmitter.
2. Remove electronics cover.
3. Remove display if applicable.
4. Identify the location of each switch (see Figure 2-2).
5. Change the setting of the desired switches with a small screwdriver.
6. Replace the electronics cover.
Figure 2-2. Rosemount 8732
Electronics Board and Hardware
Switches
Conduit Ports and
Connections Both the sensor and transmitter junction boxes have ports for 1/2-inch NPT
conduit connections, with optional CM20 and PG 13.5 connections available.
These connections should be made in accordance with national, local or plant
electrical codes. Unused ports should be sealed with metal plugs and PTFE
tape or other thread sealant. Connections should also be made in accordance
with area approval requirements, see examples below for details. Proper
electrical installation is necessary to prevent errors due to electrical noise and
interference. Separate conduits are not necessary for the coil drive and signal
cables connecting the transmitter to the sensor, but a dedicated conduit line
between each transmitter and sensor is required. A shielded cable must be
used.
Example 1: Installing flanged sensors into an IP68 area. Sensors must be
installed with IP68 cable glands and cable to maintain IP68 rating. Unused
conduit connections must be properly sealed to prevent water ingress. For
added protection, dielectric gel can be used to pot the sensor terminal block.
Example 2: Installing flowmeters into explosion proof/flameproof areas.
Conduit connections and conduit must be rated for use in the hazardous area
to maintain flowmeter approval rating.
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Rosemount 8732
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Conduit Cables Run the appropriate size cable through the conduit connections in your
magnetic flowmeter system. Run the power cable from the power source to
the transmitter. Do not run power cables and output signal cables in the same
conduit. For remote mount installations, run the coil drive and electrode
cables between the flowmeter and transmitter. Refer to Electrical
Considerations for wire type. Prepare the ends of the coil drive and electrode
cables as shown in Figure 2-3. Limit the unshielded wire length to 1-in. on
both the electrode and coil drive cables. Excessive lead length or failure to
connect cable shields can create electrical noise resulting in unstable meter
readings.
Figure 2-3. Cable Preparation
Detail
Electrical Considerations Before making any electrical connections to the Rosemount 8732, consider
the following standards and be sure to have the proper power supply, conduit,
and other accessories. When preparing all wire connections, remove only the
insulation required to fit the wire completely under the terminal connection.
Removal of excessive insulation may result in an unwanted electrical short to
the transmitter housing or other wire connections.
Transmitter Input Power
The 8732 transmitter is designed to be powered by 90-250 V AC, 50–60 Hz or
12–42 V DC. The eighth digit in the transmitter model number designates the
appropriate power supply requirement.
Supply Wire Temperature Rating
Use 12 to 18 AWG wire. For connections in ambient temperatures
exceeding 140 °F (60 °C), use wire rated to at least 194 °F (90 °C).
Disconnects
Connect the device through an external disconnect or circuit breaker.
Clearly label the disconnect or circuit breaker and locate it near the
transmitter.
Requirements for 90-250 V AC Power Supply
Wire the transmitter according to national, local, and plant electrical
requirements for the supply voltage. In addition, follow the supply wire and
disconnect requirements on page 2-7.
NOTE
Dimensions are in
inches
(millimeters).
1.00
(26)
Cable Shield
Model Number Power Supply Requirement
1 90-250 V AC
212-42 V DC
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Rosemount 8732
Requirements for 12-42 V DC Power Supply
Units powered with 12-42 V DC may draw up to 1 amp of current. As a result,
the input power wire must meet certain gauge requirements.
Figure 2-4 shows the supply current for each corresponding supply voltage.
For combinations not shown, you can calculate the maximum distance given
the supply current, the voltage of the source, and the minimum start-up
voltage of the transmitter, 12 V DC, using the following equation:
Figure 2-4. Supply Current
versus Input Voltage
Installation Category The installation category for the Rosemount 8732 is (overvoltage) Category II.
Overcurrent Protection The Rosemount 8732 Flowmeter Transmitter requires overcurrent protection
of the supply lines. Maximum ratings of overcurrent devices are as follows:
Connect Transmitter
Power To connect power to the transmitter, complete the following steps.
1. Ensure that the power source and connecting cable meet the
requirements outlined on page 2-8.
2. Turn off the power source.
3. Open the power terminal cover.
4. Run the power cable through the conduit to the transmitter.
5. Connect the power cable leads as shown in Figure 2-5.
a. Connect AC Neutral or DC- to terminal 9.
b. Connect AC Line or DC+ to terminal 10.
c. Connect AC Ground or DC Ground to the ground screw mounted
inside the transmitter enclosure.
MaximumResis cetan SupplyVoltage 12VDC
1amp
--------------------------------------------------------------------=
Power Supply (Volts)
I = 10/V
I = Supply current requirement (Amps)
V = Power supply voltage (Volts)
Supply Current (Amps)
12 18 24 30 36 42
0.2
0.3
0.4
0.5
0.6
0.7
0.8
0.9
Power System Fuse Rating Manufacturer
110 V AC 250 V; 1 Amp, Quick Acting Bussman AGCI or Equivalent
220 V AC 250 V; 2 Amp, Quick Acting Bussman AGCI or Equivalent
42 V DC 50 V, 3 Amp, Quick Acting Bussman AGCI or Equivalent
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2-8
Figure 2-5. AC Transmitter
Power Connections
Connect FOUNDATION
fieldbus Wiring The FOUNDATION fieldbus signal provides the output information from the
transmitter.
Transmitter
Communication Input The FOUNDATION fieldbus communication requires a minimum of
9 V dc and a maximum of 32 V dc at the transmitter communication terminals.
NOTES
Do not exceed 32 V dc at the transmitter communication terminals.
Do not apply ac line voltage to the transmitter
communication terminals.
Improper supply voltage can damage the transmitter.
Power Conditioning Each fieldbus power supply requires a power conditioner to decouple the
power supply output from the fieldbus wiring segment.
Field Wiring Power independent of the coil power supply must be supplied for FOUNDATION
fieldbus communications. Use shielded, twisted pair for best results. For new
installations or to get maximum performance, twisted pair cable designed
especially for fieldbus should be used. Table 2-1 details cable characteristics
and ideal specifications.
Table 2-1.
Ideal Cable Specifications for
Fieldbus Wiring
See “Safety Messages” on page 2-1 for complete warning information.
Characteristic Ideal Specification
Impedance 100 Ohms ± 20% at 31.25 kHz
Wire Size 18 AWG (0,8 mm2)
Shield Coverage 90%
Attenuation 3 db/km
Capacitive Unbalance 2 nF/km
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Rosemount 8732
NOTE
The number of devices on a fieldbus segment is limited by the power supply
voltage, the resistance of the cable, and the amount of current drawn by
each device.
Transmitter Wiring
Connection To connect the 8732 to the FOUNDATION fieldbus (FF) segment, complete
the following steps.
1. Ensure that the power source and connecting cable meet the
requirements outlined above and in “Field Wiring” on page 2-8.
2. Turn off the transmitter and power sources.
3. Run the FOUNDATION fieldbus cable into the transmitter.
4. Connect -FF to Terminal 1.
5. Connect +FF to Terminal 2.
NOTE
Foundation fieldbus signal wiring for the 8732 is not polarity sensitive.
Refer to Figure 2-6 on page 2-9.
Figure 2-6. FOUNDATION fieldbus
Signal Connections
–FF signal
+FF signal
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Rosemount 8732
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Figure 2-7. Rosemount 8732
Transmitter Field Wiring
Integrated
Power
Conditioner
and Filter Terminators
6234 ft (1900 m) max
(depending upon cable
characteristics)
Fieldbus
Segment
(Spur)
(Trunk)
(The power supply,
filter, first terminator,
and configuration tool
are typically located
in the control room.)
*Intrinsically safe installations may
allow fewer devices per I.S. barrier.
Power
Supply
FOUNDATION
Fieldbus
Configuration
Tool
(Spur)
Devices 1 through 11*
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Rosemount 8732
SENSOR CONNECTIONS This section covers the steps required to physically install the transmitter
including wiring and calibration.
Rosemount Sensors To connect the transmitter to a non-Rosemount sensor, refer to the
appropriate wiring diagram in “Universal Sensor Wiring Diagrams” on
page E-1. The calibration procedure listed is not required for use with
Rosemount sensors.
Transmitter to Sensor
Wiring Flanged and wafer sensors have two conduit ports as shown in Figure 2-8.
Either one may be used for both the coil drive and electrode cables. Use the
stainless steel plug that is provided to seal the unused conduit port. Use
Teflon tape or thread sealant appropriate for the installation when sealing the
conduit.
A single dedicated conduit run for the coil drive and electrode cables is
needed between a sensor and a remote transmitter. Bundled cables in a
single conduit are likely to create interference and noise problems in your
system. Use one set of cables per conduit run. See Figure 2-8 for proper
conduit installation diagram and Table 2-2 for recommended cable. For
integral and remote wiring diagrams refer to Figure 2-10.
Figure 2-8. Conduit Preparation
Correct Incorrect
Table 2-2. Cable Requirements
Description Units Part Number
Signal Cable (20 AWG) Belden 8762, Alpha 2411 equivalent ft
m
08712-0061-0001
08712-0061-0003
Coil Drive Cable (14 AWG) Belden 8720, Alpha 2442 equivalent ft
m
08712-0060-0001
08712-0060-0003
Combination Signal and Coil Drive Cable (18 AWG)(1)
(1) Combination signal and coil drive cable is not recommended for high-signal magmeter system. For remote mount installations, combination signal and coil
drive cable should be limited to less than 330 ft. (100 m).
ft
m
08712-0752-0001
08712-0752-0003
Coil Drive
and
Electrode
Cables
Power Power
Outputs
Outputs
Coil Drive
and
Electrode
Cables
Power
Outputs
Power
Outputs
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Rosemount recommends using the combination signal and coil drive for N5,
E5 approved sensors for optimum performance.
Remote transmitter installations require equal lengths of signal and coil drive
cables. Integrally mounted transmitters are factory wired and do not require
interconnecting cables.
Lengths from 5 to 1,000 feet (1.5 to 300 meters) may be specified, and will be
shipped with the sensor.
Conduit Cables Run the appropriate size cable through the conduit connections in your
magnetic flowmeter system. Run the power cable from the power source to
the transmitter. Run the coil drive and electrode cables between the sensor
and transmitter.
Prepare the ends of the coil drive and electrode cables as shown in Figure
2-9. Limit the unshielded wire length to 1-inch on both the electrode and coil
drive cables.
NOTE
Excessive lead length or failure to connect cable shields can create electrical
noise resulting in unstable meter readings.
Figure 2-9. Cable Preparation
Detail
1.00
(26)
NOTE
Dimensions are in
inches (millimeters).
Cable Shield
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Sensor to Remote Mount
Transmitter Connections Connect coil drive and electrode cables as shown in Figure 2-10.
Do not connect AC power to the sensor or to terminals 1 and 2 of the
transmitter, or replacement of the electronics board will be necessary.
Figure 2-10. Wiring Diagram
Rosemount 8732 Transmitter Rosemount 8705/8707/8711/8721
Sensors
11
2 2
17 17
18 18
19 19
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www.rosemount.com
Section 3 Configuration
Introduction . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . page 3-1
Local Operator Interface . . . . . . . . . . . . . . . . . . . . . . . . . . page 3-1
Basic Features . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . page 3-1
LOI Examples . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . page 3-2
Diagnostic Messages . . . . . . . . . . . . . . . . . . . . . . . . . . . . . page 3-5
Process Variables . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . page 3-5
Basic Setup . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . page 3-7
INTRODUCTION This section covers basic operation, software functionality, and configuration
procedures for the Rosemount 8732 Magnetic Flowmeter Transmitter. For
information on connecting another manufacturer’s flowtube sensor, refer to
“Universal Sensor Wiring Diagrams” on page E-1.
The Rosemount 8732 features a full range of software functions for
configuration of output from the transmitter. Software functions are accessed
through the LOI, AMS, a Handheld Communicator, or a control system.
Configuration variables may be changed at any time and specific instructions
are provided through on-screen instructions.
LOCAL OPERATOR
INTERFACE The optional Local Operator Interface (LOI) provides an operator
communications center for the 8732. By using the LOI, the operator can
access any transmitter function for changing configuration parameter settings,
checking totalized values, or other functions. The LOI is integral to the
transmitter electronics.
BASIC FEATURES The basic features of the LOI include 4 navigational arrow keys that are used
to access the menu structure. See Figure 3-1.
Table 3-1. Parameters
Basic Set-up Parameters Page
Review page 3-5
Process Variables page 3-5
Basic Setup page 3-7
Flow Units page 3-7
Range Values page 3-10
PV Sensor/Flowtube Sensor Calibration Number page 3-11
Totalizer Setup page 3-6
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Figure 3-1. Local Operator
Interface Keypad
Data Entry The LOI keypad does not have numerical keys. Numerical data is entered by
the following procedure.
1. Access the appropriate function.
2. Use the RIGHT ARROW key to move to the value to change.
3. Use the UP and DOWN ARROWS to change the highlighted value.
For numerical data, toggle through the digits 0–9, decimal point, and
dash. For alphabetical data, toggle through the letters of the alphabet
A–Z, digits 0–9, and the symbols -,&, +, -, *, /, $, @,%, and the blank
space.
4. Use the RIGHT ARROWS to highlight other digits you want to change
and change them.
5. Press “E” (the left arrow key) when all changes are complete to save
the entered values.
LOI EXAMPLES Use the DOWN ARROW to access the menu structure in Table 3-2. Use the
ARROW KEYS to select the desired parameters to review/change.
Parameters are set in one of two ways, Table Values or Select Values.
Table Values:
Parameters such as units, that are available from a predefined list
Select Values:
Parameters that consist of a user-created number or character string, such
as calibration number; values are entered one character at a time using
the ARROW KEYS.
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Table Value Example Setting the TUBE SIZE:
1. Press the DOWN arrow to access the menu.
2. Select line size from the Basic set-up menu.
3. Press the UP or DOWN arrow to increase/decrease (incrementally)
the tube size to the next value.
4. When you reach the desired size, press “E” (the left arrow).
5. Set the loop to manual if necessary, and press “E” again.
After a moment, the LCD will display the new tube size and the maximum flow
rate.
Select Value Example Changing the ANALOG OUTPUT RANGE:
1. Press the DOWN arrow to access the menu.
2. Using the arrow keys, select PV URV from the Basic Setup menu.
3. Press RIGHT arrow key to position the cursor.
4. Press UP or DOWN to set the number.
5. Repeat steps 2 and 3 until desired number is displayed.
6. Press “E”.
After a moment, the LCD will display the new analog output range.
Display Lock The display can be locked to prevent unintentional configuration changes.
The display lock can be activated through a HART communication device, or
by holding the UP arrow for 10 seconds. When the display lock is activated,
DL will appear in the lower left hand corner of the display. To deactivate the
display lock (DL), hold the UP arrow for 10 seconds. Once deactivated, the
DL will no longer appear in the lower left hand corner of the display.
Start Totalizer To start the totalizer, press the DOWN arrow to display the totalizer screen
and press “E” to begin totalization. A symbol will flash in the lower right
hand corner indicating that the meter is totalizing.
Stop Totalizer To stop the totalizer, press the DOWN arrow to display the totalizer screen
and press “E” to end totalization. The flashing symbol will no longer display
in the lower right hand corner indicating that the meter has stopped totalizing.
Reset Totalizer To reset the totalizer, press the DOWN arrow to display the totalizer screen
and follow the procedure above to stop totalization. Once totalization has
stopped, press the RIGHT arrow key to reset the NET total value to zero.
To reset the gross total value, you must change the line size. See “Line Size”
on page 3-9 for details on how to change the line size.
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Table 3-2. LOI Menu Tree
Diag Controls
Basic Diag
A dvanced Diag
Variables
Trims
Status
E mpty Pi pe
Process Noise
G round/W i ri ng
Elec Temp
Self Test
A O L oop T est
Pulse Out Test
E mpty Pi pe
Elec Temp
G round/W i ri ng
Process Noise
8714i
4-20 mA V erify
Licensing
R un 8714i
V iew R esults
Tube Signature
Test Criteria
M easurements
Values
R e-Signature
Recall V alues
Coil R esist
C oil Signature
E lectrode R es
No Flow
Flowing, Full
E mpty Pi pe
Coil R esist
C oil Signature
E lectrode R es
E mpty Pi pe
Elec Temp
L i ne N oise
5Hz SNR
37Hz SNR
Signal Power
8714i R esults
D/A Trim
Digital Trim
A uto Zero
Universal Trim
4-20 mA V erify
View Results
Tag
Flow Units
L i ne Size
PV URV
PV L R V
Cal Number
PV Damping
C oi l F requency
Proc Density
PV LSL
PV USL
PV Min Span
Analog
Pulse
DI/DO Config
Totalizer
Reverse Flow
HART
PV URV
PV L R V
Alarm Type
Test
Pulse Scaling
Pulse Width
Pulse Mode
Test
DI 1
DO 2
Totalize Units
Total Dis
p
la
y
Burst Mode
B urst C ommand
F lange T ype
F lange M atl
E lectrode T ype
E lectrode M atl
L iner Material
Software Rev
Final Asmbl #
Tag
Description
Message
Device ID
PV Sensor S/N
Flowtube Tag
Revision Num
M aterial s
Operating Mode
SP Config
C oil F requency
PV Damping
Lo-Flow Cuto
Flow Display
Total Display
L anguage
More Params
Output C onfig
LOI Config
Sig Processing
Device Info
PV Units
Special Units
Totalize Units
Diagnostics
Basic Setup
Detail ed S etup
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DIAGNOSTIC
MESSAGES The following error messages may appear on the LOI screen. See Table 6-4
on page 6-5 for potential causes and corrective actions for these errors:
Electronics Failure
Coil open circuit
Digital trim failure
Auto zero failure
Auto trim failure
Flowrate > sensor limit
Analog out of range
PZR activated
Electronics Temp Fail
Pulse out of range
Empty pipe
Reverse flow
Electronics temp out of range
The following error messages may appear on the LOI screen. See Table 6-4
on page 6-5 for potential causes and corrective actions for these errors:
High Process Noise
Grounding/Wiring Fault
4-20 mA Loop Verification Failed
8714i Failed
Review The 8732 includes a capability that enables you to review the configuration
variable settings.
The flowmeter configuration parameters set at the factory should be reviewed
to ensure accuracy and compatibility with your particular application of the
flowmeter.
NOTE
If you are using the LOI to review variables, each variable must be accessed
as if you were going to change its setting. The value displayed on the LOI
screen is the configured value of the variable.
PROCESS VARIABLES The process variables measure flow in several ways that reflect your needs
and the configuration of your flowmeter. When commissioning a flowmeter,
review each process variable, its function and output, and take corrective
action if necessary before using the flowmeter in a process application
Process Variable (PV) – The actual measured flow rate in the line. Use the
Process Variable Units function to select the units for your application.
Percent of Range – The process variable as a percentage of the Analog
Output range, provides an indication where the current flow of the meter is
within the configured range of the flowmeter. For example, the Analog Output
range may be defined as 0 gal/min to 20 gal/min. If the measured flow is 10
gal/min, the percent of range is 50 percent.
Fast Keys 1, 5
Fast Keys 1, 1
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Analog Output – The analog output variable provides the analog value for the
flow rate. The analog output refers to the industry standard output in the 4–20
mA range. The analog output and 4-20 mA loop can be verified using the
Analog Feedback diagnostic capability internal to the transmitter (See “8714i
Meter Verification” on page C-8).
Totalizer Setup – Provides a reading of the total flow of the flowmeter since
the totalizer was last reset. The totalizer value should be zero during
commissioning on the bench, and the units should reflect the volume units of
the flow rate. If the totalizer value is not zero, it may need to be reset. This
function also allows for configuration of the totalizer parameters.
Pulse Output – The pulse output variable provides the pulse value for the flow
rate.
PV - Primary Variable The Primary Variable shows the current measured flow rate. This value
determines the analog output from the transmitter.
PV -% Range The PV% Range shows where in the flow range the current flow value is as a
percentage of the configured span.
PV - Analog Output The PV Analog Output displays the mA output of the transmitter
corresponding to the measured flow rate.
Totalizer Setup The Totalizer Setup menu allows for the viewing and configuration of the
totalizer parameters.
Totalizer Units
Totalizer units allow for the configuration of the units that the totalized value
will be displayed as. These units are independent of the flow units.
Measured Gross Total
Measured gross total provides the output reading of the totalizer. This value is
the amount of process fluid that has passed through the flowmeter since the
totalizer was last reset.
NOTE
To reset the measured gross total value, the line size must be changed.
Measured Net Total
Measured net total provides the output reading of the totalizer. This value is
the amount of process fluid that has passed through the flowmeter since the
totalizer was last reset. When reverse flow is enabled, the net total represents
the difference between the total flow in the forward direction less the total flow
in the reverse direction.
Fast Keys 1, 1, 1
Fast Keys 1, 1, 2
Fast Keys 1, 1, 3
Fast Keys 1, 1, 4
Fast Keys 1, 1, 4, 1
Fast Keys 1, 1, 4, 2
Fast Keys 1, 1, 4, 3
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Measured Reverse Total
Measured reverse total provides the output reading of the totalizer. This value
is the amount of process fluid that has passed through the flowmeter in the
reverse direction since the totalizer was last reset. This value is only totalized
when reverse flow is enabled.
Start Totalizer
Start totalizer starts the totalizer counting from its current value.
Stop Totalizer
Stop totalizer interrupts the totalizer count until it is restarted again. This
feature is often used during pipe cleaning or other maintenance operations.
Reset Totalizer
Reset totalizer resets the net totalizer value to zero. The totalizer must be
stopped before resetting.
NOTE
The totalizer value is saved in the Non-Volatile memory of the electronics
every three seconds. Should power to the transmitter be interrupted, the
totalizer value will start at the last saved value when power is re-applied.
Pulse Output The Pulse Output displays the current value of the pulse signal.
BASIC SETUP The basic configuration functions of the Rosemount 8732 must be set for all
applications of the transmitter in a magnetic flowmeter system. If your
application requires the advanced functionality features of the Rosemount
8732, see Section 4 "Operation" of this manual.
Tag Tag is the quickest and shortest way of identifying and distinguishing between
transmitters. Transmitters can be tagged according to the requirements of
your application. The tag may be up to eight characters long.
Flow Units Flow Units set the output units for the Primary Variable which controls the
analog output of the transmitter.
Primary Variable Units
The Primary Variable Units specifies the format in which the flow rate will be
displayed. Units should be selected to meet your particular metering needs.
Fast Keys 1, 1, 4, 4
Fast Keys 1, 1, 4, 5
Fast Keys 1, 1, 4, 6
Fast Keys 1, 1, 4, 7
Fast Keys 1, 1, 5
Fast Keys 1, 3
Fast Keys 1, 3, 1
Fast Keys 1, 3, 2
Fast Keys 1, 3, 2, 1
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Options for Flow Rate Units
Special Units
The Rosemount 8732 provides a selection of standard unit configurations that
meet the needs of most applications (see “Flow Units” on page 3-7). If your
application has special needs and the standard configurations do not apply,
the Rosemount 8732 provides the flexibility to configure the transmitter in a
custom-designed units format using the special units variable.
Special Volume Unit
Special volume unit enables you to display the volume unit format to which
you have converted the base volume units. For example, if the special units
are abc/min, the special volume variable is abc. The volume units variable is
also used in totalizing the special units flow.
ft/sec B31/sec (1 Barrel = 31.5 gallons)
•m/sec B31/min (1 Barrel = 31.5 gallons)
gal/sec B31/hr (1 Barrel = 31.5 gallons)
• gal/min B31/day (1 Barrel = 31.5 gallons)
• gal/hr • lbs/sec
• gal/day •lbs/min
•l/sec •lbs/hr
•l/min • lbs/day
• l/hr • kg/sec
• l/day •kg/min
•ft
3/sec • kg/hr
•ft
3/min • kg/day
•ft
3/hr • (s)tons/min
•ft
3/day • (s)tons/hr
•m
3/sec • (s)tons/day
•m
3/min • (m)tons/min
•m
3/hr • (m)tons/hr
•m
3/day • (m)tons/day
Impgal/sec Special (User Defined, see
“Special Units” on page 3-8)
• Impgal/min
• Impgal/hr
• Impgal/day
B42/sec (1 Barrel = 42 gallons)
B42/min (1 Barrel = 42 gallons)
B42/hr (1 Barrel = 42 gallons)
B42/day (1 Barrel = 42 gallons)
Fast Keys 1, 3, 2, 2
Fast Keys 1, 3, 2, 2, 1
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Rosemount 8732
Base Volume Unit
Base volume unit is the unit from which the conversion is being made. Set this
variable to the appropriate option.
Conversion Number
The special units conversion number is used to convert base units to special
units. For a straight conversion of volume units from one to another, the
conversion number is the number of base units in the new unit. For example,
if you are converting from gallons to barrels and there are 31 gallons in a
barrel, the conversion factor is 31.
Base Time Unit
Base time unit provides the time unit from which to calculate the special units.
For example, if your special units is a volume per minute, select minutes.
Special Flow Rate Unit
Special flow rate unit is a format variable that provides a record of the units to
which you are converting. The Handheld Communicator will display a special
units designator as the units format for your primary variable. The actual
special units setting you define will not appear. Four characters are available
to store the new units designation. The 8732 LOI will display the four
character designation as configured.
Example
To display flow in barrels per hour, and one barrel is equal to 31.0 gallons, the
procedure would be:
Set the Volume Unit to BARL.
Set the Base Volume Unit to gallons.
Set the Input Conversion Number to 31.
Set the Time Base to Hour.
Set the Rate Unit to BR/H.
Line Size The line size (flowtube sensor size) must be set to match the actual flowtube
sensor connected to the transmitter. The size must be specified in inches
according to the available sizes listed below. If a value is entered from a
control system or Handheld Communicator that does not match one of these
figures, the value will go to the next highest option.
The line size (inches) options are as follows:
Fast Keys 1, 3, 2, 2, 2
Fast Keys 1, 3, 2, 2, 3
Fast Keys 1, 3, 2, 2, 4
Fast Keys 1, 3, 2, 2, 5
Fast Keys 1, 3, 3
0.1, 0.15, 0.25, 0.30, 0.50, 0.75, 1, 1.5, 2, 2.5, 3, 4, 6, 8, 10, 12, 14,
16, 18, 20, 24, 28, 30, 32, 36, 40, 42, 44, 48, 54, 56, 60, 64, 72, 80
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PV URV
(Upper Range Value) The upper range value (URV), or analog output range, is preset to 30 ft/s at
the factory. The units that appear will be the same as those selected under the
units parameter.
The URV (20 mA point) can be set for both forward or reverse flow rate. Flow
in the forward direction is represented by positive values and flow in the
reverse direction is represented by negative values. The URV can be any
value from –39.3 ft/s to +39.3 ft/s (-12 m/s to +12 m/s), as long as it is at least
1 ft/s (0.3 m/s) from the lower range value (4 mA point). The URV can be set
to a value less than the lower range value. This will cause the transmitter
analog output to operate in reverse, with the current increasing for lower (or
more negative) flow rates.
NOTE
Line size, special units, and density must be selected prior to configuration of
URV and LRV.
PV LRV
(Lower Range Value) Set the lower range value (LRV), or analog output zero, to change the size of
the range (or span) between the URV and LRV. Under normal circumstances,
the LRV should be set to a value near the minimum expected flow rate to
maximize resolution. The LRV must be between
–39.3 ft/s to +39.3 ft/s (-12 m/s to +12 m/s).
NOTE
Line size, special units, and density must be selected prior to configuration of
URV and LRV.
Example
If the URV is greater than the LRV, the analog output will saturate at 3.9 mA
when the flow rate falls below the selected 4 mA point.
The minimum allowable span between the URV and LRV is 1 ft/s (0.3 m/s).
Do not set the LRV within 1 ft/s (0.3 m/s) of the 20 mA point. For example, if
the URV is set to 15.67 ft/s (4.8 m/s) and if the desired URV is greater than
the LRV, then the highest allowable analog zero setting would be 14.67 ft/s
(4.5 m/s). If the desired URV is less than the LRV, then the lowest allowable
LRV would be 16.67 ft/s (5.1 m/s).
Fast Keys 1, 3, 4
Fast Keys 1, 3, 5
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Rosemount 8732
Calibration Number The tube calibration number is a 16-digit number used to identify flowtube
sensors calibrated at the Rosemount factory. The calibration number is also
printed inside the flowtube sensor terminal block or on the flowtube sensor
name plate. The number provides detailed calibration information to the
Rosemount 8732. To function properly within accuracy specifications, the
number stored in the transmitter must match the calibration number on the
flowtube sensor exactly.
NOTE
Flowtube Sensors from manufacturers other than Rosemount Inc. can also be
calibrated at the Rosemount factory. Check the tube for Rosemount
calibration tags to determine if a 16-digit tube calibration number exists for
your flowtube sensor.
NOTE
Be sure the calibration number reflects a calibration to a Rosemount
reference transmitter. If the calibration number was generated by a means
other than a certified Rosemount flow lab, accuracy of the system may be
compromised.
If your flowtube sensor is not a Rosemount flowtube sensor and was not
calibrated at the Rosemount factory, contact your Rosemount representative
for assistance.
If your flowtube sensor is imprinted with an eight-digit number or a k-factor,
check in the flowtube sensor wiring compartment for the sixteen-digit
calibration number. If there is no serial number, contact the factory for a
proper conversion.
PV Damping Adjustable between 0.0 and 256 seconds
PV Damping allows selection of a response time, in seconds, to a step
change in flow rate. It is most often used to smooth fluctuations in output.
Fast Keys 1, 3, 6
Fast Keys 1, 3, 7
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www.rosemount.com
Section 4 Operation
Introduction . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . page 4-1
Diagnostics . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . page 4-1
Advanced Configuration . . . . . . . . . . . . . . . . . . . . . . . . . . page 4-12
Detailed Setup . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . page 4-12
Mode . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . page 4-17
INTRODUCTION This section contains information for advanced configuration parameters and
diagnostics.
The software configuration settings for the Rosemount 8732 can be accessed
through a 375 Field Communicator or through a control system. The software
functions for the 375 Field Communicator are described in detail in this
section of the manual. It provides an overview and summary of communicator
functions. For more complete instructions, see the communicator manual.
Before operating the Rosemount 8732 in an actual installation, you should
review all of the factory set configuration data to ensure that they reflect the
current application.
DIAGNOSTICS Diagnostics are used to verify that the transmitter is functioning properly, to
assist in troubleshooting, to identify potential causes of error messages, and
to verify the health of the transmitter and sensor. Diagnostic tests can be
initiated through the use of a 375 Field Communicator or through the control
system.
Rosemount offers several different diagnostic suites providing various
functionality.
Standard diagnostics included with every Rosemount 8732 transmitter are
Empty Pipe detection, Electronics Temperature monitoring, Coil Fault
detection, and various loop and transmitter tests.
Advanced diagnostics suite option one (D01 option) contains advanced
diagnostics for High Process Noise detection and Grounding and Wiring fault
detection.
Advanced diagnostics suite option two (D02 option) contains advanced
diagnostics for the 8714i Meter Verification. This diagnostic is used to verify
the accuracy and performance of the magnetic flow meter installation.
Diagnostic Controls The diagnostic controls menu provides a centralized location for enabling or
disabling each of the diagnostics that are available. Note that for some
diagnostics to be available, a diagnostics suite package is required.
375 Transducer Block
375 Transducer Block, Diagnostics
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Empty Pipe Detection
Turn the empty pipe diagnostic on or off as required by the application. For
more details on the empty pipe diagnostic, see Appendix C: Diagnostics.
Electronics Temperature Out of Range
Turn the electronics temperature diagnostic on or off as required by the
application. For more details on the electronics temperature diagnostic, see
Appendix C: Diagnostics.
High Process Noise Detection
Turn the high process noise diagnostic on or off as required by the
application. For more details on the high process noise diagnostic, see
Appendix C: Diagnostics.
Grounding / Wiring Fault Detection
Turn the grounding / wiring diagnostic on or off as required by the application.
For more details on the grounding / wiring diagnostic, see Appendix C:
Diagnostics.
Basic Diagnostics The basic diagnostics menu contains all of the standard diagnostics and tests
that are available in the 8732E transmitter.
Empty Pipe Limits
Empty Pipe allows you to view the current value and configure the diagnostic
parameters. For more detail on this parameter see Appendix C: Diagnostics.
EP Value
Read the current Empty Pipe Value. This number is a unitless number and is
calculated based on multiple installation and process variables. For more
detail on this parameter see Appendix C: Diagnostics.
