MAN_1000-2000_PN 36002004-EU_B_2002-01_EN

Installation InstructionsP/N 3600204-EU, Rev. B (01/02)January 2002

Series 1000 and 2000TransmittersInstallation and Operation Manual

www.micromotion.com

Series 1000 and 2000TransmittersInstallation and Operation Manual

For technical assistance, telephone the Micro MotionCustomer Service Department:• In the U.K., phone 0800-966 180 (toll-free)• Outside the U.K., phone +31 (0) 318 549 443• Or visit us on the Internet: www.micromotion.com

Contents

1 Installing the Transmitter. . . . . . . . . . . . . . . . . . . . . . 11.1 Overview . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 11.2 Safety. . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 11.3 Determining an appropriate location . . . . . . . . . . . . . . . . . . . . 1

Environmental requirements. . . . . . . . . . . . . . . . . . . . . . . . . . . 1Wire distances. . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 2Hazardous area classifications . . . . . . . . . . . . . . . . . . . . . . . . . 2

1.4 Mounting the transmitter remotely from the sensor . . . . . . . . 2Installing the remote mount transmitter . . . . . . . . . . . . . . . . . 3Mounting the transmitter/core processor assembly remotely

from the sensor. . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 71.5 Rotating an integrally mounted transmitter . . . . . . . . . . . . . . 81.6 Connecting the transmitter wires . . . . . . . . . . . . . . . . . . . . . . . 91.7 Grounding the transmitter. . . . . . . . . . . . . . . . . . . . . . . . . . . . 121.8 Rotating the display . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 13

2 Starting the Flowmeter . . . . . . . . . . . . . . . . . . . . . . 152.1 Overview . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 152.2 Applying power . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 162.3 Performing a loop test . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 162.4 Trimming the milliamp output . . . . . . . . . . . . . . . . . . . . . . . . 192.5 Zeroing the flowmeter . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 202.6 Changing the RS-485 communication settings . . . . . . . . . . . . 22

Changing RS-485 options. . . . . . . . . . . . . . . . . . . . . . . . . . . . . 22

3 Using the Transmitter . . . . . . . . . . . . . . . . . . . . . . . 253.1 Overview . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 253.2 Viewing process variables . . . . . . . . . . . . . . . . . . . . . . . . . . . . 253.3 Responding to alarms . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 26

Viewing alarms . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 26Acknowledging alarms . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 27

3.4 Using the totalizers and inventories . . . . . . . . . . . . . . . . . . . . 28Viewing the mass totalizer. . . . . . . . . . . . . . . . . . . . . . . . . . . . 28Viewing the volume totalizer . . . . . . . . . . . . . . . . . . . . . . . . . . 29Viewing the mass inventory. . . . . . . . . . . . . . . . . . . . . . . . . . . 29Viewing the volume inventory . . . . . . . . . . . . . . . . . . . . . . . . . 30Starting the totalizers and inventories . . . . . . . . . . . . . . . . . . 30Stopping the totalizers and inventories . . . . . . . . . . . . . . . . . 31Resetting the mass totalizer . . . . . . . . . . . . . . . . . . . . . . . . . . 31Resetting the volume totalizer. . . . . . . . . . . . . . . . . . . . . . . . . 32Resetting both totalizers . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 32

Series 1000 and 2000 Transmitters 1

Contents continued

4 Changing the Transmitter Settings . . . . . . . . . . . . . . . 334.1 Overview. . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 334.2 Configuration map . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 334.3 Changing the measurement units. . . . . . . . . . . . . . . . . . . . . . 35

Mass-flow units . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 35Volume-flow units . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 36Density units . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 37Temperature units . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 38

4.4 Creating special measurement units . . . . . . . . . . . . . . . . . . . 38Special mass-flow unit . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 39Special volume-flow unit . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 40

4.5 Changing event settings . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 414.6 Changing the damping values. . . . . . . . . . . . . . . . . . . . . . . . . 42

Flow damping . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 42Density damping . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 43Temperature damping . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 43

4.7 Adjusting meter factors . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 444.8 Changing slug-flow limits and duration . . . . . . . . . . . . . . . . . 44

Low slug-flow limit. . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 44High slug-flow limit . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 45Slug-flow duration . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 46

4.9 Changing low-flow cutoff . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 46Mass low-flow cutoff. . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 46Volume low-flow cutoff. . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 47

4.10 Changing the flow direction parameter . . . . . . . . . . . . . . . . . 474.11 Changing the software tag. . . . . . . . . . . . . . . . . . . . . . . . . . . . 484.12 Changing the display functionality. . . . . . . . . . . . . . . . . . . . . 48

Enabling and disabling display parameters. . . . . . . . . . . . . . 48Changing the scroll rate . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 50Changing the off-line password. . . . . . . . . . . . . . . . . . . . . . . . 50Changing the display variables. . . . . . . . . . . . . . . . . . . . . . . . 51

4.13 Assigning process variables to analog outputs. . . . . . . . . . . . 52With a Series 1000 transmitter. . . . . . . . . . . . . . . . . . . . . . . . 52With a Series 2000 transmitter. . . . . . . . . . . . . . . . . . . . . . . . 53

4.14 Changing the milliamp output . . . . . . . . . . . . . . . . . . . . . . . . 54Changing the upper range value. . . . . . . . . . . . . . . . . . . . . . . 54Changing the lower range value . . . . . . . . . . . . . . . . . . . . . . . 55Changing damping. . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 56Changing the fault output indicator . . . . . . . . . . . . . . . . . . . . 56

4.15 Changing the frequency output. . . . . . . . . . . . . . . . . . . . . . . . 57Changing the output scale. . . . . . . . . . . . . . . . . . . . . . . . . . . . 57Changing the fault output indicator . . . . . . . . . . . . . . . . . . . . 60Changing the pulse width . . . . . . . . . . . . . . . . . . . . . . . . . . . . 60

4.16 Changing the fault timeout parameter. . . . . . . . . . . . . . . . . . 614.17 RS-485 communication settings . . . . . . . . . . . . . . . . . . . . . . . 614.18 HART® burst mode. . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 63

Enabling and disabling burst mode . . . . . . . . . . . . . . . . . . . . 63Changing the burst mode setting . . . . . . . . . . . . . . . . . . . . . . 64

4.19 Changing the polling address . . . . . . . . . . . . . . . . . . . . . . . . . 644.20 Entering milliamp and frequency range values with

the display . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 65

2 Series 1000 and 2000 Transmitters

Contents continued

5 Characterizing and Calibrating . . . . . . . . . . . . . . . . . 675.1 Overview . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 675.2 Characterizing the flowmeter . . . . . . . . . . . . . . . . . . . . . . . . . 67

When to characterize . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 67How to characterize . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 67

5.3 Calibrating the flowmeter . . . . . . . . . . . . . . . . . . . . . . . . . . . . 69When to calibrate . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 69How to calibrate for density . . . . . . . . . . . . . . . . . . . . . . . . . . . 69Density calibration with a HART® Communicator. . . . . . . . . 70Density calibration with ProLink II™ software . . . . . . . . . . . 73How to calibrate for temperature . . . . . . . . . . . . . . . . . . . . . . 75Temperature calibration with ProLink II™ software . . . . . . . 75

6 Troubleshooting . . . . . . . . . . . . . . . . . . . . . . . . . . . 776.1 Overview . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 776.2 Transmitter does not operate. . . . . . . . . . . . . . . . . . . . . . . . . . 776.3 Transmitter does not communicate . . . . . . . . . . . . . . . . . . . . . 776.4 Zero or calibration failure . . . . . . . . . . . . . . . . . . . . . . . . . . . . 776.5 HART® output problems . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 776.6 Analog output problems . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 78

Fault conditions . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 786.7 Status alarms . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 786.8 Diagnosing wiring problems . . . . . . . . . . . . . . . . . . . . . . . . . . 81

Checking the power-supply wiring . . . . . . . . . . . . . . . . . . . . . 81Checking the core processor-to-transmitter wiring . . . . . . . . 82Checking the communication loop . . . . . . . . . . . . . . . . . . . . . . 82

6.9 Checking the receiving device . . . . . . . . . . . . . . . . . . . . . . . . . 826.10 Setting the HART® polling address to zero. . . . . . . . . . . . . . . 826.11 Checking the upper and lower range values. . . . . . . . . . . . . . 826.12 Checking the frequency output scale and method . . . . . . . . . 826.13 Checking the characterization . . . . . . . . . . . . . . . . . . . . . . . . . 826.14 Checking the calibration . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 836.15 Checking the test points. . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 83

Obtaining the test points . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 83Evaluating the test points . . . . . . . . . . . . . . . . . . . . . . . . . . . . 84Excessive drive gain . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 84Erratic drive gain . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 84Bad pickoff voltage . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 85

6.16 Contacting customer service . . . . . . . . . . . . . . . . . . . . . . . . . . 85


Contents continued

Appendix A: Specifications . . . . . . . . . . . . . . . . . . . . . . 87A.1 Functional specifications . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 87

Electrical connections . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 87Input/output signals. . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 87Digital communications . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 88Power supply . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 88Environmental requirements . . . . . . . . . . . . . . . . . . . . . . . . . 88Electromagnetic interference effects. . . . . . . . . . . . . . . . . . . . 88

A.2 Hazardous area classifications . . . . . . . . . . . . . . . . . . . . . . . . 89UL and CSA . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 89CENELEC compliance. . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 89

A.3 Performance specifications . . . . . . . . . . . . . . . . . . . . . . . . . . . 89A.4 Physical specifications . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 90

Field-mount housing . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 90Mounting . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 90Interface/display. . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 91Weight. . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 91Dimensions . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 91

Appendix B: Using the HART® Communicator. . . . . . . . . . 95B.1 Overview. . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 95B.2 Connecting the HART® Communicator . . . . . . . . . . . . . . . . . 95

Connecting to communication terminals . . . . . . . . . . . . . . . . 95Connecting to a multidrop network . . . . . . . . . . . . . . . . . . . . 96

B.3 Conventions used in this manual . . . . . . . . . . . . . . . . . . . . . . 96B.4 HART® Communicator safety messages and notes . . . . . . . . 96B.5 HART® Communicator menu tree. . . . . . . . . . . . . . . . . . . . . . 96

Appendix C: Using ProLink II™ Software . . . . . . . . . . . . . 99C.1 Overview. . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 99C.2 Connecting to a personal computer. . . . . . . . . . . . . . . . . . . . . 99

Connecting to communication terminals . . . . . . . . . . . . . . . . 99Connecting to a RS-485 or Bell 202 standard network . . . . 100Connecting to the service port. . . . . . . . . . . . . . . . . . . . . . . . 101

Appendix D: Using the Display . . . . . . . . . . . . . . . . . . . 103D.1 Overview. . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 103D.2 Components . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 103D.3 Menu tree . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 103

Appendix E: Return Policy . . . . . . . . . . . . . . . . . . . . . . 105

Index . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 109


1 Installing the Transmitter

1.1 Overview This section describes how to install the Micro Motion® Series 1000 and 2000 transmitters. These procedures will enable you to:

• Determine an appropriate location to install the transmitter

• Mount the transmitter remotely from or integral to the sensor

• Rotate an integrally mounted transmitter

• Connect the transmitter wires

• Rotate the display

1.2 Safety Safety messages are provided throughout this manual to protect personnel and equipment. Read each safety message carefully before proceeding to the next step.

1.3 Determining an appropriate location

To determine an appropriate location for the transmitter, you must consider the transmitter’s environmental requirements, wire distances, accessibility for maintenance, visibility of the display (if it is equipped with a display), and hazardous area classification.

Environmental requirements

Install the transmitter in an environment where ambient temperature is between –37 and 60°C.

I IMPORTANT

Procedures and instructions in this manual may require special precautions. Actions that raise potential safety issues are preceded by a safety message. Read each safety message before performing the task that follows the message.


Installing the Transmitter continued

Wire distances Power sourceConnect to a voltage source of 18–100 VDC or 85–250 VAC.

• The transmitter automatically recognizes the source voltage.

• Install up to 300 meters of 0,8 mm2 or larger wire. At distances approaching 300 meters, a minimum DC input of 22 V is required.

Core processor to remote-mount transmitter• Install up to 100 meters of 0,35 mm2 or up to 300 meters of 0,8mm2

4-wire twisted-pair instrument cable.

• Install shielded wiring with drain wires connected at both ends or unshielded wiring in continuous metallic conduit that provides 360° termination shielding for the enclosed wiring.

Hazardous area classifications

If you plan to mount the transmitter in a hazardous area, verify that the transmitter has the appropriate hazardous area approval. Each transmitter has a hazardous area approval tag attached to the outside of the transmitter housing.

For more information about hazardous area classifications, see the instruction manual shipped with the transmitter.

1.4 Mounting the transmitter remotely from the sensor

Mounting the transmitter apart from the sensor involves attaching it to an instrument pole or wall with the mounting bracket. The bracket will accommodate either of two possible mounting configurations:

• Mount the transmitter apart from the sensor and core processor assembly.

• Mount the transmitter with core processor assembly apart from the sensor.

Instrument pole and wall-mount options for either of the two possible mounting configurations are shown in Figure 1-1. You can mount the transmitter in any orientation as long as the conduit openings do not point upward.



Figure 1-1. Instrument pole or wall mount

Installing the remote mount transmitter

The following procedure assumes that the core processor is attached to the sensor. To mount the transmitter apart from the sensor and core processor assembly:

1. Refer to the components in Figure 1-1 and Figure 1-2, page 5.

2. Remove the junction end-cap from the junction housing (see Figure 1-2, page 5).

3. If desired, re-orient the transmitter on the bracket:a. Using a 4mm hex key, loosen each of the four cap screws in the

junction housing three or four turns (see Figure 1-2, page 5).b. Rotate the bracket so the transmitter is oriented as desired.c. Tighten the cap screws, torquing to 3-4N-m.

Mounting bracket(instrument pole mount)

Mounting bracket (wall mount)

TRANSMITTER ALONE

TRANSMITTER WITH CORE PROCESSOR ATTACHED

Mounting bracket

CAUTION

Condensation or excessive moisture entering the transmitter could damage the transmitter and result in measurement error or flowmeter failure.

• Ensure the integrity of gaskets and O-rings.• Do not mount the transmitter with the conduit openings

pointing upward.• Install drip legs if a conduit is used.• Seal the conduit openings.• Fully tighten the transmitter cover.



4. Securely mount the bracket and transmitter to a panel or an instrument pole.

5. Use one of these methods to shield the wiring from the core processor to the transmitter:a. Connect the drain wires to the ground screws in the junction

housing and core processor, orb. If wiring is in metallic conduit, make sure the conduit provides

360° termination shielding for the enclosed wiring.

6. Connect wiring from the core processor on the sensor to the transmitter.a. Prepare wiring for connection by cutting back sheathing and

stripping wire ends. If you are using shielded wiring, unwind drain wires back to sheathing and twist the ends together for grounding.

b. Pull the mating connector out of the junction housing.c. Pass the cable end through the conduit opening in the junction

housing.d. Connect the four wires to the numbered slots on the mating

connector, matching corresponding numbered terminals on the core processor.

e. Plug the mating connector into the socket in the junction housing.

f. If you are using cable shields for grounding, connect the shield wire ends to the ground screw (see Figure 1-3, page 5).

7. Reattach the junction end-cap, tightening until O-ring seats.



Figure 1-2. Remote mount transmitter components

Figure 1-3. Remote-mount transmitter, junction end-cap removed

Figure 1-4. Sensor and core processor, exploded view

Ground lug

Bracket

Main enclosure

Junction housing

Mating connector socket

Mating connector

Junction end-cap

Conduit opening for sensor interface

Ground screw

Cap screws

Core processor cover

Core processor

Sensor



Figure 1-5. Connecting the mating connector to the core processor

Connect the four color-coded wires to the numbered slots on the mating

connector. Connect the opposite end of each color-coded wire to the

same-numbered terminal on the core processor.

Mating connector socket

Main enclosure

Color-coded wires

Coreprocessor

Mating connectorUse the grounds screws to

connect ground wiring at both ends.

Ground screw



Mounting the transmitter/core processor assembly remotely from the sensor

The following procedure assumes that the core processor is attached to the transmitter. To mount the transmitter and core processor assembly remotely from the sensor:

1. Attach the mounting bracket to an instrument pole or wall.

2. Remove the lower conduit ring and the end-cap from the bottom of the transmitter and core processor assembly (see Figure 1-6).

3. Place the transmitter and core processor assembly onto the mounting bracket.

4. Replace the lower conduit ring, clamping the mounting bracket between the core processor and the conduit ring as shown in Figure 1-1, page 3.

5. Connect the transmitter end of a Micro Motion 9-wire flowmeter cable to the underside of the core processor. Refer to the manual shipped with the cable for flowmeter cable preparation and wiring instructions.

6. Replace the end cap on the conduit ring.

Figure 1-6. Transmitter/core processor assembly exploded view

Lower conduit ring

End cap

Mounting bracket



1.5 Rotating an integrally mounted transmitter

You can rotate an integrally mounted transmitter on the sensor up to 360° in 90° increments to one of four possible positions. See Figure 1-7.

Figure 1-7. Rotating the transmitter

To rotate the transmitter on the core processor:

1. Push down and turn the transmitter counterclockwise (approximately 1/8 turn) to disengage the transmitter at the transition.

2. Rotate the transmitter to the desired position.

3. Align the camlock pins (not shown) with the grooves on the transition.

4. Push down and turn the transmitter clockwise to lock it into place on the sensor.

WARNING

Twisting the core processor will damage the sensor.

Do not twist the core processor.

CAUTION

To avoid damaging the wires that connect the transmitter to the core processor, do not move the transmitter more than a few inches from the core processor.

Transition

Core processor

Transmitter

Sensor



1.6 Connecting the transmitter wires

There are multiple ways to connect the transmitter wires depending upon how you will use the HART®or Modbus® protocol or analog functionality. Pages 10 and 11 provide several possible configurations, including:

• Analog wiring (Figure 1-8, page 10)

• HART/analog single-loop wiring (Figure 1-9, page 10)

• RS-485 point-to-point wiring (Figure 1-10, page 11)

• HART multidrop wiring with SMART FAMILY® transmitters and a configuration tool (Figure 1-11, page 11)

WARNING

Hazardous voltage can cause severe injury or death.

