Configuration and Use Manual P/N MMI-20012741, Rev.
©2008, Micro Motion, Inc. All rights reserved. ELITE and ProLink are registered trademarks, and MVD and MVD Direct Connect are trademarks of Micro Motion, Inc., Boulder, Colorado. Micro Motion is a registered trade name of Micro Motion, Inc., Boulder, Colorado. The Micro Motion and Emerson logos are trademarks and service marks of Emerson Electric Co. All other trademarks are property of their respective owners.
Contents Chapter 1 Before You Begin . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 1 1.1 1.2 1.3 1.4 1.5 1.6 1.7 1.8 Chapter 2 Overview . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 5 Configuration overview and flowchart . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 5 Configuration worksheet . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . .
Contents 4.5 4.6 4.7 4.8 4.9 4.10 Chapter 5 5.3 5.4 5.5 Overview . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . Configuring the display . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 5.2.1 Update period . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 5.2.2 Display language . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . .
Contents Chapter 7 Testing and Moving to Production . . . . . . . . . . . . . . . . . . . . . . . . . 71 7.1 7.2 7.3 7.4 7.5 7.6 7.7 Chapter 8 71 71 72 72 75 78 78 81 82 82 83 Operating the Transmitter . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 85 8.1 8.2 8.3 8.4 8.5 8.6 8.7 Chapter 9 Overview . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . Flowmeter zero . . . . . . . . . . . . . . . . . . . . . . . . . . . . .
Contents 10.8 10.9 10.10 10.11 10.12 10.13 10.14 10.15 10.16 10.17 10.18 10.19 10.20 10.21 10.22 10.23 10.24 Fault conditions . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . HART output problems . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . I/O problems . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . Sensor simulation mode . . . . . . . . . . .
Contents Appendix E Using the 375 Field Communicator . . . . . . . . . . . . . . . . . . . . . . . 139 E.1 E.2 E.3 E.4 E.5 Overview . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . Communicator device description . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . Connecting to a transmitter . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . E.3.1 Connecting to HART clips . . . . .
vi Micro Motion® Model 2200S Transmitters
Chapter 1 Before You Begin Before You Begin 1.1 Overview This chapter provides an orientation to the use of this manual. This manual describes the procedures required to start, configure, use, maintain, and troubleshoot the Model 2200S transmitter. If you do not know what transmitter you have, see Section 1.4 for instructions on identifying the transmitter type from the model number on the transmitter’s tag. 1.
Before You Begin 1.4 Interpreting your model number Model 2200S transmitter options are encoded in the model number located on the transmitter tag. The model number is a string of the following form: 2200S*(H or K)******** In this string: • H = No adapter-barrier supplied with the transmitter • K = Adapter-barrier supplied with the transmitter Note: See the product data sheet for information on the remaining characters in the model number. 1.
Before You Begin 1.7 Flowmeter documentation Table 1-3 lists additional documentation that may be required or useful for your flowmeter. Table 1-3 Topic Document Sensor installation Sensor documentation Transmitter installation Micro Motion ® Model 2200S Transmitters: Installation Manual Hazardous area installation See the approval documentation shipped with the transmitter, or download the appropriate documentation from the Micro Motion web site (www.micromotion.com) Before You Begin 1.
4 Micro Motion® Model 2200S Transmitters
2.1 Commissioning Chapter 2 Quick Start Overview This chapter provides “quick start” tools for people who already understand most or all of the commissioning methods and options for the Model 2200S transmitter. The following tools are provided: Configuration overview and flowchart – see Section 2.2 • Configuration worksheet – see Section 2.3 • Menu flowcharts - For the Communicator – see Section 2.4.1 - For ProLink II – see Section 2.4.2 - For the display – see Section 2.4.
Quick Start Figure 2-1 Configuration flowchart Set up administrative connection Chapter 3 Configure process measurement Chapter 4 Configure operational parameters Chapter 5 Characterize the flowmeter Configure display parameters Configure general flow parameters Configure fault handling parameters Configure mass flow measurement Configure sensor parameters Configure volume flow meaurement Configure device parameters Volume flow type Gas Integrate device with control system Chapter 6 Define
Quick Start 2.3 Configuration worksheet Configuration Worksheet Transmitter _______________________________ Commissioning The configuration worksheet in this section provides a place to specify and record information about your flowmeter and your transmitter configuration. If you are configuring multiple transmitters, make copies of this worksheet and fill one out for each transmitter.
Quick Start Configuration Worksheet Temperature Transmitter _______________________________ Units ______________________________________________ Damping Pressure compensation Enabled Disabled Default (4.
Quick Start Configuration Worksheet Commissioning Sensor parameters Transmitter _______________________________ Serial number ______________________________________________ Sensor material ______________________________________________ Liner material ______________________________________________ Flange ______________________________________________ Device parameters Descriptor ______________________________________________ Message ______________________________________________ Date _________________
Quick Start Configuration Worksheet Digital communications HART variables (SV, TV, QV) 2.
Quick Start 2.4.
Quick Start Figure 2-3 ProLink II configuration menu ProLink > Configuration Additional options Flow Density Temperature Pressure · · · · · · · · · · · · · · · · · · · · · · · · Temp units · Temp cal factor · Temp damping · · · · Flow direction Flow damp Flow cal Mass flow cutoff Mass flow units Vol flow cutoff(1) Vol flow units(1) Vol flow type Std gas vol flow cutoff(2) Std gas vol flow units(2) Std gas density(2) Density units Density damping Slug high limit Slug low limit Slug duration Low d
Quick Start Figure 2-4 ProLink II configuration menu continued Commissioning ProLink > Configuration Sensor T Series Special Units Sensor Simulation · · · · · · · · · · · · · · Base mass unit · Base mass time · Mass flow conv fact · Mass flow text · Mass total text Enable simulation mode Sensor s/n Sensor model num Sensor matl Liner matl Flange FTG FFQ DTG DFQ1 DFQ2 K3 D3 D4 K4 Alarm · · · · · Alarm · Severity PV is SV is TV is QV is Base vol unit(1) · Base vol time(1) · Vol flow conv fact
Quick Start Figure 2-6 Communicator diagnostics/service menu On-Line Menu > 4 Diag/Service 1 2 3 Test/Status Loop test Calibration 1 View status 2 Self test 1 Fix analog out 1 1 Auto zero 2 Density cal 4 6 7 Trim analog out 1 Scaled AO1 trim 5 8 Perform diagnostic action Config alarms Test points 1 Reset alarm log 2 Acknowledge all alarms 3 Reset Power On time 4 Restore factory configuration 5 Enable write protect 6 Disable write protect 7 Restore factory zero 8 Exit 1 Write severity
Quick Start Figure 2-8 Communicator detailed setup menu Commissioning On-Line Menu > 6 Detailed Setup Additional options 1 2 3 Charize sensor Config fld dev vars Config outputs 1 Sensor type (read only) 2 Sensor selection 3 Flow 4 Density 5 Temp cal factor 6 Pressure compensation 7 Meter factors 8 Polling setup 9 External temp 1 Flow 2 Density 3 Temperature 4 Pressure 1 Channel setup 2 HART output 3 Modbus data 4 Fault timeout 5 Comm fault indicator 1 1 1 1 FlowCal(1) 3 1 D1 2 K1 3 D2 4 K2 5
Quick Start Figure 2-9 Communicator detailed setup menu continued On-Line Menu > 6 Detailed Setup 4 5 6 Device information Display setup Setup simulation mode 1 Tag 2 Descriptor 3 Message 4 Date 5 Dev id 6 Final assembly number 7 Sensor s/n 8 Sensor model 9 Output option board · Construction materials · Revision #s 1 Enable/disable 2 Display variables 3 Display precision 1 Enable/disable 2 Simulate mass flow 3 Simulate temperature 4 Simulate density 1 1 Display total reset 2 Display total start
Quick Start 2.4.3 Display menus Commissioning Figure 2-10 Display menu – Managing totalizers and inventories Process variable display Scroll Mass total Scroll Volume total Select EXIT STOP/START(1) Scroll RESET(2) Scroll Scroll Select STOP/START YES? RESET YES? Yes Select No Yes Scroll Operation Select No Select Scroll (1) The transmitter must be configured to allow resetting totalizers from the display. See Section 5.2.4.
