Emerson 3000 Intelligent Field Transmitter IFT Installation, Electrical Connections

Page 45

World Class 3000

Instruction Manual

IB-106-300NH Rev. 4.3 May 2005

2-2 INTELLIGENT FIELD TRANSMITTER (IFT) INSTALLATION

a.Mechanical Installation

The outline drawing of the IFT module in Figure 2-4 shows mounting centers and clearances. The NEMA 4X enclosure is de- signed to be mounted on a wall or bulk- head. The IFT should be installed no more than 1200 feet (364 m) from the optional HPS or 150 feet (45 m) from the probe if HPS is not installed in the system.

b.Electrical Connections

11.00 (279.4)

8.00 (203.2)

12.50

(317.5)

13.10

14.00

(332.7)

(355.6)

 

To meet the Safety Requirements of IEC 1010 (EC requirement), and ensure safe operation of this equipment, con- nection to the main electrical power supply must be made through a circuit breaker (min 10A) which will discon- nect all current carrying conductors during a fault situation. This circuit breaker should also include a me- chanically operated isolating switch. If not, then another external means of disconnecting the supply from the equipment should be located close by. Circuit breakers or switches must comply with a recognized standard such as IEC 947.

NOTE

Refer to Figure 2-6 for fuse locations and specifications.

1.The IFT can be configured for 100, 120, 220, or 240 line voltages. For 120 Vac usage, install JM8, JM7, and JM1 on the power supply board. For 220 Vac usage, install jumpers JM6, JM5, JM2 (refer to Figure 2-5 and Figure 2-6).

2.For installations where the cable run is less than 150 feet (45 m), the IFT can

 

 

 

 

11.0 (279.4) MINIMUM DOOR

 

 

 

 

SWING CLEARANCE

1.62

 

 

 

 

 

(41.1)

 

NOTICE:

 

 

 

 

ABOVE 76 C

 

 

 

 

 

ALL CABLE SHOULD

 

 

 

 

 

BE RATED FOR USE

 

 

6.40

 

 

 

 

 

 

 

 

 

Assy 6A00178GXX

(162.6)

 

 

 

 

Model IFT

 

 

 

 

 

SN XXXXXXXXXXXX

 

 

 

 

 

Volts XXX @ 50/60 Hz

 

 

 

 

 

Line Fuse 5 Amps

 

 

 

 

 

Rosemount Analytical Inc.

 

 

 

 

 

P.O. Box 901, Orrville, OH

 

 

 

 

 

44667 USA

 

 

 

LINE

PROBE

 

 

1.49

1.00

 

2.25

0 0.867

 

(37.8)

 

 

(25.4)

 

(57.15)

(22.00)

 

 

 

 

NOTE: DESIGN DIMENSIONS ARE IN INCHES

 

WITH MILLIMETERS IN PARENTHESES.

37840020

Figure 2-4. Outline of Intelligent Field Transmitter

be configured to connect directly to a probe. An optional HPS is available for cable runs over 150 feet (45 m). The electrical connections for a non-HPS equipped system should be made as de- scribed in the electrical installation dia- gram, Figure 2-7. Refer to Figure 2-13 for connections for an HPS equipped system.