Shut off the power before wiring the transmitter.

WARNING

A transmitter that has been improperly wired or installed in a hazardous area could cause an explosion.

• Make sure the transmitter is wired to meet or exceed local code requirements.

• Install the transmitter in an environment that complies with the classification tag on the transmitter. See Hazardous area classifications, page 89.



Figure 1-8. Analog wiring

Figure 1-9. HART/analog single-loop wiring

Milliamp (mA) receiving device reports mass flow, volume flow, temperature, or density. See Assigning process variables to analog outputs, page 52.

Frequency receiving devicereports mass flow or volume flow. See Assigning

process variables to analog outputs, page 52.

Power supply85–265 VAC,

50/60 Hz,18–100 VDC

+–

+–

HART-compatible host

or controller


50/60 Hz,18–100 VDC

mA receiving device

+

–



Figure 1-10. RS-485 point-to-point wiring

Figure 1-11. HART multidrop wiring with SMART FAMILY transmitters and a configuration tool


50/60 Hz,18–100 VDC

Primarycontroller

Multiplexer

Other devices

RS-485A

RS-485B

Note: The RS-485 communication wires must be shielded.

––Note: For optimum HART communication, make sure the output loop is single point, grounded to an instrument-grade ground.

HART® Communicator or interface for ProLink II™ or

AMS software

250 Ω loop resistance

HART-compatible transmitters SMART FAMILY™

transmitters

24 VDC loop power supply required for HART 4–20 mA passive transmitters

+ +



1.7 Grounding the transmitter Ground the transmitter and the sensor independently.

The transmitter can be grounded via the piping, if joints in the pipeline are ground-bonded, or by means of a ground screw on the outside of the core processor housing.

The transmitter is grounded by means of a ground screw on the outside of the transmitter housing. If national standards are not in effect, adhere to these transmitter grounding guidelines:

• Use copper wire, 2,5mm2 or larger

• Keep all ground leads as short as possible

• Ground leads must have less than 1 Ω impedance

• Connect ground leads directly to earth, or follow plant standards

WARNING

Improper grounding could cause measurement error.

To reduce the risk of measurement error:• Ground the flowmeter to earth, or follow ground network

requirements for the facility.• For installation in an area that requires intrinsic safety,

refer to Micro Motion UL, CSA, or CENELEC installation instructions.

• For hazardous area installations in Europe, refer to standard EN 60079-14 if national standards do not apply.



1.8 Rotating the display You can rotate the display on the transmitter up to 360° in 90° increments.

To rotate the display, complete the following procedure:

1. Remove the end-cap clamp by removing the cap screw. See Figure 1-12.

2. Turn the display cover counterclockwise to remove it from the main enclosure.

3. Carefully loosen (and remove if necessary) the semicaptive display screws while holding the display module in place.

4. Carefully pull the display module out of the main enclosure until the sub-bezel pin terminals are disengaged from the display module.

5. Rotate the display module to the desired position.

6. Insert the sub-bezel pin terminals into the display module pin holes to secure the display in its new position.

7. If you have removed the display screws, then reinsert and tighten them.

8. Place the display cover onto the main enclosure. Turn the display cover clockwise until it is snug.

9. Replace the end-cap clamp by reinserting and tightening the cap screw.

WARNING

Removing the display cover in explosive atmospheres while the power is on can cause an explosion.

Do not remove the display cover in explosive atmospheres before shutting off the power and waiting the required delay time as indicated on the transmitter housing.

WARNING

Using a dry cloth to clean the display cover can cause static discharge, which could result in an explosion in an explosive atmosphere.

Always use a damp cloth to clean the display cover in an explosive atmosphere.


Figure 1-12. Display components

Display cover

Display screws

Display module

Main enclosure

Sub-bezel

Pin terminals

Cap screw

End-cap clamp


2 Starting the Flowmeter

2.1 Overview This section describes the procedures you should perform the first time you start the flowmeter. You do not need to use these procedures every time you cycle power to the flowmeter.

The procedures in this chapter will enable you to:

• Apply power to the flowmeter

• Perform a loop test on the transmitter

• Trim the mA output, if necessary

• Zero the flowmeter

Figure 2-1 provides an overview of the flowmeter startup procedures.

Figure 2-1. Startup procedures

Note: All HART Communicator key sequences provided in this section assume that you are starting from the “Online” menu. See Using the HART Communicator, page 95.

Note: All ProLink II procedures provided in this section assume that your computer is already connected to the transmitter and you have established communication. See Using ProLink II Software, page 99.

Finish

Zero the flowmeter.

Start

Apply power.Perform aloop test.

Trim mA output (if

necessary).

Perform these steps if you are usinganalog outputs.


Starting the Flowmeter continued

2.2 Applying power Before you apply power to the flowmeter, close and tighten all housing covers.

Turn on the electrical power at the power supply. The flowmeter will automatically perform diagnostic routines. When the flowmeter has completed its power-up sequence, the display status indicator will turn green and begin to flash (if the transmitter is equipped with a display).

2.3 Performing a loop test A loop test is a means to:

• Verify that analog outputs (mA and frequency) are being sent by the transmitter and received accurately by the receiving devices

• Determine whether or not you need to trim the mA output

You can perform a loop test with a HART Communicator, the display, or ProLink II software.

With a HART CommunicatorTo perform a loop test with a HART Communicator:

1. Press 2.

2. Select Loop test.

3. Select Fix Analog Out 1.

4. Select 4 mA.

5. Read the mA output at the receiving device or another point on the loop. The reading should be near 4 mA.

Note: The 4 mA reading does not need to be exact at this point. You will correct differences when you trim the mA output. See Trimming the milliamp output, page 19.

6. If you don’t get a reading, then the loop test has failed. Abort the loop test and see Table 6-1, page 78.

7. Select End.

8. Select Fix frequency out.

9. Select 10 KHz.

10. Read the frequency output at the receiving device or another point on the loop. The reading should be 10 kilohertz (KHz).


12. Select “End.”

WARNING

Operating the flowmeter without covers in place creates electrical hazards that can cause death, injury, or property damage.

Make sure safety barrier partition and covers for the field-wiring, circuit board compartments, electronics module, and housing are all in place before applying power to the transmitter.



With the displayTo perform a loop test with the display:

1. Simultaneously press and hold Scroll and Select for 4 seconds. When SEE ALARM or OFF-LINE MAINT appears on the display, then release the buttons.

2. If OFF-LINE MAINT does not appear on the screen, then press Scroll until OFF-LINE MAINT appears.

3. Press Select.

4. If CODE? appears on the display, then enter the off-line password (see Changing the off-line password, page 50):a. Press Scroll to select the first number (0–9) of the off-line

password.b. When you see the correct number, press Select. The selection

moves over by one decimal place so you can enter the next digit.

c. Repeat steps a and b until you complete the four-digit password.

5. Press Scroll until OFF-LINE SIM appears on the display. See Figure 2-2, page 17.

Figure 2-2. Loop test with the display

6. Press Select.

7. Press Scroll until one of three possible test points appears: 4 mA, 12 mA, or 20 mA.

8. Press Select. The transmitter begins to simulate its mA output. Dots will traverse the top line of the display while the loop test is in progress.

9. Read the mA output at the receiving device. The reading should be near the test point value you selected in Step 7.

Note: The mA reading does not need to be exact at this point. You will correct differences when you trim the mA output. See Trimming the milliamp output, page 19.


Scroll button Select button



11. Press Select to stop the simulation.

12. Press Scroll until one of two possible test points appears: 1 KHz or 10 KHz.

13. Press Select. The transmitter begins to simulate its KHz output. Dots will traverse the top line of the display while the loop test is in progress.

14. Read the frequency output at the receiving device. The reading should be the test point value you selected in Step 12.


16. Press Select to stop the simulation.

17. Press Scroll until OFF-LINE EXIT appears on the display.

18. Press Select to exit off-line mode.

With ProLink II softwareTo perform a loop test with ProLink II software:

1. Click ProLink.

2. Select Test.

3. Select Fix Freq Out.

4. Type the number of pulses per second that you want the transmitter to report. The number of pulses can be any number within the frequency range of the transmitter.

5. Click Do Cal.

6. Read the frequency output at the receiving device. The reading should be the value you typed in Step 4.


8. Click Stop.

9. Click ProLink.

10. Select Test.

11. Select Fix Milliamp 1.

12. Type the number of mA pulses that you want the transmitter to report. The number of pulses can be any number within the mA range of the transmitter.

13. Click Do Cal.

14. Read the mA output at the receiving device. The reading should be near the value you typed in Step 12.

Note: The mA reading does not need to be exact. You will correct differences when you trim the mA output. See Trimming the milliamp output, below.


16. Click Stop. The loop test is complete



2.4 Trimming the milliamp output

Trimming the mA output creates a common measurement range between the transmitter and the device that receives the mA output. For instance, a transmitter might send a 4 mA signal that the receiving device reports incorrectly as 3,8 mA. If the transmitter output is trimmed correctly, it will send a signal appropriately compensated to ensure that the receiving device actually indicates a 4 mA signal.

You must trim the output at both the 4 mA and 20 mA points to ensure appropriate compensation across the entire range of outputs.

You can trim the output with the HART Communicator or ProLink II software.

With a HART CommunicatorTo trim the mA output with a HART Communicator:

1. Press 2.

2. Select Trim Analog Out 1.

3. Read the mA output at the receiving device.

4. Return to the HART Communicator.

5. Type the value that you read at the receiving device. The value can contain up to two decimal places.

6. Press F4 ENTER.

7. Read the mA output again at the receiving device.

8. If the receiving device and the HART Communicator readings are NOT equal, then press 2 NO. Repeat Step 3 through Step 7 until the outputs are equal.

9. If the receiving device and the HART Communicator readings are equal, then press 1 YES. The HART Communicator will proceed to the 20 mA trim.

10. Repeat the procedure beginning with Step 3.

After you have completed the 20 mA trim, the procedure is complete.

With ProLink II softwareTo trim the mA output with ProLink II software:

1. Select Milliamp Trim from the Calibrate menu.

2. Click OK to begin the 4 mA trim.

3. Read the mA output at the receiving device.

4. Type the value that you read at the receiving device in the Enter Meas box.

5. Click Do Cal.

6. Read the mA output again at the receiving device.

7. If the receiving device and the ProLink II software readings are NOT equal, then click No and go to Step 4.

8. If the receiving device and the Prolink II software readings are equal, then click Yes.

9. Click OK to begin the 20 mA trim.

10. Repeat the procedure beginning with Step 3.

Once you have completed the 20 mA trim, the procedure is complete.



2.5 Zeroing the flowmeter Zeroing the flowmeter establishes the flowmeter’s point of reference when there is no flow.

When you zero the flowmeter, you may need to adjust the zero time parameter. Zero time is the amount of time the transmitter takes to determine its zero-flow reference point. The default zero time is 20 seconds.

• A long zero time may produce a more accurate zero reference but is more likely to result in a zero failure.

• A short zero time is less likely to result in a zero failure but may produce a less accurate zero reference.

You can zero the flowmeter with a HART Communicator, the display, or ProLink II software.

With a HART CommunicatorTo zero the flowmeter with a HART Communicator:

1. Apply power to the flowmeter. Allow the flowmeter to warm up for approximately 30 minutes.

2. Run the process fluid through the sensor until the sensor temperature approximates the normal process operating temperature.

3. Close the shutoff valve downstream from the sensor.

4. Ensure that the sensor is completely filled with fluid.

5. Ensure that the process flow has completely stopped.

6. Press 2, 3, 1.

7. Look at the number of seconds to the right of Zero time.

8. If you want to change the zero time, then:a. Select Zero time.b. Type a new zero time.c. Press F4 OK.

9. Select Perform auto zero.

10. If Auto Zero Failed appears on the HART Communicator, then the zero procedure failed. See Zero or calibration failure, page 77.

11. If Auto Zero Passed appears on the HART Communicator, then the zero procedure succeeded.

12. Press F4 OK.

With the displayIf the off-line menu has been disabled, you will not be able to zero the transmitter with the display. For information about enabling and disabling the off-line menu, see Enabling and disabling display parameters, page 48.

To zero the flowmeter with the display:

Note: You cannot change the zero time with the display. If you need to change the zero time, you must use ProLink II software.




2. Run the process fluid through the sensor until the sensor temperature approximates the normal process operating temperature.




6. Simultaneously press and hold Scroll and Select for 4 seconds. When SEE ALARM or OFF-LINE MAINT appears on the display, then release the buttons.

7. If OFF-LINE MAINT does not appear on the screen, then press Scroll until OFF-LINE MAINT appears.

8. Press Select.





10. Press Scroll until OFF-LINE ZERO appears on the display.

11. Press Select. Dots will traverse the top line of the display while the zero is in progress.

12. If ZERO FAIL appears on the display, then the zero procedure failed. See Zero or calibration failure, page 77.

13. If ZERO OK appears on the display, then the zero procedure succeeded.

14. Press Select until OFF-LINE EXIT appears on the display.

15. Press Select to exit off-line mode.

With ProLink II softwareTo zero the flowmeter with ProLink II software:


2. Run the process fluid through the sensor until the sensor temperature reaches the normal process operating temperature.




6. Select Zero Calibration from the Calibrate menu.

7. Type a new zero time in the Zero Time box or accept the default value.

8. Click Zero. The flowmeter will begin zeroing.

9. If the Zero Failure box appears, then the zero procedure failed. See Zero or calibration failure, page 77.

10. Click Done.



2.6 Changing the RS-485 communication settings

You can use the display to change the transmitter’s RS-485 communication settings. You can modify the following settings:

• Protocol

• Baud

• Parity

• Stop bits

• Address (protocol address)

Changing RS-485 options If the off-line menu has been disabled, you will not be able to change the RS-485 options with the display. For information about enabling and disabling the off-line menu, see Enabling and disabling display parameters, page 48.

To change the RS-485 options:

1. Simultaneously press and hold Scroll and Select for 4 seconds. When SEE ALARM appears on the screen, then release the buttons.

2. Press Scroll until OFFLINE CONFIG appears.

3. Press Select.





5. Press Scroll until CONFIG RS-485 appears on the display.

6. Press Select.

7. Press Scroll to loop through and select one of the following main-menu options:

- PROTOCOL/RS485- BAUD/RS485- PARITY/RS485- STOP/RS485- ADDRESS/RS485- EXIT

8. When the option you want is on the screen, press Select.

9. If you selected protocol, follow the steps below to select an RS-485 data protocol:a. Press Scroll to loop through and select one of the following

options:

- NONE- HART- M_RTU- M_ASCb. When the option you want is on the screen, press Select.c. To save and exit, skip to step 14.



10. If you selected baud, follow the steps below to select an RS-485 baud:a. Press Scroll to loop through and select one of the following

options:

- 1200- 2400- 4800- 9600- 19200- 38400b. When the option you want is on the screen, press Select.c. To save and exit, skip to step 14.

11. If you selected parity, follow the steps below to select an RS-485 parity:a. Press Scroll to loop through and select one of the following

options:

- ODD- EVEN- NONEb. When the option you want is on the screen, press Select.c. To save and exit, skip to step 14.

12. If you selected stop, follow the steps below to select RS-485 stop bits:a. Press Scroll to loop through and select one of the following

options:

- 1- 2b. When the option you want is on the screen, press Select.c. To save and exit, skip to step 14.

13. If you selected address, follow the steps below to read/write the polling address for the protocol configured:

Note: If the protocol is set at NONE, the address item will not appear. The address item allows users to enter the polling address.

a. Press Scroll to select the first number (0–9).b. When you see the correct number, press Select. The selection

moves over by one decimal place so you can enter the next digit in the protocol address.

c. Repeat steps a and b until you enter the entire address.d. When you are finished, press both Select and Scroll to save the

number.e. To save and exit, skip to step 14.

Note: To leave the current setting selected for any of the options in steps 9–13, press and hold both the Scroll and the Select buttons for about 4 seconds and you will be returned to the previous screen (step 7).

14. Press Scroll until EXIT appears.

15. Press Select.



3 Using the Transmitter

3.1 Overview This section describes how to use the transmitter in everyday operation. The procedures in this section will enable you to:

• View process variables

• Respond to alarms

• Use the totalizers and inventories

Note: All HART Communicator key sequences in this section assume that you are starting from the “Online” menu. See Using the HART Communicator, page 95.


3.2 Viewing process variables Process variables include measurements such as mass-flow rate, volume-flow rate, mass total, volume total, temperature, and density.

You can view process variables with a HART Communicator, the display, or ProLink II software.

With a HART CommunicatorTo view process variables with a HART Communicator:

1. Press 1, 1.

2. Scroll through the list of process variables by pressing the Down Arrow key.

3. Press the number corresponding to the process variable you wish to view.

With the displayThe display reports the abbreviated name of the process variable (e.g., DENS for density), the current value of that process variable, and the associated units of measure (e.g., g/cc).

To view a process variable with the display, press Scroll until the name of the desired process variable either:

• Appears on the process variable line

• Begins to alternate with the units of measure

With ProLink II softwareTo view process variables with ProLink II software:

1. Click Prolink.

2. Select Process Variables.


Using the Transmitter continued

3.3 Responding to alarms The transmitter broadcasts alarms whenever a process variable exceeds its defined limits or the transmitter detects a fault condition. For instructions regarding all the possible alarms, see Status alarms, page 78.

Viewing alarms You can view alarms with a HART Communicator, the display, or ProLink II software.

With a HART CommunicatorTo view alarms with a HART Communicator:

1. Press 1.

2. Select “View Status.”

3. Press F4 “OK” to scroll through the list of current alarms.

With the displayThe display reports alarms with a status indicator. See Figure 3-1. The status indicator can be in one of six possible states, as listed in Table 3-1.

Figure 3-1. Display alarm menu

Alarms reported by the display are arranged according to priority in an alarm queue. To view specific alarms in the queue:

Table 3-1. Priorities reported by the status indicator

Status indicator state Alarm priority

Green No alarm—normal operating mode

Flashing green Unacknowledged corrected condition

Yellow Acknowledged low severity alarm

Flashing yellow Unacknowledged low severity alarm

Red Acknowledged high severity alarm

Flashing red Unacknowledged high severity alarm

Statusindicator



1. Simultaneously press and hold Scroll and Select for 4 seconds. When the words “SEE ALARM” appear on the screen, then release the buttons. See Figure 3-1, page 26.

