Page 1 Configuration and Use Manual P/N MMI-20007739, Rev. B July 2008 ® Micro Motion Model 2400S Transmitters ™ for DeviceNet Configuration and Use Manual...
Page 2 Micro Motion, Inc., Boulder, Colorado. Micro Motion is a registered trade name of Micro Motion, Inc., Boulder, Colorado. The Micro Motion and Emerson logos are trademarks and service marks of Emerson Electric Co. All other trademarks are property of their respective owners.
Page 3: Table Of Contents
Contents Chapter 1 Before You Begin ........1 Overview .
Page 4 Contents Chapter 5 Using a DeviceNet Tool ....... . 21 Overview .
Page 5 Contents Chapter 8 Optional Configuration ....... . 55 Overview ............55 Configuring volume flow measurement for gas .
Page 6 Contents Chapter 10 Measurement Performance ......89 10.1 Overview ............89 10.2 Meter validation, meter verification, and calibration .
Page 7 Contents Appendix A Default Values and Ranges ......131 Overview ............131 Most frequently used defaults and ranges .
Page 8 ® ™ Micro Motion Model 2400S Transmitters for DeviceNet...
Page 9: Chapter 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 the Micro Motion Model 2400S transmitter for ™...
Page 10: Devicenet Functionality
Before You Begin DeviceNet functionality The Model 2400S DN transmitter implements the following DeviceNet functionality: • Baud rates: 125 kBaud 250 kBaud 500 kBaud • I/O slave messaging: Polling Cyclic • Configuration methods: Hardware switches Custom software Determining version information Table 1-1 lists the version information that you may need and describes how to obtain the information.
Page 11: Planning The Configuration
Before You Begin In this manual: • Basic information on using the transmitter’s user interface is provided in Chapter 3. • Basic information on using ProLink II or Pocket ProLink, and connecting ProLink II or Pocket ProLink to your transmitter, is provided in Chapter 4. For more information, see the ProLink II or Pocket ProLink manual, available on the Micro Motion web site (www.micromotion.com).
Page 12: Pre-Configuration Worksheet
Before You Begin Figure 1-1 Configuration overview Chapter 1 Chapter 8 Chapter 9 Before You Begin Optional Configuration Pressure Compensation and Temperature Compensation Fill out pre-configuration Configure volume flow worksheet Configure pressure measurement for gas compensation (optional) Chapter 2 Configure cutoffs Configure temperature Flowmeter Startup compensation (optional)
Page 13: Flowmeter Documentation
Before You Begin Pre-configuration worksheet Transmitter ____________________________ Item Configuration data Transmitter model number ______________________________________ Core processor (transmitter) software revision ______________________________________ DeviceNet node address ______________________________________ DeviceNet baud rate ______________________________________ Measurement units Mass flow ______________________________________ Volume flow ______________________________________ Density ______________________________________ Pressure ______________________________________ Temperature ______________________________________ Installed applications...
Page 14: Micro Motion Customer Service
Before You Begin 1.10 Micro Motion customer service For customer service, phone the support center nearest you: • In the U.S.A., phone (800-522-6277) (toll-free) 800-522-MASS • In Canada and Latin America, phone +1 303-527-5200 • In Asia: In Japan, phone 3 5769-6803 In other locations, phone +65 6777-8211 (Singapore) •...
Page 15: Chapter 2 Flowmeter Startup
Chapter 2 Flowmeter Startup Overview This chapter describes the following procedures: • Setting the DeviceNet node address and baud rate – see Section 2.2 • Bringing the transmitter online – see Section 2.3 Setting the DeviceNet node address and baud rate The default node address for the Model 2400S DN transmitter is .
Page 16 Flowmeter Startup 3. Insert an appropriate DeviceNet cable into the connector on the transmitter. When the transmitter receives power, it will automatically perform diagnostic routines, and the module LED flashes red and green. When the flowmeter has completed its power-up sequence, the status LED will show a solid green.
Page 17: Using The Transmitter User Interface
Chapter 3 Using the Transmitter User Interface Overview This chapter describes the user interface of the Model 2400S DN transmitter. The following topics are discussed: • Transmitters without or with display – see Section 3.2 • Removing and replacing the transmitter housing cover – see Section 3.3 •...
Page 18 Using the Transmitter User Interface Figure 3-1 User interface – Transmitters without display Digital communications hardware switches Zero button Status LED Module LED Network LED Service port clips Figure 3-2 User interface – Transmitters with display Digital communications hardware switches LCD panel Current value Status LED...
Page 19: Removing And Replacing The Transmitter Housing Cover
Using the Transmitter User Interface For information on: • Using the digital communications hardware switches, see Section 8.10. • Using the LEDs, see Section 7.4. • Making a service port connection, see Chapter 4. • Using the zero button, see Section 10.5. Removing and replacing the transmitter housing cover For some procedures, you must remove the transmitter housing cover.