Quick Start Figure 2-12 Display menu – Maintenance – Version information Scroll and Select simultaneously for 4 seconds Scroll OFF-LINE MAINT Select Scroll VER Select Yes Version info Scroll EXIT 18 Micro Motion® Model 2200S Transmitters
Quick Start Figure 2-13 Display menu – Maintenance – Configuration: Units, AO, Meter Factors Commissioning Scroll and Select simultaneously for 4 seconds Scroll OFF-LINE MAINT Select Scroll CONFG Select UNITS MASS Scroll VOL(1) Scroll Scroll TEMP Select SRC Scroll 12 mA Scroll MTR F Select MASS Scroll VOL Scroll Scroll 20 mA DENS Scroll Scroll EXIT Additional options Maintenance and Troubleshooting DENS AO Operation Select Scroll EXIT Scroll PRESS Scroll (1) Either
Quick Start Figure 2-14 Display menu – Maintenance – Configuration: Volume Type, Display, Lock VOL Scroll DISPLAY Select Select VOL TYPE TOTALS RESET Scroll Scroll EXIT TOTALS STOP Scroll LOCK Scroll DISPLAY OFFLN(1) (1) If you disable access to the offline menu, the offline menu will disappear as soon as you exit. To re-enable access, you must use ProLink II or the Communicator. (2) If Auto Scroll is enabled, a Scroll Rate screen is displayed immediately after the Auto Scroll screen.
Quick Start Figure 2-15 Display menu – Simulation (loop testing) Commissioning Scroll and Select simultaneously for 4 seconds Scroll OFF-LINE MAINT Select Scroll SIM Select Yes SET MAO Operation Select SET 12 mA Select Yes(1) (1) Fixes the output. (2) Unfixes the output. ................ Select(2) Maintenance and Troubleshooting Scroll SET 16 mA Select Yes(1) ................ Select(2) Scroll SET 20 mA Select Yes(1) ................
Quick Start Figure 2-16 Display menu – Zero Scroll and Select simultaneously for 4 seconds Scroll OFF-LINE MAINT Select Scroll ZERO Select CAL ZERO Scroll RESTORE ZERO EXIT Scroll Select Select ZERO/YES? Current zero display No Scroll Yes Select Scroll ………………….
Quick Start Figure 2-17 Display menu – Alarms Commissioning Scroll and Select simultaneously for 4 seconds SEE ALARM Select (1) This screen is displayed only if the ACK ALL function is enabled (see Section 5.2.4) and there are unacknowledged alarms.
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3.1 Commissioning Chapter 3 Getting Ready to Configure Overview This chapter contains information and procedures that are required or useful for flowmeter configuration planning and configuration. The following topics are discussed: Applying power to the flowmeter – see Section 3.2 • Setting up and making an administrative connection – see Section 3.3 • Working with mA output scales – see Section 3.4 • Configuration tips and tricks – see Section 3.
Getting Ready to Configure 3.3 Setting up and making an administrative connection To configure and make the administrative connection using the Communicator or ProLink II: 1. Make a startup connection to the transmitter using default HART parameters as listed below: • HART address = 0 • Baud rate = 1200 • Parity = Odd • Stop bits = 1 Note: For information on using ProLink II, see Appendix D. For information on using the Communicator, see Appendix E. 2. Set the HART address as required.
Getting Ready to Configure Figure 3-1 illustrates the mA measurement point options. As shown: If your installation does not include the Micro Motion adapter-barrier, always use 12–20 mA. . • If your installation does include the Micro Motion adapter-barrier, be sure you know the location of the measurement device and set the mA measurement point appropriately: • - If the mA measurement device is between the transmitter and the adapter-barrier, use 12–20 mA.
Getting Ready to Configure Example When you connect a digital multimeter (DMM) to the I/O wiring, it reads 13.5 mA. At the mA receiving device, you see a value of 7.2 mA. You don’t know if you have an adapter-barrier or if respanning is implemented in the DCS. Is there a problem? 1. Convert 13.5 mA to the corresponding value on the 4–20 mA scale: X = ( 13.5 – 10 ) × 2 X = 7 2. Compare and interpret the results: 7 vs. 7.2.
Getting Ready to Configure 3.6 Display and reporting options for process variables Table 3-2 Commissioning Table 3-2 lists the process variables that are available from the Model 2200S, and how each of them can be displayed, reported, or queried. Refer to this list as you plan the transmitter configuration.
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4.1 Commissioning Chapter 4 Configuring Process Measurement Overview The process measurement parameters control how the transmitter interprets data from the sensor. Process measurement parameters include the following: Characterization parameters – see Section 4.2 • General flow parameters – see Section 4.3 • Mass flow parameters – see Section 4.4 • Volume flow parameters – see Section 4.5 • Density parameters – see Section 4.7 • Temperature parameters – see Section 4.
Configuring Process Measurement Table 4-1 Characterization parameters Parameter Description K1 Tube period when sensor is filled with air K2 Tube period when sensor is filled with water FD Density correction factor for high flow rates D1 Density of air for K1 D2 Density of water for K2 TC Temperature coefficient to compensate for the effect of temperature on the density measurement Flowcal Flow calibration factor to define the relationship between sensor data and mass flow rate and compens
Configuring Process Measurement Options for Flow Direction include: Forward • Reverse • Absolute Value • Bidirectional • Negate/Forward • Negate/Absolute Value Commissioning • Effects of flow direction For the effect of Flow Direction on the mA output (i.e., a flow variable has been assigned to the mA output): • See Figure 4-1 if the LRV is set to 0 (zero flow). • See Figure 4-2 if the LRV is set to a negative value.
