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ManualsBrandsEmerson Process Management ManualsPacemakerModel 2700 Pacemaker

Configuration and Use Manual

P/N 20000327, Rev. FB

June 2011

Micro Motion

Model 2700 Transmitter

with PROFIBUS-PA

Configuration and Use Manual

Summary of content (204 pages)

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Configuration and Use Manual P/N 20000327, Rev.
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© 2011 Micro Motion, Inc. All rights reserved. The Emerson logo is a trademark and service mark of Emerson Electric Co. Micro Motion, ELITE, ProLink, MVD and MVD Direct Connect are marks of one of the Emerson Process Management family of companies. All other trademarks are property of their respective owners.
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Contents Chapter 1 Before You Begin . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 1 1.1 1.2 1.3 1.4 1.5 1.6 1.7 1.8 1.9 1.10 Chapter 2 1 1 1 2 2 3 4 5 6 6 Startup . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 7 2.1 2.2 2.3 2.4 2.5 2.6 2.7 2.8 Chapter 3 Overview . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . Safety . . . . . . . . . . . . . . . . . . . . . . . .
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Contents 3.5 3.6 3.7 3.8 Chapter 4 4.7 4.8 4.9 4.10 4.11 4.12 4.13 4.14 4.15 4.16 4.17 Overview . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . Default target mode . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . Configuration map. . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . Configuring standard volume flow measurement for gas .
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Contents 5.7 5.8 Chapter 6 Viewing transmitter status and alarms . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 5.7.1 With the display . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 5.7.2 With ProLink II . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 5.7.3 With EDD . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 5.7.4 With bus parameters . . . . . .
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Contents Appendix B Using the Display . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 121 B.1 B.2 B.3 B.4 B.5 B.6 Overview . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . Components . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . Using the optical switches. . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . .
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Contents Appendix G NE53 History . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 189 G.1 G.2 Overview . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 189 Software change history . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 189 Index . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . .
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viii Model 2700 Transmitter with PROFIBUS-PA
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1.1 Before You Begin Chapter 1 Before You Begin Overview This chapter provides an orientation to the use of this manual, and includes a configuration overview flowchart and a pre-configuration worksheet. This manual describes the procedures required to start, configure, use, maintain, and troubleshoot Micro Motion® Model 2700 transmitters with PROFIBUS-PA. Safety Startup 1.2 Safety messages are provided throughout this manual to protect personnel and equipment.
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Before You Begin 1.4 PROFIBUS-PA functionality The transmitter supports the following methods of configuration and operation: • • Configuration methods: - Device description (EDD) for use with a PROFIBUS configuration tool such as Siemens® Simatic® Process Device Manager (PDM). In this manual, the term “EDD” is used to refer to this type of configuration. - Direct read and write of PROFIBUS-PA bus parameters. Operation methods: - GSD file with a PROFIBUS host.
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Before You Begin Table 1-1 Obtaining version information (continued) Tool Method Core processor software With ProLink II Not available With EDD Not available With display OFF-LINE MAINT > VER With ProLink II Help > About ProLink II GSD version Text editor Open file V3x_057A.gsd or PA139742.GSD and check parameter GSD_Revision EDD version Text editor Open file MMIcorflow.
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Before You Begin 1.7 Planning the configuration Refer to the configuration overview flowchart in Figure 1-1 to plan transmitter configuration. In general, perform configuration steps in the order shown here. Note: Depending on your installation and application, some configuration tasks may be optional. Note: This manual provides information on topics that are not included in the configuration overview flowchart, e.g., using the transmitter, troubleshooting, and calibration procedures.
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Before You Begin 1.8 Pre-configuration worksheet Before You Begin The pre-configuration worksheet provides a place to record information about your flowmeter and your application. This information will affect your configuration options as you work through this manual. You may need to consult with transmitter installation or application process personnel to obtain the required information.
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Before You Begin 1.9 Flowmeter documentation Table 1-3 lists documentation sources for additional information. Table 1-3 1.
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2.1 Before You Begin Chapter 2 Startup Overview This chapter 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 section will enable you to: Apply power to the flowmeter (Section 2.2) • Set the node address (Section 2.3) • Configure the AI block channels (Section 2.4) • Set the I/O mode of the transmitter (Section 2.
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Startup 2.3 Setting the node address The factory default setting for the node address is 126. To set the node address: 2.4 • With the display, choose OFF-LINE MAINT > CONFG > ADDRESS PBUS. • With ProLink II, choose ProLink > Configuration > Device (Profibus) > Profibus Address. • With a PROFIBUS host, use the change address function of the host. Configuring the analog input function block channels You can set each of the transmitter’s AI function blocks to measure one transducer block channel.
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Startup Table 2-2 Process variables by transducer block channel (continued) 51 (0x33) 0x0C33 Concentration measurement – net volume flow 12 (0x0C) 52 (0x34) 0x0C34 Concentration measurement – concentration 12 (0x0C) 53 (0x35) 0x0C35 Concentration measurement – Baume Before You Begin 12 (0x0C) To configure the AI function block channels: Figure 2-1 • With the EDD, bus parameters, or ProLink II, see the menu flowcharts in Figure 2-1.
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Startup 2.5 Setting the I/O mode The transmitter can function in two different I/O modes: Profile-specific and Manufacturer-specific. The factory default is Manufacturer-specific. The two modes control which function blocks are available for use, and whether the format of the status byte is “classic” or “condensed.” (See Appendix D for more information on the format of the status byte.) • In Profile-specific mode, the transmitter has the use of three AI blocks and one totalizer block.
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Startup Note: Set the I/O mode in the Physical Block before loading the GSD file. PROFIBUS GSD file names Identification number GSD file name Profile specific PA139742.GSD Manufacturer specific V3x_057A.gsd 2.5.1 Before You Begin Table 2-4 Overriding the status byte format Each I/O mode has a default status byte format – classic or condensed. To override this default: • With the GSD, set the Condensed Status parameterization bit to either 1 (for condensed status) or 0 (for classic status).
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Startup Figure 2-4 Configuring totalizer function block mode EDD MMI Coriolis Flow > Function Block Totalizer 1 > Parameter Totalizer 2 > Parameter Totalizer 3 > Parameter Totalizer 4 > Parameter Integrator Function Block Selection Bus parameters Block: Totalizer 1 (Slot 4) Index 52 (set to Mode value from table) Block: Totalizer 1 (Slot 4) Index 52 (set to Mode value from table) Mode Block: Totalizer 1 (Slot 4) Index 52 (set to Mode value from table) Block: Totalizer 1 (Slot 4) Index 52 (set to Mo
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Startup 2.7 Configuring pressure compensation Not all sensors and applications require pressure compensation. Contact Micro Motion Customer Service before you configure pressure compensation. Configuring pressure compensation requires three steps: Before You Begin Due to process pressure change away from calibration pressure, there can be a change in sensor flow and density sensitivity. This change is called pressure effect. Pressure compensation corrects for these changes. 1.
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Startup 2.7.2 Enabling pressure compensation To enable pressure compensation, see the menu flowcharts in Figure 2-5. You will need the three pressure compensation values from Section 2.7.1. Figure 2-5 Enabling pressure compensation EDD Bus parameters Enable pressure comp.
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Startup 2.7.3 Configuring a pressure source • Analog Output function block – This option allows you to poll for pressure data from an external pressure source. • Fixed pressure data – This option uses a known, constant pressure value. Before You Begin You will need to choose one of two sources for pressure data: Note: If you configure a fixed pressure value, ensure that it is accurate.
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Startup Figure 2-7 2.
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Startup 2.8.2 Configuring a temperature source Before You Begin External temperature data is reported through an analog output (AO) function block. The transmitter has two AO blocks, each of which can be assigned to a compensation variable channel. To configure an AO function block for temperature compensation: Figure 2-9 • With the EDD, refer to the flowchart in Figure 2-9. • With bus parameters, refer to the flowchart in Figure 2-10. • With the display, refer to the flowcharts in Figure B-15.
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18 Model 2700 Transmitter with PROFIBUS-PA
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3.1 Before You Begin Chapter 3 Calibration Overview This chapter describes the following procedures: Characterization (Section 3.3) • Smart Meter Verification (Section 3.4) • Meter validation and adjusting meter factors (Section 3.5) • Zero calibration (Section 3.6) • Density calibration (Section 3.7) • Temperature calibration (Section 3.
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Calibration 3.2.1 Characterization Characterizing the flowmeter adjusts the transmitter to compensate for the unique traits of the sensor it is paired with. Characterization parameters (sometimes called “calibration factors”) describe the sensor’s sensitivity to flow, density, and temperature. If the transmitter and the sensor were ordered together as a Coriolis flowmeter, then the flowmeter has already been characterized.
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Calibration Zero calibration requires only that flow through the sensor is stopped. Note: Micro Motion recommends using meter validation and meter factors, rather than calibration, to prove the meter against a regulatory standard or to correct measurement error. 3.2.5 Before You Begin Flowmeters are calibrated at the factory, and normally do not need to be calibrated in the field. Calibrate the flowmeter only if you must do so to meet regulatory requirements.
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Calibration 3.3 Performing a characterization Characterizing a flowmeter involves entering parameters that are printed on the sensor tag. 3.3.1 Characterization parameters The characterization parameters that must be entered depend on the sensor type: “T-Series” or “Other,” as listed in Table 3-1. The “Other” category includes all Micro Motion sensors except T-Series. The characterization parameters are provided on the sensor tag.
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Calibration Figure 3-1 Sample calibration tags – All sensors except T-Series Older tag 19.0005.13 12502142824.44 12502.000 0.0010 14282.000 0.9980 4.44000 310 19.0005.13 12500142864.44 Sample calibration tags – T-Series sensors Newer tag Startup Figure 3-2 Before You Begin Newer tag Older tag Calibration Density calibration factors If your sensor tag does not show a D1 or D2 value: • For D1, enter the Dens A or D1 value from the calibration certificate.
