Emerson IFT9701 instruction manual Milliamp output performance

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Power Supply and Output Wiring continued

4.4.1Milliamp output

The 4–20 mA output is an active output that can represent the mass or volume flow rate. At the factory, the output is configured to represent the range of flow rates that are measured in the application. The milliamp output is active, does not require external power, and has the following features:

•Can supply any loop-powered process indicator.

•Isolated to ±500 VDC from all other outputs and earth ground.

•Requires loop resistance of 250 to 600 ohms to produce digital signals for communication via HART protocol.

•For milliamp output, the negative terminal can be grounded or left floating. If the output communicates via HART protocol, the negative terminal should be grounded for optimal performance.

Milliamp output performance is described below and illustrated in Figure 4-3.

CAUTION

Milliamp output range has changed.

Milliamp outputs will not output live signals between 2.0 and 3.8 mA, or between 20.5 and 22 mA.

Systems that rely on milliamp output signals in the ranges listed above might not perform as expected. For IFT9701 transmitters shipped after October 1999, outputs will saturate at 3.8 and 20.5 mA, unlike previous versions of IFT9701 transmitters.

Reconfigure systems as necessary.

In compliance with the NAMUR NE43 standard:

•To represent process data, the milliamp output will produce a live signal in the range of 3.8–20.5 mA.

•The milliamp output will never produce a signal in the range of 2.0–3.8 mA, or in the range of 20.5–22 mA.

•To indicate a fault, the milliamp output will produce a signal of 2 or 22 mA. The fault output level is determined by the fault-output jumper setting — downscale or upscale — as described in Section 2.3.2.

Figure 4-3 Milliamp output performance

Downscale	Upscale
fault indication level	fault indication level

Operating range (live signal)

2	3.8	20.5	22
		Output in mA

22	Model IFT9701 Transmitter Instruction Manual

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Contents Micro Motion Page Micro Motion Page Contents Flowmeter Startup Index Page About this manual Safety Before You BeginEuropean installations DefinitionsFlowmeter components Remotely mounted IFT9701 transmitter Page Safety, reliability, accessibility Getting StartedHazardous area Temperature, humidity, and vibration Orientation and mountingVisibility of tags Transmitters approved for Atex ZoneJumper settings Compartment tags and lockout deviceFault output levels SecurityRe-installing the circuit board compartment cover Remotely Mounting the Transmitter Installation dimensions for remote mounting Mounting the transmitter to a wall or other surface Connecting the transmitter to the sensor Cable typesTemperature ranges for jacket material Cable selection guidelinesWiring connections to sensor Guidelines for conduitGuidelines for cable gland Cable connections to sensors Sensor terminal designationsSensor wiring compartment and sensor wiring terminals Power Supply and Output Wiring Wiring guidelinesConnect power supply wiring Power supply wiring terminalsWire guidelines for DC power supply Connect output wiringMilliamp output Milliamp output performanceTypical Hart network wiring Milliamp output connected to Bell 202 multidrop networkCommunication tools connected to milliamp output Hart Communicator connectionsPulse output Wiring to pulse counter with internal pull-up resistor Wiring to Series 3000 applications platform with I/O cable Page Flowmeter Startup Customer serviceStartup procedures ZeroingOperating mode Diagnostic LEDStartup mode InitializationZeroing procedure Flowmeter zeroingConfiguration, calibration, and characterization Diagnosing zero failureProcess measurement Page Configuration with a Hart Communicator Configuration overviewConfiguration parameters Hart tagMeasurement units Measurement units for mass and volume flow Mass flow unit Software label Volume flow unitFlow cutoff DampingFlow direction Effect of flow direction on outputs and totalizersRange values for milliamp output Pulse output scalingCalibration procedures Auto zeroFlow calibration procedure Diagnosing zeroing failureTotal Characterization Configuration with ProLink II Software Configuration window Device panel Configuration window Flow panel Process variable measurementMass flow unit Software label Volume flow unit Effect of flow direction on outputs and totalizers Output configuration Configuration window Analog Output panelConfiguration window Frequency panel Configuration with ProLink II Software Flow Calibration dialog box Diagnosing zeroing failure Totalizer Control window Characterization Configuration window Density panel Troubleshooting Transmitter diagnostic toolsGeneral guidelines Fault outputs Optional LCDNormal conditions indicated by LED Power supply Conditions indicated by optional LCDPower supply connections WiringNormal resistance and voltage ranges for flowmeter circuits Over range and sensor failure conditionsTroubleshooting over range and sensor failure conditions Slug flowDigital diagnostic messages Transmitter failurePage Functional specifications Output signals Milliamp active IFT9701 SpecificationsPerformance specifications Pulse passivePower supply options 85 to 250 VAC Fault indicationOutput testing Current source Local display optional20 to 30 VDC Environmental limits Temperature OperatingProcess fluid vs. ambient temperature StorageHumidity limits Vibration limitsDensity limits Environmental effects Ambient temperature effect on milliamp outputShipping weight Hazardous area classificationsPage Appendix B Hart Communicator Menu TreesHart Communicator Menu Trees Installing the Optional Display Appendix CInstalling the Optional Display Return Policy New and unused equipmentUsed equipment Page Index AtexHart Customer service Index Page 3100572