2. Press Select.

3. If the alternating words “ACK ALL” appear, then press Scroll.

4. If the words “NO ALARM” appear, then go to Step 6.

5. Press Scroll to view each alarm in the queue. See Status alarms, page 78, for an explanation of the alarm codes reported by the display.

6. Press Scroll until the word “EXIT” appears.

7. Press Select.

With ProLink II softwareTo view alarms with ProLink II software:

1. Click ProLink.

2. Select Status.

3. View the status indicators. Red status indicators indicate current status alarms.

Acknowledging alarms You can acknowledge alarms with the display.

Note: If the alarm menu has been disabled, then the display will not indicate an alarm condition.

To acknowledge alarms:

1. Simultaneously press and hold Scroll and Select for 4 seconds. When the words “SEE ALARM” appear on the screen, then release the buttons. See Figure 3-1, page 26.

2. Press Select.

3. If the words “NO ALARM” appear, then go to Step 8.

4. If you want to acknowledge all alarms, then:a. Press Scroll until the word “ACK” appears by itself. The word

“ACK” begins to alternate with the word “ALL?”b. Press Select.

Note: If the “acknowledge all alarms” feature has been disabled, then you must acknowledge each alarm individually. See Step 5.

5. If you want to acknowledge a single alarm, then:a. Press Scroll until the alarm you want to acknowledge appears.b. Press Select. The word “ALARM” begins to alternate with the

word “ACK.”c. Press Select to acknowledge the alarm.

6. If you want to acknowledge another alarm, then go to Step 3.

7. If you do NOT want to acknowledge any more alarms, then go to Step 8.

8. Press Scroll until the word “EXIT” appears.

9. Press Select.



3.4 Using the totalizers and inventories

The totalizers keep track of the total amount of mass or volume measured by the transmitter over a period of time. The totalizers can be viewed, started, stopped, and reset.

The Inventories track the same values as the totalizers but are normally never reset.

Viewing the mass totalizer You can view the current value of the mass totalizer with a HART Communicator, the display, or ProLink II software.

With a HART Communicator To view the current value of the mass totalizer with a HART Communicator:

1. Press 1, 1.

2. Select “Mass totl.”

With the displayTo view the current value of the mass totalizer with the display:

1. Press Scroll until the process variable “TOTAL” appears and the units of measure are mass units (e.g., kg, lb). See Figure 3-2, page 28.

2. Read the current value from the top line of the display.

Figure 3-2. Display totalizer

With ProLink II softwareTo view the current value of the mass totalizer with ProLink II software:

1. Click ProLink.


Current value

Units of measure

Processvariable line

Scroll button



Viewing the volume totalizer

You can view the current value of the volume totalizer with a HART Communicator, the display, or ProLink II software.

With a HART CommunicatorTo view the current value of the volume totalizer with a HART Communicator:

1. Press 1, 1.

2. Select “Vol totl.”

With the displayTo view the current value of the volume totalizer with the display:

1. Press Scroll until the process variable “TOTAL” appears and the units of measure are volume units (e.g., gal, cuft).


With ProLink II softwareTo view the current value of the volume totalizer with ProLink II software:

1. Click ProLink.


Viewing the mass inventory

You can view the current value of the mass inventory with a HART Communicator, the display, or ProLink II software.

With a HART CommunicatorTo view the current value of the mass inventory with a HART Communicator:

1. Press 1, 1.

2. Select “Mass inventory.”

With the displayTo view the current value of the mass inventory with the display:

1. Press Scroll until the process variable “TOTAL” appears and the word “MASSI” alternates with the units of measure.


With ProLink II softwareTo view the current value of the mass inventory with ProLink II software:

1. Click ProLink.




Viewing the volume inventory

You can view the current value of the volume inventory with a HART Communicator, the display, or ProLink II software.

With a HART CommunicatorTo view the current value of the volume inventory with a HART Communicator:

1. Press 1, 1.

2. Select “Vol inventory.”

With the displayTo view the current value of the volume inventory with the display:

1. Press Scroll until the process variable “TOTAL” appears and the word “LVOLI” alternates with the units of measure.


With ProLink II softwareTo view the current value of the volume inventory with ProLink II software:

1. Click ProLink.


Starting the totalizers and inventories

The totalizers and inventories are always started together.

You can start the totalizers and inventories with a HART Communicator, the display, or ProLink II software.

With a HART Communicator To start all totalizers and inventories with a HART Communicator:

1. Press 1, 4.

2. Select “Start totalizer.”

With the displayTo start all totalizers and inventories with the display:

1. Press Scroll until the process variable “TOTAL” appears.

2. Press Select.

3. Press Scroll. The word “START” appears beneath the current totalizer value.

4. Press Select. The word “YES?” begins to alternate with the word “START.”

5. Press Select to start all totalizers and inventories.

With ProLink II softwareTo start all totalizers and inventories with ProLink II software:

1. Click ProLink.

2. Select Totalizer Control.

3. Click Start.



Stopping the totalizers and inventories

The totalizers and inventories are always stopped together.

You can stop the totalizers and inventories with a HART Communicator, the display, or ProLink II software.

With a HART CommunicatorTo stop all totalizers and inventories with a HART Communicator:

1. Press 1, 4.

2. Select “Stop totalizer.”

With the displayTo stop all totalizers and inventories with the display:

1. Press Scroll until the process variable “TOTAL” appears.

2. Press Select.

3. Press Scroll until the word “STOP” appears beneath the current totalizer value.

4. Press Select. The word “YES?” begins to alternate with the word “STOP.”

5. Press Select to stop the totalizers and inventories.

With ProLink II softwareTo stop all totalizers and inventories with ProLink II software:

1. Click ProLink.


3. Click Stop.

Resetting the mass totalizer

Resetting the mass totalizer sets the mass total to zero.

You can reset the mass totalizer independent of the volume totalizer with a HART Communicator or the display.

With a HART CommunicatorTo reset the mass totalizer with a HART Communicator:

1. Press 1, 4.

2. Select “Reset mass total.”

With the displayIf the ability to reset totalizers has been disabled, you will not be able to reset the mass totalizer with the display. For information about enabling and disabling the display parameters, see Changing the display functionality, page 48.

To reset the mass totalizer with the display:

1. Press Scroll until the process variable “TOTAL” appears and the units of measure are mass units (e.g., kg, lb).

2. Press Select. The word “RESET” appears beneath the current totalizer value.

3. Press Select. The word “YES?” begins to alternate with the word “RESET.”

4. Press Select to reset the mass totalizer.



Resetting the volume totalizer

Resetting the volume totalizer sets the volume total to zero.

You can reset the volume totalizer independent of the mass totalizer with a HART Communicator or the display.

With a HART CommunicatorTo reset the volume totalizer with a HART Communicator:

1. Press 1, 4.

2. Select “Reset volume total.”

With the displayIf the ability to reset totalizers has been disabled, you will not be able to reset the volume totalizer with the display. For information about enabling and disabling the display parameters, see Changing the display functionality, page 48.

To reset the volume totalizer with the display:

1. Press Scroll until the process variable “TOTAL” appears and the units of measure are volume units (e.g., gal, ft3).

2. Press Select. The word “RESET” appears beneath the current totalizer value.

3. Press Select. The word “YES?” begins to alternate with the word “RESET.”

4. Press Select to reset the volume totalizer.

Resetting both totalizers Resetting both totalizers simultaneously sets the mass and volume totals to zero.

You can reset both totalizers with a HART Communicator or ProLink II software.

With a HART CommunicatorTo reset the mass and volume totalizers with a HART Communicator:

1. Press 1, 4.

2. Select “Reset all totals.”

With ProLink II softwareTo reset the mass and volume totalizers with ProLink II software:

1. Click ProLink.


3. Click Reset.


4 Changing the Transmitter Settings

4.1 Overview This section describes procedures for changing the operating settings of the transmitter. The procedures in this section will enable you to:

• Change the measurement units

• Create special measurement units

• Change event settings

• Change the damping and slug-flow values

• Change the low-flow cutoff

• Change the flow direction parameter

• Change the software tag

• Change the display functionality

• Assign process variables to analog outputs

• Change the mA output

• Change the frequency output

• Change the fault timeout parameter

• Change communications settings

Note: All HART Communicator key sequences in this section assume that you are starting from the “Online” menu. See Conventions used in this manual, page 96.


4.2 Configuration map Use the map in Figure 4-1, page 34, to guide you through a complete or partial configuration of the transmitter.

Aside from performing the startup procedures in Section 2, you should only change the transmitter’s settings if the application needs have changed or the transmitter is being put into a service other than the one for which it was ordered.Stop


Changing the Transmitter Settings continued

Figure 4-1. Configuration map

Lowslug-flow

limit

Slug flow Pages 44–46High

slug-flowlimit

Slug-flow duration

Upper range value

Frequencyoutput

mA output

Pages 54–56Lower range

valueDamping Fault output

Pages 57–60

Output scale Fault output Pulse width

Measurement units

Pages 35–38Mass-flow

units

Special measurement

unitsPages 38–40

Volume-flow units

Densityunits

Flowdamping

Damping Pages 42–43

Density damping

Low-flow cutoff Pages 46–47

Mass low-flow cutoff

Flow direction Page 47

Volume low-flow cutoff

Software tag Page 48

Enable and disable

Displayfunctionality

Pages 48–51Scroll rate Off-line

password

Fault timeout Page 61

Events Page 41

Temperature units

Display variables

Temperature damping

Series 1000 Transmitter

Analog outputvariables

Pages 52–53Series 2000 Transmitter

RS-485 settings HART burst mode Polling address

Mass-flow units

Volume-flow units

mA & Freq.range values

Communication Pages 61–65



4.3 Changing the measurement units

You can change the unit of measure used for each process variable with a HART Communicator or ProLink II software.

Mass-flow units You can change the mass-flow measurement unit with a HART Communicator or ProLink II software.

With a HART CommunicatorTo change the mass-flow measurement unit with a HART Communicator:

1. Press 4, 2, 1.

2. Select “Mass flo unit.”

3. Select a unit from the list. See Table 4-1 for a complete list of mass-flow measurement units.

4. Press F4 “ENTER.”

5. Press F2 “SEND.”

With ProLink II softwareTo change the mass-flow measurement unit with ProLink II software:

1. Click the Flow tab.

2. Click the arrow in the Mass Flow Units box, and select a measurement unit from the list.

3. Click Apply.

Table 4-1. Mass-flow measurement units

Mass-flow unit Unit description

g/s Grams per second

g/min Grams per minute

g/h Grams per hour

kg/s Kilograms per second

kg/min Kilograms per minute

kg/h Kilograms per hour

kg/d Kilograms per day

MetTon/min Metric tons per minute

MetTon/h Metric tons per hour

MetTon/d Metric tons per day

lb/s Pounds per second

lb/min Pounds per minute

lb/h Pounds per hour

lb/d Pounds per day

STon/min Short tons (2000 pounds) per minute

STon/h Short tons (2000 pounds) per hour

STon/d Short tons (2000 pounds) per day

LTon/h Long tons (2240 pounds) per hour

LTon/d Long tons (2240 pounds) per day

Spcl Special unit (See Creating special measurement units, page 38)



Volume-flow units You can change the volume-flow measurement unit with a HART Communicator or ProLink II software.

With a HART CommunicatorTo change the volume-flow measurement unit with a HART Communicator:

1. Press 4, 2, 1.

2. Select “Vol flo unit.”

3. Select a measurement unit from the list. See Table 4-2, page 36, for a complete list of volume-flow measurement units.



With ProLink II softwareTo change the volume-flow measurement unit with ProLink II software:


2. Click the arrow in the Vol Flow Units box, and select a measurement unit from the list.

3. Click Apply.Table 4-2. Volume-flow measurement units

Volume-flow unit Unit description

Cuft/s Cubic feet per second

Cuft/min Cubic feet per minute

Cuft/h Cubic feet per hour

Cuft/d Cubic feet per day

Cum/s Cubic meters per second

Cum/min Cubic meters per minute

Cum/h Cubic meters per hour

Cum/d Cubic meters per day

gal/s U.S. gallons per second

gal/min U.S. gallons per minute

gal/h U.S. gallons per hour

gal/d U.S. gallons per day

MMgal/d Million U.S. gallons per day

L/s Liters per second

L/min Liters per minute

L/hr Liters per hour

ML/d Million liters per day

Impgal/s Imperial gallons per second

Impgal/min Imperial gallons per minute

Impgal/h Imperial gallons per hour

Impgal/d Imperial gallons per day

bbl/s Barrels per second

bbl/min Barrels per minute



Density units You can change the density measurement units with a HART Communicator or ProLink II software.

With a HART CommunicatorTo change the density measurement unit with a HART Communicator:

1. Press 4, 2, 2.

2. Select “Dens unit.”

3. Select a unit from the list. See Table 4-3 for a complete list of density measurement units.



With ProLink II softwareTo change the density measurement unit with ProLink II software:

1. Click the Density tab.

2. Click the arrow in the Dens Units box, and select a measurement unit from the list.

3. Click Apply.

bbl/h Barrels per hour

bbl/d Barrels per day

Spcl Special unit (See Creating special measurement units, page 38)

Table 4-2. Volume-flow measurement units

Volume-flow unit Unit description

Table 4-3. Density measurement units

Density unit Unit description

SGU Specific gravity unit

g/Cucm Grams per cubic centimeter

kg/Cum Kilograms per cubic meter

lb/gal Pounds per gallon

lb/Cuft Pounds per cubic foot

g/mL Grams per milliliter

kg/L Kilograms per liter

g/L Grams per liter

lb/Cuin Pounds per cubic inch

STon/Cuyd Short ton per cubic yard



Temperature units You can change the temperature measurement unit with a HART Communicator or ProLink II software.

With a HART CommunicatorTo change the temperature measurement unit with a HART Communicator:

1. Press 4, 2, 3.

2. Select “Temp unit.”

3. Select a unit from the list. See Table 4-4 for a complete list of temperature measurement units.



With ProLink II softwareTo change the temperature measurement unit with ProLink II software:

1. Click the Temperature tab.

2. Click the arrow in the Temp Units box, and select a measurement unit from the list.

3. Click Apply.

4.4 Creating special measurement units

If you need to use a non-standard unit of measure, you can create one special measurement unit for mass flow and one special measurement unit for volume flow. Special measurement units consist of:

• Base unit—A combination of:

- Base mass or base volume unit—A measurement unit that the transmitter already recognizes (e.g., kg, m3)

- Base time unit—A unit of time that the transmitter already recognizes (e.g., seconds, days)

• Conversion factor—The number by which the base unit will be divided to convert to the special unit

• Special unit—A non-standard volume-flow or mass-flow unit of measure that you want to be reported by the transmitter

The terms above are related by the following formula:

Table 4-4. Temperature measurement units

Temperature unit Unit description

degC Degrees Celsius

degF Degrees Fahrenheit

degR Degrees Rankine

Kelvin Kelvin

Base unitSpecial unit------------------------------- Conversion factor=



To create a special unit, you must:

1. Identify the simplest base volume or mass and base time units for your special mass-flow or volume-flow unit. For example, to create the special volume-flow unit pints per minute, the simplest base units are gallons per minute:a. Base volume unit: gallonb. Base time unit: minute

2. Calculate the conversion factor using the formula below:

Note: 1 gallon per minute = 8 pints per minute

3. Name the new special mass-flow or volume-flow measurement unit and its corresponding totalizer measurement unit:a. Special volume-flow measurement unit name: Pint/minb. Volume totalizer measurement unit name: Pints

Note: Special measurement unit names can be up to 8 characters long (i.e., 8 numbers or letters), but only the first 5 characters appear on the display.

Special mass-flow unit You can create a special mass-flow measurement unit with a HART Communicator or ProLink II software.

With a HART CommunicatorTo create a special mass-flow measurement unit with a HART Communicator:

1. Press 4, 2, 1.

2. Select “Spcl mass units.”

3. Specify the base mass unit:a. Select “Base mass unit.”b. Select a mass unit from the list.c. Press F4 “ENTER.”

4. Specify the base mass time:a. Select “Base mass time.”b. Select a time unit from the list.c. Press F4 “ENTER.”

5. Specify the mass-flow conversion factor:a. Select “Mass flo conv fact.”b. Type a conversion factor. The value can contain up to 5 digits.c. Press F4 “ENTER.”

6. Assign a name to the new special mass-flow measurement unit:a. Select “Mass flo text.”b. Type the name of the special mass-flow measurement unit.c. Press F4 “ENTER.”

7. Assign a name to the mass totalizer measurement unit:a. Select “Mass totl text.”b. Type the name of the mass totalizer measurement unit.c. Press F4 “ENTER.”


1 (gallon per minute)8 (pints per minute)

------------------------------------------------------- 0,125 (conversion factor)=



With ProLink II softwareTo create a special mass-flow measurement unit with ProLink II software:

1. Click the Special Units tab.

2. Click the arrow in the Base Mass Unit box, and select a base mass unit from the list.

3. Click the arrow in the Base Mass Time box, and select a base time unit from the list.

4. Type the conversion factor in the Mass Flow Conv Fact box.

5. Type the name of the special mass-flow measurement unit in the Mass Flow Text box.

6. Type the name of the mass totalizer measurement unit in the Mass Total Text box.

7. Click Apply.

Special volume-flow unit You can create a special volume-flow measurement unit with a HART Communicator or ProLink II software.

With a HART CommunicatorTo create a special volume-flow measurement unit with a HART Communicator:

1. Press 4, 2, 1.

2. Select “Spcl vol units.”

3. Specify the base volume unit:a. Select “Base vol unit.”b. Select a volume unit from the list.c. Press F4 “ENTER.”

4. Specify the base time unit:a. Select “Base vol time.”b. Select a time unit from the list.c. Press F4 “ENTER.”

5. Specify the volume-flow conversion factor:a. Select “Vol flo conv fact.”b. Type a conversion factor. The value can contain up to 5 digits.c. Press F4 “ENTER.”