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Calibration Flow calibration values Two separate values are used to describe flow calibration: a 6-character FCF value (including one decimal point) and a 4-character FT value (including one decimal point). During characterization, these are entered as a single 10-character string that includes two decimal points. In ProLink II, this value is called the Flowcal parameter.
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Calibration Figure 3-3 Characterizing the flowmeter ProLink II MMI Coriolis Flow > Transducer Block Device Information Sensor Type Code • Curved Tube • Straight Tube Before You Begin EDD ProLink > Configuration Device tab Flow tab Sensor Type Enter values from sensor tag Calibration > Density Enter values from sensor tag Density tab Sensor type Block: Transducer Block 2 (Slot 12) Index 12 (sensor type code) Flow values Block: Transducer Block 1 (Slot 11) See note (1) Enter values from sen
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Calibration 3.4 Performing Smart Meter Verification Note: To use Smart Meter Verification, the transmitter must be paired with an enhanced core processor, and the Smart Meter Verification option must be purchased for the transmitter. 3.4.1 Preparing for the Smart Meter Verification test The Smart Meter Verification procedure can be performed on any process fluid. It is not necessary to match factory conditions. During the test, process conditions must be stable.
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Calibration Figure 3-4 Smart Meter Verification – EDD Before You Begin Device > Meter Verification Start/Abort Meter Verification Start Meter Verification Start Meter Verification Enable MV Manual Abort by End User Meter verification error Startup Select Alarm Last Value Fault Mode Continue measurement Abort Meter Verification Meter Verification in Progress Meter verification PASSED Meter verification FAILED Calibration Configuration Configuration and Use Manual 27
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Calibration Figure 3-5 Smart Meter Verification – bus parameters Step 1 Set output state (optional) Step 2 Start/abort procedure Manual abort (optional) Step 3 Check current algorithm state Running? Yes (>0) Step 4 Read percent complete No (=0) Step 8 Check abort code No (<16) Step 5 Check algorithm abort state Able to complete? Yes (=16) No (>0) Step 6 Check inlet stiffness Within limits? Yes (=0) Step 7 Check outlet stiffness No (>0) Within limits? Yes (=0) CAUTION 28 PASS Model 27
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Calibration Table 3-2 PROFIBUS parameters for Smart Meter Verification Parameters 1 Set output state Block: Transducer block 1 Index: 182 Value: • 0: Last measured value (default) • 1: Fault 2 Start/abort procedure Block: Transducer block 1 Index: 72 (Start/Stop Meter Verification) • 0x00: No effect • 0x01: Start On-Line Meter Verification 3 Check current algorithm state Block: Transducer block 1 Index: 75 Value: • Bits 4–6: State 4 Read percent complete Block: Transducer block 1 Index: 189 (P
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Calibration Figure 3-6 Smart Meter Verification – ProLink II Tools > Meter Verification > Run Meter Verification Verify configuration parameters View Previous Results Next Enter descriptive data (optional) Next Configuration Changed or Zero Changed? No Yes View details (optional) Select output behavior Start Meter Verification --------------------- Test result Fail Yes Rerun test? No Abort Pass Next Back Test result chart Next Report Finish 30 Model 2700 Transmitter with PROFIBUS-
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Calibration 3.4.3 Reading and interpreting Smart Meter Verification test results When the Smart Meter Verification test is completed, the result will be reported as Pass, Fail/Caution (depending on the tool you are using), or Abort: • Pass – The test result is within the specification uncertainty limit. In other words, the stiffness of the left and right pickoffs match the factory values plus or minus the specification uncertainty limit.
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Calibration Detailed test data with ProLink II For each test, the following data is stored on the transmitter: • Powered-on seconds at the time of the test • Test result • Stiffness of the left and right pickoffs, shown as percentage variation from the factory value. If the test aborted, 0 is stored for these values.
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Calibration Figure 3-7 Test result chart Before You Begin Initiated from the display or other tool Initiated from ProLink II Startup Calibration The test result chart shows the results for all tests in the ProLink II database, plotted against the specification uncertainty limit. The inlet stiffness and the outlet stiffness are plotted separately. This helps to distinguish between local and uniform changes to the sensor tubes.
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Calibration Note the following: • The test result chart may not show all test results, and test counters may not be continuous. ProLink II stores information about all tests initiated from ProLink II and all tests available on the transmitter when the test database is synchronized. However, the transmitter stores only the twenty most recent test results. To ensure a complete result set, always use ProLink II to initiate the tests, or synchronize the ProLink II database before overwriting occurs.
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Calibration 3.5 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.
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Calibration 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.
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Calibration 3.6 Performing zero calibration When you zero the flowmeter, you may need to adjust the zero time parameter. Zero time is the length 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 zero failure. This is due to the increased possibility of noisy flow, which causes incorrect calibration.
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Calibration Figure 3-9 Zeroing procedure – EDD Calibration > Zero Cal Modify zero time if desired Zero in progress Start Zero Cal Zeroing success Troubleshoot Execute Stop flow through sensor OK Figure 3-10 Zeroing procedure – Bus parameters 38 Modify zero time (if desired) Block: Transducer Block 1 (Slot 11) Index 83 (zero time) Initiate zero Block: Transducer Block 1 (Slot 11) Index 13 (zero calibration) Check status Block: Transducer Block 1 (Slot 11) Index 143, Bit 0x8000 Check for fail
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Calibration Figure 3-11 Zeroing procedure – ProLink II Before You Begin ProLink > Calibration > Zero Calibration Modify zero time if required Perform Auto Zero Calibration in Progress LED turns red Startup Wait until Calibration in Progress LED turns green Red Calibration Failure LED Green Troubleshoot Performing density calibration Calibration 3.
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Calibration Note: Before performing the calibration, record your current calibration parameters. If you are using ProLink II, you can do this by saving the current configuration to a file on the PC. If the calibration fails, restore the known values. 3.7.1 Preparing for density calibration Before beginning density calibration, review the requirements in this section.
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Calibration Figure 3-12 D1 and D2 density calibration – EDD Before You Begin Calibration > Density Cal D1 calibration D2 calibration Fill sensor with D2 fluid D1 = density of D1 fluid D2 = density of D2 fluid Start Lo Density Cal Start Hi Density Cal Execute Execute Low Density Cal in progress High Density Cal in progress Startup Fill sensor with D1 fluid Done Figure 3-13 D1 and D2 density calibration – Bus parameters D1 Calibration D2 Calibration Fill sensor with D2 fluid Block: Transduc
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Calibration Figure 3-14 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 Calibration in P
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Calibration Figure 3-15 D3 or D3-and-D4 density calibration – EDD Before You Begin Calibration > T-Series Density Cal D3 calibration D4 calibration Fill sensor with D4 fluid D3 = density of D3 fluid D4 = density of D4 fluid Start D3 Density Cal Start D4 Density Cal Execute Execute D3 Cal in progress D4 Cal in progress Startup Fill sensor with D3 fluid Done Done Figure 3-16 D3 or D3-and-D4 density calibration – Bus parameters D3 Calibration D4 Calibration Calibration Fill sensor with D3 f
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Calibration Figure 3-17 D3 or D3-and-D4 density calibration – ProLink II D3 Calibration Close shutoff valve downstream from sensor D4 Calibration Fill sensor with D3 fluid Fill sensor with D4 fluid ProLink Menu > Calibration > Density cal – Point 3 ProLink Menu > Calibration > Density cal – Point 4 Enter density of D3 fluid Enter density of D4 fluid Do Cal Do Cal Calibration in Progress light turns red Calibration in Progress light turns red Calibration in Progress light turns green Calibratio
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Calibration Figure 3-18 Temperature calibration – ProLink II Before You Begin Temperature Offset calibration Temperature Slope calibration Fill sensor with low-temperature fluid Fill sensor with high-temperature fluid Wait until sensor achieves thermal equilibrium Wait until sensor achieves thermal equilibrium ProLink Menu > Calibration > Temp slope cal Enter temperature of low-temperature fluid Enter temperature of high-temperature fluid Do Cal Do Cal Calibration in Progress light turns red C
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46 Model 2700 Transmitter with PROFIBUS-PA
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4.1 Before You Begin Chapter 4 Configuration Overview This section describes how to change the operating settings of the transmitter. Note: All procedures provided in this chapter assume that you have established communication with the transmitter and that you are complying with all applicable safety requirements. See Appendix C or the documentation for your PROFIBUS host or configuration tool. Startup 4.2 Default target mode The default target mode for all blocks is Auto.
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Configuration 4.4 Configuring standard volume flow measurement for gas Two types of volume flow measurement are available: • Liquid volume (the default) • Gas standard volume Only one type of volume flow measurement can be performed at a time (i.e., if liquid volume flow measurement is enabled, gas standard volume flow measurement is disabled, and vice versa). Different sets of volume flow measurement units are available, depending on which type of volume flow measurement is enabled.
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Configuration Figure 4-1 Enabling and configuring gas standard volume – EDD Before You Begin Enabling GSV Configuring GSV MMI Coriolis Flow > Transducer Block > Measurement > Process Variable > Volume Flow Type Set Volume Flow Type to STD Gas Volume MMI Coriolis Flow > Transducer Block > Measurement > Process Variable > Volume Flow Gas Std Density Gas Std Vol Flow Units Startup Gas Std Vol Flow Cutoff Figure 4-2 Enabling and configuring gas standard volume – Bus parameters Block: Transducer Bl
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Configuration Figure 4-3 Enabling and configuring gas standard volume – ProLink II ProLink > Configuration Gas Wizard Flow tab Gas in Choose Gas list? No Yes Set Vol Flow Type to Std Gas Volume Enter Other Gas Property Select method: Molecular Weight Specific Gravity Compared to Air Density(1) Select gas from Choose Gas list Select units from the Std Gas Vol Flow Units list Provide required information Configure Std Gas Vol Flow Cutoff Next Known gas density? Verify reference temperature and
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Configuration 4.5 Changing the measurement units • If you are using a PROFIBUS configuration tool or the display, units will be set to match in both the relevant AI block and the transducer block. • If you are using ProLink II, use the Function Block tab to configure units. Although units can be configured on some of the other tabs, doing so may produce unintended results.