375 Transducer Block, Diagnostics
375 Transducer Block, Diagnostics, Basic Diagnostics
375 Transducer Block, Diagnostics, Basic Diagnostics, Empty Pipe Limits
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EP Trigger Level
Limits: 3 to 2000
Configure the threshold limit that the empty pipe value must exceed before
the diagnostic alert activates. Default from the factory is set to 100. For more
detail on this parameter see Appendix C: Diagnostics.
EP Counts
Limits: 5 to 50
Configure the number of consecutive times that the empty pipe value must
exceed the empty pipe trigger level before the diagnostic alert activates.
Counts are taken at 1.5 second intervals. Default from the factory is set to 5.
For more detail on this parameter see Appendix C: Diagnostics.
Electronics Temp Value
Electronics Temperature allows you to view the current value for the
electronics temperature.
Advanced Diagnostics The advanced diagnostics menu contains information on all of the additional
diagnostics and tests that are available in the 8732 transmitter if one of the
diagnostics suite packages was ordered.
Rosemount offers two advanced diagnostic suites. Functionality under this
menu will depend on which of these suites are ordered.
Advanced diagnostics suite option one (D01 option) contains advanced
diagnostics for High Process Noise detection and Grounding and Wiring fault
detection.
Advanced diagnostics suite option two (D02 option) contains advanced
diagnostics for the 8714i Meter Verification. This diagnostic is used to verify
the accuracy and performance of the magnetic flow meter installation.
8714i Meter Verification
This diagnostic allows you to test and verify that the sensor, transmitter, or
both are working within specifications. For more details on this diagnostic, see
Appendix C: Diagnostics.
Run 8714i
Run the meter verification test to check the transmitter, sensor, or entire
installation.
Full Meter Verification
Run the internal meter verification to check the entire installation, sensor and
transmitter at the same time.
Transmitter Only
Run the internal meter verification to check the transmitter only.
Sensor Only
Run the internal meter verification to check the sensor only.
375 Transducer Block, Diagnostics, Basic Diagnostics, Empty Pipe Limits
375 Transducer Block, Diagnostics, Basic Diagnostics, Empty Pipe Limits
375 Transducer Block, Diagnostics, Basic Diagnostics
375 Transducer Block, Diagnostics
375 Transducer Block, Diagnostics, Advanced Diagnostics
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8714i Results
Review the results of the most recently performed 8714i Meter Verification
test. Information in this section details the measurements taken and if the
meter passed the verification test. For more details on these results and what
they mean, see Appendix C: Diagnostics.
Test Condition
Displays the conditions that the 8714i Meter Verification test was performed
under. For more details on this parameter see Appendix C: Diagnostics.
Test Criteria
Displays the criteria that the 8714i Meter Verification test was performed
against. For more details on this parameter see Appendix C: Diagnostics.
8714i Result
Displays the results of the 8714i Meter Verification test as pass or fail. For
more details on this parameter see Appendix C: Diagnostics.
Simulated Velocity
Displays the test velocity used to verify transmitter calibration. For more
details on this parameter see Appendix C: Diagnostics.
Actual Velocity
Displays the velocity measured by the transmitter during the transmitter
calibration verification test. For more details on this parameter see
Appendix C: Diagnostics.
Velocity Deviation
Displays the deviation of the transmitter calibration verification test. For more
details on this parameter see Appendix C: Diagnostics.
Transmitter Calibration Result
Displays the result of the transmitter calibration verification test as pass or fail.
For more details on this parameter see Appendix C: Diagnostics.
Sensor Calibration Deviation
Displays the deviation of the sensor calibration verification test. For more
details on this parameter see Appendix C: Diagnostics.
375 Transducer Block, Diagnostics, Advanced Diagnostics, 8714i Meter Verification
375 Transducer Block, Diagnostics, Advanced Diagnostics, 8714i Meter Verification,
8714i Results
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8714i Results
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8714i Results
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8714i Results
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8714i Results
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8714i Results
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8714i Results
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8714i Results
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Rosemount 8732
Sensor Calibration Result
Displays the result of the sensor calibration verification test as pass or fail. For
more details on this parameter see Appendix C: Diagnostics.
Coil Circuit Result
Displays the result of the coil circuit test as pass or fail. For more details on
this parameter see Appendix C: Diagnostics.
Electrode Circuit Result
Displays the result of the electrode circuit test as pass or fail. For more details
on this parameter see Appendix C: Diagnostics.
Sensor Signature
The sensor signature describes the sensor characteristics to the transmitter
and is an integral part of the sensor meter verification test. From this menu
you can view the current stored signature, have the transmitter take and store
the sensor signature, and re-call the last saved good values for the sensor
signature. For more details on this parameter see Appendix C: Diagnostics.
Signature Values
Review the current values stored for the sensor signature. For more details on
this parameter see Appendix C: Diagnostics.
Coil Resistance
View the reference value for the coil resistance taken during the sensor
signature process.
Coil Signature
View the reference value for the coil signature taken during the sensor
signature process.
Electrode Resistance
View the reference value for the electrode resistance taken during the sensor
signature process.
375 Transducer Block, Diagnostics, Advanced Diagnostics, 8714i Meter Verification,
8714i Results
375 Transducer Block, Diagnostics, Advanced Diagnostics, 8714i Meter Verification,
8714i Results
375 Transducer Block, Diagnostics, Advanced Diagnostics, 8714i Meter Verification,
8714i Results
375 Transducer Block, Diagnostics, Advanced Diagnostics, 8714i Meter Verification
375 Transducer Block, Diagnostics, Advanced Diagnostics, 8714i Meter Verification,
Sensor Signature
375 Transducer Block, Diagnostics, Advanced Diagnostics, 8714i Meter Verification,
Sensor Signature, Signature Values
375 Transducer Block, Diagnostics, Advanced Diagnostics, 8714i Meter Verification,
Sensor Signature, Signature Values
375 Transducer Block, Diagnostics, Advanced Diagnostics, 8714i Meter Verification,
Sensor Signature, Signature Values
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Re-Signature Meter
Have the transmitter measure and store the sensor signature values. These
values will then be used as the baseline for the meter verification test. Use
this when connecting to older Rosemount or competitors’ sensors or installing
the magnetic flowmeter system for the first time. For more details on this
parameter see Appendix C: Diagnostics.
Recall Last Saved Values
Recalls the last saved “good” values for the sensor signature.
Set Pass/Fail Criteria
Set the maximum allowable deviation percentage test criteria for the 8714i
Meter Verification test. There are three tests that this criteria can be set for:
Full Pipe; No Flow (Best test condition) – Default is 2%
Full Pipe; Flowing – Default is 3%
Empty Pipe – Default is 5%
NOTE
If the 8714i Meter Verification test is done with an empty pipe, the electrode
circuit will NOT be tested.
No Flow Limit
Limits: 1 to 10 percent
Set the pass/fail test criteria for the 8714i Meter Verification test at Full Pipe,
No Flow conditions.
Flowing Limit
Limits: 1 to 10 percent
Set the pass/fail test criteria for the 8714i Meter Verification test at Full Pipe,
Flowing conditions.
Empty Pipe Limit
Limits: 1 to 10 percent
Set the pass/fail test criteria for the 8714i Meter Verification test at Empty Pipe
conditions.
375 Transducer Block, Diagnostics, Advanced Diagnostics, 8714i Meter Verification,
Sensor Signature
375 Transducer Block, Diagnostics, Advanced Diagnostics, 8714i Meter Verification,
Sensor Signature
375 Transducer Block, Diagnostics, Advanced Diagnostics, 8714i Meter Verification
375 Transducer Block, Diagnostics, Advanced Diagnostics, 8714i Meter Verification,
Set Pass/Fail Criteria
375 Transducer Block, Diagnostics, Advanced Diagnostics, 8714i Meter Verification,
Set Pass/Fail Criteria
375 Transducer Block, Diagnostics, Advanced Diagnostics, 8714i Meter Verification,
Set Pass/Fail Criteria
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Rosemount 8732
Measurements
View the measured values taken during the meter verification process. These
values are compared to the signature values to determine if the test passes or
fails. Values are shown for the Coil Resistance, Coil Signature, and Electrode
Resistance.
Coil Resistance
View the measured value for the coil resistance taken during the meter
verification test.
Coil Signature
View the measured value for the coil signature taken during the meter
verification test.
Electrode Resistance
View the measured value for the electrode resistance taken during the meter
verification test.
Licensing
If a diagnostic suite was not ordered initially, advanced diagnostics can be
licensed in the field. Access the licensing information from this menu. For
more details on licensing, see Appendix C: Diagnostics.
License Status
Determine if a diagnostics suite has been licensed, and if so, which
diagnostics are available for activation.
License Key
A license key is required to activate diagnostics in the field if the diagnostic
suite was not initially ordered. This menu allows for gathering of necessary
data to generate a license key and also the ability to enter the license key
once it has been received.
Device ID
This function displays the Device ID and Software Revision for the transmitter.
Both of these pieces of information are required to generate a license key.
License Key
Allows you to enter a license key to activate a diagnostic suite.
375 Transducer Block, Diagnostics, Advanced Diagnostics, 8714i Meter Verification
375 Transducer Block, Diagnostics, Advanced Diagnostics, 8714i Meter Verification,
measurements
375 Transducer Block, Diagnostics, Advanced Diagnostics, 8714i Meter Verification,
measurements
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measurements
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375 Transducer Block, Diagnostics, Advanced Diagnostics, Licensing
375 Transducer Block, Diagnostics, Advanced Diagnostics, Licensing
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375 Transducer Block, Diagnostics, Advanced Diagnostics, Licensing, License Key
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Diagnostic Variables From this menu, all of the diagnostic variable values can be reviewed. This
information can be used to get more information about the transmitter, sensor,
and process, or to get more detail about an alert that may have activated.
Empty Pipe Value
Read the current value of the Empty Pipe parameter. This value will read zero
if Empty Pipe is turned off.
Electronics Temperature
Read the current value of the Electronics Temperature.
Line Noise
Read the current value of the amplitude of AC line noise measured on the
transmitter’s electrode inputs. This value is used in the grounding / wiring
diagnostic.
5Hz SNR
Read the current value of the signal to noise ratio at 5 Hz. For optimum
performance, a value greater than 100 is preferred. Values less than 25 will
cause the High Process Noise alert to activate.
37Hz SNR
Read the current value of the signal to noise ratio at 37.5 Hz. For optimum
performance, a value greater than 100 is preferred. Values less than 25 will
cause the High Process Noise alert to activate.
Signal Power
Read the current value of the velocity of the fluid through the sensor. Higher
velocities result in greater signal power.
8714i Results
Review the results of the 8714i Meter Verification tests. For more details on
these results and what they mean, see Appendix C: Diagnostics.
Test Condition
Displays the conditions that the 8714i Meter Verification test was performed
under. For more details on this parameter see Appendix C: Diagnostics.
Test Criteria
Displays the criteria that the 8714i Meter Verification test was performed
against. For more details on this parameter see Appendix C: Diagnostics.
375 Transducer Block, Diagnostics
375 Transducer Block, Diagnostics, Diagnostic Variables
375 Transducer Block, Diagnostics, Diagnostic Variables
375 Transducer Block, Diagnostics, Diagnostic Variables
375 Transducer Block, Diagnostics, Diagnostic Variables
375 Transducer Block, Diagnostics, Diagnostic Variables
375 Transducer Block, Diagnostics, Diagnostic Variables
375 Transducer Block, Diagnostics, Diagnostic Variables
375 Transducer Block, Diagnostics, Diagnostic Variables, 8714i Results
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Rosemount 8732
8714i Result
Displays the results of the 8714i Meter Verification test as pass or fail. For
more details on this parameter see Appendix C: Diagnostics.
Simulated Velocity
Displays the test velocity used to verify transmitter calibration. For more
details on this parameter see Appendix C: Diagnostics.
Actual Velocity
Displays the velocity measured by the transmitter during the transmitter
calibration verification test. For more details on this parameter see
Appendix C: Diagnostics.
Velocity Deviation
Displays the deviation of the transmitter calibration verification test. For more
details on this parameter see Appendix C: Diagnostics.
Transmitter Calibration Result
Displays the result of the transmitter calibration verification test as pass or fail.
For more details on this parameter see Appendix C: Diagnostics.
Sensor Calibration Deviation
Displays the deviation of the sensor calibration verification test. For more
details on this parameter see Appendix C: Diagnostics.
Sensor Calibration Result
Displays the result of the sensor calibration verification test as pass or fail. For
more details on this parameter see Appendix C: Diagnostics.
Coil Circuit Result
Displays the result of the coil circuit test as pass or fail. For more details on
this parameter see Appendix C: Diagnostics.
Electrode Circuit Result
Displays the result of the electrode circuit test as pass or fail. For more details
on this parameter see Appendix C: Diagnostics.
Trims Trims are used to calibrate the analog loop, calibrate the transmitter, re-zero
the transmitter, and calibrate the transmitter with another manufacturer’s
sensor. Proceed with caution whenever performing a trim function.
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375 Transducer Block, Diagnostics, Diagnostic Variables, 8714i Results
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375 Transducer Block, Diagnostics, Diagnostic Variables, 8714i Results
375 Transducer Block, Diagnostics
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Electronics Trim
Electronics trim is the function by which the factory calibrates the transmitter.
This procedure is rarely needed by customers. It is only necessary if you
suspect the Rosemount 8732E is no longer accurate. A Rosemount 8714
Calibration Standard is required to complete a digital trim. Attempting an
Electronics trim without a Rosemount 8714 Calibration Standard may result in
an inaccurate transmitter or an error message. Electronics trim must be
performed only with the coil drive mode set to 5 Hz and with a nominal sensor
calibration number stored in the memory.
NOTE
Attempting an Electronics trim without a Rosemount 8714 may result in an
inaccurate transmitter, or a “DIGITAL TRIM FAILURE” message may appear.
If this message occurs, no values were changed in the transmitter. Simply
power down the Rosemount 8732E to clear the message.
To simulate a nominal sensor with the Rosemount 8714, you must change the
following five parameters in the Rosemount 8732E:
1. Sensor Calibration Number—1000015010000000
2. Units—ft/s
3. PV URV—AI EU at 100 = 30.00 ft/s
4. PV LRV—AI EU at 0 = 0 ft/s
5. Coil Drive Frequency—5 Hz
The instructions for changing the Sensor Calibration Number, Units, PV URV,
and PV LRV are located in “Basic Setup” on page 3-14. Instructions for
changing the Coil Drive Frequency can be found on page 4-12 in this section.
Set the loop to manual, if necessary, before you begin. Complete the following
steps:
1. Power down the transmitter.
2. Connect the transmitter to a Rosemount 8714 sensor simulator.
3. Power up the transmitter with the Rosemount 8714 connected and
read the flow rate. The electronics need about a 5-minute warm-up
time to stabilize.
4. Set the 8714 calibrator to the 30 ft/s setting.
5. The flow rate reading after warm-up should be between 29.97 and
30.03 ft/s.
6. If the reading is within the range, return the transmitter to the original
configuration parameters.
7. If the reading is not within this range, initiate a digital trim with the
Handheld Communicator. The digital trim takes about 90 seconds to
complete. No transmitter adjustments are required.
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January 2010
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Rosemount 8732
Auto Zero
The auto zero function initializes the transmitter for use with the 37 Hz coil
drive mode only. Run this function only with the transmitter and sensor
installed in the process. The sensor must be filled with process fluid at zero
flow. Before running the auto zero function, be sure the coil drive mode is set
to 37 Hz (Auto Zero will not run with the coil drive frequency set at 5 Hz).
Set the loop to manual if necessary and begin the auto zero procedure. The
transmitter completes the procedure automatically in about 90 seconds. A
symbol appears in the lower right-hand corner of the display to indicate that
the procedure is running.
Universal Trim
The universal auto trim function enables the Rosemount 8732E to calibrate
sensors that were not calibrated at the Rosemount factory. The function is
activated as one step in a procedure known as in-process calibration. If your
Rosemount sensor has a 16-digit calibration number, in-process calibration is
not required. If it does not, or if your sensor is made by another manufacturer,
complete the following steps for in-process calibration.
1. Determine the flow rate of the process fluid in the sensor.
NOTE
The flow rate in the line can be determined by using another sensor in the
line, by counting the revolutions of a centrifugal pump, or by performing a
bucket test to determine how fast a given volume is filled by the process fluid.
2. Complete the universal auto trim function.
3. When the routine is completed, the sensor is ready for use.
Status Review status information regarding the operation of the transducer block.
This is where additional information can be reviewed regarding transmitter
health and diagnostic messages.
375 Transducer Block, Diagnostics, Trims
375 Transducer Block, Diagnostics, Trims
375 Transducer Block, Diagnostics
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January 2010
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4-12
ADVANCED
CONFIGURATION In addition to the basic configuration options and the diagnostic information
and controls, the 8732 has many advanced functions that can also be
configured as required by the application.
DETAILED SETUP The detailed setup function provides access to other parameters within the
transmitter that can be configured such as coil drive frequency, output
parameters, local display configuration, and other general information about
the device.
Additional Parameters The additional parameters menu provides a means to configure optional
parameters within the 8732E transmitter.
Coil Drive Frequency
Coil drive frequency allows pulse-rate selection of the sensor coils.
5 Hz
The standard coil drive frequency is 5 Hz, which is sufficient for nearly all
applications.
37 Hz
If the process fluid causes a noisy or unstable output, increase the coil drive
frequency to 37 Hz. If the 37 Hz mode is selected, perform the auto zero
function.
Density Value
The density value is used to convert from a volumetric flow rate to a mass flow
rate using the following equation:
Qm = Qv
Where:
Qm is the mass flow rate
Qv is the volumetric flow rate, and
is the fluid density
NOTE
A density value is required to configure the flow units for mass flow rate
measurement.
Sensor Range: EU at 100%
This parameter is the maximum value that the PV Range value can be set to.
This is the upper measuring limit of the transmitter and sensor.
Sensor Range: EU at 0%
This parameter is the minimum value that the PV Range value can be set to.
This is the lower measuring limit of the transmitter and sensor.
375 Transducer Block
375 Transducer Block, Detailed
Setup
375 Transducer Block, Detailed Setup, Additional Params
375 Transducer Block, Detailed Setup, Additional Params
375 Transducer Block, Detailed Setup, Additional Params
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Rosemount 8732
Cal Min Span
The PV minimum span is the minimum flow range that must separate the
minimum and maximum configured PV Range values.
Reverse Flow
Enable or disable the transmitter’s ability to read reverse flow.
Reverse Flow allows the transmitter to read negative flow. This may occur
when flow in the pipe is going the negative direction, or when either electrode
wires or coil wires are reversed. This also enables the totalizer to count in the
reverse direction.
Display Language This allows you to configure the language shown on the display. There are
five options available:
• English
• Spanish
• Portuguese
•German
•French
Signal Processing The 8732E contains several advanced functions that can be used to stabilize
erratic outputs caused by process noise. The signal processing menu
contains this functionality.
Operating Mode
The Operating Mode should be used only when the signal is noisy and gives
an unstable output. Filter mode automatically uses 37 Hz coil drive mode and
activates signal processing at the factory set default values. When using filter
mode, perform an auto zero with no flow and a full sensor. Either of the
parameters, coil drive mode or signal processing, may still be changed
individually. Turning Signal Processing off or changing the coil drive frequency
to 5 Hz will automatically change the Operating Mode from filter mode to
normal mode.
Man Config DSP
Manually configure the digital signal processing parameters.
The 8732E transmitter includes digital signal processing capabilities that can
be used to condition the output from the transmitter by enabling noise
rejection. See Appendix D: Digital Signal Processing for more information on
the DSP functionality.
375 Transducer Block, Detailed Setup, Additional Params
375 Transducer Block, Detailed Setup, Additional Params
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Setup
375 Transducer Block, Detailed
Setup
375 Transducer Block, Detailed Setup, Signal Processing
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January 2010
Rosemount 8732
4-14
Control
When ON is selected, the Rosemount 8732E output is derived using a
running average of the individual flow inputs. Signal processing is a software
algorithm that examines the quality of the electrode signal against
user-specified tolerances. This average is updated at the rate of 10 samples
per second with a coil drive frequency of 5 Hz, and 75 samples per second
with a coil drive frequency of 37 Hz. The three parameters that make up
signal processing (number of samples, maximum percent limit, and time limit)
are described below.
Samples
0 to 125 Samples
The number of samples function sets the amount of time that inputs are
collected and used to calculate the average value. Each second is divided
into tenths (1/10) with the number of samples equaling the number of 1/10
second increments used to calculate the average.
For example, a value of:
1 averages the inputs over the past 1/10 second
10 averages the inputs over the past 1 second
100 averages the inputs over the past 10 seconds
125 averages the inputs over the past 12.5 seconds
% Limit
0 to 100 Percent
The maximum percent limit is a tolerance band set up on either side of the
running average. The percentage value refers to deviation from the running
average. For example, if the running average is 100 gal/min, and a 2 percent
maximum limit is selected, then the acceptable range is from 98 to 102
gal/min.
Values within the limit are accepted while values outside the limit are analyzed
to determine if they are a noise spike or an actual flow change.
Time Limit
0 to 256 Seconds
The time limit parameter forces the output and running average values to the
new value of an actual flow rate change that is outside the percent limit
boundaries. It thereby limits response time to flow changes to the time limit
value rather than the length of the running average.
375 Transducer Block, Detailed Setup, Signal Processing, Man Config DSP
375 Transducer Block, Detailed Setup, Signal Processing, Man Config DSP
375 Transducer Block, Detailed Setup, Signal Processing, Man Config DSP
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January 2010
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Rosemount 8732
For example, if the number of samples selected is 100, then the response
time of the system is 10 seconds. In some cases this may be unacceptable.
By setting the time limit, you can force the 8732E to clear the value of the
running average and re-establish the output and average at the new flow rate
once the time limit has elapsed. This parameter limits the response time
added to the loop. A suggested time limit value of two seconds is a good
starting point for most applicable process fluids. The selected signal
processing configuration may be turned ON or OFF to suit your needs.
Coil Drive Frequency
Coil drive frequency allows pulse-rate selection of the sensor coils.
5 Hz
The standard coil drive frequency is 5 Hz, which is sufficient for nearly all
applications.
37 Hz
If the process fluid causes a noisy or unstable output, increase the coil drive
frequency to 37 Hz. If the 37 Hz mode is selected, perform the auto zero
function with no flow and a full sensor.
Low Flow Cutoff
Low flow cutoff allows you to specify the flow rate, between 0.01 and 38.37
feet per second, below which the outputs are driven to zero flow. The units
format for low flow cutoff cannot be changed. It is always displayed as feet per
second regardless of the format selected. The low flow cutoff value applies to
both forward and reverse flows.
Primary Variable Damping
0 to 256 Seconds
Primary Variable Damping allows selection of a response time, in seconds, to
a step change in flow rate. It is most often used to smooth fluctuations in
output.
Device Info Information variables are used for identification of flowmeters in the field and
to store information that may be useful in service situations. Information
variables have no effect on flowmeter output or process variables.
Device ID
This function displays the Device ID of the transmitter. This is one piece of
information required to generate a license code to enable diagnostics in the
field.
PV Sensor S/N
The PV sensor serial number is the serial number of the sensor connected to
the transmitter and can be stored in the transmitter configuration for future
reference. The number provides easy identification if the sensor needs
servicing or for other purposes.
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375 Transducer Block, Detailed Setup, Signal Processing
375 Transducer Block, Detailed Setup, Signal Processing
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Setup
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Sensor Tag
Sensor tag is the quickest and shortest way of identifying and distinguishing
between sensors. Sensors can be tagged according to the requirements of
your application. The tag may be up to eight characters long.
DSP Software Rev
This function displays the software revision number of the transmitter.
Construction Materials
Construction materials contain information about the sensor that is connected
to the transmitter. This information is configured into the transmitter for later
reference. This information can be helpful when calling the factory for support.
Flange Type
Flange type enables you to select the flange type for your magnetic
transmitter system. This variable only needs to be changed if you have
changed your sensor. Options for this value are:
Flange Material
Flange material enables you to select the flange material for your magnetic
transmitter system. This variable only needs to be changed if you have
changed your sensor. Options for this value are:
Carbon Steel
304L Stainless Steel
316L Stainless Steel
• Wafer
•Other
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375 Transducer Block, Detailed Setup, Device Info
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ANSI 150 PN 10
ANSI 300 •PN 16
ANSI 600 PN 25
ANSI 900 •PN 40
ANSI 1500 PN 64
ANSI 2500 • Other
•Wafer
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Rosemount 8732
Electrode Type
Electrode type enables you to select the electrode type for your magnetic
transmitter system. This variable only needs to be changed if you have
replaced electrodes or if you have replaced your sensor. Options for this value
are:
• Standard
Std & Ground
• Bullet
•Other
Electrode Material
Electrode Material enables you to select the electrode material for your
magnetic transmitter system. This variable only needs to be changed if you
have replaced electrodes or if you have replaced your sensor. Options for this
value are:
316L SST
Nickel Alloy 276 (UNS N10276)
•Tantalum
Titanium
80% Platinum – 20% Iridium
Alloy 20
•Other
Liner Material
Liner material enables you to select the liner material for the attached sensor.
This variable only needs to be changed if you have replaced your sensor.
Options for this value are:
• PTFE
• ETFE
•PFA
• Polyurethane
• Linatex
Natural Rubber
• Neoprene
•Other
MODE Set and review the mode configuration for the transducer function block.
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Block Mode: Target Operator requested mode for the function block. Only one selection may be
made. Options include:
Auto
Use this mode when all configuration changes to the block are complete and
the transmitter is ready to be returned to service.
OOS
Out of service mode. Use this mode when making configuration changes to
parameters found in the function block. This removes the transmitter from
operation until the mode is set back to Auto.
Block Mode: Actual This is the current mode of the function block. This mode may differ from the
Target mode based on operating conditions.
Block Mode: Permitted This parameter defines which modes are available for a given function block.
Block Mode: Normal Displays the mode that the function block should be set to for normal
operation.
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January 2010 Rosemount 8732
www.rosemount.com
Section 5 Sensor Installation
Safety Messages . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . page 5-1
Sensor Handling . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . page 5-3
Sensor Mounting . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . page 5-4
Installation (Flanged Sensor) . . . . . . . . . . . . . . . . . . . . . . page 5-7
Installation (Wafer Sensor) . . . . . . . . . . . . . . . . . . . . . . . . page 5-10
Installation (Sanitary Sensor) . . . . . . . . . . . . . . . . . . . . . . page 5-12
Grounding . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . page 5-12
Process Leak Protection (Optional) . . . . . . . . . . . . . . . . . page 5-16
This section covers the steps required to physically install the magnetic
sensor. For electrical connections and cabling see Section 2: "Installation".
Instructions and procedures in this section may require special precautions to
ensure the safety of the personnel performing the operations. Please refer to
the following safety messages before performing any operation in this section.
SAFETY MESSAGES This symbol is used throughout this manual to indicate that special attention
to warning information is required.
Failure to follow these installation guidelines could result in death or serious injury:
Installation and servicing instructions are for use by qualified personnel only. Do not perform
any servicing other than that contained in the operating instructions, unless qualified. Verify
that the operating environment of the sensor and transmitter is consistent with the
appropriate hazardous area approval.
Do not connect a Rosemount 8732 to a non-Rosemount sensor that is located in an
explosive atmosphere.
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January 2010
Rosemount 8732
5-2
Explosions could result in death or serious injury:
Installation of this transmitter in an explosive environment must be in accordance with the
appropriate local, national, and international standards, codes, and practices. Please review
the approvals section of the 8732 reference manual for any restrictions associated with a
safe installation.
Before connecting a Field Communicator in an explosive atmosphere, make sure the
instruments in the loop are installed in accordance with intrinsically safe or non-incendive
field wiring practices.
Electrical shock can result in death or serious injury
Avoid contact with the leads and terminals. High voltage that may be present on leads can
cause electrical shock.
The sensor liner is vulnerable to handling damage. Never place anything through the sensor
for the purpose of lifting or gaining leverage. Liner damage can render the sensor useless.
To avoid possible damage to the sensor liner ends, do not use metallic or spiral-wound
gaskets. If frequent removal is anticipated, take precautions to protect the liner ends. Short
spool pieces attached to the sensor ends are often used for protection.
Correct flange bolt tightening is crucial for proper sensor operation and life. All bolts must be
tightened in the proper sequence to the specified torque limits. Failure to observe these
instructions could result in severe damage to the sensor lining and possible sensor
replacement.
Emerson Process Management can supply lining protectors to prevent liner damage during
removal, installation, and excessive bolt torquing.
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Rosemount 8732
SENSOR HANDLING Handle all parts carefully to prevent damage. Whenever possible, transport
the system to the installation site in the original shipping containers.
PTFE-lined sensors are shipped with end covers that protect it from both
mechanical damage and normal unrestrained distortion. Remove the end
covers just before installation.
Flanged 6- through 36-inch sensors come with a lifting lug on each flange.
The lifting lugs make the sensor easier to handle when it is transported and
lowered into place at the installation site.
Flanged ½- to 4-inch sensors do not have lugs. They must be supported with
a lifting sling on each side of the housing.
Figure 5-1 shows sensors correctly supported for handling and installation.
Notice the plywood end pieces are still in place to protect the sensor liner
during transportation.
Figure 5-1. Rosemount 8705
Sensor Support for Handling
See ”Safety Messages” on pages 5-1 and 5-2 for complete warning information.
½- through 4-Inch
Sensors 6-Inch and Larger
Sensors
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5-4
SENSOR MOUNTING Physical mounting of a sensor is similar to installing a typical section of pipe.
Conventional tools, equipment, and accessories (bolts, gaskets, and
grounding hardware) are required.
Upstream/Downstream
Piping To ensure specification accuracy over widely varying process conditions,
install the sensor a minimum of five straight pipe diameters upstream and two
pipe diameters downstream from the electrode plane (see Figure 5-2).
Figure 5-2. Upstream and
Downstream
Straight Pipe Diameters
Sensor Orientation The sensor should be installed in a position that ensures the sensor remains
full during operation. Figures 5-3, 5-4, and 5-5 show the proper sensor
orientation for the most common installations. The following orientations
ensure that the electrodes are in the optimum plane to minimize the effects of
entrapped gas.
Vertical installation allows upward process fluid flow and is generally
preferred. Upward flow keeps the cross-sectional area full, regardless
of flow rate. Orientation of the electrode plane is unimportant in vertical
installations. As illustrated in Figures 5-3 and 5-4, avoid downward flows
where back pressure does not ensure that the sensor remains full at all times.
Installations with reduced straight runs from 0 to five pipe diameters are
possible. In reduced straight pipe run installations, performance will shift to as
much as 0.5% of rate. Reported flow rates will still be highly repeatable.
Figure 5-3. Vertical Sensor
Orientation
FLOW
5 Pipe Diameters 2 Pipe Diameters
FLOW
FLOW
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Rosemount 8732
Figure 5-4. Incline or Decline
Orientation
Horizontal installation should be restricted to low piping sections that are
normally full. Orient the electrode plane to within 45 degrees of horizontal in
horizontal installations. A deviation of more than 45 degrees of horizontal
would place an electrode at or near the top of the sensor thereby making it
more susceptible to insulation by air or entrapped gas at the top of the
sensor.
Figure 5-5. Horizontal Sensor
Orientation
FLOW
FLOW
FLOW
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5-6
The electrodes in the Rosemount 8711 are properly oriented when the top of
the sensor is either vertical or horizontal, as shown in Figure 5-6. Avoid any
mounting orientation that positions the top of the sensor at 45 degrees from
the vertical or horizontal position.
Figure 5-6. Rosemount 8711
Mounting Position
Flow Direction The sensor should be mounted so that the FORWARD end of the flow arrow,
shown on the sensor identification tag, points in the direction of flow through
the sensor (see Figure 5-7).
Figure 5-7. Flow Direction
45° Electrode Plane
45° Electrode Plane
FLOW
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January 2010
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Rosemount 8732
INSTALLATION
(FLANGED SENSOR) The following section should be used as a guide in the installation of the
flange-type Rosemount 8705 and Rosemount 8707 High-Signal Sensors.
Refer to page 5-10 for installation of the wafer-type Rosemount 8711 Sensor.
Gaskets The sensor requires a gasket at each of its connections to adjacent devices or
piping. The gasket material selected must be compatible with the process fluid and
operating conditions. Metallic or spiral-wound gaskets can damage the
liner. If the gaskets will be removed frequently, protect the liner ends. All other
applications (including sensors with lining protectors or a grounding electrode)
require only one gasket on each end connection, as shown in Figure 5-8. If
grounding rings are used, gaskets are required on each side of the grounding
ring, as shown in Figure 5-9.