Page 20: Using The Display
Using the Transmitter User Interface Using the display Note: This section applies only to transmitters with a display. The display can be used to view process variable data or to access the transmitter menus for configuration or maintenance. 3.5.1 Display language The display can be configured for the following languages: •...
Page 21: Using Display Menus
Using the Transmitter User Interface 3.5.3 Using display menus 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 either ProLink II or a customer-supplied DeviceNet tool.
Page 22: Display Password
Using the Transmitter User Interface 3.5.4 Display password Some of the display menu functions, such as accessing the off-line menu, can be protected by a display password. For information about enabling and setting the display password, refer to Section 8.9. If a password is required, the word appears at the top of the password screen.
Page 23 Using the Transmitter User Interface To change from decimal to exponential notation (see Figure 3-5): until the rightmost digit is flashing. Select , then . The display changes to provide two spaces for entering the exponent. Scroll Select 3. To enter the exponent: Select until the desired digit is flashing.
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Page 25: Connecting With Prolink Ii Or Pocket Prolink Software
Chapter 4 Connecting with ProLink II or Pocket ProLink Software Overview ProLink II is a Windows-based configuration and management tool for Micro Motion transmitters. It provides access to most transmitter functions and data. Pocket ProLink is a version of ProLink II that runs on a Pocket PC.
Page 26: Connecting To A Model 2400S Dn Transmitter
Connecting with ProLink II or Pocket ProLink Software Connecting to a Model 2400S DN transmitter To connect to the Model 2400S DN transmitter using ProLink II or Pocket ProLink, you must use a service port connection. 4.4.1 Connection options The service port can be accessed via the service port clips or the IrDA port. The service port clips have priority over the IrDA port: •...
Page 27 Connecting with ProLink II or Pocket ProLink Software WARNING Removing the transmitter housing cover in a hazardous area can cause an explosion. Because the transmitter housing cover must be removed to connect to the service port clips, the service port clips should be used only for temporary connections, e.g., for configuration or troubleshooting purposes.
Page 28: Connecting Via The Irda Port
Connecting with ProLink II or Pocket ProLink Software 4.4.4 Connecting via the IrDA port Note: The IrDA port is typically used with Pocket ProLink. To use the IrDA port with ProLink II, a special device is required; the IrDA port built into many laptop PCs is not supported. For more information on using the IrDA port with ProLink II, contact Micro Motion customer service.
Page 29: Chapter 5 Using A Devicenet Tool
Chapter 5 Using a DeviceNet Tool Overview A customer-supplied DeviceNet tool can be used to communicate with the Model 2400S DN transmitter. This chapter provides basic information on using a customer-supplied DeviceNet tool. However, because there are a variety of DeviceNet tools available, this chapter does not provide detailed information for using any one tool.
Page 30: Using A Devicenet Tool
Using a DeviceNet Tool For complete documentation of the Model 2400S DN transmitter’s device profile, including input and output assemblies, see the manual entitled Micro Motion Model 2400S Transmitters for DeviceNet: Device Profile. Using a DeviceNet tool Micro Motion supplies an Electronic Data Sheet (EDS) for the Model 2400S transmitter. The EDS file is named .
Page 31: Default Assemblies
Using a DeviceNet Tool Default assemblies The default assemblies used by the Model 2400S DN transmitter are listed and described in Table 5-1. To change the default assemblies, see the flowchart in Figure 5-1. Table 5-1 Default DeviceNet assemblies Connection type Assembly type Instance ID Description...
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Page 33: Required Transmitter Configuration
Chapter 6 Required Transmitter Configuration Overview This chapter describes the configuration procedures that are usually required when a transmitter is installed for the first time. The following procedures are discussed: • Characterizing the flowmeter – see Section 6.2 • Configuring measurement units – see Section 6.3 This chapter provides basic flowcharts for each procedure.
Page 34 Required Transmitter Configuration Table 6-1 Sensor calibration parameters Sensor type Parameter T-Series Other ✓ ✓ ✓ ✓ ✓ ✓ ✓ ✓ ✓ ✓ ✓ ✓ Temp coeff (DT) ✓ Flowcal ✓ ✓ ✓ ✓ ✓ DFQ1 ✓ DFQ2 (1) On some sensor tags, shown as TC. (2) See the section entitled “Flow calibration values.”...
Page 35: How To Characterize
Required Transmitter Configuration When configuring the flow calibration factor: • With ProLink II, enter the concatenated 10-character string exactly as shown, including the decimal points. For example, using the Flow Cal value from Figure 6-1, enter 19.0005.13 • With a DeviceNet tool, enter the two factors separately, i.e., enter a 6-character string and a 4-character string.