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Configuration Table 4-3 Volume flow measurement units – Liquid Volume flow unit EDD ProLink II Display Unit description CFS ft3/sec CUFT/S Cubic feet per second CFM ft3/min CUF/MN Cubic feet per minute CFH ft3/hr CUFT/H Cubic feet per hour ft /d ft3/day CUFT/D Cubic feet per day 3 m /s m3/sec M3/S Cubic meters per second m3/min m3/min M3/MIN Cubic meters per minute m3/h m3/hr M3/H Cubic meters per hour m /d m3/day M3/D Cubic meters per day gal/s US gal/sec USGPS U.
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Configuration Table 4-4 Volume flow measurement units – Gas (continued) Before You Begin Volume flow unit EDD ProLink II Display Unit description Nm3/d Nm3/day NM3/D Normal cubic meters per day NL/s NLPS NLPS Normal liter per second NL/m NLPM NLPM Normal liter per minute NL/h NLPH NLPH Normal liter per hour NL/d NLPD NLPD Normal liter per day SCFS SCFS SCFS Standard cubic feet per second SCFM SCFM SCFM Standard cubic feet per minute SCFH SCFH SCFH Standard cubic feet pe
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Configuration Table 4-6 Temperature measurement units Temperature unit PROFIBUS-PA ProLink II Display Unit description °C °F °R °C °F °R °K °C °F °R °K Degrees Celsius K Degrees Fahrenheit Degrees Rankine Kelvin Although pressure units are listed in Table 4-7, the transmitter does not measure pressure. These units are for configuring external pressure compensation. Refer to Section 2.7.
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Configuration 4.6 Configuring the petroleum measurement application Note: The petroleum measurement application requires liquid volume measurement units. If you plan to use petroleum measurement process variables, ensure that liquid volume flow measurement is specified. See Section 4.4. 4.6.1 Before You Begin The petroleum measurement parameters determine the values that will be used in petroleum measurement-related calculations.
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Configuration Petroleum measurement reference tables Reference tables are organized by reference temperature, CTL derivation method, liquid type, and density unit. The table selected here controls all the remaining options. • • • • Reference temperature: - If you specify a 5x, 6x, 23x, or 24x table, the default reference temperature is 60 °F, and cannot be changed. - If you specify a 53x or 54x table, the default reference temperature is 15 °C.
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Configuration Table 4-8 Petroleum measurement reference temperature tables Base temperature Degrees API 5A Method 1 60 °F, non-configurable 0 to +100 5B Method 1 60 °F, non-configurable 0 to +85 5D Method 1 60 °F, non-configurable –10 to +40 23A Method 1 60 °F, non-configurable 0.6110 to 1.0760 23B Method 1 60 °F, non-configurable 0.6535 to 1.
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Configuration Figure 4-4 Setting the petroleum measurement table type EDD MMI Coriolis Flow > Transducer Block > API Bus parameters Block: Transducer Block 2 (Slot 12) Index 40 (API2540 CTL table type) Table type ProLink II API2540 CTL Table Type ProLink > Configuration Select table type from the API Table Type list API Setup tab Apply Setting the reference temperature For the temperature value to be used in CTL calculation, you can use the temperature data from the sensor, or you can configure ext
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Configuration 4.7 Configuring the concentration measurement application Before You Begin Micro Motion sensors provide direct measurements of density, but not of concentration. The concentration measurement application calculates process variables such as concentration or density at reference temperature, using density process data appropriately corrected for temperature.
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Configuration Table 4-10 Standard curves and associated measurement units (continued) Name Description Density unit Temperature unit HFCS 42 Curve represents a hydrometer scale for HFCS 42 (high fructose corn syrup) solutions that indicates the percent by mass of HFCS in solution. g/cm3 °C HFCS 55 Curve represents a hydrometer scale for HFCS 55 (high fructose corn syrup) solutions that indicates the percent by mass of HFCS in solution.
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Configuration Table 4-11 Derived variables and available process variables (continued) Before You Begin Available process variables Density at Standard reference volume temperature flow rate Specific gravity Concentration Volume Conc (SG) Volume concentration derived from specific gravity The percent volume of solute or of material in suspension in the total solution, derived from specific gravity ✓ ✓ ✓ ✓ Conc (Dens) Concentration derived from reference density The mass, volume, weight, or number
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Configuration 4.8 Changing the output scale The AI function blocks can be configured to scale their output. The output scale is established by defining a process variable value at 0% of scale and at 100% of scale. The output of the AI block will be translated to a value between these two limits. If you choose to use output scaling, note that it has no effect on the process values found in the transducer block.
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Configuration 4.9 Changing process alarms Note: Process alarms are only posted through the AI function blocks and totalizer blocks and are not shown on the display or in ProLink II. 4.9.1 Before You Begin The transmitter uses process alarms to indicate that a process value has exceeded its user-defined limits. The transmitter maintains four alarm values for each process variable. In addition, the transmitter has an alarm hysteresis function to prevent erratic alarm reports.
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Configuration Figure 4-8 Changing alarm values EDD Bus parameters 64 Model 2700 Transmitter with PROFIBUS-PA
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Configuration 4.9.2 Alarm hysteresis Note the following about hysteresis: • A low hysteresis value allows the transmitter to broadcast a new alarm every time or nearly every time the process variable crosses over the alarm limit. • A high hysteresis value prevents the transmitter from broadcasting new alarms unless the process variable first returns to a value sufficiently below the high alarm limit or above the low alarm limit.
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Configuration 4.10 Configuring status alarm severity The severity level of some status alarms can be reclassified. For example: • The default severity level for Alarm A020 (calibration factors unentered) is Fault, but you can reconfigure it to either Informational or Ignore. • The default severity level for Alarm A102 (drive over-range) is Informational, but you can reconfigure it to either Ignore or Fault. A list of all status alarms and default severity levels is shown in Table 4-12.
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Configuration Table 4-12 Status alarms and severity levels (continued) Index Description Default severity A103 43 Data loss possible Informational Configurable (1) Yes A104 44 Calibration in progress Informational Yes A105 45 Slug flow Informational Yes A107 47 Power reset occurred Informational Yes A116 56 API temperature outside standard range Informational Yes A117 57 API density out of limits Informational Yes A120 60 Concentration measurement: unable to fit curve da
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Configuration 4.11 Changing the damping values A damping value is a period of time, in seconds, over which the process variable value will change to reflect 63% of the change in the actual process. Damping 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.
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Configuration Figure 4-12 Changing the damping values Before You Begin EDD Startup Bus parameters Damping Block: Transducer Block 1 (Slot 11) Index 33 (flow damping) Index 34 (temperature damping) Index 35 (density damping) ProLink II ProLink > Configuration Density tab Temperature tab Enter a damping value in the Flow Damp box Enter a damping value in the Dens Damping box Enter a damping value in the Temp Damping box Apply Apply Apply Calibration Flow tab Configuration Configuration and
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Configuration When you specify a new damping value, it is automatically rounded down to the nearest valid damping value. Valid damping values are listed in Table 4-13. Table 4-13 Valid damping values Process variable Valid damping values Flow (mass and volume) 0, 0.04, 0.08, 0.16, ... 40.96 Density 0, 0.04, 0.08, 0.16, ... 40.96 Temperature 0, 0.6, 1.2, 2.4, 4.8, ... 76.8 4.11.
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Configuration Figure 4-13 Configuring slug flow limits and duration ProLink II MMI Coriolis Flow > Transducer Block Calibration ProLink > Configuration Slug Limit Slug Duration Density tab Slug Low Limit Slug High Limit 4.
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Configuration Figure 4-14 Configuring cutoffs EDD MMI Coriolis Flow > Transducer Block > Measurement > Process Variable Mass Flow Volume Flow Density Mass Flow Low Cutoff Volume Flow Low Cutoff(1) Density Cutoff Notes: (1) When Gas Standard Volume is configured, this option will be displayed as Gas Std Vol Flow Cutoff. (2) When Gas Standard Volume is configured, this box will be labeled Std gas vol flow cutoff.
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Configuration 4.14 Changing the measurement mode parameter • Forward flow moves in the direction of the arrow on the sensor. • Reverse flow moves in the direction opposite from the arrow on the sensor. Table 4-15 shows the possible values for the measurement mode parameter and the transmitter’s behavior when the flow is positive or negative.
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Configuration 4.15 Configuring sensor parameters The sensor parameters are used to describe the sensor component of your flowmeter. These sensor parameters are not used in transmitter processing, and are not required: • Serial number • Sensor material • Liner material • Flange To configure the sensor parameters, refer to the flowcharts in Figure 4-16.
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Configuration 4.16 Configuring the display 4.16.1 Before You Begin You can restrict the display functionality or change the variables that are shown on the display. Enabling and disabling display functions Each display function and its associated parameter are listed in Table 4-16. Table 4-16 Display functions and parameters Display function EDD name Totalizer reset Totalizer Reset Start/stop totalizers Display code Disabled TOTALS RESET Resetting mass and volume totalizers is permitted.
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Configuration Figure 4-17 Configuring the display – EDD menus Figure 4-18 Configuring the display – bus parameters Display options Block: Transducer Block 1 (Slot 11) Index 220 (Totalizer reset) Index 221 (Totalizer start/stop) Index 222 (Auto scroll enabled/disabled) Index 223 (Offline menu enabled/disabled) Index 224 (Offline password enabled/disabled) Index 225 (Alarm menu enabled/disabled) Index 226 (Acknowledge all alarms) Index 227 (Set offline password) Index 228 (Auto scroll period) Index 229 (D
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Configuration 4.16.2 Changing the scroll rate To change the scroll rate: • With the EDD, refer to Figure 4-17. • With bus parameters, refer to Figure 4-18. • With ProLink II, refer to Figure 4-19. • With the display, refer to Figure B-13. 4.16.3 Changing the update period To change the update period: • With the EDD, refer to Figure 4-17. • With bus parameters, refer to Figure 4-18. • With ProLink II, refer to Figure 4-19. • With the display, refer to Figure B-13.