Figure 5-8. Gasket Placement
Figure 5-9. Gasket Placement
with Non-attached Grounding
Rings
Flange Bolts Suggested torque values by sensor line size and liner type are listed in Table
5-1 on page 5-8 for ASME B16.5 (ANSI) flanges and Table 5-2 and Table 5-3
for DIN flanges. Consult the factory for other flange ratings. Tighten flange
bolts in the incremental sequence as shown in Figure 5-10. See Table 5-1 and
Table 5-2 for bolt sizes and hole diameters.
See ”Safety Messages” on pages 5-1 and 5-2 for complete warning information.
Gasket (Supplied by user)
Gasket (Supplied by user)
Grounding Ring
Gasket (Supplied by user)
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5-8
NOTE
Do not bolt one side at a time. Tighten each side simultaneously. Example:
1. Snug left
2. Snug right
3. Tighten left
4. Tighten right
Do not snug and tighten the upstream side and then snug and tighten the
downstream side. Failure to alternate between the upstream and downstream
flanges when tightening bolts may result in liner damage.
Always check for leaks at the flanges after tightening the flange bolts. Failure
to use the correct flange bolt tightening methods can result in severe damage.
All sensors require a second torquing 24 hours after initial flange bolt
tightening.
Table 5-1. Flange Bolt Torque Specifications for
Rosemount 8705 and 8707 High-Signal Sensors
PTFE/ETFE liner Polyurethane liner
Size Code Line Size Class 150
(pound-feet) Class 300
(pound-feet) Class 150
(pound-feet) Class 300
(pound-feet)
005 1/2-inch (15 mm) 8 8
010 1 inch (25 mm) 812 — —
015 11/2 inch (40 mm) 13 25 7 18
020 2 inch (50 mm) 19 17 14 11
030 3 inch (80 mm) 34 35 23 23
040 4 inch (100 mm) 26 50 17 32
060 6 inch (150mm) 45 50 30 37
080 8 inch (200 mm) 60 82 42 55
100 10 inch (250 mm) 55 80 40 70
120 12 inch (300 mm) 65 125 55 105
140 14 inch (350 mm) 85 110 70 95
160 16 inch (400 mm) 85 160 65 140
180 18 inch (450 mm) 120 170 95 150
200 20 inch (500 mm) 110 175 90 150
240 24 inch (600 mm) 165 280 140 250
300 30 inch (750 mm) 195 415 165 375
360 36 inch (900 mm) 280 575 245 525
See ”Safety Messages” on pages 5-1 and 5-2 for complete warning information.
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Rosemount 8732
Figure 5-10. Flange Bolt
Torquing Sequence
Table 5-2. Flange Bolt Torque and Bolt Load Specifications for Rosemount 8705
PTFE/ETFE liner
Size
Code
PN10 PN 16 PN 25 PN 40
Line Size (Newton-meter) (Newton) (Newton-meter) (Newton) (Newton-meter) (Newton) (Newton-meter) (Newton)
005 1/2-inch (15 mm) 7 3209 7 3809 7 3809 7 4173
010 1 inch (25 mm) 13 6983 13 6983 13 6983 13 8816
015 11/2 inch (40 mm) 24 9983 24 9983 24 9983 24 13010
020 2 inch (50 mm) 25 10420 25 10420 25 10420 25 14457
030 3 inch (80 mm) 14 5935 14 5935 18 7612 18 12264
040 4 inch (100 mm) 17 7038 17 7038 30 9944 30 16021
060 6 inch (150mm) 23 7522 32 10587 60 16571 60 26698
080 8 inch (200 mm) 35 11516 35 11694 66 18304 66 36263
100 10 inch (250 mm) 31 10406 59 16506 105 25835 105 48041
120 12 inch (300 mm) 43 14439 82 22903 109 26886 109 51614
140 14 inch (350 mm) 42 13927 80 22091 156 34578 156 73825
160 16 inch (400 mm) 65 18189 117 28851 224 45158 224 99501
180 18 inch (450 mm) 56 15431 99 24477 67953
200 20 inch (500 mm) 66 18342 131 29094 225 45538 225 73367
240 24 inch (600 mm) 104 25754 202 40850 345 63940 345 103014
4-Bolt 8-Bolt
12-Bolt 14-Bolt
20-Bolt
Torque the flange bolts
in increments according to
the above numerical sequence.
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Rosemount 8732
5-10
INSTALLATION
(WAFER SENSOR) The following section should be used as a guide in the installation of the
Rosemount 8711 Sensor. Refer to page 5-7 for installation of the flange-type
Rosemount 8705 and 8707 High-Signal sensor.
Gaskets The sensor requires a gasket at each of its connections to adjacent devices or
piping. The gasket material selected must be compatible with the process
fluid and operating conditions. Metallic or spiral-wound gaskets can
damage the liner. If the gaskets will be removed frequently, protect the
liner ends. If grounding rings are used, a gasket is required on each side of
the grounding ring.
Alignment and Bolting 1. On 11/2 - through 8-inch (40 through 200 mm) line sizes, place
centering rings over each end of the sensor. The smaller line sizes,
0.15- through 1-inch (4 through 25 mm), do not require centering
rings.
2. Insert studs for the bottom side of the sensor between the pipe
flanges. Stud specifications are listed in Table 5-4. Using carbon
steel bolts on smaller line sizes, 0.15- through 1-inch
(4 through 25 mm), rather than the required stainless steel bolts,
will degrade performance.
Table 5-3. Flange Bolt Torque and Bolt Load Specifications for Rosemount 8705
Size
Code Line Size
Polyurethane Liner
PN 10 PN 16 PN 25 PN 40
(Newton-meter) (Newton) (Newton-meter) (Newton) (Newton-meter) (Newton) (Newton-meter) (Newton)
005 1/2-inch (15 mm) 1 521 1 826 2 1293 6 3333
010 1 inch (25 mm) 21191 31890 52958 10 5555
015 11/2 inch (40 mm) 5 1960 7 3109 12 4867 20 8332
020 2 inch (50 mm) 62535 10 4021 15 6294 26 10831
030 3 inch (80 mm) 5 2246 9 3563 13 5577 24 19998
040 4 inch (100 mm) 73033 12 4812 23 7531 35 11665
060 6 inch (150mm) 16 5311 25 8425 47 13186 75 20829
080 8 inch (200 mm) 27 8971 28 9487 53 14849 100 24687
100 10 inch (250 mm) 26 8637 49 13700 87 21443 155 34547
120 12 inch (300 mm) 36 12117 69 19220 91 22563 165 36660
140 14 inch (350 mm) 35 11693 67 18547 131 29030 235 47466
160 16 inch (400 mm) 55 15393 99 24417 189 38218 335 62026
200 20 inch (500 mm) 58 15989 114 25361 197 39696 375 64091
240 24 inch (600 mm) 92 22699 178 36006 304 56357 615 91094
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Rosemount 8732
3. Place the sensor between the flanges. Make sure that the centering
rings are properly placed in the studs. The studs should be aligned
with the markings on the rings that correspond to the flange you are
using.
4. Insert the remaining studs, washers, and nuts.
5. Tighten to the torque specifications shown in Table 5-5. Do not
overtighten the bolts or the liner may be damaged.
NOTE
On the 4- and 6- inch PN 10-16, insert the sensor with rings first and then
insert the studs. The slots on this ring scenario are located on the inside of the
ring.
Figure 5-11. Gasket Placement
with Centering Rings
Flange Bolts Sensor sizes and torque values for both Class 150 and Class 300 flanges are
listed in Table 5-5. Tighten flange bolts in the incremental sequence, shown in
Figure 5-10.
NOTE
Do not bolt one side at a time. Tighten each side simultaneously. Example:
1. Snug left
2. Snug right
3. Tighten left
4. Tighten right
Do not snug and tighten the upstream side and then snug and tighten the
downstream side. Failure to alternate between the upstream and downstream
flanges when tightening bolts may result in liner damage.
Always check for leaks at the flanges after tightening the flange
bolts. All sensors require a second torquing 24 hours after initial flange bolt
tightening.
Table 5-4. Stud Specifications
Nominal Sensor Size Stud Specifications
0.15 – 1 inch (4 – 25 mm) 316 SST ASTM A193, Grade B8M
Class 1 threaded mounted studs
11/2 – 8 inch (40 – 200 mm) CS, ASTM A193, Grade B7, threaded mounting studs
Customer-supplied
Gasket
FLOW
Installation, Studs
Nuts and Washers
Centering Rings
See ”Safety Messages” on pages 5-1 and 5-2 for complete warning information.
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January 2010
Rosemount 8732
5-12
INSTALLATION
(SANITARY SENSOR)
Gaskets The sensor requires a gasket at each of its connections to adjacent devices or
piping. The gasket material selected must be compatible with the process
fluid and operating conditions. Gaskets are supplied with all Rosemount 8721
Sanitary sensors except when the process connection is an IDF sanitary
screw type.
Alignment and Bolting Standard plant practices should be followed when installing a magmeter with
sanitary fittings. Unique torque values and bolting techniques are not
required.
Figure 5-12. Rosemount 8721
Sanitary Installation
Process grounding the sensor is one of the most important details of sensor
installation. Proper process grounding ensures that the transmitter amplifier is
referenced to the process. This creates the lowest noise environment for the
transmitter to make a stable reading. Use Table 5-6 to determine which
grounding option to follow for proper installation.
Table 5-5. Flange bolt Torque Specifications of Rosemount 8711 Sensors
Size Code Line Size Pound-feet Newton-meter
15F 0.15 inch (4 mm) 5 6.8
30F 0.30 inch (8 mm) 56.8
005 1/2-inch (15 mm) 5 6.8
010 1 inch (25 mm) 10 13.6
015 11/2 inch (40 mm) 15 20.5
020 2 inch (50 mm) 25 34.1
030 3 inch (80 mm) 40 54.6
040 4 inch (100 mm) 30 40.1
060 6 inch (150 mm) 50 68.2
080 8 inch (200 mm) 70 81.9
User supplied clamp
User supplied gasket
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Rosemount 8732
NOTE
Consult factory for installations requiring cathodic protection or situations
where there are high currents or high potential in the process.
The sensor case should always be earth grounded in accordance with
national and local electrical codes. Failure to do so may impair the protection
provided by the equipment. The most effective grounding method is direct
connection from the sensor to earth ground with minimal impedance.
The Internal Ground Connection (Protective Ground Connection) located in
side the junction box is the Internal Ground Connection screw. This screw is
identified by the ground symbol:
Figure 5-13. No Grounding
Options or Grounding Electrode
in Lined Pipe
Table 5-6. Grounding Installation
Grounding Options
Type of Pipe No Grounding Options Grounding Rings Grounding Electrodes Lining Protectors
Conductive Unlined Pipe See Figure 5-13 Not Required Not Required See Figure 5-14
Conductive Lined Pipe Insufficient Grounding See Figure 5-14 See Figure 5-13 See Figure 5-14
Non-Conductive Pipe Insufficient Grounding See Figure 5-15 See Figure 5-16 See Figure 5-15
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5-14
Figure 5-14. Grounding with
Grounding Rings or Lining
Protectors
Figure 5-15. Grounding with
Grounding Rings or Lining
Protectors
Grounding Rings or
Lining Protectors
Grounding Rings or
Lining Protectors
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Rosemount 8732
Figure 5-16. Grounding with
Grounding Electrodes
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January 2010
Rosemount 8732
5-16
PROCESS LEAK
PROTECTION
(OPTIONAL)
The Rosemount 8705 and 8707 High-Signal Sensor housing is fabricated
from carbon steel to perform two separate functions. First, it provides
shielding for the sensor magnetics so that external disturbances cannot
interfere with the magnetic field and thus affect the flow measurement.
Second, it provides the physical protection to the coils and other internal
components from contamination and physical damage that might occur in an
industrial environment. The housing is completely welded and gasket-free.
The three housing configurations are identified by the W0, W1, or W3 in the
model number option code when ordering. Below are brief descriptions of
each housing configuration, which are followed by a more detailed overview.
Code W0 — sealed, welded coil housing (standard configuration)
Code W1 — sealed, welded coil housing with a relief valve capable of
venting fugitive emissions to a safe location (additional plumbing from
the sensor to a safe area, installed by the user, is required to vent
properly)
Code W3 — sealed, welded coil housing with separate electrode
compartments capable of venting fugitive emissions (additional
plumbing from the sensor to a safe area, installed by the user, is
required to vent properly)
Standard Housing
Configuration The standard housing configuration is identified by a code W0 in the model
number. This configuration does not provide separate electrode
compartments with external electrode access. In the event of a process leak,
these models will not protect the coils or other sensitive areas around the
sensor from exposure to the pressure fluid (Figure 5-17).
Figure 5-17. Standard Housing
Configuration — Sealed Welded
Housing (Option Code W0)
1/2–14 NPT Conduit
Connection
(no relief valve)
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Rosemount 8732
Relief Valves The first optional configuration, identified by the W1 in the model number
option code, uses a completely welded coil housing. This configuration does
not provide separate electrode compartments with external electrode access.
This optional housing configuration provides a relief valve in the housing to
prevent possible overpressuring caused by damage to the lining or other
situations that might allow process pressure to enter the housing. The relief
valve will vent when the pressure inside the sensor housing exceeds 5 psi.
Additional piping (provided by the user) may be connected to this relief valve
to drain any process leakage to safe containment (see Figure 5-18).
Figure 5-18. Coil-Housing
Configuration — Standard
Welded Housing With Relief
Valve (Option Code W1)
Process Leak
Containment The second optional configuration, identified as option code W3 in the model
number, divides the coil housing into three compartments: one for each
electrode and one for the coils. Should a damaged liner or electrode fault
allow process fluid to migrate behind the electrode seals, the fluid is contained
in the electrode compartment. The sealed electrode compartment prevents
the process fluid from entering the coil compartment where it would damage
the coils and other internal components.
The electrode compartments are designed to contain the process fluid at full
line pressure. An o-ring sealed cover provides access to each of the electrode
compartments from outside the sensor; drainports are provided in each cover
for the removal of fluid.
NOTE
The electrode compartment could contain full line pressure and it must be
depressurized before the cover is removed.
Optional:
Use drain port to
plumb to a safe area
(Supplied by user) 1/2 – 14 NPT Conduit
Connection
¼'' NPT – 5 psi
Pressure Relief Valve
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Rosemount 8732
5-18
Figure 5-19. Housing
Configuration — Sealed
Electrode Compartment (Option
Code W3)
If necessary, capture any process fluid leakage, connect the appropriate
piping to the drainports, and provide for proper disposal (see Figure 5-19).
Fused Glass Seal
Sealed Electrode Compartment
1/2 - 27 NPT
O-Ring Seal
Optional:
Use drain port to
plumb to a safe area
(Supplied by user)
Grounding Electrode Port
Reference Manual
00809-0100-4663, Rev BA
January 2010 Rosemount 8732
www.rosemount.com
Section 6 Maintenance and
Troubleshooting
Safety Information . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . page 6-1
Installation Check and Guide . . . . . . . . . . . . . . . . . . . . . . page 6-2
Diagnostic Messages . . . . . . . . . . . . . . . . . . . . . . . . . . . . . page 6-3
Transmitter Troubleshooting . . . . . . . . . . . . . . . . . . . . . . . page 6-5
Quick Troubleshooting . . . . . . . . . . . . . . . . . . . . . . . . . . . . page 6-7
This section covers basic transmitter and sensor troubleshooting. Problems in
the magnetic flowmeter system are usually indicated by incorrect output
readings from the system, error messages, or failed tests. Consider all
sources when identifying a problem in your system. If the problem persists,
consult your local Rosemount representative to determine if the material
should be returned to the factory. Emerson Process Management offers
several diagnostics that aid in the troubleshooting process.
Instructions and procedures in this section may require special precautions to
ensure the safety of the personnel performing the operations. Please read the
following safety messages before performing any operation described in this
section. Refer to these warnings when appropriate throughout this section.
SAFETY INFORMATION
The 8732 performs self diagnostics on the entire magnetic flowmeter system:
the transmitter, the sensor, and the interconnecting wiring. By sequentially
troubleshooting each individual piece of the magmeter system, it becomes
easier to pin point the problem and make the appropriate adjustments.
If there are problems with a new magmeter installation, see “Installation
Check and Guide” on page 6-2 for a quick guide to solve the most common
installation problems. For existing magmeter installations, Table 6-4 lists the
most common magmeter problems and corrective actions.
Failure to follow these installation guidelines could result in death or serious injury:
Installation and servicing instructions are for use by qualified personnel only. Do not perform
any servicing other than that contained in the operating instructions, unless qualified. Verify
that the operating environment of the sensor and transmitter is consistent with the
appropriate FM or CSA approval.
Do not connect a Rosemount 8732 to a non-Rosemount sensor that is located in an
explosive atmosphere.
Mishandling products exposed to a hazardous substance may result in death or serious
injury. If the product being returned was exposed to a hazardous substance as defined by
OSHA, a copy of the required Material Safety Data Sheet (MSDS) for each hazardous
substance identified must be included with the returned goods.
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January 2010
Rosemount 8732
6-2
INSTALLATION CHECK
AND GUIDE Use this guide to check new installations of Rosemount magnetic flowmeter
systems that appear to malfunction.
Before You Begin
Transmitter
Apply power to your system before making the following transmitter checks.
1. Verify that the correct sensor calibration number is entered in the
transmitter. The calibration number is listed on the sensor nameplate.
2. Verify that the correct sensor line size is entered in the transmitter.
The line size value is listed on the sensor nameplate.
3. Verify that the function blocks are not in Out of Service mode.
4. Verify that the transmitter is functioning correctly by using the 8714i
Meter Verification diagnostic or the 8714D Calibration Reference
Standard.
Sensor
Be sure that power to your system is removed before beginning sensor
checks.
1. For horizontal flow installations, ensure that the electrodes remain
covered by process fluid.
For vertical or inclined installations, ensure that the process fluid
is flowing up into the sensor to keep the electrodes covered by
process fluid.
2. Ensure that the grounding straps on the sensor are connected to
grounding rings, lining protectors, or the adjacent pipe flanges.
Improper grounding will cause erratic operation of the system.
Wiring for Remote Configurations
1. The signal wire and coil drive wire must be twisted shielded cable.
Emerson Process Management, Rosemount division. recommends
20 AWG twisted shielded cable for the electrodes and 14 AWG
twisted shielded cable for the coils.
2. The cable shield must be connected at both ends of the electrode and
coil drive cables. Connection of the signal wire shield at both ends is
necessary for proper operation. It is recommended that the coil drive
wire shield also be connected at both ends for maximum flowmeter
performance
3. The signal and coil drive wires must be separate cables, unless
Emerson Process Management specified combo cable is used. See
Table 2-2 on page 2-11.
4. The single conduit that houses both the signal and coil drive cables
should not contain any other wires.
Process Fluid
1. The process fluid conductivity should be 5 microsiemens
(5 micro mhos) per centimeter minimum.
2. The process fluid must be free of air and gasses.
3. The sensor should be full of process fluid.
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Rosemount 8732
DIAGNOSTIC
MESSAGES Problems in the magnetic flowmeter system are usually indicated by incorrect
output readings from the system, error messages, or failed tests. Consider all
sources in identifying a problem in your system.
Table 6-1. Rosemount 8732 Basic Diagnostic Messages
Message Potential Cause Corrective Action
“Fieldbus Not
Communicating”
Fieldbus segment is disconnected Connect the fieldbus segment
Fieldbus segment power missing Verify the segment fieldbus voltage
Electronics failure Replace electronics
“Sensor Processor Not
Communicating”
Transmitter input power (AC/DC) is
not connected
Connect the input power. If the LCD displays a message, the input power is
applied
Electronics failure Replace electronics
“Empty Pipe” Empty Pipe None - message will clear when pipe is full
Wiring Error Check that wiring matches appropriate wiring diagrams - see Appendix E:
Universal Sensor Wiring Diagrams
Electrode Error Perform sensor tests C and D (see Table 6-5 on page 6-8)
Conductivity less than 5
microsiemens per cm
Increase Conductivity to greater than or equal to 5 microsiemens per cm
Intermittent Diagnostic Adjust tuning of Empty Pipe parameters
“Coil Open Circuit” Improper wiring Check coil drive wiring and sensor coils
Perform sensor test A - Sensor Coil
Other manufacturer’s sensor Change coil current to 75 mA
Perform a Universal Auto Trim to select the proper coil current
Circuit Board Failure Replace Rosemount 8732 Electronics
Coil Circuit OPEN Fuse Return to factory for fuse replacement
“Auto Zero Failure”
(Cycle power to clear
messages, no changes
were made)
Flow is not set to zero Force flow to zero, perform autozero
Unshielded cable in use Change wire to shielded cable
Moisture problems See moisture problems in “Accuracy Section”
Empty pipe is present Fill sensor with process fluid
“Universal Trim Failure” No flow in pipe while performing
Universal Auto Trim
Establish a known flow in sensor, and perform Universal Auto-Trim
calibration
Wiring error Check that wiring matches appropriate wiring diagrams - see “Universal
Sensor Wiring Diagrams” on page E-1
Flow rate is changing in pipe while
performing Universal Auto-Trim
routine
Establish a constant flow in sensor, and perform Universal Auto-Trim
calibration
Flow rate through sensor is
significantly different than value
entered during Universal Auto-Trim
routine
Verify flow in sensor and perform Universal Auto-Trim calibration
Incorrect calibration number
entered into transmitter for
Universal Auto-Trim routine
Replace sensor calibration number with 1000005010000001
Wrong sensor size selected Correct sensor size setting - See “Line Size” on page 3-9
Sensor failure Perform sensor tests C and D (see Table 6-5 on page 6-8)
“Electronics Failure” Electronics self check failure Replace Electronics
“Electronics Temp Fail” Ambient temperature exceeded the
electronics temperature limits
Move transmitter to a location with an ambient temperature range of -40 to
165 °F (-40 to 74 °C)
“Reverse Flow” Electrode or coil wires reverse Verify wiring between sensor and transmitter
Flow is reverse Turn ON Reverse Flow Enable to read flow
Sensor installed backwards Re-install sensor correctly, or switch either the electrode wires (18 and 19)
or the coil wires (1 and 2)
“Flow Rate > Sensor Limit” Flow rate is greater than 43 ft/sec Lower flow velocity, increase pipe diameter
Improper wiring Check coil drive wiring and sensor coils
Perform sensor test A - Sensor Coil (see Table 6-5 on page 6-8)
“Digital Trim Failure”
(Cycle power to clear
messages, no changes
were made)
The calibrator (8714B/C/D) is not
connected properly
Review calibrator connections
Incorrect calibration number
entered into transmitter
Replace sensor calibration number with 1000005010000001
Calibrator is not set to 30 FPS Change calibrator setting to 30 FPS
Bad calibrator Replace calibrator
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January 2010
Rosemount 8732
6-4
Table 6-2. Rosemount 8732 Advanced Diagnostic Messages (Suite 1 - Option Code D01)
Table 6-3. Rosemount 8732 Advanced Diagnostic Messages (Suite 2 - Option Code D02)
Message Potential Cause Corrective Action
Grounding/Wiring Fault Improper installation of wiring See “Sensor Connections” on page 2-11
Coil/Electrode shield not
connected
See “Sensor Connections” on page 2-11
Improper process grounding See “Grounding” on page 5-12
Faulty ground connection Check wiring for corrosion, moisture in the terminal block, and refer to
“Grounding” on page 5-12
Sensor not full Verify sensor is full and empty pipe diagnostic is on
High Process Noise Slurry flows - mining/pulp stock Decrease the flow rate below 10 ft/s (3 m/s)
Complete the possible solutions listed under “Step 2: Process Noise” on
page 6-7
Chemical additives upstream of the
sensor
Move injection point downstream of the sensor, or move the sensor
Complete the possible solutions listed under “Step 2: Process Noise” on
page 6-7
Electrode not compatible with the
process fluid
Refer to the Rosemount Magnetic Flowmeter Material Selection Guide
(00816-0100-3033)
Air in line Move the sensor to another location in the process line to ensure that it is
full under all conditions
Electrode coating Use bulletnose electrodes
Downsize sensor to increases flowrate above 3 ft/s (1 m/s)
Periodically clean sensor
Styrofoam or other insulating
particles
Complete the possible solutions listed under “Step 2: Process Noise” on
page 6-7
Consult factory
Low conductivity fluids
(below 10 microsiemens/cm)
Trim electrode and coil wires - refer to “Installation” on page 2-1
Message Potential Cause Corrective Action
8714i Failed
Transmitter Calibration Verification
test failed
Verify pass/fail criteria
Rerun 8714i Meter Verification under no flow conditions
Verify calibration using 8714D Calibration Standard
Perform digital trim
Replace electronics board
Sensor Calibration test failed Verify pass/fail criteria
Perform sensor test - see Table 6-5 on page 6-8
Sensor Coil Circuit test failed Verify pass/fail criteria
Perform sensor test - see Table 6-5 on page 6-8
Sensor Electrode Circuit test failed Verify pass/fail criteria
Perform sensor test - see Table 6-5 on page 6-8
Reference Manual
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January 2010
6-5
Rosemount 8732
TRANSMITTER
TROUBLESHOOTING
Table 6-4. Advanced Troubleshooting–Rosemount 8732
Symptom Potential Cause Corrective Action
Does not appear to be within
rated accuracy
Transmitter, control system, or other
receiving device not configured
properly
Check all configuration variables for the transmitter, sensor,
communicator, and/or control system
Check these other transmitter settings:
•Sensor calibration number
•Units
•Line size
Electrode Coating Use bulletnose electrodes;
Downsize sensor to increase flow rate above 3 ft/s;
Periodically clean sensor
Air in line Move the sensor to another location in the process line to
ensure that it is full under all conditions.
Moisture problem Perform the sensor Tests A, B, C, and D
(see Table 6-5 on page 6-8)
Improper wiring If electrode shield and signal wires are switched, flow indication
will be about half of what is expected. Check wiring diagrams for
your application.
Flow rate is below 1 ft/s
(specification issue)
See accuracy specification for specific transmitter and sensor
Auto zero was not performed when the
coil drive frequency was changed from
5 Hz to 37 Hz
Set the coil drive frequency to 37 Hz, verify the sensor is full,
verify there is no flow, and perform the auto zero function.
Sensor failure–Shorted electrode Perform the sensor Tests C and D
(see Table 6-5 on page 6-8)
Sensor failure–Shorted or open coil Perform the sensor Tests A and B
(see Table 6-5 on page 6-8)
Transmitter failure Verify transmitter operation with an 8714 Calibration Standard or
replace the electronic board
Noisy Process Chemical additives upstream of
magnetic flowmeter
Complete the Noisy Process Basic procedure. Move injection
point downstream of magnetic flowmeter, or move magnetic
flowmeter.
Sludge flows–Mining/Coal/
Sand/Slurries (other slurries with
hard particles)
Decrease flow rate below 10 ft/s
Styrofoam or other insulating particles
in process
Complete the Noisy Process Basic procedure;
Consult factory
Electrode coating Use replaceable electrodes in Rosemount 8705.
Use a smaller sensor to increase flow rate above 3 ft/s.
Periodically clean sensor.
Air in line Move the sensor to another location in the process line to
ensure that it is full under all conditions.
Low conductivity fluids (below 10
microsiemens/cm) Trim electrode and coil wires – see “Conduit Cables” on
page 2-6
Keep flow rate below 3 FPS
Integral mount transmitter
Use 8712-0752-1,3 cable
Use N0 approval sensor
Advanced Troubleshooting continued on next page
Reference Manual
00809-0100-4663, Rev BA
January 2010
Rosemount 8732
6-6
Meter output is unstable Medium to low conductivity fluids (10–
25 microsiemens/cm) combined with
cable vibration or 60 Hz interference
Eliminate cable vibration:
Integral mount
Move cable to lower vibration run
Tie down cable mechanically
Trim electrode and coil wires
See “Conduit Cables” on page 2-6
Route cable line away from other equipment
powered by 60 Hz
Use 8712-0752-1,3 cable
Electrode incompatibility Check the Technical Data Sheet, Magnetic Flowmeter Material
Selection Guide (document number 00816-0100-3033), for
chemical compatibility with electrode material.
Improper grounding Check ground wiring – see “Mount the Transmitter” on page 2-3
for wiring and grounding procedures
High local magnetic or electric fields Move magnetic flowmeter (20–25 ft away is usually acceptable)
Control loop improperly tuned Check control loop tuning
Sticky valve (look for periodic
oscillation of meter output)
Service valve
Sensor failure Perform the sensor Tests A, B, C, and D
(See Table 6-5 on page 6-8)
Reading does not appear to be
within rated accuracy
Transmitter, control system, or other
receiving device not configured
properly
Check all configuration variables for the transmitter, sensor,
communicator, and/or control system
Check these other transmitter settings:
Sensor calibration number
Units
Line size
Electrode coating Use bulletnose electrodes in the Rosemount 8705 Sensor.
Downsize the sensor to increase the flow rate above 3 ft/s.
Periodically clean the sensor
Air in line Move the sensor to another location in the process line to
ensure that it is full under all conditions
Flow rate is below 1 ft/s
(specification issue)
See the accuracy specification for specific transmitter and
sensor
Insufficient upstream/downstream
pipe diameter
Move sensor to location where 5 pipe diameters upstream and 2
pipe diameters downstream is possible
Cables for multiple magmeters run
through same conduit
Run only one conduit cable between each sensor and
transmitter
Auto zero was not performed when the
coil drive frequency was changed from
5 Hz to 37.5 Hz
Perform the auto zero function with full pipe and no flow
Sensor failure—shorted electrode See Table 6-5 on page 6-8
Sensor failure—shorted or open coil See Table 6-5 on page 6-8
Transmitter failure Replace the electronics board
Transmitter wired to correct sensor Check wiring
Table 6-4. Advanced Troubleshooting–Rosemount 8732
Symptom Potential Cause Corrective Action
Reference Manual
00809-0100-4663, Rev BA
January 2010
6-7
Rosemount 8732
QUICK
TROUBLESHOOTING
Step 1: Wiring Errors The most common magmeter problem is wiring between the sensor and the
transmitter in remote mount installations. The signal wire and coil drive wire
must be twisted shielded cable: 20 AWG twisted shielded cable for the
electrodes and 14 AWG twisted shielded cable for the coils. Ensure that the
cable shield is connected at both ends of the electrode and coil drive cables.
Signal and coil drive wires must have their own cables. The single conduit that
houses both the signal and coil drive cables should not contain any other
wires. For more information on proper wiring practices, refer to “Transmitter to
Sensor Wiring” on page 2-11.
Step 2: Process Noise In some circumstances, process conditions rather than the magmeter can
cause the meter output to be unstable. Possible solutions for addressing a
noisy process situation are given below. When the output attains the desired
stability, no further steps are required.
Use the Auto Zero function to initialize the transmitter for use with the 37.5 Hz
coil drive mode only. Run this function only with the transmitter and sensor
installed in the process. The sensor must be filled with process fluid with zero
flow rate. Before running the auto zero function, be sure the coil drive mode is
set to 37.5 Hz.
Set the loop to manual if necessary and begin the auto zero procedure. The
transmitter completes the procedure automatically in about 90 seconds. A
symbol appears in the lower right-hand corner of the display to indicate that
the procedure is running.
1. Change the coil drive to 37.5 Hz. Complete the Auto Zero function, if
possible (see “Coil Drive Frequency” on page 4-13).
2. Turn on Digital Signal Processing (see “Signal Processing” on
page 4-25)
3. Increase the damping (see “Damping” on page 3-17).
If the preceding steps fail to resolve the process noise symptoms, consult
your Rosemount sales representative about using a high-signal magnetic
flowmeter system.
Step 3: Installed Sensor
Tests If a problem with an installed sensor is identified, Table 6-5 can assist in
troubleshooting the sensor. Before performing any of the sensor tests,
disconnect or turn off power to the transmitter. To interpret the results, the
hazardous location certification for the sensor must be known. Applicable
codes for the Rosemount 8705 are N0, N5, and KD. Applicable codes for the
Rosemount 8707 are N0 and N5. Applicable codes for the Rosemount 8711
are N0, N5, E5, and KD. Always check the operation of test equipment before
each test.
If possible, take all readings from inside the sensor junction box. If the sensor
junction box is inaccessible, take measurements as close as possible.
Readings taken at the terminals of remote-mount transmitters that are more
than 100 feet away from the sensor may provide incorrect or inconclusive
information and should be avoided. A sensor circuit diagram is provided in
Figure 6-1 on page 6-9.