Page 36: Configuring The Measurement Units
Required Transmitter Configuration Configuring the measurement units For each process variable, the transmitter must be configured to use the measurement unit appropriate to your application. To configure measurement units for process variables, see the menu flowcharts in Figure 6-3. For details on measurement units for each process variable, see Sections 6.3.1 through 6.3.4.
Page 37 Required Transmitter Configuration Figure 6-3 Configuring measurement units ProLink II Display ProLink > Off-line maint > Configuration Off-line config Flow Units Density Mass Temperature Vol (or GSV) Pressure Density Temperature DeviceNet tool Pressure Class: Analog Input Point Object (0x0A) Instance: 1 Mass flow unit Attribute ID: 102 Value: See Table 6-2...
Page 38: Mass Flow Units
Required Transmitter Configuration 6.3.1 Mass flow units The default mass flow measurement unit is . See Table 6-2 for a complete list of mass flow measurement units. Table 6-2 Mass flow measurement units Mass flow unit Display ProLink II DeviceNet tool DeviceNet code Unit description 0x0800...
Page 39 Required Transmitter Configuration Table 6-3 Volume flow measurement units – Liquid continued Volume flow unit Display ProLink II DeviceNet tool DeviceNet code Unit description CUFT/D ft3/day /day 0x0816 Cubic feet per day M3/S m3/sec 0x1405 Cubic meters per second M3/MIN m3/min /min 0x080F...
Page 40: Density Units
Required Transmitter Configuration Table 6-4 Volume flow measurement units – Gas continued Volume flow unit Display ProLink II DeviceNet tool DeviceNet code Unit description NLPM NLPM Nml l/min 0x1401 Normal liter per minute NLPH NLPH Nml l/hr 0x083E Normal liter per hour NLPD NLPD Nml l/day...
Page 41: Temperature Units
Required Transmitter Configuration 6.3.4 Temperature units The default temperature measurement unit is ° . See Table 6-6 for a complete list of temperature measurement units. Table 6-6 Temperature measurement units Temperature unit Display ProLink II DeviceNet tool DeviceNet code Unit description °...
Page 42 Required Transmitter Configuration Table 6-7 Pressure measurement units continued Pressure unit Display ProLink II DeviceNet tool DeviceNet code Unit description megapascals 0x085B Megapascals TORR Torr torr 0x1301 Torr @ 0 °C @ 0C atms 0x130B Atmospheres ® ™ Micro Motion Model 2400S Transmitters for DeviceNet...
Page 43: Using The Transmitter
Chapter 7 Using the Transmitter Overview This chapter describes how to use the transmitter in everyday operation. The following topics and procedures are discussed: • Recording process variables – see Section 7.2 • Viewing process variables – see Section 7.3 •...
Page 44: Viewing Process Variables
Using the Transmitter Viewing process variables Process variables include measurements such as mass flow rate, volume flow rate, mass total, volume total, temperature, and density. You can view process variables with the display (if your transmitter has a display), ProLink II, or a DeviceNet tool.
Page 45: With A Devicenet Tool
Using the Transmitter To view enhanced density process variables (if the enhanced density application is enabled), click ProLink > ED Process Variables . Different enhanced density process variables are displayed, depending on the configuration of the enhanced density application. 7.3.3 With a DeviceNet tool There are two methods that can be used to view process variables with a DeviceNet tool: •...
Page 46 Using the Transmitter Table 7-1 Process data in DeviceNet objects continued Attribute Data Class Instance type Description API Object (0x69) REAL Temperature-corrected density REAL Temperature-corrected (standard) volume flow REAL Temperature-corrected (standard) volume total REAL Temperature-corrected (standard) volume inventory REAL Batch weighted average density REAL Batch weighted average temperature REAL...
Page 47 Using the Transmitter Table 7-2 Summary of input assemblies continued Instance ID Data description Size (bytes) Data type Description • Status • BOOL Mass flow, mass • Mass flow • REAL totals, and other • Mass total • REAL process •...
Page 48 Using the Transmitter Table 7-2 Summary of input assemblies continued Instance ID Data description Size (bytes) Data type Description (1)(3) • Status • BOOL Petroleum • API temperature-corrected density • REAL measurement • API temperature-corrected volume flow • REAL application •...
Page 49: Using The Leds
Using the Transmitter Table 7-2 Summary of input assemblies continued Instance ID Data description Size (bytes) Data type Description (1)(4) • Status • BOOL Enhanced • Mass flow • REAL density • Volume flow • REAL application • Density • REAL •...
Page 50: Using The Network Led
Using the Transmitter Table 7-3 Module LED states, definitions, and recommendations Module LED state Definition Recommendations No power Check the connection to the DeviceNet network. Solid green No processor faults No action required. Flashing green Needs DeviceNet configuration; Indicates an A006 alarm. Characterization may be in Standby state parameters are missing.