6. Assign a name to the new special volume-flow measurement unit:a. Select “Vol flo text.”b. Type the name of the special volume-flow measurement unit.c. Press F4 “ENTER.”

7. Assign a name to the volume totalizer measurement unit:a. Select “Vol totl text.”b. Type the name of the volume totalizer measurement unit.c. Press F4 “ENTER.”




With ProLink II softwareTo create a special volume-flow measurement unit with ProLink II software:

1. Click the Special Units tab.

2. Click the arrow in the Base Vol Units box, and select a volume unit from the list.

3. Click the arrow in the Base Vol Time box, and select a time unit from the list.

4. Type the conversion factor in the Vol Flow Conv Fact box.

5. Type the name of the special volume-flow measurement unit in the Vol Flow Text box.

6. Type the name of the volume totalizer measurement unit in the Vol Total Text box.

7. Click Apply.

4.5 Changing event settings Events are specified process variable levels that trigger alarms. You can set up to two events, either on the same process variable or on two different process variables. Each event is associated with either a high or a low alarm.

Before you set the events, determine the process variable, alarm type, and setpoint that will be associated with each event. Table 4-5 lists the process variables, alarm types, and setpoints you must specify for each event.

You can change the event settings with a HART Communicator or ProLink II software.

With a HART CommunicatorTo change the event settings with a HART Communicator:

1. Select the process variable:a. Press 4, 5.b. Select “Event 1” or “Event 2.”c. Press 1 “var.”d. Select a process variable from the list.e. Press F4 “ENTER.”f. Press F2 “SEND.”

Table 4-5. Event settings

Event number Process variable Alarm type Setpoint

Event 1 Any process variable for Event 1

• High alarm—Event 1 is triggered if the process variable exceeds the setpoint.

• Low alarm—Event 1 is triggered if the process variable drops below the setpoint.

The user-defined value at which the Event 1 alarm is triggered

Event 2 Any process variable for Event 2

• High alarm—Event 2 is triggered if the process variable exceeds the setpoint.

• Low alarm—Event 2 is triggered if the process variable drops below the setpoint.

The user-defined value at which the Event 2 alarm is triggered



2. Select the alarm type:a. Press 2 “type.”b. Select “High alarm” or “Low alarm.”c. Press F4 “OK.”d. Press F2 “SEND.”

3. Define the setpoint:a. Press 3 “setpoint.”b. Type the setpoint. The setpoint can contain up to 8 digits.c. Press F4 “ENTER.”d. Press F2 “SEND.”

With ProLink II softwareTo change the event settings with ProLink II software:

1. Click the Events tab.

2. Click the arrow in each Var box, and select a process variable.

3. Click the arrow in each Type box, and select an alarm type.

4. Type the setpoint level for each event in the Setpoint boxes.

5. Click Apply.

4.6 Changing the damping values

A damping value is a period of time, in seconds, that helps the transmitter smooth out small, rapid measurement fluctuations.

• A high damping value makes the output appear to be smoother because the output must change slowly.

• A low damping value makes the output appear to be more erratic because the output changes more quickly.

You can change the damping values for flow, density, and temperature.

Flow damping Flow damping affects mass flow and volume flow. You can change the flow damping value with a HART Communicator or ProLink II software.

With a HART CommunicatorTo change the flow damping value with a HART Communicator:

1. Press 4, 2, 1.

2. Select “Flo damp.”

3. Type a new damping value.



With ProLink II softwareTo change the flow damping value with ProLink II software:


2. Type a new damping value in the Flow Damp box.

3. Click Apply.



Density damping You can change the density damping value with a HART Communicator or ProLink II software.

With a HART CommunicatorTo change the density damping value with a HART Communicator:

1. Press 4, 2, 2.

2. Select “Dens damp.”




With ProLink II softwareTo change the density damping value with ProLink II software:


2. Type a new damping value in the Dens Damping box.

3. Click Apply.

Temperature damping You can change the temperature damping value with a HART Communicator or ProLink II software.

With a HART CommunicatorTo change the temperature damping value with a HART Communicator:

1. Press 4, 2, 3.

2. Select “Temp damp.”




With ProLink II softwareTo change the temperature damping value with ProLink II software:

1. Click the Temperature tab.

2. Type a new damping value in the Temp Damp box.

3. Click Apply.



4.7 Adjusting meter factors Meter factors allow you to modify the transmitter’s output so that it matches an external measurement standard. For example, if you need to fill a customer’s 500-gallon tank based on the customer’s definition of a gallon, you can use the meter factors to make the transmitter match the customer’s gallon definition.

You can adjust meter factors for mass flow, volume flow, and density.

• If you adjust the mass-flow or density meter factor, the volume meter factor defaults to 1.0000.

• If you adjust the volume-flow meter factor, the mass and density meter factors each default to 1.0000.

• Only values from 0,8 to 1,2 may be entered.

To determine a meter factor’s value, divide the value of the external standard by the actual output of the transmitter, as in the following formula:

For example, if the external standard states that the transmitter should have a flow output of 5 gallons for a given volume of fluid, then divide the transmitter’s actual output (in gallons) by 5. The result is the volume flow meter factor.

You can adjust meter factors with a HART Communicator.

To adjust the mass flow, volume flow, or density meter factor:

1. Press 4, 1, 5.

2. Select the meter factor you want to change.


4. Type a new meter factor value.


4.8 Changing slug-flow limits and duration

Slugs—gas in a liquid process or liquid in a gas process—occasionally appear in some applications. The presence of slugs can affect the process density reading dramatically. Slug-flow limits and duration can help the transmitter suppress dramatic changes in reading.

Low slug-flow limit The low slug-flow limit is the lowest point of the typical density range of the process you are measuring. The transmitter uses the low slug-flow limit to distinguish between normal process flow and slug flow.

You can change the low slug-flow limit with a HART Communicator or ProLink II software.

Meter factor External standardActual transmitter output-----------------------------------------------------------------=



With a HART CommunicatorTo change the low slug-flow limit with a HART Communicator:

1. Press 4, 2, 2.

2. Select “Slug low limit.”

3. Type a new low slug-flow limit.



With ProLink II softwareTo change the low slug-flow limit with ProLink II software:


2. Type a new low slug-flow limit in the Slug Low Limit box. The value must be between –0,1 and 5,0 g/cc.

3. Click Apply.

High slug-flow limit The high slug-flow limit is the highest point of the typical density range of the process you are measuring. The transmitter uses the high slug-flow limit to distinguish between normal process flow and slug flow.

You can change the high slug-flow limit with a HART Communicator or ProLink II software.

With a HART CommunicatorTo change the high slug-flow limit with a HART Communicator:

1. Press 4, 2, 2.

2. Select “Slug high limit.”

3. Type a new high slug-flow limit.



With ProLink II softwareTo change the high slug-flow limit with ProLink II software:


2. Type a new high slug-flow limit in the Slug High Limit box. The value must be between –0,1 and 5,0 g/cc.

3. Click Apply.



Slug-flow duration The slug-flow duration is the number of seconds the transmitter waits for a slug-flow condition (outside the slug-flow limits) to return to normal (inside the slug-flow limits). If the transmitter detects slug flow, it will post a slug-flow alarm and hold its last “pre-slug” flow rate until the end of the slug-flow duration. If slugs are still present after the slug-flow duration has expired, the transmitter will report a flow rate of zero.

You can change the slug-flow duration with a HART Communicator or ProLink II software.

With a HART CommunicatorTo change the slug-flow duration with a HART Communicator:

1. Press 4, 2, 2.

2. Select “Slug duration.”

3. Type a new slug-flow duration.



With ProLink II softwareTo change the slug-flow duration with ProLink II software:


2. Type a new slug-flow duration in the Slug Duration box.

3. Click Apply.

4.9 Changing low-flow cutoff Low-flow cutoff is a user-defined flow measurement below which the transmitter reports zero flow. Low-flow cutoff can be changed for either mass flow or volume flow.

Mass low-flow cutoff You can change the mass low-flow cutoff with a HART Communicator or ProLink II software.

With a HART CommunicatorTo change the mass low-flow cutoff with a HART Communicator:

1. Press 4, 2, 1.

2. Select “Mass flo cutoff.”

3. Type the new mass low-flow cutoff.



With ProLink II softwareTo change the mass low-flow cutoff with ProLink II software:


2. Type the new mass low-flow cutoff in the Mass Flow Cutoff box.

3. Click Apply.



Volume low-flow cutoff You can change the volume low-flow cutoff with a HART Communicator or ProLink II software.

With a HART CommunicatorTo change the volume low-flow cutoff with a HART Communicator:

1. Press 4, 2, 1.

2. Select “Vol flo cutoff.”

3. Type the new volume low-flow cutoff.



With ProLink II softwareTo change the volume low-flow cutoff with ProLink II software:


2. Type the new volume low-flow cutoff in the Vol Flow Cutoff box.

3. Click Apply.

4.10 Changing the flow direction parameter

The flow direction parameter defines whether the transmitter reports a positive or negative flow rate and how the flow is added to or subtracted from the totalizers.

Table 4-6 shows the possible values for the flow direction parameter and the transmitter’s behavior when the flow is positive or negative.

• Positive flow moves in the direction of the arrow on the sensor.

• Negative flow moves in the direction opposite of the arrow on the sensor.

Table 4-6. Transmitter behavior for each flow direction value

Flow direction value

Process fluid flow is positive Process fluid flow is negative

Milliamp and frequency outputs

Flow totals

Flow values on display or via digital comm.

Milliamp and frequency outputs

Flow totals

Flow values on display or via digital comm.

Forward only Increase Increase Read positive Zero No change Read negative

Reverse only Zero No change Read positive Increase Increase Read negative

Bidirectional Increase Increase Read positive Increase Decrease Read negative

Absolute value Increase Increase Read positive1 Increase Increase Read positive1

1. Refer to the digital communications status bits for an indication of whether flow is positive or negative.



You can change the flow direction parameter with a HART Communicator or ProLink II software.

With a HART CommunicatorTo change the flow direction parameter with a HART Communicator:

1. Press 4, 2, 1.

2. Select “Flo direction.”

3. Select a flow direction value. See Table 4-6.



With ProLink II softwareTo change the flow direction parameter with ProLink II software:


2. Click the arrow in the Flow Direction box, and select a flow direction value from the list. See Table 4-6.

3. Click Apply.

4.11 Changing the software tag The transmitter is capable of holding a software tag in its memory. The software tag is a short name or identifier for the transmitter.

You can change the software tag with a HART Communicator or ProLink II software.

With a HART CommunicatorTo change the software tag with a HART Communicator:

1. Press 3.

2. Select “Tag.”

3. Type the new software tag name. The name can contain up to 8 characters (i.e., 8 numbers or letters).



With ProLink II softwareTo change the software tag with ProLink II software:

1. Click the Device tab.

2. Type the desired software tag in the Descriptor box.

3. Click Apply.

4.12 Changing the display functionality

You can restrict the display functionality or change the variables that are shown on the display.

Enabling and disabling display parameters

Each display parameter is listed in Table 4-7.



You can enable and disable the display parameters with a HART Communicator or ProLink II software.

With a HART CommunicatorTo enable or disable the display parameters with a HART Communicator:

1. Press 4, 6.

2. Select “Enable/Disable.”

3. Select one of the display parameters listed.

4. Select “Enable” or “Disable.”



With ProLink II softwareTo enable or disable the display parameters with ProLink II software:

1. Click the Transmitter Options tab.

2. If you want to enable a display function, then select the checkbox next to the parameter name. Parameters with check marks next to them indicate enabled functions.

3. If you want to disable a display function, then clear the checkbox next to the parameter name. Parameters without checkmarks next to them indicate disabled functions.

4. Click Apply.

Table 4-7. Display parameters

Parameter Enabled Disabled

Totalizer reset Operators are able to reset the mass and volume totalizers.

Operators are prevented from resetting the mass and volume totalizers.

Auto scroll The display automatically scrolls through each process variable.

Operators must press the Scroll button to view process variables.

Off-line menu Operators have access to the off-line menu (zero and simulation).

Operators are prevented from gaining access to the off-line menu.

Off-line password Operators must use a password to gain access to the off-line menu. See Changing the off-line password, page 50.

Operators have access to the off-line menu without a password.

Alarm menu Operators have access to the alarm menu (viewing and acknowledging alarms).

Operators are prevented from gaining access to the alarm menu.

Acknowledge all alarms

Operators are able to acknowledge all current alarms at once.

Operators must acknowledge alarms individually.



Changing the scroll rate The scroll rate is the speed at which the defined display variables cycle on the display screen. A shorter scroll rate makes the variables cycle more quickly.

You can change the scroll rate with a HART Communicator or ProLink II software.

With a HART CommunicatorYou must enable auto scroll before the scroll rate will appear on the HART Communicator (see Enabling and disabling display parameters, page 48).

To change the display scroll rate with a HART Communicator:

1. Enable “Auto scroll” (see Enabling and disabling display parameters, page 48).

2. Select “Scroll Rate.”

3. Type the desired scroll rate (from 1 to 10 seconds).



With ProLink II softwareTo change the scroll rate with ProLink II software:

1. Click the Display Config tab.

2. Type the desired scroll rate (from 1 to 10 seconds) in the Scroll Rate box.

3. Click Apply.

Changing the off-line password

The off-line password prevents unauthorized users from gaining access to the off-line menu.

You can change the off-line password with a HART Communicator or ProLink II software.

With a HART CommunicatorYou must enable the off-line password before you can set the off-line password (see Enabling and disabling display parameters, page 48).

To change the off-line password with a HART Communicator:

1. Enable the off-line password (see Enabling and disabling display parameters, page 48).

2. Select “Offline Password.”

3. Type a new password. The password can contain up to four numbers.



With ProLink II softwareTo change the off-line password with ProLink II software:


2. Type the desired off-line password in the Display Offline Password box. The password can contain up to four numbers.

3. Click Apply.



Changing the display variables

The display can scroll through up to 15 process variables in any order. You can select the process variables you wish to see and the order in which they should appear. The first process variable is permanently set to the variable assigned to the mA output.

Table 4-8 shows an example of a display variable configuration. Notice that you can repeat variables.

You can change the display variables with a HART Communicator or ProLink II software.

With a HART CommunicatorTo change the display variables with a HART Communicator:

1. Press 4.

2. Select “Display Setup.”

3. Select the display variable number you want to change.

4. Select a process variable from the list.

Note: You can also select “None” from the list, which disables a variable from being shown in the position.


6. Repeat Step 2 through Step 5 to change the remaining display variables. You can select as many as 14 process variables.


Table 4-8. Example of a display variable configuration

Display variable Process variable

Display variable 11

1. Display variable 1 always represents the same process variable that is assigned to the mA output, and cannot be changed.

Mass flow

Display variable 2 Volume flow

Display variable 3 Density

Display variable 4 Mass flow


Display variable 6 Mass totalizer

Display variable 7 Mass flow

Display variable 8 Temperature


Display variable 10 Volume totalizer

Display variable 11 Density

Display variable 12 Temperature

Display variable 13 None





With ProLink II softwareTo change the display variables with ProLink II software:


2. Click the arrow in each variable’s box, and select a process variable from the list.

3. Click Apply.

4.13 Assigning process variables to analog outputs

Depending upon whether you are using a Series 1000 transmitter or a Series 2000 transmitter, you can assign one or two process variables to the analog outputs.

With a Series 1000 transmitter

With a Series 1000 transmitter, you can assign one process variable as the primary variable (PV), which is reported by the analog outputs. The way the assigned variable is reported depends upon which variable it is. Table 4-9 shows the results of assigning each process variable as the PV.

You can assign a process variable as the PV with a HART Communicator or ProLink II software.

With a HART CommunicatorTo assign a process variable as the PV with a HART Communicator:

1. Press 4, 3, 1.

2. Select “PV is.”

3. Select a process variable.



With ProLink II softwareTo assign a process variable as the PV with ProLink II software:

1. Click the Analog Output tab.

2. Click the arrow in the PV is box, and select the desired process variable.

3. Click Apply.

Table 4-9. Series 1000 transmitter primary variable assignment

Primary variableMilliamp output (terminals 1 and 2)

Frequency output (terminals 3 and 4)

Mass flow or volume flow

Reports the mass flow or volume flow

Reports the same variable as the milliamp output

Temperature or density

Reports the temperature or density

Reports no variable (terminals are disabled)



With a Series 2000 transmitter

With a Series 2000 transmitter, you can assign two process variables, which are reported by the analog outputs:

• Primary variable (PV)—reported as the mA output

• Tertiary variable (TV)—reported as the frequency output

Table 4-10 lists the process variables that can or cannot be assigned as the PV or TV.

You can assign process variables as the Series 2000 transmitter PV and TV with a HART Communicator or ProLink II software.

With a HART CommunicatorTo assign process variables as the Series 2000 transmitter PV and TV with a HART Communicator:

1. Press 4, 3, 1.

2. Select “PV is.”

3. Select a process variable.


5. Press the Left Arrow.

6. Press 2.

7. Select “TV is.”

8. Select a process variable. You can select only mass flow or volume flow.



With ProLink II softwareTo assign process variables as the Series 2000 transmitter PV and TV with ProLink II software:


2. Click the arrow in the PV is box, and select a process variable.

3. Click Apply.

4. Click the Frequency Output tab.

5. Click the arrow in the TV is box, and select a process variable. You can select only mass flow or volume flow.

6. Click Apply.

Table 4-10. Series 2000 transmitter primary and tertiary variable assignment

Process variablePrimary variable (milliamp output)

Tertiary variable (frequency output)

Mass flow yes yes

Volume flow yes yes

Temperature yes no

Density yes no



4.14 Changing the milliamp output

To change the mA output for analog measurement, define or change the following values:

• Upper range value (URV)

• Lower range value (LRV)

• Damping

• Fault output indicator

Changing the upper range value

The transmitter uses a range of 4 to 20 mA. The upper range value (URV) is the measurement that you want to associate with the 20 mA output.

You can change the URV with a HART Communicator, the display, or ProLink II software.