Configuring Process Measurement Effect of flow direction on mA output: LRV < 0 20 20 mA output mA output 20 16 12 –x Reverse flow(1) 0 Zero flow x mA output Figure 4-2 16 12 –x Forward flow(2) Reverse flow(1) Flow direction parameter: • Forward only 0 Zero flow 16 12 x Forward flow(2) Flow direction parameter: • Reverse only • Negate/Forward only –x Reverse flow(1) 0 Zero flow x Forward flow(2) Flow direction parameter: • Absolute value • Bidirectional • Negate/Bidirectional mA outp
Configuring Process Measurement Example 2 Configuration: Flow direction = Reverse Only • mA output: LRV = 0 g/s; URV = 100 g/s Commissioning • (See the second graph in Figure 4-1.) As a result: Under conditions of forward flow or zero flow, the mA output of the transmitter is 12 mA. • Under conditions of reverse flow, up to a flow rate of 100 g/s, the mA output of the transmitter varies between 12 mA and 20 mA in proportion to the absolute value of the flow rate.
Configuring Process Measurement Table 4-2 Effect of flow direction on totalizers and digital communications Forward flow Flow direction value Flow totals Flow values via digital comm. Forward only Increase Positive Reverse only No change Positive Bidirectional Increase Positive Absolute value Increase Positive(1) Negate/Forward No change Negative Negate/Bidirectional Decrease Negative Zero flow Flow direction value Flow totals Flow values via digital comm.
Configuring Process Measurement 4.4 Configuring mass flow measurement • Mass flow measurement units • Mass flow cutoff Commissioning The mass flow measurement parameters control how the flowmeter measures and reports mass flow. You must configure: Note: If you use the display, you can configure only the mass flow measurement unit. 4.4.1 Mass flow measurement unit The default mass flow measurement unit is g/s. See Table 4-3 for a complete list of mass flow measurement units.
Configuring Process Measurement 4.4.2 Mass flow cutoff If the mass flow measurement drops below the configured mass flow cutoff, the transmitter will report 0 for the mass flowrate. The default value for the mass flow cutoff is 0.0 g/s. The recommended setting is 5% of the sensor’s rated maximum flow rate. Note the following: • The mass flow cutoff is not applied to either volume (liquid) or gas standard volume measurement.
Configuring Process Measurement Example You want to measure the mass flow in ounces per second. Commissioning 1. Set the base mass unit to pounds (lb). 2. Set the base time unit to seconds (sec). 3. Calculate and set the conversion factor: 1lb = 16oz 1 0.0625 = -----16 4. Set the unit name as desired, e.g., oz/sec. 5. Set the totalizer and inventory name as desired, e.g., oz. 4.5 Operation 6. Configure the transmitter to use this measurement unit for mass flow.
Configuring Process Measurement For the complete list of volume flow measurement units: • Liquid – see Table 4-4 • GSV – see Table 4-5 If the volume flow unit you want to use is not listed, you can define a special measurement unit for volume flow (see Section 4.6.2).
Configuring Process Measurement Table 4-5 Volume flow measurement units – Gas Commissioning Volume flow unit Display Communicator ProLink II Unit description NM3/S Not available Nm3/sec Normal cubic meters per second NM3/MN Not available Nm3/min Normal cubic meters per minute NM3/H Not available Nm3/hr Normal cubic meters per hour NM3/D Not available Nm3/day Normal cubic meters per day NLPS Normal liter per second Not available NLPM Normal liter per minute NLPH Not available NL
Configuring Process Measurement 3. If you do not know the standard density of your gas: a. Click the Gas Wizard button. b. Click Choose Gas and check the list. c. If your gas is listed, select it and click Next. d. If your gas is not listed, click Enter Other Gas Property and provide the required information. You can describe your gas by molecular weight, its specific gravity, or density.
Configuring Process Measurement 4.6.2 Defining a special unit for volume or GSV flow 1. Navigate to the special units menu: • If you are using the Communicator, select Detailed Setup > Config Fld Dev Var > Flow > Spcl vol units. • If you are using ProLink II, click ProLink > Configuration > Special Units. Commissioning To define a special unit for volume or GSV flow: Note: You cannot define a special unit for GSV flow with the Communicator.
Configuring Process Measurement 4.7 Configuring density measurement The density measurement parameters control how the flowmeter measures and reports density. You must configure: • Density measurement units • Density cutoff • Density damping • Slug flow parameters Note: If you use the display, you can configure only the density measurement unit. 4.7.1 Density measurement units The default density measurement unit is g/cm3. See Table 4-6 for a complete list of density measurement units.
Configuring Process Measurement Note the following: The density cutoff is applied to the volume (liquid) measurement. If the density drops below its configured cutoff value, the volume flow rate will go to zero. • The density cutoff is not applied to the GSV measurement. The measured density values are used in GSV calculations. Configuration Commissioning • To configure the density cutoff: • Using the Communicator, select Detailed Setup > Config Fld Dev Var > Density.
Configuring Process Measurement If the transmitter detects slug flow: • A slug flow alarm is posted immediately. • During the slug duration period, the transmitter holds the mass flow rate at the last measured pre-slug value, independent of the mass flow rate measured by the sensor. All outputs that report mass flow rate and all internal calculations that include mass flow rate will use this value.
Configuring Process Measurement Table 4-7 Temperature measurement units Commissioning Temperature unit Display Communicator ProLink II Unit description °C °F °R °K degC °C °F °R °K Degrees Celsius degF degR Kelvin Degrees Fahrenheit Degrees Rankine Kelvin Configuration To configure the temperature measurement unit: Using the Communicator, select Detailed Setup > Config Fld Dev Var > Temperature. • Using ProLink II, click ProLink > Configuration > Temperature.
Configuring Process Measurement Not all sensors or applications require pressure correction factors. For the pressure correction values to be used, obtain the pressure effect values from the product data sheet for your sensor, then reverse the signs (e.g., if the pressure effect is 0.000004, enter a pressure correction factor of –0.000004). 4.9.2 Configuration procedure To enable and configure pressure compensation: • With the Communicator, see Figure 4-3. • With ProLink II, see Figure 4-4.
Configuring Process Measurement Figure 4-4 Configuring pressure compensation with ProLink II View > Preferences ProLink > Configuration > Pressure Enable External Pressure Compensation Apply Commissioning Set measurement unit Enable Configure ProLink > Configuration > Pressure Enter Pressure units Enter Flow factor Apply Enter Density factor Enter Cal pressure Apply Operation Enter External Pressure Apply Done 4.
Configuring Process Measurement 4.10.1 Damping and volume measurement When configuring damping values, note the following: • Liquid volume flow is derived from mass and density measurements; therefore, any damping applied to mass flow and density will affect liquid volume measurement. • Gas standard volume flow is derived from mass flow measurement, but not from density measurement. Therefore, only damping applied to mass flow will affect gas standard volume measurement.
5.1 Commissioning Chapter 5 Configuring Operational Parameters Overview The operational parameters control the behavior of the transmitter and flowmeter system. The following parameters can be configured: • Display parameters – see Section 5.2 • Fault handling parameters – see Section 5.3 Operation In addition, this chapter provides information on sensor parameters (see Section 5.4) and device parameters (see Section 5.5).
