Manual 3051S 00809 0100 4803

User Manual: 3051S

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Reference Manual
00809-0100-4803, Rev GA
September 2017

Rosemount™ 3051S MultiVariable™ Transmitter

Reference Manual

Contents

00809-0100-4803, Rev GA

September 2017

1Section 1: Introduction
1.1 Using this manual. . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 1
1.2 Product recycling/disposal . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 2

2Section 2: Configuration
2.1 Overview . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 3
2.2 Safety messages . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 4
2.3 Engineering Assistant installation . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 4
2.3.1 Engineering Assistant version 6.3 or later . . . . . . . . . . . . . . . . . . . . . . . . . . . 4
2.3.2 Installation and initial setup . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 5
2.4 Flow configuration . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 7
2.4.1 Rosemount 3051SMV Engineering Assistant 6.3 or later . . . . . . . . . . . . . . 7
2.4.2 Basic navigation overview . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 8
2.4.3 Launching Engineering Assistant . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 9
2.4.4 Preferences . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 9
2.4.5 Fluid selection for database liquid/gas . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 10
2.4.6 Fluid properties . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 13
2.4.7 Primary element selection . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 13
2.4.8 Save/send . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 15
2.4.9 Other fluid configurations . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 18
2.5 Basic device configuration . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 24
2.6 Detailed device configuration . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 27
2.6.1 Model identification . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 27
2.6.2 Alarm and saturation . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 27
2.6.3 Variable mapping . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 31
2.6.4 LCD display. . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 32
2.6.5 Communication setup . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 33
2.6.6 Materials of construction. . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 35
2.6.7 Flow configuration parameters . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 36
2.7 Variable configuration. . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 38
2.7.1 Flow rate . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 38
2.7.2 Energy rate . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 44
2.7.3 Totalizer . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 49
2.7.4 Differential pressure. . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 52
2.7.5 Static pressure . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 53
2.7.6 Process temperature . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 54
2.7.7 Module temperature . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 55
2.7.8 Analog output . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 56
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2.8 Menu trees and Field Communicator Fast Keys . . . . . . . . . . . . . . . . . . . . . . . . . . . 57
2.8.1 Field Communicator Fast Keys . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 62

3Section 3: Installation
3.1 Overview . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 65
3.2 Safety messages . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 65
3.3 Installation considerations . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 67
3.3.1 General . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 67
3.3.2 Mechanical . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 67
3.3.3 Environmental . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 67
3.4 Installation procedures . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 67
3.4.1 Configure security (write protect) . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 67
3.4.2 Configure alarm direction . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 68
3.4.2 Mounting considerations . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 68
3.4.3 Mount the transmitter . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 70
3.4.4 Process connections. . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 73
3.4.5 Connect wiring and power up . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 75
3.4.6 Conduit electrical connector wiring (option GE or GM). . . . . . . . . . . . . . . 79
3.4.7 Grounding . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 79
3.5 Rosemount 305 and 304 Manifolds . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 80
3.5.1 Rosemount 305 Integral Manifold installation procedure . . . . . . . . . . . . 81
3.5.2 Rosemount 304 Conventional Manifold installation procedure . . . . . . . 81
3.5.3 Manifold operation . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 81

4Section 4: Operation and Maintenance
4.1 Overview . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 87
4.2 Safety messages . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 88
4.3 Transmitter calibration . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 89
4.3.1 Calibration overview. . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 89
4.3.2 Sensor trim overview . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 90
4.3.3 Differential pressure sensor calibration . . . . . . . . . . . . . . . . . . . . . . . . . . . . 90
4.3.4 Static pressure sensor calibration . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 92
4.3.5 Process temperature sensor calibration . . . . . . . . . . . . . . . . . . . . . . . . . . . 93
4.3.6 Analog calibration. . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 95
4.4 Transmitter functional tests. . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 96
4.4.1 Flow/energy calculation verification (test calculation) . . . . . . . . . . . . . . . 97
4.4.2 Configuring fixed process variables. . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 97
4.4.3 Analog output loop test. . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 97
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4.5 Process variables . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 98
4.5.1 Process variable tabs . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 98
4.5.2 All variables tab . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 99
4.6 Field upgrades and replacements . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 99
4.6.1 Disassembly considerations . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 99
4.6.2 Housing assembly including feature board electronics . . . . . . . . . . . . . . 100
4.6.3 Terminal block. . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 102
4.6.4 LCD display. . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 103
4.6.5 Flange and drain vent. . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 103
4.6.6 SuperModule assembly . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 105

5Section 5: Troubleshooting
5.1 Overview . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 107
5.2 Device diagnostics . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 107
5.2.1 HART host diagnostics . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 107
5.2.2 LCD display diagnostics . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 107
5.3 Measurement quality and limit status . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 112
5.4 Engineering Assistant communication troubleshooting . . . . . . . . . . . . . . . . . . 113
5.5 Measurement troubleshooting . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 114
5.6 Service support . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 117

6Section 6: Safety Instrumented Systems Requirements
6.1 Safety Instrumented Systems (SIS) Certification . . . . . . . . . . . . . . . . . . . . . . . . . 119
6.2 Rosemount 3051SMV safety certified identification. . . . . . . . . . . . . . . . . . . . . . 119
6.3 Installation in SIS applications . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 119
6.4 Configuring in SIS applications . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 120
6.4.1 Damping. . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 120
6.4.2 Alarm and saturation levels. . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 120
6.5 Rosemount 3051SMV SIS operation and maintenance . . . . . . . . . . . . . . . . . . . 121
6.5.1 Proof test . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 121
6.5.2 Partial proof test . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 121
6.5.3 Comprehensive proof test . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 122
6.6 Inspection . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 123
6.6.1 Visual inspection . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 123
6.6.2 Special tools. . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 123
6.6.3 Product repair . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 123
6.6.4 Rosemount 3051SMV SIS reference . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 123
6.6.5 Failure rate data . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 123
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6.6.6 Failure values . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 123
6.6.7 Product life. . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 123

AAppendix A: Specifications and Reference Data
A.1 Specifications . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 125
A.1.1 Performance specifications. . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 125
A.1.2 Functional specifications . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 129
A.1.3 Physical specifications . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 132
A.2 Dimensional drawings. . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 135
A.3 Ordering information . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 138
A.3.1 Rosemount 3051S MultiVariable Transmitter. . . . . . . . . . . . . . . . . . . . . . 138
A.3.2 Rosemount 300SMV housing kit . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 144
A.4 Accessories . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 147
A.4.1 Rosemount Engineering Assistant (EA) software packages . . . . . . . . . . 147
A.5 Spare parts. . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 150

BAppendix B: Product Certifications
B.1 European Directive Information . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 155
B.2 Ordinary Location Certification . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 155
B.3 Installing Equipment in North America . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 155
B.4 USA . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 155
B.5 Canada . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 156
B.6 Europe . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 156
B.7 International . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 157
B.8 Brazil . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 158
B.9 China. . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 159
B.10EAC – Belarus, Kazakhstan, Russia . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 160
B.11Japan . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 161
B.12Republic of Korea. . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 161
B.13Combinations. . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 161
B.14Additional Certifications. . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 161
B.15Installation drawings. . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 162

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Title Page
September 2017

Rosemount™ 3051S MultiVariable™
Transmitter
NOTICE
Read this manual before working with the product. For personal and system safety, and for optimum
product performance, make sure the contents are fully understood installing, using, or maintaining this
product.
For technical assistance, contacts are listed below:
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 Emerson™ representative.

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Failure to follow these installation guidelines could result in death or serious injury.


Make sure only qualified personnel perform the installation.

Explosions could result in death or serious injury.


Do not remove the transmitter cover in explosive atmospheres when the circuit is live.



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 flameproof/explosion-proof requirements.

Verify the operating atmosphere of the transmitter is consistent with the appropriate hazardous
locations certifications.
Electrical shock could cause death or serious injury.




If the sensor is installed in a high-voltage environment and a fault or installation error occurs, high
voltage may be present on the transmitter leads and terminals.



Use extreme caution when making contact with the leads and terminals.

Process leaks could result in death or serious injury.


Install and tighten all four flange bolts before applying pressure.



Do not attempt to loosen or remove flange bolts while the transmitter is in service.



Replacement equipment or spare parts not approved by Emerson for use as spare parts could reduce
the pressure retaining capabilities of the transmitter and may render the instrument dangerous.



Use only bolts supplied or sold by Emerson as spare parts.

Improper assembly of manifolds to traditional flange can damage the device.


For safe assembly of manifold to traditional flange, bolts must break back plane of flange web
(i.e., bolt hole) but must not contact the sensor module.

Improper installation or repair of the SuperModule™ assembly with high pressure option (P0)
could result in death or serious injury.


For safe assembly, the high pressure SuperModule assembly must be installed with ASTM A193 Class 2
Grade B8M bolts and either a Rosemount 305 Manifold or a DIN-compliant traditional flange.

Static electricity can damage sensitive components.


Observe safe handling precautions for static-sensitive components.

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 Emerson Sales
Representative.

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Introduction

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Section 1
1.1

Introduction

Using this manual
The sections in this manual provide information on installing, operating, and maintaining the
Rosemount™ 3051S MultiVariable™ Transmitter (Rosemount 3051SMV). The sections are organized as
follows:


Section 2: Configuration provides instruction on commissioning and operating Rosemount 3051SMV.
Information on software functions, configuration parameters, and online variables is also included.



Section 3: Installation contains mechanical and electrical installation instructions.



Section 4: Operation and Maintenance contains operation and maintenance techniques.



Section 5: Troubleshooting provides troubleshooting techniques for the most common operating
problems.



Section 6: Safety Instrumented Systems Requirements contains identification, commissioning,
maintenance, and operations information for the Rosemount 3051S MultiVariable Safety
Instrumented System (SIS) Safety Transmitter.



Appendix A: Specifications and Reference Data supplies reference and specification data, as well as
ordering information.



Appendix B: Product Certifications contains intrinsic safety approval information, European ATEX
directive information, and approval drawings.

Models covered
The following Rosemount 3051SMV Transmitters are covered in this manual:
Table 1-1. Rosemount 3051SMV Measurement with Fully Compensated Mass and Energy Flow
Output
Measurement type

Multivariable type - M

1

Differential pressure, static pressure, temperature

2

Differential pressure and static pressure

3

Differential pressure and temperature

4

Differential pressure

Table 1-2. Rosemount 3051SMV Measurement with Direct Process Variable Output
Measurement type

Introduction

Multivariable type - P

1

Differential pressure, static pressure, temperature

2

Differential pressure and static pressure

3

Differential pressure and temperature

5

Coplanar static pressure and temperature

6

In-line static pressure and temperature

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1.2

Product recycling/disposal
Recycling of equipment and packaging should be taken into consideration and disposed of in accordance
with local and national legislation/regulations.

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Section 2

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Configuration

Overview . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . page 3
Safety messages . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . page 4
Engineering Assistant installation . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . page 4
Flow configuration . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . page 7
Basic device configuration . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . page 24
Detailed device configuration . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . page 27
Variable configuration . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . page 38
Menu trees and Field Communicator Fast Keys . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . page 57

2.1

Overview
This section contains information for configuring the flow and device configuration for the Rosemount™
3051S MultiVariable™ Transmitter (Rosemount 3051SMV). Engineering Assistant installation and Flow
configuration instructions apply to Engineering Assistant version 6.3 or later. Basic device configuration,
Detailed device configuration, and Variable configuration are shown for AMS Device Manager version 9.0
or later, but also include Fast Key sequences for Field Communicator version 2.0 or later. Engineering
Assistant and AMS Device Manager screens are similar and follow the same instructions for use and
navigation. For convenience, Field Communicator Fast Key sequences are labeled “Fast Keys” for each
software function below the appropriate headings. The functionality of each host as show in Table 2-1:
Note
Coplanar transmitter configurations measuring gage pressure and process temperature (measurement
5) will report as the pressure as differential pressure. This will be reflected on the LCD display, nameplate,
digital interfaces, and other user interfaces.
Table 2-1. Host Functionality
• Available
— Not available

Multivariable
type

Fully
compensated
mass and energy
flow (M)

Direct process
variable output
(P)

Configuration

Rosemount 3051SMV
Engineering Assistant

AMS Device
Manager

Field
Communicator

Flow Configuration

•

•

—

Device Configuration

•

•

•

Test Calculation

•

•

•

Calibration

•

•

•

Diagnostics

•

•

•

Device Configuration

—

•

•

Calibration

—

•

•

Diagnostics

—

•

•

Functionality

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2.2

Safety messages
Procedures and instructions in this section may require special precautions to ensure the safety of the
personnel performing the operation. Information that raises potential safety issues is indicated with a
warning symbol ( ). Refer to the following safety messages before performing an operation preceded
by this symbol.

Failure to follow these installation guidelines could result in death or serious injury.


Make sure only qualified personnel perform the installation.

Explosions could result in death or serious injury.


Do not remove the transmitter cover in explosive atmospheres when the circuit is live.



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 flameproof/explosion-proof requirements.



Verify the operating atmosphere of the transmitter is consistent with the appropriate hazardous
locations certifications.

Electrical shock could cause death or serious injury.


If the sensor is installed in a high-voltage environment and a fault or installation error occurs, high
voltage may be present on the transmitter leads and terminals.



Use extreme caution when making contact with the leads and terminals.

Process leaks could result in death or serious injury.


Install and tighten all four flange bolts before applying pressure.



Do not attempt to loosen or remove flange bolts while the transmitter is in service.



Replacement equipment or spare parts not approved by Emerson™ for use as spare parts could
reduce the pressure retaining capabilities of the transmitter and may render the instrument
dangerous.



Use only bolts supplied or sold by Emerson as spare parts.

Improper assembly of manifolds to traditional flange can damage the device.


For safe assembly of manifold to traditional flange, bolts must break back plane of flange web
(i.e., bolt hole) but must not contact the sensor module.

Improper installation or repair of the SuperModule™ assembly with high pressure option (P0)
could result in death or serious injury.


For safe assembly, the high pressure SuperModule assembly must be installed with ASTM A193
Class 2 Grade B8M bolts and either a Rosemount 305 Manifold or a DIN-compliant traditional flange.

Static electricity can damage sensitive components.


Observe safe handling precautions for static-sensitive components.

2.3

Engineering Assistant installation

2.3.1

Engineering Assistant version 6.3 or later
The Rosemount 3051SMV Engineering Assistant 6.3 or later is PC-based software that performs
configuration, maintenance, diagnostic functions, and serves as the primary communication interface to
the Rosemount 3051SMV with the fully compensated mass and energy flow feature board.

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The Rosemount 3051SMV Engineering Assistant software is required to complete the flow
configuration.

2.3.2

Installation and initial setup
The following are the minimum system requirements to install the Rosemount 3051SMV Engineering
Assistant software:


Pentium-grade Processor: 500 MHz or faster



Operating system: Windows™ Professional 7, 8.1, 10
– 32-bit
– 64-bit



256 MB RAM



100 MB free hard disk space



RS232 serial port or USB port (for use with HART® modem)



CD-ROM

Installing the Rosemount 3051SMV Engineering Assistant version 6.3
or later
Engineering Assistant is available with or without the HART modem and connecting cables. The
complete Engineering Assistant package contains the software CD and one HART modem with cables
for connecting the computer to the Rosemount 3051SMV (See “Ordering information” on page 138.)
1. Uninstall any existing versions of Engineering Assistant 6 currently installed on the PC.
2. Insert the new Engineering Assistant disk into the CD-ROM.
3. Windows should detect the presence of a CD and start the installation program. Follow the on-screen
prompts to finish the installation. If Windows does not detect the CD, use Windows Explorer or My
Computer to view the contents of the CD-ROM, and then double select the SETUP.EXE program.
4. A series of screens (Installation Wizard) will appear and assist in the installation process. Follow the
on-screen prompts. It is recommended the default installation settings are used.
Note
Engineering Assistant version 6.3 or later requires the use of Microsoft® .NET Framework version 4.0 or
later. If .NET version 4.0 is not currently installed, the software will be automatically installed during the
Engineering Assistant installation. Microsoft .NET version 4.0 requires an additional 200 MB of disk
space.

Configuration

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Connecting to a PC
Figure 2-1 shows how to connect a computer to a Rosemount 3051SMV.
Figure 2-1. Connecting a PC to the Rosemount 3051SMV
Rosemount 3051SMV without
optional process temperature
connection

Rosemount 3051SMV with optional
process temperature connection

A

A

RL ≥ 250Ω
B

RL ≥ 250Ω
B

A. Power supply
B. HART modem

1. Remove the cover from the field terminals side of the housing.
2. Power the device as outlined in “Connect wiring and power up” on page 75.
3. Connect the HART modem cable to the PC.
4. On the side marked “Field Terminals,” connect the modem mini-grabbers to the two terminals
marked “PWR/COMM.”
5. Launch the Rosemount 3051SMV Engineering Assistant. For more information on launching
Engineering Assistant, see “Launching Engineering Assistant” on page 9.
6. Once the configuration is complete, replace cover and tighten until metal contacts metal to meet
flameproof/explosion-proof requirements. See “Cover installation” on page 69 for more information.

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2.4

Flow configuration

2.4.1

Rosemount 3051SMV Engineering Assistant 6.3 or later
The Rosemount 3051SMV Engineering Assistant is designed to guide the user through the setup of the
flow configuration of a Rosemount 3051SMV. The flow configuration screens allow the user to specify
the fluid, operating conditions, and information about the primary element including the inside pipe
diameter. This information will be used by the Rosemount 3051SMV Engineering Assistant to create the
flow configuration parameters that can be sent to the transmitter or saved for future use.

NOTICE
To ensure correct operation, download the most current version of the Engineering Assistant software
at Emerson.com/Rosemount-Engineering-Assistant-6.
Figure 2-2 shows the path in which the Rosemount 3051SMV Engineering Assistant will guide the user
through a flow configuration. If a natural gas, custom liquid, or custom gas option is chosen, an extra
screen will be provided to specify the gas composition or fluid properties.
Figure 2-2. Flow Configuration Flowchart
Start

Natural gas
Process fluid
selection

Custom gas or
custom liquid
fluid properties

Natural gas
composition

Fluid properties
(optional)

Custom liquid
Custom gas

Database liquid
Database gas or
steam
Ideal gas
Primary
element
selection

Save/Send
flow
configuration

Configuration

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Online and offline mode
The Engineering Assistant software can be used in two modes: online and offline. In online mode, the
user can receive the configuration from the transmitter, edit the configuration, send the changed
configuration to the transmitter, or save the configuration to a file. In offline mode, the user may create a
new flow configuration and save the configuration to a file or open and modify an existing file.

2.4.2

Basic navigation overview
Figure 2-3. Engineering Assistant Basic Navigation Overview
A
F
G

H

B

C

D

E

The Engineering Assistant software can be navigated in a variety of ways. The numbers below correspond to the numbers shown in
Figure 2-3.
A. The navigation tabs contain the flow configuration information. In offline mode, each tab will not become active until the
required fields on the previous tab are completed. In online mode, these tabs will be functional unless a change on a preceding
tab is made.
B. The Reset button will return each field within all of the flow configuration tabs (Fluid Selection, Fluid Properties, and Primary
Element Selection) to the values initially displayed at the start of the configuration.
a. If editing a previously saved flow configuration, the values will return to those that were last saved.
b. If starting a new flow configuration, all entered values will be erased.
C. The Back button is used to step backward through the flow configuration tabs.
D. The Next button is used to step forward through the flow configuration tabs. The Next button will not become active until all
required fields on the current page are completed.
E. The Help button may be selected at any time to get a detailed explanation of the information required on the current
configuration tab.
F. Any configuration information that needs to be entered or reviewed will appear in this portion of the screen.
G. These menus navigate to the Configure Flow, Basic Setup, Device, Variables, Calibration, and Save/Send tabs.
H. These buttons navigate to Config/Setup, Device Diagnostics, or Process Variables sections.

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2.4.3

Configuration
September 2017

Launching Engineering Assistant
Flow configuration for the Rosemount 3051SMV is achieved by launching the Engineering Assistant
Software from the START menu. The following steps show how to open the Engineering Assistant
Software, and connect to a device:
1. Select the Start menu > All Programs > Engineering Assistant. Engineering Assistant will open to
screen as shown in Figure 2-4.
2. If working offline, select the Offline button located on the bottom of the screen as shown in
Figure 2-4.
OR
If working online, select the Search button located on the lower right corner of the screen as shown in
Figure 2-4. Engineering Assistant will begin to search for online devices. When the search is
completed, select the device to communicate with and select Receive Configuration button.
The HART Master Level can be set to either primary or secondary. Secondary is the default and should be
used when the transmitter is on the same segment as another HART communication device. The COM
Port and device address may also be edited as needed.
Figure 2-4. Engineering Assistant Device Connection Screen

2.4.4

Preferences
The Preferences tab, shown in Figure 2-5 on page 10, allows the user to select the preferred engineering
units to display and specify flow configuration information.

Configuration



Select the preferred engineering units. If units are needed other than the default U.S. or S.I. units, use
the Custom Units setting. If Custom Units are selected, configure the Individual Parameters using the
drop-down menus.



Unit preferences selected will be retained for future Engineering Assistant sessions. Check the box to
prevent the Preferences tab from being automatically shown in future sessions. The Preferences are
always available by select the Preferences tab.
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Figure 2-5. Preferences Tab

2.4.5

Fluid selection for database liquid/gas
The Fluid Selection tab (see Figure 2-6) allows the user to select the process fluid.
Figure 2-6. Fluid Selection Tab

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Note
The following example will show a flow configuration for an application with database gas air as the
process fluid and a Rosemount 405C Conditioning Orifice Plate as the primary element. The procedure
to configure an application with other fluids and other primary elements will be similar to this example.
Natural gases, custom liquids, and custom gases require additional steps during the configuration. See
“Other fluid configurations” on page 18 for more information.
1. Engineering Assistant may open to the Preferences tab. Using the tabs at the top of the screen,
navigate to the Fluid Selection tab.
2. Expand the Gas category (select the + icon).
3. Expand the Database Gas category.
4. Select the appropriate fluid (Air for this example) from the list of database fluids.
Figure 2-7. Fluid Selection Tab - Database Gas Air

5. Enter the Nominal Operating Pressure, select the Enter or Tab key.
Note
The nominal operating pressure must be entered in absolute pressure units.
6. Enter the Nominal Operating Temperature, select the Enter or Tab key. Engineering Assistant will
automatically fill in suggested operating ranges, as shown in . These values may be edited as needed
by the user.
7. Verify the Reference Conditions are correct for the application. These values may be edited as needed.
Note
Reference pressure and temperature values are used by Engineering Assistant to convert the flow rate
from mass units to mass units expressed as standard or normal volumetric units.
8. Select Next > to proceed to the Fluid Properties tab.
Configuration

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Table 2-2. Liquids and Gases Database
1,1,2,2–Tetrafluoroethane

Acrylonitrile

Formaldehyde

Nitrous Oxide

1,1,2–Trichloroethane

Air

Formic Acid

Nonanal

1,2,4–Trichlorobenzene

Allyl Alcohol

Furan

n–Butane

1,2–Butadiene

Ammonia

Helium–4

n–Butanol

1,2–Propylene Glycol

Aniline

Hydrazine

n–Butyraldehyde

1,3–Propylene Glycol

Argon

Hydrogen

n–Butyronitrile

1,3,5–Trichlorobenzene

Benzene

Hydrogen Chloride

n–Decane

1,3–Butadiene

Benzaldehyde

Hydrogen Cyanide

n–Dodecane

1,4–Dioxane

Benzyl Alcohol

Hydrogen Peroxide

n–Heptadecane

1,4–Hexadiene

Biphenyl

Hydrogen Sulfide

n-Heptane

1–Butene

Bromine

Isobutane

n–Hexane

1–Decanol

Carbon Dioxide

Isobutylbenzene

n-Nonane

1–Decene

Carbon Monoxide

Isohexane

n–Octane

1–Dodecanol

Carbon Tetrachloride

Isoprene

n–Pentane

1–Dodecene

Chlorine

Isopropanol

Oxygen

1–Heptanol

Chlorotrifluoroethylene

Melamine

Pentafluoroethane

1–Heptene

Chloroprene

Methane

Phenol

1–Hexadecanol

Cycloheptane

Methanol

Propane

1–Hexene

Cyclohexane

Methyl Acrylate

Propadiene

1–Octanol

Cyclopentane

Methyl Ethyl Ketone

Pyrene

1–Octene

Cyclopentene

Methyl Vinyl Ether

Propylene

1–Nonanol

Cyclopropane

m–Chloronitrobenzene

p-Nitroaniline

1–Pentadecanol

Decanal

m–Dichlorobenzene

Sorbitol

1–Pentanol

Divinyl Ether

Neon

Styrene

1–Pentene

Ethane

Neopentane

Sulfur Dioxide

1–Undecanol

Ethanol

Nitric Acid

Toluene

2,2–Dimethylbutane

Ethylamine

Nitric Oxide

Trichloroethylene

2–Methyl–1–Pentene

Ethylbenzene

Nitrobenzene

Vinyl Acetate

Acetic Acid

Ethylene

Nitroethane

Vinyl Chloride

Acetone

Ethylene Glycol

Nitrogen

Vinyl Cyclohexane

Acetonitrile

Ethylene Oxide

Nitrogen Trifluoride

Vinylacetylene

Acetylene

Fluorene

Nitromethane

Water

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Configuration
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Fluid properties
Note
The Fluid Properties tab is an optional step and is not required to complete a flow configuration.
The Fluid Properties tab for the database gas air is shown in Figure 2-8. The user may view the properties
of the chosen fluid. The fluid properties are initially shown at nominal conditions. To view density, compressibility, and viscosity of the selected fluid at other pressure and temperature values, enter a Pressure
and Temperature and select Calculate.
Note
Changing the pressure and temperature values on the Fluid Properties tab does not affect the flow
configuration.

Figure 2-8. Fluid Properties Tab

2.4.7

Primary element selection
The Primary Element Selection tab shown in Figure 2-9 on page 14 allows the user to select the primary
element that will be used with the Rosemount 3051SMV. This database of primary elements includes:

Configuration



Rosemount proprietary elements such as the Rosemount Annubar™ and the conditioning orifice plate



Standardized primary elements such as ASME, ISO, and AGA primary elements



Other proprietary primary elements

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Figure 2-9. Primary Element Selection Tab

Continuing with the example configuration:
1. Expand the Conditioning Orifice category.
Figure 2-10. Primary Element Selection Tab - 405C/3051SFC

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2. Select 405C/3051SFC.
3. Enter the Measured Meter Tube Diameter (pipe ID) at a Reference Temperature. If the meter tube
diameter cannot be measured, select a Nominal Pipe Size and Pipe Schedule to input an estimated
value for the meter tube diameter (U.S. units only).
4. If necessary, edit the Meter Tube Material.
5. Enter the Line Size and select the Beta of the Conditioning Orifice Plate. The required primary element
sizing parameters will be different depending on what primary element is selected.
6. If necessary, select a Primary Element Material from the drop-down menu.
7. A calibration factor may be entered if a calibrated primary element is being used.
Note
A Joule-Thomson Coefficient can be enabled to compensate for the difference in process temperature
between the orifice plate location and the process temperature measurement point. The Joule-Thomson
Coefficient is available with ASME MFC-3M-2 (2004) or ISO 5167-2.2003 (E) orifice plates used with
Database Gases, Superheated Steam, or AGA DCM/ISO Molar Composition Natural Gas. For more
information on the Joule-Thomson Coefficient, reference the appropriate orifice plate standard.
8. Select Next > to advance to the Save/Send Configuration tab.
Note
To be in compliance with appropriate national or international standards, beta ratios and differential
producer diameters should be within the limits as listed in the applicable standards. The Engineering
Assistant software will alert the user if a primary element value exceeds these limits, but will allow the
user to proceed with the flow configuration.

2.4.8

Save/send
The Save/Send Configuration tab shown in Figure 2-11 on page 16 allows the user to view, save, and send
the configuration information to the Rosemount 3051SMV with the fully compensated mass and energy
flow feature board.
1. Review the information under the Flow Configuration heading and Device Configuration heading.
Note
For more information on device configuration, see “Basic device configuration” on page 24.

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Figure 2-11. Save/Send Configuration Tab (Offline Mode)

2. Select the icon above each window to be taken to the appropriate screen to edit the configuration
information. To return to the Save/Send tab, select Save/Send in the left menu.
3. When all information is correct, see “Sending a configuration in offline mode” on page 16 or “Sending
a configuration in online mode” on page 17.
Note
The user will be notified if the configuration has been modified since it was last sent to the transmitter. A
warning message will be shown to the right of the Send Flow Data and/or Send Device Data check boxes.

Sending a configuration in offline mode
1. To send the configuration, select the Send To button.
Note
The Send Flow Data and/or Send Device Data check boxes can be used to select what configuration data is
sent to the transmitter. If the check box is unselected, the corresponding data will not be sent.
2. The Engineering Assistant Device Connection screen will appear, see Figure 2-12 on page 17.

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Figure 2-12. Engineering Assistant Device Connection Screen

3. Select the Search button located in the lower right corner of the screen. Engineering Assistant will
begin to search for connected devices.
4. When the search is completed, select the device to communicate with and select Send
Configuration button.
5. Once the configuration is finished being sent to the device, a notification appears.
6. If finished with the configuration process, close Engineering Assistant.
Note
After the configuration is sent to the device, saving the configuration file is recommended. For more
information on saving a configuration file, see “Saving a configuration” on page 17.

Sending a configuration in online mode
1. To send the configuration, select the Send button. Once the configuration is finished being sent to
the device, a notification appears.
2. If finished with the configuration process, close Engineering Assistant.
Note
After the configuration is sent to the device, saving the configuration file is recommended. For more
information on saving a configuration file, see “Saving a configuration”.

Saving a configuration
1. To save the configuration, select the Save button.
2. Navigate to the save location for the configuration file, give the file a name, and select Save. The
configuration will be saved as a “.smv” file type.

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Sending a saved configuration
1. To send a saved configuration, open Engineering Assistant in offline mode and select File>Open.
2. Navigate to the saved .smv file to be sent. Select Open.
3. The Engineering Assistant Device Connection screen will appear, see Figure 2-12 on page 17.
4. Select the Search button located in the lower right corner of the screen. Engineering Assistant will
begin to search for connected devices.
5. When the search is completed, select the device to communicate with and select Send
Configuration button.
6. Once the configuration is finished being sent to the device, a notification appears.
7. If finished with the configuration process, close Engineering Assistant.

2.4.9

Other fluid configurations
Natural gas AGA No. 8 detail characterization or ISO 12213, molar
composition flow configuration
1. Expand the Gas category.
2. Expand the Natural Gas category.
3. Select AGA Report No. 8 Detail Characterization Method or ISO 12213, Molar Composition
Method.
4. Select Next > to proceed to the Fluid Composition tab. Figure 2-13 shows an example of the Fluid
Composition tab for AGA Report No. 8 Detail Characterization Method. The ISO 12213, Molar
Composition Method Fluid Composition tab will require the same information.
Figure 2-13. Fluid Composition Tab

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5. In the Available Components window, select the required components and move them into the
Selected Components window using the >> button. The << button moves the components back to the
Available Components window. The Clear button moves all components back to the Available
Components window.
6. After all required components are in the Selected Components window, begin assigning the percent
composition of each component in the Mole % column.
Note
These percent composition values should add to 100 percent. If they do not, select the Normalize
button. This will adjust the mole percentages proportionally to a total of 100 percent.
7. Enter the Nominal Operating Pressure, then the Nominal Operating Temperature as the entry blanks
become available. Engineering Assistant will automatically fill in suggested operating ranges. These
values may be edited by the user.
Note
In order to comply with the AGA requirements the calculation accuracy must be within ±50 ppm
(±0.005%). This is stated in AGA Report No. 3, Part 4, Section 4.3.1. The pressure and temperature
operating ranges will be autofilled to comply with the standard.
8. Select Next >. This will bring the user to the Fluid Properties tab.
9. Proceed with the steps in “Fluid properties” on page 13.

Natural gas AGA No. 8 gross characterization flow configuration
method 1, method 2, and natural gas ISO 12213, physical properties
(SGERG 88) flow configuration
1. Expand the Gas category.
2. Select AGA No. 8 Gross Characterization Method 1, AGA No. 8 Gross Characterization Method 2,
or ISO 12213, Physical Properties (SGERG 88).
3. Select Next to proceed to the Fluid Composition tab.
4. Enter the required data for the Natural Gas Characterization Method that was selected in Step 2.
Required data for each method is listed in Table 2-3.
Table 2-3. Required and Optional Data for Natural Gas Characterization Methods
Characterization method

Required data

Optional data

AGA Report No. 8 Gross
Characterization Method 1

Relative Density(1)
Mole Percent CO2
Volumetric Gross Heating Value(2)

Mole Percent CO
Mole Percent Hydrogen

AGA Report No. 8 Gross
Characterization Method 2

Relative Density(1)
Mole Percent CO2
Mole Percent Nitrogen

Mole Percent CO
Mole Percent Hydrogen

ISO 12213,
Physical Properties (SGERG 88)

Relative Density(1)
Mole Percent CO2
Volumetric Gross Heating Value(2)

Mole Percent CO
Mole Percent Hydrogen

1.
2.

Configuration

Reference conditions for the relative density are 60 °F (15.56 °C) and 14.73 psia (101.56 kPa).
Reference conditions for the molar gross heating value are 60 °F (15.56 °C) and 14.73 psia (101.56 kPa) and reference conditions for molar
density are 60 °F (15.56 °C) and 14.73 psia (101.56 kPa).

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5. If appropriate, enter the optional data for the Natural Gas Characterization Method that was selected
in Step 2. Optional data for each method is listed in Table 2-3 on page 19.
6. Enter the Nominal Operating Pressure, then the Nominal Operating Temperature as the entry blanks
come available. Engineering Assistant will automatically fill in suggested operating ranges. Note that
these values may be edited by the user.
7. Select Next. This will open the Fluid Properties tab.
8. Proceed with the steps in “Fluid properties” on page 13.