Reference Manual
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January 2010
Rosemount 8732
6-8
To test the sensor, a multimeter capable of measuring conductance in
nanosiemens is preferred. Nanosiemens is the reciprocal of resistance.
or
Table 6-5. Sensor Test
Test Sensor
Location Required
Equipment Measuring at
Connections Expected Value Potential Cause Corrective Action
A. Sensor
Coil
Installed or
Uninstalled
Multimeter 1 and 2 = R Open or
Shorted Coil
Remove and
replace sensor
B. Shields to
Case
Installed or
Uninstalled
Multimeter 17 and
and case
ground
17 and case
ground
Moisture in
terminal block
Leaky electrode
Process behind
liner
Clean terminal
block
Remove sensor
C. Coil Shield
to Coil
Installed or
Uninstalled
Multimeter 1 and
2 and
(< 1nS)
(< 1nS) Process behind
liner
Leaky electrode
Moisture in
terminal block
Remove sensor
and dry
Clean terminal
block
Confirm with
sensor coil test
D. Electrode
Shield to
Electrode
Installed LCR (Set to
Resistance
and 120 Hz)
18 and 17 = R1
19 and 17 = R2
R1 and R2 should be stable
NO:
N5, E5, CD,
ED:
Unstable R1 or
R2 values
confirm coated
electrode
Shorted
electrode
Electrode not in
contact with
process
Empty Pipe
Low conductivity
Leaky electrode
Remove coating
from sensor wall
Use bulletnose
electrodes
Repeat
measurement
Pull sensor,
complete test in
Table 6-6 and
Table 6-7 on
page 6-10 out of
line.
2R18
0.2


R1R2300
R1R21500
1nanosiemens 1
1gigaohm
----------------------------=
1nanosiemens 1
110
9ohm
-------------------------------=
Reference Manual
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January 2010
6-9
Rosemount 8732
Figure 6-1. Sensor Circuit
Diagram
Step 4: Uninstalled
Sensor Tests An uninstalled sensor can also be used for sensor troubleshooting. To
interpret the results, the hazardous location certification for the sensor must
be known. Applicable codes for the Rosemount 8705 are N0, N5, and KD.
Applicable codes for the Rosemount 8707 are N0 and N5. Applicable codes
for the Rosemount 8711 are N0, N5, E5, and KD.
A sensor circuit diagram is provided in Figure 6-1. Take measurements from
the terminal block and on the electrode head inside the sensor. The
measurement electrodes, 18 and 19, are on opposite sides in the inside
diameter. If applicable, the third grounding electrode is in between the other
two electrodes. On Rosemount 8711 sensors, electrode 18 is near the sensor
junction box and electrode 19 is near the bottom of the sensor (Figure 6-2).
The different sensor models will have slightly different resistance readings.
Flanged sensor resistance readings are in Table 6-6 while wafer sensor
resistance readings are in Table 6-7.
68.1k(not applicable for
sensors with N0 hazardous
certification approval option
code)
Sensor Housing
68.1k
See “Safety Information” on page 6-1 for complete warning information.
Reference Manual
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January 2010
Rosemount 8732
6-10
Figure 6-2. 45° Electrode Plane
To insure accuracy of resistance readings, zero out multimeter by shorting
and touching the leads together.
Table 6-6. Uninstalled Rosemount 8705 / 8707
Flanged Sensor Tests
Measuring at Connections
Hazardous Location Certifications
N0 N5, KD
18 and Electrode(1)
(1) It is difficult to tell from visual inspection alone which electrode is wired to which number terminal in
the terminal block. Measure both electrodes. One electrode should result in an open reading, while
the other electrode should be less than 275 .
19 and Electrode(1)
17 and Grounding Electrode
17 and Ground Symbol
17 and 18 Open Open
17 and 19 Open Open
17 and 1 Open Open
Table 6-7. Uninstalled Rosemount 8711 Wafer Sensor Tests
Measuring at Connections
Hazardous Location Certification
N0 N5, E5, CD
18 and Electrode(1)
(1) Measure the electrode closest to the junction box
19 and Electrode(2)
(2) Measure the electrode farthest away from the junction box.
17 and Grounding Electrode
17 and Grounding Symbol
17 and 18 Open Open
17 and 19 Open Open
17 and 1 Open Open
275
61kR75k 
275
61kR75k 
0.3
0.3
0.3
0.3
0.3
61kR75k 
275
61kR75k 
0.3
0.3
0.3
0.3
Reference Manual
00809-0100-4663, Rev BA
January 2010 Rosemount 8732
www.rosemount.com
Appendix A Reference Data
Functional Specifications . . . . . . . . . . . . . . . . . . . . . . . . . page A-1
Foundation™ fieldbus Specifications . . . . . . . . . . . . . . . page A-4
Performance Specifications . . . . . . . . . . . . . . . . . . . . . . . page A-5
Physical Specifications . . . . . . . . . . . . . . . . . . . . . . . . . . . page A-7
FUNCTIONAL
SPECIFICATIONS Sensor Compatibility
Compatible with Rosemount 8705, 8711, 8721, and 570TM sensors.
Compatible with Rosemount 8707 sensor with D2 Dual calibration option.
Compatible with AC and DC powered sensors of other manufacturers.
Sensor Coil Resistance
350 maximum
Flow Rate Range
Capable of processing signals from fluids that are traveling between 0.04 and
39 ft/s (0.01 to 12 m/s) for both forward and reverse flow in all sensor sizes.
Full scale continuously adjustable between –39 and 39 ft/s (–12 to 12 m/s).
Conductivity Limits
Process liquid must have a conductivity of 5 microsiemens/cm (5
micromhos/cm) or greater for 8732E. Excludes the effect of interconnecting
cable length in remote mount transmitter installations.
Power Supply
90 -250 V AC ±10%, 50–60 Hz or 12-42 V DC
AC Power Supply Requirements
Units powered by 90-250 V AC have the following power requirements.
Figure A-1. AC Current
Requirements
Supply Current (Amps)
0.100
0.120
0.140
0.180
0.200
0.220
0.240
0.260
0.280
0.300
0.320
0.160
80 100 120 140 160 180 200 220 240
Power Supply Voltage (AC RMS)
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January 2010
Rosemount 8732
A-2
Figure A-2. Apparent Power
DC Supply Current Requirements
Units powered by 12-42 V DC power supply may draw up to 1 amp of current
steady state.
Figure A-3. DC Current
Requirements
Installation Coordination
Installation (overvoltage) Category II
Power Consumption
10 watts maximum
Switch-on current
AC: Maximum 26 A (< 5 ms) at 250 V AC
DC: Maximum 30 A (< 5 ms) at 42 V DC
Ambient Temperature Limits
Operating
–58 to 165 °F (–50 to 74 °C) without local operator interface
13 to 149 °F (–25 to 65 °C) with local operator interface
Storage
–40 to 185 °F (–40 to 85 °C)
–22 to 176 °F (–30 to 80 °C) with local operator interface
Humidity Limits
0–100% RH to 150 °F (65 °C)
80 100 120 140 160 180 200 220 240
Power Supply Voltage (AC RMS)
20
22
24
26
28
30
32
34
36
38
Apparent Power (VA)
250
0
0.25
0.5
0.75
1
12 18 24 30 36 42
Power Supply (Volts)
Supply Current (Amps)
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January 2010
A-3
Rosemount 8732
Enclosure Rating
NEMA 4X CSA Type 4X, IEC 60529, IP66 (transmitter), Pollution Degree 2
Output Signal
Manchester-encoded digital signal that conforms to IEC 1158-2 and ISA 50.02
Reference Manual
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January 2010
Rosemount 8732
A-4
FOUNDATION FIELDBUS
SPECIFICATIONS Schedule Entries
Seven (7)
Links
Twenty (20)
Virtual Communications Relationships (VCRs)
One (1) predefined (F6, F7) Nineteen (19) configurable (see Table 1)
Table A-1. Block Information
Reverse Flow
Detects and reports reverse flow
Software Lockout
A write-lock switch and software lockout are provided in the resource function
block.
Turn-on Time
5 minutes to rated accuracy from power up; 10 seconds from power
interruption.
Start-up Time
50 ms from zero flow.
Low Flow Cutoff
Adjustable between 0.01 and 38.37 ft/s (0.003 and 11.7 m/s). Below selected
value, output is driven to the zero flow rate signal level.
Overrange Capability
Signal output will remain linear until 110% of upper range value or 44 ft/s (13
m/s). The signal output will remain constant above these values. Out of range
message displayed on local display and field communicator.
Damping
Adjustable between 0 and 256 seconds.
Sensor Compensation
Rosemount sensors are flow-calibrated and assigned a calibration factor at
the factory. The calibration factor is entered into the transmitter, enabling
interchangeability of sensors without calculations or a compromise in
standard accuracy.
Block Execution Time (Milliseconds)
Resource (RB)
Transducer (TB)
Analog Input (AI) 10
Proportional/Integral/
Derivative (PID)
10
Integrator (INT) 10
Arithmetic (AR) 10
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January 2010
A-5
Rosemount 8732
8732E transmitters and other manufacturer’s sensors can be calibrated at
known process conditions or at the Rosemount NIST-Traceable Flow Facility.
Transmitters calibrated on site require a two-step procedure to match a
known flow rate. This procedure can be found in “Universal Trim” on
page 4-11.
Diagnostics
Basic
Self test
Transmitter faults
Tunable empty pipe
Reverse flow
Coil circuit fault
Electronics temperature
Advanced (D01 Suite)
Ground/wiring fault
High process noise
Advanced (D02 Suite)
8714i Meter Verification
PERFORMANCE
SPECIFICATIONS (System specifications are given using the frequency output and with the unit
at reference conditions.)
Accuracy
Includes the combined effects of linearity, hysteresis, repeatability, and
calibration uncertainty.
Rosemount 8732E with 8705/8707 Sensor:
Standard system accuracy is ±0.25% of rate ±1.0 mm/sec from 0.04 to 6
ft/s (0.01 to 2 m/s); above 6 ft/s (2 m/s), the system has an accuracy of
±0.25% of rate ±1.5 mm/sec.
Optional high accuracy is ±0.15% of rate ±1.0 mm/sec from 0.04 to 13 ft/s
(0.01 to 4 m/s); above 13 ft/s (4 m/s), the system has an accuracy of
±0.18% of rate.(1)
Rosemount 8732E with 8711 Sensor:
Standard system accuracy is ±0.25% of rate ±2.0 mm/sec from 0.04 to 39
ft/s (0.01 to 12 m/s).
(1) For Sensor sizes greater than 12 in. (300 mm) the high accuracy is ±0.25% of rate from 3 to
39 ft/sec (1 to 12 m/sec).
0
0.50.5
1.01.0
1.51.5
2.02.0
2.52.5
0 3 3
(1)(1)
6 6
(2)(2)
13 13
(4)(4)
20 20
(6)(6)
27 27
(8)(8)
33 33
(10)(10)
40 40
(12)(12)
Velocity in ft/s (m/s)Velocity in ft/s (m/s)
% of Rate
0.25%0.25% 0.15%0.15%
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January 2010
Rosemount 8732
A-6
Optional high accuracy is ±0.15% of rate ±1.0 mm/sec from 0.04 to 13 ft/s
(0.01 to 4 m/s); above 13 ft/s (4 m/s), the system has an accuracy of
±0.18% of rate.
Rosemount 8732E with 8721 Sensor:
Standard system accuracy is ±0.5% of rate from 1 to 39 ft/s (0.3 to 12 m/s);
between 0.04 and 1.0 ft/s (0.01 and 0.3 m/s), the system has an accuracy
of ±0.005 ft/s (0.0015 m/s).
Optional high accuracy is ±0.25% of rate from 3 to 39 ft/s (1 to 12 m/s).
Rosemount 8732E with Legacy 8705 Sensors:
Standard system accuracy is ±0.5% of rate from 1 to 39 ft/s (0.3 to 12 m/s);
between 0.04 and 1.0 ft/s (0.01 and 0.3 m/s), the system has an accuracy
of ±0.005 ft/s (0.0015 m/s).
Rosemount 8732E with Legacy 8711 Sensors:
Standard system accuracy is ±0.5% of rate from 3 to 39 ft/s (1 to 12 m/s);
between 0.04 and 3.0 ft/s (0.01 and 1 m/s), the system has an accuracy of
±0.015 ft/s (0.005 m/s).
Rosemount 8732E with Other Manufacturers’ Sensors:
When calibrated in the Rosemount Flow Facility, system accuracies as
good as 0.5% of rate can be attained.
There is no accuracy specification for other manufacturers’ sensors
calibrated in the process line.
Vibration Effect
IEC 60770-1
Repeatability
±0.1% of reading
0
0.50.5
1.01.0
1.51.5
2.02.0
2.52.5
0 3 3
(1)(1)
6 6
(2)(2)
13 13
(4)(4)
20 20
(6)(6)
27 27
(8)(8)
33 33
(10)(10)
40 40
(12)(12)
Velocity in ft/s (m/s)Velocity in ft/s (m/s)
% of Rate% of Rate
0.25%0.25% 0.15%0.15%
0
0.50.5
1.01.0
1.51.5
2.02.0
2.52.5
0 3 3
(1)(1)
6 6
(2)(2)
13 13
(4)(4)
20 20
(6)(6)
27 27
(8)(8)
33 33
(10)(10)
40 40
(12)(12)
Velocity in ft/s (m/s)Velocity in ft/s (m/s)
% of Rate% of Rate
0.5%0.5% 0.25%0.25%
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January 2010
A-7
Rosemount 8732
Stability
±0.1% of rate over six months
Ambient Temperature Effect
±0.25% change over operating temperature range
EMC Compliance
EN61326-1 1997 + A1/A2/A3 (Industrial) electromagnetic compatibility (EMC)
for process and laboratory apparatus.
PHYSICAL
SPECIFICATIONS Materials of Construction
Housing
Low copper aluminum, NEMA 4X and IEC 60529 IP66
Pollution Degree 2
Paint
Polyurethane
Cover Gasket
Rubber
Electrical Connections
Two 1/2–14 NPT connections provided on the transmitter housing (optional
third connection available). PG13.5 and CM20 adapters are available. Screw
terminals provided for all connections. Power wiring connected to transmitter
only. Integrally mounted transmitters are factory wired to the sensor.
Transmitter Weight
Approximately 7 pounds (3.2 kg). Add 1 pound (0.5 kg) for Option Code M5.
Reference Manual
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January 2010
Rosemount 8732
A-8
Reference Manual
00809-0100-4663, Rev BA
January 2010 Rosemount 8732
www.rosemount.com
Appendix B Approval Information
Product Certifications . . . . . . . . . . . . . . . . . . . . . . . . . . . . page B-1
Approved Manufacturing Locations . . . . . . . . . . . . . . . . . page B-1
European Directive Information . . . . . . . . . . . . . . . . . . . . page B-1
Hazardous Locations Product Approvals Offering . . . . . page B-3
Hazardous Location Certifications . . . . . . . . . . . . . . . . . . page B-5
PRODUCT
CERTIFICATIONS Approved Manufacturing Locations
Rosemount Inc. — Eden Prairie, Minnesota, USA
Fisher-Rosemount Technologias de Flujo, S.A. de C.V. —
Chihuahua Mexico
Emerson Process Management Flow — Ede, The Netherlands
Emerson Process Management Flow Technologies Co., Ltd. — Nanjing, China
European Directive Information
The EC declaration of conformity for all applicable European directives for this product can be
found on our website at www.rosemount.com. A hard copy may be obtained by contacting our
local sales office.
ATEX Directive
Rosemount Inc. complies with the ATEX Directive.
Type n protection type in accordance with EN50 021
Closing of entries in the device must be carried out using the appropriate EExe or EExn metal
cable gland and metal blanking plug or any appropriate ATEX approved cable gland and
blanking plug with IP66 rating certified by an EU approved certification body.
For Rosemount 8732E transmitters:
Complies with Essential Health and Safety Requirements:
EN 60079-0: 2006
IEC 60079-1: 2007
EN 60079-7: 2007
EN 60079-11: 2007
EN 60079-26: 2004
EN 50281-1-1: 1998 + A1
European Pressure Equipment Directive (PED) (97/23/EC)
Rosemount 8705 and 8707 Magnetic Flowmeter sensors in line size and flange
combinations:
Line Size: 11/2 in. - 24 in. with all DIN flanges and ANSI 150 and
ANSI 300 flanges. Also available with ANSI 600 flanges in limited line sizes.
Line Size: 30 in. - 36 in. with AWWA 125 flanges
QS Certificate of Assessment - EC No. PED-H-20
Module H Conformity Assessment
Rosemount 8711 Magnetic Flowmeter Sensors
Line Sizes: 1.5, 2, 3, 4, 6, and 8 in.
QS Certificate of Assessment - EC No. PED-H-20
Module H Conformity Assessment
Reference Manual
00809-0100-4663, Rev BA
January 2010
Rosemount 8732
B-2
Rosemount 8721 Sanitary Magmeter Sensors
in line sizes of 11/2 in. and larger:
Module A Conformity Assessment
All other Rosemount 8705/8707/8711/8721
Sensors —
in line sizes of 1 in. and less:
Sound Engineering Practice
Sensors that are SEP are outside the scope of PED and cannot be marked for compliance with
PED.
Mandatory CE-marking for sensors in accordance with Article 15 of the PED can be found on the
sensor body (CE 0575).
Sensor category I is assessed for conformity per module A procedures.
Sensor categories II – IV, use module H for conformity assessment procedures.
Electro Magnetic Compatibility (EMC) (2004/108/EC)
Models 8712D - EN 50081-1: 1992, EN 50082-2: 1995,
Model 8732E - EN 61326: 1997: A1 + A2 + A3
Installed signal wiring should not be run together and should not be in the same cable tray as AC
power wiring.
Device must be properly grounded or earthed according to local electric codes.
To improve protection against signal interference, shielded cable is recommended.
Low Voltage Directive (93/68/EEC)
Model 8712D - EN 61010 -1: 1995
Low Voltage Directive (2006/95/EC)
Model 8732E - EN 61010 -1: 2001
Other important guidelines
Only use new, original parts.
To prevent the process medium escaping, do not unscrew or remove process flange bolts,
adapter bolts or bleed screws during operation.
Maintenance shall only be done by qualified personnel.
CE CE Marking
Compliance with all applicable European Union Directives. (Note: CE Marking is not
available on Rosemount 8712H).
IECEx Scheme
For Rosemount 8732E transmitters:
Rosemount complies with all of the stated standards below:
IEC 60079-0 : 2004
IEC 60079-1 : 2007-04
IEC 60079-11 : 2006
IEC 60079-26 : 2006
IEC 60079-7 : 2006-07
IEC 61010-1 : 2001
IEC 61241-0 : 2004
IEC 61241-1 : 2004
C-Tic Marking
Complies with IEC 61326-1 : 1997 + A1, A2, A3.
Reference Manual
00809-0100-4663, Rev BA
January 2010
B-3
Rosemount 8732
HAZARDOUS
LOCATIONS PRODUCT
APPROVALS OFFERING
The Rosemount 8700 Series magnetic flowmeters offer many different
hazardous locations certifications. The table below provides an overview of
the available hazardous area approval options. Equivalent hazardous
locations certifications for sensor and transmitter must match in integrally
mounted magnetic flowmeter systems. Remote mounted magnetic flowmeter
systems do not require matched hazardous location certifications. For
complete information about the hazardous area approval codes listed, see
Hazardous Location Certifications starting on page B-5.
Table B-1. Factory Mutual (FM)
Approvals Offering
Table B-2. Canadian Standards
Association (CSA) Approvals
Offering
Transmitter 8732E 8712D(1)
(1) Remote Transmitter Only
8712H(1)
Sensor 8705 8707 8711 8705 8707 8711 8707
FM Category Hazardous Area Approval Code
Non-Classified Locations
Transmitter NANANANANANA N0
Sensor NA N0 NA NA N0 NA N0
Suitable for Class I, Division 1
Explosion-Proof
Trans: Groups C, D T6 E5(2)
(2) Available in line sizes 0.5 in. to 8 in. (15 mm to 200 mm) only
-E5- - - -
Sensor: Groups C, D T6 E5(2) -E5 - - - -
Explosion-Proof with Intrinsically Safe Output
Trans: Groups C, D T6 E5(2)(3)
(3) For I.S. Output, Output Code B must be ordered
-E5(3) - - - -
Sensor: Groups C, D T6 E5(2) -E5- - - -
Suitable for Class I, Division 2
Non-Flammable Fluids
Trans: Groups A,B,C,D T4 N0 N0 N0 N0 N0 N0 N0
Sensor: Groups A,B,C,D T5 N0 N0(4)
(4) 8707 Sensor has Temp Code - T3C
N0 N0 N0(4) N0 N0(4)
Flammable Fluids
Trans: Groups A,B,C,D T4 N5 N5 N5 N5 N5 N5 N5
Sensor: Groups A,B,C,D T5 N5 N5(4) N5 N5 N5(4) N5 N5(4)
Non-Flammable Fluids with Intrinsically Safe Output
Trans: Groups A,B,C,D T4 N0(3) N0(3) N0(3) - - - -
Sensor: Groups A,B,C,D T5 N0 N0(4) N0 - - - -
Other Certifications Product Certification Code(5)
(5) Product Certification Codes are added to the Sensor model number only
European Pressure Equipment Directive (PED) PD -PD PD -PD -
NSF 61 Drinking Water(6)
(6) Only available with PTFE (all line sizes) or Polyurethane (4 in. or larger) Lining Materials and
316L SST Electrodes
DW - DW DW - DW -
Transmitter 8732E 8712D(1)
(1) Remote Transmitter Only
8712H(1)
Sensor 8705 8707 8711 8705 8707 8711 8707
CSA Category Hazardous Area Approval Code
Non-Classified Locations
Transmitter NA - NA NA - NA -
Sensor NA -NA NA -NA -
Suitable for Class I, Division 2
Non-Flammable Fluids
Trans: Groups A,B,C,D T4 N0 N0 N0 N0 N0 N0 N0
Sensor: Groups A,B,C,D T5 N0 N0(2)
(2) 8707 Sensor has Temp Code - T3C
N0 N0 N0(2) N0 N0(2)
Other Certifications Product Certification Code(3)
(3) Product Certification Codes are added to the Sensor model number only
European Pressure Equipment Directive (PED) PD -PD PD -PD -
NSF 61 Drinking Water(4)
(4) Only available with PTFE (all line sizes) or Polyurethane (4 in. or larger) Lining Materials and
316L SST Electrodes
DW -DW DW -DW -
Reference Manual
00809-0100-4663, Rev BA
January 2010
Rosemount 8732
B-4
Table B-3. ATEX Approvals
Offering
Table B-4. IECEx Approvals
Offering
Transmitter 8732E 8712D(1)
(1) Remote Transmitter Only
8712H(1)
Sensor 8705 8707 8711 8705 8707 8711 8707
ATEX Category Hazardous Area Approval Code
Non-Hazardous
Trans: LVD and EMC NA - NA NA - NA -
Sensor: LVD and EMC NA -NA NA -NA -
Equipment Category 2
Gas Group IIB
Trans: Ex d IIB T6 ED - ED - - - -
Sensor: Ex e ia IIC T3...T6 KD(2)
(2) With integral mount transmitter, approval is valid for Gas Group IIB
-KD(2) - - - -
Gas Group IIC
Trans: Ex d IIC T6 E1 -E1 - - - -
Sensor: Ex e ia IIC T3...T6 E1 - E1 - - - -
Gas Group IIB with Intrinsically Safe Output
Trans: Ex de [ia] IIB T6 ED(3)
(3) For I.S. Output, Output Code B must be ordered
-ED
(3) --- -
Sensor: Ex e ia IIC T3...T6 KD(2) -KD(2) - - - -
Gas Group IIC with Intrinsically Safe Output
Trans: Ex de [ia] IIC T6 E1(3) -E1(3) - - - -
Sensor: Ex e ia IIC T3...T6 E1 - E1 - - - -
Equipment Category 3
Gas Group IIC
Trans: Ex nA nL IIC T4 N1 -N1 N1 -N1 -
Sensor: Ex nA [L] IIC T3...T6 N1 - N1 N1 - N1 -
Equipment Category 1 - Dust Environment
Dust Environment Only
Trans: Dust Ignition Proof ND -ND - - - -
Sensor: Dust Ignition Proof ND - ND - - - -
Other Certifications Product Certification Code(4)
(4) Product Certification Codes are added to the Sensor model number only
European Pressure Equipment Directive (PED) PD -PD PD -PD -
NSF 61 Drinking Water(5)
(5) Only available with PTFE (all line sizes) or Polyurethane (4 in. or larger) Lining Materials and
316L SST Electrodes
DW - DW DW - DW -
Transmitter 8732E(1)
Sensor 8705 8707 8711
IECEx Category Hazardous Area Approval Code
Non-Hazardous
Trans: LVD and EMC NA - NA
Sensor: LVD and EMC NA -NA
Equipment Category 2
Gas Group IIB
Trans: Ex d IIB T6 EF - EF
Gas Group IIC
Trans: Ex d IIC T6 E7 - E7
Gas Group IIB with Intrinsically Safe Output
Trans: Ex de [ia] IIB T6 EF(2) -EF
(3)
Gas Group IIC with Intrinsically Safe Output
Trans: Ex de [ia] IIC T6 E1(3) -E1
(3)
Equipment Category 3
Gas Group IIC
Trans: Ex nA nL IIC T4 N7 -N7
Reference Manual
00809-0100-4663, Rev BA
January 2010
B-5
Rosemount 8732
HAZARDOUS LOCATION
CERTIFICATIONS Equivalent Hazardous Location Certifications for sensor and transmitter must
match in integrally-mounted magnetic flowmeter systems. Remote-mounted
systems do not require matched hazardous location certification option codes.
Transmitter Approval
Information
Table B-5. Transmitter Option
Codes
Equipment Category 1 - Dust Environment
Dust Environment Only
Trans: Dust Ignition Proof NF - NF
Other Certifications Product Certification Code(3)
European Pressure Equipment
Directive (PED)
PD -PD
NSF 61 Drinking Water(4) DW - DW
(1) Available in remote mount configuration only. Requires equivalent ATEX approval on the sensor
(2) For I.S. Output, Output Code B must be ordered
(3) Product Certification Codes are added to the Sensor model number only
(4) Only available with PTFE (all line sizes) or Polyurethane (4 in. or larger) Lining Materials and
316L SST Electrodes
Rosemount
8732E Rosemount
8712D Rosemount
8712H
Approval Codes HART FOUNDATION
fieldbus
NA • • •
N0 • • • •
N1 • • •
N5 • • • •
N7 • •
ND • •
NF • •
E1 • •
E5 • •
E7 • •
ED • •
Reference Manual
00809-0100-4663, Rev BA
January 2010
Rosemount 8732
B-6
North American Certifications
Factory Mutual (FM)
NOTE
For intrinsically safe (IS) outputs on the 8732E output option code B must be selected.
IS outputs for Class I, Division 1, Groups A, B, C, D.
Temp Code – T4 at 60°C
NOTE
For the 8732E transmitters with a local operator interface (LOI) or display, the lower ambient
temperature limit is -20 °C.
N0 Division 2 Approval (All transmitters)
Reference Rosemount Control Drawing 08732-1052 (8732E).
Class I, Division 2, Groups A, B, C, D
Temp Codes – T4 (8712 at 40°C)
T4 (8732 at 60°C: -50 °C Ta 60 °C)
Dust-ignition proof Class II/III, Division 1, Groups E, F, G
Temp Codes – T4 (8712 at 40°C), T5 (8732 at 60°C)
Enclosure Type 4X
N5 Division 2 Approval (All Transmitters)
For sensors with IS electrodes only
Reference Rosemount Control Drawing 08732-1052 (8732E).
Class I, Division 2, Groups A, B, C, D
Temp Codes – T4 (8712 at 40°C),
T4 (8732 at 60°C: -50 °C Ta 60 °C)
Dust-ignition proof Class II/III, Division 1, Groups E, F, G
Temp Codes – T4 (8712 at 40°C), T5 (8732 at 60°C)
Enclosure Type 4X
E5 Explosion-Proof Approval (8732E)
Reference Rosemount Control Drawing 08732-1052
Explosion-Proof for Class I, Division 1, Groups C, D
Temp Code – T6 at 60°C
Dust-ignition proof Class II/III, Division 1, Groups E, F, G
Temp Code – T5 at 60°C
Class I, Division 2, Groups A, B, C, D
Temp Codes – T4 (8732 at 60°C)
Enclosure Type 4X
Canadian Standards Association (CSA)
N0 Division 2 Approval
Reference Rosemount Control Drawing 08732-1051 (8732E)
Class I, Division 2, Groups A, B, C, D
Temp Codes – T4 (8732 at 60°C: -50 °C Ta 60 °C)
Dust-ignition proof Class II/III, Division 1, Groups E, F, G
Temp Codes – T4 (8712 at 40°C), T5 (8732 at 60°C)
Enclosure Type 4X
Reference Manual
00809-0100-4663, Rev BA
January 2010
B-7
Rosemount 8732
European Certifications
E1 ATEX Flameproof
Hydrogen gas group
8732 - Certificate No.: KEMA 07ATEX0073 X II 2G
Ex de [ia] IIC T6 (-50 °C Ta +60 °C)
with LOI T6 (-20 °C Ta +60 °C)
Vmax = 250 V AC or 42 V DC
0575
ED ATEX Flameproof
8732 - Certificate No.: KEMA 07ATEX0073 X II 2G
Ex de [ia] IIB T6 (-50 °C Ta +60 °C)
with LOI T6 (-20 °C Ta +60 °C)
Vmax = 250 V AC or 42 V DC
0575
ND ATEX Dust
8732 - Certificate No.: KEMA 06ATEX0006 II 1D
max T = 40 °K(1)
Amb. Temp. Limits: (-20 °C Ta + 65 °C)
Vmax = 250 V AC or 42 V DC
IP 66
0575
SPECIAL CONDITIONS FOR SAFE USE (KEMA 07ATEX0073 X):
If the Rosemount 8732 Flow Transmitter is used integrally with the Rosemount 8705 or 8711
Sensors, it shall be assured that the mechanical contact areas of the Sensor and Flow
Transmitter comply with the requirements for flat joints according to standard EN/IEC 60079-1
clause 5.2.
The relation between ambient temperature, process temperature, and temperature class is to be
taken from Table B-8 on page B-13
The electrical data is to be taken from Table B-7 on page B-12
If the Rosemount 8732 Flow Transmitter is used integrally with the Junction Box, it shall be
assured that the mechanical contact areas of the Junction Box and Flow Transmitter comply with
the requirements for flanged joints according to standard EN/IEC 60079-1 clause 5.2.
Per EN60079-1: 2004 the gap of the joint between transmitter and remote junction box/sensor is
less than required per table 1 clause 5.2.2, and is only approved for use with an approved
Rosemount transmitter and approved junction box/sensor.
INSTALLATION INSTRUCTIONS:
The cable and conduit entry devices and blanking elements shall be of a certified flameproof type,
suitable for the conditions of use and correctly installed. With the use of conduit, a certified
stopping box shall be provided immediately to the entrance of the enclosure.
SPECIAL CONDITIONS FOR SAFE USE (X) (03ATEX2159X):
The relation between ambient temperature, process temperature and temperature class is to be
taken from Table B-8 on page B-13.
(1) Max surface temperature is 40 °C above the ambient temperature conditions. Tmax = 100
°C
Reference Manual
00809-0100-4663, Rev BA
January 2010
Rosemount 8732
B-8
INSTALLATION INSTRUCTIONS:
The cable and conduit entry devices and the closing elements shall be of a certified increased
safety type, suitable for the conditions of use and correctly installed.
At ambient temperatures above 50 °C, the flow meter shall be used with heat resistant cables
with a temperature rating of at least 90 °C.
A Junction Box in type of explosion protection increased safety “e” may be attached to the base of
the Rosemount 8732E Flow Transmitter, permitting remote mounting of the Rosemount 8705 and
8711 Sensors.
Ambient temperature range of the Junction Box: -50 °C to +60 °C.
The Junction Box is classified as:
II 2 G Ex e IIB T6 and certified under KEMA 07ATEX0073 X.
N1 ATEX Type n
8712D - ATEX Certificate No: BASEEFA 05ATEX0170X
EEx nA nL IIC T4 (Ta = -50 °C to + 60 °C)
Vmax = 42 V DC
0575
8732 - ATEX Certificate No: BASEEFA 07ATEX0203X
Ex nA nL IIC T4 (Ta = -50 °C to + 60 °C)
Vmax = 42 V DC
0575
Remote Junction Box
8732 - Certificate No.: KEMA 07ATEX0073 X II 2G
ATEX Ex e (1) T6 (Ta = -50 °C to +60 °C)
When installed per drawing 08732-1060
After de-energizing, wait 10 minutes before opening cover
0575
(1) IIC for E1
IIB for ED
International Certifications
E7 IECEx Flameproof
8732 - Certificate No.: KEM 07.0038X
Ex de [ia] IIC T6 (-50 °C Ta +60 °C)
Vmax = 250 V AC or 42 V DC
EF IECEx Flameproof
8732 - Certificate No.: KEM 07.0038X
Ex de [ia] IIB T6 (-50 °C Ta +60 °C)
Vmax = 250 V AC or 42 V DC
NF IECEx Dust
8732 - Certificate No.: KEM 07.0038X
Ex tD A20 IP66 T 100 °C
T6 (-20 °C Ta +60 °C)
Vmax = 250 V AC or 42 V DC
Reference Manual
00809-0100-4663, Rev BA
January 2010
B-9
Rosemount 8732
SPECIAL CONDITIONS FOR SAFE USE (KEM 07.0038X):
If the Rosemount 8732 Flow Transmitter is used integrally with the Rosemount 8705 or 8711
Sensors, it shall be assured that the mechanical contact areas of the Sensor and Flow
Transmitter comply with the requirements for flat joints according to standard EN/IEC 60079-1
clause 5.2.