With a HART CommunicatorTo change the URV with a HART Communicator:

1. Press 4, 3, 1, 2.

2. Select “PV URV.”

3. Type a new URV.



With the displayTo change the URV with the display:

1. Simultaneously press and hold Scroll and Select for 4 seconds. When the words “SEE ALARM” or “OFF-LINE MAINT” appear on the display, then release the buttons.

2. If the words “OFF-LINE MAINT” do not appear on the display, then press Scroll until the words “OFF-LINE MAINT” appear.

3. Press Select.

4. If the word “CODE?” appears on the display, then enter the off-line password (see Changing the off-line password, page 50):a. Press Scroll until the digit above “CODE?” equals the first digit

of the off-line password.b. Press Select.c. Repeat steps a and b for the second, third, and fourth digits of

the off-line password.

5. Press Scroll until the words “OFF-LINE CONFIG” appear on the display.

6. Press Select.

7. Press Scroll until the words “CONFIG 20 MA” appear on the display.

8. Press Select.

9. Enter a new URV. See Entering milliamp and frequency range values with the display, page 65.

10. Press Scroll, if necessary, until the words “CONFIG EXIT” appear on the display.

11. Press Select to exit the off-line configuration menu.



12. Press Scroll until the words “OFF-LINE EXIT” appear on the display.

13. Press Select to exit the off-line menu.

With ProLink II softwareTo change the URV with ProLink II software:


2. Type a new URV in the URV box.

3. Click Apply.

Changing the lower range value

The transmitter uses a range of 4 to 20 mA. The lower range value (LRV) is the measurement that you want to associate with the 4 mA output.

You can change the LRV with a HART Communicator, the display, or ProLink II software.

With a HART CommunicatorTo change the LRV with a HART Communicator:

1. Press 4, 3, 1, 2.

2. Select “PV LRV.”

3. Type a new LRV.



With the displayTo change the LRV with the display:



3. Press Select.





6. Press Select.

7. Press Scroll until the words “CONFIG 4 MA” appear on the display.

8. Press Select.

9. Enter a new LRV. See Entering milliamp and frequency range values with the display, page 65.







With ProLink II softwareTo change the LRV with ProLink II software:


2. Type a new LRV in the LRV box.

3. Click Apply.

Changing damping You can specify a damping value strictly for the mA output. (See Changing the damping values, page 42, for general information about damping.) If you specify damping for the mA output, it affects only the mA output, not the HART digital output.

You can change the damping value for the mA output with a HART Communicator or ProLink II software.

With a HART CommunicatorTo change the damping value for the mA output with a HART Communicator:

1. Press 4, 3, 1.

2. Select “PV AO added damp.”

3. Type the desired number of seconds for damping.



With ProLink II softwareTo change the damping value for the mA output with ProLink II software:


2. Type a new damping value in the AO Added Damp box.

3. Click Apply.

Changing the fault output indicator

If the transmitter encounters an internal fault condition, it will send a preprogrammed measurement value to the receiving device. You can change the value by changing the output indicator. See Table 4-11.

Note: By default, the transmitter immediately reports a fault when a fault is encountered. You can delay reporting faults by changing the fault timeout. See Changing the fault timeout parameter, page 61.



You can change the fault output indicator with a HART Communicator or ProLink II software.

With a HART CommunicatorTo change the fault output indicator with a HART Communicator:

1. Press 4, 3, 1.

2. Select “AO Fault Setup.”

3. Select “AO Fault Indicator.”

4. Select a fault indicator. See Table 4-11, page 57.



With ProLink II softwareTo change the fault output indicator with ProLink II software:


2. Click the arrow in the Fault Code box, and select the desired fault output indicator.

3. Click Apply.

4.15 Changing the frequency output

To change the frequency output, select or change the following variables:

• Output scale

• Fault output indicator

• Pulse width

Changing the output scale The frequency output scale denotes the relationship between each pulse the transmitter reports and the number of flow units each pulse represents. You can select one of three output scale methods as listed in Table 4-12.

Table 4-11. Milliamp fault output indicators and values

Fault indicator Fault output value

Upscale 21–24 mA (22 mA by default)

Downscale 1–3 mA (2 mA by default)

Internal zero The value associated with 0 (zero) flow

Table 4-12. Frequency output scale methods and results

Method Parameters you must define Scale result

Frequency = flow • TV frequency factor—The number of pulses you want to equal the TV rate factor

• TV rate factor—The number of units you want to equal the TV frequency factor

The relationship between the frequency and the units is defined by the TV frequency factor and the TV rate factor.

Pulses per unit • TV pulses/unit—The number of pulses you want to equal one unit

One measurement unit equals the number of pulses defined as “TV pulses/unit.”

Units per pulse • TV units/pulse—The number of units you want to equal one pulse

One pulse equals the number of units of measure defined as “TV units/pulse.”



You can change the frequency output scale with a HART Communicator, the display, or ProLink II software.

With a HART CommunicatorTo change the frequency output scale with a HART Communicator:

1. Press 4, 3, 2.

2. Select “FO Scale Method.”

3. Select one of the scale methods listed in Table 4-12.


5. If you selected “Freq=flow” in Step 3, then:a. Press 3 “FO Scaling.”b. Press 1 “TV Freq factr.”c. Type the number of pulses you want to equal a specific number

of units.d. Press F4 “ENTER.”e. Press 2 “TV Rate factr.”f. Type the number of units you want to equal the number of

pulses you assigned to the TV frequency factor in Step c.g. Press F4 “ENTER.”h. Press F2 “SEND.”

6. If you selected “Pulses Per Unit” in Step 3, then:a. Press 3 “FO Scaling.”b. Press 1 “TV Pulses/Unit.”c. Type the number of pulses you want to equal one measurement

unit.d. Press F4 “ENTER.”e. Press F2 “SEND.”

7. If you selected “Units Per Pulse” in Step 3, then:a. Press 3 “FO Scaling.”b. Press 2 “TV Units/Pulse.”c. Type the number of units you want to equal one frequency

pulse.d. Press F4 “ENTER.”e. Press F2 “SEND.”

With the displayIf the off-line menu has been disabled, you will not be able to change the output scale with the display. For information about enabling and disabling the off-line menu, see Enabling and disabling display parameters, page 48.

To change the frequency output scale with the display:



3. Press Select.







6. Press Select.

7. Press Scroll until the words “CONFIG FREQ” appear on the display.

8. Press Select.

9. Enter the number of pulses you want to equal a specific number of units. See Entering milliamp and frequency range values with the display, page 65.

10. Press Scroll until the words “CONFIG RATE” appear on the display.

11. Enter the number of units you want to equal the number of pulses you entered in Step 9. See Entering milliamp and frequency range values with the display, page 65.





With ProLink II softwareTo change the frequency output scale with ProLink II software:

1. Click the Frequency tab.

2. Click the arrow next to Scaling Method, and select one of the scale methods listed in Table 4-12, page 57.

3. If you selected “Freq = Flow” in Step 2, then:a. Type the number of pulses you want to equal a specific number

of units in the Pulses Per Unit box.b. Type the number of units you want to equal the number of

pulses per unit you typed in Step a in the Units Per Pulse box.c. Click Apply.

4. If you selected “Pulses Per Unit” in Step 2, then:a. Type the number of pulses you want to equal one measurement

unit in the Pulses Per Unit box.b. Click Apply.

5. If you selected “Units Per Pulse” in Step 2, then: a. Type the number of units you want to equal one pulse in the

Units Per Pulse box.b. Click Apply.



Changing the fault output indicator

If the transmitter encounters an internal fault condition, it will send a preprogrammed measurement value to the receiving device. You can change the value by changing the fault output indicator. See Table 4-13.

Note: By default, the transmitter immediately reports a fault when a fault is encountered. You can delay reporting faults by changing the fault timeout. See Changing the fault timeout parameter, page 61.

You can change the fault output indicator with a HART Communicator or ProLink II software.

With a HART CommunicatorTo change the fault output indicator with a HART Communicator:

1. Press 4, 3, 2.

2. Select “FO Fault Setup.”

3. Select “FO Fault Indicator.”

4. Select a fault output setting.



With ProLink II softwareTo change the fault output indicator with ProLink II software:


2. Click the arrow in the Fault Code box, and select the desired fault indicator.

3. Click Apply.

Changing the pulse width The frequency output pulse width denotes the maximum duration of each pulse the transmitter sends to the frequency receiving device. If you have a receiving device that cannot recognize long pulse durations (widths), you might need to change the maximum pulse width.

You can change the maximum pulse width with a HART Communicator or ProLink II software.

With a HART CommunicatorTo change the maximum pulse width with a HART Communicator:

1. Press 4, 3, 2.

2. Select “FO Scaling.”

3. Select “Max Pulse Width.”

Table 4-13. Frequency fault output indicators and values

Fault indicator Fault output value

Upscale The user-specified upscale value in Hz

Downscale 0 Hz

Internal zero 0 Hz



4. Type a new maximum pulse width (duration), in milliseconds.



With ProLink II softwareTo change the maximum pulse width with ProLink II software:


2. Type a new maximum pulse width (duration), in milliseconds, in the Freq Pulse Width box.

3. Click Apply.

4.16 Changing the fault timeout parameter

By default, the transmitter immediately reports a fault when a fault is encountered. You can configure the transmitter to delay reporting a fault by changing the fault timeout parameter to a nonzero value. During the fault timeout period, the transmitter continues to report its last valid measurement.

You can change the fault timeout parameter with a HART Communicator or ProLink II software.

With the HART CommunicatorTo change the fault timeout parameter with a HART Communicator:

1. Press 4, 3.

2. Select “Fault Timeout.”

3. Type a new fault timeout value. The value can be no greater than 60 seconds.



With ProLink II softwareTo change the fault timeout parameter with ProLink II software:


2. Type a new value in the LMV Timeout box.

3. Click Apply.

4.17 RS-485 communication settings

Transmitter terminals 5 and 6 communicate digitally via RS-485 communication standard. You can change the communication protocol, parity, number of stop bits, and baud rate of the terminals to the values shown in Table 4-14.

Table 4-14. RS-485 communication settings for terminals 5 and 6

Protocol Parity Stop bits Baud rate

Modbus or HART Odd, even, or none 1 or 2 1200 to 38,400



You can change the RS-485 communication settings with a HART Communicator or ProLink II software

Note: Changing the RS-485 communication settings affects only terminals 5 and 6; it does not affect the mA/Bell 202 terminals (1 and 2) or the service port (terminals 7 and 8).

With a HART CommunicatorTo change the RS-485 Communication settings with a HART Communicator:

1. Press 4, 3, 4.

2. Select “RS485 Setup.”

3. If you want to change the communication protocol, then:a. Select “RS485 Protocol.”b. Select one of the protocol options.c. Press F4 “ENTER.”

4. If you want to change the baud rate, then:a. Select “RS485 Baudrate.”b. Select one of the baud rate options.c. Press F4 “ENTER.”

5. If you want to change the parity, then:a. Select “RS485 Parity.”b. Select one of the parity options. If you chose “HART” in Step 3,

then parity must be set to odd.c. Press F4 “ENTER.”

6. If you want to change the number of stop bits, then:a. Select “RS485 Stop Bits.”b. Type a new number of stop bits. If you chose “HART” in Step 3,

then stop bits must be 1.c. Press F4 “ENTER.”


With ProLink II softwareTo change the RS-485 communication settings with ProLink II software:

1. Click the Comm tab.

2. Click one of the two options under Protocol.

3. Click one of the two options under Parity.

4. Click one of the six options under Baud rate.

Note: If you are communicating with the transmitter via terminals 5 and 6, ProLink II software will lose communication with the transmitter as soon as you complete Step 5. Thereafter, you can change the ProLink II communication settings and reestablish communication.

5. Click Apply.



4.18 HART® burst mode The following HART communication settings can be changed:

• Enable and disable burst mode

• Change burst-mode options

• Change the polling address

Enabling and disabling burst mode

Burst mode is a specialized mode of communication during which the primary mA output is fixed at 4 mA and the transmitter regularly broadcasts HART digital information. Burst mode is ordinarily disabled, and should be enabled only if another device on the network requires HART burst-mode communication.

You can enable or disable HART burst mode with a HART Communicator or ProLink II software.

With a HART CommunicatorTo enable or disable HART burst mode with a HART Communicator:

1. Press 4, 3, 3.

2. Select “Burst Mode.”

3. If you want to enable burst mode, then select “On.”

4. If you want to disable burst mode, then select “Off.”



With ProLink II softwareTo enable or disable HART burst mode with ProLink II software:


2. Click the Burst Mode checkbox. When the checkbox is selected, burst mode is enabled.

3. Click Apply.



Changing the burst mode setting

When the transmitter is in burst mode, it produces one of the following outputs:

• PV—The transmitter repeats the primary variable (in measurement units) in each burst (e.g., 14,0 g/s, 13,5 g/s, 12,0 g/s).

• % range/current—the transmitter sends the PV’s percent of range and the PV’s actual mA level in each burst. (e.g., 25%, 11,0 mA).

• Process variables/current—the transmitter sends PV, SV, TV, and quaternary variable (QV) in measurement units and the PV’s actual milliamp reading in each burst (e.g., 50 lb/min, 23°C, 50 lb/min 0,0023 g/cc 11,8 mA).

You can change the burst-mode setting with a HART Communicator or ProLink II software.

With a HART CommunicatorTo change the burst-mode setting with a HART Communicator:

1. Press 4, 3, 3.

2. Select “Burst option.”

3. Select one of the three burst-mode settings.



With ProLink II softwareTo change the burst-mode setting with ProLink II software:

Note: Enable burst mode before you change the burst mode output. See Enabling and disabling burst mode, page 63.


2. Click the arrow next to Burst Option and select an item from the drop-down list.

3. Click Apply.

4.19 Changing the polling address

Polling addresses are integers assigned to transmitters to distinguish them from other devices on multidrop networks. Each transmitter on a multidrop network must have a polling address that is different from the polling addresses of other devices on the network.

Transmitters that communicate using HART protocol can have polling addresses of 0–15. Zero is a special-purpose polling address that enables the primary mA output to vary according to the PV. When a transmitter’s HART polling address is set to any value other than zero, the primary mA output is fixed at 4 mA.

Transmitters that communicate using Modbus protocol can have polling addresses of 1–15, 32–47, 64–79, or 96–110.

You can change the transmitter’s polling address with a HART Communicator or ProLink II software.



With a HART CommunicatorTo change the transmitter’s polling address with a HART Communicator:

1. Press 4, 3, 3.

2. Select “Poll addr.”

3. Type a new polling address.



With ProLink II softwareTo change the transmitter’s polling address with ProLink II software:

1. Click the Device tab.

2. Type a new polling address in the Address box.

Note: ProLink II software will lose communication with the transmitter as soon as you complete Step 3. Thereafter, you can change the ProLink II communication settings and reestablish communication.

3. Click Apply.

4.20 Entering milliamp and frequency range values with the display

The display uses a standard format and procedure for entering range values for either mA or frequency outputs.

Enter range and scale values in scientific notation according to the following format:

SX.XXXESY

SignFor positive numbers, leave this space blank. For negative numbers, enter a dash (–).

DigitsEnter a four-digit number; three digits must fall to the right of the decimal point.

EEnter the letter “E”.

Sign

ExponentEnter the power of 10 by which the digits will be multiplied.


Example of range value formatThe correct format for the number –810,000 is shown below:

To enter mA or frequency range values with the display:

Note: This procedure assumes that you are already at the correct point in the display menu to begin entering the range values.

1. Press Scroll, if necessary, until the first space is either a dash (–) for a negative number or a blank space for a positive number.

2. Press Select.

3. Press Scroll until the first digit is the correct number.

4. Press Select.

5. Press Scroll until the second digit is the correct number.

6. Press Select.

7. Press Scroll until the third digit is the correct number.

8. Press Select.

9. Press Scroll until the fourth digit is the correct number.

10. Press Select.

11. Press Scroll, if necessary, until the sign for the exponent is either a dash (–) for a negative exponent or a blank space for a positive exponent.

12. Press Select.

13. Press Scroll until the exponent is the correct power of ten.

14. Press Scroll and Select simultaneously for four seconds to exit.

–8.100E 5


5 Characterizing and Calibrating

5.1 Overview This section describes transmitter characterization and calibration procedures. Using the procedures in this section, you will be able to:

• Characterize the flowmeter

• Calibrate the flowmeter



5.2 Characterizing the flowmeter

Characterizing the flowmeter adjusts the transmitter to compensate for the unique traits of the sensor it is paired with.

When to characterize If the transmitter and the sensor were ordered together as a Coriolis flowmeter, then the flowmeter has already been characterized. You need to characterize the flowmeter only if the transmitter and the sensor are being paired together for the first time.

How to characterize Every sensor’s characterization data are printed on its factory tag. See Figure 5-1.

Figure 5-1. Sample sensor factory tag

If the sensor and transmitter were ordered together as a Coriolis flowmeter, then the transmitter has already been characterized for the sensor. Only perform the procedures described in this section when the conditions under When to characterize and When to calibrate are met.

Stop


Characterizing and Calibrating continued

To characterize the flowmeter, you must enter data from the sensor’s factory tag into the transmitter memory. You can characterize the flowmeter with a HART Communicator or ProLink II software.

With a HART CommunicatorTo characterize the flowmeter with a HART Communicator, first select the appropriate sensor. Complete the following procedure to select the sensor:

1. Press 4, 1.

2. Select “Sensor Selection.”

3. Select “T-Series.”


Next, set each of the HART parameters to the values printed on the sensor’s factory tag. See Figure 5-1. The HART Communicator locations for each sensor tag name are listed in Table 5-1, page 68.

With ProLink II softwareTo characterize the flowmeter with ProLink II software:


2. Type the K1 data from the sensor’s factory tag in the K1 box.

3. Type the K2 data from the sensor’s factory tag in the K2 box.

4. Type the FD data from the sensor’s factory tag in the K3 box.

5. Type the D1 data from the sensor’s factory tag in the D1 box.

Table 5-1. Characterization guide

Sensor factory tag name HART Communicator location

FCF and FT1

1. FCF and FT consist of 10 characters that are labeled “FCF” and “FT” on the sensor tag. To characterize the flowmeter for FCF and FT, type the six characters that appear after “FCF” and the four characters that appear after “FT” on the sensor’s factory tag.