Configuring Operational Parameters 5.2.3 Display variables and display precision The display can scroll through up to 15 process variables in any order. You can configure the process variables to be displayed and the order in which they should appear. Auto Scroll may or may not be enabled: • If Auto Scroll is enabled, each configured display variable will be shown for the number of seconds specified for Scroll Rate.
Configuring Operational Parameters 5.2.4 Enabling and disabling display functions Do not enable display functions that require use of the display buttons if you do not want the operator to remove the transmitter housing cover. To access the display buttons, the transmitter housing cover must be removed. Commissioning Table 5-2 lists the configurable display functions and describes their behavior when enabled (shown) or disabled (hidden).
Configuring Operational Parameters Note the following: • If you use the display to disable access to the off-line menu, the off-line menu will disappear as soon as you exit the menu system. If you want to re-enable access, you must use ProLink II or the Communicator. • Scroll Rate is used to control the speed of scrolling when Auto Scroll is enabled. Scroll Rate defines how long each display variable (see Section 5.2.3) will be shown on the display. The time period is defined in seconds; e.g.
Configuring Operational Parameters Example Case 1: Operators do not need to know which alarms are active. Commissioning There are no special requirements for configuring Auto Scroll and Alarm Menu. The display will indicate when alarms are active. Information on specific alarms can be retrieved via the Communicator, ProLink II, or the host. Case 2: Operators must be able to view the list of active alarms at the device. Operators are allowed to remove the transmitter housing cover.
Configuring Operational Parameters Table 5-4 Status alarm severity levels Severity level Transmitter action Fault If this condition occurs, the alarm status flags are set, ALM_F flashes on the display, the alarm is posted to the active alarm log, and the configured fault actions are performed. Informational If this condition occurs, the alarm status flags are set, ALM_I flashes on the display, and the alarm is posted to the active alarm log, but fault actions are not performed.
Configuring Operational Parameters Table 5-5 Status alarms and severity levels continued Alarm code ProLink II message Default severity Configurable Affected by LMV Timeout A013 Process too Noisy to Perform Auto Zero Fault Yes No Fault No No Fault Yes Yes Fault Yes Yes Fault Yes No Fault No No Fault No No Fault No No Fault No No Fault No Yes Info Yes(1) No Info Yes(1) No Info Yes No Info Yes(1) No Info Yes No Info Yes(1) No Ignore Yes No Info Yes
Configuring Operational Parameters Configuration To configure status alarm severity: • Using the Communicator, select Diag/Service > Config Alarms > Write Severity. • Using ProLink II, click ProLink > Configuration > Alarm. Note: You cannot configure status alarm severity with the display. 5.3.2 Last measured value (LMV) timeout By default, the transmitter immediately performs the configured mA output fault action as soon as a fault is detected.
Configuring Operational Parameters 5.5 Configuring device parameters Commissioning The device parameters are used to describe the flowmeter as a system. Device parameters are listed and defined in Table 5-6. Note: The HART device ID, which is displayed in some menus, can be set only once, and is usually set at the factory to the device serial number. If the HART device ID has not been set, its value is 0. On a multidrop network, the HART device ID must be a unique value.
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6.1 Commissioning Chapter 6 Integrating the Meter with the Control System Overview This chapter discusses the following topics and tasks: • Configuring the mA output – see Section 6.2 • Configuring digital communications – see Section 6.3 6.2 Configuring the mA output Operation Before beginning configuration, make an administrative connection to the transmitter and ensure that you are complying with all applicable safety requirements. The mA output is used to report a process variable.
Integrating the Meter with the Control System 6.2.1 Process variable Table 6-2 lists the process variables that can be assigned to the mA output as the primary variable.
Integrating the Meter with the Control System Table 6-3 Default LRV and URV settings LRV URV Mass flow –200.000 g/s +200.000 g/s Volume flow (liquid) –0.200 l/s +0.200 l/s Gas standard volume flow –423.78 SCFM Density variables 0.000 g/cm Temperature +423.78 SCFM 3 –240.000 °C Drive gain Commissioning Process variable 0.000% 10.000 g/cm3 +450.000 °C 100.
Integrating the Meter with the Control System Example Configuration: • mA output process variable: Mass flow • AO Cutoff: 15 g/sec • Mass Flow Cutoff: 10 g/sec As a result, if the mass flow rate drops below 15 g/sec, the mA output will report zero flow. Configuration To configure the AO cutoff: • Using the Communicator, select Detailed Setup > Config Outputs > Channel Setup > AO Setup. • Using ProLink II, click ProLink > Configuration > Analog Output.
Integrating the Meter with the Control System Example Configuration: Flow Damping: 1 • mA output process variable: Mass flow • Added Damping: 2 As a result, a change in mass flow will be reflected in the mA output over a time period that is greater than 3 seconds. The exact time period is calculated by the transmitter according to internal algorithms which are not configurable.
Integrating the Meter with the Control System Effects of mA output fault action on transmitter behavior If the transmitter is operating near the limit of its power requirement: • And mA Fault Action is set to Upscale, if a fault occurs, the upscale (>20 mA) fault level may cause the transmitter to oscillate between the A031 alarm (low power) and a no-alarm state.
Integrating the Meter with the Control System 6.3.1 Digital communications fault action Table 6-5 Commissioning The Digital Communications Fault Action parameter specifies the values that will be reported via digital communications if the transmitter encounters an internal fault condition. Table 6-5 lists the options for Digital Communications Fault Action.
Integrating the Meter with the Control System Note: Whenever you use ProLink II to set the HART address to 0, ProLink II also enables the Loop Current Mode parameter (places a check in the checkbox). Whenever you use ProLink II to set the HART address to any other value, ProLink II also disables the Loop Current Mode parameter. Be sure to verify the Loop Current Mode setting after you configure the transmitter’s HART address.
Integrating the Meter with the Control System Table 6-6 Process variable assignments for PV, SV, TV, and QV continued PV SV TV QV Gas standard volume inventory ✓ ✓ ✓ Gas standard volume total ✓ ✓ ✓ LPO amplitude ✓ ✓ ✓ RPO amplitude ✓ ✓ ✓ Raw tube frequency ✓ ✓ ✓ Live zero ✓ ✓ ✓ Commissioning Process variable Configuration To configure the PV, SV, TV, and QV assignments: • Using the Communicator: To configure the PV, assign the desired process variable to the mA output.
Integrating the Meter with the Control System Table 6-7 Burst Mode Output options Parameter ProLink II label Communicator label Definition Primary variable 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). PV current & % of range % 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).
7.1 Commissioning Chapter 7 Testing and Moving to Production Overview This chapter contains information and procedures that may be useful for testing the flowmeter before moving it into production. The following topics are discussed: Zeroing the flowmeter – see Section 7.2 • Loop testing – see Section 7.3 • Trimming the mA output – see Section 7.4 • Using sensor simulation to test the system – see Section 7.5 • Backing up the configuration – see Section 7.