The relation between ambient temperature, process temperature, and temperature class is to be
taken from Table B-8 on page B-13
The electrical data is to be taken from Table B-7 on page B-12
If the Rosemount 8732 Flow Transmitter is used integrally with the Junction Box, it shall be
assured that the mechanical contact areas of the Junction Box and Flow Transmitter comply with
the requirements for flanged joints according to standard EN/IEC 60079-1 clause 5.2.
INSTALLATION INSTRUCTIONS:
The cable and conduit entry devices and blanking elements shall be of a certified flameproof type,
suitable for the conditions of use and correctly installed. With the use of conduit, a certified
stopping box shall be provided immediately to the entrance of the enclosure.
N7 IECEx Type n
8712D - Certificate No: IECEx BAS 07.0036X
EEx nA nL IIC T4 (Ta = -50 °C to + 60 °C)
Vmax = 42 V DC
8732 - Certificate No: IECEx BAS 07.0062X
Ex nA nL IIC T4 (Ta = -50 °C to + 60 °C)
Vmax = 42 V DC
Remote Junction Box
8732 - Certificate No.: KEM 07.0038X
IECEx Ex e (1) T6 (Ta = -50 °C to + 60 °C)
When installed per drawing 08732-1060
After de-energizing, wait 10 minutes before opening cover
(1) IIC for E7
IIB for EF
Table B-6. Sensor Approval
Information
Approval
Codes
Rosemount 8705 Sensor Rosemount 8707 Sensor Rosemount 8711 Sensor Rosemount 8721
Sensors
For
Non-flammable
Fluids
For
Flammable
Fluids
For
Non-flammable
Fluids
For
Flammable
Fluids
For
Non-flammable
Fluids
For
Flammable
Fluids
For
Non-flammable
Fluids
NA •
N0 • •
ND•••• •
N1 • •
N5•••
N7 • •
ND •
NF • •
E1 •
E5(1)
(1) Available in line sizes up to 8 in. (200 mm) only.
• •
KD(2)
(2) Refer to Table B-8 on page B-13 for relation between ambient temperature, process
temperature, and temperature class.
••
Reference Manual
00809-0100-4663, Rev BA
January 2010
Rosemount 8732
B-10
North American Certifications
Factory Mutual (FM)
N0 Division 2 Approval for
Non-Flammable Fluids (All Sensors)
Class I, Division 2, Groups A, B, C, D
Temp Code – T5 (8705/8711 at 60°C)
Temp Code – T3C (8707 at 60°C)
Dust-Ignition proof Class II/III, Division 1, Groups E, F, G
Temp Code – T6 (8705/8711 at 60°C)
Temp Code – T3C (8707 at 60°C)
Enclosure Type 4X
N0 for 8721 Hygienic Sensor
Factory Mutual (FM) Ordinary Location;
CE Marking; 3-A Symbol Authorization #1222;
EHEDG Type EL
N5 Division 2 Approval for Flammable Fluids
(All Sensors)
Class I, Division 2, Groups A, B, C, D
Temp Code – T5 (8705/8711 at 60°C)
Temp Code – T3C (8707 at 60°C)
Dust-Ignition proof Class II/III, Division 1, Groups E, F, G
Temp Code – T6 (8705/8711 at 60°C)
Temp Code – T3C (8707 at 60°C)
Enclosure Type 4X
E5 Explosion-Proof (8705 and 8711 Only)
Explosion-Proof for Class I, Division 1, Groups C, D
Temp Code – T6 at 60°C
Dust-Ignition proof Class II/III, Division 1, Groups E, F, G
Temp Code – T6 at 60°C
Class I, Division 2, Groups A, B, C, D
Temp Code – T5 at 60°C
Enclosure Type 4X
Canadian Standards Association (CSA)
N0 Suitable for Class I, Division 2, Groups A, B, C, D
Temp Code – T5 (8705/8711 at 60°C)
Temp Code – T3C (8707 at 60°C)
Dust-Ignition proof Class II/III, Division 1, Groups E, F, G
Enclosure Type 4X
N0 for 8721 Hygienic Sensor
Canadian Standards Association (CSA) Ordinary Location;
CE Marking; 3-A Symbol Authorization #1222;
EHEDG Type EL
European Certifications
ND ATEX Dust
8732 - Certificate No.: KEMA 06ATEX0006 II 1D max
T = 40 °K(1) Amb. Temp. Limits: (-20 °C = Ta = +65 °C)
Vmax = 40 V DC (pulsed)
IP 66
CE 0575
N1 ATEX Non-Sparking/Non-incendive (8705/8711 Only)
Certificate No: KEMA02ATEX1302X II 3G
EEx nA [L] IIC T3... T6
Ambient Temperature Limits -20 to 65°C
Reference Manual
00809-0100-4663, Rev BA
January 2010
B-11
Rosemount 8732
SPECIAL CONDITIONS FOR SAFE USE (X):
The relation between ambient temperature, process temperature and temperature class is to be
taken from the table under (15-description) above. - (See Table 13) The electrical data is to be
taken from the summary under (15-electrical data above). (See Table 12)
E1 ATEX Increased Safety (Zone 1)
KD with IS Electrodes (8711 only)
Certificate No: KEMA03ATEX2052X II 1/2G
EEx e ia IIC T3... T6 (Ta = -20 to +60°) (See Table B-8 on page B-13)
0575
Vmax = 40 V DC (pulsed)
SPECIAL CONDITIONS FOR SAFE USE (X):
If the Rosemount 8732 Flow Transmitter is used integrally with the Rosemount 8705 or
Rosemount 8711 Sensors, it shall be assured that the mechanical contact areas of the Sensor
and Flow Transmitter comply with the requirements for flat joints according to standard EN 50018,
clause 5.2. The relation between ambient temperature, process temperature and temperature
class is to be taken from the table under (15-description) above. - (See Table 11) The electrical
data is to be taken from the summary under (15-electrical data above). (See Table 12)
INSTALLATION INSTRUCTIONS:
At ambient temperature above 50 °C, the flowmeter shall be used with heat resistant cables with
a temperature rating of at least 90 °C.
A fuse with a rating of maximum 0,7 A according to IEC 60127-1 shall be included in the coil
excitation circuit if the sensors are used with other flow transmitters (e.g. Rosemount 8712).
E1 ATEX Increased Safety (Zone 1)
KD with IS Electrodes (8705 only)
Certificate No. KEMA 03ATEX2052X II 1/2G
EEx e ia IIC T3... T6 (Ta = -20 to 60 °C) (See Table B-8 on page B-13)
0575
Vmax = 40 V DC (pulsed)
SPECIAL CONDITIONS FOR SAFE USE (X):
If the Rosemount 8732 Flow Transmitter is used integrally with the Rosemount 8705 or
Rosemount 8711 Sensors, it shall be assured that the mechanical contact areas of the Sensor
and Flow Transmitter comply with the requirements for flat joints according to standard EN 50018,
clause 5.2. The relation between ambient temperature, process temperature and temperature
class is to be taken from the table under (15-description) above. - (See Table 11) The electrical
data is to be taken from the summary under (15-electrical data above). (See Table 12)
INSTALLATION INSTRUCTIONS:
At ambient temperature above 50 °C, the flowmeter shall be used with heat resistant cables with
a temperature rating of at least 90 °C.
A fuse with a rating of maximum 0.7 A according to IEC 60127-1 shall be included in the coil
excitation circuit.
Reference Manual
00809-0100-4663, Rev BA
January 2010
Rosemount 8732
B-12
Table B-7. Electrical Data Rosemount 8732 Flow Transmitter
Power supply: 250 V AC, 1 A or 42 Vdc, 2,5 A, 20 W maximum
Foundation fieldbus
output:
30 V DC, 30 mA, 1 W maximum
Rosemount 8705 and 8711 Sensors
Coil excitation
circuit:
40 V DC (pulsed), 0,5 A, 20 W maximum
Electrode circuit: Intrinsically Safe Electrode Circuit: Ui = 5 V, li = 0.2 mA, Pi = 1 mW,
Um = 250 V
Rosemount 8732E Flow Transmitter:
Power supply: 250 V AC, 1 A or 42 Vdc, 2, 5 A, 20 W maximum
FOUNDATION
fieldbus output: Intrinsically Safe Output:
Ui = 30 V
Ii = 380 mA
Pi = 5,32 W
Ci = 924 pF
Li = 0 mH
Reference Manual
00809-0100-4663, Rev BA
January 2010
B-13
Rosemount 8732
Table B-8. Relation between
ambient temperature, process
temperature, and temperature
class(1)
Table B-9. Relation between the
maximum ambient temperature,
the maximum process
temperature, and the
temperature class(2)
(1) This table is applicable for CD and KD option codes only.
Meter Size (Inches) Maximum Ambient Temperature Maximum Process
Temperature Temperature
Class
1/2115°F (65°C) 239°F (115°C) T3
1149°F (65°C) 248°F (120°C) T3
1 95°F (35°C) 95°F (35°C) T4
11/2149°F (65°C) 257°F (125°C) T3
11/2122°F (50°C) 148°F (60°C) T4
2149°F (65°C) 257°F (125°C) T3
2 149°F (65°C) 167°F (75°C) T4
2104°F (40°C) 104°F (40°C) T5
3 - 36 149°F (65°C) 266°F (130°C) T3
3 - 36 149°F (65°C) 194°F (90°C) T4
3 - 36 131°F (55°C) 131°F (55°C) T5
3 - 36 104°F (40°C) 104°F (40°C) T6
6 115°F (65°C) 275°F(135°C) T3
6115°F (65°C) 230°F (110°C) T4
6 115°F (65°C) 167°F (75°C) T5
6140°F (60°C) 140°F (60°C) T6
8-60 115°F (65°C) 284°F (140°C) T3
8-60 115°F (65°C) 239°F (115°C) T4
8-60 115°F (65°C) 176°F (80°C) T5
8-60 115°F (65°C) 156°F (69°C) T6
(2) This table is applicable for N1 option codes only.
Maximum Ambient
Temperature
Maximum process temperature °F (°C) per temperature class
T3 T4 T5 T6
0.5 in. sensor size
149°F (65°C) 297°F (147°C) 138°F (59°C) 54°F (12°C) 18°F (-8°C)
140°F (60°C) 309°F (154°C) 151°F (66°C) 66°F (19°C) 28°F (-2°C)
131°F (55°C) 322°F (161°C) 163°F (73°C) 79°F (26°C) 41°F (5°C)
122°F (50°C) 334°F (168°C) 176°F (80°C) 90°F (32°C) 54°F (12°C)
113°F (45°C) 347°F (175°C) 189°F (87°C) 102°F (39°C) 66°F (19°C)
104°F (40°C) 351°F (177°C) 199°F (93°C) 115°F (46°C) 79°F (26°C)
95°F (35°C) 351°F (177°C) 212°F (100°C) 127°F (53°C) 90°F (32°C)
86°F (30°C) 351°F (177°C) 225°F (107°C) 138°F (59°C) 102°F (39°C)
77°F (25°C) 351°F (177°C) 237°F (114°C) 151°F (66°C) 115°F (46°C)
68°F (20°C) 351°F (177°C) 248°F (120°C) 163°F (73°C) 127°F (53°C)
1.0 in. sensor size
149°F (65°C) 318°F (159°C) 158°F (70°C) 72°F (22°C) 34°F (1°C)
140°F (60°C) 331°F (166°C) 171°F (77°C) 84°F (29°C) 46°F (8°C)
131°F (55°C) 343°F (173°C) 183°F (84°C) 97°F (36°C) 59°F (15°C)
122°F (50°C) 351°F (177°C) 196°F (91°C) 109°F (43°C) 72°F (22°C)
113°F (45°C) 351°F (177°C) 207°F (97°C) 122°F (50°C) 84°F (29°C)
104°F (40°C) 351°F (177°C) 219°F (104°C) 135°F (57°C) 97°F (36°C)
95°F (35°C) 351°F (177°C) 232°F (111°C) 145°F (63°C) 109°F (43°C)
86°F (30°C) 351°F (177°C) 244°F (118°C) 158°F (70°C) 122°F (50°C)
77°F (25°C) 351°F (177°C) 257°F (125°C) 171°F (77°C) 135°F (57°C)
68°F (20°C) 351°F (177°C) 270°F (132°C) 183°F (84°C) 145°F (63°C)
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1.5 in. sensor size
149°F (65°C) 297°F (147°C) 160°F (71°C) 88°F (31°C) 55°F (13°C)
140°F (60°C) 307°F (153°C) 171°F (77°C) 97°F (36°C) 66°F (19°C)
131°F (55°C) 318°F (159°C) 181°F (83°C) 108°F (42°C) 77°F (25°C)
122°F (50°C) 329°F (165°C) 192°F (89°C) 118°F (48°C) 88°F (31°C)
113°F (45°C) 340°F (171°C) 203°F (95°C) 129°F (54°C) 97°F (36°C)
104°F (40°C) 351°F (177°C) 214°F (101°C) 140°F (60°C) 108°F (42°C)
95°F (35°C) 351°F (177°C) 223°F (106°C) 151°F (66°C) 118°F (48°C)
86°F (30°C) 351°F (177°C) 234°F (112°C) 160°F (71°C) 129°F (54°C)
77°F (25°C) 351°F (177°C) 244°F (118°C) 171°F (77°C) 140°F (60°C)
68°F (20°C) 351°F (177°C) 255°F (124°C) 181°F (83°C) 151°F (66°C)
2.0 in. sensor size
149°F (65°C) 289°F (143°C) 163°F (73°C) 95°F (35°C) 66°F (19°C)
140°F (60°C) 300°F (149°C) 172°F 78(°C) 104°F (40°C) 75°F (24°C)
131°F (55°C) 309°F (154°C) 183°F (84°C) 115°F (46°C) 84°F (29°C)
122°F (50°C) 318°F (159°C) 192°F (89°C) 124°F (51°C) 95°F (35°C)
113°F (45°C) 329°F (165°C) 201°F (94°C) 135°F (57°C) 104°F (40°C)
104°F (40°C) 338°F (170°C) 212°F (100°C) 144°F (62°C) 115°F (46°C)
95°F (35°C) 349°F (176°C) 221°F (105°C) 153°F (67°C) 124°F (51°C)
86°F (30°C) 351°F (177°C) 232°F (111°C) 163°F (73°C) 135°F (57°C)
77°F (25°C) 351°F (177°C) 241°F (116°C) 172°F (78°C) 144°F (62°C)
68°F (20°C) 351°F (177°C) 252°F (122°C) 183°F (84°C) 153°F (67°C)
3 to 60 in. sensor size
149°F (65°C) 351°F (177°C) 210°F (99°C) 117°F (47°C) 75°F (24°C)
140°F (60°C) 351°F (177°C) 223°F (106°C) 129°F (54°C) 90°F (32°C)
131°F (55°C) 351°F (177°C) 237°F (114°C) 144°F (62°C) 102°F (39°C)
122°F (50°C) 351°F (177°C) 250°F (121°C) 156°F (69°C) 117°F (47°C)
113°F (45°C) 351°F (177°C) 264°F (129°C) 171°F (77°C) 129°F (54°C)
104°F (40°C) 351°F (177°C) 266°F (130°C) 183°F (84°C) 144°F (62°C)
95°F (35°C) 351°F (177°C) 266°F (130°C) 198°F (92°C) 156°F (69°C)
86°F (30°C) 351°F (177°C) 266°F (130°C) 203°F (95°C) 171°F (77°C)
77°F (25°C) 351°F (177°C) 266°F (130°C) 203°F (95°C) 176°F (80°C)
68°F (20°C) 351°F (177°C) 266°F (130°C) 203°F (95°C) 176°F (80°C)
Maximum Ambient
Temperature
Maximum process temperature °F (°C) per temperature class
T3 T4 T5 T6
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January 2010
B-15
Rosemount 8732
Figure B-1. ATEX Installation
(1 of 6)
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Rosemount 8732
B-16
Figure B-2. ATEX Installation
(2 of 6)
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Rosemount 8732
Figure B-3. ATEX Installation
(3 of 6)
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Rosemount 8732
B-18
Figure B-4. ATEX Installation
(4 of 6)
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B-19
Rosemount 8732
Figure B-5. ATEX Installation
(5 of 6)
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Rosemount 8732
B-20
Figure B-6. ATEX Installation
(6 of 6)
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B-21
Rosemount 8732
Figure B-7. FM Certified I.S.
Output (1 of 4)
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Rosemount 8732
B-22
Figure B-8. FM Certified I.S.
Output (2 of 4)
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Rosemount 8732
Figure B-9. FM Certified I.S.
Output (3 of 4)
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Rosemount 8732
B-24
Figure B-10. FM Certified I.S.
Output (4 of 4)
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January 2010
B-25
Rosemount 8732
Figure B-11. CSA Certified I.S.
Output (1 of 2)
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B-26
Figure B-12. CSA Certified I.S.
Output (2 of 2)
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Rosemount 8732
Figure B-13. CSA Installation
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Rosemount 8732
B-28
Figure B-14. Factory Mutual
Hazardous Locations
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January 2010 Rosemount 8732
www.rosemount.com
Appendix C Diagnostics
Diagnostic Availability . . . . . . . . . . . . . . . . . . . . . . . . . . . . page C-1
Licensing and Enabling . . . . . . . . . . . . . . . . . . . . . . . . . . . page C-2
Tunable Empty Pipe Detection . . . . . . . . . . . . . . . . . . . . . page C-2
Ground/Wiring Fault Detection . . . . . . . . . . . . . . . . . . . . . page C-4
High Process Noise Detection . . . . . . . . . . . . . . . . . . . . . . page C-5
8714i Meter Verification . . . . . . . . . . . . . . . . . . . . . . . . . . . page C-8
Rosemount Magnetic Flowmeter
Calibration Verification Report . . . . . . . . . . . . . . . . . . . . . page C-16
DIAGNOSTIC
AVAILABILITY Rosemount Magmeters provide device diagnostics that powers PlantWeb and
informs the user of abnormal situations throughout the life of the meter - from
installation to maintenance and meter verification. With Rosemount Magmeter
diagnostics enabled, users can change their practices to improve plant
availability and output, and reduce costs through simplified installation,
maintenance and troubleshooting.
Table C-1. Rosemount
Magmeter Diagnostics
Options for Accessing Diagnostics
Rosemount Magmeter Diagnostics can be accessed through the 375 Field
Communicator, AMS Device Manager, or any other FOUNDATION fieldbus
configuration tool.
Access Diagnostics through AMS Intelligent Device Manager for the
Ultimate Value
The value of the Diagnostics increases significantly when AMS is used. AMS
provides a simplified screen flow and procedures for how to respond to the
Diagnostic messages.
Diagnostics Mag User Practice 8732
FF
Basic
Empty Pipe Process Management
Electronics Temperature Maintenance
Coil Fault Maintenance
Transmitter Faults Maintenance
Reverse Flow Process Management
Advanced (Suite 1) D01 Option
High Process Noise Process Management
Grounding/Wiring Fault Installation
Advanced (Suite 2) D02 Option
8714i Meter Verification Meter Verification
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January 2010
Rosemount 8732
C-2
LICENSING AND
ENABLING All non-basic diagnostics must be licensed by ordering option code D01, D02,
or both. In the event that a diagnostic option is not ordered, advanced
diagnostics can be licensed in the field through the use of a license key. To
obtain a license key, contact your local Rosemount Representative. Each
transmitter has a unique license key specific to the diagnostic option code.
See the detailed procedures below for entering the license key and enabling
the advanced diagnostics.
Licensing the 8732
Diagnostics For licensing the advanced diagnostics, follow the steps below.
1. Power-up the 8732 transmitter
2. Verify that you have 1.01.001 software or later
3. Determine the Device ID
4. Obtain a License Key from your local Rosemount Representative.
5. Enter License Key
6. Enable Advanced Diagnostics
TUNABLE EMPTY PIPE
DETECTION The Tunable Empty Pipe detection provides a means of minimizing issues
and false readings when the pipe is empty. This is most important in batching
applications where the pipe may run empty with some regularity.
If the pipe is empty, this diagnostic will activate, set the flow rate to 0, and
deliver a PlantWeb alert.
Turning Empty Pipe On/Off
The Empty Pipe diagnostic can be turned on or off as required by the
application. If the advanced diagnostics suite 1 (D01 Option) was ordered,
then the Empty Pipe diagnostic will be turned on. If D01 was not ordered, the
default setting is off.
Tunable Empty Pipe
Parameters The Tunable Empty Pipe diagnostic has one read-only parameter, and two
parameters that can be custom configured to optimize the diagnostic
performance.
375 Transducer Block, Diagnostics, Advanced Diagnostics, Licensing
AMS Tab License
375 Transducer Block, Diagnostics, Advanced Diagnostics, Licensing, License Key,
Device ID
AMS Tab License
375 Transducer Block, Diagnostics, Advanced Diagnostics, Licensing, License Key,
License Key
AMS Tab License
375 Transducer Block, Diagnostics, Diagnostic Controls
AMS Tab Diagnostics
375 Transducer Block, Diagnostics, Diagnostic Controls
AMS Tab Diagnostics
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January 2010
C-3
Rosemount 8732
Empty Pipe Value
Reads the current Empty Pipe Value. This is a read-only value. This number
is a unitless number and is calculated based on multiple installation and
process variables such as sensor type, line size, process fluid properties, and
wiring. If the Empty Pipe Value exceeds the Empty Pipe Trigger Level for a
specified number of updates, then the Empty Pipe diagnostic alert will
activate.
Empty Pipe Trigger Level
Limits: 3 to 2000
This value configures the threshold limit that the Empty Pipe Value must
exceed before the Empty Pipe diagnostic alert activates. The default setting
from the factory is 100.
Empty Pipe Counts
Limits: 5 to 50
This value configures the number of consecutive updates that the Empty Pipe
Value must exceed the Empty Pipe Trigger Level before the Empty Pipe
diagnostic alert activates. The default setting from the factory is 5.
Optimizing Tunable
Empty Pipe The Tunable Empty Pipe diagnostic is set at the factory to properly diagnose
most applications. If this diagnostic unexpectedly activates, the following
procedure can be followed to optimize the Empty Pipe diagnostic for the
application.
1. Record the Empty Pipe Value with a full pipe condition.
Example
Full reading = 0.2
2. Record the Empty Pipe Value with an empty pipe condition.
Example
Empty reading = 80.0
3. Set the Empty Pipe Trigger Level to a value between the full and
empty readings. For increased sensitivity to empty pipe conditions,
set the trigger level to a value closer to the full pipe value.
Example
Set the trigger level to 25.0
4. Set the Empty Pipe Counts to a value corresponding to the desired
sensitivity level for the diagnostic. For applications with entrained air
or potential air slugs, less sensitivity may be desired.
Example
Set the counts to 10
375 Transducer Block, Diagnostics, Basic Diagnostics, Empty Pipe Limits, EP Value
AMS Tab Diagnostics
375 Transducer Block, Diagnostics, Basic Diagnostics, Empty Pipe Limits, EP Trigger
Level
AMS Tab Diagnostics
375 Transducer Block, Diagnostics, Basic Diagnostics, Empty Pipe Limits, EP Counts
AMS Tab Diagnostics
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C-4
Troubleshooting Empty
Pipe The following actions can be taken if Empty Pipe detection is unexpected.
1. Verify the sensor is full.
2. Verify that the sensor has not been installed with a measurement
electrode at the top of the pipe.
3. Decrease the sensitivity by setting the Empty Pipe Trigger Level to a
value above the Empty Pipe Value read with a full pipe.
4. Decrease the sensitivity by increasing the Empty Pipe Counts to
compensate for process noise. The Empty Pipe Counts is the number
of consecutive Empty Pipe Value readings above the Empty Pipe
Trigger Level required to activate the Empty Pipe alert. The count
range is 5-50, with factory default set at 5.
5. Increase process fluid conductivity above 50 microsiemens/cm.
6. Properly connect the wiring between the sensor and the transmitter.
Corresponding terminal block numbers in the sensor and transmitter
must be connected.
7. Perform the sensor electrical resistance tests. Confirm the resistance
reading between coil ground (ground symbol) and coil (1 and 2) is
infinity, or open. Confirm the resistance reading between electrode
ground (17) and an electrode (18 or 19) is greater than 2 kohms and
rises. For more detailed information, consult Table 6-5 on page 6-8.
GROUND/WIRING FAULT
DETECTION The Ground/Wiring Fault Detection diagnostic provides a means of verifying
installations are done correctly. If the installation is not wired or grounded
properly, this diagnostic will activate and deliver a PlantWeb alert. This
diagnostic can also detect if the grounding is lost over-time due to corrosion or
another root cause.
Turning Ground/Wiring Fault On/Off
The Ground/Wiring Fault diagnostic can be turned on or off as required by the
application. If the advanced diagnostics suite 1 (D01 Option) was ordered,
then the Ground/Wiring Fault diagnostic will be turned on. If D01 was not
ordered or licensed, this diagnostic is not available.
Ground/Wiring Fault
Parameters The Ground/Wiring Fault diagnostic has one read-only parameter. It does not
have any configurable parameters.
Line Noise
Reads the current amplitude of the Line Noise. This is a read-only value. This
number is a measure of the signal strength at 50/60 Hz. If the Line Noise
value exceeds 5 mV, then the Ground/Wiring Fault diagnostic alert will
activate.
375 Transducer Block, Diagnostics, Basic Diagnostics, Empty Pipe Limits, EP Counts
AMS Tab Diagnostics
375 Transducer Block, Diagnostics, Diagnostic Variables, Line Noise
AMS Tab Diagnostics
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C-5
Rosemount 8732
Troubleshooting
Ground/Wiring Fault The transmitter detected high levels of 50/60 Hz noise caused by improper
wiring or poor process grounding.
1. Verify that the transmitter is earth grounded.
2. Connect ground rings, grounding electrode, lining protector, or
grounding straps. Grounding diagrams can be found in “Grounding”
on page 5-12.
3. Verify sensor is full.
4. Verify wiring between sensor and transmitter is prepared properly.
Shielding should be stripped back less than 1 in. (25 mm).
5. Use separate shielded twisted pairs for wiring between sensor and
transmitter.
6. Properly connect the wiring between the sensor and the transmitter.
Corresponding terminal block numbers in the sensor and transmitter
must be connected.
Ground/Wiring Fault
Functionality The transmitter continuously monitors signal amplitudes over a wide range of
frequencies. For the Ground/Wiring Fault diagnostic, the transmitter
specifically looks at the signal amplitude at frequencies of 50 Hz and 60 Hz
which are the common AC cycle frequencies found throughout the world. If
the amplitude of the signal at either of these frequencies exceeds 5 mV, that is
an indication that there is a ground or wiring issue and that stray electrical
signals are getting into the transmitter. The diagnostic alert will activate
indicating that the ground and wiring of the installation should be carefully
reviewed.
HIGH PROCESS NOISE
DETECTION The High Process Noise diagnostic detects if there is a process condition
causing unstable or noisy readings, but the noise is not real flow variation.
One common cause of high process noise is slurry flow, like pulp stock or
mining slurries. Other conditions that cause this diagnostic to activate are high
levels of chemical reaction or entrained gas in the liquid. If unusual noise or
variation is seen, this diagnostic will activate and deliver a PlantWeb alert. If
this situation exists and is left without remedy, it will add additional uncertainty
and noise to the flow reading.
Turning High Process Noise On/Off
The High Process Noise diagnostic can be turned on or off as required by the
application. If the advanced diagnostics suite 1 (D01 Option) was ordered,
then the High Process Noise diagnostic will be turned on. If D01 was not
ordered or licensed, this diagnostic is not available.
375 Transducer Block, Diagnostics, Diagnostic Controls
AMS Tab Diagnostics
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C-6
High Process Noise
Parameters The High Process Noise diagnostic has two read-only parameters. It does not
have any configurable parameters. This diagnostic requires that flow be
present in the pipe and the velocity be > 1 ft/s.
5 Hz Signal to Noise Ratio
Reads the current value of the signal to noise ratio at the coil drive frequency
of 5 Hz. This is a read-only value. This number is a measure of the signal
strength at 5 Hz relative to the amount of process noise. If the transmitter is
operating in 5 Hz mode, and the signal to noise ratio remains below 25 for
approximately one minute, then the High Process Noise diagnostic alert will
activate.
37 Hz Signal to Noise Ratio
Reads the current value of the signal to noise ratio at the coil drive frequency
of 37 Hz. This is a read-only value. This number is a measure of the signal
strength at 37 Hz relative to the amount of process noise. If the transmitter is
operating in 37 Hz mode, and the signal to noise ratio remains below 25 for
approximately one minute, then the High Process Noise diagnostic alert will
activate.
Troubleshooting High
Process Noise The transmitter detected high levels of process noise. If the signal to noise
ratio is less than 25 while operating in 5 Hz mode, proceed with the following
steps:
1. Increase transmitter coil drive frequency to 37 Hz (refer to “Coil Drive
Frequency” on page 4-13) and, if possible, perform Auto Zero
function (refer to “Auto Zero” on page 4-12).
2. Verify sensor is electrically connected to the process with grounding
electrode, grounding rings with grounding straps, or lining protector
with grounding straps.
3. If possible, redirect chemical additions downstream of the magmeter.
4. Verify process fluid conductivity is above 10 microsiemens/cm.
If the signal to noise ratio is less than 25 while operating in 37 Hz mode,
proceed with the following steps:
375 Transducer Block, Diagnostics, Diagnostic Variables, 5Hz SNR
AMS Tab Diagnostics
375 Transducer Block, Diagnostics, Diagnostic Variables, 37Hz SNR
AMS Tab Diagnostics
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Rosemount 8732
1. Turn on the Digital Signal Processing (DSP) technology and follow
the setup procedure (refer to Appendix D: Digital Signal Processing).
This will minimize the level of damping in the flow measurement and
control loop while also stabilizing the reading to minimize valve
actuation.
2. Increase damping to stabilize the signal (refer to “PV Damping” on
page 3-11). This will add dead-time to the control loop.
3. Move to a Rosemount High-Signal flowmeter system. This flowmeter
will deliver a stable signal by increasing the amplitude of the flow
signal by ten times to increase the signal to noise ratio. For example if
the signal to noise ratio (SNR) of a standard magmeter is 5, the
High-Signal would have a SNR of 50 in the same application. The
Rosemount High-Signal system is comprised of the 8707 sensor
which has modified coils and magnetics and the 8712H High-Signal
transmitter.
NOTE
In applications where very high levels of noise are a concern, it is
recommended that a dual-calibrated Rosemount High-Signal 8707 sensor be
used. These sensors can be calibrated to run at lower coil drive current
supplied by the standard Rosemount transmitters, but can also be upgraded
by changing to the 8712H High-Signal transmitter.
High Process Noise
Functionality The High Process Noise diagnostic is useful for detecting situations where the
process fluid may be causing electrical noise resulting in a poor measurement
from the magnetic flowmeter. There are three basic types of process noise
that can affect the performance of the magnetic flowmeter system.
1/f Noise
This type of noise has higher amplitudes at lower frequencies, but generally
degrades over increasing frequencies. Potential sources of 1/f noise include
chemical mixing and the general background noise of the plant.
Spike Noise
This type of noise generally results in a high amplitude signal at specific
frequencies which can vary depending on the source of the noise. Common
sources of spike noise include chemical injections directly upstream of the
flowmeter, hydraulic pumps, and slurry flows with low concentrations of
particles in the stream. The particles bounce off of the electrode generating a
“spike” in the electrode signal. An example of this type of flow stream would
be a recycle flow in a paper mill.
White Noise
This type of noise results in a high amplitude signal that is relatively constant
over the frequency range. Common sources of white noise include chemical
reactions or mixing that occurs as the fluid passes through the flowmeter and
high concentration slurry flows where the particulates are constantly passing
over the electrode head. An example of this type of flow stream would be a
high consistency pulp stock stream (>10%) in a paper mill.