4, 1, 2, FCF

FTG 4, 1, 2, FTG

FFQ 4, 1, 2, FFQ

D1 4, 1, 3, D1

K1 4, 1, 3, K1

D2 4, 1, 3, D2

K2 4, 1, 3, K2

DTG 4, 1, 3, DTG

DFQ1 4, 1, 3, DFQ1

DFQ2 4, 1, 3, DFQ2

DT 4, 1, 3, DT

FD 4, 1, 3, FD

FCF and FT



6. Type the D2 data from the sensor’s factory tag in the D2 box.

7. Type the DT data from the sensor’s factory tag in the Temp Coeff box.

8. Click Apply.


10. Type the FCF and FT data from the sensor’s factory tag in the Flow Cal box.

Note: FCF and FT data consist of 10 characters that are labeled “FCF” and “FT” on the sensor’s factory tag. To properly characterize the transmitter, enter all six characters that appear after “FCF” followed by all four characters that appear after “FT”.

11. Click Apply.

12. Click the T Series Config tab.

13. Type the FTG data from the sensor’s factory tag in the FTG box.

14. Type the FFQ data from the sensor’s factory tag in the FFQ box.

15. Type the DTG data from the sensor’s factory tag in the DTG box.

16. Type the DFQ1 data from the sensor’s factory tag in the DFQ1 box.

17. Type the DFQ2 data from the sensor’s factory tag in the DFQ2 box.

18. Click Apply.

5.3 Calibrating the flowmeter The flowmeter measures process variables based on fixed points of reference. Calibration adjusts those points of reference.

When to calibrate The transmitter is factory calibrated and does not normally need to be calibrated in the field. Calibrate the transmitter only if you must do so to meet regulatory requirements.

How to calibrate for density

Density calibration consists of three mandatory calibration points and two optional calibration points:

• Point one (low density)

• Point two (high density)

• Flowing density

• Optional D3 calibration

• Optional D4 calibration

You must perform all of the density calibration procedures in sequence, without interruption, including the optional D3 and D4 calibrations if you choose to include them.

When to perform optional D3 or D4 calibrationThe optional D3 and D4 calibration might improve the accuracy of the density measurement. If the density measurement is critical at high flow rates, or if the process fluid varies greatly in flow rate or density, consider performing the D3 and D4 calibration.



Density calibration with a HART® Communicator

Perform the following steps to calibrate the flowmeter for density with a HART Communicator.

Step 1: Point one (low-density calibration)To perform a low-density calibration:


2. Fill the sensor completely with a low-density fluid (e.g., air).

3. Press 2, 3.

4. Select “Density cal.”

5. Select “Dens Pt1.”

6. Select “Perform Cal.”

7. Type the density of the low-density fluid.


9. Press F4 “OK” to begin the calibration.

10. Press F4 “OK” when the calibration is complete.

11. Press F3 “HOME” and proceed to the high-density calibration procedure.

Step 2: Point two (high-density calibration)To perform a high-density calibration:


2. Fill the sensor completely with a high-density fluid (e.g., water).

3. Press 2, 3.


5. Select “Dens Pt2.”


7. Type the density of the high-density fluid.




11. Press F3 “HOME” and proceed to the flowing-density calibration procedure.

Step 3: Flowing-density calibrationTo perform a flowing-density calibration:

1. Press 2, 3.


3. Select “Flowing Dens (FD).”

4. Adjust process conditions so that the process flow rate is greater than or equal to the appropriate flow rate that is listed in Table 5-2, page 71. If the maximum flow rate for the process is lower than the appropriate flow rate listed in Table 5-2, then the flowing-density calibration should not be performed.


6. Type the density of the fluid.






10. Press F3 “HOME.”

Table 5-2. Flowing density calibration minimum flow rates

Sensor modelMinimum flow rate

in kg/h

ELITE® sensor CMF010 69

CMF025 720

CMF050 2350

CMF100 7575

CMF200 34540

CMF300 119600

CMF400 409000

T-Series sensor T075 13630

T100 29990

T150 95430

F-Series sensor F200 63045

All other F-Series sensors Flowing density calibration not necessary

Model D sensor D6 25

D12 125

D25 485

D40 stainless steel 900

D40 Hastelloy® C-22 1395

D65 3060

D100 11010

D150 31050

D300 73660

D600 245520

Model DH sensor All DH sensors Flowing density calibration not necessary

Model DL sensor DL65 3075

DL100 8780

DL200 32950

Model DT sensor DT65 4040

DT100 8460

DT150 15780



Step 4: Optional D3 calibrationYou may perform a D3 calibration, a D4 calibration, or both calibrations.

• The minimum density of the D3 or D4 fluid is 0,6 g/cc.

• The difference between the density of the D3 calibration fluid and the fluid that was used to perform the high-density calibration must be at least 0,1 g/cc.


• If D3 and D4 density calibrations are performed, the difference between the densities of the D3 and D4 calibration fluids must be at least 0,1 g/cc.

To perform the optional D3 calibration:


2. Fill the sensor completely with a fluid with a known density.

3. Press 2, 3.


5. Select “Dens Pt3 T-series.”












To perform the optional D4 calibration:


2. Fill the sensor completely with a fluid with a known density.

3. Press 2, 3.


5. Select “Dens Pt4 T-series.”









Density calibration with ProLink II™ software

Perform the following procedures to calibrate the flowmeter for density with ProLink II software.

Step 1: Point one (low-density calibration)To perform a low-density calibration:

1. Select Density Cal - Point 1 from the Calibrate menu.


3. Fill the sensor completely with a low-density fluid (e.g., air).

4. Type the density of the low-density fluid in the Enter box.

5. Click Do Cal.

6. If a dialog box appears containing a reason for failure, then the calibration procedure has failed. See Checking the calibration, page 83.

7. Read the results of the calibration in the K1 box.

8. Click Done and proceed to the high-density calibration procedure.

Step 2: Point two (high-density calibration)To perform a high-density calibration:

1. Select Density Cal - Point 2 from the Calibrate menu.


3. Fill the sensor completely with a high-density fluid (e.g., water).

4. Type the density of the fluid in the Enter box.

5. Click Do Cal.



8. Click Done and proceed to the flowing-density calibration procedure.

Step 3: Flowing-density calibrationTo perform a flowing-density calibration:

1. Select Density Cal - Flowing Density from the Calibrate menu.

2. Adjust process conditions so that the process flow is greater than or equal to the appropriate flow rate that is listed in Table 5-2, page 71. If the maximum flow rate for the process is lower than the appropriate flow rate listed in Table 5-2, then the flowing-density calibration should not be performed.


4. Click Do Cal.




6. Read the results of the calibration in the FD box.

7. Click Done.






To perform an optional D3 calibration with ProLink II software:

1. On the ProLink menu, point to Calibration then selectDensity Cal - Point 3.


3. Fill the sensor completely with a fluid of known density


5. Click Do Cal.

6. If a dialog box appears containing a reason for failure, then the calibration procedure has failed. See Zero or calibration failure, page 77.


8. Click Done.








To perform an optional D4 calibration with ProLink II software:

1. On the ProLink menu, point to Calibration then selectDensity Cal - Point 4.


3. Fill the sensor completely with a fluid of known density.


5. Click Do Cal.



8. Click Done.

How to calibrate for temperature

Temperature calibration is a two-point procedure. The entire procedure must be completed without interruption.

You can calibrate for temperature with ProLink II software.

Temperature calibration with ProLink II™ software

To calibrate for temperature with ProLink II software:

1. On the ProLink menu, point to Calibration then selectTemp Offset Cal.

2. Fill the sensor with a low-temperature fluid, and allow the sensor to achieve thermal equilibrium.

3. Type the temperature of the low-temperature fluid in the Enter box.

4. Click Do Cal.


6. Read the results of the calibration in the Measured Temp box.

7. Click Done.

8. On the ProLink menu, point to Calibration then select Temp Slope Cal.

9. Fill the sensor with a high-temperature fluid, and allow the sensor to achieve thermal equilibrium.

10. Type the temperature of the high-temperature fluid in the Enter box.

11. Click Do Cal.


13. Read the results of the calibration in the Measured Temp box.

14. Click Done.



6 Troubleshooting

6.1 Overview This section describes guidelines and procedures for troubleshooting the flowmeter. The information in this section will enable you to:

• Categorize the problem

• Determine whether you are able to correct the problem

• Take corrective measures (if possible)

• Contact the appropriate support agency



6.2 Transmitter does not operate

If the transmitter does not operate at all (i.e., the transmitter is not receiving power and cannot communicate over the HART network or the display), then perform all of the procedures under Diagnosing wiring problems, page 81.

If the procedures do not indicate a problem with the electrical connections, contact the Micro Motion Customer Service Department. See Contacting customer service, page 85.

6.3 Transmitter does not communicate

If the transmitter does not appear to be communicating on the HART network, then the network wiring may be faulty. Perform the procedures under Checking the communication loop, page 82.

6.4 Zero or calibration failure If a zero or calibration procedure fails, the transmitter will send a status alarm indicating the cause of failure. See Status alarms, page 78, for specific remedies for status alarms indicating calibration failure.

6.5 HART® output problems HART output problems include inconsistent or unexpected behavior that does not trigger status alarms. For example, the HART Communicator might show incorrect units of measure or respond sluggishly. If you experience HART output problems, verify that the transmitter configuration is correct.

If you discover that the configuration is incorrect, change the necessary transmitter settings. See Changing the Transmitter Settings, page 33, for the procedures to change the appropriate transmitter settings.

If you confirm that all the settings are correct, but the unexpected outputs prevail, then the transmitter or sensor could require service. See Contacting customer service, page 85.


Troubleshooting continued

6.6 Analog output problems If you are experiencing problems with the analog outputs (frequency or mA), use Table 6-1 to identify an appropriate remedy.

Fault conditions If the analog outputs indicate a fault condition (by reporting a fault output), determine the exact nature of the fault by checking the status alarms with a HART Communicator, the display, or ProLink II software. Once you have identified the status alarm(s) associated with the fault condition, refer to Status alarms.

6.7 Status alarms Status alarms are reported by a HART Communicator, the display, and ProLink II software. Remedies for the alarm states appear in Table 6-2, page 79.

Table 6-1. Analog output problems and remedies

Symptom Possible cause Possible remedy

No mA output and no frequency output or loop test failed

Power supply problem Check power supply and power-supply wiring. See page 81.

Fault condition present if fault outputs are set to downscale or internal zero

Check the fault output settings to verify whether or not the transmitter is in a fault condition. See page 56 to check the mA fault output or page 60 to check the frequency fault output.

If a fault condition is present, then see page 78.

No mA output Fault condition if fault output is set to internal zero

Check the fault output settings to verify whether or not the transmitter is in a fault condition. See page 56.


Bad mA receiving device Check the mA receiving device or try another mA receiving device. See page 82.

No frequency output Actual flow is below low-flow cutoff Verify or change the low-flow cutoff. See page 46.

Fault condition if fault output is set to downscale or internal zero



Bad frequency receiving device Check the frequency receiving device or try another frequency receiving device. See page 82.

Constant 4 mA output Transmitter is set to multidrop (digital only) communication

Set HART polling address to zero. See page 82.

mA output consistently out of range

Fault condition if fault output is set to upscale or downscale



LRV and URV not set correctly Check the LRV and URV. See page 82.

Consistently incorrect mA measurement

Output not trimmed correctly Trim the output. See page 19.

LRV and URV not set correctly Check the LRV and URV. See page 82.

Consistently incorrect frequency measurement

Output not scaled correctly Check frequency output scale and method. See page 82.



Table 6-2. Status alarms and remedies

Display code

HART Communicator ProLink II software Possible remedy

A1 EEPROM Checksum—Core Processor

EEPROM Checksum The flowmeter needs service. Contact Micro Motion. See page 85.

A2 RAM Error—Core Processor

RAM Error Cycle power to the flowmeter.

The flowmeter might need service. Contact Micro Motion. See page 85.

A3 Sensor failure Sensor Failure Check the test points. See page 83.

A4 Temperature out of range

Temperature Overrange

Check the test points. See page 83.

A5 Input over range Input Overrange Check the test points. See page 83.

A6 Field device not characterized

Not Configured Check the characterization. Specifically, verify the FCF and K1 values. See page 82.

If the problem persists, contact Micro Motion. See page 85.

A7 Real time interrupt failure

RTI Failure The transmitter needs service. Contact Micro Motion. See page 85.

A8 Density outside limits Density Overrange Check the test points. See page 83.

A9 Field device warming up

Transmitter Initializing Allow the flowmeter to warm up. The error should disappear once the flowmeter is ready for normal operation.

A10 Calibration failed Calibration Failure Cycle power to the flowmeter, then retry calibrating the transmitter. See page 83.

A11 Excess calibration correction, zero too low

Zero too Low Cycle power to the flowmeter, then retry calibrating the transmitter. See page 83.

A12 Excess calibration correction, zero too high

Zero too High Cycle power to the flowmeter, then retry calibrating the transmitter. See page 83.

A13 Process too noisy to perform auto zero

Zero too Noisy Remove or reduce sources of electromechanical noise, then attempt the calibration or zero procedure again.

Sources of noise include:• Mechanical pumps• Electrical interference• Vibration effects from nearby machinery

A14 Electronics failure Transmitter Fail The flowmeter needs service. Contact Micro Motion. See page 85.

A15 Data loss possible Data Loss Possible Cycle power to the flowmeter.

View the entire current configuration to determine what data was lost. Configure any settings with missing or incorrect data.

The transmitter might need service. Contact Micro Motion. See page 85.

A16 Line RTD Overrange Temperature Overrange


A17 Case RTD Overrange Temperature Overrange


A18 EEPROM Checksum—1000/2000




A19 RAM Error—1000/2000

RAM Error Cycle power to the flowmeter.


A20 Calibration Factor Unentered (Flocal)

Not Configured Check the characterization. Specifically, verify the FCF value. See page 67.

A21 Unrecognized/Unentered Sensor Type (K1)

Not Configured Check the characterization. Specifically, verify the K1 value. See page 67.

A22 EEPROM Config Corrupt–Core Processor


A23 EEPROM Totals Corrupt–Core Processor


A24 EEPROM Program Corrupt–Core Processor


A25 Core Processor Boot Sector Fault

Transmitter Fail The flowmeter needs service. Contact Micro Motion. See page 85.

A26 Sensor/Xmtr Communication Error

Sensor Failure Check the wiring between the transmitter and the core processor. The wires may be swapped. See page 6.

A100 Analog output 1 saturated

Analog 1 Saturated Change the mA output scale. See page 54.

A101 Analog output 1 fixed Analog 1 Fixed Check the HART polling address. See page 82.

Be advised that a loop test is in progress.

A102 Drive over range Drive Overrange Excessive drive gain. See page 84.

A103 Data loss possible Data Loss Possible Cycle power to the flowmeter.

View the entire current configuration to determine what data were lost. Configure any settings with missing or incorrect data.


A104 Calibration in progress Calibration in Progress Allow the flowmeter to complete calibration.

A105 Slug flow Slug Flow Allow the slug flow to clear from the process.

Adjust slug-flow limits and duration to prevent future error. See page 44.

A106 Burst mode enabled Burst Mode No action required.

A107 Power reset occurred Power Reset No action required.

A108 Event 1 triggered Event 1 On Be advised of alarm condition.

If you believe the event has been triggered erroneously, verify the Event 1 settings. See page 41.

A109 Event 2 triggered Event 2 On Be advised of alarm condition.

If you believe the event has been triggered erroneously, verify the Event 2 settings. See page 41.

A110 Frequency over range Frequency Saturated Change the frequency output. See page 57.

A111 Freq output fixed Frequency Fixed Be advised that a loop test is in progress.

Table 6-2. Status alarms and remedies (continued)

Display code




6.8 Diagnosing wiring problems

Use the procedures under the following headings to check the transmitter installation for wiring problems.

Checking the power-supply wiring

To check the power-supply wiring:

1. Open the field-wiring compartment cover.

2. Inspect the voltage label on the inside of the field-wiring compartment. Verify that the voltage supplied to the transmitter matches the voltage specified on the label.

3. Use a voltmeter to test the voltage at the power-supply terminals.

4. Verify that the power-supply wires are making good contact with the power-supply terminals.

A112 Series 1000/2000 software upgrade recommended

NA Contact Micro Motion to get a Series 1000/2000 transmitter software upgrade. See page 85. Note that the device is still functional.

NA Density FD cal in progress

NA Be advised that density calibration is in progress.

NA Density 1st point cal in progress


NA Density 2nd point cal in progress


NA Density 3rd point cal in progress


NA Density 4th point cal in progress


NA Mech. zero cal in progress

NA Be advised that zero calibration is in progress.

NA Flow is in reverse direction

NA Be advised that the process is flowing in reverse direction.

Table 6-2. Status alarms and remedies (continued)

Display code


WARNING

Removing the wiring compartment covers in explosive atmospheres while the power is on can cause an explosion.

Do not remove the field wiring compartment cover in explosive atmospheres before shutting off the power and waiting the required delay time as indicated on the transmitter housing.



Checking the core processor-to-transmitter wiring

To check the core processor-to-transmitter wiring, verify that:

• The transmitter is connected to the core processor according to the wiring information beginning on page 1.

• The wires are making good contact with the terminals.

Checking the communication loop

To check the communication loop, verify that the loop wires are connected as shown in the wiring diagrams on pages 9–11.

If your HART network is more complex than the wiring diagrams on pages 9–11, either:

• Contact the Micro Motion Customer Service Department. See page 85.

• Contact the HART Communication Foundation or refer to the HART Application Guide, available from the HART Communication Foundation on the Internet at:

http://www.hartcomm.org

6.9 Checking the receiving device

If you receive an inaccurate frequency or mA reading, you might be using a faulty receiving device. Use a different receiving device to confirm that the mA or frequency reading you are receiving is accurate. Another receiving device will help you determine if the problem exists in the receiving device or in the transmitter.

6.10 Setting the HART® polling address to zero

If the HART polling address is set to a nonzero number, or if the transmitter is in burst mode, the mA output is fixed at 4 mA. If the polling address is changed to zero and the transmitter is not in burst mode, the mA output will report the primary variable on a 4–20 mA scale. See Changing the polling address, page 64 and Enabling and disabling burst mode, page 63.