Testing and Moving to Production If desired, you can use one of these functions to return the meter to operation while you are troubleshooting the cause of the zero failure (see Section 10.6). Availability of these functions depends on the tool you are using to zero the flowmeter: • If you are using the Communicator or the display, only Restore Factory Zero is available. • If you are using ProLink II, both Restore Prior Zero and Restore Factory Zero are available. 7.2.
Testing and Moving to Production Figure 7-1 Display – Flowmeter zero procedure Commissioning Scroll and Select simultaneously for 4 seconds Scroll OFF-LINE MAINT Select Note: For a complete presentation of the Zero menu structure, see Figure 2-16. Scroll ZERO Select ZERO/YES? Operation Select ………………….
Testing and Moving to Production Figure 7-2 Communicator – Flowmeter zero procedure On-Line Menu > 3 Diag/Service > 3 Calibration 1 Auto zero Modify zero time if required Perform auto zero OK Calibration in Progress message Figure 7-3 Auto Zero Failed Auto Zero Complete Troubleshoot OK ProLink II – Flowmeter zero procedure ProLink > Calibration > Zero Calibration Modify zero time if required Perform Auto Zero Calibration in Progress LED turns red Wait until Calibration in Progress LED turns
Testing and Moving to Production 7.3 Loop testing • Verify that the mA output is being sent by the transmitter and received accurately by the receiving devices • Determine whether or not you need to trim the mA output Commissioning A loop test is a means to: Note the following: • During the loop test, the transmitter’s mA output will not report process data. CAUTION! Do not use the mA output for process control while you are performing the loop test.
Testing and Moving to Production Figure 7-4 Display – Loop test procedure Scroll and Select simultaneously for 4 seconds Scroll OFFLINE MAINT Scroll OFFLINE SIM Select Yes SET MAO Select SET 12 mA Select Yes Correct at receiving device? No Troubleshoot No Troubleshoot No Troubleshoot Yes Select Scroll SET 16 mA Select Yes Correct at receiving device? Yes Select Scroll SET 20 mA Select Yes Correct at receiving device? Yes Select Scroll EXIT 76 Micro Motion® Model 2200S Transmitter
Testing and Moving to Production Figure 7-5 Communicator – Loop test procedure Commissioning On-Line Menu > 3 Diag/Service > 2 Loop test Set mA measurement point 1 Fix Analog Out 1 4 mA 20 mA Other Operation Correct? Yes Loop test successful END to unfix No Check output wiring Troubleshoot receiving device Maintenance and Troubleshooting Appendices Configuration and Use Manual 77
Testing and Moving to Production Figure 7-6 ProLink II – Loop test procedure ProLink Menu > Test Fix Milliamp Set mA measurement point Enter mA value Fix mA Read output at receiving device Correct? Yes Unfix 7.4 No Check output wiring Troubleshoot receiving device Trimming the milliamp output Trimming the mA output creates a common measurement range between the transmitter and the device that receives the mA output.
Testing and Moving to Production Note the following: During the trim, the transmitter’s mA output will not report process data. CAUTION! Do not use the mA output for process control while you are performing the trim. • Enter the measured value in the same scale that you specified for the mA measurement point. If you specified “Don’t Know”: - If you are using ProLink II, enter the measured value in one scale and the tool will display the equivalent value in the other scale.
Testing and Moving to Production Figure 7-8 ProLink II – mA output trim procedure ProLink > Calibration > Milliamp 1 Trim Set mA measurement point 4 (12) mA trim 20 mA trim Read mA output at receiving device Read mA output at receiving device Enter receiving device value in Enter Meas Enter receiving device value in Enter Meas Next Next Read mA output at receiving device Read mA output at receiving device Equal? Yes Equal? Next No Back No Back Yes Finish 80 Micro Motion® Model 2200S
Testing and Moving to Production Figure 7-9 Communicator – Scaled AO trim procedure Commissioning On-Line Menu > 3 Diag/Service > 7 Scaled AO Trim Set mA measurement point OK CHANGE Enter low mA value ENTER ENTER Operation Enter high mA value Trim at low mA value Trim at high mA value PROCEED OK Expanded mA output trim Adapt the following procedure as required for your installation: 1. Trim the mA output at the Model 2200S transmitter as described in Section 7.4.1.
Testing and Moving to Production 7.5 Using sensor simulation to test, tune, and troubleshoot the system Sensor simulation allows you to tell the transmitter to behave as if it were receiving specific values for mass flow, temperature, and density from the sensor. You can use sensor simulation for a variety of purposes: • Testing and verifying the flowmeter’s response to a variety of process conditions without having to create those conditions in the real world.
Testing and Moving to Production 7.7 Write-protecting the configuration Commissioning To prevent unintended changes to the transmitter configuration, you can write-protect the configuration. To write-protect the configuration using ProLink II: 1. Click ProLink > Configuration > Device. 2. Enable write-protection. To write-protect the configuration using the Communicator: 1. Select Diag/Service > Perform Diagnostic Action. 2. Select Enable Write Protect.
84 Micro Motion® Model 2200S Transmitters
8.1 Commissioning Chapter 8 Operating the Transmitter Overview This chapter describes how to use the transmitter in everyday operation. The following topics and procedures are discussed: Interpreting mA output data – see Section 8.3 • Recording process variables – see Section 8.4 • Viewing process variables – see Section 8.5 • Viewing and acknowledging status alarms – see Section 8.6 • Viewing and controlling the totalizers and inventories – see Section 8.
Operating the Transmitter 8.4 Recording process variables Micro Motion suggests that you make a record of the process variables listed below, under normal operating conditions. This will help you recognize when the process variables are unusually high or low, and may help in fine-tuning transmitter configuration.
Operating the Transmitter 8.5.2 With ProLink II 1. The Process Variables window opens automatically when you first connect to the transmitter. 2. If you have closed the Process Variables window: a. Open the ProLink menu. b. Select Process Variables. 8.5.3 Commissioning To view process variables with ProLink II: With the Communicator To view process variables with the Communicator: 1. Select Process Variables > View fld dev vars. 2. Scroll through the list of process variables by pressing Down Arrow.
Operating the Transmitter When the transmitter detects an alarm condition: • • Its status flags are set as follows: - The first status flag is set to “active.” - The second status flag is set to “unacknowledged.” The transmitter checks severity level for the specific alarm: - For Fault alarms, an alarm record is written to the active alarm log and the configured fault actions are performed (after the LMV Timeout has expired, if applicable).
Operating the Transmitter 8.6.3 Commissioning To view or acknowledge status alarms using the display menus, see the menu flowchart in Figure 2-17. Note that the Acknowledge All Alarms display function may be enabled or disabled. If disabled, the Acknowledge All Alarms screen is not displayed and alarms must be acknowledged individually.
Operating the Transmitter 8.6.4 With the Communicator The Communicator allows you to perform the following actions related to status alarms: • View a list of active status alarms • Acknowledge a single status alarm • Acknowledge all status alarms at once • View the alarm event log To view all active Fault and Information alarms, you can use either of the following methods: • Select Diag/Service > Test/Status > View Status, then press OK to cycle through a list of active alarms.