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C-8
The transmitter continuously monitors signal amplitudes over a wide range of
frequencies. For the high process noise diagnostic, the transmitter specifically
looks at the signal amplitude at frequencies of 2.5 Hz, 7.5 Hz, 32.5 Hz, and
42.5 Hz. The transmitter uses the values from 2.5 and 7.5 Hz and calculates
an average noise level. This average is compared to the amplitude of the
signal at 5 Hz. If the signal amplitude is not 25 times greater than the noise
level, and the coil drive frequency is set at 5 Hz, the High Process Noise alert
will activate indicating that the flow signal may be compromised. The
transmitter performs the same analysis around the 37.5 Hz coil drive
frequency using the 32.5 Hz and 42.5 Hz values to establish a noise level.
8714I METER
VERIFICATION The 8714i Meter Verification diagnostic provides a means of verifying the
flowmeter is within calibration without removing the sensor from the process.
This is a manually initiated diagnostic test that provides a review of the
transmitter and sensors critical parameters as a means to document
verification of calibration. The results of running this diagnostic provide the
deviation amount from expected values and a pass/fail summary against
user-defined criteria for the application and conditions.
Initiating 8714i Meter Verification
The 8714i Meter Verification diagnostic can be initiated as required by the
application. If the advanced diagnostic suite (D02) was ordered, then the
8714i Meter Verification diagnostic will be available. If D02 was not ordered or
licensed, this diagnostic will not be available.
Sensor Signature
Parameters The sensor signature describes the magnetic behavior of the sensor. Based
on Faraday’s law, the induced voltage measured on the electrodes is
proportional to the magnetic field strength. Thus, any changes in the magnetic
field will result in a calibration shift of the sensor.
Establishing the baseline sensor signature
The first step in running the 8714i Meter Verification test is establishing the
reference signature that the test will use as the baseline for comparison. This
is accomplished by having the transmitter take a signature of the sensor.
Having the transmitter take an initial sensor signature when first installed will
provide the baseline for the verification tests that are done in the future. The
sensor signature should be taken during the start-up process when the
transmitter is first connected to the sensor, with a full line, and ideally with no
flow in the line. Running the sensor signature procedure when there is flow in
the line is permissible, but this may introduce some noise into the signature
measurements. If an empty pipe condition exists, then the sensor signature
should only be run for the coils.
Once the sensor signature process is complete, the measurements taken
during this procedure are stored in non-volatile memory to prevent loss in the
event of a power interruption to the meter.
375 Transducer Block, Diagnostics, Advanced Diagnostics, 8714i Meter Verification
AMS Tab Diagnostics
375 Transducer Block, Diagnostics, Advanced Diagnostics, 8714i Meter Verification,
Sensor Signature, Re-Signature
AMS Tab Context Menu, Diagnostics and Tests,
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January 2010
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Rosemount 8732
8714i Meter Verification
Test Parameters The 8714i has a multitude of parameters that set the test criteria, test
conditions, and scope of the calibration verification test.
Test Conditions for the 8714i Meter Verification
There are three possible test conditions that the 8714i Meter Verification test
can be initiated under. This parameter is set at the time that the Sensor
Signature or 8714i Meter Verification test is initiated.
No Flow
Run the 8714i Meter Verification test with a full pipe and no flow in the line.
Running the 8714i Meter Verification test under this condition provides the
most accurate results and the best indication of magnetic flowmeter health.
Flowing, Full
Run the 8714i Meter Verification test with a full pipe and flow in the line.
Running the 8714i Meter Verification test under this condition provides the
ability to verify the magnetic flowmeter health without shutting down the
process flow in applications where a shutdown is not possible. Running the
calibration verification under flowing conditions can cause false fails if the flow
rate is not at a steady flow, or if there is process noise present.
Empty Pipe
Run the 8714i Meter Verification test with an empty pipe. Running the 8714i
Meter Verification test under this condition provides the ability to verify the
magnetic flowmeter health with an empty pipe. Running the calibration
verification under empty pipe conditions will not check the electrode circuit
health.
8714i Meter Verification Test Criteria
The 8714i Meter Verification diagnostic provides the ability for the user to
define the test criteria that the verification must test to. The test criteria can be
set for each of the flow conditions discussed above.
No Flow
Set the test criteria for the No Flow condition. The factory default for this value
is set to two percent with limits configurable between one and ten percent.
Flowing, Full
Set the test criteria for the Flowing, Full condition. The factory default for this
value is set to three percent with limits configurable between one and ten
percent.
375 Transducer Block, Diagnostics, Diagnostic Variables, Line Noise
AMS Tab 8714i
375 Transducer Block, Diagnostics, Advanced Diagnostics, 8714i Meter Verification,
Set Pass/Fail Criteria, No Flow Limit
AMS Tab 8714i
375 Transducer Block, Diagnostics, Advanced Diagnostics, 8714i Meter Verification,
Set Pass/Fail Criteria, Flowing Limit
AMS Tab 8714i
Reference Manual
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January 2010
Rosemount 8732
C-10
Empty Pipe
Set the test criteria for the Empty Pipe condition. The factory default for this
value is set to three percent with limits configurable between one and ten
percent.
8714i Meter Verification Test Scope
The 8714i Meter Verification can be used to verify the entire flowmeter
installation, or individual parts such as the transmitter or sensor. This
parameter is set at the time that the 8714i Meter Verification test is initiated.
All
Run the 8714i Meter Verification test and verify the entire flowmeter
installation. This parameter results in the verification test performing the
transmitter calibration verification, sensor calibration verification, coil health
check, and electrode health check. Transmitter calibration and sensor
calibration are verified to the percentage associated with the test condition
selected when the test was initiated.
Transmitter
Run the 8714i Meter Verification test on the transmitter only. This results in
the verification test only checking the transmitter calibration to the limits of the
test criteria selected when the 8714i Meter Verification test was initiated.
Sensor
Run the 8714i Meter Verification test on the sensor only. This results in the
verification test checking the sensor calibration to the limits of the test criteria
selected when the 8714i Meter Verification test was initiated, verifying the coil
circuit health, and the electrode circuit health.
8714i Meter Verification
Test Results Parameters Once the 8714i Meter Verification test is initiated, the transmitter will make
several measurements to verify the transmitter calibration, sensor calibration,
coil circuit health, and electrode circuit health. The results of these tests can
be reviewed and recorded on the calibration verification report found on
page C-16. This report can be used to validate that the meter is within the
required calibration limits to comply with governmental regulatory agencies
such as the Environmental Protection Agency or Food and Drug
Administration.
375 Transducer Block, Diagnostics, Advanced Diagnostics, 8714i Meter Verification,
Set Pass/Fail Criteria, Empty Pipe Limit
AMS Tab 8714i
375 Transducer Block, Diagnostics, Advanced Diagnostics, 8714i Meter Verification,
Run 8714i
AMS Tab Context Menu, Diagnostics and Tests, 8714i Meter Verification
375 Transducer Block, Diagnostics, Advanced Diagnostics, 8714i Meter Verification,
Run 8714i
AMS Tab Context Menu, Diagnostics and Tests, 8714i Meter Verification
375 Transducer Block, Diagnostics, Advanced Diagnostics, 8714i Meter Verification,
Run 8714i
AMS Tab Context Menu, Diagnostics and Tests, 8714i Meter Verification
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January 2010
C-11
Rosemount 8732
Viewing the 8714i Meter Verification Results
Depending on the method used to view the results, they will be displayed in
either a menu structure, as a method, or in the report format. When using the
375 Field Communicator, each individual component can be viewed as a
menu item. In AMS, the calibration report is populated with the necessary
data eliminating the need to manually complete the report found on
page C-16.
NOTE
When using AMS there are two possible methods that can be used to print the
report. Method one involves taking a screen capture of the 8714i Report tab.
Using Ctrl + Alt + PrntScrn will capture the active window and allow for
pasting of the report directly into a word processing program.
Method two involves using the print feature within AMS while on the status
screen. This will result in a printout of all of the information stored on the
status tabs. Page two of the report will contain all of the necessary calibration
verification result data.
The results are displayed in the following order:
Test Condition
Review the test condition that the 8714i Meter Verification test was performed
under.
Test Criteria
Review the test criteria used to determine the results of the 8714i Meter
Verification tests.
8714i Result
Displays the overall result of the 8714i Meter Verification test as either a Pass
or Fail.
Simulated Velocity
Displays the simulated velocity used to verify the transmitter calibration.
375 Transducer Block, Diagnostics, Advanced Diagnostics, 8714i Meter Verification,
8714i Results, Test Condition
AMS Tab Context Menu, Device Diagnostics, 8714i Report
375 Transducer Block, Diagnostics, Advanced Diagnostics, 8714i Meter Verification,
8714i Results, Test Criteria
AMS Tab Context Menu, Device Diagnostics, 8714i Report
375 Transducer Block, Diagnostics, Advanced Diagnostics, 8714i Meter Verification,
8714i Results, 8714i Result
AMS Tab Context Menu, Device Diagnostics, 8714i Report
375 Transducer Block, Diagnostics, Advanced Diagnostics, 8714i Meter Verification,
8714i Results, Simulated Vel
AMS Tab Context Menu, Device Diagnostics, 8714i Report
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Rosemount 8732
C-12
Actual Velocity
Displays the velocity measured by the transmitter during the transmitter
calibration verification process.
Velocity Deviation
Displays the deviation in the actual velocity compared to the simulated
velocity in terms of a percentage. This percentage is then compared to the
test criteria to determine if the transmitter is within calibration limits.
Transmitter Calibration Verification
Displays the results of the transmitter calibration verification test as either a
Pass or Fail.
Sensor Calibration Deviation
Displays the deviation in the sensor calibration. This value tells how much the
sensor calibration has shifted from the original baseline signature. This
percentage is compared to the test criteria to determine if the sensor is within
calibration limits.
Sensor Calibration Verification
Displays the results of the sensor calibration verification test as either a Pass
or Fail.=
Coil Circuit Verification
Displays the results of the coil circuit health check as either a Pass or Fail.
Electrode Circuit Verification
Displays the results of the electrode circuit health check as either a Pass or
Fail.
375 Transducer Block, Diagnostics, Advanced Diagnostics, 8714i Meter Verification,
8714i Results, Actual Velocity
AMS Tab Context Menu, Device Diagnostics, 8714i Report
375 Transducer Block, Diagnostics, Advanced Diagnostics, 8714i Meter Verification,
8714i Results, Velocity Dev
AMS Tab Context Menu, Device Diagnostics, 8714i Report
375 Transducer Block, Diagnostics, Advanced Diagnostics, 8714i Meter Verification,
8714i Results, Xmtr Cal Result
AMS Tab Context Menu, Device Diagnostics, 8714i Report
375 Transducer Block, Diagnostics, Advanced Diagnostics, 8714i Meter Verification,
8714i Results, Sensor Cal Dev
AMS Tab Context Menu, Device Diagnostics, 8714i Report
375 Transducer Block, Diagnostics, Advanced Diagnostics, 8714i Meter Verification,
8714i Results, Sensor Cal Rslt
AMS Tab Context Menu, Device Diagnostics, 8714i Report
375 Transducer Block, Diagnostics, Advanced Diagnostics, 8714i Meter Verification,
8714i Results, Coil Ckt Result
AMS Tab Context Menu, Device Diagnostics, 8714i Report
375 Transducer Block, Diagnostics, Advanced Diagnostics, 8714i Meter Verification,
8714i Results, Electrode Ckt Res
AMS Tab Context Menu, Device Diagnostics, 8714i Report
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January 2010
C-13
Rosemount 8732
Optimizing the 8714i
Meter Verification The 8714i Meter Verification diagnostic can be optimized by setting the test
criteria to the desired levels necessary to meet the compliance requirements
of the application. The following examples below will provide some guidance
on how to set these levels.
Example
An effluent meter must be certified every year to comply with Environmental
Protection Agency and Pollution Control Agency standards. These
governmental agencies require that the meter be certified to five percent
accuracy.
Since this is an effluent meter, shutting down the process may not be viable.
In this instance the 8714i Meter Verification test will be performed under
flowing conditions. Set the test criteria for Flowing, Full to five percent to meet
the requirements of the governmental agencies.
Example
A pharmaceutical company requires semi-annual verification of meter
calibration on a critical feed line for one of their products. This is an internal
standard, but plant requirements require a calibration record be kept on-hand.
Meter calibration on this process must meet one percent. The process is a
batch process so it is possible to perform the calibration verification with the
line full and with no flow.
Since the 8714i Meter Verification test can be run under no flow conditions,
set the test criteria for No Flow to one percent to comply with the necessary
plant standards.
Example
A food and beverage company requires an annual verification of a meter on a
product line. The plant standard calls for the accuracy to be three percent or
better. They manufacture this product in batches, and the measurement
cannot be interrupted when a batch is in process. When the batch is
complete, the line goes empty.
Since there is no means of performing the 8714i Meter Verification test while
there is product in the line, the test must be performed under empty pipe
conditions. The test criteria for Empty Pipe should be set to three percent, and
it should be noted that the electrode circuit health cannot be verified.
Reference Manual
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January 2010
Rosemount 8732
C-14
Troubleshooting the
8714i Meter Verification
Test
In the event that the 8714i Meter Verification test fails, the following steps can
be used to determine the appropriate course of action. Begin by reviewing the
8714i results to determine the specific test that failed.
Figure C-1. Troubleshooting the
8714i Meter Verification Test
Table
8714i Meter Verification
Functionality The 8714i Meter Verification diagnostic functions by taking a baseline sensor
signature and then comparing measurements taken during the verification
test to these baseline results.
Sensor Signature Values
The sensor signature describes the magnetic behavior of the sensor. Based
on Faraday’s law, the induced voltage measured on the electrodes is
proportional to the magnetic field strength. Thus, any changes in the magnetic
field will result in a calibration shift of the sensor. Having the transmitter take
an initial sensor signature when first installed will provide the baseline for the
verification tests that are done in the future. There are three specific
measurements that are stored in the transmitter’s non-volatile memory that
are used when performing the calibration verification.
Coil Circuit Resistance
The Coil Circuit Resistance is a measurement of the coil circuit health. This
value is used as a baseline to determine if the coil circuit is still operating
correctly when the 8714i Meter Verification diagnostic is initiated.
Coil Signature
The Coil Signature is a measurement of the magnetic field strength. This
value is used as a baseline to determine if a sensor calibration shift has
occurred when the 8714i Meter Verification diagnostic is initiated.
Test Potential Causes of Failure Steps to Correct
Transmitter Verification Test
Failed Unstable flow rate during
the verification test
Noise in the process
Transmitter drift
Faulty electronics
Perform the test with no
flow in the pipe
Check calibration with an
external standard like the
8714D
Perform a digital trim
Replace the electronics
Sensor Verification Failed Moisture in the terminal
block of the sensor
Calibration shift caused by
heat cycling or vibration
Remove the sensor and
send back for recalibration.
Coil Circuit Health Failed Moisture in the terminal
block of the sensor
Shorted Coil
Perform the sensor checks
detailed on page 6-8.
Electrode Circuit Health
Failed Moisture in the terminal
block of the sensor
Coated Electrodes
Shorted Electrodes
Perform the sensor checks
detailed on page 6-8.
375 Transducer Block, Diagnostics, Advanced Diagnostics, 8714i Meter Verification,
Sensor Signature, Signature Values, Coil Resistance
AMS Tab Config/Setup, 8714i
375 Transducer Block, Diagnostics, Advanced Diagnostics, 8714i Meter Verification,
Sensor Signature, Signature Values, Coil Signature
AMS Tab Config/Setup, 8714i
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January 2010
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Rosemount 8732
Electrode Circuit Resistance
The Electrode Circuit Resistance is a measurement of the electrode circuit
health. This value is used as a baseline to determine if the electrode circuit is
still operating correctly when the 8714i Meter Verification diagnostic is
initiated.
8714i Meter Verification Measurements
The 8714i Meter Verification test will make measurements of the coil
resistance, coil signature, and electrode resistance and compare these values
to the values taken during the sensor signature process to determine the
sensor calibration deviation, the coil circuit health, and the electrode circuit
health. In addition, the measurements taken by this test can provide additional
information when troubleshooting the meter.
Coil Circuit Resistance
The Coil Circuit Resistance is a measurement of the coil circuit health. This
value is compared to the coil circuit resistance baseline measurement taken
during the sensor signature process to determine coil circuit health.
Coil Signature
The Coil Signature is a measurement of the magnetic field strength. This
value is compared to the coil signature baseline measurement taken during
the sensor signature process to determine sensor calibration deviation.
Electrode Circuit Resistance
The Electrode Circuit Resistance is a measurement of the electrode circuit
health. This value is compared to the electrode circuit resistance baseline
measurement taken during the sensor signature process to determine
electrode circuit health.
375 Transducer Block, Diagnostics, Advanced Diagnostics, 8714i Meter Verification,
Sensor Signature, Signature Values, Electrode Resistance
AMS Tab Config/Setup, 8714i
375 Transducer Block, Diagnostics, Advanced Diagnostics, 8714i Meter Verification,
Measurements, Coil Resistance
AMS Tab Config/Setup, 8714i
375 Transducer Block, Diagnostics, Advanced Diagnostics, 8714i Meter Verification,
Measurements, Coil Signature
AMS Tab Config/Setup, 8714i
375 Transducer Block, Diagnostics, Advanced Diagnostics, 8714i Meter Verification,
Measurements, Electrode Resistance
AMS Tab Config/Setup, 8714i
Reference Manual
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January 2010
Rosemount 8732
C-16
ROSEMOUNT MAGNETIC FLOWMETER CALIBRATION VERIFICATION REPORT
Calibration Verification Report Parameters
User Name: _____________________________________________
Calibration Conditions: Internal External
Tag #:__________________________________________________
Test Conditions: Flowing No Flow, Full Pipe Empty Pipe
Flowmeter Information and Configuration
Software Tag:____________________________________________ PV URV (20 mA scale):____________________________________
Calibration Number:_______________________________________ PV LRV (4 mA scale):_____________________________________
Line Size:_______________________________________________ PV Damping:____________________________________________
Transmitter Calibration Verification Results Sensor Calibration Verification Results
Simulated Velocity:_______________________________________ Sensor Deviation %:_____________________________________
Actual Velocity:__________________________________________ Sensor: PASS / FAIL / NOT TESTED
Deviation %:____________________________________________ Coil Circuit Test: PASS / FAIL / NOT TESTED
Transmitter: PASS / FAIL / NOT TESTED Electrode Circuit Test: PASS / FAIL / NOT TESTED
Summary of Calibration Verification Results
Verification Results: The result of the flowmeter verification test is: PASSED / FAILED
Verification Criteria: This meter was verified to be functioning within _____________ % of deviation from the original test parameters.
Signature:______________________________________________ Date:__________________________________________________
Reference Manual
00809-0100-4663, Rev BA
January 2010 Rosemount 8732
www.rosemount.com
Appendix D Digital Signal Processing
Safety Messages . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . page D-1
Procedures . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . page D-2
SAFETY MESSAGES Instructions and procedures in this section may require special precautions to
ensure the safety of the personnel performing the operations. Please read the
following safety messages before performing any operation described in this
section.
Warnings
Explosions could result in death or serious injury:
Verify that the operating atmosphere of the sensor and transmitter is consistent
with the appropriate hazardous locations certifications.
Do not remove the transmitter cover in explosive atmospheres when the circuit is
alive.
Before connecting a Field Communicator in an explosive atmosphere, make sure
the instruments in the loop are installed in accordance with intrinsically safe or
non-incendive field wiring practices.
Both transmitter covers must be fully engaged to meet explosion-proof
requirements.
Failure to follow safe installation and servicing guidelines could result in death or
serious injury:
Make sure only qualified personnel perform the installation.
Do not perform any service other than those contained in this manual unless
qualified.
Process leaks could result in death or serious injury:
The electrode compartment may contain line pressure; it must be depressurized
before the cover is removed.
High voltage that may be present on leads could cause electrical shock:
Avoid contact with leads and terminals.
Reference Manual
00809-0100-4663, Rev BA
January 2010
Rosemount 8732
D-2
PROCEDURES If the output of your Rosemount 8732 is unstable, first check the wiring and
grounding associated with the magnetic flowmeter system. Ensure that the
following conditions are met:
Ground straps are attached to the adjacent flange or ground ring?
Grounding rings, lining protectors, or grounding electrodes are being
used in lined or nonconductive piping?
Both of the shields are attached at both ends?
The causes of unstable transmitter output can usually be traced to extraneous
voltages on the measuring electrodes. This “process noise” can arise from
several causes including electrochemical reactions between the fluid and the
electrode, chemical reactions in the process itself, free ion activity in the fluid,
or some other disturbance of the fluid/electrode capacitive layer. In such noisy
applications, an analysis of the frequency spectrum reveals process noise
that typically becomes significant below 15 Hz.
In some cases, the effects of process noise may be sharply reduced by
elevating the coil drive frequency above the 15 Hz region. The Rosemount
8732 coil drive mode is selectable between the standard 5 Hz and the
noise-reducing 37 Hz. See “Coil Drive Frequency” on page 4-26 for
instructions on how to change the coil drive mode to 37 Hz.
Auto Zero To ensure optimum accuracy when using 37 Hz coil drive mode, there is an
auto zero function that must be initiated during start-up. The auto zero
operation is also discussed in the start-up and configuration sections. When
using 37 Hz coil drive mode it is important to zero the system for the specific
application and installation.
The auto zero procedure should be performed only under
the following conditions:
With the transmitter and sensor installed in their final positions. This
procedure is not applicable on the bench.
With the transmitter in 37 Hz coil drive mode. Never attempt this
procedure with the transmitter in 5 Hz coil drive mode.
With the sensor full of process fluid at zero flow.
These conditions should cause an output equivalent to zero flow.
Signal Processing If the 37 Hz coil drive mode has been set, and the output is still unstable, the
damping and signal processing function should be used. It is important to set
the coil drive mode to 37 Hz first, so the loop response time is not increased.
The 8732 provides for a very easy and straightforward start-up, and also
incorporates the capability to deal with difficult applications that have
previously manifested themselves in a noisy output signal. In addition to
selecting a higher coil drive frequency (37 Hz vs. 5 Hz) to isolate the flow
signal from the process noise, the 8732 microprocessor can actually
scrutinize each input based on three user-defined parameters to reject the
noise specific to the application.
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January 2010
D-3
Rosemount 8732
This software technique, known as signal processing, “qualifies” individual
flow signals based on historic flow information and three user-definable
parameters, plus an on/off control. These parameters are:
1. Number of samples: The number of samples function sets the amount
of time that inputs are collected and used to calculate the average
value. Each second is divided into tenths (1/10 ) with the number of
samples equaling the number of 1/10 second increments used to
calculate the average. Factory Preset Value = 90 samples.
For example, a value of:
1 averages the inputs over the past 1/10 second
10 averages the inputs over the past 1 second
100 averages the inputs over the past 10 seconds
125 averages the inputs over the past 12.5 seconds
2. Maximum Percent Limit: The tolerance band set up on either side of
the running average, referring to percent deviation from the average.
Values within the limit are accepted while value outside the limit are
scrutinized to determine if they are a noise spike or an actual flow
change. Factory Preset Value = 2 percent.
3. Time Limit: Forces the output and running average values to the new
value of an actual flow rate change that is outside the percent limit
boundaries, thereby limiting response time to real flow changes to the
time limit value rather than the length of the running average. Factory
Preset Value = 2 seconds.
How Does It Really Work?
The best way to explain this is with the help of an example, plotting flow rate
versus time
Figure D-1. Signal Processing .
Flow
Rate
Max
%
Limit
Time Limit
12 Samples = 1
Second Time
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January 2010
Rosemount 8732
D-4
x: Input flow signal from sensor.
o: Average flow signals and transmitter output, determined by the “number
of samples” parameter.
Tolerance band, determined by the “percent limit” parameter.
– Upper value = average flow + [(percent limit/100) average flow]
– Lower value = average flow – [(percent limit/100) average flow]
1. This scenario is that of a typical non-noisy flow. The input flow signal
is within the percent limit tolerance band, therefore qualifying itself as
a good input. In this case the new input is added directly into the
running average and is passed on as a part of the average value to
the output.
2. This signal is outside the tolerance band and therefore is held in
memory until the next input can be evaluated. The running average is
provided as the output.
3. The previous signal currently held in memory is simply rejected as a
noise spike since the next flow input signal is back within the
tolerance band. This results in complete rejection of noise spikes
rather than allowing them to be “averaged” with the good signals as
occurs in the typical analog damping circuits.
4. As in number 2 above, the input is outside the tolerance band. This
first signal is held in memory and compared to the next signal. The
next signal is also outside the tolerance band (in the same direction),
so the stored value is added to the running average as the next input
and the running average begins to slowly approach the new input
level.
5. To avoid waiting for the slowly incrementing average value to catch
up to the new level input, a shortcut is provided. This is the “time limit”
parameter. The user can set this parameter to eliminate the slow
ramping of the output toward the new input level.
When Should Signal Processing Be Used?
The Rosemount 8732 offers three separate functions that can be used in
series for improving a noisy output. The first step is to toggle the coil drive to
the 37 Hz mode and initialize with an auto zero. If the output is still noisy at
this stage, signal processing should be actuated and, if necessary, tuned to
match the specific application. Finally, if the signal is still too unstable, the
traditional damping function can be used.
NOTE
Failure to complete an Auto Zero will result in a small (<1%) error in the
output. While the output level will be offset by the error, the repeatability will
not be affected.
Reference Manual
00809-0100-4663, Rev BA
January 2010 Rosemount 8732
www.rosemount.com
Appendix E Universal Sensor Wiring
Diagrams
Rosemount Sensors . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . page E-3
Brooks Sensors . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . page E-6
Endress And Hauser Sensors . . . . . . . . . . . . . . . . . . . . . . page E-8
Fischer And Porter Sensors . . . . . . . . . . . . . . . . . . . . . . . page E-9
Foxboro Sensors . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . page E-15
Kent Veriflux VTC Sensor . . . . . . . . . . . . . . . . . . . . . . . . . page E-19
Kent Sensors . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . page E-20
Krohne Sensors . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . page E-21
Taylor Sensors . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . page E-22
Yamatake Honeywell Sensors . . . . . . . . . . . . . . . . . . . . . . page E-24
Yokogawa Sensors . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . page E-25
Generic Manufacturer Sensors . . . . . . . . . . . . . . . . . . . . . page E-26
The wiring diagrams in this section illustrate the proper connections between
the Rosemount 8732 and most sensors currently on the market. Specific
diagrams are included for most models, and where information for a particular
model of a manufacturer is not available, a generic drawing pertaining to that
manufacturers’ sensors is provided. If the manufacturer for your sensor is not
included, see the drawing for generic connections.
Any trademarks used herein regarding sensors not manufactured by
Rosemount are owned by the particular manufacturer of the sensor.
Reference Manual
00809-0100-4663, Rev BA
January 2010
Rosemount 8732
E-2
Table E-1. Sensor Cross
References Rosemount Transmitter Sensor Manufacturer Page Number
Rosemount
Rosemount 8732 Rosemount 8705, 8707, 8711 page E-3
Rosemount 8732 Rosemount 8701 page E-4
Brooks
Rosemount 8732 Model 5000 page E-6
Rosemount 8732 Model 7400 page E-7
Endress and Hauser page E-5
Rosemount 8732 Generic Wiring for Sensor page E-8
Fischer and Porter page E-9
Rosemount 8732 Model 10D1418 page E-9
Rosemount 8732 Model 10D1419 page E-10
Rosemount 8732 Model 10D1430 (Remote) page E-11
Rosemount 8732 Model 10D1430 page E-12
Rosemount 8732 Model 10D1465, 10D1475 (Integral) page E-13
Rosemount 8732 Generic Wiring for Sensors page E-14
Foxboro
Rosemount 8732 Series 1800 page E-15
Rosemount 8732 Series 1800 (Version 2) page E-16
Rosemount 8732 Series 2800 page E-17
Rosemount 8732 Generic Wiring for Sensors page E-18
Kent
Rosemount 8732 Veriflux VTC page E-19
Rosemount 8732 Generic Wiring for Sensors page E-20
Krohne
Rosemount 8732 Generic Wiring for Sensors page E-21
Taylor
Rosemount 8732 Series 1100 page E-23
Rosemount 8732 Generic Wiring for Sensors page E-23
Yamatake Honeywell
Rosemount 8732 Generic Wiring for Sensors page E-24
Yokogawa
Rosemount 8732 Generic Wiring for Sensors page E-25
Generic Manufacturer Wiring page E-26
Rosemount 8732 Generic Wiring for Sensors page E-26
Reference Manual
00809-0100-4663, Rev BA
January 2010
E-3
Rosemount 8732
ROSEMOUNT SENSORS
Rosemount
8705/8707/8711/8721
Sensors to Rosemount
8732 Transmitter
Connect coil drive and electrode cables as shown in Figure .
Figure E-1. Wiring Diagram to a
Rosemount 8732 Transmitter
Table E-2. Rosemount
8705/8707/8711/8721 Sensor
Wiring Connections Rosemount 8732 Transmitters Rosemount 8705/8707/8711/8721 Sensors
11
2 2
17 17
18 18
19 19
This is a pulsed DC magnetic flowmeter.
Do not connect AC power to the sensor
or to terminals 1 and 2 of the
transmitter, or replacement of the
electronics board will be necessary.
Reference Manual
00809-0100-4663, Rev BA
January 2010
Rosemount 8732
E-4
Rosemount 8701 Sensor
to Rosemount 8732
Transmitter
Connect coil drive and electrode cables as shown in Figure E-2 on page E-4.
Figure E-2. Wiring Diagram for
Rosemount 8701 Sensor and
Rosemount 8732 Transmitter
Table E-3. Rosemount 8701
Sensor Wiring Connections
2
1
19
18
17
ROSEMOUNT 8701
SENSOR ROSEMOUNT 8732
TRANSMITTER
Rosemount 8732 Rosemount 8701 Sensors
11
2 2
17 17
18 18
19 19
This is a pulsed DC magnetic flowmeter.
Do not connect AC power to the sensor
or to terminals 1 and 2 of the
transmitter, or replacement of the
electronics board will be necessary.
Reference Manual
00809-0100-4663, Rev BA
January 2010
E-5
Rosemount 8732
Connecting Sensors of
Other Manufacturers Before connecting another manufacturer’s sensor to the Rosemount 8732
transmitter, it is necessary to perform the following functions.
1. Turn off the AC power to the sensor and transmitter. Failure to do so
could result in electrical shock or damage to the transmitter.
2. Verify that the coil drive cables between the sensor and the
transmitter are not connected to any other equipment.
3. Label the coil drive cables and electrode cables for connection to the
transmitter.
4. Disconnect the wires from the existing transmitter.
5. Remove the existing transmitter. Mount the new transmitter. See
“Mount the Transmitter” on page 2-3.
6. Verify that the sensor coil is configured for series connection. Other
manufacturers sensors may be wired in either a series or parallel
circuit. All Rosemount magnetic sensors are wired in a series circuit.
(Other manufacturers AC sensors (AC coils) wired for 220V operation
are typically wired in parallel and must be rewired in series.)
7. Verify that the sensor is in good working condition. Use the
manufacturer’s recommended test procedure for verification of
sensor condition. Perform the basic checks:
a. Check the coils for shorts or open circuits.
b. Check the sensor liner for wear or damage.
c. Check the electrodes for shorts, leaks, or damage.
8. Connect the sensor to the transmitter in accordance with reference
wiring diagrams. See Appendix E: Universal Sensor Wiring Diagrams
for specific drawings.
9. Connect and verify all connections between the sensor and the
transmitter, then apply power to the transmitter.
10. Perform the Universal Auto Trim function.
This is a pulsed DC magnetic flowmeter. Do not connect
AC power to the sensor or to terminals 1 and 2 of the
transmitter, or replacement of the electronics board will be
necessary.
Reference Manual
00809-0100-4663, Rev BA
January 2010
Rosemount 8732
E-6
BROOKS SENSORS Connect coil drive and electrode cables as shown in Figure E-3.
Model 5000 Sensor to
Rosemount 8732
Transmitter
Figure E-3. Wiring Diagram for
Brooks Sensor Model 5000 and
Rosemount 8732
Table E-4. Brooks Model 5000
Sensor Wiring Connections
BROOKS MODEL
5000
ROSEMOUNT 8732
TRANSMITTER
Rosemount 8732 Brooks Sensors Model 5000
11
2 2
17 17
18 18
19 19
This is a pulsed DC magnetic flowmeter.
Do not connect AC power to the sensor
or to terminals 1 and 2 of the
transmitter, or replacement of the
electronics board will be necessary.
Reference Manual
00809-0100-4663, Rev BA
January 2010
E-7
Rosemount 8732
Model 7400 Sensor to
Rosemount 8732
Transmitter
Connect coil drive and electrode cables as shown in Figure E-4.