6.11 Checking the upper and lower range values

A saturated mA output or incorrect mA measurement could indicate a faulty URV or LRV. Verify that the URV and LRV are correct and change them if necessary. See Changing the upper range value and Changing the lower range value, page 55.

6.12 Checking the frequency output scale and method

A saturated frequency output or an incorrect frequency measurement could indicate a faulty frequency output scale and/or method. Verify that the frequency output scale and method are correct and change them if necessary. See Changing the output scale, page 57.

6.13 Checking the characterization

A flowmeter that is incorrectly characterized for its sensor might produce inaccurate output values. If the flowmeter appears to be operating correctly but sends inaccurate output values, then an incorrect characterization could be the cause.

To verify the characterization with a HART Communicator:

1. Press 5.

2. Select “Charize sensor.”



3. Press F3 “NEXT” to scroll through the list of characterization data.

4. Compare the characterization data to the characterization data on the sensor’s factory tag.

5. Press F4 “EXIT.”

If you discover that any of the characterization data are wrong, then perform a complete characterization. See How to characterize, page 67.

6.14 Checking the calibration Improper calibration can cause the transmitter to send unexpected output values. If the transmitter appears to be operating correctly but sends inaccurate output values, then an improper calibration may be the cause.

Micro Motion calibrates every transmitter at the factory. Therefore, you should only suspect improper calibration if the transmitter has been calibrated after it was shipped from the factory.

The calibration procedures in this manual are designed for calibration to a regulatory standard. See Calibrating the flowmeter, page 69. To calibrate for true accuracy, always use a measurement source that is more accurate than the flowmeter. Contact the Micro Motion Customer Service Department for assistance. See Contacting customer service, page 85.

6.15 Checking the test points Some status alarms that indicate a sensor failure or overrange condition can be caused by problems other than a failed sensor. You can diagnose sensor failure or overrange status alarms by checking the flowmeter test points. The test points include left and right pickoff voltages, drive gain, and tube frequency.

Obtaining the test points You can obtain the test points with a HART Communicator or ProLink II software.

With a HART CommunicatorTo obtain the test points with a HART Communicator:

1. Press 2, 6.

2. Select “Drive.”

3. Write down the drive gain.

4. Press F4.

5. Select “LPO.”

6. Write down the left pickoff voltage.

7. Press F4.

8. Select “RPO.”

9. Write down the right pickoff voltage.

10. Press F4.

11. Select “Tube Frequency.”

12. Write down the tube frequency.



With ProLink II softwareTo obtain the test points with ProLink II software:

1. Select Diagnostic Information from the Prolink menu.

2. Write down the value you find in the Tube Frequency box, the Left Pickoff box, the Right Pickoff box, and the Drive Gain box.

Evaluating the test points Use the following guidelines to evaluate the test points:

• If the drive gain is unstable, refer to Excessive drive gain.

• If the value for the left or right pickoff does not equal the appropriate value from Table 6-3, based on the sensor flow tube frequency, refer to Bad pickoff voltage.

• If the values for the left and right pickoffs equal the appropriate values from Table 6-3, based on the sensor flow tube frequency, contact the Micro Motion Customer Service Department for assistance. See Contacting customer service, page 85.

Excessive drive gain Excessive drive can be caused by several problems. See Table 6-4.

Erratic drive gain Erratic drive gain can be caused by several problems. See Table 6-5.

Table 6-3. Sensor pickoff values

Sensor model Pickoff value

ELITE® Model CMF sensors 3,4 mV per Hz based on sensor flow tube frequency

Model D, DL, and DT sensors 3,4 mV per Hz based on sensor flow tube frequency

Micro Motion® F-Series sensors 3,4 mV per Hz based on sensor flow tube frequency

Model R025, R050, or R100 sensor 3,4 mV per Hz based on sensor flow tube frequency

Model R200 sensor 2,0 mV per Hz based on sensor flow tube frequency

Micro Motion T-Series sensors 0,5 mV per Hz based on sensor flow tube frequency

Table 6-4. Excessive drive gain causes and solutions

Cause Solution

Excessive slug flow Eliminate slugs.

Change the sensor orientation.

Plugged flow tube Purge the flow tubes.

Cavitation or flashing Increase inlet or back pressure at the sensor.

If a pump is located upstream from the sensor, increase the distance between the pump and sensor.

Drive board or module failure, cracked flow tube, or sensor imbalance

Contact Micro Motion. See page 85.



Bad pickoff voltage Bad pickoff voltage can be caused by several problems. See Table 6-6.

6.16 Contacting customer service

For technical assistance, contact the Micro Motion Customer Service Department at:

• In the U.K., phone : 0800-966 181 (toll-free)

• Outside the U.K., phone : +31 (0) 318 549 443

Table 6-5. Erratic drive gain causes and solutions

Cause Solution

Wrong K1 characterization constant for sensor

Re-enter the K1 characterization constant. See page 67.

Polarity of pick-off reversed or polarity of drive reversed

Contact Micro Motion. See page 85.

Table 6-6. Bad pickoff voltage causes and solutions

Cause Solution

Faulty wiring runs between the sensor and core processor.

Refer to the sensor manual.

The process flow rate is beyond the limits of the sensor.

Verify that the process flow rate is not out of range of the sensor.

There is moisture in the sensor electronics.

Eliminate the moisture in the sensor electronics.

The sensor is damaged. Contact Micro Motion. See page 85.



Appendix A Specifications

A.1 Functional specifications The transmitter’s functional specifications include:

• Electrical connections

• Input/output signals

• Digital communications

• Power supply

• Environmental requirements

• Electromagnetic interference (EMI) effects

Electrical connections Input and output connectionsThe transmitter has the following input and output connections:

• Three pairs of wiring terminals for transmitter outputs

• Screw terminals accept one or two solid conductors, 2,5 to 4 mm2; or one or two stranded conductors, 0,34 to 2,5 mm2

Power connectionThe transmitter has the following power connection:

• One pair of wiring terminals accepts either AC or DC power

• One internal ground lug for power-supply ground wiring

• Screw terminals accept one or two solid conductors, 2,5 to 4 mm2; or one or two stranded conductors, 0,34 to 2,5 mm2

Service port connectionThe transmitter has two clips for temporary connection to the service port.

Input/output signals The transmitter communicates using the following input and output methods:

• One 4-wire sensor signal input connection with ground, intrinsically safe

• One active 4-20 mA output

- Not intrinsically safe- Isolated to ±50 VDC from all other outputs and earth ground- Maximum load limit, 600 ohms- Can report mass flow, volume flow, density, or temperature- Output is linear with process from 3,8 to 20,5 mA, per NAMUR

NE43 (June 1994)


Specifications continued

• One active frequency/pulse output

- Not intrinsically safe- Can report mass flow or volume flow, which can be used to

indicate flow rate or total- For Series 1000, output is dependent on mA output; for Series

2000, output is independent- Scalable to 10.000 Hz- Maximum output of 30 VDC max., 24 VDC typical- Internal 2,2 kohm pull-up- Output is linear with flow rate to 12.500 Hz

Digital communications The transmitter has the following digital communications ports:

• One service port can be used for temporary connection only

• Uses RS-485 Modbus signal, baud rate of 38,4 kilobaud, one stop bit, no parity

• HART Bell 202 signal is superimposed on the primary milliamp output, and is available for host system interface

- Frequency 1,2 and 2,2 kHz- Amplitude 0,8 V peak-to-peak- 1200 baud- Requires 250 to 600 ohms load resistance

• One RS-485 output can be used for direct connection to a HART or Modbus host system, which accepts baud rates between 1200 baud and 38,4 kilobaud

Power supply The power supply switches automatically to accept AC or DC power:

• 18–100 VDC or 85–250 VAC 50/60 Hz:

- 9 W maximum power- 1,25 A slow-blow fuse- Complies with low-voltage directive 73/23/EEC per IEC 1010-1

with Amendment 2- Installation (Overvoltage) Category II, Pollution Degree 2

Environmental requirements

Environmental requirements include ambient temperature limits:

• Ambient temperature limits between –37 and 60°C

- Some darkening of the display may occur above 55 °C- Display responsiveness decreases below 20 °C

Electromagnetic interference effects

The transmitter meets the following EMI effects standards:

• Series 1000 and 2000 transmitters conform to NAMUR NE21 (June 1997)

• Series 1000 and 2000 transmitters meet EMC directive 89/336/EEC per EN 50081-2 (August 1993) and EN 50082-2 (March 1995), and EN 61326 Industrial



A.2 Hazardous area classifications

The transmitter may have a tag listing hazardous area classifications, which indicate compliance with the standards listed below.

UL and CSA UL and CSA marked transmitters comply to the following standards:

• Transmitter: Class I, Div. 1, Groups C and D. Class II, Div. 1, Groups E, F, and G explosion proof (when installed with approved conduit seals). Otherwise, Class I, Div. 2, Groups A, B, C, and D.

• Outputs: Provides nonincendive sensor outputs for use in Class I, Div. 2, Groups A, B, C, and D; or intrinsically safe sensor outputs for use in Class I, Div. 1, Groups C and D or Class II, Div. 1, Groups E, F, and G.

CENELEC compliance Transmitters with the CENELEC-compliant tag are suitable for installation in hazardous areas as follows:

• Flameproof when installed with approved cable glands:

- with display EEx d [ib] IIB+H2 T5- without display EEx d [ib] IIC T5

• Increased safety when installed with approved cable glands:

- with display EEx de [ib] IIB+H2 T5- without display EEx de [ib] IIC T5

A.3 Performance specifications

The performance specifications below apply when used with Micro Motion T-Series sensors on liquids and slurries only.

Flow• Accuracy ±0,15% ± [(zero stability/flow rate) x 100]% of rate

• Repeatability ±0,05% ± [½(zero stability/flow rate) x 100]% of rate

Note: Flow accuracy includes the combined effects of repeatability, linearity, and hysteresis. All specifications are based on reference conditions of water at 20 to 25°C, and 1 to 2 bar unless otherwise noted. For values of zero stability, refer to product specifications for each sensor.

Density• Accuracy ±2,0 kg/m3

• Repeatability ±0,5 kg/m3

Temperature• Accuracy ±1°C ± 0,5% of reading in °C

• Repeatability ±0,2°C



A.4 Physical specifications The physical specifications of the transmitter include:

• Field-mount housing

• Mounting

• Interface/display

• Weight

Field-mount housing The characteristics of the field-mount transmitter housing are as follows:

• NEMA 4X (IP67) epoxy-painted cast aluminum housing

• Terminal compartment contains output terminals, power terminals and service-port terminals. The output terminals are physically separated from the power- and service-port terminals.

- The electronics compartment contains all electronics and the standard display.

- The sensor compartment contains the wiring terminals for connection to the core processor on the sensor.

• Screw-terminal on housing for chassis ground

• Cable gland entrances are either ½-14 NPT or M20 x 1.5 female conduit ports

Mounting Model 1700 and 2700 field-mount transmitters are available integrally mounted to Micro Motion T-Series sensors, or in a remote-mount configuration.

• Remote-mount transmitters include a mounting bracket, and require standard 4-wire signal cable, up to 300 meters in length, between the sensor and the transmitter. Hardware for installing the transmitter on the mounting bracket is included.

• The transmitter can be rotated on the sensor or the mounting bracket, 360 degrees, in 90-degree increments.



Interface/display The characteristics of the display are as follows:

• Segmented 2-line display with LCD screen with optical controls and flowmeter-status LED is standard and is suitable for hazardous area installation.

• To facilitate various mounting orientations, the display can rotate 360° on the transmitter in 90° increments.

- LCD line 1 lists the process variable, line 2 lists engineering unit of measure through a non-glare tempered glass lens.

- Display controls feature optical switches that are operated through the glass with a red LED visual-feedback to confirm when a “button” is pressed.

Display functionsThe display supports the following functions:

• Operational: view process variables; start, stop, and reset totalizers

• Off-line: view diagnostic messages, zero flowmeter, initiate output simulation and diagnostic self-check

Status lightThree-color LED status light on display panel indicates flowmeter condition at a glance. A green, yellow, or red status light, either continuously on or blinking, immediately indicates flowmeter status.

Weight The weight of the transmitter is as follows:

• 1 kg

• For weight of integrally mounted transmitter and sensor, refer to sensor specifications.

Dimensions Figure 1, page 92, and Figure 2, page 93 show the transmitter and core processor assembly’s dimensions. For dimensions of integrally mounted transmitters and sensors, refer to sensor specifications.



Figure A-1. Remote mount transmitter dimensions

Dimensions in mm

71

71

4X Ø10

93

58

26

110

214

244

45

48

69

174

99

62

114

120

3X 1/2–14 NPTor M20 X 1,5

60

122

Ø124



Figure A-2. Remote mount transmitter and core processor assembly dimensions

Dimensions in mm

71

71

4X Ø10

93

110

214

244

69

174

993X 1/2–14 NPT

or M20 X 1,5

62

114

120

60

22

111

65

78

21

207

Ø124



Appendix B Using the HART® Communicator

B.1 Overview The instructions in this manual assume that users are already familiar with the HART Communicator and can perform the following tasks:

• Turn on the HART Communicator

• Navigate the HART Communicator menus

• Establish communication with HART-compatible devices

• Transmit and receive configuration information between the HART Communicator and HART-compatible devices

• Use the alpha keys to type information

B.2 Connecting the HART® Communicator

You can connect the HART Communicator directly to the transmitter’s HART/mA terminals or to a point on a HART network.

Connecting to communication terminals

To connect the HART Communicator directly to the transmitter’s communication terminals:

1. Open the cover to the intrinsically safe wiring compartment.

Note: The HART Communicator must be connected across a resistance of 250–600 Ω . Add resistance to the connection.

2.Connect the HART Communicator leads to transmitter terminals1 and 2. See Figure B-1.

Figure B-1. Connecting to communication terminals

HART Communicator

250–600 Ω resistance


Using the HART® Communicator continued

Connecting to a multidrop network

The HART Communicator can be connected to any point in a multidrop network. See Figure B-2.

Note: The HART communicator must be connected across a resistance of 250–600 Ω . Add resistance to the connection if necessary.

Figure B-2. Connecting to a multidrop network

B.3 Conventions used in this manual

All HART Communicator procedures assume that you are starting at the on-line menu. “Online” appears on the top line of the HART Communicator main menu when the HART Communicator is at the on-line menu. See Figure B-3.

Figure B-3. HART Communicator on-line menu

B.4 HART® Communicator safety messages and notes

Users are responsible for responding to safety messages (e.g., warnings) and notes that appear on the HART Communicator. Safety messages and notes that appear on the HART Communicator are not discussed in this manual.

B.5 HART® Communicator menu tree

Figure B-4. page 97, illustrates the HART Communicator menu tree for Series 1000 and 2000 transmitters.

Transmitters

HART Communicator

Master device

250–600 Ω resistance (if necessary)



Figure B-4. HART® Communicator menu tree

1 View field dev vars2 View output vars3 View status4 Totalizer cntrl

1 Mass flow2 Temp3 Mas totl4 Dens5 Mass inventory6 Vol flo 7 Vol totl8 Vol inventory

1 Mass totl2 Vol totl3 Start totalizer4 Stop totalizer5 Reset all totals6 Reset mass total7 Reset volume total

1 Process Variables

2

4

1 View PV-analog12 View SV3 View TV-frequency4 View QV5 View event16 View event2

1 Value2 Event1 type3 Event1 setpoint4 Status alarm1

1 Value2 Event2 type3 Event2 setpoint4 Status alarm2

1

1 Test/status2 Loop test3 Calibration4 Trim analog out15 Scaled AO trim6 Test points

1 Perform cal1 LPO2 RPO3 Tube4 Drive5 Board temperature6 Live zero flow

2 Diag/Services

1 Fix analog out12 Fix frequency out

1 Perform auto zero2 Mass flo3 Zero time4 Zero

1 View status2 Self test1

2

3

6

1 Auto zero2 Density cal

1 Dens pt1 (air)2 Dens pt2 (water)3 Dens pt3 T-series4 Dens pt4 T-series5 Flowing dens (FD)

1Tag2 PV unit3 Analog1 range vals4 Freq scaling

1 PV URV2 PV LRV

3 Basic Setup

41 FO scale method2 FO scaling 1 TV freq factr

2 TV rate factr

3

1 Device info2 Charize sensor3 Fld dev vars4 Outputs

5 Review

See page 98

4 Detailed Setup



1 Mass factor2 Vol factor3 Dens factor

1 Protocol2 Baudrate3 Parity4 Stop bits

1 Tag2 Descriptor3 Message4 Date5 Dev id6 Final asmbly num7 Snsr s/n8 Snsr model9 Output opt brd

Construction matlsRevision #s

1 Total reset2 Auto scroll3 Offline menu4 Alarm menu5 Ack all6 Offline pswd

1 Dens unit2 Dens damping3 Slug low limit4 Slug high limit5 Slug duration

1 Temp unit2 Temp damp

1 Analog output12 Frequency output3 HART output4 RS485 setup5 Fault timeout

4 Detailed Setup

1 Base mass unit2 Base mass time3 Mass flo conv factor4 Mass flo text5 Mass totl text

1 Base vol unit2 Base vol time3 Vol flow conv fact4 Vol flo text5 Vol totl text

1Poll addr2 Num req preams3 Burst mode4 Burst option

1 T-Series2 Other

1 Flow cal

1 D12 K13 D24 K25 Temp coeff6 FD7 FD cal value

2

4

5

6

1 Flow2 Density3 Temperature

1

2

3

4

1 Mass flo unit2 Mass flo cutoff3 Spcl mass units4 Vol flo unit5 Vol flo cutoff6 Spcl vol units7 Flo direction8 Flo damp

1 PV is 2 Range values3 PV AO cutoff4 PV AO added damp5 AO fault setup6 Fix analog out17 Trim analog out18 Scaled AO trim

1 TV is 2 FO scale method3 FO scaling4 FO fault setup5 Fix frequency out

1 AO fault indicator2 mA fault value

1 FO fault indicator2 FO fault value

1 TV freq factr2 TV rate factr3 Max pulse width

1 Enable/disable2 Display var #s

1 Event1 var2 Event1 type3 Event1 setpoint

1 Event2 var2 Event2 type3 Event2 setpoint

1 Event12 Event2

1 Charize sensor2 Config fld dev var3 Config outputs4 Device information5 Config events6 Display setup

1 Sensor selection2 Flow3 Density4 Temp cal factor5 Meter factors

1

3

Figure B-4. HART® Communicator menu tree (continued)


Appendix C Using ProLink II™ Software

C.1 Overview The instructions in this manual assume that users are already familiar with ProLink II software and can perform the following tasks:

• Start and navigate in ProLink II software

• Establish communication between ProLink II software and compatible devices

• Transmit and receive configuration information between ProLink II software and compatible devices

If you are unable to perform the tasks listed above, consult the ProLink II software manual before attempting to use the software to configure a transmitter.