Page 51: Using Prolink Ii
Using the Transmitter Table 7-5 Transmitter status LED Status LED state Alarm priority Definition Green No alarm Normal operating mode Flashing yellow A104 alarm Zero or calibration in progress Solid yellow Low severity (information) alarm • Alarm condition: will not cause measurement error •...
Page 52: Using The Display
Using the Transmitter In addition, the transmitter maintains alarm history for the 50 most recent alarm occurrences. Alarm history includes: • The alarm code • The “alarm active” timestamp • The “alarm inactive” timestamp • The “alarm acknowledged” timestamp When the transmitter detects an alarm condition, it checks the severity level of the specific alarm and performs the actions described in Table 7-6.
Page 53: Using Prolink Ii
Using the Transmitter Figure 7-1 Viewing and acknowledging alarms with the display Scroll and Select simultaneously for 4 seconds SEE ALARM Select ACK ALL (1) This screen is displayed only if the ACK ALL function is enabled (see Section 8.9.3) and there are unacknowledged alarms.
Page 54: Using A Devicenet Tool
Using the Transmitter In the Status window: • Alarms are organized into three categories: Critical, Informational, and Operational. Each category is displayed on a separate panel. • If one or more alarms is active on a panel, the corresponding tab is red. •...
Page 55: Using The Totalizers And Inventories
Using the Transmitter To view information about a single alarm: 1. Execute a Set for Attribute 18, specifying the code for the alarm you want to check. 2. Execute a Get for Attribute 42, and interpret the data using the following codes: •...
Page 56: Viewing Current Values For Totalizers And Inventories
Using the Transmitter 7.7.1 Viewing current values for totalizers and inventories You can view current values for the totalizers and inventories with the display (if your transmitter has a display), ProLink II, or a DeviceNet tool. With the display You cannot view current totalizer or inventory values with the display unless the display has been configured to show them.
Page 57: Controlling Totalizers And Inventories
Using the Transmitter With ProLink II To view current totals for the totalizers and inventories with ProLink II: 1. Click ProLink 2. Select Process Variables API Process Variables, ED Process Variables. With a DeviceNet tool To view current totals for the totalizers and inventories with a DeviceNet tool, see Section 7.3.3. 7.7.2 Controlling totalizers and inventories Specific starting, stopping, and resetting functionality depends on the tool you are using.
Page 58 Using the Transmitter With ProLink II The totalizer and inventory control functions available with ProLink II are listed in Table 7-7. Note the following: • ProLink II does not support separate resetting of the API volume totalizer and API volume inventory.
Page 59 Using the Transmitter To reset an individual totalizer or inventory: 1. Click (if the enhanced ProLink > Totalizer Control ProLink > ED Totalizer Control density application is enabled). 2. Click the appropriate button (e.g., Reset Mass Total Reset Volume Inventory Reset Net Mass Total With a DeviceNet tool...
Page 60 Using the Transmitter Table 7-8 Totalizer and inventory control with a DeviceNet tool using explicit write continued To accomplish this Use this device profile data Reset all inventories Analog Input Point Object (0x0A) Instance: 0 Attribute ID: 102 Service: Set Value: 1 Reset mass totalizer Analog Input Point Object (0x0A)
Page 61 Using the Transmitter Table 7-9 Output assemblies used for totalizer and inventory control Instance ID Data description Size (bytes) Data type • Start/stop all totalizers and inventories • BOOL • Reset all totalizer values • BOOL • Reset all inventory values •...
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Page 63: Optional Configuration
Chapter 8 Optional Configuration Overview This chapter describes transmitter configuration parameters that may or may not be used, depending on your application requirements. For required transmitter configuration, see Chapter 6. Table 8-1 lists the parameters that are discussed in this chapter. Default values and ranges for the most commonly used parameters are provided in Appendix A.
Page 64: Configuring Volume Flow Measurement For Gas
Optional Configuration Table 8-1 Configuration map continued Tool Topic Subtopic ProLink II DeviceNet tool Display Section ✓ ✓ ✓ Display Update period 8.9.1 ✓ ✓ ✓ Display language 8.9.2 ✓ ✓ ✓ Totalizer start/stop 8.9.3 ✓ ✓ ✓ Totalizer reset ✓...
Page 65: Using Prolink Ii
Optional Configuration 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 (see Tables 6-3 and 6-4).
Page 66: Using A Devicenet Tool
Optional Configuration 5. Click Next 6. Verify the reference temperature and reference pressure. If these are not appropriate for your application, click the button and enter new values for Change Reference Conditions reference temperature and reference pressure. 7. Click . The calculated standard density value is displayed. Next •...