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Configuration 4.16.6 Changing the display variables and precision 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. Additionally, you can configure display precision for each display variable. Display precision controls the number of digits to the right of the decimal place. The range of the display precision is 0 to 5. Table 4-17 shows an example of a display variable configuration.
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Configuration Figure 4-20 Changing the display variables and precision Before You Begin EDD ProLink II ProLink > Configuration For each display variable, select a process variable from the list Display tab Enter a precision in the Number of Decimals box Apply Startup Bus parameters Display variables Block: Transducer Block 1 (Slot 11) Indices 232 through 246 Display precision Block: Transducer Block 1 (Slot 11) Index 231 (Number of decimals) Calibration Configuration Configuration and Use Manua
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Configuration 4.17 Enabling LD Optimization LD Optimization is a special compensation is that is specifically for hydrocarbon liquids. LD Optimization should not be used with any other process fluids. LD Optimization is available only with certain large sensor sizes. If your sensor can benefit from LD Optimization, the enable/disable option will appear in ProLink II or on the display.
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Configuration Figure 4-22 LD Optimization – Display Before You Begin Scroll and Select simultaneously for 4 seconds Scroll OFF-LINE MAINT Select Scroll CONFG FACTOR LD Scroll Scroll MTR F Startup Select Select Select LD OPT Calibration Configuration Configuration and Use Manual 81
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5.1 Operation Chapter 5 Operation Overview This chapter describes how to use the transmitter in everyday operation. The following topics and procedures are discussed: Using the I&M functions (Section 5.2) • Recording process variables (Section 5.3) • Viewing process variables (Section 5.4) • Using sensor simulation mode (Section 5.5) • Accessing diagnostic information with a PROFIBUS host (Section 5.6) • Viewing transmitter status and alarms (Section 5.
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Operation Record the following process variables: • Flow rate • Density • Temperature • Tube frequency • Pickoff voltage • Drive gain To view these values, refer to Section 5.4. 5.4 Viewing process variables Process variables include measurements such as mass flow rate, volume flow rate, temperature, and density. You can view process variables with the display (if your transmitter has a display), ProLink II, a PROFIBUS configuration tool (e.g.
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Operation 5.4.2 With ProLink II Operation The Process Variables window opens automatically when you first connect to the transmitter. This window displays current values for the standard process variables (mass, volume, density, temperature, external pressure, and external temperature). If you have closed the Process Variables window, select ProLink > Process Variables.
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Operation Figure 5-1 Sensor simulation mode – ProLink II ProLink > Configuration Select a wave form for mass flow, density, and temperature from the Wave Form lists Sensor Simulation tab Select Enable Simulation Mode Fixed wave Triangular or sine wave Enter a value in the Fixed Value box Enter period in the Period box Enter minimum and maximum amplitude in the Minimum and Maximum boxes Apply 5.
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Operation The status LED is located at the top of the display (Figure 5-2). The status LED can be in one of six possible states, as listed in Table 5-1. The procedure for responding to alarms is shown in Figure B-5.
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Operation Note: The location of alarms in the Status and Alarm Log windows is not affected by the configured alarm severity (see Section 4.10). Alarms in the Status window are predefined as Critical, Informational, or Operational. Alarms in the Alarm Log window are predefined as High Priority or Low Priority. 5.7.3 With EDD The transmitter sets its PROFIBUS output status to bad or uncertain whenever an alarm condition occurs.
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Operation Table 5-2 Totalizer and inventory display unit names Mass total Mass unit Mass inventory Mass unit alternating with MASSI Volume total (liquid) Volume unit Volume inventory (liquid) Volume unit alternating with LVOLI Gas standard volume total Volume unit Gas standard volume inventory Volume unit alternating with GSV I Petroleum measurement corrected volume total Volume unit alternating with TCORR Petroleum measurement corrected volume inventory Volume unit alternating with TCORI
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Operation With EDD To view the current value of the totalizers and inventories: • For standard mass, liquid standard volume, and gas standard volume, select View > Process Variables > Totalizer and then select Mass or Volume. (If the transmitter is configured to use gas standard volume, then Volume will be replaced by Gas Standard Volume.) Totals and inventories are displayed together. • For petroleum measurement, select Device > Device > API Totalizer.
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Operation With Prolink II Operation To control concentration measurement totalizers and inventories, choose ProLink > CM Totalizer Control. To control all other totalizer and inventory functions, choose ProLink > Totalizer Control. To reset inventories using ProLink II, you must first enable this capability. To enable inventory reset using ProLink II: 1. Choose View > Preferences. 2. Select the Enable Inventory Totals Reset checkbox. 3. Click Apply.
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6.1 Operation Chapter 6 Troubleshooting 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) Note: All procedures provided in this chapter assume that you have established communication with the transmitter and that you are complying with all applicable safety requirements.
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Troubleshooting 6.4 Transmitter does not communicate If the transmitter does not appear to be communicating on the network, then: 6.5 • Make sure the PROFIBUS network has proper termination. • Check the PROFIBUS wiring between the transmitter and the DP/PA coupler, and between the DP/PA coupler and the host system. • Perform the procedures under Section 6.9.4. • Make sure the node address is set correctly. The node address is set to a default value of 126 at the factory. See Section 2.3.
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Troubleshooting 6.7 Output problems • Flow rate • Density • Temperature • Tube frequency • Pickoff voltage • Drive gain Operation 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. Troubleshooting For troubleshooting, check the process variables under both normal flow and tubes-full no-flow conditions.
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Troubleshooting Table 6-3 Output problems and possible remedies (continued) Symptom Cause Possible remedies Erratic non-zero flow rate under no-flow conditions Wiring problem Verify all sensor-to-transmitter wiring and ensure the wires are making good contact. Refer to the installation manual. Incorrectly grounded 9-wire cable (only in 9-wire remote and remote core processor with remote transmitter installations) Verify 9-wire cable installation. Refer to the installation manual.
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Troubleshooting Table 6-3 Output problems and possible remedies (continued) Cause Possible remedies Inaccurate flow rate Bad flow cal factor Verify characterization. See Section 6.7.4. Inappropriate measurement unit Check measurement units using a PROFIBUS host or configuration tool. Bad sensor zero Rezero the flowmeter. See Section 3.6. Inaccurate density reading Verify characterization. See Section 6.7.4. Bad flowmeter grounding See Section 6.9.3. Slug flow See Section 6.10.
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Troubleshooting 6.7.1 Damping An incorrectly set damping value may make the transmitter’s output appear too sluggish or too jumpy. Adjust the damping parameters in the transducer block to achieve the damping effect you want. See Section 4.11.
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Troubleshooting 6.8 Status alarms Note: Some status alarms will cause all of the function blocks (AI, AO, and totalizer) to change to Out of Service mode. Table 6-4 Operation Status alarms are reported by a PROFIBUS host, the display, and ProLink II software. Remedies for the alarm states appear in Table 6-4. Status alarms and remedies Display code Description Possible remedies A001 EEPROM checksum Cycle power to the transmitter. The flowmeter might need service.
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Troubleshooting Table 6-4 Status alarms and remedies (continued) Display code Description Possible remedies A010 Calibration failure If alarm appears during zero, ensure there is no flow through the sensor, then retry. Cycle power to the flowmeter, then retry. A011 Calibration too low Ensure there is no flow through sensor, then retry. A012 Calibration too high Ensure there is no flow through sensor, then retry. Cycle power to the flowmeter, then retry.
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Troubleshooting Table 6-4 Status alarms and remedies (continued) Description Possible remedies A028 Sensor/transmitter write failure Cycle power to the meter. The flowmeter might need service. Contact Micro Motion Customer Service. A030 Hardware/software incompatible The loaded software is not compatible with the programmed board type. Contact Micro Motion. A031 Low Power The core processor is not receiving enough power.
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Troubleshooting 6.9 Diagnosing wiring problems Use the procedures in this section to check the transmitter installation for wiring problems. Installation procedures are provided in the manual entitled Model 1700 and Model 2700 Transmitters: Installation Manual. Removing the wiring compartment covers in explosive atmospheres while the power is on can cause an explosion. Before removing the field wiring compartment cover in explosive atmospheres, shut off the power and wait five minutes. 6.9.
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Troubleshooting 6.9.3 Checking the grounding 6.9.4 Operation The sensor and the transmitter must be grounded. If the core processor is installed as part of the transmitter or the sensor, it is grounded automatically. If the core processor is installed separately, it must be grounded separately. Refer to the installation manual. Checking the communication wiring To check the communication wiring, verify that: 6.10 • Communication wires and connections meet PROFIBUS wiring standards.
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Troubleshooting 6.12 Checking the test points 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. 6.12.1 Obtaining the test points You can obtain the test points with the PROFIBUS EDD, PROFIBUS bus parameters, or ProLink II. With PROFIBUS EDD To obtain the test points, select View > Diagnostics > Meter Diagnostics.
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Troubleshooting Table 6-6 Sensor pickoff values (continued) Pickoff value Model F200 sensors 2.0 mV peak to peak per Hz based on flow tube frequency Model H025, H050, and H100 sensors 3.4 mV peak to peak per Hz based on flow tube frequency Model H200 sensors 2.0 mV peak to peak per Hz based on flow tube frequency Model R025, R050, or R100 sensor 3.4 mV peak to peak per Hz based on flow tube frequency Model R200 sensor 2.
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Troubleshooting 6.12.5 Low pickoff voltage The causes and possible solutions of low pickoff voltage are listed in Table 6-9. Table 6-9 Low pickoff voltage causes and solutions Cause Solution Faulty wiring runs between the sensor and core processor Refer to the sensor manual and transmitter installation manual.