Operating the Transmitter • For the mass totalizer, mass units (e.g., kg, lb) • For the volume totalizer, volume units (e.g., gal, cuft, scf, nm3) See Figure 8-1. Read the current value from the top line of the display. 2.
Operating the Transmitter 8.7.2 Controlling totalizers and inventories Table 8-1 shows all of the totalizer and inventory functions and which configuration tools you can use to control them.
Operating the Transmitter With ProLink II Table 8-3 Commissioning Table 8-3 shows how you can control the totalizers and inventories using ProLink II. Totalizer and inventory control with ProLink II To accomplish this On the totalizer control screen...
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9.1 Commissioning Chapter 9 Measurement Performance Overview This chapter describes the following procedures: • Meter validation and adjusting meter factors – see Section 9.3 • Density calibration – see Section 9.4 • Temperature calibration – see Section 9.5 9.2 Operation Before performing the procedures in this chapter, make an administrative connection to the transmitter and ensure that you are complying with all applicable safety requirements.
Measurement Performance 9.2.2 Calibration The flowmeter measures process variables based on fixed points of reference. Calibration adjusts those points of reference. Three types of calibration can be performed: • Zero, or no flow (see Section 7.2) • Density calibration • Temperature calibration Density and temperature calibration require two data points (low and high) and an external measurement for each.
Measurement Performance 9.3 Performing meter validation 1. Determine the meter factor(s) to use. You may set any combination of the mass flow, volume flow, and density meter factors. Note that all three meter factors are independent: • The mass flow meter factor affects only the value reported for mass flow. • The density meter factor affects only the value reported for density. • The volume flow meter factor affects only the value reported for volume flow.
Measurement Performance Example The flowmeter is installed and proved for the first time. The flowmeter mass measurement is 250.27 lb; the reference device measurement is 250 lb. A mass flow meter factor is determined as follows: 250 MeterFactor MassFlow = 1 × ------------------ = 0.9989 250.27 The first mass flow meter factor is 0.9989. One year later, the flowmeter is proved again. The flowmeter mass measurement is 250.07 lb; the reference device measurement is 250.25 lb.
Measurement Performance Figure 9-1 D1 and D2 density calibration – Communicator Close shutoff valve downstream from sensor Fill sensor with D1 fluid On-Line Menu > 3 Diag/Service > 3 Calibration > 2 Density cal Commissioning D1 calibration D2 calibration Fill sensor with D2 fluid 3 Diag/Service > 3 Calibration > 2 Density cal 2 Dens Pt 2 1 Dens Pt 1 Perform Cal Perform Cal Enter density of D2 fluid Enter density of D1 fluid Operation OK OK Calibration in Progress message Density Calibration Com
Measurement Performance Figure 9-2 D1 and D2 density calibration – ProLink II D1 calibration Close shutoff valve downstream from sensor D2 calibration Fill sensor with D1 fluid ProLink Menu > Calibration > Density cal – Point 1 Fill sensor with D2 fluid ProLink Menu > Calibration > Density cal – Point 2 Enter density of D1 fluid Enter density of D2 fluid Do Cal Do Cal Calibration in Progress light turns red Calibration in Progress light turns red Calibration in Progress light turns green Cal
Measurement Performance 9.5 Performing temperature calibration Note: Before performing the calibration, record your current calibration parameters. You can do this by saving the current configuration to a file on the PC. If the calibration fails, restore the known values. Commissioning Temperature calibration is a two-part procedure: temperature offset calibration and temperature slope calibration. The entire procedure must be completed without interruption.
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10.1 Commissioning Chapter 10 Troubleshooting Overview This chapter describes guidelines and procedures for troubleshooting the flowmeter.
Troubleshooting Table 10-1 Troubleshooting topics and locations continued 10.3 Section Topic Section 10.16 Checking the output wiring and receiving device Section 10.17 Checking slug flow Section 10.18 Checking output saturation Section 10.19 Checking the HART address and Loop Current Mode parameter Section 10.20 Checking the flow measurement configuration Section 10.21 Checking the characterization Section 10.22 Checking the calibration Section 10.
Troubleshooting 10.7 Low power and mA fault action If the transmitter is spontaneously powering down and restarting, check the mA Fault Action setting and the power supply to the transmitter. If the transmitter is operating near the limit of its power requirement and mA Fault Action is set to Downscale, the mA output will be set to a low value when the alarm occurs, and the drop in power may be enough to cause a powerdown.
Troubleshooting 10.10 I/O problems If you are experiencing problems with the mA output, use Table 10-2 to identify an appropriate remedy. Simulation mode may also be helpful (see Section 10.11). Table 10-2 I/O problems and remedies Symptom Possible cause Possible remedy No output Loop test failed Power supply problem • Check power supply and power supply wiring. See Section 10.14.1. mA output < 4 mA Process condition below LRV • Verify process. • Change the LRV. See Section 6.2.2.
Troubleshooting 10.11 Sensor simulation mode Commissioning Sensor simulation mode allows you to set values for mass flow, density, and temperature. The transmitter will then behave as though it was receiving those values from the sensor. Sensor simulation mode can be useful in a variety of troubleshooting situations. See Section 7.5 for information on setting up and using sensor simulation mode. 10.12 Status alarms Status alarms can be viewed with the display, ProLink II, or the Communicator.
Troubleshooting Table 10-3 Status alarms and remedies continued Alarm code A008 Communicator ProLink II Cause Suggested remedy Density Outside Limits The measured density has exceeded 0–10 g/cm3 • If other alarms are present (typically, A003, A006, A102, or A105), resolve those alarm conditions first. If the A008 alarm persists, continue with the suggestions here. • Verify process. Check for air in the flow tubes, tubes not filled, foreign material in tubes, or coating in tubes.
Troubleshooting Table 10-3 Status alarms and remedies continued A021 Communicator ProLink II Cause Suggested remedy Unrecognized/ Unentered Sensor Type The sensor is recognized as a straight tube but the K1 value indicates a curved tube, or vice versa. • Check the characterization. Specifically, verify the FCF and K1 values. See Section 4.2. • Check the sensor RTD circuitry. See Section 10.24. • If the problem persists, contact Micro Motion.
Troubleshooting Table 10-3 Status alarms and remedies continued Alarm code A106 Communicator ProLink II Cause Suggested remedy Burst Mode Enabled Device is in HART burst mode. • No action required. • If desired, reconfigure the alarm severity to Ignore (see Section 5.3.1). The transmitter has been restarted. • No action required. • If desired, reconfigure the alarm severity to Ignore (see Section 5.3.1). Simulation mode is enabled. • Disable sensor simulation. See Section 7.5.
Troubleshooting Table 10-4 Process variables problems and remedies continued Cause Suggested remedy Erratic non-zero flow rate under no-flow conditions Leaking valve or seal • Check pipeline. Incorrect sensor orientation • Sensor orientation must be appropriate to process fluid. See the installation manual for your sensor. Wiring problem • Check the sensor circuitry. See Section 10.24. Vibration in pipeline at rate close to sensor tube frequency • Check environment and remove source of vibration.