Page 67: Cutoffs And Volume Flow
Optional Configuration Table 8-2 Cutoff default values Cutoff type Default Comments Mass flow 0.0 g/s Recommended setting: 5% of the sensor’s rated maximum flowrate Liquid volume flow 0.0 L/s Limit: the sensor’s flow calibration factor in liters per second, multiplied by 0.2 Gas standard volume No limit flow...
Page 68: Damping And Volume Measurement
Optional Configuration Table 8-3 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 To configure damping values: •...
Page 69: Configuring Events
Optional Configuration Table 8-4 Effect of flow direction on totalizers and flow values Forward flow Flow direction value Flow totals Flow values Forward only Increase Positive Reverse only No change Positive Bidirectional Increase Positive Absolute value Increase Positive Negate/Forward only No change Negative Negate/Bidirectional...
Page 70 Optional Configuration 3. Assign a process variable to the event (Attribute 10). 4. Specify the event’s setpoint(s) – the value(s) at which the event will occur or switch state (ON to OFF, or vice versa). • If Event Type is High or Low, only Setpoint A is used (Attribute 8) •...
Page 71 Optional Configuration Table 8-6 Event actions continued DeviceNet ProLink II label Display label code Description Reset all totals RESET ALL Resets the value of all totalizers to 0 Start/stop all totalization START STOP If totalizers are running, stops all totalizers If totalizers are not running, starts all totalizers Increment current ED INCR CURVE...
Page 72: Checking And Reporting Event Status
Optional Configuration 8.6.2 Checking and reporting event status There are several ways that event status can be determined: • ProLink II automatically displays event information on the Informational panel of the Status window. • The status of each event is stored in the Diagnostics Object (0x66), Instance 1, Attribute 11. For more information, see Table C-7, or see the manual entitled Micro Motion Model 2400S Transmitters for DeviceNet: Device Profile.
Page 73: Configuring Status Alarm Severity
Optional Configuration If the transmitter detects slug flow: • A slug flow alarm is posted immediately. • During the slug duration period, the transmitter holds the mass flow rate at the last measured pre-slug value, independent of the mass flow rate measured by the sensor. The reported mass flow value is set to this value, and all internal calculations that include mass flow rate will use this value.
Page 74 Optional Configuration Some 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 Ignore • The default severity level for Alarm A102 (drive over-range) is Informational , but you can reconfigure it to either...
Page 75: Configuring The Display
Optional Configuration Table 8-8 Status alarms and severity levels continued Default Affected by Alarm code ProLink II message severity Configurable? fault timeout? A116 API: Temperature Outside Standard Range Info A117 API: Density Outside Standard Range Info A120 ED: Unable to Fit Curve Data Info A121 ED: Extrapolation Alarm...
Page 76: Configuring The Lcd Backlight
Optional Configuration Table 8-9 Display functions Parameter Enabled (shown) Disabled (hidden) Totalizer start/stop Operators can start or stop totalizers using the Operators cannot start or stop totalizers using display. the display. Totalizer reset Operators can reset the mass and volume Operators cannot reset the mass and volume totalizers using the display.
Page 77: Configuring The Display Variables And Display Precision
Optional Configuration In addition, if you are using ProLink II or a DeviceNet tool, you can control the intensity of the backlight. You can specify any value between ; the higher the value, the brighter the backlight. To control the intensity of the backlight: •...
Page 78: Configuring Digital Communications
Optional Configuration 8.10 Configuring digital communications The digital communications parameters control how the transmitter will communicate using digital communications. The following digital communications parameters can be configured: • DeviceNet node address (MAC ID) • DeviceNet baud rate • DeviceNet configurable input assembly •...
Page 79: Devicenet Baud Rate
Optional Configuration 8.10.2 DeviceNet baud rate The default baud rate for the Model 2400S DN transmitter is . Valid baud rates are listed in 125 kBaud Table 8-11. The baud rate can be set using a digital communications hardware switch or a DeviceNet tool. If the device cannot determine what its baud rate should be, it defaults to 500 kBaud.
Page 80: Modbus Address
Optional Configuration The Assembly Object is used to configure the configurable input assembly. See the flowchart in Figure 8-2. Figure 8-2 Configurable input assembly – DeviceNet tool Class: Assembly Object (0x0A) Instance: 26 User-specified Attribute ID: 100 variable 1 Value: See Table C-15 Service: Set Class: Assembly Object (0x0A) Instance: 26...
Page 81: Irda Port Usage
Optional Configuration The primary reason to disable Modbus ASCII support is to allow a wider range of Modbus addresses for the service port. To enable or disable Modbus ASCII support: • Using ProLink II, see Figure B-2. • Using the display menus, see Figure B-6. 8.10.6 IrDA port usage The IrDA port on the display can be enabled or disabled.