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Troubleshooting 6.13 Checking the core processor Two core processor procedures are available: You can check the core processor LED. The core processor has an LED that indicates different flowmeter conditions. • You can perform the core processor resistance test to check for a damaged core processor. Operation • For both tests you will need to expose the core processor. 6.13.1 Exposing the core processor Follow these procedures to expose the core processor. 1. Determine your installation type.
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Troubleshooting 6.13.2 Checking the core processor LED Do not shut off power to the transmitter when checking the core processor LED. To check the core processor LED: 1. Expose the core processor according to the instructions in Section 6.13.1. 2. Check the core processor LED against the conditions listed in Table 6-10 (standard core processor) or Table 6-11 (enhanced core processor).
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Troubleshooting Table 6-11 Enhanced core processor LED behavior, meter conditions, and remedies (continued) Possible remedy Solid red High severity alarm Check alarm status. Flashing red (80% on, 20% off) Tubes not full Flashing red (50% on, 50% off) Electronics failed Contact Micro Motion Customer Service. Flashing red (50% on, 50% off, skips every 4th) Sensor failed Contact Micro Motion Customer Service.
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Troubleshooting 6.14 Checking sensor coils and RTD Problems with sensor coils can cause several alarms, including sensor failure and a variety of out-of-range conditions. Checking the sensor coils involves testing the terminal pairs and testing for shorts to the case. 6.14.1 9-wire remote or remote core processor with remote transmitter installation If you have a 9-wire remote or a remote core processor with remote transmitter installation: 1. Power down the transmitter. 2.
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Troubleshooting 8.
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Troubleshooting 5. If you have a standard core processor, loosen the captive screw (2,5 mm) at the center of the core processor. Carefully remove the core processor from the sensor by grasping it and lifting it straight up. Do not twist or rotate the core processor. 6. If you have an enhanced core processor, loosen the two captive screws (2,5 mm) that hold the core processor in the housing. Gently lift the core processor out of the housing, then disconnect the sensor cable from the feedthrough pins.
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Troubleshooting Figure 6-2 Sensor pins – Standard core processor Operation Right pickoff (–) Right pickoff (+) Lead length compensator(1) (+) Left pickoff (–) Resistance temperature detector return / Lead length compensator (common) Left pickoff (+) Resistance temperature detector (+) Drive (–) Troubleshooting Drive (+) (1) LLC for all sensors except T-Series and CMF400 I.S. For T-Series sensors, functions as composite RTD. For CMF400 I.S. sensors, functions as fixed resistor.
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Troubleshooting Reinstalling the core processor If you removed the core processor, replace the core processor according to the instructions below. 1. If you have a standard core processor: a. Align the three guide pins on the bottom of the core processor with the corresponding holes in the base of the core processor housing. b. Carefully mount the core processor on the pins, taking care not to bend any pins. 2. If you have an enhanced core processor: a.
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A.1 Operation Appendix A Flowmeter Installation Types and Components Overview This appendix provides illustrations of different flowmeter installations and components for the Model 2700 transmitter. Installation diagrams Troubleshooting A.2 Model 2700 transmitters can be installed in four different ways (see Figure A-1): A.
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Flowmeter Installation Types and Components Figure A-1 Installation types Transmitter Integral Core processor (standard only) Sensor 4-wire remote Transmitter Sensor 4-wire cable Core processor (standard or enhanced) Transmitter 9-wire remote Sensor Core processor (standard only) 9-wire cable Junction box Transmitter Remote core processor with remote transmitter 4-wire cable Sensor Core processor (standard only) Junction box 116 9-wire cable Model 2700 Transmitter with PROFIBUS-PA
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Flowmeter Installation Types and Components Figure A-2 Transmitter and core processor components — Integral installations Operation Transmitter Transition ring Core processor 4 X Cap screws (4 mm) Base Sensor Troubleshooting Figure A-3 Transmitter components, junction end-cap removed — 4-wire remote and remote core processor with remote transmitter installations – Ground lug Main enclosure Conduit opening for 4-wire cable Mounting bracket Diagrams Junction housing 4 X Cap screws (4 mm) Junction
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Flowmeter Installation Types and Components Figure A-4 Transmitter/core processor assembly exploded view — 9-wire remote installations Transmitter Core processor 4 X Cap screws (4 mm) Core processor housing Conduit opening for 9-wire cable End-cap Mounting bracket Figure A-5 Remote core processor components Core processor lid 4 X Cap screws (4 mm) Conduit opening for 4-wire cable Conduit opening for 9-wire cable Mounting bracket 118 Core processor housing End-cap Model 2700 Transmitter with PRO
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Flowmeter Installation Types and Components Figure A-6 4-wire cable between Model 2700 transmitter and standard core processor User-supplied or factory-supplied 4-wire cable Mating connector (transmitter) Operation Core processor terminals VDC+ (Red) RS-485/B (Green) RS-485/A (White) Troubleshooting VDC– (Black) Figure A-7 4-wire cable between Model 2700 transmitter and enhanced core processor Core processor terminals User-supplied or factory-supplied 4-wire cable Mating connector (transmitter)
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Flowmeter Installation Types and Components Figure A-8 9-wire cable between sensor junction box and core processor 9-wire cable 9-wire terminal connections (core processor) Ground screw Black (Drains from all wire sets) to sensor junction box Green White Black Brown Violet Yellow Red Green White Brown Red Blue Gray Orange Violet Yellow Plug and socket Blue Gray Orange Mounting screw Figure A-9 Output and power supply terminals PROFIBUS terminals 1 2 9 (–, N) 10 (+, L) Equipment ground 7 8
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B.1 Operation Appendix B Using the Display 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. B.2 Components Figure B-1 illustrates the display components. Figure B-1 Troubleshooting Note that Model 2700 transmitters can be ordered with or without displays. Not all configuration and use functions are available through the display.
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Using the Display B.3 Using the optical switches The Scroll and Select optical switches are used to navigate the display menus. To activate an optical switch, touch the lens in front of the optical switch or move your finger over the optical switch close to the lens. There is an optical switch indicator between the optical switches. When an optical switch is activated, the optical switch indicator is a solid red.
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Using the Display B.4.3 Using display menus Operation Note: The display menu system provides access to basic transmitter functions and data. It does not provide access to all functions and data. To access all functions and data, use a PROFIBUS host, PROFIBUS configuration tool, or ProLink II To enter the display menu system: 1. Activate Scroll and Select simultaneously. 2. Hold Scroll and Select until the words SEE ALARM or OFF-LINE MAINT appear.
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Using the Display B.4.5 Entering floating-point values with the display 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 B-2) and the active digit is flashing. Figure B-2 Numeric values in decimal notation SX.XXXX Sign For positive numbers, leave this space blank. For negative numbers, enter a minus sign (–).
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Using the Display Figure B-3 Numeric values in exponential notation Sign Operation SX.XXXEYY Digit (0–9) Digits Enter a four-digit Sign or Digit (0–3) number; three digits must fall to the right E of the decimal point. Exponent indicator To change from exponential to decimal notation: 2. Scroll to d. 3. Select. The display changes to remove the exponent. To exit the menu: • • If the value has been changed, Select and Scroll simultaneously until the confirmation screen is displayed.
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Using the Display B.5 Abbreviations The display uses a number of abbreviations. Table B-1 lists the abbreviations used by the display.
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Using the Display B.6 Display menus Figures B-4 through B-16 show the commands accessible through the display.
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Using the Display Figure B-6 Display menu – Smart Meter Verification: Run verification ENTER METER/VERFY Select RUN VERFY RESULTS READ Scroll Scroll SCHEDULE VERFY Select OUTPUTS Select CONTINUE MEASR FAULT Scroll Select LAST VALUE Scroll Select Select ARE YOU SURE/YES? Select . . . . . . . . . . . . . . .
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Using the Display Figure B-7 Display menu – Smart Meter Verification: Read results Operation ENTER METER/VERFY Select RUN VERFY Scroll RESULTS READ SCHEDULE VERFY Scroll Select RUNCOUNT x Select Result type Abort Troubleshooting Pass Scroll Fail xx HOURS xx HOURS Select Select Select PASS CAUTION Abort Type Select Select Select xx L STF% xx L STF% Select Select xx R STF% xx R STF% Select Select Diagrams xx HOURS RESULTS MORE? Select To Runcount x-1 Scroll To Run V
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Using the Display Figure B-8 Display menu – Smart Meter Verification: Scheduling ENTER METER/VERFY Select RUN VERFY RESULTS READ Scroll SCHEDULE VERFY Scroll Select No Schedule set? Yes SCHED IS OFF TURN OFF SCHED/YES? Scroll Scroll Select Schedule deleted SET NEXT SET RECUR Scroll HOURS LEFT Select Select xx HOURS xx HOURS SAVE/YES? SAVE/YES? No No Scroll Select xx HOURS Scroll Figure B-9 Yes Select Scroll Select Yes Select Display menu – Off-line Maintenance OFF-LINE
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Using the Display Figure B-10 Display menu – Off-line Maintenance: Configuration Operation OFF-LINE MAINT Select Scroll SWREV CONFG Scroll ZERO Scroll SENSOR VERFY Scroll MTR F Scroll DISPLAY Select UNITS ADDRESS PBUS Scroll IDENT SEL Scroll CONFIG AO Scroll CONFIG TOT Scroll CONFIG AI Troubleshooting Scroll Figure B-11 Display menu – Off-line Maintenance: Configuration: Units UNITS Select Scroll MASS Scroll DENS TEMP Scroll GSV Diagrams Scroll Scroll VOL PRESS Figu
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Using the Display Figure B-13 Display menu – Off-line Maiintenance: Configuration: Display DISPLAY Select TOTALS RESET Scroll TOTALS STOP Scroll DISPLAY OFFLN Scroll DISPLAY ALARM Scroll DISPLAY ACK Scroll AUTO SCRLL Scroll SCROLL RATE Scroll CODE OFFLN Scroll CODE ALARM Scroll CHANGE CODE Scroll DISPLAY RATE Scroll DISPLAY LANG Scroll DISPLAY BKLT Figure B-14 Display menu – Off-line Maintenance: Configuration: AI blocks CONFG AI Select 132 AI1 CHAN Scroll AI1 UNITS Scroll
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Using the Display Figure B-15 Display menu – Off-line Maintenance: Configuration: AO blocks Operation CONFG AO Select Scroll AO1 PV UNITS Scroll AO1 OUTCH Scroll AO1 OUT UNITS Scroll AO2 INCH Scroll AO2 PV UNITS Scroll AO2 OUTCH Scroll AO2 OUT UNITS Troubleshooting AO1 INCH Figure B-16 Display menu – Off-line Maintenance: Configuration: Totalizers CONFG TOT Select Scroll TOT1 CHAN Scroll TOT1 UNITS Scroll TOT2 MODE Scroll TOT2 CHAN Scroll TOT2 UNITS Scroll TOT3 MODE Scroll
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Using the Display Figure B-17 Display menu – Off-line Maintenance: Zeroing OFF-LINE MAINT Select SWREV Scroll CONFG Scroll ZERO Scroll SENSOR VERFY Select CAL ZERO ………………….