Ideal gas
The ideal gas option should be used when the fluid behavior can be modeled by the ideal gas law. This
option uses a modified version of the ideal gas law with a constant value of compressibility. The default
value for compressibility is 1.00 but it may be edited by the user. To use an ideal gas enter in the
operating pressure and temperature followed by either the density, specific gravity, or molecular weight.
1. Expand the GAS category.
2. Select the Ideal Gas option.
3. Enter the Nominal Operating Pressure and Temperature Ranges. Engineering Assistant will use these
ranges to identify the pressure and temperature values at which the fluid properties are required.
For the ideal gas being used the nominal density, specific gravity, or molecular weight must now be
entered using the drop-down menu. Once these are entered the other data entry fields, compressibility
and viscosity, are enabled as shown on Figure 2-14.
Figure 2-14. Fluid Selection Ideal Gas

4. Adjust the compressibility and viscosity to fit the ideal gas of the process.
5. Select Next to proceed to the Fluid Properties tab.

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Note
The Fluid Properties tab is an optional step and is not required to complete a flow configuration.
The Fluid Properties tab for the database gas air is shown in Figure 2-15. The user may view the
properties of the chosen fluid. The fluid properties are initially shown at nominal conditions. To view
density, compressibility, and viscosity of the selected fluid at other pressure and temperature values,
enter a Pressure and Temperature and select Calculate.
Changing the pressure and temperature values on the Fluid Properties tab does not affect the flow
configuration.

Figure 2-15. Fluid Properties Tab

6. Select Next to continue with the flow configuration on the Primary Element Selection tab.
7. Proceed with the steps in “Primary element selection” on page 13.

Custom gas
The custom gas option should be used for fluids not in the database such as proprietary fluids or gas
mixtures. To properly calculate the fluid properties, the compressibility factor or density needs to be
entered at specific pressure and temperature values based on the operating ranges entered by the user.
The pressure and temperature values may be edited as needed. The editable values are shown in fields
with white backgrounds. For best performance, it is recommended that, whenever possible, the compressibility or density values be entered at the suggested pressure and temperature values.
To ease entering the compressibility/density or viscosity values, data can be copied from a spreadsheet
and pasted into the grid. The recommended process is to copy the pressure and temperature values
from the table on the Engineering Assistant screen to assist in computing the density or compressibility
values. Once the compressibility or density values are computed, they may then be copied from the
spreadsheet and pasted into the grid on the Custom Gas Fluid Properties tab.

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1. Expand the Gas category.
2. Select the Custom Gas option.
3. Enter the Nominal Operating Pressure and Temperature Ranges. Engineering Assistant will use these
ranges to identify the pressure and temperature values at which the fluid properties are required.
4. Select Next to proceed to the Custom Gas Fluid Properties tab.
5. Enter the Molecular Weight of the Custom Gas. When the molecular weight of the gas is entered, the
other data entry fields on the tab are enabled as shown in Figure 2-16 on page 22.
6. Select either Density or Compressibility and enter data.
Note
All pressure and temperature values may be edited except the minimum and maximum values. The
minimum and maximum values were set on the Fluid Selection tab.
7. Enter the Density or Compressibility at reference conditions.
8. Enter the Custom Gas Viscosity at the given temperatures. Note that all temperature values may be
edited except the minimum and maximum temperatures.
9. Enter the Custom Gas Isentropic Exponent.
10.Select Next to continue with the flow configuration on the Primary Element Selection tab.
11.Proceed with the steps in “Primary element selection” on page 13.
Figure 2-16. Custom Gas Fluid Properties Tab

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Custom liquid (Density [T])
The Custom Liquid option should be used for fluids not in the database such as proprietary fluids.
1. Expand the Liquid category.
2. Expand the Custom Liquid category.
3. Select the Custom Liquid (Density [T]) option.
4. Enter the Nominal and Operating Temperature Range. Engineering Assistant will use this range to
identify the temperature values at which the fluid properties are required.
5. Select Next to continue the flow configuration on the Fluid Properties tab.
6. Enter the Custom Liquid Density at the given temperatures.
Note
All temperature values may be edited except the minimum and maximum temperatures.
7. Enter the Reference Density at the reference temperature.
8. Enter the Custom Liquid Viscosity at the given temperatures. Note that all temperature values may be
edited except the minimum and maximum temperatures. The minimum and maximum values were
set on the Fluid Selection tab.
9. Proceed with the steps in “Primary element selection” on page 13.
Figure 2-17. Custom Liquid (Density [T]) Fluid Properties Tab

Configuration

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2.5

Basic device configuration
Mass and energy flow Fast Keys

1, 3

Direct process variable output Fast Keys

1, 3

This section provides procedures for configuring the basic requirements to commission the Rosemount
3051SMV. The Basic Setup tab, shown in Figure 2-18 on page 25, can be used to perform all of the
required transmitter configuration. The complete list of Field Communicator Fast Keys for basic setup are
shown in Table 2-13 on page 62 and Table 2-14 on page 63.
Based on the configuration ordered, some measurements (i.e. static pressure, process temperature)
and/or calculation types (i.e. mass, volumetric, and energy flow) may not be available for all fluid types.
Available measurements and/or calculation types are determined by the multivariable type and
measurement type codes ordered. See “Ordering information” on page 138 for more information.
All screens in this section are shown for multivariable type M (fully compensated mass and energy flow)
with measurement type 1 (differential pressure, static pressure, and process temperature). Field
Communicator Fast Keys are given for both multivariable type M and P (direct process variable output)
with measurement type 1. Field Communicator Fast Keys and screens for other multivariable types and
measurement types may vary.
Note
All screen shots in this section will be shown using AMS Device Manager. Engineering Assistant screens
are similar and the instructions shown here apply to both AMS Device Manager and Engineering
Assistant.
When using Engineering Assistant, a Reset Page button will be shown. In online mode, the Reset Page
button will return all values on tab to the initial values received from the device before the start of the
configuration. If editing a previously saved configuration, the Reset Page button will return all values on
tab to those that were last saved. If starting a new configuration, all entered values on tab will be erased.
When information is edited on any AMS Device Manager tab, it will be highlighted in yellow. Edited
information is not sent to the transmitter until the Apply or OK button is selected.

Units of measure
If a unit of measure is edited and the Apply button is selected, the unit of measure will be changed in the
device memory and on screen, but the value may take up to 30 seconds to be updated on the AMS
Device Manager screen.

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Figure 2-18. Basic Setup Tab



Verify the Device Tag information. The tag information is used to identify specific transmitters on the
4–20 mA loop. This tag information may be edited.



Under the Flow Rate heading (fully compensated mass and energy flow feature board only), the type of
flow calculation (mass or volumetric) is displayed by the indicators on the right side of the box. The
Flow Calculation Type may be edited by selecting the Configure Flow Calculation Type button. The
Damping and Units of the Flow Rate may also be edited under this heading.

Note
The flow calculation within the device uses undamped process variables. Flow rate damping is set
independently of measured process variables.

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

Under the Energy Rate heading (fully compensated mass and energy flow feature board only), the Units
and Damping for the Energy Rate may be edited.

Note
Energy rate calculations are only available for steam and natural gas.
The energy rate calculation within the device uses undamped process variables. Energy rate damping is
set independently of flow rate damping or measured process variables.


Under the Differential Pressure heading, the Units and Damping for the Differential Pressure may be
edited.



Under the Static Pressure heading, the Units for both absolute and gage pressure and static pressure
Damping may be edited.

Note
Both absolute and gage pressure are available as variables. The type of transmitter ordered will
determine which variable is measured and which is calculated based on the user defined atmospheric
pressure. For more information on configuring the atmospheric pressure, see “Static pressure” on
page 53. Since only one of the static pressures is actually being measured, there is a single damping
setting for both variables which may be edited under the Static Pressure heading.

26



Under the Process Temperature heading, the Units and Damping for the Process Temperature may be
edited.



Under the Module Temperature heading, the Units for the sensor module temperature may be set. The
sensor module temperature measurement is taken within the module, near the differential pressure
and/or static pressure sensors and can be used to control heat tracing or diagnose device overheating.



Under the Analog Output heading, the primary variable can be selected from the drop down menu and
the upper and lower range values (4 and 20 mA points) for the primary variable may be edited.



Under the Totalizer heading (fully compensated mass and energy flow feature board only), the Totalizer
can be configured by selecting the Configure Totalizer button. This button allows the user to select
the variable to be totalized. The Totalizer Units may also be edited under this heading.

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2.6

Detailed device configuration

2.6.1

Model identification
Mass and energy flow Fast Keys

1, 3, 5

Direct process variable output Fast Keys

1, 3, 5

The Identification tab displays the device identification information on one screen. The fields with white
backgrounds may be edited by the user.
Figure 2-19. Device - Identification Tab

2.6.2

Alarm and saturation
The Rosemount 3051SMV automatically and continuously performs self-diagnostic routines. If the
self-diagnostic routines detect a failure, the transmitter drives the output to the configured alarm value.
The transmitter will also drive the output to configured saturation values if the primary variable goes
outside the 4–20 mA range values.
The alarm and saturation settings can be configured using Engineering Assistant, AMS Device Manager,
or a Field Communicator. See “Alarm and saturation level configuration” on page 28 for more
information. The alarm direction can be configured using the hardware switch on the feature board. See
“Configure security (write protect)” on page 67 for more information on the hardware switch.
The Rosemount 3051SMV has three options for alarm and saturation levels:

Configuration



Rosemount (Standard), see Table 2-4 on page 28



NAMUR, see Table 2-5 on page 28



Custom (user-defined), see Table 2-6 on page 28

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Table 2-4. Rosemount (Standard) Alarm and Saturation Values
Level

Saturation

Alarm

Low

3.9 mA

≤ 3.75 mA

High

20.8 mA

≥ 21.75 mA

Table 2-5. NAMUR-Compliant Alarm and Saturation Values
Level

Saturation

Alarm

Low

3.8 mA

≤ 3.6 mA

High

20.5 mA

≥ 22.5 mA

Table 2-6. Custom Alarm and Saturation Values
Level

Saturation

Alarm

Low

3.7 mA — 3.9 mA

3.6 mA — 3.8 mA

High

20.1 mA — 22.9 mA

20.2 mA — 23.0 mA

The following limitations exist for custom levels:


Low alarm level must be less than the low saturation level



High alarm level must be higher than the high saturation level



Alarm and saturation levels must be separated by at least 0.1 mA

Alarm and saturation level configuration
Mass and energy flow Fast Keys

1, 4, 2, 6, 6

Direct process variable output Fast Keys

1, 4, 2, 6, 6

The Alarm/Sat Levels tab allows the Alarm and Saturation Levels to be configured. To change alarm/saturation level settings, select the Config Alarm/Sat Levels button.

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Figure 2-20. Device - Alarm/Sat Levels Tab

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Alarm level verification
The transmitter alarm level should be verified before returning the transmitter to service if alarm and
saturation levels are changed.
This feature is also useful in testing the reaction of the control system to a transmitter in an alarm state.
To verify the transmitter alarm values, perform a loop test and set the transmitter output to the alarm
value (see Table 2-4, Table 2-5, and Table 2-6 on page 28, and “Analog output loop test” on page 96).

Variable saturation behavior
The analog output of the Rosemount 3051SMV may respond differently based on which measurement
goes outside the sensor limits. This response will also depend on the device configuration. Table 2-7 lists
the behaviors of the analog output under different conditions.
Table 2-7. Variable Saturation Behavior

30

Primary variable

Action

Analog output behavior

Flow or Energy Flow

Differential Pressure goes outside
the sensor limits

Analog output goes to high or low saturation

Flow or Energy Flow

Absolute Pressure or Gage Pressure
goes outside the sensor limits

Analog output does not saturate

Flow or Energy Flow

Process Temperature goes outside
the user defined sensor limits

Temperature mode is Normal:
Analog output goes into high or low alarm.
Temperature Mode is Backup:
The Process Temp will go into backup mode and
be fixed at the user defined value. Analog
output will not saturate or go into alarm.

DP

Differential Pressure goes outside
the sensor limits

Analog output goes to high or low saturation

AP or GP

Absolute Pressure or Gage Pressure
goes outside the sensor limits

Analog output goes to high or low saturation

Process Temp

Process Temperature goes outside
the user defined sensor limits

Direct process variable output:
Analog output goes to high or low saturation
Mass and Energy Flow:
Analog output goes to high or low alarm

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Variable mapping
Mass and energy flow Fast Keys

1, 4, 3, 4

Direct process variable output Fast Keys

1, 4, 3, 4

The Variable Mapping tab is used to define which process variable will be mapped to each HART variable.
The primary variable represents the 4–20 mA analog output signal while the 2nd, 3rd, and 4th variables
are digital. To edit the variable assignments, select the appropriate process variables from the
drop-down menus and select Apply.
Figure 2-21. Device - Variable Mapping Tab

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2.6.4

LCD display
Mass and energy flow Fast Keys

1, 3, 8

Direct process variable output Fast Keys

1, 3, 8

The LCD display features a four-line display and a 0–100 percent scaled bar graph. The first line of five
characters displays the output description, the second line of seven digits displays the actual value, and
the third line of six characters displays engineering units. The fourth line displays “Error” when there is a
problem detected with the transmitter. The LCD display can also show diagnostic messages. These
diagnostic messages are listed in Table 5-1 on page 108.
The LCD tab allows the user to configure which variables will be shown on the LCD display. Select the
check box next to each variable to select a variable for display. The transmitter will scroll through the
selected variables, showing each for three seconds.
Figure 2-22. Device - LCD Tab

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Communication setup
Mass and energy flow Fast Keys

1, 4, 3, 3

Direct process variable output Fast Keys

1, 4, 3, 3

The Comm Setup tab allows the settings for burst mode and multidrop communications to be
configured.
Figure 2-23. Device - Comm Setup Tab

Burst mode
When Burst Mode Enable is set to on, the Rosemount 3051SMV sends up to four HART variables to the
control system without the control system polling for information from the transmitter.
When operating with Burst Mode Enable set to on, the transmitter will continue to output a 4–20 mA
analog signal. Because the HART protocol features simultaneous digital and analog data transmission,
the analog value can drive other equipment in the loop while the control system is receiving the digital
information. Burst mode applies only to the transmission of dynamic data (process variables in
engineering units, primary variable in percent of range, and/or analog output), and does not affect the
way other transmitter data is accessed.
Access to information that is not burst can be obtained through the normal poll/response method of
HART communication. A Field Communicator, AMS Device Manager, Engineering Assistant, or the
control system may request any of the information that is normally available while the transmitter is in
burst mode.

Enabling burst mode
Mass and energy flow Fast Keys

1, 4, 3, 3, 3

Direct process variable output Fast Keys

1, 4, 3, 3, 3

To enable burst mode, select On from the Burst Mode Enable drop-down menu under the Burst Mode
heading.
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Choosing a burst option
Mass and energy flow Fast Keys

1, 4, 3, 3, 4

Direct process variable output Fast Keys

1, 4, 3, 3, 4

This parameter selects the information to be burst. Make a selection from the Burst Option drop-down
menu under the Burst Mode heading. The Dyn vars/current option is the most common, because it is used
to communicate with the Rosemount 333 HART Tri-Loop™.
Table 2-8. Burst Options
HART command

Burst option

Description

1

PV

Primary variable

2

% range/current

Percent of range and milliamp output

3

Dyn vars/current

All process variables and milliamp output

9

Device vars w/ status

Burst variables and status information

33

Device variables

Burst variables

Choosing burst variable slot definition
Mass and energy flow Fast Keys

1, 4, 3, 3, 5

Direct process variable output Fast Keys

1, 4, 3, 3, 5

If the burst option Device vars w/ status or Device variables is selected, the user may select the four
variables that will be burst. These are defined in slots 1–4 under the Burst Variable Slot Definitions
heading. The variables defined in slots 1–4 can be different than the variables mapped to the primary,
2nd, 3rd, and 4th variable outputs.

Multidrop communication
Multidropping transmitters refers to the connection of several transmitters to a single communications
transmission line.
Note
Figure 2-24 on page 35 shows a typical multidrop network. This figure is not intended as an installation
diagram.
Communication between the host and the transmitters takes place digitally with the analog output of
the transmitters deactivated.
Note
A transmitter in multidrop mode with Loop Current Mode disabled has the analog output fixed at 4 mA.

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Figure 2-24. Typical Multidrop Network
B

A

A. Power supply
B. HART modem

Enable multidrop communication
Mass and energy flow Fast Keys

1, 4, 3, 3, 1

Direct process variable output Fast Keys

1, 4, 3, 3, 1

The Rosemount 3051SMV is set to address zero (0) at the factory, which allows operation in the standard
point-to-point manner with a 4–20 mA output signal. To activate multidrop communication, the
transmitter address must be changed to 1–15 for HART 5 hosts or 1–63 for HART 6 hosts. This change
deactivates the 4–20 mA analog output, sending it to a fixed value of 4 mA. It also disables the failure
alarm signal, which is controlled by the HI/LO alarm switch position on the feature board. Failure signals
in multidropped transmitters are communicated through HART messages.

Loop current mode
Mass and energy flow Fast Keys

1, 4, 3, 3, 2

Direct process variable output Fast Keys

1, 4, 3, 3, 2

When using multidrop communication, the loop current mode drop-down menu defines how the 4–20
mA analog output behaves. When loop current mode is disabled, the analog output will be fixed at
4 mA. When the loop current mode is enabled, the analog output will follow the primary variable.

2.6.6

Materials of construction
Mass and energy flow Fast Keys

1, 4, 4, 2

Direct process variable output Fast Keys

1, 4, 4, 2

The Materials of Construction tab allows the materials of construction, remote seal, and equipped sensor
information to be viewed. The parameters shown in white boxes may be edited by the user, but do not
affect the operation of the device.

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Figure 2-25. Device - Materials of Construction Tab

2.6.7

Flow configuration parameters
Mass and energy flow Fast Keys

1, 4, 4, 3

(Fully compensated mass and energy flow feature board only)
The Flow Config Parameters tab allows the Process Fluid, Primary Element type and Pipe Diameter used in
the flow configuration to be viewed. These values may only be edited using Engineering Assistant
version 6.3 or later.

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Figure 2-26. Device - Flow Config Parameters Tab

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2.7

Variable configuration

2.7.1

Flow rate
Mass and energy flow Fast Keys

1, 4, 1, 1

(Fully compensated mass and energy flow feature board only)
The Flow tab is used to configure the settings associated with the Flow Variable. Fluid and primary
element information which defines the flow calculation is configured using Engineering Assistant.
Figure 2-27. Variables - Flow Tab



Under the Flow Rate Setup heading, the type of flow calculation is indicated by the check boxes next to
either Mass Flow Calculation or Volumetric Flow Calculation. To edit the flow calculation type, select the
Configure Flow Calculation Type button.



Edit the Flow Rate Units and Damping value as needed. The flow calculation within the device uses
undamped process variables. Flow rate damping is set independently of the measured process
variables.

Note
If the flow calculation type is changed, the totalizer will be stopped and reset automatically.

38



Under the Low Flow Cutoff heading, edit the current Minimum DP Value as needed. The unit for this
value is the user-selected DP unit. If the measured DP value is less than the minimum DP value, the
transmitter will calculate the Flow Rate value to be zero.



The Sensor Limits and Minimum Span can be viewed under the Flow Rate Sensor Limits heading.

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Note
If the flow rate is configured as the primary variable and is being output via the 4–20 mA signal, verify the
4–20 mA range (LRV and URV) after completing the custom unit configuration. For more information on
verifying the 4–20 mA range, see “Basic device configuration” on page 24.
Follow these steps to configure a custom unit:
a. Custom Unit: Enter the desired custom unit label to be displayed for the flow rate. Up to five
characters including letters, numbers, and symbols can be entered in the custom unit field.
Note
It is recommended that the Custom Unit be entered in upper case letters. If lower case letters are
entered, the LCD display will show upper case letters. Additionally, the following special characters are
recognized by the LCD display: hyphens (“-”), percent symbols (“%”), asterisks (“*”), forward slashes (“/”)
and spaces. Any other character entered for the Custom Unit will be displayed as an asterisk (“*”) on the
LCD display. The following warning will be returned indicating these changes: “Custom Unit contains
characters that will display in upper case or asterisks on LCD display. The DCS will display as entered.”
b. Base Unit: From the drop-down menu, select a base unit to be used for the custom unit
relationship.
c. Base per Custom: Enter a numeric value that represents the number of base units per one
custom unit. The Rosemount 3051SMV uses the following convention:
Number of Base Units
Base per Custom = ---------------------------------------------------------------------1xCustomxUnit

Example
Custom Unit: kg
Base Unit: g
Because:
1 kg (Kilogram) = 1000 g (Grams)
1000 ⋅ g
of Base Units
- = 1000
Base per Custom = Number
---------------------------------------------------------------------- = -------------------1 ⋅ kg
1xCustomxUnit
The values of Base per Custom for common flow units are shown in Table 2-9.
d. Select Apply.
e. Flow Rate Unit: From the drop-down menu, select the custom unit that was created in Step b.
Note
The custom unit may not be available as a selection in the Flow Rate Unit drop-down menu until the
drop-down menu is refreshed. To refresh the drop-down menu, navigate to the Basic Setup tab and then
return to the Variables - Flow tab.
Table 2-9. Common Custom Units - Flow

Configuration

Custom unit

Base unit

Base per custom

Barrels per Minute (BBL/M)

bbl/h

60

Cubic Meters per Day (CUM/D)

Cum/h

0.041667

Millions of Cubic Meters per Day (MMCMD)

Cum/h

41666.7
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Table 2-9. Common Custom Units - Flow
Custom unit

Base unit

Base per custom

Millions of Gallons per Day (MGD)

gal/d

1000000

Millions of Liters per Day (MML/D)

L/h

41666.7

Millions of Standard Cubic Feet per Day (MMCFD)

StdCuft/min

694.444

Normal Cubic Meters per Day (NCM/D)

NmlCum/h

0.041667

Normal Cubic Meters per Minute (NCM/M)

NmlCum/h

60

Short Tons per Day (STOND)

lb/d

2000

Short Tons per Hour (STONH)

lb/h

2000

Standard Cubic Feet per Day (SCF/D)

StdCuft/min

0.000694

Standard Cubic Feet per Hour (SCF/H)

StdCuft/min

0.016667

Standard Cubic Feet per Second (SCF/S)

StdCuft/min

60

Standard Cubic Meters per Day (SCM/D)

StdCum/h

0.041667

Thousands of Gallons per Day (KGD)

gal/d

1000

Thousands of Pounds per Hour (KLB/H)

lb/h

1000

Thousands of Standard Cubic Feet per Day (KSCFD)

StdCuft/min

0.694444

Thousands of Standard Cubic Feet per Hour (KSCFH)

StdCuft/min

16.6666

If conversion factor tables or internet search engines are used to determine the Base per Custom value, it
is important to enter the Custom Unit in the “From” field and the Base Unit in the “To” Field. An example
of this is shown below:

To calculate the Base per Custom value for a custom unit not shown in Table 2-9 on page 39, see one of
the following examples:

40



Mass/volume conversion example: page 41



Time conversion example: page 42



Mass/volume and time conversion example: page 43

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Mass/volume conversion example
To find the Base per Custom relationship for a custom unit of kilograms per hour (kg/h) and a base unit of
grams per hour (g/h), input the following:
Custom Unit = kg/h
Base Unit = g/h
Because:
1 kg (Kilogram) = 1000 g (Grams)
Then:
1 ⋅ kg
1000 ⋅ g
1 kg/h = -------------- ⫻ --------------------- = 1000 g/h
1⋅h
1 ⋅ kg
1 kg/h = 1000 g/h
Therefore:
of Base Units 1000 ⋅ g ⁄ h- = 1000
Base per Custom = Number
---------------------------------------------------------------------- = --------------------------1 ⋅ kg ⁄ h
1xCustomxUnit
Figure 2-28. Flow Rate Custom Units - Mass/Volume Conversion Example

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Time conversion example
To find the Base per Custom relationship for a custom unit of standard cubic feet per hour (scf/h) and a
base unit of standard cubic feet per minute (StdCuft/min), input the following:
Custom Unit = scf/h
Base Unit = StdCuft/min
Because:
1 h (Hour) = 60 min (Minutes)
Then:
1 ⋅ scf
1⋅h
1 scf/h = --------------- ⫻ --------------------- = 0.016667 StdCuft/min
1⋅h
60 ⋅ min
1 scf/h = 0.016667 StdCuft/min
Therefore:
0.016667 ⋅ StdCuft ⁄ min
of Base Units
Base per Custom = Number
---------------------------------------------------------------------- = ------------------------------------------------------------------ = 0.016667
1 ⋅ scf ⁄ h
1xCustomxUnit
Figure 2-29. Flow Rate Custom Units - Time Conversion Example

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Mass/volume and time conversion example
To find the Base per Custom relationship for a custom unit of standard millions of standard cubic feet per
day (mmcfd) and a base unit of standard cubic feet per minute (StdCuft/min), input the following:
Custom Unit = mmcfd
Base Unit = StdCuft/min
Because:
1 mmcf (Millions of Standard Cubic Feet) = 1000000 StdCuft (Standard Cubic Feet) and
1 d (Day) = 1440 min (Minutes)
Then:
1000000 ⋅ StdCuft
1 ⋅ mmcf
1⋅d
1 mmcfd = ------------------------ ⫻ ------------------------------------------------- ⫻ ---------------------------- = 694.444 StdCuft/min
1 ⋅ mmcf
1⋅d
1440 ⋅ min
1 mmcfd = 694.444 StdCuft/min
Therefore:
Number of Base Units
694.444 ⋅ StdCuft ⁄ min
Base per Custom = ---------------------------------------------------------------------- = -------------------------------------------------------------- = 694.444
1xCustomxUnit
1 ⋅ mmcfd
Figure 2-30. Flow Rate Custom Units - Mass/Volume and Time Conversion Example

Under the Custom Units Setup heading, the user may configure a custom unit for the flow rate
measurement. Custom units allow the flow rate to be displayed in units of measure that are not standard
in the Rosemount 3051SMV.

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2.7.2

Energy rate
Mass and energy flow Fast Keys

1, 4, 1, 2

(Fully compensated mass and energy flow feature board only)
Note
Energy Rate calculations are only available for certain fluid types.
The Energy tab allows the user to configure the settings associated with the energy flow.


Under the Energy Rate Setup heading, edit the Energy Rate Units and Damping values as needed. The
energy rate calculation within the device uses undamped process variables. Energy rate damping is set
independently of flow rate damping and measured process variables.



Under the Custom Units Setup heading, the user may configure a custom unit for the energy rate
measurement. Custom units allow the energy rate to be displayed in units of measure that are not
standard in the Rosemount 3051SMV.

Note
If the energy rate is configured as the primary variable and is being output via the 4-20 mA signal, verify
the 4–20 mA range (LRV and URV) after completing the custom unit configuration. For more
information on verifying the 4–20 mA range, see “Basic device configuration” on page 24.
Follow these steps to configure a custom unit:
a. Custom Unit: Enter the desired custom unit label to be displayed for the energy rate. Up to five
characters including letters, numbers, and symbols can be entered in the custom unit field.
Note
It is recommended that the Custom Unit be entered in upper case letters If lower case letters are entered,
the LCD display will show upper case letters. Additionally, the following special characters are recognized
by the LCD display: hyphens (“-”), percent symbols (“%”), asterisks (“*”), forward slashes (“/”) and
spaces. Any other character entered for the Custom Unit will be displayed as an asterisk (“*”) on the LCD
display. The following warning will be returned indicating these changes: “Custom Unit contains
characters that will display in upper case or asterisks on LCD display. The DCS will display as entered.”
b. Base Unit: From the drop-down menu, select a base unit to be used for the custom unit
relationship.
c. Base per Custom: Enter a numeric value that represents the number of base units per one
custom unit. The Rosemount 3051SMV uses the following convention:
Number of Base Units
Base per Custom = ---------------------------------------------------------------------1xCustomxUnit

Example
Custom Unit: kg
Base Unit: g
Because:
1 kg (Kilogram) = 1000 g (Grams)
Number of Base Units
1000 ⋅ g
Base per Custom = ---------------------------------------------------------------------- = --------------------- = 1000
1xCustomxUnit
1 ⋅ kg
The values of Base per Custom for common energy units are shown in Table 2-10 on page 45.
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d. Select Apply.
e. Energy Rate Unit: From the drop-down menu, select the custom unit that was created in Step b.
Note
The custom unit may not be available as a selection in the Energy Rate Unit drop-down menu until the
drop-down menu is refreshed. To refresh the drop-down menu, navigate to the Basic Setup tab and then
return to the Variables - Energy tab.
Table 2-10. Common Custom Units - Energy Flow
Custom unit

Base unit

Base per custom

BTU per Day (BTU/D)

Btu/h

0.041667

BTU per Minute (BTU/M)

Btu/h

60

Megajoules per Day (MJ/D)

MJ/h

0.041667

Megajoules per Minute (MJ/M)

MJ/h

60

Thousands of BTU per Day (KBTUD)

Btu/h

41.6667

Thousands of BTU per Hour (KBTUH)

Btu/h

1000

If conversion factor tables or internet search engines are used to determine the Base per Custom value, it
is important to enter the Custom Unit in the “From” field and the Base Unit in the “To” Field. An example
of this is shown below:

To calculate the Base per Custom value for a custom unit not shown in Table 2-10 on page 45, see one of
the following examples:

Configuration



Energy conversion example: page 46



Time conversion example: page 47



Energy and time conversion example: page 47

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Energy conversion example
To find the Base per Custom relationship for a custom unit of thousands of BTU per hour (kBtuh) and a
base unit of BTU per hour (Btu/h), input the following:
Custom Unit = kBtuh
Base Unit = Btu/h
Because:
1 kBtu (Thousands of BTU) = 1000 Btu
Then:
1 ⋅ kBtu
1000 ⋅ Btu
1 kBtuh = -------------------- ⫻ --------------------------- = 1000 Btu/h
1⋅h
1⋅h
1 kBtuh = 1000 Btu/h
Therefore:
Number of Base Units
1000 ⋅ Btu ⁄ h
Base per Custom = ---------------------------------------------------------------------- = ---------------------------------- = 1000
1xCustomxUnit
1 ⋅ kBtuh
Figure 2-31. Energy Rate Custom Units - Energy Conversion Example

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Time conversion example
To find the Base per Custom relationship for a custom unit of BTU per day (Btu/d) and a base unit of BTU
per hour (Btu/h), input the following:
Custom Unit = Btu/d
Base Unit = Btu/h
Because:
1 d (Day) = 24 h (Hours)
Then:
1 ⋅ Btu
1⋅d
1 Btu/d = ----------------- ⫻ -------------- = 0.041667 Btu/h
1⋅d
24 ⋅ h
1 Btu/d = 0.041667 Btu/h
Therefore:
Number of Base Units
0.041667 ⋅ Btu ⁄ h
Base per Custom = ---------------------------------------------------------------------- = ---------------------------------------------- = 0.041667
1xCustomxUnit
1 ⋅ Btu ⁄ d
Figure 2-32. Energy Rate Custom Units - Time Conversion Example

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Energy and time conversion example
To find the Base per Custom relationship for a custom unit of thousands of BTU per day (kBtud) and a
base unit of BTU per hour (Btu/h), input the following:
Custom Unit = kBtud
Base Unit = Btu/h
Because:
1 kBtu (Thousands of BTU)= 1000 Btu and
1 d (Day) = 24 h (Hours)
Then:
1000 ⋅ Btu
1 ⋅ kBtu
1⋅d
1 kBtud = -------------------- ⫻ --------------------------- ⫻ -------------- = 41.6667 Btu/h
1
⋅
kBtu
1⋅d
24 ⋅ h
1 kBtud = 41.6667 Btu/h
Therefore:
Number of Base Units
41.6667 ⋅ Btu ⁄ h
Base per Custom = ---------------------------------------------------------------------- = ------------------------------------------- = 41.6667
1xCustomxUnit
1 ⋅ kBtud
Figure 2-33. Energy Rate Custom Units - Energy and Time Conversion Example

48



Under the Low Flow Cutoff heading, edit the current Minimum DP Value as needed. The unit for this
value is the user-selected DP unit. If the measured DP value is less than the minimum DP value, the
transmitter will calculate the energy value to be zero.



The Sensor Limits and Minimum Span can be viewed under the Energy Rate Sensor Limits heading.

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2.7.3

September 2017

Totalizer
Mass and energy flow Fast Keys

1, 4, 1, 3

(Fully compensated mass and energy flow feature board only)
The Totalizer tab is used to configure the settings associated with the totalizer functionality within the
transmitter.
Figure 2-34. Variables - Totalizer Tab

1. To turn the totalizer functionality on or off, select Start or Stop from the Mode drop down menu
under the Totalizer Setup heading. The totalizer Units may also be edited under this heading.
2. Verify the Totalized Parameter and the Totalizer Maximum value. To edit the Totalized Parameter, select
the Configure Totalizer button under the Totalizer Control heading.
Note
When the totalizer reaches its maximum value, it automatically resets to zero and continues totalizing.
The default maximum is a value equivalent to 4.29 billion pounds, actual cubic feet, or BTU. To edit the
Totalizer Maximum value, select the Set Totalizer Maximum button under the Totalizer Control heading.
3. To reset the Totalized Reading to zero, select the Reset Totalizer button under the Totalizer Control
heading.
4. Under the Custom Units Setup heading, the user may configure a custom unit for the Totalized Reading.
Custom units allow the totalizer rate to be displayed in units of measure that are not standard in the
Rosemount 3051SMV.
Note
If the totalizer rate is configured as the primary variable and is being output via the 4–20 mA signal, verify
the 4–20 mA range (LRV and URV) after completing the custom unit configuration. For more
information on verifying the 4–20 mA range, see “Basic device configuration” on page 24.