Troubleshooting Table 10-4 Process variables problems and remedies continued Symptom Cause Suggested remedy Inaccurate density reading Problem with process fluid • Use standard procedures to check quality of process fluid. Bad density calibration factors • Verify characterization. See Section 4.2. Wiring problem • Check the sensor circuitry. See Section 10.24. Bad flowmeter grounding • See Section 10.14.2. Slug flow • See Section 10.17.
Troubleshooting 10.14 Diagnosing wiring problems 10.14.1 Checking the power supply wiring To check the power supply wiring: 1. Verify that the power supply wires are making good contact, and are not clamped to the wire insulation. Commissioning Use the procedures in this section to check the transmitter installation for wiring problems. 2. Verify that the supply voltage to the loop is in conformance with the power supply requirements specified in the transmitter installation manual. 10.14.
Troubleshooting 4. Select New Configuration. 5. Select Micro Motion. 6. Ensure that the required device description is listed. If the correct device description is not found, a Generic Device menu is displayed. Contact Micro Motion to obtain the correct device description. ProLink II ProLink II v2.8 or later is required. To check the version of ProLink II: 1. Start ProLink II. 2. Open the Help menu. 3. Click on About ProLink. 10.
Troubleshooting 10.18 Checking output saturation • The process is outside normal operational limits. • Sensor flow tubes are not filled with process fluid. • Sensor flow tubes are plugged. Commissioning If an output variable exceeds the upper range limit or goes below the lower range limit, the transmitter produces an output saturation alarm. The alarm can mean: If an output saturation alarm occurs: • Check the process. • Bring the flow rate within the sensor limit.
Troubleshooting 10.22 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, an improper calibration may be the cause. Micro Motion calibrates every transmitter at the factory. Therefore, you should suspect improper calibration only if the transmitter has been calibrated after it was shipped from the factory.
Troubleshooting Table 10-5 Drive gain problems, causes, and remedies Excessive slug flow • See Section 10.17. Entrained air • Correct the process. 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. Plugged flow tube • Purge the flow tubes. Mechanical binding of sensor tubes • Ensure sensor tubes are free to vibrate. Possible problems include: - Pipe stress.
Troubleshooting Note: To check the sensor circuitry, you must remove the transmitter from the sensor. Before performing this test, ensure that all other applicable diagnostics have been performed. Diagnostic capabilities of the Model 2200S transmitter have been greatly enhanced, and may provide more useful information than these tests. 1. Power down the transmitter. 2. If the transmitter is in a hazardous environment, wait five minutes. 3. To access the sensor cable and feedthrough: a.
Troubleshooting Figure 10-1 Accessing the feedthrough pins Commissioning Transmitter housing cover User interface module Transmitter Sensor cable with feedthrough connection Transmitter housing Feedthrough Operation Feedthrough pins Clamp Note: In order to access all feedthrough pins, you may need to remove the clamp and rotate the transmitter to a different position. In this test: • There should be no open circuits, i.e., no infinite resistance readings.
Troubleshooting Table 10-7 Nominal resistance ranges for flowmeter circuits Circuit Pin pairs Nominal resistance range(1) Drive Drive + and – 8–1500 Ω Left pickoff Left pickoff + and – 16–1000 Ω Right pickoff Right pickoff + and – 16–1000 Ω Flow tube temperature sensor RTD + and RTD – 100 Ω at 0 °C + 0.38675 Ω / °C LLC/RTD • T-Series sensors RTD – and composite RTD 300 Ω at 0 °C + 1.16025 Ω / °C • CMF400 I.S. sensors RTD – and fixed resistor 39.7–42.
Troubleshooting Table 10-8 Sensor and cable short to case causes and remedies Cause Possible remedy Moisture inside the transmitter housing • Make sure that the transmitter housing is dry and no corrosion is present. Liquid or moisture inside the sensor case • Contact Micro Motion. Internally shorted feedthrough (sealed passage for wiring from sensor to transmitter) • Contact Micro Motion. Faulty cable connecting sensor to transmitter • Visually inspect the cable for damage.
122 Micro Motion® Model 2200S Transmitters
A.1 Commissioning Appendix A Default Values and Ranges Overview This appendix provides information on the default values for most transmitter parameters. Where appropriate, valid ranges are also defined. These default values represent the transmitter configuration after a master reset. Depending on how the transmitter was ordered, certain values may have been configured at the factory. Operation A.
Default Values and Ranges Table A-1 Transmitter default values and ranges continued Type Setting Default Range Comments Density Density damping 1.28 sec 0.0 – 60.0 sec User-entered value is corrected to nearest value in list of preset values. Density units g/cm3 Density cutoff 0.2 g/cm3 D1 0.00000 D2 1.00000 K1 1000.00 K2 50,000.00 FD 0.00000 Temp Coefficient 4.44 Slug flow low limit 0.0 g/cm3 0.0 – 10.0 g/cm3 3 0.0 – 10.0 g/cm3 Slug flow Temperature 0.0 – 0.
Default Values and Ranges Table A-1 Transmitter default values and ranges continued Setting Default mA output Primary variable Mass flow LRV –200.00000 g/s Automatically reset when primary variable is reset. URV 200.00000 g/s Automatically reset when primary variable is reset. AO cutoff 0.00000 g/s AO added damping 0.00000 sec Fault action Downscale AO fault level – downscale 2.0 mA 1.0 – 3.6 mA AO fault level – upscale 22 mA 21.0 – 24.0 mA Last measured value timeout 0.
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B.1 Commissioning Appendix B Flowmeter Installation Types and Components Overview This appendix provides illustrations of transmitter components and wiring, for use in troubleshooting. For detailed information on installation and wiring procedures, see the transmitter installation manual. B.2 Transmitter components • Figure B-1 shows an exploded view of the Model 2200S transmitter and its components, integral-mount. • Figure B-2 shows the extended-mount option.
Flowmeter Installation Types and Components Figure B-2 Model 2200S transmitter – Extended-mount Conduit openings Transmitter housing cover Sensor case Clamping ring B.3 Terminal diagrams Figure B-3 shows the transmitter’s wiring terminals. These terminals are used for both power supply and I/O. They are beneath the Warning flap. The transmitter housing cover and the Warning flap screw must be removed to access the wiring terminals.
C.1 Commissioning Appendix C Model 2200S Display and User Interface Overview This appendix describes the display user interface of the Model 2200S transmitter. The following topics are discussed: Identifying the components of the user interface – see Section C.2 • Removing and replacing the transmitter housing cover – see Section C.3 • Using the display – see Section C.4 • Codes and abbreviations used by the display – see Section C.5 Operation C.
Model 2200S Display and User Interface The user interface components have the following functions: C.3 • Display – displays process data • Scroll and Select buttons – used to navigate the display and the display menu system • HART clips – used to make a HART administrative connection to the transmitter, typically from ProLink II or the Communicator Removing and replacing the transmitter housing cover For some procedures, you must remove the transmitter housing cover.