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C.
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Connecting with ProLink II C.2.1 Connecting to the service port To temporarily connect to the service port, which is located in the non-intrinsically safe power-supply compartment: 1. Open the cover to the intrinsically safe wiring compartment. Opening the wiring compartment in a hazardous area can cause an explosion. The service port should only be used for temporary connections. When the transmitter is in an explosive atmosphere, do not use the service port to connect to the transmitter. 2.
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D.1 ProLink Appendix D PROFIBUS-PA Status Byte Overview This appendix describes the status byte reported by the transmitter to a PROFIBUS host. The output of each AI, AO, and totalizer function block is a 5-byte package: four bytes of process information and one byte indicating measurement quality, also called the status byte. The format of the status byte depends on whether the transmitter is configured for classic mode or condensed mode.
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PROFIBUS-PA Status Byte Table D-3 Bits Meaning Comment 0000 Non-specific TRUE if the following alarm codes are active: A005, A008, A010, A011, A012, A013, A021, A033, or A102. 0011 Initial value TRUE if the following alarm codes are active: A006 or A120. 1000 Simulated value TRUE if the following alarm codes are active: A132. 1001 Sensor calibration TRUE if the following alarm codes are active: A104.
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PROFIBUS-PA Status Byte D.3 Condensed-mode status byte format Table D-7 ProLink Table D-7 describes the format of the status byte when the transmitter is configured for condensed mode. Refer to the PROFIBUS Specification Profile for Process Control Devices Version v3.01 December 2004 and the PROFIBUS Specification June 2005 Amendment 2 to the PROFIBUS Profile for Process Control Devices v3.01, Condensed Status and Diagnostic Messages v1.0 for additional information.
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PROFIBUS-PA Status Byte Table D-7 Condensed-mode status byte format (continued) Expanded status Condensed status Alarms Totalizer Fail Safe: UC_NON_SPECIFIC (0x40) C_UNCERTAINC_SUBSTITUTE_SET (0x4B) Failsafe – MEMORY mode UC_INITIAL_VAL (0x4C) C_UNCERTAIN_INITIAL_VALUE (0x4F) When reset or preset totals. UC_SUBSTITUTE_VAL (0x48) C_UNCERTAIN_SUBSTITUTE_SET (0x4B) AO failsafe active. (1) Limits status as applicable. (2) AI function block FB behaves like FSAFE_TYPE = 1 as per Section 3.3.
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E.1 ProLink Appendix E Slave Diagnostic Response Bytes Overview This appendix describes the diagnostic bytes reported by the transmitter to a PROFIBUS host. There are two sets of diagnostic bytes sent: Bytes 1–6 conform to the standard PROFIBUS specification. • Byte 7 is the extended diagnostic header byte. • Bytes 8–15 are extended diagnostic bytes that conform to the Profile 3.01 specification and the Diagnosis, Alarms, and Timestamping Profile Guidelines.
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Slave Diagnostic Response Bytes Table E-2 Byte 2 Bit Indication 0 Slave must be parameterized 1 Static diagnostic: master requesting diagnostics until bit is reset 2 This bit is always set to 1 3 Response monitoring/watchdog (1 = ON; 0 = OFF) 4 Slave is in freeze mode (1 = ON; 0 = OFF) 5 Slave is in sync mode (1 = ON; 0 = OFF) 6 Reserved 7 Slave is deactivated in master parameter set (this is set by the master) Table E-3 Byte 3 Bit Indication 0 Reserved (this is always set to 0) 1
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Slave Diagnostic Response Bytes Table E-5 Bit Byte 5 Indication ProLink 0 1 2 3 4 Ident number (MSB)(1) 5 6 7 (1) The identification number will be 0x9742 when in profile-specific I/O mode and 0x057A when in manufacturing-specific I/O mode. Refer to Section 2.5 for information about I/O modes.
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Slave Diagnostic Response Bytes Table E-8 Bit Byte 8 Indication 8 9 10 11 Status type = manufacturer-specific (32 decimal, 0x20 hex) 12 13 14 15 Table E-9 Bit Identifier for status—always set to 1 Byte 9 Indication 8 9 10 11 12 Slot number of physical block (per Profile 3.
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Slave Diagnostic Response Bytes Table E-11 Byte 11 Indication 24 Reserved (always set to 0) 25 Reserved (always set to 0) 26 Reserved (always set to 0)—Not used 27 Reserved (always set to 0) 28 Reserved (always set to 0) 29 Reserved (always set to 0) 30 Reserved (always set to 0) 31 Reserved (always set to 0) ProLink Bit Table E-12 Byte 12 Indication 32 Reserved 33 Reserved 34 Reserved 35 Restart (A107) 36 Cold start (A107) 37 Maintenance required—Not used 38 Reserved 39
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Slave Diagnostic Response Bytes Table E-14 Byte 14 Bit Indication 48 Reserved (always set to 0) 49 Reserved (always set to 0) 50 Reserved (always set to 0) 51 Reserved (always set to 0) 52 Reserved (always set to 0) 53 Reserved (always set to 0) 54 Reserved (always set to 0) 55 Extension available Table E-15 Byte 15 Bit Indication 56 Undefined (A000) 57 EEPROM checksum error (A001) 58 RAM test error (A002) 59 Sensor not responding (no tube interrupt) (A003) 60 Temperature senso
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Slave Diagnostic Response Bytes Table E-17 Byte 17 Indication 72 Line RTD temperature out-of-range (A016) 73 Meter RTD temperature out-of-range (A017) 74 Reserved 75 Reserved 76 Calibration factors unentered (A020) 77 Unrecognized/unentered sensor type (A021) 78 Reserved 79 Reserved ProLink Bit Table E-18 Byte 18 Indication 80 Reserved 81 Reserved 82 Sensor/xmtr communication failure (A026) 83 Reserved 84 Sensor/xmtr write failure (A028) 85 Internal communication failure (A02
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Slave Diagnostic Response Bytes Table E-20 Byte 20 Bit Indication 96 Reserved 97 Reserved 98 Drive overrange/partially full tube (A102) 99 Data loss possible (A103) 100 Calibration in progress (A104) 101 Slug flow (A105) 102 Reserved 103 Power reset occurred (A107) Table E-21 Byte 21 Bit Indication 104 Reserved 105 Reserved 106 Reserved 107 Reserved 108 Reserved 109 Reserved 110 Reserved 111 Reserved Table E-22 Byte 22 148 Bit Indication 112 Petroleum measurement: t
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Slave Diagnostic Response Bytes Table E-23 Byte 23 Indication 120 Reserved 121 Reserved 122 Reserved 123 Reserved 124 Reserved 125 Reserved 126 Reserved 127 Meter verification info alarm (A131) ProLink Bit Table E-24 Byte 24 Indication 128 Simulation mode active (A132) 129 Reserved 130 Reserved 131 Reserved 132 Reserved 133 Reserved 134 Reserved 135 Reserved Status Bytes Bit Diagnostic Bytes Block Parameters Configuration and Use Manual 149
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F.1 ProLink Appendix F Model 2700 PROFIBUS Block Parameters Overview This appendix describes the block parameters of the Model 2700 transmitter with PROFIBUS-PA. F.2 Slot identification Table F-1 shows the slot assignment for blocks.
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Model 2700 PROFIBUS Block Parameters Table F-2 Physical block parameters (continued) Index Parameter Mnemonic Definition Message Type Data Type/ Structure Size Store /Rate (HZ) Default Value Access Enumerated List of Values / Range Modbus Register / Coil 20 ALERT_KEY This parameter contains the identification number of the plant unit. SIMPLE Unsigned8 1 S 0 R/W NA NA 21 TARGET_MODE This parameter contains desired mode normally set by a control application of an operator.
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Model 2700 PROFIBUS Block Parameters Table F-2 Physical block parameters (continued) Parameter Mnemonic Definition Message Type Data Type/ Structure Size Store /Rate (HZ) Default Value Access Enumerated List of Values / Range Modbus Register / Coil 43 COND_STATUS_DIAG Condensed Status Diagnostics Simple Unsigned-8 1 S 0 R/W 0: Status and Diagnosis is provided as defined in -PROFIBUS Profile: “PROFIBUS-PA Profile for Process Control Devices” V3.01, December 2004. PNO-Order-No. 3.042.
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Model 2700 PROFIBUS Block Parameters F.3.2 Physical block views Table F-4 shows the physical block views. Table F-4 Physical block views OD Index Parameter Mnemonic 16 BLOCK_OBJECT 17 ST_REV 18 TAG_DESC 19 STRATEGY 20 ALERT_KEY View 1 View 2 View 3 View 4 View 2 View 3 View 4 Standard Parameters 2 21 TARGET_MODE 22 MODE_BLK 3 23 ALARM_SUM 8 Overall sum of bytes in View Object 13 Parameter Mnemonic View 1 OD Index Standard Parameters 29 F.