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Follow these steps to configure a custom unit:
a. Custom Unit: Enter the desired custom unit label to be displayed for the Totalized Reading. Up to
five characters including letters, numbers, and symbols can be entered in the custom unit field.
Note
It is recommended that the Custom Unit be entered in upper case letters. If lower case letters are
entered, the LCD display will show upper case letters. Additionally, the following special characters are
recognized by the LCD display: hyphens (“-”), percent symbols (“%”), asterisks (“*”), forward slashes (“/”)
and spaces. Any other character entered for the Custom Unit will be displayed as an asterisk (“*”) on the
LCD display. The following warning will be returned indicating these changes: “Custom Unit contains
characters that will display in upper case or asterisks on LCD display. The DCS will display as entered.”
b. Base Unit: From the drop-down menu, select a base unit to be used for the custom unit
relationship.
c. Base per Custom: Enter a numeric value that represents the number of base units per one
custom unit. The Rosemount 3051SMV uses the following convention:
Number of Base Units
Base per Custom = ---------------------------------------------------------------------1xCustomxUnit

Example
Custom Unit: kg
Base Unit: g
Because:
1 kg (Kilogram) = 1000 g (Grams)
Number of Base Units
1000 ⋅ g
Base per Custom = ---------------------------------------------------------------------- = --------------------- = 1000
1xCustomxUnit
1 ⋅ kg
The values of Base per Custom for common totalizer units are shown in Table 2-11.
d. Select Apply.
e. Totalizer Unit: From the drop-down menu, select the custom unit that was created in Step b.
Note
The custom unit may not be available as a selection in the Totalizer Unit drop-down menu until the
drop-down menu is refreshed. To refresh the drop-down menu, navigate to the Basic Setup tab and then
return to the Variables - Totalizer tab.
Table 2-11. Common Custom Units - Totalizer

50

Custom unit

Base unit

Base per custom

Millions of Normal Cubic Meters (MMNCM)

NmlCum

1000000

Millions of Standard Cubic Feet (MMSCF)

StdCuft

1000000

Millions of Standard Cubic Meters (MMSCM)

StdCum

1000000

Thousands of Metric Tons (KMTON)

MetTon

1000

Thousands of Normal Cubic Meters (KNCM)

NmlCum

1000

Thousands of Short Tons (KSTON)

STon

1000

Thousands of Standard Cubic Feet (KSCF)

StdCuft

1000

Thousands of Standard Cubic Meters (KSCM)

StdCum

1000

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Configuration
September 2017

If conversion factor tables or internet search engines are used to determine the Base per Custom value, it
is important to enter the Custom Unit in the “From” field and the Base Unit in the “To” Field.
To calculate the Base per Custom value for a custom unit not shown in Table 2-9 on page 39, see the
example:

Totalizer conversion example
To find the Base per Custom relationship for a custom unit of millions of standard cubic feet (mmscf) and
a base unit of standard cubic feet (StdCuft), input the following:
Custom Unit = mmscf
Base Unit = StdCuft
Because:
1 mmscf (Millions of Standard Cubic Feet) = 1000000 StdCuft (Standard Cubic Feet)
Therefore:
Number of Base Units
1000000 ⋅ StdCuft
Base per Custom = ---------------------------------------------------------------------- = ------------------------------------------------- = 1000000
1xCustomxUnit
1 ⋅ mmscf
Figure 2-35. Totalizer Custom Units - Totalizer Example

Configuration

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2.7.4

Differential pressure
Mass and energy flow Fast Keys

1, 4, 1, 4

Direct process variable output Fast Keys

1, 4, 1, 1

Note
For Differential pressure sensor calibration, see page 90.

Figure 2-36. Variables - Differential Pressure Tab

52



Under the Differential Pressure Setup heading, edit the DP Units and Damping value as needed.



The Sensor Limits and Minimum Span can be viewed under the Differential Pressure Sensor Limits
heading.

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2.7.5

September 2017

Static pressure
Mass and energy flow Fast Keys

1, 4, 1, 5

Direct process variable output Fast Keys

1, 4, 1, 2

Note
For Static pressure sensor calibration, see page 92.
Figure 2-37. Variables - Static Pressure Tab



Under the Static Pressure Setup heading, edit the Absolute Pressure Units and Gage Pressure Units as
needed. The static pressure Damping may also be edited.

Note
The transmitter may be equipped with either an absolute or gage static pressure sensor type depending
on specified model code. The type of static pressure sensor equipped in the transmitter can be
determined by referring to the Static Pressure Sensor Type heading. The static pressure type not being
measured is a calculated value using the atmospheric pressure value as specified under the User-Defined
Atmospheric Pressure heading.


Configuration

The Sensor Limits and Minimum Span for the absolute and gage static pressure can be viewed under the
Sensor Limit headings.

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2.7.6

Process temperature
Mass and energy flow Fast Keys

1, 4, 1, 6

Direct process variable output Fast Keys

1, 4, 1, 3

Note
For Process temperature sensor calibration, see page 93.
If a transmitter was ordered with Fixed Process Temperature Only, the Fixed Temperature Value and
Units can be edited on the Fixed Temperature tab.
Figure 2-38. Variables - Process Temperature Tab



Under the Process Temperature Setup heading, edit the Units and Damping value as needed.



Select the Temperature Mode under the Process Temperature Setup heading. See Table 2-12.

Table 2-12. Temperature Modes
Temperature mode

Description

Normal

The transmitter will only use the actual measured Process Temperature value. If the
temperature sensor fails, the transmitter will put the analog signal into Alarm.

Backup

The transmitter will use the actual measured Process Temperature value. If the
temperature sensor fails, the transmitter will use the value shown in the Fixed/Backup
Temperature field.

Fixed

The transmitter will always use the temperature value shown in the Fixed/Backup
Temperature field.

Note
Process Temperature Mode Setup only applies to transmitters with fully compensated mass and energy
flow feature board.

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

September 2017

The Sensor Limits and Minimum Span can be viewed under the Process Temperature Sensor Limits
heading. The upper and lower sensor limits may be edited as needed.

The Rosemount 3051SMV accepts Callendar-Van Dusen constants from a calibrated RTD schedule and
generates a special custom curve to match that specific sensor Resistance vs. Temperature performance.
Matching the specific sensor curve with the transmitter configuration enhances the temperature
measurement accuracy.


Under the Sensor Matching heading, the Callendar-Van Dusen constants R0, A, B, and C can be viewed.
If the Callendar-Van Dusen constants are known for the user’s specific Pt 100 RTD sensor, the constants
R0, A, B, and C may be edited by selecting the Callendar-Van Dusen Setup button and following the
on-screen prompts.
The user may also view the α, β, and δ coefficients by selecting the View Alpha, Beta, Delta button.
The constants R0, α, β, and δ may be edited by selecting the Callendar-Van Dusen Setup button and
following the on-screen prompts. To reset the transmitter to the IEC 751 Defaults, select the Reset to
IEC 751 Defaults button.

2.7.7

Module temperature
Mass and energy flow Fast Keys

1, 4, 1, 7

Direct process variable output Fast Keys

1, 4, 1, 4

The sensor module temperature variable is the measured temperature of the sensors and electronics
within the SuperModule assembly. The module temperature can be used to control heat tracing or
diagnose device overheating.
Figure 2-39. Variables - Module Temperature Tab

Configuration



Under the Module Temperature Setup heading, edit the Units as needed.



The Sensor Limits can be viewed under the Module Temperature Sensor Limits heading.

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2.7.8

Analog output
Mass and energy flow Fast Keys

1, 4, 3, 2

Direct process variable output Fast Keys

1, 4, 3, 2

Note
For Analog calibration, see page 95.

Figure 2-40. Variables - Analog Output Tab

1. Select the Primary Variable under the Analog Output Setup heading. The Upper Range Value and Lower
Range Value may also be edited under this heading.
2. Verify the Upper Sensor Limit and Lower Sensor Limit and minimum span under the Primary Variable
Sensor Limits heading.

Transfer function (direct process variable output feature board only)
The Rosemount 3051SMV with direct process variable output feature board has two analog output
settings: Linear and Square Root. Activate the square root output option to make analog output
proportional to flow. As input approaches zero, the Rosemount 3051SMV automatically switches to
linear output in order to ensure a smooth, stable output near zero (see Figure 2-41 on page 57).
From 0 to 0.6 percent of the ranged pressure input, the slope of the curve is unity (y = x). This allows
accurate calibration near zero. Greater slopes would cause large changes in output (for small changes at
input). From 0.6 to 0.8 percent, curve slope equals 41.72 (y = 41.72x) to achieve continuous transition
from linear to square root at the transition point.
Note
Do not set both the analog output of the device and the control system to square root.

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Figure 2-41. Square Root Output Transition Point
20

16

12

7.2
5.4
4

Full scale
flow (%)

100
90
80
70
60

Sq. root curve

50
40
30
20

Transition point
Linear section

10
0

Full scale output (mA dc)

0
5.6

10

Sq. root curve

5.424

8.9

Transition point

4.8

5

20

40

60

80

100

Slope = 41.72

4.096
4

0.6
0

Slope = 1
0

0.6 0.8 1
% Pressure input

Figure 2-41 only applies to the square root output for the Rosemount 3051SMV with the direct process
variable output feature board.
Note
For a flow turndown of greater than 10:1, it is not recommended to perform a square root transfer
function in the transmitter. Instead, perform the square root transfer function in the control system.

2.8

Menu trees and Field Communicator Fast Keys
Based on the configuration ordered, some measurements (i.e. static pressure, process temperature)
and/or calculation types (i.e. mass, volumetric, and energy flow) may not be available for all fluid types.
Available measurements and/or calculation types are determined by the multivariable type and
measurement type codes ordered. See “Ordering information” on page 138 for more information.
The menu trees and Field Communicator Fast Keys in this section are shown for the following model
codes:


Multivariable type M (fully compensated mass and energy flow) with measurement type 1 (differential
pressure, static pressure, and process temperature)



Multivariable type P (direct process variable output) with measurement type 1 (differential pressure,
static pressure, and process temperature)

The menu trees and 475 Field Communicator Fast Keys for other model codes will vary.
Configuration

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Figure 2-42. Menu Tree for Fully Compensated Mass and Energy Flow
1. Device Setup 2. PV 3. AO 4. PV LRV 5. PV URV
1. Process Variables...........................2. Diagnostics and Service............................... 3. Basic Setup....................4. Detailed Setup...........
1. Flow Rate
2. Energy Rate
3. Totalizer
4. Diff. Pressure
5. Absolute Pressure
6. Gage Pressure
7. Process Temp.
8. Module Temp.
9. Analog Output
10.Percent of Range
11.Primary Variable is
1. Reading
2. Status

1.
2.
3.
4.

Status
Loop Test
Test Flow Calc
Configure Fixed
Variables
5. Calibration

1. Rerange

2. Analog
Output
Trim

3. Diff.
Pressure
Trim

1. Upper Range Value
2. Lower Range Value
1. Digital-to-Analog
Trim
2. Scaled
Digital-to-Analog
Trim
3. Recall Factory Trim
Zero Trim
Lower Sensor Trim
Upper Sensor Trim
Sensor Trim
Calibration Type
5. Sensor Trim Points
6. Recall Factory Trim

1. Tag
2. Long Tag
3. Units

5.
6.
7.
8.

4. Range
Value

5. Device
Info

1.
2.
3.
4.

4. Static
Pressure
Trim

1.
2.
3.
4.

Zero Trim
Lower Sensor Trim
Upper Sensor Trim
Sensor Trim
Calibration Type
5. Sensor Trim Points
6. Recall Factory Trim

5. Process
Temp.
Trim

1.
2.
3.
4.

Lower Sensor Trim
Upper Sensor Trim
Sensor Trim Points
Callendar Van
Dusen
5. Recall Factory Trim

1.
2.
3.
4.

6. Transfer
Function
7. Damping

5. Review

Flow Rate
Energy Rate
Totalizer
Differential
Pressure
Absolute Pressure
Gage Pressure
Process Temp.
Module Temp.

1. Upper Range
Value
2. Lower Range Value
1.
2.
3.
4.
5.
6.
7.
8.
9.

Date
Descriptor
Message
Write Protect
Model
Model Number I
Model Number II
Model Number III
Model Number IV

1. Flow Rate
2. Energy Rate
3. Differential
Pressure
4. Static Pressure
5. Process

8. LCD
Display
Config.

1. Configure
Coefficients
2. Reset Coefficients
3. Process Temp.
1. Diff. Pressure
2. Static Pressure
3. Process Temp.

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1. Device Setup 2. PV 3. AO 4. PV LRV 5. PV
1. Process Variables. 22. Diagnostics and Service

3. Basic Setup..........4. Detailed Setup....>>.......................5. Review

1. Sensors.................................. _2. Signal Condition............................3. Output Condition............................4. Device Info...........................
1.
2.
3.
4.

Flow Rate
Energy Rate
Totalizer
Differential
Pressure
5. Static Pressure
6. Process Temp.
7. Module Temp.
1. Reading
2. Unit
1.
2.
3.
4.
5.

Reading
Unit
Damping
Sensor Service
Lower Sensor
Limit
6. Upper Sensor
Limit
7. Min Span
8. Process Temp

1.
2.
3.
4.
5.
6.

Process Variables
Range Values
Units
Transfer Function
Damping
Alarm/Saturation
Levels

1.
2.
3.
4.
5.
6.

Alarm Direction
High Alarm
Low Alarm
High Saturation
Low Saturation
Config Alarm &
Saturation Levels

1. Flow Rate
2. Energy Rate
3. Differential
Pressure
4. Static Pressure

1.
2.
3.
4.

Flow Rate
Energy Rate
Totalizer
Differential
Pressure
Absolute Pressure
Gage Pressure
Process Temp.
Module Temp.

1. Absolute
Reading
2. Absolute Unit
3. Gage Reading
4. Gage Unit
5. Damping
6. Atmospheric
Pressure
7. Sensor Service
8. Absolute Sensor
Limit

1. Upper Range Value
2. Lower Range Value

1.
2.
3.
4.
5.

1.
2.
3.
4.

Reading
Unit
Damping
Sensor Service
Upper Sensor
Limit
6. Lower Sensor
Limit
1. Reading
2. Totalized
Parameter
3. Unit
4. Mode
5. Max Value
6. Configure
Totalizer
7. Set Max Value
8. Reset Totalizer
9. Custom Unit
1. Reading
2. Unit
3. Damping
4. Custom Unit
5. Upper Sensor Limit
6. Lower Sensor Limit
7. Min. Span

5.
6.
7.
8.

Flow Rate
Energy Rate
Totalizer
Differential
Pressure
5. Absolute Pressure
6. Gage Pressure
7. Process Temp.
8. Module Temp.
9. Analog Output
10.Percent of Range
11.Primary Variable is
1. Reading
2. Status

1.
2.
3.
4.

Process Variables
Analog Output
HART Output
Variable
Remapping

1.
2.
3.
4.

Primary Variable
2nd Variable
3rd Variable
4th Variable

1.
2.
3.
4.
5.

Poll Address
Loop Current Mode
Burst Mode
Burst Option
Burst Slot
Definition

1.
2.
3.
4.

Slot 0
Slot 1
Slot 2
Slot 3

1. Loop Test
2. Digital-to-Analog
Trim
3. Scaled
Digital-to-Analog
Trim
4. Alarm Direction
1.
2.
3.
4.

Flow Rate
Energy Rate
Totalizer
Differential
Pressure
5. Absolute Pressure
6. Gage Pressure
7. Process Temp.
8. Module Temp.
9. Analog Output
10.Percent of Range
11.Primary Variable is
1. Reading
2. Status

1.
2.
3.
4.
5.

Field Device Info
Sensor Info
Flow Config
Equipped Sensors
Diaphragm Seals
Info

1. # of Diaphragm
Seals
2. Seal Type
3. Seal Fill Fluid
4. Remote Seal
Isolator Material
1.
2.
3.
4.

DP Sensor
AP Sensor
GP Sensor
PT Sensor

1. Fluid
2. Primary Element
3. Pipe Diameter
1.
2.
3.
4.
5.
6.

Sensor Module Type
Module Config Type
Isolator Material
Fill Fluid
Process Connector
Process Connector
Material
7. O-Ring Material
8. Drain Vent Material

1. Tag
2. Long Tag
3. Date
4. Descriptor
5. Write Protect
6. Message
7. Model
8. Model Number I
9. Model Number II
10.Model Number III
11.Model Number IV
12.Revision #s
13.Transmitter S/N
14.Sensor Module S/N
15.Feature board S/N
1.
2.
3.
4.

Universal Rev
Field Device Rev
Software Rev
Hardware Rev

1. Reading
2. Calculation Type
3. Config. Flow Calc
4. Unit
5. Damping
6. Low Flow Cutoff
7. Custom Unit
8. Upper Sensor Limit
9. Lower Sensor Limit
10.Min. Span

Configuration

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Figure 2-43. Menu Tree for Direct Process Variable Output
1. Device Setup

2. PV 3. AO 4. PV LRV 5. PV

1. Process Variables...........................2. Diagnostics and Service............................. 3. Basic Setup......................4. Detailed Setup..........5. Review
1.
2.
3.
4.
5.
6.
7.
8.

Diff. Pressure
Absolute Pressure
Gage Pressure
Process Temp.
Module Temp.
Analog Output
Percent of Range
Primary Variable is

1. Reading
2. Status

1. Status
2. Loop Test
3. Configure Fixed
Variables
4. Calibration

1. Rerange

2. Analog
Output
Trim

3. Diff.
Pressure
Trim

4. Static
Pressure
Trim

5. Process
Temp.
Trim

1. Upper Range Value
2. Lower Range Value
1. Digital-to-Analog
Trim
2. Scaled
Digital-to-Analog
Trim
Zero Trim
Lower Sensor Trim
Upper Sensor Trim
Sensor Trim
Calibration Type
5. Sensor Trim Points
6. Recall Factory Trim

1. Tag
2. Long Tag
3. Units

4. Range
Value

5. Device
Info

1.
2.
3.
4.

1.
2.
3.
4.

Zero Trim
Lower Sensor Trim
Upper Sensor Trim
Sensor Trim
Calibration Type
5. Sensor Trim Points
6. Recall Factory Trim
1.
2.
3.
4.

Lower Sensor Trim
Upper Sensor Trim
Sensor Trim Points
Callendar Van
Dusen

6. Transfer
Function
7. Damping

1. Differential
Pressure
2. Absolute Pressure
3. Gage Pressure
4. Process Temp.
5. Module Temp.

1. Upper Range
Value
2. Lower Range Value
1.
2.
3.
4.
5.
6.
7.
8.
9.

Date
Descriptor
Message
Write Protect
Model
Model Number I
Model Number II
Model Number III
Model Number IV

1. Differential
Pressure
2. Static Pressure
3. Process
Temperature

8. LCD
Display
Config.

1. Configure
Coefficients
2. Reset Coefficients
1. Diff. Pressure
2. Static Pressure
3. Process Temp.

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Configuration

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September 2017

1. Device Setup
1. Process Variables.22. Diagnostics and Service.

2. PV 3. AO 4. PV LRV 5. PV URV

3. Basic Setup..........4. Detailed Setup....>>.......................5. Review

1. Sensors.....................................2. Signal Condition...........................3. Output Condition................................4. Device Info...........................
1. Differential
Pressure
2. Static Pressure
3. Process Temp.
4. Module Temp.

1. Reading
2. Unit
1.
2.
3.
4.
5.

Reading
Unit
Damping
Sensor Service
Lower Sensor
Limit
6. Upper Sensor
Limit
7. Min Span
1. Absolute
Reading
2. Absolute Unit
3. Gage Reading
4. Gage Unit
5. Damping
6. Atmospheric
Pressure
7. Sensor Service
8. Absolute Sensor
Limits
1.
2.
3.
4.
5.

Reading
Unit
Damping
Sensor Service
Upper Sensor
Limit
6. Lower Sensor
Limit

1.
2.
3.
4.
5.
6.

Process Variables
Range Values
Units
Transfer Function
Damping
Alarm/Saturation
Levels

1.
2.
3.
4.
5.
6.

Alarm Direction
High Alarm
Low Alarm
High Saturation
Low Saturation
Config Alarm &
Saturation Levels

1. Differential
Pressure
2. Static Pressure
3. Process Temp.
1. Differential
Pressure
2. Absolute Pressure
3. Gage Pressure
4. Process Temp.
5. Module Temp.
1. Upper Range Value
2. Lower Range Value
1. Differential
Pressure
2. Absolute
Pressure
3. Gage Pressure
4. Process Temp.
5. Module Temp.
6. Analog Output
7. Percent of Range
8. Primary Variable
1. Reading
2. Status

1.
2.
3.
4.

Process Variables
Analog Output
HART Output
Variable
Remapping

1.
2.
3.
4.

Primary Variable
2nd Variable
3rd Variable
4th Variable

1.
2.
3.
4.
5.

Poll Address
Loop Current Mode
Burst Mode
Burst Option
Burst Slot
Definition

1.
2.
3.
4.

Slot 0
Slot 1
Slot 2
Slot 3

1. Loop Test
2. Digital-to-Analog
Trim
3. Scaled
Digital-to-Analog
Trim
4. Alarm Direction
1. Differential
Pressure
2. Absolute
Pressure
3. Gage Pressure
4. Process Temp.
5. Module Temp.
6. Analog Output
7. Percent of Range
8. Primary Variable
is
1. Reading
2. Status

1.
2.
3.
4.

1. # of Diaphragm
Seals
2. Seal Type
3. Seal Fill Fluid
4. Remote Seal
Isolator Material
1.
2.
3.
4.

DP Sensor
AP Sensor
GP Sensor
PT Sensor

1.
2.
3.
4.
5.
6.

Sensor Module Type
Module Config Type
Isolator Material
Fill Fluid
Process Connector
Process Connector
Material
7. O-ring Material
8. Drain Vent Material

1. Tag
2. Long Tag
3. Date
4. Descriptor
5. Write Protect
6. Message
7. Model
8. Model Number I
9. Model Number II
10.Model Number III
11.Model Number IV
12.Revision #s
13.Transmitter S/N
14.Sensor Module S/N
15.Feature board S/N
1.
2.
3.
4.

Configuration

Field Device Info
Sensor Info
Equipped Sensors
Diaphragm Seals
Info

Universal Rev
Field Device Rev
Software Rev
Hardware Rev

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2.8.1

Field Communicator Fast Keys
Use Rosemount 3051SMV Engineering Assistant or any HART-compliant master to communicate with
and verify configuration of the Rosemount 3051SMV.
Table 2-13 shows the Field Communicator Fast Keys for the fully compensated mass and energy flow.
Table 2-14 on page 63 shows the Fast Keys for the direct process variable output.
A check (⻫) indicates the basic configuration parameters. At a minimum, these parameters should be
verified as part of the configuration and startup procedure.
Table 2-13. Fast Keys for Fully Compensated Mass and Energy Flow Output
Function
Absolute Pressure Reading and Status

1, 4, 2, 1, 5

Absolute Pressure Sensor Limits

1, 4, 1, 5, 8

Absolute Pressure Units
Alarm and Saturation Level Configuration

⻫

Analog Output Trim Options

1, 2, 5, 2

Burst Mode Setup

1, 4, 3, 3, 3

Burst Mode Options

1, 4, 3, 3, 4

Callendar-van Dusen Sensor Matching

1, 2, 5, 5, 4

Configure Fixed Variables

1, 2, 4

Damping

1, 3, 7
1, 4, 4, 5

Differential Pressure Low Flow Cutoff

1, 4, 1, 1, 6

Differential Pressure Reading and Status

1, 4, 2, 1, 4

Differential Pressure Sensor Trim Options

1, 2, 5, 3

Differential Pressure Zero Trim

1, 2, 5, 3, 1

Differential Pressure Units

1, 3, 3, 4

Energy Rate Units

1, 3, 3, 2
1, 4, 2, 1, 2

Equipped Sensors

1, 4, 4, 4

Field Device Information

1, 4, 4, 1

Flow Calculation Type
Flow Rate Units

1, 4, 1, 1, 2
1, 3, 3, 1

Flow Reading and Status

1, 4, 2, 1, 1

Gage Pressure Reading and Status

1, 4, 2, 1, 6

Gage Pressure Sensor Limits

1, 4, 1, 5, 9

Gage Pressure Units

62

1, 4, 2, 6, 6
1, 4, 2, 6

Energy Reading and Status

⻫

1, 3, 3, 5

Alarm and Saturation Levels

Diaphragm Seals Information
⻫

Fast Key sequence

1, 3, 3, 6

LCD Display Configuration

1, 3, 8

Loop Test

1, 2, 2
Configuration

Reference Manual

Configuration

00809-0100-4803, Rev GA

September 2017

Table 2-13. Fast Keys for Fully Compensated Mass and Energy Flow Output
Function
Module Temperature Reading and Status
Module Temperature Units

⻫

⻫

1, 4, 2, 1, 8
1, 3, 3, 8

Poll Address

1, 4, 3, 3, 1

Process Temperature Reading and Status

1, 4, 2, 1, 7

Process Temperature Sensor Mode

1, 4, 1, 6, 8

Process Temperature Sensor Trim Options

1, 2, 5, 5

Process Temperature Unit

1, 3, 3, 7

Ranging the Analog Output

1, 2, 5, 1

Recall Factory Trim Settings

1, 2, 5, 2, 3

Sensor Information
⻫

Fast Key sequence

Static Pressure Sensor Lower Trim (AP Sensor)
Static Pressure Sensor Trim Options

1, 4, 4, 2
1, 2, 5, 4, 2
1, 2, 5, 4

⻫

Static Pressure Sensor Zero Trim (GP Sensor)

⻫

Status

1, 2, 1

⻫

Tag

1, 3, 1

Test Flow Calculation

1, 2, 3

Totalizer Configuration
Totalizer Reading and Status

1, 2, 5, 4, 1

1, 4, 1, 3
1, 4, 2, 1, 3

Totalizer Units

1, 3, 3, 3

Variable Mapping

1, 4, 3, 4

Write Protect

1, 3, 5, 4

Table 2-14. Fast Keys for Direct Process Variable Measurement
Function

⻫

Absolute Pressure Reading and Status

1, 4, 2, 1, 2

Absolute Pressure Sensor Limits

1, 4, 1, 2, 8

Absolute Pressure Units
Alarm and Saturation Level Configuration

1, 3, 3, 2
1, 4, 2, 6, 6

Alarm and Saturation Levels

1, 4, 2, 6

Analog Output Trim Options

1, 2, 4, 2

Burst Mode Setup

1, 4, 3, 3, 3

Burst Mode Options

1, 4, 3, 3, 4

Callendar-van Dusen Sensor Matching

1, 2, 4, 5, 4

Damping
Diaphragm Seals Information
Configuration

Fast Key sequence

1, 3, 7
1, 4, 4, 4
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September 2017

Table 2-14. Fast Keys for Direct Process Variable Measurement
Function
Differential Pressure Reading and Status

1, 4, 2, 1, 1

Differential Pressure Sensor Trim Options

1, 2, 4, 3

⻫

Differential Pressure Zero Trim

⻫

Differential Pressure Units

1, 3, 3, 1

Equipped Sensors

1, 4, 4, 3

Field Device Information

1, 4, 4, 1

⻫

1, 2, 4, 3, 1

Gage Pressure Reading and Status

1, 4, 2, 1, 3

Gage Pressure Sensor Limits

1, 4, 1, 2, 9

Gage Pressure Units

1, 3, 3, 3

LCD Display Configuration

1, 3, 8

Loop Test

1, 2, 2

Module Temperature Reading and Status
Module Temperature Units

1, 4, 2, 1, 5
1, 3, 3, 5

Poll Address

1, 4, 3, 3, 1

Process Temperature Reading and Status

1, 4, 2, 1, 4

Process Temperature Sensor Trim Options

1, 2, 4, 5

⻫

Process Temperature Unit

1, 3, 3, 4

⻫

Ranging the Analog Output

1, 2, 4, 1

Recall Factory Trim Settings

1, 2, 4, 2, 3

Sensor Information
⻫

Static Pressure Sensor Lower Trim (AP Sensor)
Static Pressure Sensor Trim Options

64

Fast Key sequence

1, 4, 4, 2
1, 2, 4, 4, 2
1, 2, 4, 4

⻫

Static Pressure Sensor Zero Trim (GP Sensor)

⻫

Status

1, 2, 1

⻫

Tag

1, 3, 1

⻫

Transfer Function

1, 3, 6

Variable Mapping

1, 4, 3, 4

Write Protect

1, 3, 5, 4

1, 2, 4, 4, 1

Configuration

Reference Manual

Installation

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Section 3

September 2017

Installation

Overview . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . page 65
Safety messages . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . page 65
Installation considerations . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . page 67
Installation procedures . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . page 67
Rosemount 305 and 304 Manifolds . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . page 80

3.1

Overview
This section contains information that covers installation considerations for Rosemount™ 3051S
MultiVariable™ Transmitter (Rosemount 3051SMV). The Rosemount 3051SMV Quick Start Guide is
shipped with every transmitter to describe basic installation, wiring, configuration, and startup
procedures. Dimensional drawings for each Rosemount 3051SMV type and mounting configuration are
included in “Specifications and Reference Data” on page 125.

3.2

Safety messages
Procedures and instructions in this section may require special precautions to ensure the safety of the
personnel performing the operation. Information that raises potential safety issues is indicated with a
warning symbol ( ). Refer to the following safety messages before performing an operation preceded
by this symbol.

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Failure to follow these installation guidelines could result in death or serious injury.


Make sure only qualified personnel perform the installation.

Explosions could result in death or serious injury.


Do not remove the transmitter cover in explosive atmospheres when the circuit is live.



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 flameproof/explosion-proof requirements.



Verify the operating atmosphere of the transmitter is consistent with the appropriate hazardous
locations certifications.

Electrical shock could cause death or serious injury.


If the sensor is installed in a high-voltage environment and a fault or installation error occurs, high
voltage may be present on the transmitter leads and terminals.



Use extreme caution when making contact with the leads and terminals.

Process leaks could result in death or serious injury.


Install and tighten all four flange bolts before applying pressure.



Do not attempt to loosen or remove flange bolts while the transmitter is in service.



Replacement equipment or spare parts not approved by Emerson™ for use as spare parts could
reduce the pressure retaining capabilities of the transmitter and may render the instrument
dangerous.



Use only bolts supplied or sold by Emerson as spare parts.

Improper assembly of manifolds to traditional flange can damage the device.


For safe assembly of manifold to traditional flange, bolts must break back plane of flange web
(i.e., bolt hole) but must not contact the sensor module.

Improper installation or repair of the SuperModule™ assembly with high pressure option (P0)
could result in death or serious injury.


For safe assembly, the high pressure SuperModule assembly must be installed with ASTM A193
Class 2 Grade B8M bolts and either a Rosemount 305 Manifold or a DIN-compliant traditional flange.

Static electricity can damage sensitive components.
Observe safe handling precautions for static-sensitive components.

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3.3

Installation considerations

3.3.1

General

Installation
September 2017

Measurement performance depends upon proper installation of the transmitter, impulse piping, and
process temperature sensor. Mount the transmitter close to the process and use minimum piping to
achieve best performance. Also, consider the need for easy access, personnel safety, practical field
calibration, and a suitable transmitter environment. Install the transmitter to minimize vibration, shock,
and temperature fluctuation.
Note
Install the enclosed pipe plug (found in the box) in the unused conduit opening if optional process
temperature input is not used. For proper straight and tapered thread engagement requirements, see
the appropriate approvals drawings in Appendix B: Product Certifications.
For material compatibility considerations, see Material Selection Technical Note.

3.3.2

Mechanical
For steam service or for applications with process temperatures greater than the limits of the
transmitter, do not blow down impulse piping through the transmitter. Flush lines with the blocking
valves closed and refill lines with water before resuming measurement.
When the transmitter is mounted on its side, position the coplanar flange to ensure proper venting or
draining. Mount the flange as shown in Figure 3-5 on page 72, keeping drain/vent connections on the
bottom for gas service and on the top for liquid service.

3.3.3

Environmental
Access requirements and “Cover installation” on page 69 can help optimize transmitter performance.
Mount the transmitter to minimize ambient temperature changes, vibration, mechanical shock, and to
avoid external contact with corrosive materials. “Specifications and Reference Data” on page 125 lists
temperature operating limits.

3.4

Installation procedures

3.4.1

Configure security (write protect)
Changes to the transmitter configuration data can be prevented with the security (write protect) switch
located on the feature board. See Figure 3-1 on page 68 for the location of the switch. Position the
switch in the ON position to prevent accidental or deliberate change of configuration data.
If the transmitter write protection switch is in the ON position, the transmitter will not accept any
“writes” to its memory. Configuration changes, such as digital trim and reranging, cannot take place
when the transmitter security is on.
To reposition the switches, follow the procedure described below:
1. Do not remove the transmitter covers in explosive atmospheres when the circuit is live. If the
transmitter is live, set the loop to manual and remove power.
2. Remove the housing cover opposite the field terminal side of the housing.
3. To reposition the switches as desired, slide the security and alarm switches into the preferred position
using a small screwdriver. See Figure 3-1 on page 68.

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September 2017

Figure 3-1. Switch Configuration

A
B

C

A. Feature board
B. Security
C. Alarm

4. Re-install the transmitter cover. Transmitter covers must be fully engaged so that metal contacts
metal in order to meet flameproof/explosion-proof requirements.

3.4.2

Configure alarm direction
The transmitter alarm direction is set by repositioning the alarm switch. Position the switch in the HI
position for fail high and in the LO position for fail low. See “Alarm and saturation” on page 27 for more
information on alarm and saturation levels.

3.4.2

Mounting considerations
For dimensional drawing information refer to “Specifications and Reference Data” on page 125.