Model 2200S Display and User Interface C.4.2 Entering floating-point values from the display menus Figure C-2 Commissioning Certain configuration values, such as meter factors or output ranges, are entered as floating-point values. When you first enter the configuration screen, the value is displayed in decimal notation (as shown in Figure C-2) and the active digit is flashing. Numeric values in decimal notation SX.XXXX Sign For positive numbers, leave this space blank.
Model 2200S Display and User Interface To change from decimal to exponential notation (see Figure C-3): 1. Select until the rightmost digit is flashing. 2. Scroll to E, then Select. The display changes to provide two spaces for entering the exponent. 3. To enter the exponent: a. Select until the desired digit is flashing. b. Scroll to the desired value.
Model 2200S Display and User Interface C.5 Codes and abbreviations Table C-2 lists and defines the codes and abbreviations that are used in the off-line menu. Note: These tables do not list terms that are spelled out completely, or codes that are used to identify measurement units. For the codes that are used to identify measurement units, see Chapter 4.
Model 2200S Display and User Interface Table C-2 134 Codes used in off-line menu continued Code or abbreviation Definition Comment or reference ENABL Enable Select to enable EXTRN External FAC Z Factory zero FCF Flow calibration factor FLDIR Flow direction FLSWT, FL SW Flow switch GSV Gas standard volume GSV T Gas standard volume total INTRN Internal IO Inputs/outputs LANG Display language MAO mA output MASS Mass flow MFLOW Mass flow MSMT Measurement MTR F Meter factor
D.1 Commissioning Appendix D Connecting with ProLink II Software Overview ProLink II is a Windows-based configuration and management tool for Micro Motion transmitters. It provides complete access to transmitter functions and data. This chapter provides basic information for connecting ProLink II to your transmitter. The following topics and procedures are discussed: Requirements – see Section D.2 • Configuration upload/download – see Section D.
Connecting with ProLink II Software To make a HART/Bell 202 connection using ProLink II: 1. Attach the HART signal converter to the serial or USB port of your PC. 2. To connect to a HART multidrop network, connect the HART signal converter leads to any point on the network (see Figure D-1). The HART/Bell 202 connection is polarity-insensitive. To connect to the HART clips: a. Remove the transmitter housing cover (see Section C.3). b.
Connecting with ProLink II Software Figure D-2 HART/Bell 202 connections to HART clips Commissioning VIATOR Connection is polarity-insensitive Operation Note: Additional resistance may be required. See Step 3. 3. Add resistance as required. The HART signal converter must be connected across a resistance of 250–600 Ω. To meet the resistance requirements, you may use any combination of resistors R1, R2, and R3 (see Figure D-1). 4. Start ProLink II. In the Connection menu, click Connect to Device. a.
Connecting with ProLink II Software 7. If an error message appears: a. You may be using incorrect connection parameters. - Ensure you are using the correct COM port. - If you are unsure of the transmitter’s address, use the Poll button in the Connect window to return a list of all devices on the network. b. Check all the wiring between the PC and the transmitter. c. Increase or decrease resistance. Note: For more troubleshooting information, see Section 10.14.3. D.
E.1 Commissioning Appendix E Using the 375 Field Communicator Overview The 375 Field Communicator is a handheld configuration and management tool for HART-compatible devices, including Micro Motion transmitters. It provides complete access to transmitter functions and data. This appendix provides basic information for connecting the 375 Field Communicator to your transmitter. The following topics and procedures are discussed: Communicator device description – see Section E.
Using the 375 Field Communicator E.3 Connecting to a transmitter You can connect the Communicator to the transmitter’s HART clips or to a point on a HART network. Note: The HART clips on the face of the transmitter are connected to the transmitter’s mA/HART terminals. You may connect directly to the mA/HART terminals if you have removed the user interface module.
Using the 375 Field Communicator E.3.2 Connecting to a multidrop network The Communicator must be connected across a resistance of 250–600 Ω . Add resistance to the connection if necessary. Figure E-2 Commissioning The Communicator can be connected to any point in a multidrop network. The connection is polarityinsensitive. See Figure E-2. Connecting to a multidrop network Master device Connection is polarity-insensitive 250–600 Ω resistance (if necessary) Operation Transmitters E.
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Index Numerics 12–20 mA output See mA output, scale 4–20 mA output See mA output, scale A Added damping 64 Administrative connection 26 Alarm severity 55 Alarms See Status alarms Analog output cutoff See AO cutoff AO cutoff 63 Auto Scroll 86 enabling and disabling 53 Autozero 71 B Burst mode 69 Configuration and Use Manual 143 Index C Calibration 95, 96 calibration failure 104 density calibration 98 temperature calibration 101 troubleshooting 116 Calibration parameters See Characterizing Characterizing
Index GSV flow cutoff 42 gas properties 41 measurement unit 39 special unit 43 volume flow type 39 HART address 26 LMV timeout 58 loop current mode 67 mA output 61 added damping 64 AO cutoff 63 fault action 65 process variable 62 scale 62 mass flow cutoff 38 measurement 37 measurement unit 37 special unit 38 menu flowcharts 10 meter factors 97 PV, SV, TV, and QV (HART variables) 68 quick start 5 restoring factory 28 saving to a file 135 sensor parameters 58 slug flow parameters 45 software tag 26 special u
Index Display parameters 51 Documentation additional documentation 3 manual organization 1 Drive gain, troubleshooting 116 E Engineering unit See Measurement unit F Factory configuration 28 Factory zero 71 Fault action digital communications 67 mA output 65 Fault conditions 105 Fault handling 55 Fault timeout See LMV timeout Flow calibration pressure 47 Flow damping 36 Flow direction 32 Flow factor 47 G Gas properties 41 Gas Standard Volume See GSV flow General flow parameters 32 Grounding, troubleshooting
Index Menu flowcharts 10 Communicator 13 display 17 ProLink II 11 Meter factors 95 configuration 97 Meter validation 95 procedure 97 Micro Motion customer service 3, 104 Model number 2 O Off-line password enabling/disabling 53 setting 53 Output saturation 115 sensor simulation 107 troubleshooting 105, 106 wiring, troubleshooting 114 P Password 53 Pickoff voltage 117 Power supply troubleshooting 113 Power-up 25 warm-up delay 25, 85 Pressure compensation 47 pressure correction factors 47 pressure effect 47 P
Index Configuration and Use Manual U Unit density 44 GSV flow 39 mass flow 37 See also Special unit temperature measurement 46 volume flow 39 Update period configuration 51 URV (Upper Range Value) default values 63 See also Scale User interface 129 removing transmitter housing cover 130 V Variable assignment primary variable 62, 68 quaternary variable 68 secondary variable 68 tertiary variable 68 Viewing inventory values 90 process variables 86 status alarms 87 totalizer values 90 Volume flow cutoff 42 me
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© 2008, Micro Motion, Inc. All rights reserved. P/N MMI-20012741, Rev. A *MMI-20012741* For the latest Micro Motion product specifications, view the PRODUCTS section of our web site at www.micromotion.com Micro Motion Inc.