Figure E-4. Wiring Diagram for
Brooks Sensor Model 7400 and
Rosemount 8732
Table E-5. Brooks Model 7400
Sensor Wiring Connections
BROOKS MODEL 7400
ROSEMOUNT 8732
TRANSMITTER
Rosemount 8732 Brooks Sensors Model 7400
1 Coils +
2Coils –
17 Shield
18 Electrode +
19 Electrode –
This is a pulsed DC magnetic flowmeter.
Do not connect AC power to the sensor
or to terminals 1 and 2 of the
transmitter, or replacement of the
electronics board will be necessary.
Reference Manual
00809-0100-4663, Rev BA
January 2010
Rosemount 8732
E-8
ENDRESS AND HAUSER
SENSORS Connect coil drive and electrode cables as shown in Figure E-5.
Endress and Hauser
Sensor to
Rosemount 8732
Transmitter
Figure E-5. Wiring Diagram for
Endress and Hauser Sensors
and Rosemount 8732
Table E-6. Endress and Hauser
Sensor Wiring Connections
41
42
4
5
7
Electrodes
Coils
ROSEMOUNT 8732
TRANSMITTER
ENDRESS AND HAUSER
SENSORS
Rosemount 8732 Endress and Hauser Sensors
141
242
14
17 4
18 5
19 7
This is a pulsed DC magnetic flowmeter.
Do not connect AC power to the sensor
or to terminals 1 and 2 of the
transmitter, or replacement of the
electronics board will be necessary.
Reference Manual
00809-0100-4663, Rev BA
January 2010
E-9
Rosemount 8732
FISCHER AND PORTER
SENSORS Connect coil drive and electrode cables as shown in Figure E-6.
Model 10D1418 Sensor
to Rosemount 8732
Transmitter
Figure E-6. Wiring Diagram for
Fischer and Porter Sensor
Model 10D1418 and
Rosemount 8732
Table E-7. Fischer and Porter
Model 10D1418 Sensor Wiring
Connections
ROSEMOUNT 8732 TRANSMITTER
Electrode Connections
U1
U2
G
8
6
7
L1
L2
5
3
2
1
Coil Connections
Rosemount 8732 Fischer and Porter Model 10D1418 Sensors
1L1
2L2
Chassis Ground
17 3
18 1
19 2
This is a pulsed DC magnetic flowmeter.
Do not connect AC power to the sensor
or to terminals 1 and 2 of the
transmitter, or replacement of the
electronics board will be necessary.
Reference Manual
00809-0100-4663, Rev BA
January 2010
Rosemount 8732
E-10
Model 10D1419 Sensor
to Rosemount 8732
Transmitter
Connect coil drive and electrode cables as shown in Figure E-7.
Figure E-7. Wiring Diagram for
Fischer and Porter Sensor
Model 10D1419 and Rosemount
8732
Table E-8. Fischer and Porter
Model 10D1419 Sensor Wiring
Connections
ROSEMOUNT 8732 TRANSMITTER
3
2
1
18
L1
L2
16
17
Electrode Connections
Coil Connections
Rosemount 8732 Fischer and Porter Model 10D1419 Sensors
1L1
2L2
3
17 3
18 1
19 2
This is a pulsed DC magnetic flowmeter.
Do not connect AC power to the sensor
or to terminals 1 and 2 of the
transmitter, or replacement of the
electronics board will be necessary.
Reference Manual
00809-0100-4663, Rev BA
January 2010
E-11
Rosemount 8732
Model 10D1430 Sensor
(Remote) to
Rosemount 8732
Transmitter
Connect coil drive and electrode cables as shown in Figure E-8.
Figure E-8. Wiring Diagram for
Fischer and Porter Sensor
Model 10D1430 (Remote) and
Rosemount 8732
Table E-9. Fischer and Porter
Model 10D1430 (Remote)
Sensor Wiring Connections
ROSEMOUNT 8732 TRANSMITTER
1
2
3
G
L1
8
Coil Connections
Electrode Connections
Rosemount 8732 Fischer and Porter Model 10D1430 (Remote)
Sensors
1L1
2 8
G
17 3
18 1
19 2
This is a pulsed DC magnetic flowmeter.
Do not connect AC power to the sensor
or to terminals 1 and 2 of the
transmitter, or replacement of the
electronics board will be necessary.
Reference Manual
00809-0100-4663, Rev BA
January 2010
Rosemount 8732
E-12
Model 10D1430 Sensor
(Integral) to
Rosemount 8732
Transmitter
Connect coil drive and electrode cables as shown in Figure E-9.
Figure E-9. Wiring Diagram for
Fischer and Porter Sensor
Model 10D1430 (Integral) and
Rosemount 8732
Table E-10. Fischer and Porter
Model 10D1430 (Integral)
Sensor Wiring Connections
Electrode Connections ROSEMOUNT 8732 TRANSMITTER
To L2
1
2
3
7
6
8
L2
L1
U2
U1
1
2
3
7
6
L2
L1
U2
U1
G
TB1
TB2
Coil Connections
To Calibration Device
(Disconnect)
Rosemount 8732 Fischer and Porter Model 10D1430 (Integral)
Sensors
1L1
2L2
G
17 3
18 1
19 2
This is a pulsed DC magnetic flowmeter.
Do not connect AC power to the sensor
or to terminals 1 and 2 of the
transmitter, or replacement of the
electronics board will be necessary.
Reference Manual
00809-0100-4663, Rev BA
January 2010
E-13
Rosemount 8732
Model 10D1465 and
Model 10D1475 Sensors
(Integral) to 8732
Transmitter
Connect coil drive and electrode cables as shown in Figure E-10.
Figure E-10. Wiring Diagram for
Fischer and Porter Sensor
Model 10D1465 and Model
10D1475 (Integral) and
Rosemount 8732
Table E-11. Fischer and Porter
Model 10D1465 and 10D1475
Sensor Wiring Connections
2A
2
1
5
6
16
3
CT
M2
M1
MR
Electrode
Connections
Coil Connections
ROSEMOUNT 8732 TRANSMITTER
Disconnect
Rosemount 8732 Fischer and Porter Model 10D1465 and
10D1475 Sensors
1MR
2M1
3
17 3
18 1
19 2
This is a pulsed DC magnetic flowmeter.
Do not connect AC power to the sensor
or to terminals 1 and 2 of the
transmitter, or replacement of the
electronics board will be necessary.
Reference Manual
00809-0100-4663, Rev BA
January 2010
Rosemount 8732
E-14
Fischer and Porter
Sensor to
Rosemount 8732
Transmitter
Connect coil drive and electrode cables as shown in Figure E-11.
Figure E-11. Generic Wiring
Diagram for Fischer and Porter
Sensors and Rosemount 8732
Table E-12. Fischer and Porter
Generic Sensor
Wiring Connections
Electrodes
2
Coils
Chassis
ROSEMOUNT 8732
TRANSMITTER
FISCHER AND PORTER
SENSORS
Fuse
1
3
M2
M1
Rosemount 8732 Fischer and Porter Sensors
1M1
2M2
Chassis Ground
17 3
18 1
19 2
This is a pulsed DC magnetic flowmeter.
Do not connect AC power to the sensor
or to terminals 1 and 2 of the
transmitter, or replacement of the
electronics board will be necessary.
Reference Manual
00809-0100-4663, Rev BA
January 2010
E-15
Rosemount 8732
FOXBORO SENSORS Connect coil drive and electrode cables as shown in Figure E-12.
Series 1800 Sensor to
Rosemount 8732
Transmitter
Figure E-12. Wiring Diagram for
Foxboro Series 1800 and
Rosemount 8732
Table E-13. Foxboro Generic
Sensor Wiring Connections
ROSEMOUNT 8732
TRANSMITTER
Coil Connections
Electrode Connections
FOXBORO SERIES
1800 SENSOR
Outer Shield
White Lead
White Shield
Black Lead
Black Shield
Inner Shield
Rosemount 8732 Foxboro Series 1800 Sensors
1L1
2L2
Chassis Ground
17 Any Shield
18 Black
19 White
This is a pulsed DC magnetic flowmeter.
Do not connect AC power to the sensor
or to terminals 1 and 2 of the
transmitter, or replacement of the
electronics board will be necessary.
Reference Manual
00809-0100-4663, Rev BA
January 2010
Rosemount 8732
E-16
Series 1800 (Version 2)
Sensor to
Rosemount 8732
Transmitter
Connect coil drive and electrode cables as shown in Figure E-13.
Figure E-13. Wiring Diagram for
Foxboro Series 1800 (Version 2)
and Rosemount 8732
Table E-14. Foxboro Generic
Sensor Wiring Connections
FOXBORO SERIES
1800 SENSOR
(VERSION 2)
ROSEMOUNT
8732
TRANSMITTER
Coil Connections
Electrode
Connections
GND L2 L1
White Black Shield
Rosemount 8732 Foxboro Series 1800 Sensors
1L1
2L2
Chassis Ground
17 Any Shield
18 Black
19 White
This is a pulsed DC magnetic flowmeter.
Do not connect AC power to the sensor
or to terminals 1 and 2 of the
transmitter, or replacement of the
electronics board will be necessary.
Reference Manual
00809-0100-4663, Rev BA
January 2010
E-17
Rosemount 8732
Series 2800 Sensor to
8732 Transmitter Connect coil drive and electrode cables as shown in Figure E-14.
Figure E-14. Wiring Diagram for
Foxboro Series 2800 and
Rosemount 8732
Table E-15. Foxboro Series
2800 Sensor Wiring
Connections
ROSEMOUNT 8732
TRANSMITTER
Coil Connections
Electrode Connections
FOXBORO SERIES
1800 SENSOR
Outer Shield
White Lead
White Shield
Black Lead
Black Shield
Inner Shield
White
Black
Any Shield
L2
L1
G
Rosemount 8732 Foxboro Series 2800 Sensors
1L1
2L2
Chassis Ground
17 Any Shield
18 Black
19 White
This is a pulsed DC magnetic flowmeter.
Do not connect AC power to the sensor
or to terminals 1 and 2 of the
transmitter, or replacement of the
electronics board will be necessary.
Reference Manual
00809-0100-4663, Rev BA
January 2010
Rosemount 8732
E-18
Foxboro Sensor to 8732
Transmitter Connect coil drive and electrode cables as shown in Figure E-15.
Figure E-15. Generic Wiring
Diagram for Foxboro Sensors
and Rosemount 8732
Table E-16. Foxboro Sensor
Wiring Connections
Electrodes
Coils
Ground
ROSEMOUNT 8732
TRANSMITTER
FOXBORO
SENSOR
L2
L1
White
Black
Any Shield
Fuse
Rosemount 8732 Foxboro Sensors
1L1
2L2
Chassis Ground
17 Any Shield
18 Black
19 White
This is a pulsed DC magnetic flowmeter.
Do not connect AC power to the sensor
or to terminals 1 and 2 of the
transmitter, or replacement of the
electronics board will be necessary.
Reference Manual
00809-0100-4663, Rev BA
January 2010
E-19
Rosemount 8732
KENT VERIFLUX VTC
SENSOR Connect coil drive and electrode cables as shown in Figure E-16.
Veriflux VTC Sensor to
8732 Transmitter
Figure E-16. Wiring Diagram for
Kent Veriflux VTC Sensor and
Rosemount 8732
Table E-17. Kent Veriflux VTC
Sensor Wiring Connections
Electrode Connections
Coil Connections
ROSEMOUNT 8732
TRANSMITTER
KENT VERIFLUX VTC
SENSOR
1SCR OUT
2
3 SIG 1
4 SIG 2
5
6
1
2–
5+
6 SCR OUT
Fuse
Rosemount 8732 Kent Veriflux VTC Sensors
12
2 1
SCR OUT
17 SCR OUT
18 SIG1
19 SIG2
This is a pulsed DC magnetic flowmeter.
Do not connect AC power to the sensor
or to terminals 1 and 2 of the
transmitter, or replacement of the
electronics board will be necessary.
Reference Manual
00809-0100-4663, Rev BA
January 2010
Rosemount 8732
E-20
KENT SENSORS Connect coil drive and electrode cables as shown in Figure E-17.
Kent Sensor to
Rosemount 8732
Transmitter
Figure E-17. Generic Wiring
Diagram for Kent Sensors and
Rosemount 8732
Table E-18. Kent Sensor
Wiring Connections
Coils
Electrodes
SCR OUT
ROSEMOUNT 8732
TRANSMITTER
KENT SENSORS
2
1
SIG2
SIG1
SCR OUT
Fuse
Rosemount 8732 Kent Sensors
11
2 2
SCR OUT
17 SCR OUT
18 SIG1
19 SIG2
This is a pulsed DC magnetic flowmeter.
Do not connect AC power to the sensor
or to terminals 1 and 2 of the
transmitter, or replacement of the
electronics board will be necessary.
Reference Manual
00809-0100-4663, Rev BA
January 2010
E-21
Rosemount 8732
KROHNE SENSORS Connect coil drive and electrode cables as shown in Figure E-18.
Krohne Sensor to
Rosemount 8732
Transmitter
Figure E-18. Generic Wiring
Diagram for Krohne Sensors
and Rosemount 8732
Table E-19. Krohne Sensor
Wiring Connections
Electrodes
Coils
Coil Shield
ROSEMOUNT 8732
TRANSMITTER
KROHNE
SENSORS
7
8
3
2
Electrode Shield
Fuse
Rosemount 8732 Krohne Sensors
18
2 7
Coil Shield
17 Electrode Shield
18 2
19 3
This is a pulsed DC magnetic flowmeter.
Do not connect AC power to the sensor
or to terminals 1 and 2 of the
transmitter, or replacement of the
electronics board will be necessary.
Reference Manual
00809-0100-4663, Rev BA
January 2010
Rosemount 8732
E-22
TAYLOR SENSORS Connect coil drive and electrode cables as shown in Figure E-19.
Series 1100 Sensor to
Rosemount 8732
Transmitter
Figure E-19. Wiring Diagram for
Taylor Series 1100 Sensors and
Rosemount 8732
Table E-20. Taylor Series 1100
Sensor Wiring Connections
ROSEMOUNT 8732
TRANSMITTER
Electrode Connections
Coil Connections
TAYLOR SERIES 1100
SENSOR
C
L
A
R
White
Black
Green
L N G 1 2 3 4
Rosemount 8732 Taylor Series 1100 Sensors
1Black
2White
Green
17 S1 and S2
18 E1
19 E2
This is a pulsed DC magnetic flowmeter.
Do not connect AC power to the sensor
or to terminals 1 and 2 of the
transmitter, or replacement of the
electronics board will be necessary.
Reference Manual
00809-0100-4663, Rev BA
January 2010
E-23
Rosemount 8732
Taylor Sensor to
Rosemount 8732
Transmitter
Connect coil drive and electrode cables as shown in Figure E-20.
Figure E-20. Generic Wiring
Diagram for Taylor Sensors and
Rosemount 8732
Table E-21. Taylor Sensor
Wiring Connections
Electrodes
Coils
Green
ROSEMOUNT 8732
TRANSMITTER
TAYLOR
SENSORS
White
Black
E2
E1
S1 and S2
Fuse
Rosemount 8732 Taylor Sensors
1Black
2White
Green
17 S1 and S2
18 E1
19 E2
This is a pulsed DCDC magnetic
flowmeter. Do not connect AC power to
the sensor or to terminals 1 and 2 of the
transmitter, or replacement of the
electronics board will be necessary.
Reference Manual
00809-0100-4663, Rev BA
January 2010
Rosemount 8732
E-24
YAMATAKE
HONEYWELL SENSORS Connect coil drive and electrode cables as shown in Figure E-21.
Yamatake Honeywell
Sensor to
Rosemount 8732
Transmitter
Figure E-21. Generic Wiring
Diagram for Yamatake
Honeywell Sensors and
Rosemount 8732
Table E-22. Yamatake
Honeywell Sensor Wiring
Connections
Electrodes
Coils
Chassis Ground
ROSEMOUNT 8732
TRANSMITTER
YAMATAKE
HONEYWELL
SENSORS
Y
X
A
B
C
Fuse
Rosemount 8732 Yamatake Honeywell Sensors
1X
2 Y
Chassis Ground
17 C
18 B
19 A
This is a pulsed DC magnetic flowmeter.
Do not connect AC power to the sensor
or to terminals 1 and 2 of the
transmitter, or replacement of the
electronics board will be necessary.
Reference Manual
00809-0100-4663, Rev BA
January 2010
E-25
Rosemount 8732
YOKOGAWA SENSORS Connect coil drive and electrode cables as shown in Figure E-22.
Yokogawa Sensor to
Rosemount 8732
Transmitter
Figure E-22. Generic Wiring
Diagram for Yokogawa Sensors
and Rosemount 8732
Table E-23. Yokogawa Sensor
Wiring Connections
Electrodes
Coils
Chassis Ground
ROSEMOUNT 8732
TRANSMITTER
YOKOGAWA
SENSORS
Ex 2
Ex 1
A
B
C
Fuse
Rosemount 8732 Yokogawa Sensors
1 EX1
2EX2
Chassis Ground
17 C
18 B
19 A
This is a pulsed DC magnetic flowmeter.
Do not connect AC power to the sensor
or to terminals 1 and 2 of the
transmitter, or replacement of the
electronics board will be necessary.
Reference Manual
00809-0100-4663, Rev BA
January 2010
Rosemount 8732
E-26
GENERIC
MANUFACTURER
SENSORS
Generic Manufacturer
Sensor to
Rosemount 8732
Transmitter
Identify the Terminals First check the sensor manufacturer’s manual to identify the appropriate
terminals. Otherwise, perform the following procedure.
Identify coil and electrode terminals
1. Select a terminal and touch an ohmmeter probe to it.
2. Touch the second probe to each of the other terminals and record the
results for each terminal.
3. Repeat the process and record the results for every terminal.
Coil terminals will have a resistance of approximately 3-300 ohms.
Electrode terminals will have an open circuit.
Identify a chassis ground
1. Touch one probe of an ohmmeter to the sensor chassis.
2. Touch the other probe to the each sensor terminal and the record the
results for each terminal.
The chassis ground will have a resistance value of one ohm or less.
Wiring Connections Connect the electrode terminals to Rosemount 8732 terminals
18 and 19. The electrode shield should be connected to terminal 17.
Connect the coil terminals to Rosemount 8732 terminals 1, 2, and .
If the Rosemount 8732 Transmitter indicates a reverse flow condition, switch
the coil wires connected to terminals 1 and 2.
This is a pulsed DC magnetic flowmeter.
Do not connect AC power to the sensor
or to terminals 1 and 2 of the
transmitter, or replacement of the
electronics board will be necessary.
Reference Manual
00809-0100-4663, Rev BA
January 2010 Rosemount 8732
www.rosemount.com
Appendix F Resource Block
Parameters and Descriptions . . . . . . . . . . . . . . . . . . . . . . page F-1
Resource Block Errors . . . . . . . . . . . . . . . . . . . . . . . . . . . . page F-5
Modes . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . page F-5
Troubleshooting . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . page F-6
This section contains information on the resource block for the
Rosemount 8732 Magnetic Flowmeter Transmitter. Descriptions of all
resource block parameters, errors, and diagnostics are included. Also, the
modes, alarm detection, status handling, virtual communication relationships
(VCRs), and troubleshooting are discussed.
Definition The resource block defines the physical resources of the device, such as
measurement and memory. The resource block also handles functionality,
such as shed times, that is common across multiple blocks. The block has no
linkable inputs or outputs, and it performs memory-level diagnostics.
PARAMETERS AND
DESCRIPTIONS Table F-1 lists all of the configurable parameters of the resource block,
including the descriptions and index numbers for each parameter. Newer
software revisions have added functionality and some index numbers have
changed. To determine the software revision of a transmitter, check the
parameter SOFTWARE_REVISION_MAJOR. The most recent transmitters
have a label on the electronic board stack.
Table F-1. Resource Block
Parameters
Index Number
Parameter Rev 5 Description
ACK_OPTION 38 ACK_OPTION is a selection of whether alarms associated with the function block
will be automatically acknowledged.
ADVISE_ACTIVE 82 Active advisory alarms.
ADVISE_ALM 83 Alarm indicating advisory alarms. These conditions do not have a direct impact on
the process or device integrity.
ADVISE_ENABLE 80 Enables or disables the advisory conditions within a device.
ADVISE_MASK 81 Mask of advisory Alarm. Corresponds bit for bit to the Advisory Active. A bit on
means that the failure is masked out from alarming.
ADVISE_PRI 79 Designates the alarming priority of the advisory alarm.
ALARM_SUM 37 This parameter shows the current alert status, unacknowledged states, unreported
states, and disabled states of the alarms associated with the function block. In the
Rosemount 8732 Magnetic Flowmeter Transmitter, the two resource block alarms
are write alarm and block alarm.
ALERT_KEY 04 ALERT_KEY shows the identification number of the plant unit. This information
may be used in the host for sorting alarms, etc.
Reference Manual
00809-0100-4663, Rev BA
January 2010
Rosemount 8732
F-2
BLOCK_ALM 36 The block alarm is used for all configuration, hardware, connection failure, or
system problems in the block. The cause of the alert is entered in the subcode
field. The first alert to become active will set the active status in the status
parameter. As soon as the unreported status is cleared by the alert reporting task,
another block alert may be reported without clearing the active status, if the
subcode has changed.
BLOCK_ERR 06 This parameter reflects the error status of the hardware or software components
associated with a block. It is a bit string, so multiple errors may be shown.
CLR_FSAFE 30 Writing a Clear to this parameter will clear the device FAULT_ STATE if the field
condition has cleared.
CONFIRM_TIME 33 This parameter represents the minimum time between retries of alert reports.
CYCLE_SEL 20 This parameter is used to select the block execution method for this resource. The
Rosemount 8732 supports the following executions:
Scheduled: Blocks are only executed based on the schedule in FB_START_LIST.
Block Execution: A block may be executed by linking to another block’s completion.
CYCLE_TYPE 19 This parameter identifies the block execution methods available for this resource.
DD_RESOURCE 09 This string identifies the tag of the resource that contains the device description for
this resource.
DD_REV 13 DD_REV is a revision of the DD associated with the resource—used by an
interface device to locate the DD file for the resource.
DEFINE_WRITE_LOCK 60 This parameter is an enumerated value describing the implementation of the
WRITE_LOCK.
DETAILED_STATUS 55 DETAILED_STATUS is an additional status bit string.
DEV_REV 12 This parameter represents the manufacturer revision number associated with the
resource—used by an interface device to locate the DD file for the resource.
DEV_STRING 43 Used to load new licensing into the device. The value can be written but will always
read back with a value of 0.
DEV_TYPE 11 This parameter represents the manufacturer’s model number associated with the
resource—used by interface devices to locate the DD file for the resource
(Rosemount 8732).
DIAG_OPTION 46 Indicates which diagnostics licensing options are enabled.
DISTRIBUTOR 42 References the company that is responsible for the distribution of this device.
DOWNLOAD_MODE 67 DOWNLOAD_MODE gives access to the boot block code for over-the-wire
downloads.
FAILED_ACTIVE 72 Active fail alarms.
FAILED_ALM 73 Alarm indicating a failure within a device which makes the device non-operational.
FAILED_ENABLE 70 Enables or disables the failure conditions within a device.
FAILED_MASK 71 Mask of Failure Alarm. Corresponds bit of bit to the Fail Active. A bit on means that
the failure is masked out from alarming.
FAILED_PRI 69 Designates the alarming priority of the fail alarm.
FAULT_STATE 28 Condition set by loss of communication to an output block, fault promoted to an
output block or physical contact. When FAULT_ STATE condition is set, then output
function blocks will perform their FAULT_ STATE actions.
FB_OPTION 45 Indicates which function block licensing options are enabled.
FEATURES 17 This parameter is used to show supported resource block options.
FEATURE_SEL 18 Used to show selected resource block options. The Rosemount 8732 Magnetic
Flowmeter Transmitter supports the following options:
Unicode: Tells the host to use unicode for string values
Reports: Enables alarms; must be set for alarming to work
Software Lock: Software write locking enabled but not active; WRITE_LOCK must
be set to activate
Hardware Lock: Hardware write locking enabled but not active; WRITE_LOCK
follows the status of the security switch
FINAL_ASSY_NUM 54 FINAL_ASSEMBLY_NUMBER is used for identification purposes and is associated
with the overall field device.
Index Number
Parameter Rev 5 Description
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Rosemount 8732
FREE_SPACE 24 This parameter represents the percent of memory available for further
configuration (zero in a preconfigured device).
FREE_TIME 25 This parameter represents the percent of the block processing time that is free to
process additional blocks.
GRANT_DENY 14 Options for controlling access of host computers and local control panels to
operating, tuning, and alarm parameters of the block (not used by the device).
HARD_TYPES 15 HARD_TYPES shows the types of hardware available as channel numbers. For
the Rosemount 8732, this parameter is limited to scalar (i.e., analog) inputs.
HARDWARE_REV 52 This parameter represents the hardware revision of the hardware that has the
resource block in it.
HEALTH_INDEX 84 Parameter representing the overall health of the device, 100 being perfect and 1
being non-functioning. The value is based on the active PWA alarms.
ITK_VER 41 FOUNDATION fieldbus Interoperability Test Kit Version
LIM_NOTIFY 32 Maximum number of unconfirmed alert notify messages allowed.
MAINT_ACTIVE 77 Active maintenance alarms.
MAINT_ALM 78 Alarm indicating the device needs maintenance soon. If the condition is ignored,
the device will eventually fail.
MAINT_PRI 74 Designates the alarming priority of the maintenance alarm.
MAINT_ENABLE 75 Enables or disables the maintenance conditions within a device.
MAINT_MASK 76 Mask of Maintenance Alarm. Corresponds bit for bit to the Maintenance Active. A
bit on means that the failure is masked out from alarming.
MANUFAC_ID 10 Manufacturer identification number—used by an interface device to locate the DD
file for the resource (001151 for Rosemount).
MAX_NOTIFY 31 Maximum number of unconfirmed alert notify messages possible.
MEMORY_SIZE 22 Available configuration memory in the empty resource. To be checked before
attempting a download.
MESSAGE_DATE 57 MESSAGE_DATE is the date associated with the MESSAGE_TEXT parameter.
MESSAGE_TEXT 58 MESSAGE_TEXT is used to indicate changes made by the user to the device's
installation, configuration, or calibration.
MIN_CYCLE_T 21 Time duration of the shortest cycle interval of which the resource is capable.
MISC_OPTION 47 Indicates which miscellaneous licensing options are enabled.
MODE_BLK 05 The actual, target, permitted, and normal modes of the block:
Target: The mode to “go to”
Actual: The mode the “block is currently in”
Permitted: Allowed modes that the target mode may take on
Normal: Most common mode for the actual mode
NV_CYCLE_T 23 NV_CYCLE_T is the interval between which copies of nonvolatile (NV) parameters
are written to NV memory. Zero denotes that NV parameters are never written to
NV memory.
OUTPUT_BOARD_SN 53 This parameter represents the output board serial number.
PWA_SIMULATE 85 Parameter allows simulation of PWA alarms.
RB_SFTWR_REV_ALL 51 Software revision string containing the following fields: major revision, minor
revision, build, time of build, day of week of build, month of build, day of month of
build, year of build, initials of builder.
RB_SFTWR_REV_BUILD 50 This parameter shows the build of software that the resource block was created
with.
RB_SFTWR_REV_MAJOR 48 This parameter shows the major revision of the software that the resource block
was created with.
RB_SFTWR_REV_MINOR 49 This parameter shows the minor revision of the software that the resource block
was created with.
RECOMMENDED_ACTION 68 Enumerated list of recommended actions displayed with an alert.
Index Number
Parameter Rev 5 Description
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F-4
RESTART 16 Allows a manual restart to be initiated. Several degrees of restart are possible:
1 Run: Nominal state when not restarting
2 Restart resource: Not used
3 Restart with defaults: Set parameters to default values (see
START_WITH_DEFAULTS below for which parameters are set).
4 Restart processor: Does a warm start of the central processing unit (CPU).
RS_STATE 07 RS_STATE denotes the state of the function block application state machine.
SAVE_CONFIG_NOW 61 This parameter controls saving of configuration in EEPROM.
SAVE_CONFIG_BLOCKS 62 Number of EEPROM blocks that have been modified since the last burn. This value
will count down to zero when the configuration is saved.
SECURITY_IO 65 SECURITY_JUMPER denotes the status of security jumper/switch.
SELF_TEST 59 SELF_TEST instructs the resource block to perform a self-test.
SET_FSAFE 29 Allows the FAULT_ STATE condition to be manually initiated by selecting Set.
SHED_RCAS 26 This parameter represents the time duration at which to give up on computer writes
to function block RCas locations.
SHED_ROUT 27 This parameter represents the time duration at which to give up on computer writes
to function block ROut locations.
SIMULATE_IO 64 SIMULATE_JUMPER shows the status of the simulate jumper/switch.
SIMULATE_STATE 66 SIMULATE_STATE represents the state of the simulate function.
ST_REV 01 The revision level of the static data associated with the function block. The revision
value will be incremented each time a static parameter value in the block is
changed.
START_WITH_DEFAULTS 63 START_WITH_DEFAULTS controls what defaults are used at power-up.
STRATEGY 03 The strategy field can be used to identify grouping of blocks. These data are not
checked or processed by the block.
SUMMARY_STATUS 56 This parameter represents an enumerated value of repair analysis.
TAG_DESC 02 The user description of the intended application of the block.
TEST_RW 08 A parameter for a host to use to test reading and writing. Not used by the device at
all.
UPDATE_EVT 35 This alert is generated by any change to the static data.
WRITE_ALM 40 This alert is generated if the write lock parameter is cleared.
WRITE_LOCK 34 If set, no writes from anywhere are allowed, except to clear WRITE_LOCK. Block
inputs will continue to be updated.
WRITE_PRI 39 WRITE_PRI represents the priority of the alarm generated by clearing the write
lock.
XD_OPTION 44 Indicates which transducer block licensing block options are enabled.
Index Number
Parameter Rev 5 Description
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F-5
Rosemount 8732
RESOURCE BLOCK
ERRORS Table F-2 lists conditions reported in the BLOCK_ERR parameter. Conditions
in italics are inactive for the resource block and are given here only for
your reference.
Table F-2. Resource
BLOCK_ERR Conditions
MODES The resource block supports two modes of operation as defined by the
MODE_BLK parameter:
Automatic (Auto)—The block is processing its normal background
memory checks.
Out of Service (O/S)—The block is not processing its tasks. When the
resource block is in O/S, all blocks within the resource (device) are
forced into O/S. The BLOCK_ERR parameter shows OUT OF
SERVICE. In this mode, you can make changes to all configurable
parameters. The target mode of a block may be restricted to one or
more of the supported modes.
Condition
Number Condition Name and Description
1Block Configuration Error: A feature in FEATURES_SEL is set that is
not supported by FEATURES or an execution cycle in CYCLE_SEL is
set that is not supported by CYCLE_TYPE.
2Link Configuration Error: A link used in one of the function blocks is
improperly configured.
3Simulate Active: The simulation jumper is in place. Simulate active is
not an indication that the I/O blocks are using simulated data.
4Local Override
5 Device Fault State Set
6Device Needs Maintenance Soon
7 Input failure/process variable has bad status
8Output Failure: The output is bad based primarily upon a bad input.
9Memory Failure: A memory failure has occurred in FLASH, RAM, or
EEPROM memory.
10 Lost Static Data: Static data that are stored in nonvolatile memory have
been lost.
11 Lost NV Data: Nonvolatile data that are stored in nonvolatile memory
have been lost.
12 Readback Check Failed
13 Device Needs Maintenance Now
14 Power Up: The device was just powered-up.
15 Out of Service: The actual mode is out of service.
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F-6
Alarm Detection A block alarm will be generated whenever the BLOCK_ERR has an error bit
set. The types of block error for the resource block are defined in Table F-2.
A write alarm is generated whenever the WRITE_LOCK parameter is cleared.
The priority of the write alarm is set in the following parameter:
•WRITE_PRI
Alarms are grouped into five levels of priority, as shown in Table F-3.
Table F-3. Alarm Priorities
Status Handling There are no status parameters associated with the resource block.
VCR The number of configurable virtual communication relationships or VCRs is
18. The parameter is not contained or viewable within the resource block, but
it does apply to all blocks.
TROUBLESHOOTING Refer to Table F-4 to troubleshoot resource block problems.
Table F-4. Troubleshooting
Priority
Number Priority Description
0 The priority of an alarm condition changes to 0 after the condition that
caused the alarm is corrected.
1An alarm condition with a priority of 1 is recognized by the system, but is
not reported to the operator.
2 An alarm condition with a priority of 2 is reported to the operator, but
does not require operator attention (such as diagnostics and system
alerts).
3–7 Alarm conditions of priority 3–7 are advisory alarms of increasing
priority.
8–15 Alarm conditions of priority 8–15 are critical alarms of increasing priority.
Symptom Possible Causes Corrective Action
Mode will not
leave OOS.