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Model 2700 PROFIBUS Block Parameters Table F-5 Transducer block 1 parameters (continued) Parameter Mnemonic Definition Message Type Data Type/ Structure Size Store /Rate (HZ) Default Access Value 8 CALIBR_FACTOR (DD Name :Flow Cal Factor) Gain compensation value for the flow sensor, so that flow indication is accurate as specified by the manufacturer. SIMPLE Float 4 S --- R/W R-0407 9 LOW_FLOW_CUTOFF (DD Name : Mass Flow Cutoff) Mass Flow can have an hysteresis.
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Model 2700 PROFIBUS Block Parameters Table F-5 Transducer block 1 parameters (continued) Index Parameter Mnemonic Definition Message Type Data Type/ Structure Size Store /Rate (HZ) Default Access Value Enumerated List of Values / Range Modbus Register / Coil 26 DENSITY_UNITS (DD Name : Density Units) Selected unit code for DENSITY, DENSITY _LO_LIMIT and DENSITY _HI_LIMIT SIMPLE Unsigned16 2 S 1103 R/W 0000 = None 1097 = kg/m3 1100 = g/cm3 1103 = kg/L 1104 = g/ml 1105 = g/L 1106 = lb/in
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Model 2700 PROFIBUS Block Parameters Table F-5 Transducer block 1 parameters (continued) Parameter Mnemonic Definition Message Type Data Type/ Structure Size Store /Rate (HZ) Default Access Value Enumerated List of Values / Range Modbus Register / Coil 59 SNS_VolTotalUnits (DD Name: Volume Total/Inv Units) Standard or special volume total or mass inventory unit ENUM Unsigned16 2 S l/s R 0000 = None 1034 = m3 1036 = cm3 1038 = l 1043 = ft3 1048 = gal 1049 = ImpGal 1051 = bbl 1641 = Beer
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Model 2700 PROFIBUS Block Parameters Table F-5 Index Transducer block 1 parameters (continued) Parameter Mnemonic Definition Message Type Data Type/ Structure Size Store /Rate (HZ) Default Access Value Enumerated List of Values / Range Modbus Register / Coil CALIBRATION BLOCK 82 SNS_FlowCalTempCoeff (DD Name: Flow Temp Coeff (FT)) Temperature coefficient for flow VARIABLE FLOAT 4 S 5.13 R/W >=0.
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Model 2700 PROFIBUS Block Parameters Table F-5 Transducer block 1 parameters (continued) Parameter Mnemonic 112 113 Definition Message Type Data Type/ Structure Size Store /Rate (HZ) Default Access Value Enumerated List of Values / Range Modbus Register / Coil SNS_EnablePresComp Enable/Disable Pressure (DD Name: Pressure Compensation Compensation Enable /Disable) ENUM Unsigned 8 1 S 0 R/W 0x00 = disabled 0x01 = enabled Coil-0082 SNS_ExternalPresInput Pressure RECORD 101 5 D ---
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Model 2700 PROFIBUS Block Parameters Table F-5 Index 138 Transducer block 1 parameters (continued) Parameter Mnemonic Definition Message Type Data Type/ Structure Size Store /Rate (HZ) Default Access Value Enumerated List of Values / Range Modbus Register / Coil R-419 EMPTY Alarm Status 139 PA_StatusWords1 (DD Name: Alarm One Status) Status Word 1 ENUM BIT_ENUM ERATED 2 D/20 - R 0x0001 = Core EEPROM Checksum Error 0x0002 = Core RAM Test Error 0x0004 = Not Used 0x0008 = Sensor Failure
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Model 2700 PROFIBUS Block Parameters Table F-5 Transducer block 1 parameters (continued) Parameter Mnemonic Definition Message Type Data Type/ Structure Size Store /Rate (HZ) Default Access Value Enumerated List of Values / Range Modbus Register / Coil 143 PA_StatusWords5 (DD Name: Alarm Five Status) Status Word 5 ENUM BIT_ENUM ERATED 2 D/20 - R 0x0001 = Boot sector (CP) 0x0002 = Not Used 0x0004 = Not Used 0x0008 = Not Used 0x0010 = Not Used 0x0020 = Not Used 0x0040 = D3 in progress 0x0
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Model 2700 PROFIBUS Block Parameters Table F-5 Transducer block 1 parameters (continued) Index Parameter Mnemonic Definition Message Type Data Type/ Structure Size Store /Rate (HZ) Default Access Value Enumerated List of Values / Range 149 UNI_Alarm_Index (DD Name: Alarm N Index) Alarm Index ENUM Unsigned8 1 S 0 R/W 0 = Reserved R-1237 1 = NVM Failure 2 = RAM error /ROM error 3 = Sensor Fail 4 = Temp. Overrange 5 = Input Overrange 6 = Transmitter not charactized 7 = Reserved 8 = Dens.
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Model 2700 PROFIBUS Block Parameters Table F-5 Index Transducer block 1 parameters (continued) Parameter Mnemonic Definition Message Type Data Type/ Structure Size Store /Rate (HZ) Default Access Value Enumerated List of Values / Range Modbus Register / Coil 101 5 D 161 SNS_RawTubeFreq (DD Name: Tube Frequency) Raw Tube Period VARIABLE FLOAT 4 D/20 0 R N/A R-285-286 162 SNS_LiveZeroFlow (DD Name : Live Zero Flow) Live Zero (MassFlow) VARIABLE FLOAT 4 D/20 0 R N/A R-293-29
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Model 2700 PROFIBUS Block Parameters Table F-5 Transducer block 1 parameters (continued) Index Parameter Mnemonic Definition Message Type Data Type/ Structure Size Store /Rate (HZ) Default Access Value Enumerated List of Values / Range Modbus Register / Coil 185 FRF_AbortCode (DD Name: Abort Code) Abort Code ENUM Uns igned16 2 S --- R 0=No error 1=Manual Abort 2=Watchdog Timeout 3=Frequency Drift 4=High Peak Drive Voltage 5=High Drive Current Standard Deviation 6=High Drive Current Mea
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Model 2700 PROFIBUS Block Parameters Table F-5 Transducer block 1 parameters (continued) Parameter Mnemonic 212 EMPTY 213 EMPTY 214 EMPTY 215 EMPTY 216 EMPTY 217 EMPTY 218 EMPTY 219 Definition Message Type Data Type/ Structure Size Store /Rate (HZ) Default Access Value Enumerated List of Values / Range Modbus Register / Coil ProLink Index EMPTY LDO UI_EnableLdoTotalizerReset(D D Name: Totalizer Reset) Enable/Disable LDO Totalizer Reset ENUM Unsigned8 1 S 0x01 R/W 0x00 =
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Model 2700 PROFIBUS Block Parameters Table F-5 Index Transducer block 1 parameters (continued) Parameter Mnemonic Definition Message Type Data Type/ Structure Size Store /Rate (HZ) Default Access Value Enumerated List of Values / Range Modbus Register / Coil 22= CM: Density (Fixed SG Units) 23= CM: Standard Volume Flow Rate 24= CM: Standard Volume Total 25= CM: Standard Volume Inventory 26= CM: Net Mass Flow Rate 27= CM: Net Mass Total 28= CM: Net Mass Inventory 29= CM: Net Volume Flow Rate 30=
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Model 2700 PROFIBUS Block Parameters Table F-5 Index Transducer block 1 parameters (continued) Parameter Mnemonic Definition Message Type Data Type/ Structure Size Store /Rate (HZ) Default Access Value Enumerated List of Values / Range Modbus Register / Coil ProLink For Totals, the number of digits to the right of the decimal point to display on LDO VARIABLE Unsigned8 1 S - R/W 0 to 5 R-1368 232 UI_ProcessVariables (LDO_VAR_1_CODE) (DD Name: Display Variable 1) Display the Variable #
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Model 2700 PROFIBUS Block Parameters Table F-5 Index Transducer block 1 parameters (continued) Parameter Mnemonic Definition Message Type Data Type/ Structure Size Store /Rate (HZ) Default Access Value Enumerated List of Values / Range Modbus Register / Coil 51 = Board Temperature 52 = Input Voltage 53 = Ext. Input Pressure 54 = Not used 55 = Ext.
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Model 2700 PROFIBUS Block Parameters Table F-5 Transducer block 1 parameters (continued) Parameter Mnemonic Definition Message Type Data Type/ Structure Size Store /Rate (HZ) Default Access Value Enumerated List of Values / Range Modbus Register / Coil 233 UI_ProcessVariables (LDO_VAR_2_CODE) (DD Name: Display Variable 2) Display the Variable#2 associated with the code on the LDO ENUM Unsigned16 2 S 2 R/W 0 = Mass Flow Rate 1 = Temperature 2 = Mass Total 3 = Density 4 = Mass Inventory 5
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Model 2700 PROFIBUS Block Parameters Table F-5 Transducer block 1 parameters (continued) Index Parameter Mnemonic Definition Message Type Data Type/ Structure Size Store /Rate (HZ) Default Access Value Enumerated List of Values / Range Modbus Register / Coil 238 UI_ProcessVariables (LDO_VAR_7_CODE) (DD Name: Display Variable 7) Display the Variable#7 associated with the code on the LDO ENUM Unsigned16 2 S 251 R/W Same as LDO_VAR_2_CODE R-1123 239 UI_ProcessVariables (LDO_VAR_8_CODE)
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Model 2700 PROFIBUS Block Parameters Table F-6 Transducer block 1 object Element name Data type Size in bytes Slot 11/Index 0 Reserved Unsigned 8 1 250 (default) Block_Object Unsigned 8 1 03 Parent_Class Unsigned 8 1 03 Class Unsigned 8 1 03 DD_Refrence Unsigned 32 4 00 ,00, 00, 00 (reserved) DD_Revision Unsigned 16 2 00 ,00 (reserved) Profile Octet String 2 64 02 (compact class B) Profile_Revision Unsigned 16 2 03 01 (3.