Rosemount Analytical Inc. A Division of Emerson Process Management

Installation 2-9

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Contents World Class Essential Instructions Effective May, 1999 Rev Highlights of ChangesSummary Effective November, 2001 RevEffective May, 2005 Rev Appendix a Effective July, 2002 Rev Appendix B Effective February, 1992 RevEffective January, 1995 Rev Page Effective June, 1994 Rev Appendix DRevised view of check valve in Figure D-3 Effective June, 1999 Rev Appendix EFiguration. Revised replacement parts list Appendix J Effective April, 1995 RevEffective June, 1995 Rev Page World Class Table of ContentsList of Illustrations Calibrate O2 Sub-Menu List of TablesWorld Class Definitions PrefaceWorld Class Glossary of Terms Semiautomatic Calibration Reference AirThermocouple Vee DeflectorComplete World Class 3000 System What YOU Need to KnowUse this Quick Start Guide if Quick Start GuideQuick Start Guide for IFT 3000 Systems Line Voltage Jumper Section Install Performing a Manual Semiautomatic Calibration Setting up the Analog OutputTechnical Support Hotline Hart Communicator Fast KEY SequencesComponent Checklist of Typical System Package Contents Section Description and SpecificationsSystem Overview ScopeSystem Description System Features System ConfigurationWorld Class Standard HPS World Class World Class Section Installation Oxygen Analyzer Probe InstallationSelecting Location Probe Installation Sheet 1 Probe Installation Sheet 2 Probe Installation Sheet 3 Probe Installation Sheet 4 Probe Installation Sheet 5 Orienting the Optional Vee Deflector Reference Air Package Service RequiredElectrical Connections Intelligent Field Transmitter IFT InstallationPower Supply Board Jumper Configuration IFT Power Supply Board Jumpers Wiring Layout for IFT Systems without HPS Jumper Configuration Condition during Microcontroller failure Switch SW3Heater Power Supply Installation Output JumperIFT Microprocessor Board 10. Interconnect Board Jumper Configuration Refer to -16 for fuse locations and specifications 12. Outline of Heater Power Supply Electrical ConnectionsJ8 + + Conductor 14. Heater Power Supply Wiring Connections 16. Jumpers on HPS Mother Board Gas Connections Multiprobe Calibration GAS Sequencer Installation18. MPS Gas Connections Refer to -19 for fuse locations and specifications19. MPS Probe Wiring World Class Configuring the Analog Output Section SetupSetting Calibration Parameters OverviewSetting the O2 Alarm Setpoints Configuring Efficiency CalculationsConfiguring the Relay Outputs Analog Output Calibration CalibrationSystem Calibration OverviewLiquid Carbonic GAS Corp Specialty GAS Laboratories Calibration MethodsScott Environmental TECHNOLOGY, INC. Scott Specialty Gases % O Portable Rosemount Analytical Oxygen Calibration Gas Kit Fully Automatic Calibration Typical Automatic Calibration System Figure analog output Automatic Calibration ParametersCalibration Record For Rosemount Analytical In Situ O2 Probe World Class Hart Communicator Interface Devices Section General User Interface GUI OperationIndex No Control/LED Description Deluxe Version IFT Displays and ControlsMENU, SUB-MENU, Help Or Parameter Name Message Probe Data Quick Reference ChartCalibrate O2 Help KEYCalibrate O2 SUB-MENU Setup SUB-MENU Probe Data Sub-MenuSUB-MENU Selection Parameter Description Quick Reference Chart Sheet 1 Quick Reference Chart Sheet 2 Quick Reference Chart Sheet 3 Quick Reference Chart Sheet 4 Quick Reference Chart Sheet 5 Calibrate O2 Sub-Menu XD XH SUB-MENU Selection Parameters Description Setup Sub-MenuSelected in the Setup sub-menu Xfer FnctRange Values Normal Range Values Dual Range SetupEfficiency Constants Constant United States Europe GAS OILSection Troubleshooting Special Troubleshooting NotesSystem Troubleshooting IFT Status Codes Heater Troubleshooting Problem Heater ProblemWorld Class Cell Troubleshooting Problem Cell ProblemStatus is LowO2 Cell mV = -127 mV Status is ResHi or CalEr Cell mV = -20 to 120 mV normalStatus is Res Hi Cell mV = -120 to 20 mV IFT Problem IFT Troubleshooting ProblemFaulty GUI or LDP IFT LED is Flashing MPS Troubleshooting Problem MPS ProblemStatus is NoGas Cell mV is between -20 to 120 mV Status is ResHi or CalEr Cell mV is between -20 to 120 mVPerformance Problem Troubleshooting Performance Problem Process Response is SuspectWorld Class Section Return of Material World Class Section Appendices Appendix a Figure A-2. Main Probe Components Oxygen Analyzer Probe GeneralTable A-1. Specifications for Oxygen Analyzing Equipment.1 Probe Assembly Exterior Cell and Flange AssemblyProbe Tube Assembly Cell General Inner Probe AssemblyAbrasive Shield Assembly Cable AssemblyProbe Junction BOX Probe OptionsView a Ceramic Diffusion Assembly Figure A-8. Ceramic Diffusion/Dust Seal AssemblyProbe Mounting Jacket Options Snubber Diffusion/Dust Seal AssemblyFigure A-15. Bypass Probe Option Sheet 1 Figure A-15. Bypass Probe Option Sheet 2 Group Code Description Extended Temperature By-Pass Arrangements 2400F 1300CProbe Troubleshooting Probe TroubleshootingProbe Faults Table A-2. Fault Finding Symptom Check RemedyWorld Class Figure A-16. Flowchart of Probe Related Problems, #1 Figure A-17. Flowchart of Probe Related Problems, #2 Service and Normal Maintenance Cell ReplacementProbe Recalibration Figure A-18. Cell Wiring Connection General Optional Ceramic Diffusion Element ReplacementWorld Class Figure A-21. Probe Junction Box Mechanical Connections Replacement of Contact Thermocouple AssemblyContact Heater Screws Not Shown Thermocoupler World Class Figure A-24. Oxygen Analyzer Probe, Cross-Sectional View Figure A-25. High Temperature Corrosive Environment Kit Index No Replacement PartsFigure A-9 Figure B-1. HPS 3000 Heater Power Supply Field Module Appendix B, REV HPS 3000 Heater Power Supply DescriptionFront Theory of Operation Table B-1. Specifications for Heater Power SupplyOverview HPS 3000 Troubleshooting HPS 3000 TroubleshootingSymptom Figure B-5. HPS Troubleshooting Flowchart, #2 Figure B-6. HPS Troubleshooting Flowchart, #3 Fuse Replacement Transformer ReplacementMother Board Replacement Daughter Board Replacement Figure B-7. Heater Power Supply, Exploded View Part Number Description Table B-2. Replacement Parts for Heater Power SupplyWorld Class Figure D-1. MPS 3000 Multiprobe Calibration Gas Sequencer 20 to 160F -30 to 71C Figure D-3. Typical Automatic Calibration System Bebco Model Z-PURGE Rear View Troubleshooting MPS 3000 TroubleshootingTable D-2. Fault Finding Symptom Check Fault RemedyFigure D-5. MPS Troubleshooting Flowchart Power Supply Replacement Solenoid Valve Replacement4543 Pressure Regulator Maintenance Pressure AdjustmentsCondensation Drain Adding Probes to the MPS Flowmeter AdjustmentsFigure D-6 1A97909H01 Power Supply World Class Interconnect Board Power Supply BoardGUI/LED Display Board Heater optionalPurge optional Table E-1. Specifications for Intelligent Field TransmitterHeater Power Supply Optional IFT IFT Troubleshooting IFT 3000 TroubleshootingMicroprocessor Status LED Equipment Status LCD DisplaysFigure E-3. IFT Troubleshooting Flowchart, #1 Symptom Microprocessor Board LED is Steady on Symptom Component Failure Table E-2. GUI Equipped IFT Fault FindingFigure E-6. Intelligent Field Transmitter, Exploded View Remove Power and Open Cover Replace FuseRemove Electronics Chassis from Enclosure Figure E-7. Microprocessor Assembly Exploded View Replace Microprocessor Board Replace Power Supply BoardReplace Interconnect Board Replace FANFigure E-8. Electronics Chassis Exploded View Install Electronics Chassis Replace Heater and ThermoswitchReplace Transformer Figure E-9. Electronics Chassis Installation Replace GUI Assembly or Close Cover and Restore PowerRibbon Cable Figure E-8 1N04946G01 Transformer Figure J-1. Typical Hart Communicator Package, Model 275D9E Specifications Method 1, For Load Resistance 250 Ohms Hart Communicator Signal Line ConnectionsHart Communicator PC Connections Load Resistor See Note Hart Communicator OFF-LINE and ON-LINE Operations OperationMenu Tree for Hart Communicator World Class 3000 IFT ApplicationsFigure J-4. Menu Tree for IFT 3000 Applications Sheet 1 Figure J-4. Menu Tree for IFT 3000 Applications Sheet 2 Figure J-4. Menu Tree for IFT 3000 Applications Sheet 3 Troubleshooting Flowchart Figure J-5. Model 275D9E, Troubleshooting Flowchart Sheet 1 Figure J-5. Model 275D9E, Troubleshooting Flowchart Sheet 2 Returning Equipment to the Factory World Class Section Index World Class Rosemount Analytical Warranty World Class 3000 Probe HPS Serial No Order No IFT MPS
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3000 specifications