Page 82: Fault Timeout
Optional Configuration To configure digital communications fault action: • Using ProLink II, see Figure B-2. • Using a DeviceNet tool, see Table C-7. Note: This functionality is not available via the display menus. 8.10.8 Fault timeout By default, the transmitter activates the digital communications fault action as soon as the fault is detected.
Page 83: Configuring Sensor Parameters
Optional Configuration 8.12 Configuring sensor parameters The sensor parameters are used to describe the sensor component of your flowmeter. They are not used in transmitter processing, and are not required. The following sensor parameters can be changed: • Serial number (can be set only once) •...
Page 84 Optional Configuration API 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.
Page 85: Configuration Procedure
Optional Configuration Table 8-14 summarizes these options. Table 8-14 API reference temperature tables Density unit and range derivation Table method Base temperature Degrees API Base density Relative density Method 1 60 °F, non-configurable 0 to +100 Method 1 60 °F, non-configurable 0 to +85 Method 1 60 °F, non-configurable...
Page 86: Configuring The Enhanced Density Application
Optional Configuration For the temperature value to be used in CTL calculation, you can use the temperature data from the sensor, or you can configure external temperature compensation to use either a static temperature value or temperature data from an external temperature device. •...
Page 87 Optional Configuration Table 8-16 Standard curves and associated measurement units continued Name Description Density unit Temperature unit HFCS 42 Curve represents a hydrometer scale for HFCS 42 g/cm °C (high fructose corn syrup) solutions that indicates the percent by mass of HFCS in solution. HFCS 55 Curve represents a hydrometer scale for HFCS 55 g/cm...
Page 88: Configuration Procedure
Optional Configuration Table 8-17 Derived variables and available process variables continued Available process variables Density at Standard Specific Concentration Net Derived variable – ProLink II label reference volume gravity mass volume and definition temperature flow rate flow rate flow rate ✓...
Page 89 Optional Configuration Figure 8-3 Configuring the enhanced density application – DeviceNet tool Class: Enhanced Density Object (0x64) Instance: 1 Attribute ID: 39 Data type: BOOL Enable the enhanced density application Value: · 0: Disabled · 1: Enabled Service: Set Set transmitter density measurement unit to Class: Analog Input Point Object (0x0A) match curve unit Instance: 3...
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Page 91: Chapter 9 Pressure Compensation And Temperature Compensation
Chapter 9 Pressure Compensation and Temperature Compensation Overview This chapter describes the following procedures: • Configuring pressure compensation – see Section 9.2 • Configuring external temperature compensation – see Section 9.3 • Obtaining external pressure or temperature data – see Section 9.4 Note: All ProLink II procedures provided in this chapter assume that you have established communication between ProLink II and the Model 2400S DN transmitter and that you are complying with all applicable safety requirements.
Page 92: Pressure Correction Factors
Pressure Compensation and Temperature Compensation 9.2.2 Pressure correction factors When configuring pressure compensation, you must provide the flow calibration pressure – the pressure at which the flowmeter was calibrated (which therefore defines the pressure at which there will be no effect on the calibration factor). Enter unless the calibration document for your 20 PSI sensor indicates a different calibration pressure.
Page 93: External Temperature Compensation
Pressure Compensation and Temperature Compensation Figure 9-2 Configuring pressure compensation with a DeviceNet tool Class: Calibration Object (0x65) Instance: 1 Set pressure unit Attribute ID: 29 Value: See Table 6-7 Service: Set (1) Pressure measurement unit must be configured to match pressure unit used by external device.
Page 94 Pressure Compensation and Temperature Compensation There are two ways to configure external temperature compensation: • If the operating temperature is a known static value, you can configure that value in the transmitter. • If the operating temperature varies significantly, you must write a temperature value to the transmitter at appropriate intervals, using an appropriate output assembly.
Page 95: Obtaining External Pressure And Temperature Data
Pressure Compensation and Temperature Compensation Figure 9-4 Configuring external temperature compensation with a DeviceNet tool Class: Analog Input Point Object (0x0A) (1) Temperature measurement unit Instance: 4 must be configured to match Set temperature unit Attribute ID: 102 temperature unit used by Value: See Table 6-6 Service: Set external device.
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Page 97: Chapter 10 Measurement Performance
Chapter 10 Measurement Performance 10.1 Overview This chapter describes the following procedures: • Meter verification – see Section 10.3 • Meter validation and adjusting meter factors – see Section 10.4 • Zero calibration – see Section 10.5 • Density calibration – see Section 10.6 •...
Page 98: Meter Verification
Measurement Performance 10.2.1 Meter verification Meter verification evaluates the structural integrity of the sensor tubes by comparing current tube stiffness to the stiffness measured at the factory. Stiffness is defined as the load per unit deflection, or force divided by displacement. Because a change in structural integrity changes the sensor’s response to mass and density, this value can be used as an indicator of measurement performance.