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Model 2700 PROFIBUS Block Parameters F.4.3 Transducer block 2 (device information, API, CM) parameters Table F-8 shows the parameters for transducer block 2.
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Model 2700 PROFIBUS Block Parameters Table F-8 Transducer block 2 parameters (continued) Parameter Mnemonic Definition Message Type Data Type/ Structure Size Store /Rate (HZ) Default Acce Value ss Enumerated List of Values / Range Modbus Register / Coil 15 SNS_FlangeType (DD Name : Sensor Flange) Flange Type ENUM Unsigned16 2 S 0 R/W 0 = ANSI 150 1 = ANSI 300 2 = ANSI 600 5 = PN 40 7 = JIS 10K 8 = JIS 20K 9 = ANSI 900 10 = Sanitary Clamp Fitting 11 = Union 12 = PN 100 252 = Unknown 253
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Model 2700 PROFIBUS Block Parameters Table F-8 Transducer block 2 parameters (continued) Index Parameter Mnemonic Definition Message Type Data Type/ Structure Size Store /Rate (HZ) Default Acce Value ss Enumerated List of Values / Range Modbus Register / Coil 40 SNS_API2540TableType (DD Name: PM2540 CTL Table Type) API 2540 CTLTable Type ENUM Unsigned16 2 S API_ TABLE _53A R/W 19= Table 5D 36= Table 6C 49= Table 23A 50= Table 23B 51= Table 23D 68= Table 24C 81 = Table 53A 82 = Table 53
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Model 2700 PROFIBUS Block Parameters Table F-8 Transducer block 2 parameters (continued) Parameter Mnemonic Definition Message Type Data Type/ Structure Size Store /Rate (HZ) Default Acce Value ss Enumerated List of Values / Range Modbus Register / Coil 66 SNS_ED_CurveLock (DD Name: Lock/Unlock ED Curves) Lock Enhanced Density Tables ENUM Unsigned8 1 S 1 R/W 0x00 = not locked 0x01 = locked Coil-0085 67 SNS_ED_Mode (DD Name: Derived Variable) Enhanced Density Mode ENUM Unsigned16
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Model 2700 PROFIBUS Block Parameters Table F-8 Transducer block 2 parameters (continued) Index Parameter Mnemonic Definition Message Type Data Type/ Structure Size Store /Rate (HZ) Default Acce Value ss Enumerated List of Values / Range Modbus Register / Coil 88 SNS_ED_ConcUnitCode (DD Name: Curve N Concentration Units) Curven Concentration Units Code ENUM Unsigned16 2 S ---- R/W 1110 = Degrees Twaddell 1426= Degrees Brix 1111= Deg Baume (heavy) 1112= Deg Baume (light) 1343=% sol/wt 13
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Model 2700 PROFIBUS Block Parameters F.4.5 Transducer block 2 (device information, API, CM) views Table F-10 shows the views for transducer block 2.
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Model 2700 PROFIBUS Block Parameters Table F-11 I & M parameters (continued) Index Sub-Index 65001 65002 65016 Parameter Mnemonic IM_1 IM_2 PA_IM_0 Definition Message Type Data Type/ Structure Size Store/ Rate (HZ) Default Value Access Enu mera ted List of Valu es Modbus Register / Coil PROFILE_ID –Profile type of supporting Profile VARIABLE Unsigned16 2 S 0x9700 R -- Hard Coded PROFILE_SPECIFIC_TYP E –Specific Profile Type VARIABLE Octet String 2 S 0x01 0x01 R -- Byte 0:
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Model 2700 PROFIBUS Block Parameters F.4.7 AI function block parameters Table F-12 shows the parameters for the AI function blocks.
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Model 2700 PROFIBUS Block Parameters Table F-12 AI function block parameters (continued) Index Parameter Mnemonic Definition Message Type Data Type/ Structure Size Store /Rate (HZ) Default Access Value Enumerated List of Values / Range Modbus Register / Coil 35 ALARM_HYS (DD Name: AI Alarm Hys) Hysteresis SIMPLE FLOAT 4 S 0.
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Model 2700 PROFIBUS Block Parameters F.4.8 Analog input block objects Table F-13 shows the analog input block objects.
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Model 2700 PROFIBUS Block Parameters F.4.10 AO function block parameters Table F-15 lists the parameters for the AO function blocks.
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Model 2700 PROFIBUS Block Parameters Table F-15 AO function block parameters (continued) Parameter Mnemonic Definition Message Type Data Type/ Structure Size Store /Rate (HZ) Default Access Value Enumerated List of Values / Range Modbus Register / Coil 37 IN_CHANNEL (DD Name: AO IN Channel) Reference to the active Transducer Block and its parameter that provides the actual position of the final control element.
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Model 2700 PROFIBUS Block Parameters Table F-15 AO function block parameters (continued) Index Parameter Mnemonic 61 RESERVED 62 RESERVED 63 RESERVED 64 RESERVED 65 AO BLOCK VIEW 1 F.4.11 Definition Message Type Data Type/ Structure Size Store /Rate (HZ) Default Access Value Enumerated List of Values / Range Modbus Register / Coil Analog output block objects Table F-16 shows the analog output block objects.
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Model 2700 PROFIBUS Block Parameters Table F-17 AO function block views ST_REV 18 TAG_DESC 19 STRATEGY 20 ALERT_KEY 2 ProLink 17 21 TARGET_MODE 22 MODE_BLK 23 ALARM_SUM 8 Overall sum of bytes in View Object 13 OD Index Parameter Mnemonic View 1 28 READBACK 47 POS_D 2 49 CHECK_BACK 3 61 Overall sum of bytes in View Object (+ 13 Standard parameters bytes) 10+13 3 View 2 View 3 View 4 Standard Parameters Status Bytes F.4.
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Model 2700 PROFIBUS Block Parameters Table F-18 Totalizer block parameters (continued) Index Parameter Mnemonic 25 RESERVED Definition Message Type Data Type/ Structure Size Store /Rate (HZ) Default Access Value Enumerated List of Values / Range Modbus Register / Coil Totalizer Function Block Standard Parameters 26 TOTAL (DD Name: TOT Total) The Function Block parameter TOTAL contains the integrated quantity of the rate parameter provided by CHANNEL and the associated status.
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Model 2700 PROFIBUS Block Parameters Table F-18 Totalizer block parameters (continued) 51 RESERVED 52 Totalizer Selection (DD Name: TOT Selection) 53 TOTALIZER BLOCK VIEW1 F.4.
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Model 2700 PROFIBUS Block Parameters Table F-20 Totalizer function block views OD Index Parameter Mnemonic 16 BLOCK_OBJECT 17 ST_REV 18 TAG_DESC View 1 View 2 View 3 View 4 View 2 View 3 View 4 Standard Parameters 2 19 STRATEGY 20 ALERT_KEY 21 TARGET_MODE 22 MODE_BLK 23 ALARM_SUM 8 Overall sum of bytes in View Object 13 Parameter Mnemonic View 1 OD Index 3 Standard Parameters 188 26 TOTAL 5 53 Overall sum of bytes in View Object (+ 13 Standard parameters bytes) 5+13
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G.1 NE53 Appendix G NE53 History Overview This appendix documents the change history of the Model 2700 transmitter with PROFIBUS-PA software. G.2 Software change history Table G-1 Transmitter software change history Date Software version Changes to software 09/2000 1.0 Initial release 08/2001 1.1 Software improvements Operating instructions 20000327 Rev. A 20000327 Rev. B Expanded the ability to control totalizers through multiple communication protocols. 02/2002 2.
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NE53 History Table G-1 Transmitter software change history (continued) Date Software version Changes to software Operating instructions 10/2009 3.0 Software improvements 20000327 Rev. FA Improved EDD more closely matches ProLink II. Added petroleum measurement application. Added enhanced density application. Improved consistency with other Micro Motion 2700 transmitters. Feature additions Added compatibility with enhanced core processor. Added gas standard volume measurement.
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Index NE53 B Bus parameter reference 151 C Cable 119, 120 Calibration 19 density 20, 39 failure 94 temperature 20, 44 zero 20 Channels assigning AI blocks 8 transducer block 8, 12 Characterization 19, 20, 22 sensor tags 23 Characterizing sample calibration tags 23 Classic mode 137 CODE? 123 Codes display codes 126 Communication problems 94 Component diagrams 115 Concentration measurement application 59 Condensed mode 139 Configuration planning 4, 5, 47 Configuration and Use Manual Core processor 116, 117
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Index E EDD 2, 3 Engineering units 51 Errors see Alarms Exponential notation 125 F Fault configuring alarms for 66 Flanges 74 Flow calibration values 24 Flow direction 73 G Gas standard volume 48 measurement units list 52 GSD 2, 3, 10 H High alarm 63 Hysteresis 65 I I & M 2, 83 I/O mode 10 Installation types 115, 116 Inventories 88 controlling 90 value of 88 L Language on local display 77, 122 LED core processor 108 Liner material 74 Local display see Display Low alarm 63 Low-flow cutoffs see Cutoffs M Man
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Index Configuration and Use Manual Index T Temperature measurement units list 54 Temperature calibration 20, 44 Temperature compensation 16 enabling 16 temperature source 17 Temperature correction for petroleum measurement 55 Terminal diagrams 115, 119, 120 Test points 104 Thermal expansion coefficient 55 for petroleum measurement 58 Totalizer block mode 11 Totalizers 88 controlling 90 value of 88 Transducer block channels 8, 9, 12 meter factor parameters 36 Transmitter components 117, 118 Transmitter s
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194 Model 2700 Transmitter with PROFIBUS-PA
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© 2011 Micro Motion, Inc. All rights reserved. P/N 20000327, Rev. FB *20000327* For the latest Micro Motion product specifications, view the PRODUCTS section of our web site at www.micromotion.com Micro Motion Inc.