The Emerson 3000 is a cutting-edge control system designed to enhance the efficiency, reliability, and precision of industrial operations. Employed across various sectors such as oil and gas, pharmaceutical, food and beverage, and power generation, the Emerson 3000 has gained recognition for its robustness and versatility.

One of the main features of the Emerson 3000 is its advanced process control capability. With integrated control algorithms, it can optimize complex processes in real-time, resulting in significant improvements in production rates and reduced operational costs. The system's predictive analytics capabilities enable operators to anticipate equipment failures and maintenance needs, allowing for proactive management and minimizing downtime.

The Emerson 3000 features a modular architecture, providing flexibility for scaling and customization. Operators can easily tailor the system to fit specific application needs, whether it requires additional control loops or integration with other systems. This adaptability is particularly beneficial for facilities planning for future expansions or modifications.

Another technology highlight of the Emerson 3000 is its seamless integration with the latest Internet of Things (IoT) advancements. The system is designed to communicate effectively with a variety of smart devices and sensors, harnessing data to create insightful analytics that drive operational excellence. This connectivity empowers businesses to leverage big data for improved decision-making and increased agility.

Additionally, the Emerson 3000 incorporates state-of-the-art cybersecurity measures to safeguard critical data and operations. With built-in security protocols and regular updates, the system protects against emerging cyber threats, ensuring the integrity of the control network.

User experience is also a focal point of the Emerson 3000. The intuitive graphical user interface presents complex data in a user-friendly format, making it easier for operators to monitor system performance and respond to alerts quickly. This ease of use contributes to enhanced safety and operational efficiency.

In summary, the Emerson 3000 represents a fusion of advanced process control, modular design, IoT connectivity, robust cybersecurity, and user-centric interface, making it an ideal choice for industries seeking to enhance their operational performance while adapting to ever-evolving technological landscapes.
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