Page 99: Comparison And Recommendations
Measurement Performance 10.2.4 Comparison and recommendations When choosing among meter verification, meter validation, and calibration, consider the following factors: • Process interruption Meter verification requires approximately four minutes to perform. During these four minutes, flow can continue (provided sufficient stability is maintained); however, current process data will not be reported.
Page 100 Measurement Performance During meter verification, you can choose between setting digital communications process variable values to the configured fault indicator or the last measured value. The values will remain fixed for the duration of the test (approximately four minutes). Disable all control loops for the duration of the procedure, and ensure that any data reported during this period is handled appropriately.
Page 101 Measurement Performance Figure 10-2 Meter verification procedure – Display menu Scroll and Select simultaneously for 4 seconds Scroll OFF-LINE MAINT Select Scroll SENSOR VERFY Select OUTPUTS Select Scroll Choose output setting SENSOR EXIT STOP MSMT/YES? (1) Either Unstable Flow or Unstable Drive Gain may be displayed, indicating that the standard deviation of the flow or drive gain is outside limits.
Page 102 Measurement Performance Figure 10-3 Meter verification procedure – DeviceNet tool See Table 10-1 for the device profile Step 1 Set output state (optional) information for each step. Step 2 Set uncertainty limit (optional) Step 3 Manual abort (optional) Start/abort procedure Step 4 Check current algorithm state Step 5...
Page 103 Measurement Performance Table 10-1 DeviceNet interface for meter verification Step number Step description Interface Set output state Class: Diagnostics Object (0x66) Instance: 1 Attribute ID: 58 Data type: USINT Value: • 0: Last measured value (default) • 1: Fault Service: Set Set uncertainty limit Class: Diagnostics Object (0x66) Instance: 1...
Page 104: Uncertainty Limit And Test Results
Measurement Performance 10.3.1 Uncertainty limit and test results The result of the meter verification test will be a percent uncertainty of normalized tube stiffness. The default limit for this uncertainty is ±4.0%. This limit is stored in the transmitter, and can be changed with ProLink II or a DeviceNet tool when optional test parameters are entered.
Page 105: Additional Prolink Ii Tools For Meter Verification
Measurement Performance 10.3.2 Additional ProLink II tools for meter verification In addition to the Pass, Fail/Caution, and Abort result provided by the procedure, ProLink II provides the following additional meter verification tools: • Test metadata – ProLink II allows you to enter a large amount of metadata about each test so that past tests can be audited easily.
Page 106 Measurement Performance Therefore, to adjust volume flow, you must set the meter factor for volume flow. Setting a meter factor for mass flow and a meter factor for density will not produce the desired result. The volume flow calculations are based on original mass flow and density values, before the corresponding meter factors have been applied.
Page 107: Performing Zero Calibration
Measurement Performance Example The flowmeter is installed and proved for the first time. The flowmeter mass measurement is 250.27 lb; the reference device measurement is 250 lb. A mass flow meter factor is determined as follows: × ----------------- - MassFlowMeterFactor 0.9989 250.27 The first mass flow meter factor is 0.9989.
Page 108: Preparing For Zero
Measurement Performance 10.5.1 Preparing for zero To prepare for the zero procedure: 1. Apply power to the flowmeter. Allow the flowmeter to warm up for approximately 20 minutes. 2. Run the process fluid through the sensor until the sensor temperature reaches the normal process operating temperature.
Page 109 Measurement Performance Figure 10-4 Zero button – Flowmeter zero procedure Press ZERO button Status LED flashes yellow Status LED Solid Green or Solid Solid Yellow Troubleshoot Done Figure 10-5 Display menu – Flowmeter zero procedure Scroll and Select simultaneously for 4 seconds Scroll OFF-LINE MAINT Select...
Page 110 Measurement Performance Figure 10-6 ProLink II – Flowmeter zero procedure ProLink > Calibration > Zero Calibration Modify zero time if required Perform Auto Zero Calibration in Progress LED turns red Wait until Calibration in Progress LED turns green Calibration Green Failure LED Done Troubleshoot...
Page 111: Performing Density Calibration
Measurement Performance Figure 10-7 DeviceNet tool – Flowmeter zero procedure Class: Calibration Object (0x65) Instance: 1 Modify zero time if Attribute ID: 3 required Data type: UINT Units: seconds Service: Set Class: Calibration Object (0x65) Instance: 1 Service: 0x4B (perform or abort zero) Perform zero Value: ·...
Page 112: Preparing For Density Calibration
Measurement Performance The calibrations that you choose must be performed without interruption, in the order listed here. 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.