Housing rotation
The housing can be rotated to improve field access to wiring or to better view the optional LCD display.
To rotate the housing, perform the following procedure:
1. Loosen the housing rotation set screw.
2. Turn the housing up to 180° to the left or right of its original (as shipped) position.
Note
Do not rotate the housing more than 180° without first performing a disassembly procedure (see
“Housing assembly including feature board electronics” on page 100). Over-rotation may sever the
electrical connection between the sensor module and the feature board.
3. Retighten the housing rotation set screw.
Figure 3-2. Housing
A

B
A. Feature board
B. 3/32-in. housing rotation set screw

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Installation
September 2017

LCD display rotation
In addition to housing rotation, the optional LCD display can be rotated in 90° increments by squeezing
the two tabs, pulling out, rotating and snapping back into place.
Note
If LCD display pins are inadvertently removed from the feature board, re-insert the pins before snapping
the LCD display back into place.

Field terminal side of housing
Mount the transmitter so the terminal side is accessible. Clearance of 0.75-in. (19 mm) is required for
cover removal. Use a conduit plug in the unused conduit opening if the optional Process Temperature
Input is not installed.

Feature board side of housing
Provide 0.75-in. (19 mm) of clearance for units without an LCD display. Three inches of clearance is
required for cover removal if an LCD display is installed.

Cover installation
Always ensure a proper seal by installing the housing covers so that metal contacts metal in order to
prevent performance degradation due to environmental effects. For replacement cover O-rings, use
Rosemount O-rings (part number 03151-9040-0001).

Conduit entry threads
For NEMA® 4X, IP66, and IP68 requirements, use thread seal (PTFE) tape or paste on male threads to
provide a watertight seal.

Cover jam screw
For transmitter housings shipped with a cover jam screw, as shown in Figure 3-3 on page 70, the screw
should be properly installed once the transmitter has been wired and powered up. The cover jam screw is
intended to prevent the removal of the transmitter cover in flameproof environments without the use of
tools. Follow these steps to install the cover jam screw:
1. Verify the cover jam screw is completely threaded into the housing.
2. Install the transmitter housing covers and verify that metal contacts metal in order to meet
flameproof/explosion-proof requirements.
3. Using an M4 hex wrench, turn the jam screw counterclockwise until it contacts the transmitter cover.
4. Turn the jam screw an additional 1/2 turn counterclockwise to secure the cover. Application of
excessive torque may strip the threads.
5. Verify the covers cannot be removed.

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September 2017

Figure 3-3. Cover Jam Screw

A
A. Cover jam screw (one per side)

Process flange orientation
Mount the process flanges with sufficient clearance for process connections. For safety reasons, place
the drain/vent valves so the process fluid is directed away from possible human contact when the vents
are used. In addition, consider the need for a testing or calibration input.

3.4.3

Mount the transmitter
Figure 3-4 illustrates a typical Rosemount 3051SMV installation site measuring dry gas with an orifice
plate.
Figure 3-4. Typical Rosemount 3051SMV Installation Site
A

B

C

D

Flow
A. Rosemount 3051SMV
B. RTD cable
C. Pt 100 RTD sensor
D. Process connections

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September 2017

Mounting brackets
The Rosemount 3051SMV can be mounted to a 2-in. pipe or to a panel using an optional mounting
bracket. The B4 Bracket (SST [Stainless steel]) option is for use with the coplanar flange process
connection. “Coplanar Flange Mounting Configurations” on page 135 shows bracket dimensions and
mounting configurations for the B4 option. Other bracket options are listed in Table 3-1. When installing
the transmitter to one of the optional mounting brackets, torque the bolts to 125 in-lb (0,9 N-m).
Table 3-1. Mounting Brackets
Options

Description

Mounting type

Bracket material

Bolt material

B4

Coplanar flange bracket

2-in. pipe/panel

SST

SST

B1

Traditional flange bracket

2-in. pipe

Painted CS (Carbon steel)

CS

B2

Traditional flange bracket

Panel

Painted CS

CS

B3

Traditional flange flat bracket

2-in. pipe

Painted CS

CS

B7

Traditional flange bracket

2-in. pipe

Painted CS

SST

B8

Traditional flange bracket

Panel

Painted CS

SST

B9

Traditional flange flat bracket

2-in. pipe

Painted CS

SST

BA

Traditional flange bracket

2-in. pipe

SST

SST

BC

Traditional flange flat bracket

2-in. pipe

SST

SST

Flange bolts
The Rosemount 3051SMV can be shipped with a coplanar flange or a traditional flange installed with four
1.75-in. flange bolts. Mounting bolts and bolting configurations for the coplanar and traditional flanges
can be found in Figure 3-5 on page 72. SST bolts supplied by Emerson are coated with a lubricant to ease
installation. CS bolts do not require lubrication. No additional lubricant should be applied when installing
either type of bolt. Bolts supplied by Emerson are identified by their head markings:
Carbon Steel (CS)
Head Markings

B7M

316

KM

B8M

660
CL A

F593_(1)

Stainless Steel (SST)
Head Markings
Alloy K-500 Head
Marking

1.The last digit in the F593_ head marking may be any letter between A and M.

Bolt installation
Only use bolts supplied with the Rosemount 3051SMV or sold by Emerson as spare parts. Use the
following bolt installation procedure to:
1. Finger-tighten the bolts.
2. Torque the bolts to the initial torque value using a crossing pattern. For initial torque values, see Table
3-2 on page 72.
3. Torque the bolts to the final torque value using the same crossing pattern. For final torque values, see
Table 3-2 on page 72.

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September 2017

Torque values for the flange and manifold adapter bolts are as follows:
Table 3-2. Bolt Installation Torque Values
Bolt material

Option code

Initial torque value

Final torque value

CS-ASTM-A449

Standard

300 in-lb (34 N-m)

650 in-lb (73 N-m)

316 SST

Option L4

150 in-lb (17 N-m)

300 in-lb (34 N-m)

ASTM-A-193-B7M

Option L5

300 in-lb (34 N-m)

650 in-lb (73 N-m)

Alloy K-500

Option L6

300 in-lb (34 N-m)

650 in-lb (73 N-m)

ASTM-A-453-660

Option L7

150 in-lb (17 N-m)

300 in-lb (34 N-m)

ASTM-A-193-B8M

Option L8

150 in-lb (17 N-m)

300 in-lb (34 N-m)

Figure 3-5. Common Transmitter Assemblies
A

D

4 × 2.25-in. (57 mm)
C

4 × 1.75-in. (44 mm)
B

4 × 1.75-in.
(44 mm)

4 × 1.75-in. (44 mm)
4 × 1.50-in.
(38 mm)

4 × 2.88-in. (73 mm)
A. Transmitter with coplanar flange
B. Transmitter with coplanar flange and optional flange adapters
C. Transmitter with traditional flange and optional flange adapters
D. Transmitter with coplanar flange and optional manifold and flange adapters

Mounting requirements
Impulse piping configurations depend on specific measurement conditions. Refer to Figure 3-6 on
page 73 for examples of the following mounting configurations:

Liquid flow measurement


Place taps to the side of the line to prevent sediment deposits on the process isolators.



Mount the transmitter beside or below the taps so gases vent into the process line.



Mount drain/vent valve upward to allow gases to vent.

Gas flow measurement

72



Place taps in the top or side of the line.



Mount the transmitter beside or above the taps so to drain liquid into the process line.

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Steam flow measurement


Place taps to the side of the line.



Mount the transmitter below the taps to ensure that impulse piping will remain filled with condensate.



In steam service above 250 °F (121 °C), fill impulse lines with water to prevent steam from contacting
the transmitter directly and to ensure accurate measurement start-up.

Note
For steam or other elevated temperature services, it is important that temperatures at the transmitter
process connection do not exceed the transmitter’s operating limits.

Figure 3-6. Installation Examples
Liquid service

Gas service

Steam service

FLOW

3.4.4

Process connections
The Rosemount 3051SMV flange process connection size is 1/4–18 NPT. Flange adapters with a 1/4–18
NPT to 1/2–14 NPT connection are available with the D2 option. Use a plant-approved lubricant or sealant
when making the process connections. The process connections on the transmitter flange are on 21/8-in.
(54 mm) centers to allow direct mounting to a 3- or 5-valve manifold. Rotate one or both of the flange
adapters to attain connection centers of 2-in. (51 mm), 21/8-in. (54 mm), or 21/4-in. (57 mm).
Install and tighten all four flange bolts before applying pressure to avoid leakage. When properly
installed, the flange bolts will protrude through the top of the SuperModule isolator plate. See
Figure 3-7. Do not attempt to loosen or remove the flange bolts while the transmitter is in service.
Figure 3-7. SuperModule Isolator Plate
C

A
B

D

A. Bolt
B. SuperModule isolator plate
C. Coplanar flange
D. Flange adapters

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To install adapters to a coplanar flange, perform the following procedure:
1. Remove the flange bolts.
2. Leaving the flange in place, move the adapters into position with the O-rings installed.
3. Attach the adapters and the coplanar flange to the transmitter SuperModule assembly using the
longer of the bolts supplied.
4. Tighten the bolts. Refer to Table 3-2 on page 72 for torque specifications.
Refer to “Service support” on page 117 for the correct part numbers of the flange adapters and O-rings
designed for the Rosemount 3051SMV.
Note
The two styles of Rosemount flange adapters (Rosemount 3051S/3051/2051) each require a unique
O-ring . Use only the O-ring designed for the corresponding flange adaptor.

O-ring

Failure to install proper flange adapter O-rings may cause process leaks, which can result in death or
serious injury. The two flange adapters are distinguished by unique O-ring grooves. Only use the O-ring
designed for its specific flange adapter, as shown below:
Rosemount 3051S/3051/2051
A
B

C
D

A. Flange adapter
B. O-ring
C. PTFE-based profile (square)
D. Elastomer profile (round)
When removing flanges or adapters, visually inspect the PTFE O-rings. Replace them if there are any
signs of damage, such as nicks or cuts. If replacing the O-rings, re-torque the flange bolts after
installation to compensate for seating of the PTFE O-ring. Refer to “Flange and drain vent” on page 103.

Impulse piping considerations
The piping between the process and the transmitter must accurately transfer the pressure to obtain
accurate measurements. There are many possible sources of error: pressure transfer, leaks, friction loss
(particularly if purging is used), trapped gas in a liquid line, liquid in a gas line, density variations between
the legs, and plugged impulse piping.
The best location for the transmitter in relation to the process pipe depends on the process itself. Use the
following guidelines to determine transmitter location and placement of impulse piping:

74



Keep impulse piping as short as possible.



For liquid service, slope the impulse piping at least 1 in. per ft. (8 cm per m) upward from the
transmitter toward the process connection.
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

For gas service, slope the impulse piping at least 1 in. per ft. (8 cm per m) downward from the
transmitter toward the process connection.



Avoid high points in liquid lines and low points in gas lines.



Make sure both impulse legs are the same temperature.



Use impulse piping large enough to avoid friction effects and blockage.



Vent all gas from liquid piping legs.



When using a sealing fluid, fill both piping legs to the same level.



When purging, make the purge connection close to the process taps and purge through equal lengths
of the same size pipe. Avoid purging through the transmitter.



Keep corrosive or hot, above 250 °F (121 °C), process material out of direct contact with the
SuperModule process connection and flanges.



Prevent sediment deposits in the impulse piping.



Keep the liquid head balanced on both legs of the impulse piping.

Note
Take necessary steps to prevent process fluid from freezing within the process flange to avoid damage to
the transmitter.
Note
Verify transmitter zero point after installation. To reset zero point, refer to “Sensor trim overview” on
page 90.

3.4.5

Connect wiring and power up
It is recommended to use twisted pair wiring. To ensure proper communication, use 24 to 14 AWG wire,
and do not exceed 5000 ft. (1500 m).
Note
Proper electrical installation is necessary to prevent errors due to improper grounding and electrical
noise. Shielded wiring is recommended for environments with high EMI/RFI levels. Shielded wiring is
required in order to comply with NAMUR requirements.

Figure 3-8. Terminal Blocks
Without optional process
temperature connection

With optional process
temperature connection

To make connections, perform the following procedure:
1. Remove the cover on the field terminals side of the housing.
2. Connect the positive lead to the “PWR/COMM +” terminal, and the negative lead to the “PWR/COMM
–” terminal.
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Note
Do not connect the power across the test terminals. Power could damage the test diode in the test
connection.
3. If the optional process temperature input is not installed, plug and seal the unused conduit
connection. If the optional process temperature input is being utilized, see “Install optional process
temperature input (Pt 100 RTD sensor)” on page 76 for more information.
When the enclosed pipe plug is utilized in the conduit opening, it must be installed with a minimum
engagement of five threads in order to comply with flameproof/explosion-proof requirements.
4. If applicable, install wiring with a drip loop. Arrange the drip loop so the bottom is lower than the
conduit connections and the transmitter housing.
5. Reinstall the housing cover and tighten so that metal contacts metal to meet
flameproof/explosion-proof requirements.
Figure 3-9 shows the wiring connections necessary to power a Rosemount 3051SMV and enable
communications with a Hand-held Field Communicator.
Figure 3-9. Transmitter Wiring
Without optional process temperature
connection

With optional process temperature
connection

A

A

RL ≥ 250Ω
RL ≥ 250Ω

A. Power supply

Note
Installation of the transient protection terminal block does not provide transient protection unless the
Rosemount 3051SMV housing is properly grounded. See “Grounding” on page 79 for more information.

Install optional process temperature input (Pt 100 RTD sensor)
Note
To meet ATEX/IECEx Flameproof certification, only ATEX/IECEx Flameproof cables (temperature input
code C30, C32, C33, C34 or customer supplied equivalent) may be used.
1. Mount the Pt 100 RTD Sensor in the appropriate location.
Note
Use shielded four-wire cable for the process temperature connection.

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2. Connect the RTD cable to the Rosemount 3051SMV by inserting the cable wires through the unused
housing conduit connection and connect to the four screws on the transmitter terminal block. An
appropriate cable gland should be used to seal the conduit opening around the cable. See Figure 3-10
on page 77.
3. Connect the RTD cable shield wire to the ground lug in the housing.
Figure 3-10. RTD Wiring Connection

A

Red
Red
White
White

D

B
C

A. Ground lug
B. RTD connection head

C. Pt 100 RTD sensor
D. RTD cable assembly wires

Three-wire RTD
A four-wire Pt 100 RTD is required to maintain published performance specifications. A three-wire Pt 100
RTD may be used with degraded performance. If connecting to a three-wire RTD, use a four-wire cable to
connect the Rosemount 3051SMV terminal block to the RTD connection head. Within the RTD
connection head, connect two of the same colored wires from the Rosemount 3051SMV to the single
colored wire of the RTD sensor.

Surges/transients
The transmitter will withstand electrical transients of the energy level usually encountered in static
discharges or induced switching transients. However, high-energy transients, such as those induced in
wiring from nearby lightning strikes, can damage the transmitter.

Optional transient protection terminal block
The transient protection terminal block can be ordered as an installed option (code T1 in the transmitter
model number) or as a spare part to retrofit existing Rosemount 3051SMV in the field. For a complete
listing of spare part numbers for transient protection terminal blocks, refer to “Service support” on
page 117. A lightning bolt symbol on a terminal block identifies it as having transient protection.

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Note
Grounding the transmitter case using the threaded conduit connection may not provide a sufficient
ground. The transient protection terminal block (option code T1) will not provide transient protection
unless the transmitter case is properly grounded. See “Grounding” on page 79 to ground the transmitter
case. Do not run transient protection ground wire with signal wiring; the ground wire may carry
excessive current if a lightning strike occurs.

Signal wire grounding
Do not run signal wiring in conduit or open trays with power wiring, or near heavy electrical equipment.
Ground the shield of the signal wiring at any one point on the signal loop. See Figure 3-11. The negative
terminal of the power supply is a recommended grounding point.
Figure 3-11. Signal Wire Grounding
E
F
A

B

C

DP

D

A. Positive
B. Negative
C. Connect shield back to the power supply negative terminal

D. Insulate shield
E. Minimize distance
F. Trim shield and insulate

Power supply 4–20 mA transmitters
The DC power supply should provide power with less than two percent ripple. Total resistance load is the
sum of resistance from signal leads and the load resistance of the controller, indicator, and related
pieces. Note that the resistance of intrinsic safety barriers, if used, must be included.
See “Load limitations” on page 131 for transmitter resistance load limits.
Note
A minimum loop resistance of 250 ohms is required to communicate with a Field Communicator. If a
single power supply is used to power more than one Rosemount 3051SMV, the power supply used and
circuitry common to the transmitters should not have more than 20 ohms of impedance at 1200 Hz.

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3.4.6

September 2017

Conduit electrical connector wiring (option GE or GM)
For Rosemount 3051SMV with conduit electrical connectors GE or GM, refer to the cordset
manufacturer’s installation instructions for wiring details. For FM Intrinsically Safe, non-incendive
hazardous locations, install in accordance with Rosemount drawing 03151-1009 to maintain outdoor
rating (NEMA® 4X and IP66.) For more information, see “Product Certifications” on page 155.

3.4.7

Grounding
Transmitter case
Always ground the transmitter case in accordance with national and local electrical codes. The most
effective transmitter case grounding method is a direct connection to earth ground with minimal
impedance (< 1Ω). Methods for grounding the transmitter case include:

Internal ground connection
The internal ground connection screw is inside the terminal side of the electronics housing. The screw is
identified by a ground symbol ( ), and is standard on all Rosemount 3051SMV.
Figure 3-12. Internal Ground Connection
A

A. Ground lug

External ground connection
The external ground connection is on the outside of the SuperModule housing. The connection is
identified by a ground symbol ( ). An external ground assembly is included with the option codes
shown in Table 3-3 on page 80 or is available as a spare part (03151-9060-0001).
Figure 3-13. External Ground Connection

B
A

A. External ground lug
B. External ground assembly (03151-9060-0001)

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Table 3-3. External Ground Screw Approval Option Codes
Option code Description

3.5

E1

ATEX Flameproof

I1

ATEX Intrinsic Safety

N1

ATEX Type n

ND

ATEX Dust

E4

TIIS Flameproof

K1

ATEX Flameproof, Intrinsic Safety, Type n, Dust (combination of E1, I1, N1, and ND)

E7

IECEx Flameproof, Dust Ignition-proof

N7

IECEx Type n

K7

IECEx Flameproof, Dust Ignition-proof, Intrinsic Safety, and Type n (combination of E7, I7, and N7)

KA

ATEX and CSA Explosion-proof, Intrinsically Safe, Division 2 (combination of E1, E6, I1, and I6)

KC

FM and ATEX Explosion-proof, Intrinsically Safe, Division 2 (combination of E5, E1, I5, and I1)

T1

Transient terminal block

D4

External ground screw assembly

Rosemount 305 and 304 Manifolds
The Rosemount 305 Integral Manifold is available in two designs: coplanar and traditional. The
traditional Rosemount 305 can be mounted to most primary elements with mounting adapters.
Figure 3-14. Rosemount 305 Manifold Styles
Rosemount 305 Integral Coplanar
Rosemount305 Integral Traditional

The Rosemount 304 comes in two basic styles: traditional (flange ⫻ flange and flange ⫻ pipe) and wafer.
The Rosemount 304 Traditional Manifold comes in 2-, 3-, and 5-valve configurations. The Rosemount
304 Wafer Manifold comes in 3- and 5-valve configurations.
Figure 3-15. Rosemount 304 Manifold Styles
Rosemount 304 Traditional
Rosemount 304 Wafer

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3.5.1

Installation
September 2017

Rosemount 305 Integral Manifold installation procedure
To install a Rosemount 305 Integral Manifold to a Rosemount 3051SMV:
1. Inspect the PTFE SuperModule O-rings. If the O-rings are undamaged, reusing them is recommended.
If the O-rings are damaged (e.g. nicks), replace them with new O-rings.
Note
If replacing the O-rings, be careful not to scratch or deface the O-ring grooves or the surface of the
isolating diaphragm when removing the damaged O-rings.
2. Install the Integral manifold on the SuperModule process connection. Use the four manifold bolts for
alignment. Finger tighten the bolts, then tighten the bolts incrementally in a cross pattern to final
torque value. See “Flange bolts” on page 71 for complete bolt installation information and torque
values. When fully tightened, the bolts should extend through the top of the SuperModule housing.
3. If the PTFE SuperModule O-rings have been replaced, the flange bolts should be re-tightened after
installation to compensate for seating of the O-rings.
4. If applicable, install flange adapters on the process end of the manifold using the 1.75-in. flange bolts
supplied with the transmitter.

3.5.2

Rosemount 304 Conventional Manifold installation procedure
To install a Rosemount 304 Conventional Manifold to a Rosemount 3051SMV:
1. Align the conventional manifold with the transmitter flange. Use the four manifold bolts for
alignment.
2. Finger tighten the bolts, then tighten the bolts incrementally in a cross pattern to final torque value.
See “Flange bolts” on page 71 for complete bolt installation information and torque values. When
fully tightened, the bolts should extend through the top of the SuperModule assembly bolt hole but
must not contact the SuperModule housing.
3. If applicable, install flange adapters on the process end of the manifold using the 1.75-in. flange bolts
supplied with the transmitter.

3.5.3

Manifold operation
Improper installation or operation of manifolds may result in process leaks, which may cause death or
serious injury.
Always perform a zero trim on the transmitter/manifold assembly after installation to eliminate any shift
due to mounting effects. See “Sensor trim overview” on page 90.

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Coplanar transmitters
3-valve and 5-valve manifolds
Performing zero trim at static line pressure
In normal operation the two isolate (block) valves
between the process ports and transmitter will be open
and the equalize valve will be closed.

H
Drain/Vent
valve

L
Drain/Vent
valve

Equalize
(closed)

Isolate
(open)

Isolate
(open)
Process

1. To zero trim the transmitter, close the isolate valve
on the low side (downstream) side of the
transmitter.

H
Drain/Vent
valve

L
Drain/Vent
valve

Equalize
(closed)

Isolate
(closed)

Isolate
(open)
Process

2. Open the equalize valve to equalize the pressure on
both sides of the transmitter. The manifold is now in
the proper configuration for performing a zero trim
Drain/Vent
on the transmitter.

H

valve

L
Drain/Vent
valve

Equalize
(open)

Isolate
(open)

Isolate
(closed)
Process

3. After performing a zero trim on the transmitter,
close the equalize valve.

H
Drain/Vent
valve

L
Drain/Vent
valve

Equalize
(closed)

Isolate
(open)

Isolate
(closed)
Process

4. Finally, to return the transmitter to service, open the
low side isolate valve.

H
Drain/Vent
valve

L

Equalize
(closed)

Isolate
(open)

Drain/Vent
valve
Isolate
(open)

Process

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5-valve natural gas manifold
Performing zero trim at static line pressure
5-valve natural gas configurations shown:
In normal operation, the two isolate (block) valves
between the process ports and transmitter will be open,
and the equalize valves will be closed. Vent valves may be
opened or closed.

H

L
(Plugged)

(Plugged)
Equalize Equalize
(closed) (closed)
Isolate
(open)

Isolate
(open)

Process Drain vent Process
(closed)

1. To zero trim the transmitter, first close the isolate
valve on the low pressure (downstream) side of the
transmitter and the vent valve.

H

L

(Plugged)

(Plugged)
Equalize Equalize
(closed) (closed)

Isolate
(open)

Isolate
(closed)

Process Drain vent Process
(closed)

2. Open the equalize valve on the high pressure
(upstream) side of the transmitter.

H

L

(Plugged)

(Plugged)
Equalize Equalize
(open) (closed)

Isolate
(open)

Isolate
(closed)

Process Drain vent Process
(closed)

3. Open the equalize valve on the low pressure
(downstream) side of the transmitter. The manifold is
now in the proper configuration for performing a zero
trim on the transmitter.

H

L

(Plugged)

(Plugged)
Equalize Equalize
(open) (open)

Isolate
(open)

Isolate
(closed)

Process Drain vent Process
(closed)

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4. After performing a zero trim on the transmitter, close
the equalize valve on the low pressure (downstream)
side of the transmitter.

H

L

(Plugged)

(Plugged)
Equalize Equalize
(open) (closed)

Isolate
(open)

Isolate
(closed)

Process Drain vent Process
(closed)

5. Close the equalize valve on the high pressure
(upstream) side.

H

L

(Plugged)

(Plugged)
Equalize Equalize
(closed) (closed)

Isolate
(open)

Isolate
(closed)

Process Drain vent Process
(closed)

6. Finally, to return the transmitter to service, open the
low side isolate valve and vent valve. The vent valve
can remain open or closed during operation.

H

L
(Plugged)

(Plugged)
Equalize Equalize
(closed) (closed)
Isolate
(open)

Isolate
(open)

Process Drain vent Process
(closed)

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In-line transmitters
2-valve and block and bleed style manifolds
Isolating the transmitter
In normal operation the isolate (block) valve between the process
port and transmitter will be open and the test/vent valve will be
closed. On a block and bleed style manifold, a single block valve
provides transmitter isolation and a bleed screw provides drain/vent
capabilities.

Transmitter
Vent
(closed)

Isolate

Process
(open)

1. To isolate the transmitter, close the isolate valve.

Transmitter
Vent
(closed)

Isolate

Process
(closed)

2. To bring the transmitter to atmospheric pressure, open the vent
valve or bleed screw.
Note
A 1/4-in. male NPT pipe plug may be installed in the test/vent port
and will need to be removed with a wrench in order to vent the
manifold properly.
Always use caution when venting directly to atmosphere.

Transmitter
Vent
(open)

Isolate

Process
(closed)

3. After venting to atmosphere, perform any required calibration
and then close the test/vent valve or replace the bleed screw.

Transmitter
Vent
(closed)

Isolate

Process
(closed)

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4. Open the Isolate (block) valve to return the transmitter to
service.

Transmitter
Vent
(closed)

Isolate

Process
(open)

Adjusting valve packing
Over time, the packing material inside a Rosemount manifold may require adjustment in order to
continue to provide proper pressure retention. Not all manifolds have this adjustment capability. The
manifold model number will indicate what type of stem seal or packing material has been used.
The following steps are provided as a procedure to adjust valve packing:
1. Remove all pressure from device.
2. Loosen manifold valve jam nut.
3. Tighten manifold valve packing adjuster nut 1/4 turn.
4. Tighten manifold valve jam nut.
5. Re-apply pressure and check for leaks.
6. Above steps can be repeated, if necessary.
If the above procedure does not result in proper pressure retention, the complete manifold should be
replaced.
Figure 3-16. Adjusting Valve Packing

E
A
F
D
C

G

B
A. Bonnet
B. Ball seat
C. Packing
D. Stem

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Section 4

September 2017

Operation and Maintenance

Overview . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . page 87
Safety messages . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . page 88
Transmitter calibration . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . page 89
Transmitter functional tests . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . page 96
Process variables . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . page 98
Field upgrades and replacements . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . page 99

4.1

Overview
This section contains information on operating and maintaining Rosemount™ 3051S MultiVariable™
Transmitters (Rosemount 3051SMV). Instructions for performing configuration and calibration
procedures are given for Field Communicator version 2.0 or later, AMS Device Manager version 9.0 or
later, and Engineering Assistant version 6.3 or later. Screen shots for this section are taken from AMS
Device Manager version 9.0; Engineering Assistant screens will look similar and follow the same
instructions for use and navigation. For convenience, Field Communicator Fast Key sequences are labeled
“Fast Keys” for each software function below the appropriate headings.
Based on the configuration ordered, some measurements (i.e. static pressure, process temperature)
and/or calculation types (i.e. mass, volumetric, and energy flow) may not be available for all fluid types.
Available measurements and/or calculation types are determined by the multivariable type and
measurement type codes ordered. See “Ordering information” on page 138 for more information.
All screens in this section are shown for multivariable type M (fully compensated mass and energy flow),
measurement type 1 (differential pressure, static pressure, and process temperature). Field
Communicator Fast Keys are given for both multivariable type M and P (direct process variable output)
with measurement type 1. Field Communicator Fast Keys and screens for other multivariable types and
measurement types may vary.

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4.2

Safety messages
Procedures and instructions in this section may require special precautions to ensure the safety of the
personnel performing the operation. Information that raises potential safety issues is indicated with a
warning symbol (
by this symbol.

). Refer to the following safety messages before performing an operation preceded

Failure to follow these installation guidelines could result in death or serious injury.


Make sure only qualified personnel perform the installation.

Explosions could result in death or serious injury.


Do not remove the transmitter cover in explosive atmospheres when the circuit is live.



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 flameproof/explosion-proof requirements.



Verify the operating atmosphere of the transmitter is consistent with the appropriate hazardous
locations certifications.

Electrical shock could cause death or serious injury.


If the sensor is installed in a high-voltage environment and a fault or installation error occurs, high
voltage may be present on the transmitter leads and terminals.



Use extreme caution when making contact with the leads and terminals.

Process leaks could result in death or serious injury.


Install and tighten all four flange bolts before applying pressure.



Do not attempt to loosen or remove flange bolts while the transmitter is in service.



Replacement equipment or spare parts not approved by Emerson™ for use as spare parts could
reduce the pressure retaining capabilities of the transmitter and may render the instrument
dangerous.



Use only bolts supplied or sold by Emerson as spare parts.

Improper assembly of manifolds to traditional flange can damage the device.


For safe assembly of manifold to traditional flange, bolts must break back plane of flange web
(i.e., bolt hole) but must not contact the sensor module.

Improper installation or repair of the SuperModule™ assembly with high pressure option (P0)
could result in death or serious injury.


For safe assembly, the high pressure SuperModule assembly must be installed with ASTM A193
Class 2 Grade B8M Bolts and either a Rosemount 305 Manifold or a DIN-compliant traditional flange.

Static electricity can damage sensitive components.
Observe safe handling precautions for static-sensitive components.

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4.3

Transmitter calibration

4.3.1

Calibration overview
Complete configuration and calibration of the Rosemount 3051SMV involves the following tasks:

Configure the output parameters


Basic setup screen



Set process variable units



Set primary variable



Rerange



Set transfer function (direct process variable feature board only)



Set damping

Calibrate the sensor (DP, P, and/or T)
For each sensor, perform:


Sensor trim (page 90)



Zero or lower sensor trim (page 91)

Calibrate the 4–20 mA output


4–20 mA analog trim (page 95); or



4–20 mA scaled output trim (page 95)

Figure 4-1 summarizes the data flow for the Rosemount 3051SMV. Data flows from left to right, and a
parameter change affects all values to the right of the changed parameter.
Figure 4-1. Transmitter Data Flow
Measured
process
inputs

DP
P
T

A/D

Micro

D/A

Analog mA output
(primary variable)
Digital HART variables
(primary, 2nd, 3rd, and 4th)

Data flow can be summarized in four major steps:
1. A change in a process variable (DP, P, and/or T) corresponds to a change in the sensor output
(Sensor Signal).
2. The sensor signal is converted to a digital format that is understood by the microprocessor
(Analog-to-Digital Signal Conversion).
3. Corrections and flow calculations are performed in the microprocessor to obtain a digital
representation of the process output variables.
4. The Digital Primary Variable (PV) is converted to an analog value (Digital-to-Analog Signal
Conversion).
Note
Coplanar transmitter configurations measuring gage pressure and process temperature (measurement
5) will report as the pressure as differential pressure. This will be reflected on the LCD display, nameplate,
digital interfaces, and other user interfaces.
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4.3.2

Sensor trim overview
Trim the sensors using either sensor or zero trim functions. Trim functions vary in complexity and are
application-dependent. Both trim functions alter the transmitter’s interpretation of the input signal.

Zero trim
Zero trim is a single-point offset adjustment. It is useful for compensating for mounting position effects
and is most effective when performed with the transmitter installed in its final mounting position. Since
this correction maintains the slope of the characterization curve, it should not be used in place of a
sensor trim over the full sensor range.
When performing a zero trim with a manifold, refer to “Rosemount 305 and 304 Manifolds” on page 80.
Note
The transmitter must be within five percent or less of the maximum span of true zero (zero-based) in
order to calibrate with zero trim function.
The transmitter will not allow the user to perform a zero trim on an absolute static pressure sensor. To
correct mounting position effects on the absolute static pressure sensor, perform a lower sensor trim.
The lower sensor trim function provides an offset correction similar to the zero trim function, but it does
not require zero-based input.

Upper and lower sensor trim
Sensor trim is a two-point sensor calibration where two end-point pressures are applied, and all output is
linearized between them. Always adjust the lower sensor trim value first to establish the correct offset.
Adjustment of the upper sensor trim value provides a slope correction to the characterization curve
based on the lower sensor trim value. The trim values allow the user to optimize performance over a
specified measuring range at the calibration temperature.

4.3.3

Differential pressure sensor calibration
Mass and energy flow Fast Keys

1, 2, 5, 3

Direct process variable output Fast Keys

1, 2, 4, 3

The Differential Pressure Calibration tab allows the user to complete a zero trim procedure or a full DP
sensor trim, see Figure 4-2 on page 91.

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Figure 4-2. Calibration - Differential Pressure Calibration Tab

Zero trim
To perform a DP sensor zero trim, select the Zero Trim button under the Differential Pressure Sensor Trim
heading and follow the on-screen prompts. The transmitter must be within five percent or less of the
maximum span of true zero (zero-based) in order to calibrate with zero trim function.
Note
When performing a DP sensor zero trim, ensure the equalizing valve is open and all wet legs are filled to
the correct levels.

Upper and lower sensor trim
A reference pressure device is required to perform a full sensor trim. Use a reference pressure device that
is at least three times more accurate than the transmitter and allow the pressure input to stabilize for ten
seconds before entering any values. It is possible to degrade the performance of the transmitter if the full
sensor trim is done improperly or with inaccurate calibration equipment.
To perform a DP full trim, perform the following procedure:
1. Select the Lower Sensor Trim button and follow the on-screen prompts.
2. Select the Upper Sensor Trim button and follow the on-screen prompts.
Note
Select process variable calibration input values so that low and high values are equal to or outside the
upper and lower range limits. Do not attempt to obtain reverse output by reversing the high and low
points. The transmitter allows approximately five percent URL deviation from the characterized curve
established at the factory.