C.2 Connecting to a personal computer

You can connect a personal computer (PC) directly to the transmitter’s HART/Bell 202 terminals, the RS-485 terminals, the service port, or to a point on a network. Figure C-1. identifies the transmitter terminals to which a PC can be connected.

Note: You must use a signal converter to convert the transmitter’s RS-485 or Bell 202 standard to the RS-232 standard used by the PC’s serial port.

Figure C-1. Transmitter terminal identification

Connecting to communication terminals

To temporarily connect a PC directly to the HART/Bell 202 or RS-485 terminals:


Note: The signal converter must be connected across a resistance of 250–600 Ω . Add resistance to the connection.

HART/Bell 202 terminals (1,2)

RS-485 terminals (5,6)

Service port terminals (7,8)


Using ProLink II™ Software continued

2. If you are going to temporarily connect to the HART/Bell 202 terminals, then:a. Connect one end of the signal converter leads to the Bell 202

terminals on the signal converter.b. Connect the other end of the signal converter leads to the

transmitter terminals labeled “1” and “2.” See Figure C-2.

3. If you are going to temporarily connect to the RS-485 terminals, then:a. Connect one end of the signal converter leads to the RS-485

terminals on the signal converter.b. Connect the other end of the signal converter leads to the

transmitter terminals labeled “5” and “6.” See Figure C-2.

Figure C-2. Connecting to communication terminals

Connecting to a RS-485 or Bell 202 standard network

To connect to an RS-485 or HART/Bell 202 standard network:

1. Identify the communication standard used on the multidrop network (i.e., Bell 202 or RS-485).

Note: The signal converter must be connected across a resistance of 250–600 Ω . Add resistance if necessary.

2. If the multidrop network uses Bell 202 communication standard, then:a. Connect one end of the signal converter leads to the Bell 202

terminals on the signal converter.b. Connect the other end of the signal converter leads to any point

in the multidrop network. See Figure C-3.

3. If the multidrop network uses RS-485 communication standard, then:a. Connect one end of the signal converter leads to the RS-485

terminals on the signal converter.b. Connect the other end of the signal converter leads to any point

in the multidrop network. See Figure C-3.

Bell 202 to RS-232 signal converter

RS-485 to RS-232signal converter

25 to 9 pin serial portadapter (if necessary)

If connecting toHART/Bell 202

terminals

If connecting toRS-485 terminals

250–600Ω resistance added

250–600Ω resistance added



Figure C-3. Connecting to a Bell 202 or RS-485 standard network

Connecting to the service port

To temporarily connect to the service port, which is located in the non-intrinsically safe power-supply compartment:


2. Open the transmitter’s power-supply compartment door.

3. Connect one end of the signal converter leads to the RS-485 terminals on the signal converter.

4. Connect the other end of the signal converter leads to the service-port terminals. See Figure C-4.

Distributed control system

or programmable logic controller

Add 250–1000 Ω resistance (if necessary)

TransmittersRS-232 to Bell 202 signal converter

RS-485 to RS-232 signal converter

25 to 9 pin serial port adapter (if necessary)

If RS-485 network

If HART/Bell 202 network

WARNING

Opening the power-supply compartment in explosive atmospheres while the power is on can cause an explosion.

Do not open the power-supply compartment in explosive atmospheres before shutting off the power and waiting the required delay time as indicated on the transmitter housing.



Figure C-4. Connecting to the service port

Series 1000 or 2000 transmitter terminal compartment

Service port RS-485 to RS-232 signal converter

25 to 9 pin serial port adapter (if necessary)


Appendix D Using the Display

D.1 Overview This appendix describes the basic use of the display and provides a menu tree for the display. You can use the menu tree to locate and perform display commands quickly.

D.2 Components Figure D-1. illustrates the display components.

Figure D-1. Display components

The Scroll and Select buttons are infrared-sensitive detectors. To press either button, touch the glass in front of the button or move your finger close enough over the button to trigger the detector. The button-press indicator will flash red each time a button is pressed.

D.3 Menu tree Figure D-2. shows the display menu tree for the transmitter. To perform the functions listed in the menu tree, refer to the appropriate procedures in sections 2, 3, and 4, and in this appendix.

Current value

Units of measure

Processvariable line

Scroll buttonSelect button

Button-pressindicator


Using the Display continued

Figure D-2. Display menu tree

Reset totalizers

SCROLLSELECTTotalizers and inventories

Off-line menu

Alarm menu View alarms

SCROLL

Press SCROLL until a totalizer

or inventory appears.

Press SCROLL and SELECT

simultaneously.

Start totalizers

SCROLL Stoptotalizers

SELECT Acknowledge alarms

SELECT

SELECT Simulate outputs

SCROLL Zero the flowmeter

SCROLL Configure RS-485

Set the protocol

Set thebaud

Set theparity

Set thestop bits

Set the address

SCROLL

SCROLL

SCROLL

SCROLL

SELECT


Appendix E Return Policy

To conform with Dutch ARBO regulations and to provide a safe working environment for our employees, Micro Motion has instituted the following Return/Repair conditions. Strict adherence to these conditions is required.

Returned equipment that does not conform to the requirements listed below will NOT be processed. If Micro Motion finds evidence of contamination, we may, at our option, have the sensor cleaned or returned AT YOUR EXPENSE, after notifying you of the contamination.

1. The equipment must be COMPLETELY cleaned and decontaminated prior to shipment to Fisher-Rosemount. This decontamination procedure applies to the sensor tubes, sensor case exterior, sensor case interior, electronics, and any part that might have been exposed to process fluids or cleaning substances.

2. A Decontamination Statement is REQUIRED for all process fluids that have been in contact with the equipment. This includes fluids used for cleaning the equipment. A blank Decontamination/Cleaning Statement is provided on page 106. You may copy and use this form to return any Micro Motion instrument. Complete the form PRIOR to returning the equipment.

3. If the equipment being returned has been used on a food-grade process fluid, for which no decontamination statement is available, a statement listing all process fluids and certifying decontamination is acceptable.

4. Obtain a Return Material Authorization (RMA) number from the Micro Motion Service Department: +31 (0) 318 549 443. Complete the RMA form on page 107 PRIOR to returning the equipment.

5. The Decontamination Statement and RMA form must be attached to the outside of the packaging. Goods received without these forms will be put on hold


.

Decontamination Statement

PO NUMBER:

EQUIPMENT TO BE

LIST ALL CHEMICALS AND PROCESS FLUIDS IN CONTACT WITH THE EQUIPMENT

*ATTACH ADDITIONAL PAGES IF NECESSARY*

INFORMATION PRODUCT(S):

CHEMICAL NAME

DESCRIPTION

HEALTH SAFETY HAZARDS

PRECAUTIONS FIRST AID

I hereby certify that the equipment being returned has been cleaned and decontaminated in accordance with good industrial practices and is in compliance with all regulations. This equipment poses no health or safety risks due to contamination.

BY:(Signature) (Please Print)

TITLE: DATE: (dd/mm/yy)

COMPANY

COUNTRY:

PHONE

FAX NUMBER:

E-MAIL

Return Material Authorization (RMA)

RMA NumberFor an RMA number, contact the Micro Motion Customer Service Department: +31 (0) 318 549 443

User information Return shipping information

Customer name Name

Customer address Address

Customer contact City

Fax number Country

Phone number

Purchase order number Requested return date

Returning instrument information

Sensor model Transmitter model

Sensor serial number Transmitter serial number

Sales order number Sales order number

Flange type Power supply

Tag number Tag number

Process conditions Order information

Medium Date of delivery

Chemical formula Date of installation

Max. temperature Date of failure

Max. pressure Reason of return

Warranty (Yes or No)

Calibration data

mA output 1 mA output 2 Frequency output

Units of measure = Units of measure =

4 mA = flow rate =

20 mA = Frequency =

Reason for return / description of failure (in detail)

Receiving date

received by

Authorized by


Index

AAcknowledging alarms 27Adjusting meter factors 44Alarm menu 26Alarm priorities, status indicator 26Alarms

acknowledging 27events

high alarm 41low alarm 41

status 78viewing 26

Analog wiring 10

BBad pickoff voltage 85Base mass unit 38Base time unit 38Base unit 38Base volume unit 38Burst mode 63

CCalibrating 69

failure 77how to calibrate 69troubleshooting 83when to calibrate 69with ProLink II 73with the HART Communicator 70

Changingdamping values 42density damping 43density units 37display options 48display scroll rate 50display variables 51fault output

frequency output 60mA output 56

flow damping 42flow direction 47high slug-flow limit 45low slug-flow limit 44lower range value 55low-flow cutoff

mass flow 46volume flow 47

mA fault output 56mA output damping 56mass-flow units 35meter factors 44off-line password 50output scale 57pulse width 60slug-flow duration 46slug-flow limits 44software tag 48

temperature damping 43temperature units 38upper range value 54volume-flow units 36

Characterizing 67FCF parameter 68how to characterize 67troubleshooting 82when to characterize 67with ProLink II 68with the HART Communicator 68

Checking the test points 83Command tree for the display 103Communication loop, troubleshooting 82Components of the transmitter 5Connecting ProLink II 99, 100, 101Connecting the HART Communicator 95Contacting customer service 85Conventions 96Conversion factor 38Customer service, contacting 85

DDamping

density damping 43flow damping 42mA output 56temperature damping 43values 42

Densitymeter factor 44

Density calibration 69Density damping, changing 43Density units

changing 37list 37

Digital communications 88Disabling display parameters 48Display

alarm menu 26alarms

acknowledging 27viewing 26

changing lower range value 55changing output scale 58changing upper range value 54changing variables 51command tree 103components 14, 103enabling/disabling parameters 48loop test 17mA and frequency range values 65options 48resetting mass totalizer 31resetting volume totalizer 32rotating 13scroll rate 50starting all inventories 30


Index continued

starting all totalizers 30stopping all inventories 31stopping all totalizers 31viewing mass inventory 29viewing mass totalizer 28viewing process variables 25viewing volume inventory 30viewing volume totalizer 29zeroing 20

Drive gainerratic 84

EElectrical connections 87EMI effects 88Enabling display parameters 48Environmental effects 88Environmental limits 88Environmental requirements 1Erratic drive gain 84Events

definition 41setting 41

alarm type 41process variable 41setpoint 41

Excessive drive gain 84

FFault conditions 78Fault output, changing

frequency output 60mA output 56

FCF parameter 68Flow damping, changing 42Flow direction, changing 47Flowmeter

calibrating 69Flowmeter, characterizing 67Frequency output, changing

fault output 60output scale 57pulse width 60

Frequency range values 65Frequency/pulse output characteristics 88Functional specifications 87Fuse

power supply 88

HHART

burst mode 63enabling/disabling 63settings 64

menu tree 96multidrop wiring 11polling address 82single-loop wiring 10

HART Communicatorassigning variables 52, 53burst mode 63, 64calibrating with 70changing

density damping 43density units 37display scroll rate 50display variables 51fault timeout 61flow damping 42flow direction 48frequency fault output 60high slug-flow limit 45low slug-flow limit 45lower range value 55mA damping 56mA fault output 57mA output damping 56mass low-flow cutoff 46mass-flow units 35off-line password 50output scale 57, 58polling address 65pulse width 60RS-485 settings 62slug-flow duration 46software tag 48temperature damping 43temperature units 38upper range value 54volume low-flow cutoff 47volume-flow units 36

characterizing with 68connecting 95conventions 96inventories

starting all 30stopping all 31

loop test 16menu tree 96obtaining test points 83polling address 82safety messages 96setting events 41special units

mass-flow unit 39volume-flow unit 40

totalizersresetting all 32resetting mass totalizer 31, 32resetting volume totalizer 32starting all 30stopping all 31

trimming mA output 19viewing

alarms 26mass inventory 29mass totalizer 28process variables 25volume inventory 30volume totalizer 29

zeroing with 20Hazardous area classifications 89High alarm 41High slug-flow limit 45Humidity limits 88


Index continued

IInput signals 87Inventories

definition 28starting 30stopping 31viewing mass inventory 29viewing volume inventory 30

LLocation, determining appropriate 1Loop test 16, 17, 18Low alarm 41Low slug-flow limit 44Lower range value

changing 55definition 55troubleshooting 82

Low-flow cutoffmass flow 46volume flow 47

MMass flow

meter factor 44Mass inventory, viewing 29Mass-flow units

changing 35list 35

Mating connector 6Measurement range, changing

lower range value 55upper range value 54

Measurement unitschanging

density units 37mass-flow units 35temperature units 38volume-flow units 36

density 37mass flow 35special


temperature 38volume flow 36

Menu treeHART 96

Meter factors 44Milliamp output characteristics 87Milliamp output, changing

damping 56fault output 56lower range value 55upper range value 54

Milliamp output, trimming 19Milliamp range values 65Mounting

pipe 3wall 3

Mounting the transmitter 2

OOff-line password, changing 50Output scale


Output signals 87Output, troubleshooting

analog 78HART 77

PPassword, changing 50Performance specifications 89Physical specifications 90Pickoff voltage 85Pipe mounting 3Point-to-point wiring 11Power supply 88Power supply, troubleshooting 81Power, applying to transmitter 16Process variables

assigning to analog outputs 52viewing 25

ProLink IIassigning variables 52, 53burst mode 63, 64calibrating 73changing

density damping 43density units 37display scroll rate 50display variables 52fault timeout 61flow damping 42flow direction 48frequency fault output 60high slug-flow limit 45low slug-flow limit 45lower range value 56mA damping 56mA fault output 57mass low-flow cutoff 46mass-flow units 35off-line password 50output scale 59polling address 65pulse width 61RS-485 settings 62slug-flow duration 46software tag 48temperature damping 43temperature units 38upper range value 55volume low-flow cutoff 47volume-flow units 36

characterizing with 68connecting 99, 100, 101display parameters 49loop test 18resetting totalizers 32


Index continued

setting events 42special units


starting all inventories 30starting all totalizers 30stopping all inventories 31test points 84trimming the mA output 19viewing

alarms 27viewing mass inventory 29viewing mass totalizer 28viewing process variables 25viewing volume inventory 30viewing volume totalizer 29zeroing with 21

Pulse widthchanging 60definition 60

RReceiving device, troubleshooting 82Return policy 105–??

Europe ??–106Rotating the display 13Rotating the transmitter 8

SSafety messages 1

HART Communicator 96Scroll rate

changing 50definition 50

Sensorpickoff values 84

Sensor, characterizing for 67Service port 99Setpoint 41Slug flow

duration 46limits 44

Slugs 44Software tag 48Special units

base mass unit 38base time unit 38base unit 38base volume unit 38conversion factor 38mass-flow unit 39volume-flow unit 40

Specificationsfunctional 87performance 89physical 90

Status alarm indicator 26Status alarms 78

TTables

flowing density calibration minimum flow rates 71

sensor pickoff values 84Tag, software 48Temperature damping, changing 43Temperature effect 89Temperature limits 88Temperature units

changing 38list 38

Terminalscommunication 99

Test pointschecking 83obtaining with a HART Communicator 83obtaining with ProLink II 84

Totalizersdefinition 28resetting all 32resetting mass totalizer 31resetting volume totalizer 32starting 30stopping 31viewing mass totalizer 28viewing volume totalizer 29

Transmitterchanging settings 33components 5environmental requirements 1installing 1mounting 2rotating 8troubleshooting

no communication 77no operation 77

wiring 9Trimming mA output 19Trimming the mA output 19Troubleshooting

alarms 78analog output 78bad pickoff voltage 85calibration 77, 83characterization 82checking test points 83communication loop 82core module to transmitter wiring 82customer service telephone number 85erratic drive gain 84excessive drive gain 84fault conditions 78frequency output scale and method 82HART output 77HART polling address 82measurement range 82power supply wiring 81receiving device 82transmitter does not communicate 77transmitter does not operate 77wiring problems 81zero failure 77

UUpper range value


Index continued


VViewing

alarms 26mass inventory 29mass totalizer 28process variables 25volume inventory 30volume totalizer 29

Volume flowmeter factor 44

Volume inventory, viewing 30Volume-flow units

changing 36list 36

WWall mounting 3Wire distances 2Wiring problems 81Wiring the transmitter 9

ZZeroing 20

failure 77with ProLink II 21with the display 20with the HART Communicator 20



Emerson Process ManagementMicro Motion EuropeGroeneveldselaan 6-83903 AZ VeenendaalThe NetherlandsTel +31 (0) 318 549 549Fax +31 (0) 318 549 559

Toll-free numbers (UK only)Tel 0800-966 180Fax 0800-966 181

Customer ServiceTel +31 (0) 318 549 443Fax +31 (0) 318 549 449

Visit us on the Internet atWWW.MICROMOTION.COM

Toll-free numbers (UK only)

Tel 0800-966 180 / Fax 0800-966 181

Micro Motion is a registered trademark of Micro Motion, Inc. ProLink II is a trademark of Micro Motion, Inc. SMART FAMILY is aregistered trademark of Rosemount, Inc. HART is a registered trademark of the HART Communication Foundation.Modbus is a registered trademark of Modicon, Inc.

©2001 Micro Motion, Inc.All rights reservedP/N: 3600204-EU, Rev. B (01/02)

MAN_1000-2000_PN 36002004-EU_B_2002-01_EN

Documents

changing damping

changing rs

changing slugflow limits

changing event settings

massflow units

volume lowflow cutoff

mass lowflow cutoff

slugflow duration464