Target mode not set Set target mode to something other
than OOS.
Memory failure BLOCK_ERR will show the lost NV
Data or Lost Static Data bit set.
Restart the device by setting
RESTART to Processor. If the block
error does not clear, call the factory.
Block alarms will
not work.
Features FEATURES_SEL does not have
Alerts enabled. Enable the Alerts bit.
Notification LIM_NOTIFY is not high enough. Set
equal to MAX_NOTIFY.
Status options STATUS_OPTS has Propagate Fault
Forward bit set. This should be
cleared to cause an alarm to occur.
Reference Manual
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January 2010 Rosemount 8732
www.rosemount.com
Appendix G Transducer Block
Parameters and Descriptions . . . . . . . . . . . . . . . . . . . . . . page G-2
Flow-Specific Block Configuration Values . . . . . . . . . . . . page G-3
Transducer Block Errors . . . . . . . . . . . . . . . . . . . . . . . . . . page G-4
Transducer Block Diagnostics . . . . . . . . . . . . . . . . . . . . . page G-5
Modes . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . page G-5
Troubleshooting . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . page G-6
This appendix contains information on the transducer block for the
Rosemount 8732 Magnetic Flowmeter Transmitter (see Figure G-1).
Descriptions of all transducer block parameters, errors, and diagnostics are
listed. Also, the modes, alarm detection, status handling, application
information, and troubleshooting are discussed.
Figure G-1. Transducer
Block Diagram
Definition The transducer block contains the actual flow measurement data. This data
includes information about sensor type, engineering units, digital filter
settings, damping, and diagnostics. Only a single channel is defined in the
Rosemount 8732. Channel 1 provides flow measurements to the analog input
(AI) block.
Diagnostics
A/D Signal
Conversion Flow
Damping
Units/ Ranging
Diagnostics
A/D Signal
Conversion Flow
Damping
Units/ Ranging
TB
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G-2
PARAMETERS AND
DESCRIPTIONS Table G-1 lists all of the configurable parameters of the transducer block,
indicating the descriptions and index numbers for each parameters.
Table G-1. Transducer Block
Parameters
Parameter Index Number Definition
ALERT_KEY 4ID number of the transmitter–may be used on the host for sorting alarms
BLOCK_ALM 8Block alarm
COIL_DRIVE_FREQ 35 Frequency at which the coils are being driven (5 or 37.5 Hz)
DAMPING 30 Damping filter value (in seconds)
DENSITY_UNIT 31 Unit code associated with DENSITY_VALUE. Valid values are lb/cubic feet, or
kg/cubic meter
DENSITY_VALUE 75 User entered density value to be used by the transducer block when calculating flow
rate in mass flow units
DIAGNOSTIC_HANDLING 60 On/Off handling for diagnostics
ELECTRODE_MATERIAL 51 Enumerated string indicating flange material of installed flowtube
ELECTRODE_TYPE 52 Enumerated string indicating electrode type of installed flowtube
EP_TRIG_COUNTS 40 Number of EP measurements that must be above the trigger level to set empty pipe
EP_TRIG_LEVELS 41 Empty Pipe Trigger Levels
FLANGE_MATERIAL 54 Enumerated string indicating liner material of installed flowtube
FLANGE_TYPE 53 Enumerated string indicating liner material of installed flowtube
FLOW_TUBE_SERIAL_NUMBER 49 Flow tube serial number from physical tag on flowtube
FLOW_TUBE_TAG 48 Text String Identifier of flowtube
LICENSE_KEY 78 Key/password to enable diagnostic features. Any changes to the licensing will be
shown in the LICENSE_STATUS parameter
LINER_MATERIAL 50 Enumerated string indicating liner material of installed flowtube
LOI_LANG 39 Selects the language to be used in the local display for status and diagnostics
messages
LOW_FLOW_CUTOFF 37 When flow rate is less than this entered value, flow rate output will be set to 0 ft/s
MODE_BLK 5Mode of the record of the block–contains the actual, target, permitted,
and normal modes
SENSOR_CAL_DATE 25 Date of the last sensor calibration–intended to reflect the calibration of the sensor
SENSOR_CAL_LOC 24 Location of the last sensor calibration–describes the physical location at which the
calibration was performed
SENSOR_CAL_METHOD 23 Method of the last sensor calibration–ISO defines several standard methods of
calibration (This parameter is intended to record that method or if some other method
was used.)
SENSOR_CAL_WHO 26 Name of the person responsible for the last sensor calibration
STATUS_MESSAGE_MFG 61 Used by manufacturing to test groups to simulate status codes
STRATEGY 3Can be used to help group the blocks (Not checked or processed by the block)
TAG_DESC 2Static tag–ASCII character string
TUBE_CAL_NO 33 Sensor gain and zero offset number used in flow calculation
(Number entered is locate on physical tag of the sensor.)
TUBE_SIZE 34 Tube Size. See Tube Size for actual line sizes
UPDATE_EVT 7Update event
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Rosemount 8732
FLOW-SPECIFIC BLOCK
CONFIGURATION
VALUES
Once the transmitter is installed and communication is established,
configuration must be completed. Three parameters must be entered for
proper configuration:
Sensor calibration number
Engineering units (configured via AI block)
Sensor size
The sensor calibration number can be found on the sensor nameplate. A list
of all possible sensor sizes and engineering units are listed in Table G-2 and
Table G-3. Mass units (lb, kg, ton, and ston) require configuration of the
DENSITY_VALUE.
Table G-2. Supported Line
Sizes
Table G-3. Supported
Engineering Units
User-Defined Sensor Line Size
0.1 in. (3 mm) 16 in. (400 mm)
0.15 in. (4 mm) 18 in. (450 mm)
0.25 in. (6 mm) 20 in. (500 mm)
0.3 in (8 mm) 24 in. (600 mm)
0.5 in. (15 mm) 28 in. (700 mm)
0.75 in. (20 mm) 30 in. (750 mm)
1 in. (25 mm) 32 in (800 mm)
1.5 in. (40 mm) 36 in. (900 mm)
2 in. (50 mm) 40 in. (1000 mm)
2.5 in. (65 mm) 42 in. (1050 mm)
3 in. (80 mm)(1)
(1) Default Factory Configuration
48 in. (1200 mm)
4 in. (100 mm) 54 in. (1350 mm)
6 in. (150 mm) 56 in. (1400 mm)
8 in. (200 mm) 60 in. (1500 mm)
10 in. (250 mm) 64 in. (1600 mm)
12 in. (300 mm) 72 in. (1800 mm)
14 in. (350 mm) 80 in. (2000 mm)
User Defined Engineering Units
• ft/s(1)
(1) Default factory configuration
•CFS •bbl/s •kg/s
•ft/m •CFM •bbl/min •kg/min
• ft/h •CFH •bbl/h •kg/h
•m/s •ft
3/d • bbl/d • kg/d
•m/h •m
3/s •cm
3/s • STon/s
• gal/s • m3/min • cm3/min • STon/min
•GPM •m
3/h •cm
3/h • STon/h
• gal/h • m3/d • cm3/d • STon/d
• gal/d •IGAL/s •lb/s • t/s
• L/s • IGAL/min • lb/min • t/min
•L/min •IGAL/h •lb/h • t/h
• L/h • IGAL/d • lb/d • t/d
•L/d
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Rosemount 8732
G-4
TRANSDUCER BLOCK
ERRORS The following conditions are reported in the BLOCK_ERR and XD_ERROR
parameters. Conditions in italics are inactive for the transducer block and are
given here only for your reference.
Table G-4. Transducer
BLOCK_ERR and XD_ERR
Conditions Condition
Number Condition Name and Description
1 Block Configuration Error
2Link Configuration Error
3 Simulate Active
4Local Override
5 Device Fault State Set
6Device Needs Maintenance Soon
7 Input Failure/Process Variable Has Bad Status
8Output Failure
9 Memory Failure
10 Lost Static Data
11 Lost NV Data
12 Readback Check Failed
13 Device Needs Maintenance Now
14 Power Up: The device was just powered-up.
15 Out of Service: The actual mode is out of service.
16 Unspecified Error: An unidentified error occurred.
17 General Error: A general error that cannot be specified below occurred.
18 Calibration Error: An error occurred during calibration of the device, or
a calibration error was detected during normal operations.
19 Configuration Error: An error occurred during configuration of the
device, or a configuration error was detected during normal operations.
20 Electronics Failure: An electrical component failed.
21 Mechanical Failure: A mechanical component failed.
22 I/O Failure: An input/output (I/O) failure occurred.
23 Data Integrity Error: Data stored in the device are no longer valid due
to a nonvolatile memory checksum failure, a data verify after write
failure, etc.
24 Software Error: The software has detected an error due to an improper
interrupt service routine, an arithmetic overflow, a watchdog time-out,
etc.
25 Algorithm Error: The algorithm used in the transducer block produced
an error due to overflow, data reasonableness failure, etc.
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G-5
Rosemount 8732
TRANSDUCER BLOCK
DIAGNOSTICS In addition to the BLOCK_ERR and XD_ERROR parameters, more detailed
information on the measurement status can be obtained via
DETAILED_STATUS. Table G-5 lists the potential errors and the possible
corrective actions for the given values. Reset the transmitter by cycling power
and then, if the error persists, perform the corrective action as described in
Table G-5. More detailed and descriptive corrective actions are listed in
Section 4: Operation and Section 6: Maintenance and Troubleshooting.
Table G-5.
TB_DETAILED_STATUS
Descriptions and Corrective
Actions
MODES The transducer block supports two modes of operation as defined by the
MODE_BLK parameter:
Automatic (Auto)—The channel outputs reflect the analog input
measurement.
Out of Service (O/S)—The block is not processed. Channel outputs
are not updated and the status is set to BAD: OUT OF SERVICE for
each channel. The BLOCK_ERR parameter shows OUT OF SERVICE.
In this mode, you can make changes to all configurable parameters.
The target mode of a block may be restricted to one or more of the
supported modes.
Alarm Detection Alarms are not generated by the transducer block. By correctly handling the
status of the channel values, the down stream block (AI) will generate the
necessary alarms for the measurement. The error that generated this alarm
can be determined by looking at BLOCK_ERR and XD_ERROR.
Status Handling Normally, the status of the output channels reflects the status of the
measurement value, the operating condition of the measurement electronics
card, and any active alarm condition.
Value Name and Description Corrective Action
0x00000001 DSP hardware not compatible
with software
Send to service center(1)
(1) See Section 6: Maintenance and Troubleshooting for detailed instructions on how to return
products to an authorized service center or factory.
0x00000002 Electronics failure Replace the electronics board
stack
0x00000004 Coil drive open circuit Perform sensor electrical
resistance checks
0x00000008 Empty Pipe Detected Verify sensor is full
0x00000010 Calibration failure Cycle transmitter power to clear
message
0x00000020 Auto Zero failure Repeat Auto Zero process
0x00000040 Sensor high limit exceeded Lower the process flowrate
0x00000080 Sensor processor not
communicating
Replace electronics
0x00000100 Universal Trim failure Re-run Universal Trim with steady
state flow
0x00000200 Reverse flow detected Verify sensor is not installed
backwards
0x00000400 Electronics Temp outside limits Status message –
no corrective action
0x00002000 High Process Noise Increase the coil drive frequency to
37.5 Hz
0x00008000 Grounding/Wiring Fault Connect process grounding
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G-6
In Auto mode, OUT reflects the value and status quality of the
output channels.
TROUBLESHOOTING Refer to Table G-6 to troubleshoot transducer block problems.
Table G-6. Troubleshooting Symptom Possible Causes Corrective Action
Mode will not leave out of
service (OOS).
Target mode not set Set target mode to something other
than OOS.
Resource block The actual mode of the resource block
is OOS. See Appendix F: Resource
Block: and Section 3: Configuration.
PVor SV is BAD Measurement See Diagnostics, Table G-4.
Flow is above
SENSOR_RANGE.EU100.
PV or SV is UNCERTAIN Measurement Flow is above
PRIMARY_VALUE_RANGE.EU100.
Reference Manual
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January 2010 Rosemount 8732
www.rosemount.com
Appendix H 375 Field Communicator
Operation
HandHeld Communicator . . . . . . . . . . . . . . . . . . . . . . . . . . page H-1
Connections and Hardware . . . . . . . . . . . . . . . . . . . . . . . . page H-2
Basic Features . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . page H-3
Menus and Functions . . . . . . . . . . . . . . . . . . . . . . . . . . . . . page H-4
HANDHELD
COMMUNICATOR NOTE
Please refer to the Handheld Communicator manual for detailed instructions
on the use, features, and full capabilities of the Handheld Communicator.
Explosions can result in death or serious injury.
Do not make connections to the serial port or NiCad recharger jack in an
explosive atmosphere.
Before connecting the Handheld Communicator in an explosive atmosphere, make sure the
instruments in the loop are installed in accordance with intrinsically safe or non-incendive
field wiring practices.
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January 2010
Rosemount 8732
H-2
CONNECTIONS AND
HARDWARE The 375 Field Communicator exchanges information with the transmitter from
the control room, the instrument site, or any wiring termination point in the
loop. Be sure to install the instruments in the loop in accordance with
intrinsically safe or non-incendive field wiring practices. Explosions can result
if connections to the serial port or NiCad recharger jack are made in an
explosive situation. The Handheld Communicator should be connected in
parallel with the transmitter. Use the loop connection ports on the rear panel
of the Handheld Communicator (see Figure H-1). The connections are
non-polarized.
Figure H-1. Rear Connection
Panel
Figure H-2. Connecting the
Handheld Communicator to a
Transmitter Loop
IRDA Port Fieldbus Connection Ports
375 Field Communicator Ports
Power
Supply
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January 2010
H-3
Rosemount 8732
BASIC FEATURES The basic features of the Handheld Communicator include Action Keys,
Function Keys, and Alphanumeric and Shift Keys.
Figure H-3. The Handheld
Communicator
Action Keys The Action Keys
As shown in Figure H-3, the action keys are the six blue, white, and black
keys located above the alphanumeric keys. The function of each key is
described as follows:
ON/OFF Key
Use this key to power the Handheld Communicator. When the
communicator is turned on, it searches for a transmitter on the
FOUNDATION filedbus loop.
If a FOUNDATION fieldbus compatible device is found, the communicator
displays the Online Menu with device ID (8732) and tag (TRANSMITTER).
Directional Keys
Use these keys to move the cursor up, down, left, or right. The right arrow
key also selects menu options, and the left arrow key returns to the
previous menu.
Tab Key
Use this key to quickly access important, user-defined options when
connected to a device. Pressing the Hot Key turns the Handheld
Communicator on and displays the Hot Key Menu. See Customizing the
Hot Key Menu in the Handheld Communicator manual for more
information.
Action Keys
Page
Up
Page
Dn
Bksp
Delete
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Rosemount 8732
H-4
Function Key
Use the four software-defined function keys, located below the LCD, to
perform software functions. On any given menu, the label appearing
above a function key indicates the function of that key for the current
menu. As you move among menus, different function key labels appear
over the four keys. For example, in menus providing access to on-line
help, the label may appear above the F1 key. In menus providing
access to the Home Menu, the label may appear above the F3 key.
Simply press the key to activate the function. See your Handheld
Communicator manual for details on specific Function Key definitions.
Alphanumeric and
Shift Keys The Alphanumeric keys perform two functions: the fast selection of menu
options and data entry.
Figure H-4. Handheld
Communicator Alphanumeric
and Shift Keys
Data Entry
Some menus require data entry. Use the Alphanumeric and Shift keys to enter
all alphanumeric information into the Handheld Communicator. If you press an
Alphanumeric key alone from within an edit menu, the bold character in the
center of the key appears. These large characters include the numbers zero
through nine, the decimal point (.), and the dash symbol (—).
To enter an alphabetic character, first press the Shift key that corresponds to
the position of the letter you want on the alphanumeric key. Then press the
alphanumeric key. For example, to enter the letter R, first press the right Shift
key, then the “6” key (see Figure H-4 on page H-4). Do not press these keys
simultaneously, but one after the other.
MENUS AND
FUNCTIONS The Handheld Communicator is a menu driven system. Each screen provides
a menu of options that can be selected as outlined above, or provides
direction for input of data, warnings, messages, or other instructions.
HELP
HOME
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Rosemount 8732
Main Menu The Main Menu provides the following options:
Offline - The Offline option provides access to offline configuration data
and simulation functions.
Online - The Online option checks for a device and if it finds one, brings
up the Online Menu.
Transfer - The Transfer option provides access to options for
transferring data either from the Handheld Communicator (Memory) to
the transmitter (Device) or vice versa. Transfer is used to move off-line
data from the Handheld Communicator to the flowmeter, or to retrieve
data from a flowmeter for off-line revision.
NOTE
Online communication with the flowmeter automatically loads the current
flowmeter data to the Handheld Communicator. Changes in on-line data are
made active by pressing SEND (F2). The transfer function is used only for
off-line data retrieval and sending.
Frequency Device - The Frequency Device option displays the
frequency output and corresponding flow output of flow transmitters.
Utility - The Utility option provides access to the contrast control for the
Handheld Communicator LCD screen and to the autopoll setting used
in multidrop applications.
Once selecting a Main Menu option, the Handheld Communicator provides
the information you need to complete the operation. If further details are
required, consult the Handheld Communicator manual.
Online Menu The Online Menu can be selected from the Main Menu as outlined above, or it
may appear automatically if the Handheld Communicator is connected to an
active loop and can detect an operating flowmeter.
NOTE
The Main Menu can be accessed from the Online Menu. Press the left arrow
action key to deactivate the on-line communication with the flowmeter and to
activate the Main Menu options.
When configuration variables are reset in the on-line mode, the new settings
are not activated until the data are sent to the flowmeter.
Press SEND (F2) to update the process variables of the flowmeter.
On-line mode is used for direct evaluation of a particular meter,
re-configuration, changing parameters, maintenance, and other functions.
Reference Manual
00809-0100-4663, Rev BA
January 2010
Rosemount 8732
H-6
Diagnostic Messages The following is a list of messages used by the Handheld Communicator (HC)
and their corresponding descriptions.
Variable parameters within the text of a message are indicated with <variable
parameter>.
Reference to the name of another message is identified by
[another message].
Table H-1. Handheld Communicator Diagnostic Messages
Message Description
Add item for ALL device types or only for this ONE device type Asks the user whether the hot key item being added should be added
for all device types or only for the type of device that is connected.
Command Not Implemented The connected device does not support this function.
Communication Error Either a device sends back a response indicating that the message it
received was unintelligible or the HC cannot understand the response
from the device.
Configuration memory not compatible with connected device The configuration stored in memory is incompatible with the device to
which a transfer has been requested.
Device Busy The connected device is busy performing another task.
Device Disconnected Device fails to respond to a command
Device write protected Device is in write-protect mode Data can not be written
Device write protected – do you still want to shut off? Device is in write-protect mode – press YES to turn the HC off and lose
the unsent data.
Display value of variable on hot key menu? Asks whether the value of the variable should be displayed adjacent to
its label on the hot key menu if the item being added to the hot key menu
is a variable.
Download data from configuration memory to device Prompts user to press SEND softkey to initiate a memory to device
transfer.
Exceed field width Indicates that the field width for the current arithmetic variable exceeds
the device- specified description edit format
Exceed precision Indicates that the precision for the current arithmetic variable exceeds
the device- specified description edit form
Ignore next 50 occurrences of status? Asked after displaying device status – softkey answer determines
whether next 50 occurrences of device status will be ignored or
displayed
Illegal character An invalid character for the variable type was entered.
Illegal date The day portion of the date is invalid.
Illegal month The month portion of the date is invalid.
Illegal year The year portion of the date is invalid.
Incomplete exponent The exponent of a scientific notation floating point variable is
incomplete.
Incomplete field The value entered is not complete for the variable type.
Looking for a device Polling for multidropped devices at addresses 1–15
Mark as read only variable on hot key menu? Asks whether the user should be allowed to edit the variable from the
hot key menu if the item being added to the hot key menu is a variable
No device configuration in configuration memory There is no configuration saved in memory available to re-configure
off-line or transfer to a device.
No Device Found Poll of address zero fails to find a device, or poll of all addresses fails to
find a device if auto-poll is enabled
No hot key menu available for this device There is no menu named “hot key” defined in the device description for
this device.
No off-line devices available There are no device descriptions available to be used to configure a
device off-line.
No simulation devices available There are no device descriptions available to simulate a device.
No UPLOAD_VARIABLES in ddl for this device There is no menu named “upload_variables” defined in the device
description for this device – this menu is required for off-line
configuration.
No Valid Items The selected menu or edit display contains no valid items.
Reference Manual
00809-0100-4663, Rev BA
January 2010
H-7
Rosemount 8732
OFF KEY DISABLED Appears when the user attempts to turn the HC off before sending
modified data or before completing a method
On-line device disconnected with unsent data – RETRY or OK to
lose data
There is unsent data for a previously connected device. Press RETRY
to send data, or press OK to disconnect and lose unsent data.
Out of memory for hot key configuration – delete unnecessary
items
There is no more memory available to store additional hot key items.
Unnecessary items should be deleted to make space available.
Overwrite existing configuration memory Requests permission to overwrite existing configuration either by a
device-to-memory transfer or by an off-line configuration; user answers
using the softkeys
Press OK... Press the OK softkey – this message usually appears after an error
message from the application or as a result of hart communications.
Restore device value? The edited value that was sent to a device was not properly
implemented. Restoring the device value returns the variable to its
original value.
Save data from device to configuration memory Prompts user to press SAVE softkey to initiate a device-to-memory
transfer
Saving data to configuration memory Data is being transferred from a device to configuration memory.
Sending data to device Data is being transferred from configuration memory to a device.
There are write only variables which have not been edited.
Please edit them.
There are write-only variables which have not been set by the user.
These variables should be set or invalid values may be sent to the
device.
There is unsent data. Send it before shutting off? Press YES to send unsent data and turn the HC off. Press NO to turn
the HC off and lose the unsent data.
Too few data bytes received Command returns fewer data bytes than expected as determined by the
device description
Transmitter Fault Device returns a command response indicating a fault with the
connected device
Units for <variable label> has changed – unit must be sent before
editing, or invalid data will be sent
The engineering units for this variable have been edited. Send
engineering units to the device before editing this variable.
Unsent data to on-line device – SEND or LOSE data There is unsent data for a previously connected device which must be
sent or thrown away before connecting to another device.
Use up/down arrows to change contrast. Press DONE when done. Gives direction to change the contrast of the HC display
Value out of range The user-entered value is either not within the range for the given type
and size of variable or not within the min/max specified by the device.
<message> occurred reading/writing <variable label> Either a read/write command indicates too few data bytes received,
transmitter fault, invalid response code, invalid response command,
invalid reply data field, or failed pre- or post-read method; or a response
code of any class other than SUCCESS is returned reading a particular
variable.
<variable label> has an unknown value – unit must be sent before
editing, or invalid data will be sent
A variable related to this variable has been edited. Send related variable
to the device before editing this variable.
Table H-1. Handheld Communicator Diagnostic Messages
Message Description
Reference Manual
00809-0100-4663, Rev BA
January 2010
Rosemount 8732
H-8
Reference Manual
00809-0100-4663, Rev BA
January 2010
Index-1
Rosemount 8732
A
Action Keys
Handheld Communicator .H-3
Alphanumeric Keys
Handheld Communicator .H-4
Analog Output
Range . . . . . . . . . . . . . 3-10
Zero . . . . . . . . . . . . . . . 3-10
Applications/Configurations . . . 2-4
Auto Zero . . . . . . . . . . . . . . .D-2
B
Basic Setup . . . . . . . . . . 3-6, 3-7
BLOCK_ERR
Resource Block . . . . F-5, F-6
Transducer Block . . . . . .G-4
Bolts
Flanged . . . . . . . . . . . . . 5-7
C
Cables
Conduit . . . . . . . . 2-6, 2-12
Calibration Number . . . . . . . 3-11
Conduit Connections
Installation . . . . . . 2-6, 2-12
Conduit Ports and Connections
Wiring . . . . . . . . . . . . . . 2-5
Configurations/Applications . . . 2-4
Connections
Handheld Communicator .H-2
D
Damping . . . . . . . . . . . . . . . 3-11
Data Entry
Handheld Communicator .H-4
Dedicated Conduit . . . . . . . . 2-11
DETAILED_STATUS
Transducer Block . . . . . .G-5
Device Software Functions
Basic Setup . . . . . . 3-6, 3-7
Diagnostic Messages . . . . . . . 6-3
Handheld Communicator .H-6
LOI . . . . . . . . . . . . . . . . 3-5
Digital Signal Processing . . . .D-1
Direction . . . . . . . . . . . . . . . . 5-5
Display Lock . . . . . . . . . . . . . 3-3
Downstream/Upstream Piping . 5-4
E
Electrical
Considerations . . . . . . . . 2-6
Electrical Considerations . . . . 2-6
Environmental Considerations . 2-3
F
Flange Bolts . . . . . . . . . . . . . 5-7
Flanges
Class 150 . . . . . . . . . . . 5-11
Class 300 . . . . . . . . . . . 5-11
Flow Direction . . . . . . . . .5-5, 5-6
Flow Rate
Units . . . . . . . . 3-7, 3-8, 3-9
Flowtube
Connections . . . . . . . . . 2-11
Orientation . . . . . . . . . . . 5-4
Test . . . . . . . . . . . . . . . . 6-8
Flowtubes
Brooks Model 5000 . . . . . E-6
Endress and Hauser Models E-5
Fischer and Porter Model 10D1418
. . . . . . . . . . . . . E-9
Foxboro Series 1800 . . . E-15
Generic Flowtube . . . . . E-26
Kent Flowtubes . . . . . . . E-20
Kent Veriflux VTC . . . . . E-19
Krohne Flowtubes . . . . . E-21
Rosemount Model
8705/8707/8711 . E-3
Taylor Series 1100 . . . . E-22
Yamatake Honeywell Flowtubes
E-24
Yokogawa Flowtubes . . E-25
Function Keys
Handheld Communicator . H-4
G
Gaskets . . . . . . . . . . . . . . . . 5-7
Installation
Wafer Flowtube . . . 5-10
Ground Connection
Internal . . . . . . . . . . . . 5-13
Protective . . . . . . . . . . . 5-13
Grounding . . . . . . . . . . . . . 5-12
Grounding Electrodes . . 5-13
Grounding Rings . . . . . . 5-13
Lining Protectors . . . . . . 5-13
Process Grounding . . . . 5-12
H
Handheld Communicator
Action Keys . . . . . . . . . . H-3
Alphanumeric Keys . . . . H-4
Basic Features . . . . . . . . H-3
Connections . . . . . . . . . H-2
Data Entry . . . . . . . . . . . H-4
Diagnostic Messages . . . H-6
Function Keys . . . . . . . . H-4
Functions . . . . . . . . . . . H-4
Hardware . . . . . . . . . . . H-2
Main Menu . . . . . . . . . . H-5
Menus . . . . . . . . . . . . . . H-4
Online Menu . . . . . . . . . H-5
Shift Keys . . . . . . . . . . . H-4
I
Installation
Category . . . . . . . . . . . . .2-7
Conduit Connections 2-6, 2-12
Connect 4-20 mA Loop External
Power Source . . .2-8
Considerations . . . . . . . . .2-7
Diagram
Cable Preparation . .2-12
Field Wiring . . . . . . .2-10
Electrical . . . . . . . . . . . . .2-8
Environmental Considerations 2-3
Flowtube Connections . . 2-11
Mechanical Considerations 2-2
Mounting . . . . . . . . . . . . .2-3
Options . . . . . . . . . . . . . .2-7
Procedures . . . . . . . . . . .2-3
Process Leak
Containment . . . . . .5-17
Relief Valves . . . . . . . . .5-17
Safety Messages . . . 2-1, 5-1
Wafer Flowtube . . 5-10, 5-12
Alignment and Bolting 5-10
Flange Bolts . . . . . . 5-11
Gaskets . . . . . . . . .5-10
Wiring . . . . . . . . . . . . . . .2-8
Installation Category . . . . . . . .2-7
Internal
Ground Connection . . . .5-13
L
Line Size . . . . . . . . . . . . . . . .3-9
Lining Protectors
Grounding . . . . . . . . . . .5-13
Local Operator Interface (LOI)
Diagnostic Messages . . . .3-5
Examples . . . . . . . . . . . .3-2
Lock LOI . . . . . . . . . . . . . . . .3-3
Index
Reference Manual
00809-0100-4663, Rev BA
January 2010
Rosemount 8732
Index-2
Lower Range Value (LRV) . . 3-10
M
Mechanical Considerations 2-2, 2-6
Menu
Handheld Communicator .H-4
Messages
Safety . . . . . . . . . . . . . . 1-2
Mode
Transducer Block . . . . . .G-5
MODE_BLK
Transducer Block . . . . . .G-5
Mounting . . . . . . . . . . . . . . . . 2-3
N
NiCad Recharger . . . . . . . . . .H-2
North American Response Center 1-2
O
Options . . . . . . . . . . . . . . . . . 2-4
Orientation
Flowtube . . . . . . . . . . . . 5-4
Overcurrent Protection . . . . . . 2-7
Overrange Capability . . . . . . . A-4
P
Piping . . . . . . . . . . . . . . . . . . 5-4
Process Grounding . . . . . . . 5-12
Process Leak
Containment . . . . . . . . . 5-17
Process Variables . . . . . . . . . 3-5
Protection
Overcurrent . . . . . . . . . . 2-7
Protective
Ground Connection . . . . 5-13
R
Relief Valves . . . . . . . . . . . . 5-17
Resource Block . . . . . . . . . . . F-1
Modes . . . . . . . . . . . . . . F-5
Parameters . . . . . . . . . . . F-1
BLOCK_ERR . . F-5, F-6
WRITE_LOCK . . . . . F-6
Parameters and Descriptions F-1
Resource Block Errors . . . F-5
Troubleshooting . . . . . . . F-6
S
Safety Messages . . . . . . . . . . 1-2
Security . . . . . . . . . . . . . . . . 2-4
Shift Keys
Handheld Communicator .H-4
Signal Processing . . . . . . . . .D-2
Specifications and Reference Data
Functional Specifications
Overrange Capability A-4
Switches . . . . . . . . . . . . . . . 2-4
Changing Settings . . . . . 2-4
T
Tag . . . . . . . . . . . . . . . . . . . 3-7
Transducer Block
Diagnostics . . . . . . . . . . G-5
Errors . . . . . . . . . . . . . . G-4
Flow-specific Block Configuration
Values . . . . . . . G-3
Modes . . . . . . . . . . . . . . G-5
Parameters . . . . . . . . . . G-2
BLOCK_ERR . . . . . . G-4
MODE_BLK . . . . . . . G-5
XD_ERROR . . . . . . G-4
Parameters and Descriptions G-2
Transducer block
Parameters
DETAILED_STATUS G-5
Transmitter Output Instability
Auto Zero . . . . . . . . . . . . D-2
Procedures . . . . . . . . . . D-2
Signal Processing . . . . . . D-2
Transmitter Security . . . . . . . 2-4
Transporting System . . . . . . . 5-3
Troubleshooting
Advanced (Transmitter) . . 6-5
Installed Flowtube Tests . 6-7
Process Noise . . . . . . . . 6-7
Resource Block . . . . . . . F-6
Uninstalled Flowtube Tests 6-9
Wiring Errors . . . . . . . . . 6-7
U
Upper Range Value (URV) . . 3-10
Upstream/Downstream Piping 5-4
Accuracy
Ensuring . . . . . . . . . 5-4
V
VCR . . . . . . . . . . . . . . . A-4, F-6
Virtual Communications Relationships
F-6
W
Wiring
Conduit Ports and Connections
2-5
Dedicated Conduit . . . . 2-11
Installation Category . . . . 2-7
Wiring Diagrams
Brooks Model 5000 . . . . E-6
Endress and Hauser Models E-5
Fisher and Porter Model 10D1418
E-9
Foxboro Series 1800 . . E-15
Generic Flowtube . . . . . E-26
Kent Flowtubes . . . . . . E-20
Kent Verifulx VTC . . . . . E-19
Krohne Flowtubes . . . . E-21
Rosemount Model
8705/8707/8711 E-3
Taylor Series 1100 . . . . E-22
Yamatake Honeywell Flowtubes
E-24
Yokogawa Flowtubes . . E-25
WRITE_LOCK
Resource Block . . . . . . . .F-6
X
XD_ERROR
Transducer Block . . . . . . G-4
Emerson Process Management
00809-0100-4663 Rev BA, 1/10
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Rosemount and the Rosemount logotype are registered trademarks of Rosemount Inc.
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All other marks are the property of their respective owners.
Standard Terms and Conditions of Sale can be found at www.rosemount.com/terms_of_sale
Reference Manual
00809-0100-4663, Rev BA
January 2010
Emerson Process Management
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