Calibration type
The calibration type drop-down menu allows the user to note the type of device last used to calibrate the
sensor (either Differential, Gage, or Absolute). This field does not affect the calibration of the device.
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Recall factory trim
The Recall Factory Trim button will restore the transmitter to the original factory characterization
curve. The Recall Factory Trim button can be useful for recovering from an inadvertent zero trim or
inaccurate pressure source.
When the recall factory trim function is used, the transmitter’s upper and lower trim values are set to the
values configured at the factory. If custom trim values were specified when the transmitter was ordered,
the device will recall those values. If custom trim values were not specified, the device will recall the
upper and lower sensor limits.

Last DP sensor trim point
The current upper and lower trim points can be seen under the Last DP Sensor Trim Point heading.

4.3.4

Static pressure sensor calibration
Mass and energy flow Fast Keys

1, 2, 5, 4

Direct process variable output Fast Keys

1, 2, 4, 4

The Static Pressure Calibration tab allows the user to complete either a zero trim procedure or a full SP
sensor trim, see Figure 4-3.
Figure 4-3. Calibration - Static Pressure Calibration Tab

Zero trim and lower sensor trim
The type of static pressure sensor equipped in the transmitter can be determined by referring to the
Static Pressure Sensor Type heading. This determines whether a zero trim (gage sensor) or lower sensor
trim (absolute sensor) required to correct for mounting position effects.
To perform a zero trim on a gage static pressure sensor, select the Zero Trim button under the Static
Pressure Sensor Trim heading and follow the on-screen prompts. The transmitter must be within five
percent or less of the maximum span of true zero (zero-based) in order to calibrate with zero trim
function.
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To correct for mounting position effects on transmitters equipped with an absolute static pressure
sensor, perform a lower sensor trim. This is accomplished by selecting the Lower Sensor Trim button
and following the on-screen prompts. The lower sensor trim function provides an offset correction
similar to the zero trim function, but it does not require a zero-based input.

Upper and lower sensor trim
To perform a Static Pressure Full Sensor Trim, perform the following procedure:
1. Select the Lower Sensor Trim button and follow the on-screen prompts.
2. Select the Upper Sensor Trim button and follow the on-screen prompts.
Note
It is possible to degrade the performance of the transmitter if the full sensor trim is done improperly or
with inaccurate calibration equipment. Use a pressure input source that is at least three times more
accurate than the transmitter and allow the pressure input to stabilize for ten seconds before entering
any values.

Recall factory trim
The Recall Factory Trim button will restore the transmitter to the original factory characterization
curve. The Recall Factory Trim button can be useful for recovering from an inadvertent zero trim or
inaccurate pressure source.
When the recall factory trim function is used, the transmitter’s upper and lower trim values are set to the
values configured at the factory. If custom trim values were specified when the transmitter was ordered,
the device will recall those values. If custom trim values were not specified, the device will recall the
upper and lower sensor limits.

Last static pressure sensor trim
The current upper and lower trim points can be seen under the Last Static Pressure Sensor Trim Points
heading.

Calibration type
The calibration type drop-down menu allows the user to note the type of device last used to calibrate the
sensor (either Differential, Gage, or Absolute). This field does not affect the calibration of the device.

4.3.5

Process temperature sensor calibration
Mass and energy flow Fast Keys

1, 2, 5, 5

Direct process variable output Fast Keys

1, 2, 4, 5

The Temperature Calibration tab allows the user to perform a sensor trim and configure the sensor
matching of a process temperature sensor, see Figure 4-4 on page 94.

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Figure 4-4. Calibration - Temperature Calibration Tab

Process temperature upper and lower sensor trim
To calibrate the Process Temperature Input using the sensor trim, follow the procedure shown below:
1. Set up a Temperature Calibrator to simulate a Pt 100 (100-ohm platinum, alpha 385 RTD). Wire the
two red wires from the Rosemount 3051SMV terminal block to one connection, and the two white
wires to the other connection. See “Install optional process temperature input (Pt 100 RTD sensor)”
on page 76 for more information.
2. Adjust the calibrator/RTD simulator to a test point temperature value that represents a minimum
process temperature (for example, 32 °F or 0 °C). Select the Lower Sensor Trim button under the
Process Temperature Sensor Trim heading and follow the on-screen prompts.
3. Adjust the calibrator/RTD simulator to a test point temperature value that represents the maximum
process temperature (for example, 140 °F or 60 °C). Select the Upper Sensor Trim button under the
Process Temperature Sensor Trim heading and follow the on-screen prompts.

Recall factory trim
The Recall Factory Trim button will restore the transmitter to the original factory calibration settings.
When the recall factory trim function is used, the transmitter’s upper and lower trim values are set to the
values configured at the factory. If custom trim values were specified when the transmitter was ordered,
the device will recall those values. If custom trim values were not specified, the device will recall the
upper and lower sensor limits.

Transmitter RTD sensor matching using Callendar-Van Dusen
constants
The Rosemount 3051SMV accepts Callendar-Van Dusen constants from a calibrated RTD schedule and
generates a special custom curve to match that specific sensor Resistance vs. Temperature performance.
Matching the specific sensor curve with the transmitter configuration enhances the temperature
measurement accuracy.

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Under the Sensor Matching heading, the Callendar-Van Dusen constants R0, A, B, and C can be viewed. If
the Callendar-Van Dusen constants are known for the user’s specific Pt 100 RTD sensor, the constants R0,
A, B, and C may be edited by selecting the Callendar-Van Dusen Setup button and following the
on-screen prompts.
The user may also view the α, β, and δ Coefficients by selecting the View Alpha, Beta, Delta button. The
constants R0, α, β, and δ may be edited by selecting the Callendar-Van Dusen Setup button and
following the on-screen prompts. To reset the transmitter to the IEC 751 Defaults, select the Reset to IEC
751 Defaults button.

4.3.6

Analog calibration
Mass and energy flow Fast Keys

1, 2, 5, 2

Direct process variable output Fast Keys

1, 2, 4, 5

Figure 4-5. Calibration - Analog Calibration Tab

Analog output trim
The Analog Output Trim commands allow the user to adjust the transmitter’s current output at the 4 and
20 mA points to match the plant standards. This command adjusts the digital to analog signal
conversion, see Figure 4-5.
To perform an analog trim, select the Analog Trim button and follow the on-screen prompts.

Scaled analog output trim
The scaled analog trim command matches the 4 and 20 mA points to a user selectable reference scale
other than 4 and 20 mA (for example, 1 to 5 volts if measuring across a 250 ohm load, or 0 to 100 percent
if measuring from a Distributed Control System [DCS]). To perform a scaled analog trim, connect an
accurate reference meter, select the Scaled Analog Trim button, and follow the on-screen prompts.

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Note
Use a precision resistor for optimum accuracy. When adding a resistor to the loop, ensure that the power
supply is sufficient to power the transmitter to a 23 mA (maximum high alarm) output with the
additional loop resistance.

Analog output loop test
Under the Analog Output Verify heading, a loop test can be performed by selecting the Loop Test button.
The loop test command verifies the output of the transmitter, the integrity of the loop, and the
operations of any recorders or similar devices installed in the loop.

Analog output diagnostic alerts
Two diagnostic alerts are shown under the Diagnostics heading.
The first is mA Output Fixed. This alerts the user that the 4–20 mA analog output signal is fixed at a
constant value and is not representative of the HART Primary Variable. This diagnostic alert may also be
triggered if “Loop Current Mode” is disabled, the device is in alarm, or if “Test Calculation” is running.
The second diagnostic is mA Output Saturated. This alerts the user that the measured Primary Variable
has exceeded the range points defined for the 4–20 mA analog output signal. The analog output is fixed
at the user-defined high or low saturation point and is not representative of the current HART Primary
Variable.

4.4

Transmitter functional tests
Figure 4-6. Transmitter Functional Tests Screen

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September 2017

Flow/energy calculation verification (test calculation)
Mass and energy flow Fast Keys

1, 2, 3

(Fully compensated mass and energy flow feature board only):
The Flow and Energy Calculation Verification Test allows the user to verify the flow configuration of the
Rosemount 3051SMV by entering expected values for the differential pressure, static pressure, and
process temperature variables. Under the Flow/Energy Calculation Verification heading, perform the
following steps:
1. Select the Enable Test Calculation button.
2. Select Simulate DP option. Select Next.
3. Select DP Units from the drop-down menu. Select Next.
4. Enter the DP Value corresponding to the desired flow rate simulation. Select Next.
5. Repeat steps 1–3 for static pressure (Simulate AP/GP) and process temperature (Simulate PT), if
applicable.
6. Select View Results. Select Next. The simulated flow rate and corresponding flow properties will be
shown. Select Next.
7. Select Exit. Select Next. Leaving the Enable Test Calculation window automatically returns all process
variables fixed by the test calculation method to live process variable measurements.

4.4.2

Configuring fixed process variables
Mass and energy flow Fast Keys

1, 2, 4

Direct process variable output Fast Keys

1, 2, 3

Under the Fixed Process Variables heading, the user may temporarily set the differential pressure, static
pressure or process temperature to a user defined fixed value for testing purposes. Once the user leaves
the Configure Fixed Variable method, the fixed process variable will be automatically returned to a live
process variable measurement.

4.4.3

Analog output loop test
Mass and energy flow Fast Keys

1, 2, 2

Direct process variable output Fast Keys

1, 2, 2

Under the Analog Output Verify heading, a Loop Test can be performed by selecting the Loop Test button.
The loop test command verifies the output of the transmitter, the integrity of the loop, and the
operations of any recorders or similar devices installed in the loop.

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4.5

Process variables

4.5.1

Process variable tabs
Mass and energy flow Fast Keys

1, 1

Direct process variable output Fast Keys

1, 1

The Process Variables screen shows a graphical representation of the respective variable. An example of
the Primary Variable tab (as shown in Figure 4-7). The chart on these Process Variables tabs will begin
plotting when the user first navigates to the screen, and will only continue plotting while the user is
viewing this tab. The user may view a larger version of the chart by selecting the Large Chart button.
Each of the four digital output variables has a screen similar to the one shown in Figure 4-7.
Figure 4-7. Process Variables - Primary Variable Tab

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All variables tab
The All Variables tab allows the user to view a complete overview of all variables available within the
device.
Figure 4-8. Process Variables - All Variables Tab

4.6

Field upgrades and replacements

4.6.1

Disassembly considerations
During disassembly, do not remove the instrument cover in explosive atmospheres when the circuit is
live as this may result in serious injury or death. Also, be aware of the following:


Follow all plant safety rules and procedures.



Isolate and vent the process from the transmitter before removing the transmitter from service.



Disconnect optional process temperature sensor leads and cable.



Remove all other electrical leads and conduit.



Detach the process flange by removing the four flange bolts and two alignment screws that secure it.



Do not scratch, puncture, or depress the isolating diaphragms.



Clean isolating diaphragms with a soft rag and a mild cleaning solution, then rinse with clear water.



Whenever the process flange or flange adapters are removed, visually inspect the PTFE O-rings.
Emerson recommends reusing O-rings if possible. If the O-rings show any signs of damage, such as
nicks or cuts, they should be replaced.

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4.6.2

Housing assembly including feature board electronics
Field device labels
The SuperModule label reflects the replacement model code for reordering a complete transmitter,
including both the SuperModule assembly and Plantweb™ housing. The Rosemount 3051SMV model
code stamped on the Plantweb housing nameplate can be used to reorder the Plantweb housing
assembly.

Upgrading feature board electronics
The Rosemount 3051SMV allows feature board electronics upgrades. Different feature board electronics
assemblies provide new functionality and are easily interchanged for upgrade. When replacing or
upgrading the feature board electronics, use the “Rosemount 300SMV housing kit” on page 144 which
also includes the appropriate Plantweb housing.

Upgrading or replacing the housing assembly including feature board
electronics
Remove the feature board
The Rosemount 3051SMV feature board is located opposite the field terminal side in the Plantweb
housing. To remove the feature board, perform the following procedure:
1. Remove the housing cover opposite the field terminal side.
2. Remove the LCD display, if applicable. To do this, hold in the two clips and pull outward. This will
provide better access to the two screws located on the feature board.
3. Loosen the two captive screws located on the feature board.
4. Pull out the feature board to expose and locate the SuperModule connector, see Figure 4-10 on
page 101.
5. Press the locking tabs and pull the SuperModule connector upwards (avoid pulling wires). Housing
rotation may be required to access locking tabs. See “Housing rotation” on page 68 for more
information.
Figure 4-9. SuperModule Connector View
A

B

A. Feature board
B. SuperModule connector

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Separate the SuperModule assembly from the housing
1. To prevent damage to the SuperModule connector, remove the feature board from the SuperModule
assembly and remove the connector before separating the SuperModule assembly from the housing.
2. Loosen the housing rotation set screw by one full turn with a 3/32-in. hex wrench.
3. Unscrew the housing from the SuperModule threads.
Figure 4-10. SuperModule Connector

A
A. 3/32-in. housing rotation set screw

Note
The V-Seal (03151-9061-0001) must be installed at the bottom of the housing.

Figure 4-11. V-Seal

A

A. Black rubber V-seal

Attach the SuperModule assembly to the Plantweb housing
1. Apply a light coat of low temperature silicon grease to the SuperModule threads and O-ring.
2. Thread the housing completely onto the SuperModule assembly. The housing must be no more than
one full turn from flush with the SuperModule assembly to comply with flameproof/explosion-proof
requirements.
3. Tighten the housing rotation set screw using a 3/32-in. hex wrench to a recommended torque of
30 in-lb (3.4 N-m).

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Install feature board in the Plantweb housing
1. Apply a light coat of low temperature silicon grease to the SuperModule connector O-ring.
2. Insert the SuperModule connector into the top of the SuperModule assembly. Ensure the locking tabs
are fully engaged.
3. Gently slide the feature board into the housing, making sure the pins from the Plantweb housing
properly engage the receptacles on the feature board.
4. Tighten the captive screws.
5. Attach the Plantweb housing cover and tighten so that metal contacts metal to meet
flameproof/explosion-proof requirements.

4.6.3

Terminal block
Electrical connections are located on the terminal block in the compartment labeled “FIELD
TERMINALS.” The terminal block may be replaced or upgraded to add transient protection. Part numbers
can be found in “Service support” on page 117.
Loosen the two captive screws (see Figure 4-12), and pull the entire terminal block out.
Figure 4-12. Terminal Blocks
Without optional
process temperature connections

With optional
process temperature connections

A
A

A. Captive screws

1. Gently slide the terminal block into the housing, making sure the pins from the Plantweb housing
properly engage the receptacles on the terminal block.
2. Tighten the captive screws on the terminal block.
3. Attach the Plantweb housing cover and tighten so that metal contacts metal to meet
flameproof/explosion-proof requirements.

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September 2017

LCD display
Transmitters ordered with the LCD display will be shipped with the display installed. Installing the display
on an existing Rosemount 3051SMV requires the LCD display kit (part number 03151-9193-0001 for
aluminum housing and 03151-9193-0004 for stainless steel (SST) housing).
Use the following procedure and Figure 4-13 to install the LCD display:
1. If the transmitter is installed in a loop, then secure the loop and disconnect power.
2. Remove the transmitter cover on the feature board side (opposite the field terminals side). Do not
remove the instrument covers in explosive environments when the circuit is live.
3. Engage the four-pin connector into the feature board and snap the LCD display into place.
4. Install the display cover and tighten to ensure metal to metal contact in order to meet
flameproof/explosion-proof requirements.
Figure 4-13. Optional LCD Display
A
B

C

A. Feature board
B. LCD display
C. Display cover

4.6.5

Flange and drain vent
The Rosemount 3051SMV is attached to the process connection flange by four bolts and two alignment
cap screws.
1. Remove the two alignment cap screws.
Figure 4-14. Alignment Cap Screws
A

A. Alignment cap screw

2. Remove the four bolts and separate the transmitter from the process connection, but leave the
process connection flange in place and ready for re-installation.

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Note
If the installation uses a manifold, see “Manifold operation” on page 81.
3. Inspect the SuperModule PTFE O-rings. If the O-rings are undamaged, they may be reused. Emerson
recommends reusing O-rings if possible. If the O-rings show any signs of damage, such as nicks or
cuts, they should be replaced (part number 03151-9042-0001 for glass-filled PTFE and part number
03151-9042-0002 for graphite-filled PTFE).
Note
If replacing the O-rings, be careful not to scratch or deface the O-ring grooves or the surface of the
isolating diaphragm when removing the damaged O-rings.
4. Install the process flange on the SuperModule process connection. To hold the process flange in
place, install the two alignment cap screws finger tight (these screws are not pressure retaining). Do
not overtighten; this will affect module-to-flange alignment.
5. Install the appropriate flange bolts.
a. If the installation requires a 1/4–18 NPT connection(s), use four 1.75-in. flange bolts.
Finger tighten the bolts. Go to Step d.
b. If the installation requires a 1/2–14 NPT connection(s), use flange adapters and four 2.88-in.
process flange/adapter bolts.
c. Hold the flange adapters and adapter O-rings in place while finger-tightening the bolts.
d. Tighten the bolts to the initial torque value using a crossed pattern. See Table 4-1 for appropriate
torque values.
e. Tighten the bolts to the final torque value using a crossed pattern. See Table 4-1 for appropriate
torque values. When fully tightened, the bolts should extend through the top of the module
housing.
f. Torque alignment screws to 30 in-lb (3.4 N-m). If the installation uses a conventional manifold,
then install flange adapters on the process end of the manifold using the 1.75-in. flange bolts
supplied with the transmitter.
Table 4-1. Bolt Installation Torque Values
Bolt material

Initial torque value

Final torque value

CS-ASTM-A449 Standard

300 in-lb (34 N-m)

650 in-lb (73 N-m)

316 SST—Option L4

150 in-lb (17 N-m)

300 in-lb (34 N-m)

ASTM-A-193-B7M—Option L5

300 in-l (34 N-m)

650 in-lb (73 N-m)

Alloy K-500—Option L6

300 in-lb (34 N-m)

650 in-lb (73 N-m)

ASTM-A-453-660—Option L7

150 in-lb (17 N-m)

300 in-lb (34 N-m)

ASTM-A-193-B8M—Option L8

150 in-lb (17 N-m)

300 in-lb (34 N-m)

6. If the SuperModule PTFE O-rings are replaced, re-torque the flange bolts and alignment cap screws
after installation to compensate for seating of the PTFE O-ring.
7. Install the drain/vent valve.
a. Apply sealing tape to the threads on the seat. Starting at the base of the valve with the threaded
end pointing toward the installer, apply two clockwise turns of sealing tape.
b. Take care to place the opening on the valve so that process fluid will drain toward the ground and
away from human contact when the valve is opened.
c. Tighten the drain/vent valve to 250 in-lb (28.25 N-m).
d. Tighten the stem to 70 in-lb (8 N-m).
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Note
Due to the sensitivity of the Range 1 DP Sensor, extra steps are required to optimize performance. It is
necessary to temperature soak the assembly using the following procedure.
1. After replacing O-rings on DP Range 1 transmitters and re-installing the process flange, expose the
transmitter to a temperature of 185 °F (85 °C) for two hours.
2. Re-tighten the flange bolts in a cross pattern.
3. Again, expose the transmitter to a temperature of 185 °F (85 °C) for two hours before calibration.

4.6.6

SuperModule assembly
To reorder an upgrade or replacement SuperModule assembly, use the Rosemount 3051SMV “Ordering
information” on page 138 but replace the housing option code with ‘00’.
1. Remove the housing assembly per “Upgrading or replacing the housing assembly including feature
board electronics” on page 100.
2. Remove currently installed SuperModule assembly from process flange per “Flange and drain vent”
on page 103.
3. Reassemble replacement or upgraded SuperModule assembly to process flange per “Flange and drain
vent” on page 103.
4. Reassemble the housing assembly per “Upgrading or replacing the housing assembly including
feature board electronics” on page 100.

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Section 5

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Troubleshooting

Overview . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . page 107
Device diagnostics . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . page 107
Measurement quality and limit status . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . page 112
Engineering Assistant communication troubleshooting . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . page 113
Measurement troubleshooting . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . page 114
Service support . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . page 117

5.1

Overview
This section contains information for troubleshooting the Rosemount™ 3051S MultiVariable™
Transmitter (Rosemount 3051SMV). Diagnostic messages are communicated via the LCD display or a
HART® host.

5.2

Device diagnostics

5.2.1

HART host diagnostics
The Rosemount 3051SMV provides numerous diagnostic alerts via a HART host. These alerts can be
viewed in Engineering Assistant 6.3 or later, Field Communicator, or AMS Device Manager.
Table 5-1 on page 108 lists the possible diagnostic alerts that may be shown with the Rosemount
3051SMV. The tables also give a brief description of what each alert indicates and the recommended
actions.
Table 5-2 on page 111 provides summarized maintenance and troubleshooting suggestions for the most
common operating problems. If a malfunction is suspected despite the absence of any diagnostic
messages on the Field Communicator or host, follow the procedures described here to verify that
transmitter hardware and process connections are in good working order.

5.2.2

LCD display diagnostics
In addition to output, the LCD display shows abbreviated operation, error, and warning messages for
troubleshooting. Messages appear according to their priority; normal operating messages appear last.
To determine the cause of a message, use a HART host to further interrogate the transmitter.
A description of each LCD display diagnostic message follows.

Error messages
An error indicator message appears on the LCD display to warn of serious problems affecting the
operation of the transmitter. The LCD display shows an error message until the error condition is
corrected; ERROR appears at the bottom of the display.

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Warning messages
Warning messages appear on the LCD display to alert the user of user-repairable problems with the
transmitter, or current transmitter operations. Warning messages appear alternately with other
transmitter information until the warning condition is corrected or the transmitter completes the
operation that warrants the warning message.
Table 5-1. Diagnostic Message Troubleshooting
LCD display messages

Host diagnostic message

Possible problems

Recommended actions

AP GP LIMIT

Static Pressure Out of Limits

The static pressure is exceeding
the sensor limits.

Verify process conditions are
within the sensor limits.

Feature Board
Communication Error

The feature board electronics
are experiencing
communication problems. This
problem may be temporary and
could clear automatically.

Cycle power to the device. If the
problem persists, replace the
feature board electronics.

CURR SAT

Primary Variable Analog
Output Saturated

The primary variable has
exceeded the range points
defined for the
4–20 mA analog output signal.
The analog output is fixed at the
high or low saturation point and
is not representative of the
current process conditions.

Verify the process conditions and
modify the analog range values if
necessary.

DP LIMIT

Differential Pressure Out of
Limits

The Differential Pressure is
exceeding the sensor limits.

Verify that the process conditions
are within the sensor limits.

FAIL BOARD ERROR

Feature Board Error

The feature board electronics
have detected an unrecoverable
failure.

Replace the feature board
electronics.

Process Temperature Sensor
Failure

The process temperature sensor
has failed or is incorrectly wired.

Check the sensor wiring and fix
any shorts or open connections.
If the sensor wiring is correct,
check the PT sensor and replace if
necessary. If the problems
persists, replace the feature board
electronics.

Sensor Module Failure

The SuperModule™ assembly is
providing measurements that
may no longer be valid.

Verify the sensor module
temperature is within the
operating limits of the transmitter.
Replace SuperModule assembly if
necessary.

Updating Flow Configuration
- Flow Values Constant

A flow configuration is currently
being downloaded to the
transmitter. During the
download, the flow output will
be fixed at the last calculated
value. Once the download is
complete the transmitter will
resume live calculations.

No action is required. Wait until
the flow configuration download is
complete before performing other
configuration tasks.

BOARD COMM ERROR

FAIL PT ERROR

FAIL SENSOR ERROR

FLOW CONFIG

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Table 5-1. Diagnostic Message Troubleshooting
LCD display messages

Possible problems

Recommended actions

Energy Invalid for Flow
Configuration

The energy flow variable is not
compatible with the current
flow configuration but is
mapped to the totalizer, a
process variable, or a burst
variable.

These discrepancies can be fixed
with the following actions:
Verify configuration for the fluid
type supports Energy Flow
calculation.
Do not specify energy flow for the
totalizer, process variables or burst
variables unless the transmitter
has a compatible flow
configuration.

FLOW INCOMP ERROR

Static Pressure Sensor
Missing

A static pressure sensor is
needed for the current flow
configuration.

Download a flow configuration
that is compatible with the sensors
equipped in the device or replace
the module with a model that
includes a static pressure sensor.

FLOW INCOMP ERROR

Flow Configuration
Download Error

The flow configuration did not
successfully download to the
transmitter.

Re-download the flow
configuration using the
Engineering Assistant software.

Flow Output Out of Limits

The flow output value is
exceeding the flow rate
operating limits.

Verify the process conditions, and
modify the flow configuration
parameters and operating ranges
as needed.

Energy Flow Out of Limits

The energy flow value is
exceeding the flow rate
operating limits.

Verify the process conditions, and
modify the flow configuration
parameters and operating ranges
as needed.

The LCD display is not receiving
updates from the feature board
electronics.

Examine the LCD display
Connector and reset the LCD
display. If the problem persists,
first replace the LCD display then
replace the feature board
electronics if necessary.

FLOW INCOMP ERROR

FLOW LIMIT

FLOW LIMIT

LCD UPDATE ERROR

Host diagnostic message

LCD Update Error

(LCD is blank)

LCD Update Error

The LCD display is no longer
powered.

Examine the LCD display
connector and reset the LCD
display. If the problem persists,
first replace the LCD display then
replace the feature board
electronics if necessary.

PT LIMIT

Process Temperature Out of
Limits

The process temperature sensor
is exceeding the user defined
sensor limits.

Verify the process conditions and
adjust limits if necessary. Check
the process temperature sensor
and replace if necessary.

RVRSE FLOW

Reverse Flow Detected

The transmitter is measuring a
negative differential pressure.

Verify the process conditions and
the transmitter installation.

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Table 5-1. Diagnostic Message Troubleshooting
LCD display messages

Host diagnostic message

Possible problems

Recommended actions

Module Communication
Failure

Communication between the
sensor module and the feature
board electronics have been
lost.

Verify the connection between the
sensor module and the feature
board electronics. Replace the
SuperModule assembly and/or
feature board electronics if
necessary.

SNSR INCOMP ERROR

Sensor Module
Incompatibility

The SuperModule assembly is
not compatible with the feature
board electronics. The
SuperModule assembly is not
equipped with a differential
pressure sensor or it is an older
revision of the sensor module.

Replace the SuperModule
assembly with one that is
compatible with the Rosemount
3051SMV Plantweb™ Housing.

SNSR MISSING ERROR

Sensor Missing

The sensor mapped to the
primary variable is not present.

Remap the primary variable to a
sensor that is present.

SNSRT LIMIT

Sensor Temperature Out of
Limits

The Sensor Module
Temperature is exceeding the
sensor limits.

Verify ambient conditions are
within the sensor limits.

XMTR Info

Non-Volatile Memory
Warning

Transmitter information data is
incomplete. Transmitter
operation will not be affected.

Replace the feature board
electronics at next maintenance
shutdown.

XMTR Info Error

Non-Volatile Memory Error

Non-volatile data of the device is
corrupted.

Replace the feature board
electronics.

(Other message)(1)

Maintenance Required

The transmitter may not be
operating properly and requires
attention.

Check other warning messages.

(Other message)(1)

mA Output Fixed

The 4–20 mA analog output
signal is fixed at a constant value
and is not representative of the
HART primary variable.

Disable loop current mode.

(Other message)(1)

Primary variable out of limits

The primary variable is outside
the range of the transmitter.

View other diagnostic messages to
determine which variable is out of
limits.

(Other message)(1)

Non-primary variable out of
limits

A variable other than the
primary variable is outside the
range of the transmitter.

View other diagnostic messages to
determine which variable is out of
limits.

(LCD is reading normally)

Configuration changed

A modification has been made
to the device configuration
using a host other than AMS
Device Manager.

No action is required; message will
clear after a change is made using
AMS.

(LCD is reading normally)

Cold start

Transmitter was restarted.

No action is required; message will
clear automatically.

SNSR COMM ERROR

1.

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Table 5-2. Transmitter Troubleshooting
Symptom

Corrective actions
Verify power is applied to signal terminals.

Transmitter milliamp output is zero

Check power wires for reversed polarity.
Verify terminal voltage is 12 to 42.4 Vdc.
Check for open diode across test terminal on Rosemount 3051SMV terminal block.
Verify the output is between 4 and 20 mA or saturation levels.

Transmitter not communicating with Field
Communicator, AMS Device Manager, or
Engineering Assistant

Verify clean DC Power to transmitter (Max AC noise 0.2 volts peak to peak).
Check loop resistance, 250–1321 Ω.
Loop Resistance = (Power supply voltage - transmitter voltage)/loop current
Check if unit is at an alternate HART address.
Verify applied process variables.

Transmitter milliamp output is low or high

Verify 4 and 20 mA range points and flow configuration.
Verify output is not in alarm or saturation condition.
An analog output trim or sensor trim may be required.
Check to ensure that the equalization valve is closed.
Check test equipment.

Transmitter will not respond to changes in
measured process variables

Check impulse piping or manifold for blockage.
Verify primary variable measurement is between the 4 and 20 mA set points.
Verify output is not in alarm or saturation condition.
Verify transmitter is not in Loop Test, Multidrop, Test Calculation,
or Fixed Variable mode.
Check test equipment (verify accuracy).

Digital Variable output is low or high

Check impulse piping for blockage or low fill in wet leg.
Verify transmitter sensor trim.
Verify measured variables are within transmitter limits.
Check application for faulty equipment in process line.

Digital Variable output is erratic

Verify transmitter is not reacting directly to equipment turning on/off.
Verify damping is set properly for application.
Verify power source to transmitter has adequate voltage and current.

Milliamp output is erratic

Check for external electrical interference.
Verify transmitter is properly grounded.
Verify shield for twisted pair is only grounded at one end.

Transmitter output is normal, but LCD
display is off and diagnostics indicate an
LCD display problem

Verify LCD display is installed correctly.
Replace LCD display.

Transmitter indicating a flow value and/or
DP value during no flow condition

Zero DP sensor
Verify DP Low Flow Cutoff setting.

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5.3

Measurement quality and limit status
The Rosemount 3051SMV is compliant with the HART Revision 6 Standard. One of the most noticeable
enhancements available with the HART 6 standard is that each variable has a measurement quality and
limit status. These statuses can be viewed in AMS Device Manager, on a Field Communicator, or with any
HART 6 compatible host system. In AMS Device Manager, variable statuses can be viewed by selecting
Variables in the upper left menu tree under the Configure/Setup heading.
Figure 5-1. Quality and Limit Status

A. Measurement quality and limit status

A

Each variable status reading consists of two parts separated by a hyphen; Measurement Quality and Limit
Status.

Possible measurement quality readings
Good – Displayed during normal device operation.
Poor Accuracy – Indicates the accuracy of the variable measurement has been compromised.
Example: The module temperature sensor failed and is no longer compensating the differential pressure
and status pressure measurements.
Bad – Indicates the variable has failed. Example: A differential pressure, static pressure, or process
temperature sensor failure.

Possible limit status readings
Not Limited – Displayed during normal device operation.
High Limited – Indicates the current variable reading has gone above the transmitter’s maximum possible
reading and is no longer representative of the actual variable measurement.
Low Limited – Indicates the current variable reading has gone below the transmitter’s minimum possible
reading and is no longer representative of the actual variable measurement.
Constant – Indicates the variable reading is set to a fixed value. Example: The totalizer has been stopped.
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Engineering Assistant communication
troubleshooting
Table 5-3 identifies the most common communication issues between the Engineering Assistant
software and the Rosemount 3051SMV.

Table 5-3. Corrective Action for Engineering Assistant Communication Problems
Symptom

Corrective action
Loop wiring (HART)

•
•
•
•
No Communication
between the
Engineering Assistant
software and the
Rosemount 3051SMV

HART protocol communication requires a loop resistance value between 250 to 1321 ohms, inclusive.
Check for adequate voltage to the transmitter. See “Load limitations” on page 131.
Check for intermittent shorts, open circuits, and multiple grounds.
Check for capacitance across the load resistor. Capacitance should be less than 0.1 microfarad.

Engineering Assistant

•
•
•
•

Verify correct COM port selected.
Verify laptop computer is not in low energy mode (certain laptops disable all COM ports in low energy mode).
Check if HART modem is properly connected.
Check if HART driver is loaded and installed. If using a HART USB port modem, install drivers from CD-ROM provided
with USB modem.

• Check if another HART configuration program, such as AMS Device Manager, is currently open. Only one HART
configuration program may be opened at a time.

• Verify the COM port buffer setting is set to the lowest setting (1) in the advanced COM port settings and re-boot the
computer.

• Set the Device Address to search All.

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5.5

Measurement troubleshooting
The transmitter provides a means to display the current process variables and flow calculations. If the
process variable reading is unexpected, this section provides the symptoms and possible corrective
actions.

Table 5-4. Unexpected Process Variable (PV) Readings
Symptom

Corrective action
Primary element

• Check for restrictions at the primary element.
• Check the installation and condition of the primary element.
• Note any changes in process fluid properties that may affect output.
Impulse piping

•
•
•
•
•
•
•

Check to ensure the pressure connection is correct.
Check for leaks or blockage.
Check to ensure that blocking valves are fully open.
Check for entrapped gas in liquid lines or for liquid in gas lines.
Check to ensure the density of fluid in impulse lines is unchanged.
Check for sediment in the transmitter process flange.
Make sure that process fluid has not frozen within the process flange.

Power supply

• Check the output voltage of the power supply at the transmitter. It should be 12 to 42.4 V dc for HART with no load at
the transmitter terminals.

High PV Reading

Note
Do not use higher than the specified voltage to check the loop, or damage to the transmitter may result.
Feature board electronics

• Connect a personal computer and use AMS Device Manager, Engineering Assistant Software, or the Field
Communicator to check the sensor limits to ensure calibration adjustments are within the sensor range and that
calibration is correct for the pressure being applied.

• Confirm the electronics housing is properly sealed against moisture.
• If the feature board electronics are still not functioning properly, substitute new feature board electronics.
Flow configuration (fully compensated mass and energy flow feature board only)

• Verify flow configuration is correct for current application
Process temperature RTD input

• Verify all wire terminations
• Verify sensor is a Pt 100 RTD
• Replace Pt 100 sensor
Sensor module

• The sensor module is not field repairable and must be replaced if found to be defective. Check for obvious defects,
such as a punctured isolating diaphragm or fill fluid loss, and contact your nearest Emerson™ Service Center.

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Table 5-4. Unexpected Process Variable (PV) Readings
Symptom

Corrective action
Primary element

• Check the installation and condition of the primary element.
Loop wiring

• Check for adequate voltage to the transmitter. It should be 12 to 42.4 Vdc for HART with no load at the transmitter
terminals.

• Check for intermittent shorts, open circuits, and multiple grounds.
Process pulsation

• Adjust the damping.
Feature board electronics
Erratic PV Reading

• Connect a personal computer and use AMS Device Manager, Engineering Assistant Software, or the Field
Communicator to check the sensor limits to ensure calibration adjustments are within the sensor range and that
calibration is correct for the pressure being applied.

• Confirm the electronics housing is properly sealed against moisture.
• If the feature board electronics are still not functioning properly, substitute new feature board electronics.
Impulse piping

• Check for entrapped gas in liquid lines or for liquid in gas lines.
• Make sure that process fluid has not frozen within the process flange.
• Ensure that block valves are fully open and equalize valves are fully and tightly closed.
Sensor module

• The sensor module is not field repairable and must be replaced if found to be defective. Check for obvious defects,
such as a punctured isolating diaphragm or fill fluid loss, and contact your nearest Emerson Service Center.

Primary element

• Check the installation and condition of the primary element.
Note any changes in process fluid properties that may affect output.

Loop wiring

• Check for adequate voltage to the transmitter. It should be 12 to 42.4 Vdc for HART with no load at the transmitter
terminals.

• Check the milliamp rating of the power supply against the total current being drawn for all transmitters being
powered.

Low PV Reading or No
PV Reading

•
•
•
•

Check for shorts and multiple grounds.
Check for proper polarity at the signal terminal.
Check loop impedance.
Check the wire insulation to detect possible shorts to ground.

Impulse piping

•
•
•
•
•
•

Troubleshooting

Check to ensure the pressure connection is correct.
Check for leaks or blockage.
Check to ensure blocking valves are fully open and that bypass valves are tightly closed.
Check for entrapped gas in liquid lines or for liquid in gas lines.
Check for sediment in the transmitter process flange.
Make sure process fluid has not frozen within the process flange.

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Table 5-4. Unexpected Process Variable (PV) Readings
Symptom

Corrective action
Feature board electronics

• Check the sensor limits to ensure calibration adjustments are within the sensor range and that calibration is correct for
the pressure being applied.

• Confirm the electronics housing is properly sealed against moisture.
• If the feature board electronics are still not functioning properly, substitute new feature board electronics.
Flow configuration (fully compensated mass and energy flow feature board only)
Low PV Reading or No
PV Reading

• Verify flow configuration is correct for current application.
Process temperature RTD input

• Verify all wire terminations
• Verify sensor is a Pt 100 RTD
• Replace Pt 100 sensor
Sensor module

• The sensor module is not field repairable and must be replaced if found to be defective. Check for obvious defects,
such as a punctured isolating diaphragm or fill fluid loss, and contact your nearest Emerson Service Center.

Primary element

• Check for restrictions at the primary element.
Impulse piping

Sluggish Output
Response/Drift

•
•
•
•
•
•

Check for leaks or blockage.
Ensure blocking valves are fully open.
Check for sediment in the transmitter process flange.
Check for entrapped gas in liquid lines and for liquid in gas lines.
Ensure the density of fluid in impulse lines is unchanged.
Make sure process fluid has not frozen within the process flange.

Feature board electronics

• Confirm damping is correctly set.
• Confirm the electronics housing is properly sealed against moisture.
Sensor module

• The sensor module is not field repairable and must be replaced if found to be defective. Check for obvious defects,
such as a punctured isolating diaphragm or fill fluid loss, and contact your nearest Emerson Process Management
Service Center.

• Confirm the electronics housing is properly sealed against moisture.

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Note
The following performance limitations may inhibit efficient or safe operation. Critical applications should
have appropriate diagnostic and backup systems in place.
Pressure transmitters contain an internal fill fluid. It is used to transmit the process pressure through the
isolating diaphragms to the pressure sensor module. In rare cases, oil loss paths in oil-filled pressure
transmitters can be created. Possible causes include: physical damage to the isolator diaphragms,
process fluid freezing, isolator corrosion due to an incompatible process fluid, etc.
A transmitter with oil fill fluid loss may continue to perform normally for a period of time. Sustained oil
loss will eventually cause one or more of the operating parameters to exceed published specifications as
the operating point output continues to drift. Symptoms of advanced oil loss and other unrelated
problems include:

5.6



Sustained drift rate in true zero and span or operating point output or both



Sluggish response to increasing or decreasing pressure or both



Limited output rate or very nonlinear output or both



Change in output process noise



Noticeable drift in operating point output



Abrupt increase in drift rate of true zero or span or both



Unstable output



Output saturated high or low

Service support
To expedite the return process outside of the United States, contact the nearest Emerson representative.
Within the United States, call the Emerson Instrument and Valves Response Center using the
1-800-654-RSMT (7768) toll-free number. This center, available 24 hours a day, will assist 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 process material to which the product was
last exposed.

Individuals who handle products exposed to a hazardous substance can avoid injury if they are informed
of and understand the hazard. 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.
Emerson Instrument and Valves Response Center representatives will explain the additional information
and procedures necessary to return goods exposed to hazardous substances.

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Section 6

Safety Instrumented Systems
Requirements

Safety Instrumented Systems (SIS) Certification . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . .page 119
Rosemount 3051SMV safety certified identification . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . .page 119
Installation in SIS applications . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . .page 119
Configuring in SIS applications . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . .page 120
Rosemount 3051SMV SIS operation and maintenance . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . .page 121
Inspection . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . .page 122

6.1

Safety Instrumented Systems (SIS) Certification
The safety-critical output of the Rosemount 3051SMV is provided through a two-wire, 4–20 mA signal
representing pressure. The Rosemount 3051SMV safety certified pressure transmitter is certified to: Low
Demand; Type B.
SIL 2 for random integrity @ HFT=0
SIL 3 for random integrity @ HFT=1
SIL 3 for systematic integrity
The Rosemount 3051SMV must be installed per manufacturer’s instructions, specifications and the
materials must be compatible with process conditions.
The HART® Protocol is only used for setup, calibration, and diagnostic purposes and is not for safety
critical operation.

6.2

Rosemount 3051SMV safety certified identification
All Rosemount 3051SMV Transmitters must be identified as safety certified before installing into SIS
systems.
To identify a safety certified Rosemount 3051SMV:
1. Verify the model string contains Rosemount 3051SMV and QT.
– If the transmitter was ordered as part of a flowmeter, verify the model string reads Rosemount
3051SFx(1–7) and QT.
2. Verify software revision is 3.

6.3

Installation in SIS applications
Installations are to be performed by qualified personnel. No special installation is required in addition to
the standard installation practices outlined in this document. Always ensure a proper seal by installing
the electronics housing cover(s) so that metal contacts metal.
Environmental and operational limits are available in Appendix A: Specifications and Reference Data
The loop should be designed so the terminal voltage does not drop below 12.0 Vdc when the
transmitter output is set to 23 mA.

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Position the security switch to the ( ) position to prevent accidental or deliberate change of
configuration data during normal operation.

6.4

Configuring in SIS applications
Use any HART capable configuration tool to communicate with and verify configuration of the
Rosemount 3051SMV.
Note
Transmitter output is not safety-rated during the following: configuration changes, multidrop, and loop
test. Alternative means should be used to ensure process safety during transmitter configuration and
maintenance activities.

6.4.1

Damping
User-selected damping will affect the transmitters ability to respond to changes in the applied process.
The damping value + response time must not exceed the loop requirements.
Reference “Damping” on page 132 to change damping value.

6.4.2

Alarm and saturation levels
DCS or safety logic solver should be configured to match transmitter configuration. Figure 6-1 identifies
the three alarm levels available and their operation values.
Figure 6-1. Alarm Levels
Rosemount alarm level
Normal Operation
3.75 mA(1)

3.9 mA
low saturation

20 mA

4 mA

20.8 mA
high saturation

21.75(2)

Namur alarm level
Normal Operation
3.6 mA(1)

3.8 mA
low saturation

20 mA

4 mA

22.5(2)
20.5 mA
high saturation

Custom alarm level
Normal Operation
3.6 - 3.8 mA(1)

4 mA

3.7 - 3.9 mA
low saturation

20 mA
20.1 - 22.9 mA
high saturation

20.2 - 23.0(2)

1. Transmitter Failure, hardware or software alarm in LO position.
2. Transmitter Failure, hardware or software alarm in HI position.

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6.5

Rosemount 3051SMV SIS operation and maintenance

6.5.1

Proof test
The following proof tests are recommended.
All proof test procedures must be carried out by qualified personnel.
Use “Field Communicator Fast Keys” on page 62 to perform a loop test, analog output trim, or sensor
trim. security switch should be in the (
( ) position after execution.

6.5.2

) position during proof test execution and repositioned in the

Partial proof test
The partial suggested proof test consists of a power cycle plus reasonability checks of the transmitter
output. This test will detect ~48% of possible DU failures in the device.
FMEDA report can be found at Emerson.com/Automation-Solutions/Pressure/Rosemount-3051SMV
and look at the certificates and approvals documentation.
Required tools: Field Communicator and mA meter.
1. Bypass the safety function and take appropriate action to avoid a false trip.
2. Use HART communications to retrieve any diagnostics and take appropriate action.
3. Send a HART command to the transmitter to go to the high alarm current output and verify that the
analog current reaches that value.(1) See “Alarm level verification” on page 30.
4. Send a HART command to the transmitter to go to the low alarm current output and verify that the
analog current reaches that value.(2)
5. Perform a “reasonability check” on the pressure sensor reading and the sensor temperature reading
and if applicable the process temperature reading.(3)
6. Remove the bypass and otherwise restore the normal operation.
7. Place the Security switch in the (

6.5.3

) position.

Comprehensive proof test
The comprehensive proof test consists of performing the same steps as the simple suggested proof test
but with a two point calibration of the pressure and temperature sensors in place of the reasonability
check of the sensors. This test will detect ~90% of possible DU failures in the device.
Required tools: Field Communicator and pressure calibration equipment.
1. Bypass the safety function and take appropriate action to avoid a false trip.
2. Use HART communications to retrieve any diagnostics and take appropriate action.
3. Send a HART command to the transmitter to go to the high alarm current output and verify that the
analog current reaches that value.(1) See “Alarm level verification” on page 30.
4. Send a HART command to the transmitter to go to the low alarm current output and verify that the
analog current reaches that value.(2)

1.
2.
3.

This tests for compliance voltage problems such as a low loop power supply voltage or increased wiring resistance. This also tests for other possible
failures.
This tests for possible quiescent current related failures.
This tests for faults in the input multiplexer and A to D converter.

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5. Perform a two-point verification(1) of the transmitter pressure over the full working range (and
process temperature where applicable).
6. Remove the bypass and otherwise restore the normal operation.
7. Place the Security switch in the (

) position.

Note
 The user determines the proof test requirements for impulse piping.


Automatic diagnostics are defined for the corrected % DU: The tests performed internally by the
device during runtime without requiring enabling or programming by the user.

6.6

Inspection

6.6.1

Visual inspection
Not required

6.6.2

Special tools
Not required

6.6.3

Product repair
The Rosemount 3051SMV is repairable with limited replacement options.
All failures detected by the transmitter diagnostics or by the proof-test must be reported. Feedback can
be submitted electronically at Emerson.com/Rosemount/Report-A-Failure
All product repair and part replacement should be performed by qualified personnel.

6.6.4

Rosemount 3051SMV SIS reference
The Rosemount 3051SMV must be operated in accordance to the functional and performance
specifications provided in “Specifications and Reference Data” on page 125.

6.6.5

Failure rate data
The FMEDA report includes failure rates and the assumptions for how these failure rates were derived.
The report is available under Certificates and Approvals at
Emerson.com/Automation-Solutions/Pressure/Rosemount-3051SMV

6.6.6

Failure values
Safety Deviation (defines what is dangerous in a FMEDA): ±2.0% of analog output span
Transmitter response time: provided in “Dynamic performance ambient temperature effect” on
page 127.
Self-diagnostics Test Interval: At least once every 60 minutes

1.
122

If the two-point process temperature verification is performed with electrical instrumentation, this proof test will not detect any failures of the sensor.
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6.6.7

Safety Instrumented Systems Requirements
September 2017

Product life
50 years - based on worst case component wear-out mechanisms - not based on wear-out of process
wetted materials

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Appendix A

Specifications and Reference Data

Specifications . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . page 125
Dimensional drawings . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . page 135
Ordering information . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . page 138
Accessories . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . page 147
Spare parts . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . page 150

A.1 Specifications
A.1.1 Performance specifications
For zero-based spans, reference conditions, silicone oil fill, glass-filled PTFE O-rings, Stainless steel (SST) materials, or
coplanar flange digital trim values set to equal range points.

Conformance to specification (±3σ [Sigma])
Technology leadership, advanced manufacturing techniques, and statistical process control ensure measurement
specification conformance to ±3σ or better.

Reference accuracy(1)
Rosemount
models

Classic MV

Ultra for Flow

3051SMV_ _1: Differential pressure, static pressure, and temperature
3051SMV_ _2: Differential pressure and static pressure
DP Ranges 2–3

±0.04% of span;
For spans less than 10:1,
URL
±  0.01 + 0.004 -------------  % of span

span 

±0.04% of reading up to 8:1
DP turndown from URL;
±(0.04 + 0.0023[URL/RDG(2)])% reading to 200:1
DP turndown from URL(3)

DP Range 1

±0.10% of span;
For spans less than 15:1,

N/A

URL
±  0.025 + 0.005 -------------  % of span
span
AP and GP
Ranges 3–4

Process Temp.
RTD Interface(4)

125

±0.055% of span;
For spans less than 10:1,
URL
±  0.0065 -------------  % of span
span

±0.025% of span;
For spans less than 10:1,
URL
±  0.004 -------------  % of span

span 

±0.67 °F (0.37 °C)

±0.67 °F (0.37 °C)

Specifications and Reference Data

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Rosemount
models

Ultra

Classic

Ultra for Flow

3051SMV_ _3: Differential pressure and temperature
3051SMV_ _4: Differential pressure
Ranges 2–4

±0.025% of span;
For spans less than 10:1,

±0.055% of span;
For spans less than 10:1,
URL 

URL
-  % of span
±  0.005 + 0.0035 -------------  % of span ±  0.015 + 0.005 -----------span
span

Range 5

±0.05% of span;
For spans less than 10:1,

±0.04% of reading up to 8:1
DP turndown from URL;
±(0.04 + 0.0023[URL/RDG(2)])%
reading to 200:1 DP turndown
from URL(3)

URL
±  0.005 + 0.0045 -------------  % of span
span

±0.065% of span;
N/A
For spans less than 10:1,
URL
±  0.015 + 0.005 -------------  % of span

span 

±0.09% of span;
For spans less than 15:1,

±0.10% of span;
For spans less than 15:1,

URL
±  0.015 + 0.005 -------------  % of span
span

URL
± 0.025 + 0.005  ------------- % of span
 span

Range 0

±0.09% of span;
For spans less than 2:1,
±0.045% of URL

±0.10% of span;
For spans less than 2:1,
±0.05% of URL

N/A

Process Temp.
RTD Interface(4)

±0.67 °F (0.37 °C)

±0.67 °F (0.37 °C)

±0.67 °F (0.37 °C)

Range 1

1.
2.
3.
4.

N/A

Stated reference accuracy equations include terminal based linearity, hysteresis, and repeatability, but does not include analog only reference accuracy of ±0.005% of
span.
RDG refers to transmitter DP reading.
Ultra for Flow is only available for Rosemount™ 3051SMV DP Ranges 2–3. For calibrated spans from 1:1 to 2:1 of URL, add ±0.005% of span analog output error.
Specifications for process temperature are for the transmitter portion only. The transmitter is compatible with any Pt 100 (100 ohm platinum) RTD. Examples of
compatible RTDs include Rosemount Series 68 and 78 RTD Temperature Sensors.

Total performance(1)
Models
Rosemount
3051SMV

1.
2.

DP Ranges 2–3

Ultra(1)

Classic and Classic MV

Ultra for Flow(2)

±0.1% of span;
for ±50 °F (28 °C) temperature
changes; 0-100% relative
humidity, up to 740 psi (51 bar)
line pressure (DP only),
from 1:1 to 5:1 rangedown

±0.15% of span;
for ±50 °F (28 °C) temperature
changes; 0-100% relative
humidity, up to 740 psi (51 bar)
line pressure (DP only),
from 1:1 to 5:1 rangedown

±0.1% of reading;
for ±50 °F (28 °C) temperature
changes; 0-100% relative
humidity, up to 740 psi (51 bar)
line pressure,
over 8:1 DP turndown from URL

Total performance is based on combined errors of reference accuracy, ambient temperature effect, and line pressure effect. Specifications apply only to differential
pressure measurement.
Ultra for Flow is only available for Rosemount 3051SMV DP Ranges 2–3.

Multivariable flow performance(1)
Mass, energy, actual volumetric, and totalized flow reference accuracy(2)
Models(1)(2)
Rosemount
3051SMV

1.
2.

Ultra for Flow

Classic MV

DP Ranges 2–3

±0.65% of flow rate over a 14:1 flow range
(200:1 DP range)

±0.70% of flow rate over 8:1 flow range
(64:1 DP range)

DP Range 1

N/A

±0.90% of flow rate over 8:1 flow range
(64:1 DP range)

Applies to the 3051SMV_M Multivariable™ type only. Flow performance specifications assume device is configured for full compensation of static pressure, process
temperature, density, viscosity, gas expansion, discharge coefficient, and thermal correction variances over a specified operating range.
Uncalibrated differential producer (0.2 < beta < 0.6 Orifice) installed per ASME MFC 3M or ISO 5167-1. Uncertainties for discharge coefficient, producer bore, tube
diameter, and gas expansion factor as defined in ASME MFC 3M or ISO 5167-1. Reference accuracy does not include RTD sensor accuracy.

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Long term stability
Models
Rosemount
3051SMV

DP Ranges 2–5 AP
and GP Ranges 3–4

Ultra and Ultra for Flow(1)

Classic and Classic MV

±0.15% of URL for 15 years;
for ±50 °F (28 °C) temperature changes,
up to 1000 psi (68,9 bar) line pressure

±0.20% of URL for 15 years;
for ±50 °F (28 °C) temperature changes,
up to 1000 psi (68,9 bar) line pressure

Process Temperature RTD Interface(2) The greater of ±0.185 °F (0.103 °C) or 0.1% of reading per year (excludes RTD sensor stability).
1.
2.

Ultra is only available for Rosemount 3051SMV_ _3, 4. Ultra for Flow is only available for Rosemount 3051SMV DP Ranges 2-3.
Specifications for process temperature are for the transmitter portion only. The transmitter is compatible with any Pt 100 (100 ohm platinum) RTD. Examples of
compatible RTDs include Rosemount Series 68 and 78 RTD Temperature Sensors.

Warranty(1)
Models

Ultra and Ultra for Flow

Classic and Classic MV

Rosemount 3051S Scalable Products 12-year limited warranty(2)
1.
2.
3.

1-year limited warranty(3)

Warranty details can be found in Emerson™ Terms & Conditions of Sale, Document 63445, Rev G (10/06).
Rosemount Ultra and Ultra for Flow transmitters have a limited warranty of twelve (12) years from date of shipment. All other provisions of Emerson standard limited
warranty remain the same.
Goods are warranted for twelve (12) months from the date of initial installation or eighteen (18) months from the date of shipment by seller, whichever period expires
first.

Dynamic performance ambient temperature effect
4–20 mA (HART®)(1)

Typical transmitter response time

Total response time (Td + Tc)(2)

Transmitter Output vs. Time

3051SMV_ _1: DP, SP, & T
3051SMV_ _2: DP & SP:
DP Range 1:
DP Range 2:
DP Range 3:
AP and GP:

Pressure released
310 milliseconds
170 milliseconds
155 milliseconds
240 milliseconds

Td

Td = Dead time
Tc = Time constant
Tc

Response time = Td + Tc

100%

3051SMV_ _3: DP & T
3051SMV_ _4: DP:
DP Ranges 2–5:
DP Range 1:
DP Range 0:

145 milliseconds
300 milliseconds
745 milliseconds

0%

Dead time (Td)
DP:
AP and GP:
Process Temp. RTD Interface:

63.2% of total
step change

36.8%

Time

100 milliseconds
140 milliseconds
1 second

Update rate
Measured Variables:
DP:
AP and GP:
Process Temp. RTD Interface:

22 updates per second
11 updates per second
1 update per second

Calculated Variables:
Mass or Volumetric Flow Rate:
Energy Flow Rate:
Totalized Flow:
1.
2.

127

22 updates per second
22 updates per second
1 update per second

Dead time and update rate apply to all models and ranges; analog output only.
Nominal total response time at 75 °F (24 °C) reference conditions.

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Ambient temperature effect
Rosemount
models

Ultra
per 50 °F (28 °C)

Classic or Classic MV
per 50 °F (28 °C)

Ultra for Flow(1)
–40 to 185 °F (–40 to 85 °C)

3051SMV_ _1: Differential pressure, static pressure, and temperature
3051SMV_ _2: Differential pressure and static pressure
DP Ranges 2–3

N/A

± (0.0125% URL + 0.0625% span)
from 1:1 to 5:1;
± (0.025% URL + 0.125% span) for
> 5:1

±0.13% reading up to 8:1 DP turndown
from URL;
±(0.13 + 0.0187 [URL/RDG(3)])% reading
to 100:1 DP turndown from URL

DP Range 1

N/A

± (0.1% URL + 0.25% Span)
from 1:1 to 50:1

N/A

AP and GP

N/A

± (0.0125% URL + 0.0625% span)
from 1:1 to 10:1;
± (0.025% URL + 0.125% span) for
>10:1

± (0.009% URL + 0.025% span)
from 1:1 to 10:1;
± (0.018% URL + 0.08% span)
for > 10:1

3051SMV_ _ 3: Differential pressure and temperature
3051SMV_ _ 4: Differential pressure
Range 2–5(2)

± (0.009% URL + 0.025% span)
from 1:1 to 10:1;
± (0.018% URL + 0.08% span)
from >10:1 to 200:1

± (0.0125% URL + 0.0625% span)
from 1:1 to 5:1;
± (0.025% URL + 0.125% span)
from >5:1 to 100:1

±0.13% reading up to 8:1 DP turndown
from URL;
±(0.13 + 0.0187 [URL/RDG(3)])% reading
to 100:1 DP turndown from URL

Range 0

± (0.25% URL + 0.05% span)
from 1:1 to 30:1

± (0.25% URL + 0.05% span)
from 1:1 to 30:1

N/A

Range 1

± (0.1% URL + 0.25% span)
from 1:1 to 50:1

± (0.1% URL + 0.25% span)
from 1:1 to 50:1

N/A

Process Temp.
RTD Interface(4)

N/A

±0.39 °F (0,216 °C)
per 50 °F (28 °C)

±0.39 °F (0,216 °C)
per 50 °F (28 °C)

1.
2.
3.
4.

Ultra for Flow is only available for Rosemount 3051SMV DP Ranges 2–3.
Use classic specification for Rosemount 3051SMV DP Range 5 Ultra.
RDG refers to transmitter reading.
Specifications for process temperature are for the transmitter portion only. The transmitter is compatible with any Pt 100 (100 ohm platinum) RTD. Examples of
compatible RTDs include Rosemount Series 68 and 78 RTD Temperature Sensors.

Line Pressure effect(1)
Models(1)

Ultra and Ultra for Flow

Classic and Classic MV

Rosemount 3051SMV: Differential pressure measurement only

Zero error(2)
Range 2–3
Range 0
Range 1

± 0.025% URL per 1000 psi (69 bar)
± 0.125% URL per 100 psi (6,89 bar)
± 0.25% URL per 1000 psi (69 bar)

± 0.05% URL per 1000 psi (69 bar)
± 0.125% URL per 100 psi (6,89 bar)
± 0.25% URL per 1000 psi (69 bar)

± 0.1% of reading per 1000 psi (69 bar)
± 0.15% of reading per 100 psi (6,89 bar)
± 0.4% of reading per 1000 psi (69 bar)

± 0.1% of reading per 1000 psi (69 bar)
± 0.15% of reading per 100 psi (6,89 bar)
± 0.4% of reading per 1000 psi (69 bar)

Span error(3)
Range 2–3
Range 0
Range 1
1.
2.
3.

For zero error specifications for line pressures above 2000 psi (137,9 bar) or line pressure effect specifications for DP Ranges 4–5, see the Rosemount 3051SMV
Reference Manual.
Zero error can be zeroed.
Specifications for option code P0 are two times those shown above.

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Mounting position effects
Rosemount models

Ultra, Ultra for Flow, Classic, and Classic MV

3051SMV_ _ 1, 2

Zero shifts up to ±1.25 inH2O (3,11 mbar), which can be zeroed; no span effect
Zero shifts to ±2.5 inH2O (6,22 mbar), which can be zeroed; no span effect

DP:
AP/GP:

3051SMV_ _ 3, 4

Zero shifts up to ±1.25 inH2O (3,11 mbar), which can be zeroed; no span effect

Electro Magnetic Compatibility (EMC)(1)

Vibration effect

Meets all relevant requirements of EN 61326 and NAMUR NE-21.

Less than ±0.1% of URL when tested per the requirements of
IEC60770-1 field or pipeline with high vibration level(10–60
Hz 0.21mm displacement peak amplitude/60–2000 Hz 3g).

1.

Requires shielded cable for both temperature and loop wiring.

Transient protection (Option T1)

For housing style codes 1J, 1K, and 1L:
Less than ±0.1% of URL when tested per the requirements of
IEC60770-1 field with general application or pipeline with
low vibration level (10–60 Hz 0.15mm displacement peak
amplitude/
60–500 Hz 2g).

6 kV crest (0.5 μs - 100 kHz)
3 kA crest (8 ⫻ 20 microseconds)
6 kV crest (1.2 ⫻ 50 microseconds)

Power supply effect

SWC 2.5 kV crest, 1.0 MHz wave form

Meets IEEE C62.41.2-2002, location category B

Meets IEEE C37.90.1-2002 surge withstand capability

Less than ±0.005% of calibrated span per volt change in
voltage at the transmitter terminals

A.1.2 Functional specifications
Range and sensor limits
Range

Table A-1. Rosemount 3051SMV Differential Pressure Range and Sensor Limits

Ultra and Ultra for Flow

Classic and classic MV

Upper (URL)

Lower (LRL)(1)

0

0.1 inH2O (0,25 mbar)

0.1 inH2O (0,25 mbar)

3.0 inH2O (7,5 mbar)

–3.0 inH2O (–7,5 mbar)

1

0.5 inH2O (1,24 mbar)

0.5 inH2O (1,24 mbar)

25.0 inH2O (62,3 mbar)

–25.0 inH2O (–62,3 mbar)

2

1.3 inH2O (3,11 mbar)

2.5 inH2O (6,23 mbar)

250.0 inH2O (0,62 bar)

–250.0 inH2O (–0,62 bar)

3

5.0 inH2O (12,4 mbar)

10.0 inH2O (24,9 mbar)

1000.0 inH2O (2,49 bar)

–1000.0 inH2O (–2,49 bar)
–300.0 psi (–20,7 bar)(2)
– 2000.0 psi (–137,9 bar)

Minimum span

Range limits

4

1.5 psi (103,4 mbar)

3.0 psi (206,8 mbar)

300.0 psi (20,7 bar)(2)

5

10.0 psi (689,5 mbar)

20.0 psi (1,38 bar)

2000.0 psi (137,9 bar)

1.
2.

129

Lower (LRL) is 0 inH2O (0 mbar) for Ultra for Flow.
For measurement type 1 and 2, URL = 150.0 psi (10,34 bar) and LRL = –150.0 psi (10,34 bar).

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Range

Table A-2. Rosemount 3051SMV Static Pressure Range and Sensor Limits

Ultra for Flow

Classic MV

Upper (URL)

Lower (LRL) (Absolute)

Lower (LRL)(Gage)(1)(2)

3

4.0 psi (276 mbar)

8.0 psi (552 mbar)

800 psi (55,16 bar)

0.5 psia (34,5 mbar)

–14.2 psig (–0,98 bar)

4

18.13 psi (1,25 bar)

36.26 psi (2,50 bar)

3626 psi (250.0 bar)(3)

0.5 psia (34,5 mbar)

–14.2 psig (–0,98 bar)

1.
2.
3.

Minimum span

Range limits

Assumes atmospheric pressure of 14.7 psig (1 bar).
Inert fill: Minimum pressure = 1.5 psia (0,10 bar) or -13.2 psig (-0,91 bar).
For SP Range 4 and DP Range 1, the URL is 2000 psi (137,9 bar).

Table A-3. Process Temperature RTD Interface Range Limits(1)

1.

Minimum Span

Upper (URL)

Lower (LRL)

50 °F (28 °C)

1562 °F (850 °C)

–328 °F (–200 °C)

Designed to accommodate a Pt 100 RTD sensor. Examples of compatible RTDs include Rosemount Series 68 and 78 RTD Temperature Sensors.

Service
Rosemount 3051SMV_P (direct process variable output)
Liquid, gas, and vapor applications

Rosemount 3051SMV_M (mass and energy flow output)
Some fluid types are only supported by certain measurement types

Fluid compatibility with pressure and temperature
compensation

• Available

— Not available

Fluid types
Ordering code Measurement type
Liquids

Saturated steam

Superheated steam Gas and natural gas

1

DP/P/T (full compensation)

•

•

•

•

2

DP/P

•

•

•

•

3

DP/T

•

•

—

—

4

DP only

•

•

—

—

4–20 mA/HART
Zero and span adjustment

Power supply
External power supply required.
Rosemount 3051SMV: 12 to 42.4 Vdc with no load

Zero and span values can be set anywhere within the
range.
Span must be greater than or equal to the minimum
span.

Output
Two-wire 4–20 mA is user-selectable for linear or square
root output. Digital process variable superimposed on
4–20 mA signal, available to any host that conforms to
the HART Protocol.
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Static pressure limit

Load limitations
Maximum loop resistance is determined by the voltage
level of the external power supply, as described by:
Rosemount 3051SMV Transmitter
Maximum loop resistance = 43.5 ⫻ (Power supply voltage – 12.0)

Load (Ohms)

1322

Rosemount 3051SMV_ _1: Differential and
Static Pressure, temperature
Rosemount 3051SMV_ _2: Differential
Pressure and Static Pressure
Operates within 0.5 psia (0,03 bar) and the values in the
table below:

1000
500

Differential Pressure

Operating
Region

Static Pressure
Range 1

Range 2

Range 3

Range 3 GP/AP

800 psi
(57,91 bar)

800 psi
(57,91 bar)

800 psi
(57,91 bar)

Range 4 GP/AP

2000 psi
(137,9 bar)

3626 psi
(250 bar)

3626 psi
(250 bar)

0
12.0

20

30

42.4

Voltage (Vdc)

The Field Communicator requires a minimum loop resistance of 250Ω
for communication.

Overpressure limits
Transmitters withstand the following limits without
damage:

Rosemount 3051SMV_ _1: Differential and
Static Pressure, temperature
Rosemount 3051SMV_ _2: Differential
Pressure and Static Pressure

Rosemount 3051SMV_ _ 3: Differential
Pressure and temperature
Rosemount 3051SMV_ _ 4: Differential
Pressure
Operates within specifications between static line pressures
of 0.5 psia and 3626 psig;
Option code P9

4500 psig (310,3 bar)

Option code P0 (classic only)

6092 psig (420 bar)

Range 0

0.5 psia to 750 psig
(0,03 to 51,71 bar)

Range 1

0.5 psia to 2000 psig
(0,03 to 137,9 bar)

Differential Pressure
Static Pressure
Range 1

Range 2

Range 3

Range 3 GP/AP

1600 psi
(110,3 bar)

1600 psi
(110,3 bar)

1600 psi
(110,3 bar)

Range 4 GP/AP

2000 psi
(137,9 bar)

3626 psi
(250 bar)

3626 psi
(250 bar)

Rosemount 3051SMV_ _ 3: Differential
Pressure and temperature
Rosemount 3051SMV_ _ 4: Differential
Pressure
Range 0

750 psi (51,7 bar)

Range 1

2000 psig (137,9 bar)

Ranges 2–5

3626 psig (250,0 bar)

Option code P9

4500 psig (310,3 bar)

Option code P0 (classic only)

6092 psig (420 bar)

131

Burst pressure limits
Rosemount 3051SMV with coplanar or
traditional process flange
10000 psig (689,5 bar)

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Temperature limits
Ambient


–40 to 185 °F (–40 to 85 °C)



with LCD display (1): –40 to 175 °F (–40 to 80 °C)



with option code P0: –20 to 185 °F (–29 to 85 °C)



–50 to 185 °F (–46 to 85 °C)



with LCD display: –40 to 185 °F (–40 to 85 °C)



with wireless output: –40 to 185 °F (–40 to 85 °C)

Process temperature limits
At atmospheric pressures and above:
Silicone fill sensor(2)(3)

2.

3.
4.
5.
6.
7.

Analog output response to a step change is user-selectable
from 0 to 60 seconds for one time constant. Each variable
can be individually adjusted. This software damping is in
addition to sensor module response time.

Failure mode alarm

Storage

1.

Damping

with coplanar flange

–40 to 250 °F (–40 to 121 °C)(4)

with traditional flange

–40 to 300 °F (–40 to 149 °C)(4)(5)

with level flange

–40 to 300 °F (–40 to 149 °C)(4)

with Rosemount 305
Integral Manifold

–40 to 300 °F (–40 to 149 °C)(4)(5)

Inert fill sensor(2)(6)

–40 to 185 °F (–40 to 85 °C)(7)

CD display may not be readable and LCD display updates will be slower at
temperatures below –4 °F (–20 °C).
Process temperatures above 185 °F (85 °C) require derating the ambient
limits by a 1.5:1 ratio. For example, for process temperature of 195 °F
(91 °C), new ambient temperature limit is equal to 170 °F (77 °C). This can be
determined as follows:
(195 °F –185 °F) ⫻ 1.5 = 15 °F,
185 °F–15 °F = 170 °F
212 °F (100 °C) is the upper process temperature limit for DP Range 0.
220 °F (104 °C) limit in vacuum service; 130 °F (54 °C) for pressures below 0.5
psia.
–20 °F (–29 °C) is the lower process temperature limit with option code P0.
32 °F (0 °C) is the lower process temperature limit for DP Range 0.
For Rosemount 3051SMV_ _ 1, 2, 140 ° F (60 °C) limit in vacuum service.

If self-diagnostics detect a gross transmitter failure, the
analog signal will be driven offscale to alert the user.
Rosemount standard (default), NAMUR, and custom alarm
levels are available (see Table A-4).
High or low alarm signal is software-selectable or
hardware-selectable via the optional switch (option D1).
Table A-4. Alarm Configuration
High alarm

Low alarm

Default

≥ 21.75 mA

≤ 3.75 mA

NAMUR compliant(1)

≥ 22.5 mA

≤ 3.6 mA

20.2–23.0 mA

3.6–3.8 mA

Custom levels(2)
1.
2.

Analog output levels are compliant with NAMUR recommendation NE 43,
see option codes C4 or C5.
Low alarm must be 0.1 mA less than low saturation and high alarm must be
0.1 mA greater than high saturation.

A.1.3 Physical specifications
Electrical connections
/ –14 NPT, G1/2, and M20 ⫻ 1.5 (CM20) conduit. HART
interface connections fixed to terminal block.

1 2

Humidity limits

Process connections

0–100 percent relative humidity

 1/4–18 NPT on 21/8-in. centers

Turn-on time
Performance within specifications less than five seconds for
Rosemount 3051SMV (typical) after power is applied to the
transmitter.

 1/2–14 NPT and RC 1/2 on 2-in.(50.8 mm),

21/8-in. (54.0 mm), or 21/4-in. (57.2 mm) centers (process
adapters)

Volumetric displacement
Less than 0.005 in3 (0,08 cm3)

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Process-wetted parts

Paint
Polyurethane

Process isolating diaphragms


316L SST (UNS S31603)

Cover O-rings



Alloy C-276 (UNS N10276)

Buna-N



Alloy 400 (UNS N04400)



Tantalum (UNS R05440)



Gold-plated Alloy 400



Gold-plated 316L SST

Drain/vent valves
316 SST, Alloy C-276, or Alloy 400/K-500 material
(Drain vent seat: alloy 400, drain vent stem: Alloy K-500)

Process flanges and adapters


Plated carbon steel



SST: CF-8M (Cast 316 SST) per ASTM A743



Cast C-276: CW-12MW per ASTM A494



Cast Alloy 400: M-30C per ASTM A494

Shipping weights for Rosemount 3051S
MultiVariable Transmitter (3051SMV)
Rosemount 3051SMV with Plantweb™ housing: 6.7 lb
(3,1 kg)
Table A-5. Transmitter Option Weights
Option
code

Option

Add
lb (kg)

1J, 1K, 1L

SST Plantweb housing

3.5 (1,6)

1A, 1B, 1C

Aluminum Plantweb housing

1.1 (0,5)

M5(1)

LCD display for Aluminum Plantweb
housing

0.8 (0,4)

LCD display for SST Plantweb housing

1.6 (0,7)

Wetted O-rings

B4

SST mounting bracket for coplanar
flange

1.2 (0,5)

Glass-filled PTFE
(Graphite-filled PTFE with isolating diaphragm code 6)

B1, B2, B3

Mounting bracket for traditional flange

1.7 (0,8)

B7, B8, B9

Mounting bracket for traditional flange
with SST bolts

1.7 (0,8)

BA, BC

SST bracket for traditional flange

1.6 (0,7)

B4

SST mounting bracket for In-Line

1.3 (0,6)

F12, F22(2)

SST traditional flange with SST drain
vents

3.2 (1,5)

F13, F23(2)

Cast C-276 traditional flange with alloy
C-276 drain vents

3.6 (1,6)

E12, E22(2)

SST coplanar flange with SST drain
vents

1.9 (0,9)

F14, F24(2)

Cast alloy 400 traditional flange with
alloy 400/K-500 drain vents

3.6 (1,6)

F15, F25(2)

SST traditional flange with alloy C-276
drain vents

3.2 (1,5)

G21

Level flange—3-in., 150

12.6 (5,7)

G22

Level flange—3-in., 300

15.9 (7,2)

G11

Level flange—2-in., 150

6.8 (3,1)

G12

Level flange—2-in., 300

8.2 (3,7)

G31

DIN Level flange, SST, DN 50, PN 40

7.8 (3,5)

DIN Level flange, SST, DN 80, PN 40

13.0 (5,9)

Non-wetted parts
Electronics housing




Low-copper aluminum alloy or SST: CF-3M (Cast 316L SST)
or CF-8M (Cast 316 SST)
NEMA® 4X, IP 66, IP 68 (66 ft. [20 m] for 168 hours)

Coplanar sensor module housing
SST: CF-3M (Cast 316L SST)

Bolts


Plated carbon steel per ASTM A449, Type 1



Austenitic 316 SST per ASTM F593



ASTM A453, Class D, Grade 660 SST



ASTM A193, Grade B7M alloy steel



ASTM A193, Class 2, Grade B8M SST



Alloy K-500

Sensor module fill fluid
Silicone or inert halocarbon

G41
1.
2.

133

Includes LCD display and display cover.
Includes mounting bolts.

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Item

Weight in lb (kg)

Aluminum standard cover

0.4 (0,2)

SST standard cover

1.3 (0,6)

Aluminum display cover

0.7 (0,3)

SST display cover

1.5 (0,7)

LCD display(1)

0.1 (0,04)

Plantweb terminal block

0.2 (0,1)

1.

Display only.

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A.2 Dimensional drawings
Process adapters (option D2) and Rosemount 305 integral manifolds must be ordered with the transmitter.
Figure A-1. Plantweb Housing with Coplanar™ SuperModule™ Platform and Rosemount 305 Coplanar Integral
Manifold
4.51
(115)

4.20
(107)

8.57
(218)

9.67
(246)

6.55
(166)
Dimensions are in inches (millimeters).

Figure A-2. Coplanar Flange Mounting Configurations
Pipe mount

Panel mount
4.51
(115)

6.15
(156)
6.25
(159)

2.81
(71)
3.54
(90)

4.73
(120)

Dimensions are in inches (millimeters).

135

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Figure A-3. Plantweb Housing with Coplanar SuperModule Platform and Rosemount 305 Traditional Integral
Manifold

A

1.63
(41)
C

3.56
B
(90)
max open
1.16
(29)

3.40
(86)

1.10
(28)
6.80 (173)
max open

2.13
(54)
9.72 (247)
max open

2.70
(69)

A. 1/2–14 NPT on mounting adapters
B. Drain vent valve
C. 1/4–18 NPT
Dimensions are in inches (millimeters).

Figure A-4. Plantweb Housing with Coplanar SuperModule Platform and Traditional Flange

9.30
(236)

1.63
(41)
3.40
(86)

1.10
(28)

2.13
(54)

Dimensions are in inches (millimeters).

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Figure A-5. Traditional Flange Mounting Configurations
Pipe mount Rosemount 305 Integral manifold
3.56 (90)
max open

8.10
(206)

Panel mount
10.71
(272)

1.10
(28)

2.62
(67)

3.42
(87)

2.62
(67)

7.70
(196)

0.93
(24)

13.03
(331)

4.85
(123)
3.56 (90)
max open

1.10
(28)

3.40
(86)

1.94
(49)
7.70
(196)

5.32
(135)

Dimensions are in inches (millimeters).

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A.3 Ordering information
A.3.1 Rosemount 3051S MultiVariable Transmitter
Table A-6. Rosemount 3051S Scalable MultiVariable Transmitter Ordering Information
The starred offerings (★) represent the most common options and should be selected for best delivery. The non-starred offerings are subject to
additional delivery lead time.

Rosemount
Transmitter type
model
3051SMV

Scalable MultiVariable Transmitter

Performance class
Rosemount 3051SMV multivariable SuperModule, measurement types 1 and 2
3(1)

Ultra for Flow: 0.04% reading DP accuracy, 200:1 rangedown,15-year stability, 12-year limited warranty

★

5

Classic MV: 0.04% span DP accuracy, 100:1 rangedown, 15-year stability

★

Rosemount 3051SMV single variable SuperModule, measurement types 3 and 4
1(2)

Ultra: 0.025% span DP accuracy, 200:1 rangedown, 10-year stability, 12-year limited warranty

★

2

Classic: 0.055% span DP accuracy, 100:1 rangedown, 5-year stability

★

3(1)

Ultra for Flow: 0.04% reading DP accuracy, 200:1 rangedown,10-year stability, 12-year limited warranty

★

Multivariable type
M

Multivariable measurement with fully compensated mass and energy flow

★

P

Multivariable measurement with direct process variable output

★

Measurement type
1

Differential pressure, static pressure, and temperature

★

2

Differential pressure and static pressure

★

3

Differential pressure and temperature

★

4

Differential pressure

★

Differential pressure range
0(2)(3)

–3 to 3 inH2O (–7,47 to 7,47 mbar)

★

1

–25 to 25 inH2O (–62,2 to 62,2 mbar)

★

2

–250 to 250 inH2O (–623 to 623 mbar)

★

3

–1000 to 1000 inH2O (–2,5 to 2,5 bar)

★

4

–300 to 300 psi (–20,7 to 20,7 bar)

★

5

–2000 to 2000 psi (–137,9 to 137,9 bar)

★

Static pressure type
N(4)

None

★

A

Absolute

★

G

Gage

★

Static pressure range

Absolute

Gage

N(4)

None

N/A

N/A

★

3

Range 3

0.5 to 800 psia (0,03 to 55,2 bar)

–14.2 to 800 psig (–0,98 to 55,2 bar)

★

4(5)

Range 4

0.5 to 3626 psia (0,03 to 250 bar)

–14.2 to 3626 psig (–0,98 to 250 bar)

★

Temperature input
N(6)

None

★

R(7)

RTD input (type Pt 100, –328 to 1562 °F [–200 to 850 °C])

★

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Table A-6. Rosemount 3051S Scalable MultiVariable Transmitter Ordering Information
The starred offerings (★) represent the most common options and should be selected for best delivery. The non-starred offerings are subject to
additional delivery lead time.

Isolating diaphragm
2(8)

316L SST

★

3(8)

Alloy C-276

★

5(9)

Tantalum

7

Gold-Plated 316L SST

Process connection

Size

Material type
Flange material Drain vent

Bolting

000

None

★

A11(10)

Assemble to Rosemount 305/306 Integral Manifold

★

A12(10)

Assemble to Rosemount 304 or AMF Manifold with SST traditional flange

★

B11(10)(11)

Assemble to one Rosemount 1199 Seal

★

B12(10)(11)

Assemble to two Rosemount 1199 Seals

★

C11(10)

Assemble to Rosemount 405 Primary Element

★

D11(10)

Assemble to Rosemount 1195 Integral orifice and Rosemount 305 Integral Manifold

★

EA2(10)

Assemble to Rosemount Annubar™ Primary Element
with coplanar flange

SST

316 SST

N/A

★

EA3(10)

Assemble to Rosemount Annubar Primary Element
with coplanar flange

Cast C-276

Alloy C-276

N/A

★

EA5(10)

Assemble to Rosemount Annubar Primary Element
with coplanar flange

SST

Alloy C-276

N/A

★

E11

Coplanar flange

1 4

/ –18 NPT

Carbon Steel (CS)

316 SST

N/A

★

E12

Coplanar flange

1 4

/ –18 NPT

SST

316 SST

N/A

★

E13(8)

Coplanar flange

1 4

/ –18 NPT

Cast C-276

Alloy C-276

N/A

★

E14

Coplanar flange

1 4

/ –18 NPT

Cast alloy 400

Alloy 400/K-500

N/A

★

E15(8)

Coplanar flange

1 4

/ –18 NPT

SST

Alloy C-276

N/A

★

E16(8)

Coplanar flange

1 4

/ –18 NPT

CS

Alloy C-276

N/A

★

E21

Coplanar flange

RC 1/4

CS

316 SST

N/A

★

E22

Coplanar flange

RC /

SST

316 SST

N/A

★

E23(8)

Coplanar flange

RC 1/4

Cast C-276

Alloy C-276

N/A

★

E24

Coplanar flange

RC /

Cast alloy 400

Alloy 400/K-500

N/A

★

E25(8)

Coplanar flange

RC 1/4

SST

Alloy C-276

N/A

★

E26(8)

Coplanar flange

RC /

F12

Traditional flange

1 4

F13(8)

Traditional flange

1 4

F14

Traditional flange

1 4

F15(8)
F22

1 4

1 4

CS

Alloy C-276

N/A

★

/ –18 NPT

SST

316 SST

N/A

★

/ –18 NPT

Cast C-276

Alloy C-276

N/A

★

/ –18 NPT

Cast alloy 400

Alloy 400/K-500

N/A

★

Traditional flange

1 4

/ –18 NPT

SST

Alloy C-276

N/A

★

Traditional flange

RC 1/4

SST

316 SST

N/A

★

F23(8)

Traditional flange

RC /

Cast C-276

Alloy C-276

N/A

★

F24

Traditional flange

RC 1/4

Cast alloy 400

Alloy 400/K-500

N/A

★

F25(8)

Traditional flange

RC /

SST

Alloy C-276

N/A

★

F52

DIN-compliant traditional
flange

1 4

SST

316 SST

7 16

G11

Vertical mount level flange

2-in. ANSI class 150

SST

N/A

N/A

139

1 4

1 4

1 4

/ –18 NPT

/ -in. bolting

★
★

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Table A-6. Rosemount 3051S Scalable MultiVariable Transmitter Ordering Information
The starred offerings (★) represent the most common options and should be selected for best delivery. The non-starred offerings are subject to
additional delivery lead time.

G12

Vertical mount level flange

2-in. ANSI class 300

SST

N/A

N/A

★

G14(8)

Vertical mount level flange

2-in. ANSI class 150

Cast C-276

N/A

N/A

★

G15(8)

Vertical mount level flange

2-in. ANSI class 300

Cast C-276

N/A

N/A

★

G21

Vertical mount level flange

3-in. ANSI class 150

SST

N/A

N/A

★

G22

Vertical mount level flange

3-in. ANSI class 300

SST

N/A

N/A

★

G31

Vertical mount level flange

DIN- DN 50 PN 40

SST

N/A

N/A

★

EB6

Assemble to primary element with manifold and coplanar flange, CS, Alloy C-276

F32

Bottom vent traditional
flange

1 4

SST

316 SST

N/A

F42

Bottom vent traditional
flange

RC 1/4

SST

316 SST

N/A

F62

DIN-compliant traditional
flange

1 4

/ –18 NPT

SST

316 SST

M10 bolting

F72

DIN-compliant traditional
flange

1 4

/ –18 NPT

SST

316 SST

M12 bolting

G41

Vertical mount level flange

DIN- DN 80 PN 40

SST

N/A

N/A

/ –18 NPT

Transmitter output
A

★

4–20 mA with digital signal based on HART Protocol

Housing style

Material

Conduit entry size

1A

Plantweb housing

Aluminum

1 2

/ –14 NPT

★

1B

Plantweb housing

Aluminum

M20 ⫻ 1.5

★

1J

Plantweb housing

SST

1 2

/ –14 NPT

★

1K

Plantweb housing

SST

M20 ⫻ 1.5

★

1C

Plantweb housing

Aluminum

G1/2

1L

Plantweb housing

SST

G1/2

Options (include with selected model number)
RTD cable (RTD sensor must be ordered separately)
C12

RTD input with 12 ft. (3,66 m) of shielded cable

★

C13

RTD input with 24 ft. (7,32 m) of shielded cable

★

C14

RTD input with 75 ft. (22,86 m) of shielded cable

★

C20(12)

RTD input with 27-in. (69 cm) of armored shielded cable

★

C21

RTD input with 4 ft. (1,22 m) of armored shielded cable

★

C22

RTD input with 12 ft. (3,66 m) of armored shielded cable

★

C23

RTD input with 24 ft. (7,32 m) of armored shielded cable

★

C24

RTD input with 75 ft. (22,86 m) of armored shielded cable

★

C30(12)

RTD input with 25-in. (64 cm) of ATEX/IECEx Flameproof cable

★

C32

RTD input with 12 ft. (3,66 m) of ATEX/IECEx Flameproof cable

★

C33

RTD input with 24 ft. (7,32 m) of ATEX/IECEx Flameproof cable

★

C34

RTD input with 75 ft. (22,86 m) of ATEX/IECEx Flameproof cable

★

C40(12)

RTD input with 34-in. (86,36 cm) shielded cable and 24-in. (60,96 cm) FM Approved coupling flex

★

C41(12)

RTD input with 40-in. (101,60 cm) shielded cable and 30-in. (76,20 cm) FM Approved coupling flex

★

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Table A-6. Rosemount 3051S Scalable MultiVariable Transmitter Ordering Information
The starred offerings (★) represent the most common options and should be selected for best delivery. The non-starred offerings are subject to
additional delivery lead time.

Mounting brackets(13)
B4

Coplanar flange bracket, all SST, 2-in. pipe and panel

★

B1

Traditional flange bracket, CS, 2-in. pipe

★

B2

Traditional flange bracket, CS, panel

★

B3

Traditional flange flat bracket, CS, 2-in. pipe

★

B7

Traditional flange bracket, B1 with SST bolts

★

B8

Traditional flange bracket, B2 with SST bolts

★

B9

Traditional flange bracket, B3 with SST bolts

★

BA

Traditional flange bracket, B1, all SST

★

BC

Traditional flange bracket, B3, all SST

★

Software configuration
C1

Custom software configuration (Rosemount 3051SMV Configuration Data Sheet required.)

★

C2

Custom flow configuration (Rosemount 3051SMV Configuration Data Sheet required.)

★

C4

NAMUR alarm and saturation levels, high alarm

★

C5

NAMUR alarm and saturation levels, low alarm

★

C6

Custom alarm and saturation signal levels, high alarm

★

C7

Custom alarm and saturation signal levels, low alarm

★

C8

Low alarm (standard Rosemount alarm and saturation levels)

★

Flange adapter(13)
D2

1 2

D9

RC / SST flange adapter

★

/ –14 NPT flange adapter
1 2

Ground screw
D4

★

External ground screw assembly

Drain/vent valve(13)
D5

Delete transmitter drain/vent valves (install plugs)

D7

Coplanar flange without drain/vent ports

★

Conduit plug(14)
DO

★

316 SST Conduit Plug

Product certifications
E1

ATEX Flameproof

★

I1

ATEX Intrinsic Safety

★

N1

ATEX Type n

★

ND

ATEX Dust

★

K1

ATEX Flameproof, Intrinsic Safety, Type n, Dust (combination of E1, I1, N1, and ND)

★

E4

TIIS Flameproof

★

E5

FM Explosion-proof, Dust Ignition-proof

★

I5

FM Intrinsically Safe, Division 2

★

K5

FM Explosion-proof, Dust Ignition-proof, Intrinsically Safe, Division 2 (combination of E5 and I5)

★

E6(15)

CSA Explosion-proof, Dust Ignition-proof, Division 2

★

I6

CSA Intrinsically Safe

★

K6(15)

CSA Explosion-proof, Dust Ignition-proof, Intrinsically Safe, Division 2 (combination of E6 and I6)

★

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September 2017

Table A-6. Rosemount 3051S Scalable MultiVariable Transmitter Ordering Information
The starred offerings (★) represent the most common options and should be selected for best delivery. The non-starred offerings are subject to
additional delivery lead time.

E7

IECEx Flameproof, Dust Ignition-proof

★

I7

IECEx Intrinsic Safety

★

N7

IECEx Type n

★

K7

IECEx Flameproof, Dust Ignition-proof, Intrinsic Safety, and Type n (combination of E7, I7, and N7)

★

E2

INMETRO Flameproof

★

I2

INMETRO Intrinsic Safety

★

E3

China Flameproof

★

I3

China Intrinsic Safety

★

KA(15)(16)

ATEX and CSA Explosion-proof, Intrinsically Safe, Division 2 (combination of E1, E6, I1, and I6)

★

KB(15)(16)

FM and CSA Explosion-proof, Dust Ignition-proof, Intrinsically Safe, Division 2 (combination of E5, E6, I5, and I6)

★

KC

FM and ATEX Explosion-proof, Intrinsically Safe, Division 2 (combination of E5, E1, I5, and I1)

★

KD(15)(16)

FM, CSA, and ATEX Explosion-proof, Intrinsically Safe (combination of E5, E6, E1, I5, I6, and I1)

★

DW(17)

NSF Drinking Water Certification

★

Alternate materials of construction
L1(18)

Inert sensor fill fluid (differential and gage sensors only)

★

L2

Graphite-filled PTFE O-ring

★

L4(13)

Austenitic 316 SST bolts

★

L5(8)(13)

ASTM A193, Grade B7M bolts

★

L6(13)

Alloy K-500 bolts

★

L7(8)(13)

ASTM A453, Class D, Grade 660 bolts

★

L8(13)

ASTM A193, Class 2, Grade B8M bolts

★

Digital display
M5

Plantweb LCD display

★

Special procedures
P1(19)

Hydrostatic testing with certificate

★

P9(2)

4500 psig (310 bar) static pressure limit

★

P0(2)(20)

6092 psig (420 bar) static pressure limit

★

P2(13)

Cleaning for special services

P3(13)

Cleaning for less than 1PPM chlorine/fluorine

Special certifications
Q4

Calibration Certificate

★

QP

Calibration Certificate and Tamper Evident Seal

★

Q8

Material Traceability Certification per EN 10204 3.1B

★

Q16

Surface Finish Certification for Sanitary Remote Seals

★

QZ

Remote Seal System Performance Calculation Report

★

Quality Certification for Safety(21)
QS

Prior-use certificate of FMEDA data

★

QT

Safety certified to IEC 61508 with certificate of FMEDA data

★

Transient protection
T1

Transient terminal block

Specifications and Reference Data

★

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Table A-6. Rosemount 3051S Scalable MultiVariable Transmitter Ordering Information
The starred offerings (★) represent the most common options and should be selected for best delivery. The non-starred offerings are subject to
additional delivery lead time.

Conduit electrical connector(22)
GE

M12, 4-pin, male connector (eurofast®)

★

GM

A size Mini, 4-pin, male connector (minifast®)

★

Cold temperature
BRR

Typical model number:
1.
2.
3.
4.
5.
6.
7.
8.
9.
10.
11.
12.
13.
14.
15.
16.
17.
18.
19.
20.
21.
22.

143

★

–60 °F (–51 °C) cold temperature start-up

3051SMV 3 M 1 2 G 4 R 2 E12 A 1A B4 C2 M5

Only available with DP range codes 2 and 3, 316L SST or Alloy C-276 isolating diaphragm and silicone fill fluid.
Only available with measurement type codes 3 and 4.
DP Range 0 is only available with traditional flange, 316L SST diaphragm material, and bolting option L4.
Required for measurement type codes 3 and 4.
For measurement type 1 and 2 with DP range 1, absolute limits are 0.5 to 2000 psi (0,03 to 137,9 bar) and gage limits are –14.2 to 2000 psig (–0,98 to 137,9 bar).
Required for measurement type codes 2 and 4.
Required for measurement type codes 1 and 3. RTD Sensor must be ordered separately.
Materials of Construction comply with metallurgical requirements highlighted within NACE® MR0175/ISO 15156 for sour oil field production environments.
Environmental limits apply to certain materials. Consult latest standard for details. Selected materials also conform to NACE MR0103 for sour refining environments.
Tantalum diaphragm material is only available for DP ranges 2–5.
“Assemble to” items are specified separately and require a completed model number.
Consult an Emerson representative for performance specifications.
For use with Flowmeters with integral RTDs.
Not available with process connection option code A11.
Transmitter is shipped with 316 SST conduit plug (uninstalled) in place of standard carbon steel conduit plug.
Not available with M20 or G 1/2 conduit entry size.
RTD cable not available with this option.
Requires 316L SST diaphragm material, glass-filled PTFE O-ring (standard), and process connection code E12 or F12.
Silicone fill fluid is standard.
Not available with DP range 0.
Requires 316L SST or Alloy C-276 diaphragm material, assemble to Rosemount 305 Integral Manifold or DIN-compliant traditional flange process connection, and
bolting option L8. Limited to differential pressure ranges 2–5.
Not available with output code F or X.
Available with Intrinsically Safe approvals only. For FM Intrinsically Safe, Non-Incendive approval (option code I5), install in accordance with Rosemount drawing
03151-1009 to maintain outdoor rating (NEMA 4X and IP66).

Specifications and Reference Data

Specifications and Reference Data

Reference Manual

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A.3.2 Rosemount 300SMV housing kit
Table A-7. Ordering Information
Rosemount
model
300SMV

Housing kit for Rosemount 3051SMV

Multivariable type
M

Multivariable measurement with fully compensated mass and energy flow

★

P

Multivariable measurement with direct process variable output

★

Temperature input
N

None

★

R(1)

RTD input (type Pt 100, –328 to 1562 °F [–200 to 850 °C])

★

Transmitter output
A

★

4–20 mA with digital signal based on HART Protocol

Housing style

Material(2)

Conduit entry

1A

Plantweb housing

Aluminum

1 2

★

1B

Plantweb housing

Aluminum

M20 ⫻ 1.5 (CM20)

★

1J

Plantweb housing

SST

1 2

★

1K

Plantweb housing

SST

M20 ⫻ 1.5 (CM20)

★

1C

Plantweb housing

Aluminum

G1/2

1L

Plantweb housing

SST

G1/2

/ –14 NPT

/ –14 NPT

Options (include with selected model number)
RTD cable (RTD sensor must be ordered separately)
C12

RTD input with 12 ft. (3,66 m) of shielded cable

★

C13

RTD input with 24 ft. (7,32 m) of shielded cable

★

C14

RTD input with 75 ft. (22,86 m) of shielded cable

★

C20(3)

RTD input with 27-in. (69 cm) of armored shielded cable

★

C21

RTD input with 4 ft. (1,22 m) of armored shielded cable

★

C22

RTD input with 12 ft. (3,66 m) of armored shielded cable

★

C23

RTD input with 24 ft. (7,32 m) of armored shielded cable

★

C24

RTD input with 75 ft. (22,86 m) of armored shielded cable

★

C30(3)

RTD input with 25-in. (64 cm) of ATEX/IECEx Flameproof cable

★

C32

RTD input with 12 ft. (3,66 m) of ATEX/IECEx Flameproof cable

★

C33

RTD input with 24 ft. (7,32 m) of ATEX/IECEx Flameproof cable

★

C34

RTD input with 75 ft. (22,86 m) of ATEX/IECEx Flameproof cable

★

C40(3)

RTD input with 34-in. (86,36 cm) shielded cable and 24-in. (60,96 cm) FM Approved coupling flex

★

C41(3)

RTD input with 40-in. (101,60 cm) shielded cable and 30-in. (76,20 cm) FM Approved coupling flex

★

Specifications and Reference Data

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Table A-7. Ordering Information
Alarm limit
C4

NAMUR alarm and saturation levels, high alarm

★

C5

NAMUR alarm and saturation levels, low alarm

★

C8

Low alarm (standard Rosemount alarm and saturation levels)

★

External ground screw assembly
D4

★

External ground screw assembly

Product certifications
E1

ATEX Flameproof

★

I1

ATEX Intrinsic Safety

★

N1

ATEX Type n

★

ND

ATEX Dust

★

K1

ATEX Flameproof, Intrinsic Safety, Type n, Dust (combination of E1, I1, N1, and ND)

★

E4

TIIS Flameproof

★

I4

TIIS Intrinsic Safety

★

K4

TIIS Flameproof and Intrinsic Safety (combination E4 and I4)

★

E5

FM Explosion-proof, Dust Ignition-proof

★

I5

FM Intrinsically Safe, Division 2

★

K5

FM Explosion-proof, Dust Ignition-proof, Intrinsically Safe, Division 2 (combination of E5 and I5)

★

E6

CSA Explosion-proof, Dust Ignition-proof, Division 2

★

I6

CSA Intrinsically Safe

★

K6

CSA Explosion-proof, Dust Ignition-proof, Intrinsically Safe, Division 2 (combination of E6 and I6)

★

E7

IECEx Flameproof, Dust Ignition-proof

★

I7

IECEx Intrinsic Safety

★

N7

IECEx Type n

★

K7

IECEx Flameproof, Dust Ignition-proof, Intrinsic Safety, Type n (combination of E7, I7, and N7)

★

E2(4)

INMETRO Flameproof

★

I2(4)

INMETRO Intrinsic Safety

★

K2(4)

INMETRO Flameproof, Intrinsic Safety (combination of E2 and I2)

★

E3(4)

China Flameproof

★

I3(4)

China Intrinsic Safety

★

KA(5)

ATEX and CSA Explosion-proof, Intrinsically Safe, Division 2 (combination of E1, E6, I1, and I6)

★

KB

FM and CSA Explosion-proof, Dust Ignition-proof, Intrinsically Safe, Division 2 (combination of E5, E6, I5, and I6)

★

KC(5)

FM and ATEX Explosion-proof, Intrinsically Safe, Division 2 (combination of E5, E1, I5, and I1)

★

KD(5)

FM, CSA, and ATEX Explosion-proof, Intrinsically Safe (combination of E5, E6, E1, I5, I6, and I1)

★

Digital display
M5

145

Plantweb LCD display

★

Specifications and Reference Data

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Reference Manual

September 2017

00809-0100-4803, Rev GA
Table A-7. Ordering Information
Terminal blocks
T1

★

Transient terminal block

Conduit electrical connector(6)
GE

M12, 4-pin, male connector (eurofast)

★

GM

A size mini, 4-pin, male connector (minifast)

★

Typical model number:
1.
2.
3.
4.
5.
6.

300SMV

M

R

1A C22

M5

RTD Sensor must be ordered separately.
Material specified is cast as follows: CF-8M is the cast version of 316 SST, CF-3M is the cast version of 316L SST, CW-12MW is the cast version of Alloy C-276, M-30C is the
cast version of alloy 400. For housing, material is aluminum with polyurethane paint.
For use with Flowmeters with integral RTDs.
Contact an Emerson representative for availability.
RTD cable not available with this option.
Available with Intrinsically Safe approvals only. For FM Intrinsically Safe, Non-Incendive approval (option code I5), install in accordance with Rosemount drawing
03151-1206 to maintain outdoor rating (NEMA 4X and IP66).

Specifications and Reference Data

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A.4 Accessories
A.4.1 Rosemount Engineering Assistant (EA) software packages
The Rosemount Engineering Assistant software supports flow configuration for the Rosemount 3051SMV. The package is
available with or without modem and connecting cables. All configurations are packaged separately.
For best performance of the EA Software, the following computer hardware and software is recommended:


Pentium-grade Processor: 500 MHz or faster



Operating system: Windows™ Professional 7, 8.1, or 10.
– 32-bit
– 64-bit



256 MB RAM



100 MB of available hard disk space



RS232 serial port or USB port (for use with HART modem)



CD-ROM

Engineering Assistant software packages
Code

Product description

EA

Engineering Assistant software program

Software media
3

EA Rev. 6 (compatible with Rosemount 3051SMV only)

Language
E

English

Modem and connecting cables
O

None

H

Serial Port HART modem and cables

B

USB Port HART modem and cables

License
N1

Single PC license

N2

Site license

Typical model number:

EA

3

E O

N1

Accessories
Item description

Part number

Serial Port HART modem and cables only

03095-5105-0001

USB Port HART modem and cables only(1)

03095-5105-0002

1.

147

Supported by SNAP-ON™ EA with AMS Device Manager version 6.2 or higher.

Specifications and Reference Data

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Figure A-6. Exploded View Diagram
The following drawing shows the name and location for commonly ordered spare parts:

D
C
B
E
A

F

G
H
I
J

L
K

M

A. Cover
B. Cover O-ring
C. Terminal block
D. Plantweb housing
E. Feature board
F. Module O-ring
G. Coplanar flange

Specifications and Reference Data

H. Process flange O-ring
I. Drain/vent valve
J. Flange adapter O-ring
K. Flange adapters
L. Flange alignment screw (not pressure retaining)
M. Flange/adapters bolts

148

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Specifications and Reference Data

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00809-0100-4803, Rev GA

September 2017

A.5 Spare parts
Sensor modules
See “Rosemount 3051S Scalable MultiVariable Transmitter Ordering Information” on page 138 for ordering spare sensor modules. Use
housing style code 00 within the Rosemount 3051SMV model number.

Typical model number: 3051SMV 3 M 1 2 G 3 R 2 E11 A 00 C21
Feature board electronics and housing assembly
See “Rosemount 300SMV housing kit” on page 144 for ordering spare housings or feature boards.

Typical model number: 300SMV M R A 1A C21
LCD display

Part number

Aluminum Plantweb housing
LCD display kit: LCD display assembly, 4-pin interconnection header and aluminum cover assembly

03151-9193-0001

LCD display only: LCD display assembly, 4-pin interconnection header

03151-9193-0002

Cover assembly kit: Aluminum cover assembly

03151-9193-0003

Rosemount 316L SST Plantweb housing
LCD display kit: LCD display assembly, 4-pin interconnection header, 316L SST cover assembly

03151-9193-0004

LCD display only: LCD display assembly, 4-pin interconnection header

03151-9193-0002

Cover assembly kit: 316L SST cover assembly

03151-9193-0005

Electrical housing, terminal blocks
Plantweb housing terminal block, HART (4–20 mA)
Standard terminal block assembly with Temperature input

03151-9006-0001

Standard terminal block assembly without Temperature input

03151-9005-0001

Transient protection terminal block assembly with Temperature input

03151-9006-0002

Transient protection terminal block assembly without Temperature input

03151-9005-0002

Covers
Aluminum electronics cover; cover and O-ring

03151-9030-0001

316L SST electronics cover; cover and O-ring

03151-9030-0002

Housing miscellaneous
External ground screw assembly (option D4): screw, clamp, washer

03151-9060-0001

Housing V-seal for both Plantweb and Junction Box housings

03151-9061-0001

Plantweb housing header cable O-ring (package of 12)

03151-9011-0001

Specifications and Reference Data

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September 2017

Flanges

Reference Manual
00809-0100-4803, Rev GA

Part number

Differential coplanar flange
Nickel-plated CS

03151-9200-0025

SST

03151-9200-0022

Cast C-276

03151-9200-0023

Cast alloy 400

03151-9200-0024

Gage/absolute coplanar flange
Nickel-plated CS

03151-9200-1025

SST

03151-9200-1022

Cast C-276

03151-9200-1023

Cast alloy 400

03151-9200-1024

Coplanar flange alignment screw (package of 12)

03151-9202-0001

Traditional flange
SST

03151-9203-0002

Cast C-276

03151-9203-0003

Cast Alloy 400

03151-9203-0004

Flange adapter kits
(each kit contains adapters, bolts, and O-ring for one DP transmitter or two GP/AP transmitters)
CS bolts, glass-filled PTFE O-rings
SST adapters

03031-1300-0002

Cast C-276 adapters

03031-1300-0003

Cast alloy 400 adapters

03031-1300-0004

Nickel-plated CS adapters

03031-1300-0005

SST bolts, glass-filled PTFE O-rings
SST adapters

03031-1300-0012

Cast C-276 adapters

03031-1300-0013

Cast Alloy 400 adapters

03031-1300-0014

Ni-plated CS adapters

03031-1300-0015

CS bolts, Graphite PTFE O-rings
SST adapters

03031-1300-0102

Cast C-276 adapters

03031-1300-0103

Cast alloy 400 adapters

03031-1300-0104

Ni-plated CS adapters

03031-1300-0105

SST bolts, Graphite PTFE O-rings
SST adapters

03031-1300-0112

Cast C-276 adapters

03031-1300-0113

Cast Alloy 400 adapters

03031-1300-0114

Ni-plated CS adapters

03031-1300-0115

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Flange adapter

Specifications and Reference Data
September 2017

Part number

Nickel-plated CS

03151-9259-0005

SST

03151-9259-0002

Cast C-276

03151-9259-0003

Cast alloy 400

03151-9259-0004

Drain/vent valve kits (each kit contains parts for one transmitter)
Differential drain/vent kits
SST valve stem and seat kit

03151-9268-0022

Alloy C-276 valve stem and seat kit

03151-9268-0023

Alloy K-500 valve stem and alloy 400 seat kit

03151-9268-0024

SST Ceramic ball drain/vent kit

03151-9268-0122

Alloy C-276 ceramic ball drain/vent kit

03151-9268-0123

Alloy 400/K-500 ceramic ball drain/vent kit

03151-9268-0124

Gage/absolute drain/vent kits
SST valve stem and seat kit

03151-9268-0012

Alloy C-276 valve stem and seat kit

03151-9268-0013

Alloy K-500 valve stem and Alloy 400 Seat Kit

03151-9268-0014

SST ceramic ball drain/vent kit

03151-9268-0112

Alloy C-276 ceramic ball drain/vent kit

03151-9268-0113

Alloy 400 ceramic ball drain/vent kit

03151-9268-0114

O-ring packages (package of 12)
Electronic housing, cover (Standard and LCD display)

03151-9040-0001

Electronics housing, module

03151-9041-0001

Process flange, glass-filled PTFE

03151-9042-0001

Process flange, Graphite-filled PTFE

03151-9042-0002

Flange adapter, glass-filled PTFE

03151-9043-0001

Flange adapter, graphite-filled PTFE

03151-9043-0002

Gland and collar kits
Gland and collar kits

03151-9250-0001

Mounting brackets
Coplanar flange bracket kit
B4 bracket, SST, 2-in. pipe mount, SST bolts

03151-9270-0001

Traditional flange bracket kits
B1 bracket, 2-in. pipe mount, CS bolts

03151-9272-0001

B2 bracket, panel mount, CS bolts

03151-9272-0002

B3 Flat bracket for 2-in. pipe mount, CS bolts

03151-9272-0003

Specifications and Reference Data

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B7 (B1 style bracket with SST bolts)

03151-9272-0007

B8 (B2 style bracket with SST bolts)

03151-9272-0008

B9 (B3 style bracket with SST bolts)

03151-9272-0009

BA (SST B1 bracket with SST bolts)

03151-9272-0011

BC (SST B3 bracket with SST bolts)

03151-9272-0013

DIN compliant traditional flange bracket kits – M10 threads (F62 process connection)
B1 bracket, 2-in. pipe mount, CS bolts

03151-9272-0101

B2 bracket, panel mount, CS bolts

03151-9272-0101

B3 flat bracket for 2-in. pipe mount, CS bolts

03151-9272-0103

B7 (B1 style bracket with SST bolts)

03151-9272-0107

B8 (B2 style bracket with SST bolts)

03151-9272-0108

B9 (B3 style bracket with SST bolts)

03151-9272-0109

BA (SST B1 bracket with SST bolts)

03151-9272-0111

BC (SST B3 bracket with SST bolts)

03151-9272-0113

DIN compliant traditional flange bracket kits – M12 threads (F72 process connection)
B1 bracket, 2-in. pipe mount, CS bolts

03151-9272-0201

B2 bracket, panel mount, CS bolts

03151-9272-0202

B3 flat bracket for 2-in. pipe mount, CS bolts

03151-9272-0203

B7 (B1 style bracket with SST bolts)

03151-9272-0207

B8 (B2 style bracket with SST bolts)

03151-9272-0208

B9 (B3 style bracket with SST bolts)

03151-9272-0209

BA (SST B1 bracket with SST bolts)

03151-9272-0211

BC (SST B3 bracket with SST bolts)

03151-9272-0213

Bolt kits
Coplanar flange
Flange bolt kit (44 mm [1.75-in.])
CS (set of four)

03151-9280-0001

316 SST (set of four)

03151-9280-0002

ANSI/ASTM-A-193-B7M (set of four)

03151-9280-0003

Alloy K-500 (set of four)

03151-9280-0004

ASTM A 453, Class D Grade 660 (set of four)

03151-9280-0005

ASTM A193, Grade B8M, Class 2 (set of four)

03151-9280-0006

Flange/adapter bolt kit (73 mm [2.88-in.])
CS (set of four)

03151-9281-0001

316 SST (set of four)

03151-9281-0002

ANSI/ASTM-A-193-B7M (set of four)

03151-9281-0003

Alloy K-500 (set of four)

03151-9281-0004

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Specifications and Reference Data
September 2017

ASTM A 453, Class D Grade 660 (set of four)

03151-9281-0005

ASTM A193, Grade B8M, Class 2 (set of four)

03151-9281-0006

Manifold/flange kit (57 mm [2.25-in.])
CS (set of four)

03151-9282-0001

316 SST (set of four)

03151-9282-0002

ANSI/ASTM-A-193-B7M (set of four)

03151-9282-0003

Alloy K-500 (set of four)

03151-9282-0004

ASTM A 453, Class D, Grade 660 (set of four)

03151-9282-0005

ASTM A193, Grade B8M, Class 2 (set of four)

03151-9282-0006

Traditional flange
Differential flange and adapter bolt kit
CS (set of eight)

03151-9283-0001

316 SST (set of eight)

03151-9283-0002

ANSI/ASTM-A-193-B7M (set of eight)

03151-9283-0003

Alloy K-500 (set of eight)

03151-9283-0004

ASTM A 453, Class D, Grade 660 (set of eight)

03151-9283-0005

ASTM A193, Grade B8M, Class 2 (set of eight)

03151-9283-0006

Gage/absolute flange and adapter bolt kit
Carbon Steel (set of six)

03151-9283-1001

316 SST (set of six)

03151-9283-1002

ANSI/ASTM-A-193-B7M (set of six)

03151-9283-1003

Alloy K-500 (set of six)

03151-9283-1004

ASTM A 453, Class D, Grade 660 (set of six)

03151-9283-1005

ASTM A193, Grade B8M, Class 2 (set of six)

03151-9283-1006

Manifold/traditional flange bolts
CS

Use bolts supplied with manifold

316 SST

Use bolts supplied with manifold

Specifications and Reference Data

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Appendix B

Product Certifications

Rev 1.19

European Directive Information . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . page 155
Ordinary Location Certification . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . .page 155
Installing Equipment in North America . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . .page 155
USA . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . .page 155
Canada . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . .page 156
Europe . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . .page 156
International . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . .page 157
Brazil . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . .page 158
China . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . .page 159
EAC – Belarus, Kazakhstan, Russia . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . .page 160
Japan . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . .page 161
Republic of Korea . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . .page 161
Combinations . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . .page 161
Additional Certifications . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . .page 161
Installation drawings . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . .page 162

B.1 European Directive Information

B.4 USA

A copy of the EU Declaration of Conformity can be found at the end
of the Quick Start Guide. The most recent revision of the EU
Declaration of Conformity can be found at
Emerson.com/Rosemount.

E5

US Explosionproof (XP) and Dust-Ignitionproof (DIP)
Certificate: FM16US0089X
Standards: FM Class 3600 – 2011, FM Class 3615 – 2006,
FM Class 3616 – 2011, FM Class 3810 – 2005,
ANSI/NEMA 250 – 2003
Markings: XP CL I, DIV 1, GP B, C, D; T5; DIP CL II, DIV 1, GP
E, F, G; CL III; T5(–50 °C ≤ Ta ≤ +85 °C); Factory
Sealed; Type 4X

I5

US Intrinsic Safety (IS) and Nonincendive (NI)
Certificate: FM16US0233
Standards: FM Class 3600 – 2011, FM Class 3610 – 2007,
FM Class 3611 – 2004, FM CLASS 3616 - 2006,
FM Class 3810 – 2005, NEMA 250 – 1991
Markings: IS CL I, DIV 1, GP A, B, C, D; CL II, DIV 1, GP E, F, G;
Class III; Class 1, Zone 0 AEx ia IIC T4; NI CL 1,
DIV 2, GP A, B, C, D; T4(–50 °C ≤ Ta ≤ +70 °C)
when connected per Rosemount™ drawing
03151-1206; Type 4X

B.2 Ordinary Location Certification
As standard, the transmitter has been examined and tested to
determine that the design meets the basic electrical, mechanical,
and fire protection requirements by a nationally recognized test
laboratory (NRTL) as accredited by the Federal Occupational Safety
and Health Administration (OSHA).

B.3 Installing Equipment in North
America
The US National Electrical Code® (NEC) and the Canadian Electrical
Code (CEC) permit the use of Division marked equipment in Zones
and Zone marked equipment in Divisions. The markings must be
suitable for the area classification, gas, and temperature class. This
information is clearly defined in the respective codes.

Product Certifications

Note
Transmitters marked with NI CL 1, DIV 2 can be installed in
Division 2 locations using general Division 2 wiring methods or
Nonincendive Field Wiring (NIFW). See Drawing 03151-1206.
IE

US FISCO Intrinsically Safe
Certificate: FM16US0233
Standards: FM Class 3600 – 2011, FM Class 3610 – 2010,
FM Class 3611 – 2004, FM Class 3616 – 2006,
FM Class 3810 – 2005, NEMA 250 – 1991
Markings: IS CL I, DIV 1, GP A, B, C, D;
T4(–50 °C ≤ Ta ≤ +70 °C); when connected per
Rosemount drawing 03151-1006; Type 4X

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B.5 Canada

B.6 Europe

E6

E1

I6

IF

Canada Explosionproof, Dust-Ignitionproof, Division 2
Certificate: 1143113
Standards: CAN/CSA C22.2 No. 0-10,
CSA Std C22.2 No. 25-1966,
CSA Std C22.2 No. 30-M1986,
CSA C22.2 No. 94.2-07,
CSA Std C22.2 No. 213-M1987,
CAN/CSA C22.2 60079-11:14,
CAN/CSA-C22.2 No. 61010-1-12,
ANSI/ISA 12.27.01-2003,
CSA Std C22.2 No. 60529:05 (R2010)
Markings: Explosionproof Class I, Division 1, Groups B, C, D;
Dust-Ignitionproof Class II, Division 1, Groups E,
F, G; Class III; suitable for Class I, Division 2,
Groups A, B, C, D; Type 4X

Temperature class

Process temperature

T6

–60 °C to +70 °C

T5

–60 °C to +80 °C

T4

–60 °C to +120 °C

Special Conditions for Safe Use (X):
1. This device contains a thin wall diaphragm less than 1 mm
thickness that forms a boundary between EPL Ga (process
connection) and EPL Gb (all other parts of the equipment).
The model code and datasheet are to be consulted for details
of the diaphragm material. Installation, maintenance and use
shall take into account the environmental conditions to
which the diaphragm will be subjected. The manufacturer's
instructions for installation and maintenance shall be
followed in detail to assure safety during its expected
lifetime.

Canada Intrinsically Safe
Certificate: 1143113
Standards: CAN/CSA C22.2 No. 0-10,
CSA Std C22.2 No. 25-1966,
CSA Std C22.2 No. 30-M1986,
CSA C22.2 No. 94.2-07,
CSA Std C22.2 No. 213-M1987,
CAN/CSA C22.2 60079-11:14,
CAN/CSA-C22.2 No. 61010-1-12,
ANSI/ISA 12.27.01-2003,
CSA Std C22.2 No. 60529:05 (R2010)
Markings: Intrinsically Safe Class I, Division 1; Groups A, B, C,
D; suitable for Class 1, Zone 0, IIC, T3C, Ta = 70 °C;
when connected per Rosemount drawing
03151-1207; Type 4X
Canada FISCO Intrinsically Safe
Certificate: 1143113
Standards: CAN/CSA C22.2 No. 0-10,
CSA Std C22.2 No. 25-1966,
CSA Std C22.2 No. 30-M1986,
CSA C22.2 No. 94.2-07,
CSA Std C22.2 No. 213-M1987,
CAN/CSA C22.2 60079-11:14,
CAN/CSA-C22.2 No. 61010-1-12,
ANSI/ISA 12.27.01-2003,
CSA Std C22.2 No. 60529:05 (R2010)
Markings: FISCO Intrinsically Safe Class I, Division 1; Groups
A, B, C, D; suitable for Class I, Zone 0; T3C,
Ta = 70 °C; when installed per Rosemount
drawing 03151-1207; Type 4X

ATEX Flameproof
Certificate: KEMA 00ATEX2143X
Standards: EN 60079-0:2012+A11:2013, EN 60079-1: 2014,
EN 60079-26:2015
Markings:
II 1/2 G Ex db IIC T6…T4 Ga/Gb,
T6(–60 °C ≤ Ta ≤ +70 °C),
T5/T4(–60 °C ≤ Ta ≤ +80 °C)

2. Flameproof joints are not intended for repair.
3. Non-standard paint options may cause risk from
electrostatic discharge. Avoid installations that could cause
electrostatic build-up on painted surfaces, and only clean the
painted surfaces with a damp cloth. If paint is ordered
through a special option code, contact the manufacturer for
more information.
4. Appropriate cable, glands and plugs need to be suitable for a
temperature of 5 °C greater than maximum specified
temperature for location where installed.
I1

ATEX Intrinsic Safety
Certificate: Baseefa08ATEX0064X
Standards: EN 60079-0: 2012, EN 60079-11: 2012
Markings: Ex II 1 G Ex ia IIC T4 Ga, T4(–60 °C ≤ Ta ≤ +70 °C)

Parameter

FOUNDATION™ SuperModule™
Fieldbus
only

Voltage Ui

30 V

30 V

Current Ii

300 mA

300 mA

300 mA

Power Pi

1W

1.3 W

887 mW

14.8 nF

0

0.11 μF

0

0

0

Capacitance Ci
Inductance Li

156

HART®

7.14 V

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Parameter

RTD (for 3051SFx) RTD (for 3051SFx)
(HART)
(Fieldbus)

Voltage Ui

30 V

30 V

Current Ii

2.31 mA

18.24 mA

Power Pi

17.32 mW

137 mA

Capacitance Ci

0

0.8 nF

Inductance Li

0

1.33 mH

Special Conditions for Safe Use (X):
1. If the equipment is fitted with the optional 90 V transient
suppressor, it is incapable of withstanding the 500 V isolation
from earth test and this must be taken into account during
installation.
2. The enclosure may be made of aluminum alloy and given a
protective polyurethane paint finish; however, care should
be taken to protect it from impact or abrasion if located in a
Zone 0 environment.
IA

ATEX FISCO
Certificate: Baseefa08ATEX0064X
Standards: EN 60079-0: 2012, EN 60079-11: 2012
Markings: Ex II 1 G Ex ia IIC T4 Ga, T4(–60 °C ≤ Ta ≤ +70 °C)

Parameter

FISCO

Voltage Ui

17.5 V

Current Ii

380 mA

Power Pi

5.32 W

Capacitance Ci

0

Inductance Li

0

ND ATEX Dust
Certificate: BAS01ATEX1374X
Standards: EN 60079-0: 2012+A11:2013,
EN 60079-31:2009
Markings: Ex II 1 D Ex ta IIIC T105 °C T500 95 °C Da,
(–20 °C ≤ Ta ≤ +85 °C), Vmax = 42.4 V
Special Conditions for Safe Use (X):

N1

ATEX Type n
Certificate: Baseefa08ATEX0065X
Standards: EN 60079-0: 2012, EN 60079-15: 2010
Markings: Ex II 3 G Ex nA IIC T4 Gc, (-40 °C ≤ Ta ≤ 70 °C),
Vmax = 45 V

Special Condition for Safe Use (X):
1. If fitted with a 90 V transient suppressor, the equipment is
not capable of withstanding the 500 V electrical strength
test as defined in Clause 6.5.1 of EN 60079-15:2010. This
must be taken into account during installation.

B.7 International
E7

IECEx Flameproof and Dust
Certificate: IECEx KEM 08.0010X (Flameproof)
Standards: IEC 60079-0:2011, IEC 60079-1:2014,
IEC 60079-26:2014
Markings: Ex db IIC T6…T4 Ga/Gb, T6(–60 °C ≤ Ta ≤ +70 °C),
T5/T4(–60 °C ≤ Ta ≤ +80 °C)

Temperature class

Process temperature

T6

–60 °C to +70 °C

T5

–60 °C to +80 °C

T4

–60 °C to +120 °C

Special Conditions for Safe Use (X):
1. This device contains a thin wall diaphragm less than 1 mm
thickness that forms a boundary between EPL Ga (process
connection) and EPL Gb (all other parts of the equipment).
The model code and datasheet are to be consulted for details
of the diaphragm material. Installation, maintenance and use
shall take into account the environmental conditions to
which the diaphragm will be subjected. The manufacturer's
instructions for installation and maintenance shall be
followed in detail to assure safety during its expected
lifetime.
2. Flameproof joints are not intended for repair.

2. Unused cable entries must be filled with suitable blanking
plugs which maintain the ingress protection of the enclosure
to at least IP66.

3. Non-standard paint options may cause risk from electrostatic
discharge. Avoid installations that could cause electrostatic
build-up on painted surfaces, and only clean the painted
surfaces with a damp cloth. If paint is ordered through a
special option code, contact the manufacturer for more
information.

3. Cable entries and blanking plugs must be suitable for the
ambient temperature range of the apparatus and capable of
withstanding a 7J impact test.

4. Appropriate cable, glands and plugs need to be suitable for a
temperature of 5 °C greater than maximum specified
temperature for location where installed.

1. Cable entries must be used which maintain the ingress
protection of the enclosure to at least IP66.

4. The SuperModule(s) must be securely screwed in place to
maintain the ingress protection of the enclosure(s).

Product Certifications

Certificate: IECEx BAS 09.0014X (Dust)
Standards: IEC 60079-0:2011, IEC 60079-31:2008
Markings: Ex ta IIIC T105 °C T500 95 °C Da,
(–20 °C ≤ Ta ≤ +85 °C), Vmax = 42.4 V

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Special Conditions for Safe Use (X):
1. Cable entries must be used which maintain the ingress
protection of the enclosure to at least IP66.

Parameter

FISCO

2. Unused cable entries must be filled with suitable blanking
plugs which maintain the ingress protection of the enclosure
to at least IP66.

Voltage Ui

17.5 V

Current Ii

380 mA

Power Pi

5.32 W

3. Cable entries and blanking plugs must be suitable for the
ambient temperature range of the apparatus and capable of
withstanding a 7J impact test.
4. The Rosemount 3051S - SuperModule must be securely
screwed in place to maintain the ingress protection of the
enclosure.
I7

IECEx Intrinsic Safety
Certificate: IECEx BAS 08.0025X
Standards: IEC 60079-0: 2011, IEC 60079-11: 2011
Markings: Ex ia IIC T4 Ga, T4(–60 °C ≤ Ta ≤ +70 °C)

Parameter

30 V

30 V

7.14 V

Current Ii

300 mA

300 mA

300 mA

Power Pi

1W

1.3 W

887 mW

14.8 nF

0

0.11 μF

0

0

0

Inductance Li

Parameter

E2

RTD (for 3051SFx) RTD (for 3051SFx)
(HART)
(Fieldbus)

Voltage Ui

30 V

30 V

Current Ii

2.31 mA

18.24 mA

Power Pi

17.32 mW

137 mA

Capacitance Ci

0

0.8 nF

Inductance Li

0

1.33 mH

2. The enclosure may be made of aluminum alloy and given a
protective polyurethane paint finish; however, care should
be taken to protect it from impact or abrasion if located in a
Zone 0 environment.

158

IECEx Type n
Certificate: IECEx BAS 08.0026X
Standards: IEC 60079-0: 2011, IEC 60079-15: 2010
Markings: Ex nA IIC T5 Gc, (–40 °C ≤ Ta ≤ 70 °C)

INMETRO Flameproof
Certificate: UL-BR 15.0393X
Standards: ABNT NBR IEC 60079-0:2008 + Corrigendum
1:2011,
ABNT NBR IEC 60079-1:2009 + Corrigendum
1:2011,
ABNT NBR IEC 60079-26:2008 + Corrigendum 1:
2008
Markings: Ex d IIC T* Ga/Gb, T6(–60 °C ≤ Ta ≤ +70 °C),
T5/T4(-60 °C ≤ Ta ≤ +80 °C), IP66

Special Conditions for Safe Use (X):
1. The device contains a thin wall diaphragm. Installation,
maintenance and use shall take into account the
environmental conditions to which the diaphragm will be
subjected. The manufacturer's instructions for installation
and maintenance shall be followed in detail to assure safety
during its expected lifetime.

1. If the equipment is fitted with the optional 90 V transient
suppressor, it is incapable of withstanding the 500 V isolation
from earth test and this must be taken into account during
installation.

IECEx FISCO
Certificate: IECEx BAS 08.0025X
Standards: IEC 60079-0: 2011, IEC 60079-11: 2011
Markings: Ex ia IIC T4 Ga, T4(–60 °C ≤ Ta ≤ +70 °C)

0

B.8 Brazil

Special Conditions for Safe Use (X):

IG

Inductance Li

1. If fitted with a 90 V transient suppressor, the equipment is
not capable of withstanding the 500 V electrical strength
test as defined in Clause 6.5.1 of IEC 60079-15:2010. This
must be taken into account during installation.

FOUNDATION SuperModule
Fieldbus
only

HART

0

Special Condition for Safe Use (X):

Voltage Ui

Capacitance Ci

N7

Capacitance Ci

2. For information on the dimensions of the flameproof joints,
the manufacturer shall be contacted.
I2

INMETRO Intrinsic Safety
Certificate: UL-BR 15.0357X
Standards: ABNT NBR IEC 60079-0:2008 + Addendum
1:2011, ABNT NBR IEC 60079-11:2009
Markings: Ex ia IIC T4 Ga (–60 °C ≤ Ta ≤ +70 °C)

Product Certifications

Product Certifications

Reference Manual

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00809-0100-4803, Rev GA

Special Conditions for Safe Use (X):
1. If the equipment is fitted with the optional 90 V transient
suppressor, it is incapable of withstanding the 500 V isolation
from earth test and this must be taken into account during
installation.
2. For processes with temperatures above 135 °C, the user must
assess whether the SuperModule temperature class is
suitable for such applications, because in this situation there
is a risk of the SuperModule temperature being above T4.
HART

FOUNDATION Fieldbus

Parameter
Input

RTD

Input

RTD

Voltage Ui

30 V

30 V

30 V

30 V

Current Ii

300 mA

2.31 mA

300 mA

18.24 mA

Power Pi

1W

17.32 W

1.3 W

137 mW

14.8 nF

0

0

0.8 nF

0

0

0

1.33 mH

Capacitance Ci
Inductance Li

B.9 China
E3

China Flameproof and Dust Ignition-proof
Certificate: 3051SMV: GYJ14.1039X
[Mfg USA, China, Singapore]
3051SFx: GYJ11.1466X
[Mfg USA, China, Singapore]
Standards: 3051SMV: GB3836.1-2010, GB3836.2-2010,
GB3836.20-2010
3051SFx: GB3836.1-2010, GB3836.2-2010,
GB3836.20-2010, GB12476.1-2013,
GB12476.5-2013
Markings: 3051SMV: Ex d IIC T6/T5 Ga/Gb
3051SFx: Ex d IIC T4…T6 Ga/Gb; Ex tD A20 TA
105 °C T50095 °C; IP66

Special Conditions for Safe Use (X):
1. Symbol “X” is used to denote specific conditions of use: For
information on the dimensions of the flameproof joints the
manufacturer shall be contacted.
2. The relationship between T code and ambient temperature
range for the Rosemount 3051SMV are as follows:

T code

Ambient temperature range

T6

–50 °C ~ +65 °C

T5

–50 °C ~ +80 °C

Product Certifications

3. The relationship between T code and ambient temperature
range for the Rosemount 3051SFx are as follows:

T code

Ambient temperature range

T6

–60 °C ~ +70 °C

T4/T5

–60 °C ~ +80 °C

4. The earth connection facility in the enclosure should be
connected reliably.
5. During installation, use and maintenance of the product in
explosive atmosphere, observe the warning “Do not open
cover when circuit is alive”. During installation, use, and
maintenance in explosive dust atmosphere, observe the
warning “Do not open when an explosive dust atmosphere is
present”.
6. During installation there should be no mixture harmful to the
housing.
7. During installation, use and maintenance in explosive dust
atmosphere, product enclosure should be cleaned to avoid
dust accumulation, but compressed air should not be used.
8. During installation in a hazardous location, cable glands and
blanking plugs certified by state appointed inspection bodies
with Ex d II C Gb or Ex d IIC Gb DIP A20 [Flowmeters] IP66
type of protection should be used. Redundant cable entries
should be blocked with blanking plugs.
9. End users are not permitted to change any components, but
to contact the manufacturer to avoid damage to the
product.
10. Maintenance should be done when no explosive gas and dust
atmosphere is present.
11. During installation, use and maintenance of this product,
observe following standards:
GB3836.13-1997 “Electrical apparatus for explosive gas
atmospheres Part 13: Repair and overhaul for apparatus used
in explosive gas atmospheres”
GB3836.15-2000 “Electrical apparatus for explosive gas
atmospheres Part 15: Electrical installations in hazardous
area (other than mines)”
GB3836.16-2006 “Electrical apparatus for explosive gas
atmospheres Part 16: Inspection and maintenance of
electrical installation (other than mines)”
GB50257-1996 “Code for construction and acceptance of
electric device for explosion atmospheres and fire hazard
electrical equipment installation engineering”
GB15577-2007 “Safety regulations for dust explosion
prevention and protection”
GB12476.2-2010 “Electrical apparatus for use in the
presence of combustible dust”

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China Intrinsic Safety
Certificate: 3051SMV: GYJ14.1040X
[Mfg USA, China, Singapore]
3051SFx: GYJ16.14
[Mfg USA, China, Singapore]
Standards: 3051SMV: GB3836.1-2010, GB3836.4-2010,
GB3836.20-2010
3051SFx: GB3836.1/4-2010, GB3836.20-2010,
GB12476.1-2000
Markings: 3051SMV: Ex ia IIC T4 Ga
3051SFx: Ex ia IIC T4 Ga, Ex tD A20 TA105 °C
T500 95 °C; IP66

Special Conditions for Safe Use (X):
1. The enclosure may contain light metal, attention should be
taken to avoid ignition hazard due to impact or friction.
2. The apparatus is not capable of withstanding the 500 V
electrical strength test defined in Clause 6.3.12 of
GB3836.4-2010.
3. Ambient temperature range: –60 °C ~ +70 °C.
4. Intrinsically safe electric parameters:
Maximum
Maximum
Maximum Maximum internal
parameters:
input voltage: input current: input power:
Ui (V)
Ii (mA)
Pi (W)
Ci (nF) Li (μH)
30

Model

RTD
SuperModule

300

1.0

14.8

0

Maximum Maximum Maximum Maximum
external
output
output
output
parameters:
voltage: current:
power:
Ui (V)
Ii (mA)
Pi (W) C (nF) L (μH)
i
i
30

2.31

17.32

0

0

7.14

300

8871.0

110

0

5. The cables between this product and associated apparatus
should be shielded cables. The shield should be grounded
reliably in non-hazardous area.

6. The product should be used with Ex certified associated
apparatus to establish explosion protection system that can
be used in explosive gas atmospheres. Wiring and terminals
should comply with the instruction manual of the product
and associated apparatus.
7. End users are not permitted to change any components,
contact the manufacturer to avoid damage to the product.
8. During installation in hazardous location, cable glands,
conduit, and blanking plugs certified by state-appointed
inspection bodies with DIP A20 IP66 type of protection
should be used. Redundant cable entries should be blocked
with blanking plugs.
9. During installation, use, and maintenance in explosive dust
atmosphere, observe the warning “Do not open when an
explosive dust atmosphere is present”.
10. Maintenance should be done when no explosive dust
atmosphere is present.
11. During installation, use and maintenance of this product,
observe following standards:
GB3836.13-2013 “Electrical apparatus for explosive gas
atmospheres Part 13: Repair and overhaul for apparatus used
in explosive gas atmospheres”
GB3836.15-2000 “Electrical apparatus for explosive gas
atmospheres Part 15: Electrical installations in hazardous
area (other than mines)”
GB3836.16-2006 “Electrical apparatus for explosive gas
atmospheres Part 16: Inspection and maintenance of
electrical installation (other than mines)”
GB3836.18-2010 “Intrinsically Safe System”
GB50257-1996” - Code for construction and acceptance of
electric device for explosion atmospheres and fire hazard
electrical equipment installation engineering”
GB15577-2007 Safety regulations for dust explosion
prevention and protection
GB12476.2-2010 “Electrical apparatus for use in the
presence of combustible dust”

B.10 EAC – Belarus, Kazakhstan, Russia
EM Technical Regulation Customs Union (EAC) Flameproof and
Dust Ignition-proof
Certificate: RU C-US.AA87.B.00378
Markings: Ga/Gb Ex d IIC T6…T4 X
Ex tb IIIC T105 °C T50095 °C Db X
Ex ta IIIC T105 °C T50095 °C Da X
IM

160

Technical Regulation Customs Union (EAC) Intrinsic Safety
Certificate: RU C-US.AA87.B.00378
Markings: 0Ex ia IIC T4 Ga X

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B.11 Japan
E4

Japan Flameproof
Certificate:TC19070, TC19071, TC19072, TC19073
Markings: Ex ia IIC T4

B.12 Republic of Korea
EP

IP

Republic of Korea Flameproof
Certificate: 12-KB4BO-0180X [Mfg USA],
11-KB4BO-0068X [Mfg Singapore]
Markings: Ex d IIC T5 or T6
Republic of Korea Intrinsic Safety [HART Only]
Certificate: 10-KB4BO-0021X [Mfg USA, SMMC]
Markings: Ex ia IIC T4

Application:

Location classes
Type

Rosemount 3051S

Temperature

D

Humidity

B

Vibration

A

EMC

A

Enclosure

D/IP66/IP68

SLL Lloyds Register (LR) Type Approval
Certificate: 11/60002
Application: Environmental categories ENV1, ENV2, ENV3,
and ENV5. [HART Only]

B.13 Combinations
K1
K2
K5
K6
K7
KA
KB
KC
KD
KM
KP

Combination of E1, I1, N1, and ND
Combination of E2 and I2
Combination of E5 and I5
Combination of E6 and I6
Combination of E7, I7, and N7
Combination of E1, I1, E6, and I6
Combination of E5, I5, E6, and I6
Combination of E1, I1, E5, and I5
Combination of E1, I1, E5, I5, E6, and I6
Combination of EM and IM
Combination of EP and IP

B.14 Additional Certifications
SBS American Bureau of Shipping (ABS) Type Approval
Certificate:
00-HS145383
Intended Use: Measure gauge or absolute pressure of liquid,
gas or vapor applications on ABS classed
vessels, marine, and offshore installations.
[HART Only]
SBV Bureau Veritas (BV) Type Approval
Certificate:
31910 BV
Requirements: Bureau Veritas Rules for the Classification of
Steel Ships
Application: Class Notations: AUT-UMS, AUT-CCS,
AUT-PORT and AUT-IMS. [HART Only]
SDN Det Norske Veritas (DNV) Type Approval
Certificate:
A-14186
Intended Use: Det Norske Veritas' Rules for Classification of
Ships, High Speed & Light Craft, and Det
Norske Veritas' Offshore Standards. [HART
Only]

Product Certifications

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B.15 Installation drawings
Figure B-1. Factory Mutual (FM)

CO
162

S

CO

O
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i

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i

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Figure B-2. Canadian Standards Association (CSA)

170

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Global Headquarters
Emerson Automation Solutions
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