Page 113 Measurement Performance Figure 10-8 D1 and D2 density calibration – ProLink II D1 calibration D2 calibration Close shutoff valve Fill sensor with D1 fluid Fill sensor with D2 fluid downstream from sensor ProLink Menu > ProLink Menu > Calibration > Calibration >...
Page 114 Measurement Performance Figure 10-9 D1 and D2 density calibration – DeviceNet tool Close shutoff valve downstream from sensor D1 calibration D2 calibration Fill sensor with Fill sensor with D1 fluid D2 fluid Object: Calibration object (0x65) Object: Calibration object (0x65) Instance: 1 Instance: 1 Enter density of...
Page 115 Measurement Performance Figure 10-10 D3 or D3 and D4 density calibration – ProLink II D3 calibration D4 calibration Close shutoff valve Fill sensor with D3 fluid Fill sensor with D4 fluid downstream from sensor ProLink Menu > ProLink Menu > Calibration >...
Page 116 Measurement Performance Figure 10-11 D3 or D3 and D4 density calibration – DeviceNet tool Close shutoff valve downstream from sensor D3 calibration D4 calibration Fill sensor with Fill sensor with D3 fluid D4 fluid Object: Calibration Object (0x65) Object: Calibration Object (0x65) Instance: 1 Instance: 1 Enter density of...
Page 117: Performing Temperature Calibration
Measurement Performance 10.7 Performing temperature calibration Temperature calibration is a two-part procedure: temperature offset calibration and temperature slope calibration. The entire procedure must be completed without interruption. To perform temperature calibration, you must use ProLink II. See Figure 10-12. Figure 10-12 Temperature calibration –...
Page 118 ® ™ Micro Motion Model 2400S Transmitters for DeviceNet...
Page 119: Chapter 11 Troubleshooting
Chapter 11 Troubleshooting 11.1 Overview This chapter describes guidelines and procedures for troubleshooting the flowmeter. The information in this chapter will enable you to: • Categorize the problem • Determine whether you are able to correct the problem • Take corrective measures (if possible) •...
Page 120: Micro Motion Customer Service
Troubleshooting Table 11-1 Troubleshooting topics and locations continued Section Topic Section 11.7.2 Checking grounding Section 11.8 Zero or calibration failure Section 11.9 Fault conditions Section 11.10 Simulation mode for process variables Section 11.11 Transmitter LEDs Section 11.12 Status alarms Section 11.13 Checking process variables Section 11.14 Checking slug flow...
Page 121: Checking The Communication Device
Troubleshooting If the transmitter is communicating via the service port but not via DeviceNet, if you are experiencing intermittent DeviceNet communications, or if the transmitter appears to be operating normally but you cannot establish a DeviceNet connection: 1. Verify the DeviceNet node address and baud rate for the transmitter. If necessary, change their values using the digital communications hardware switches on the user interface (see Sections 8.10.1 and 8.10.2), and retry the connection using the new digital communications parameters.
Page 122: Checking Grounding
Troubleshooting 3. Visually inspect the cable and connector. Ensure that contact is good at both ends, that the pins are not bent, the cable is not crimped, and the cable covering is intact. 4. Retry the connection using a different cable. Figure 11-1 DeviceNet connector 11.7.2...
Page 123: 11.11 Transmitter Leds
Troubleshooting If simulation mode is active, the simulated values are stored in the same memory locations used for process data from the sensor. Therefore, the simulated values will be used throughout transmitter functioning. For example, simulation will affect: • All mass flow, temperature, or density values shown on the display or reported via digital communications •...
Page 124: 11.12 Status Alarms
Troubleshooting 11.12 Status alarms Status alarm codes are reported on the LCD panel (for transmitters that have a display), and status alarms can be viewed with ProLink II or a DeviceNet tool (see Section 7.6). All possible status alarms are listed in Table 11-2, along with the ProLink II message, possible causes, and suggested remedies. You may find it useful to acknowledge all alarms before beginning the troubleshooting procedures.
Page 125 Troubleshooting Table 11-2 Status alarms and remedies continued Alarm ProLink II code message Cause Suggested remedy A009 Transmitter Transmitter in power-up • Allow the flowmeter to warm up (approximately 30 Initializing/Warming mode seconds). The error should disappear once the flowmeter is ready for normal operation.
Page 126 Troubleshooting Table 11-2 Status alarms and remedies continued Alarm ProLink II code message Cause Suggested remedy A030 Incorrect Board The loaded software is not • Contact Micro Motion. See Section 11.3. Type compatible with the programmed board type A031 Low Power The transmitter is not •...
Page 127: 11.13 Checking Process Variables
Troubleshooting 11.13 Checking process variables Micro Motion suggests that you make a record of the process variables listed below, under normal operating conditions. This will help you recognize when the process variables are unusually high or low. • Flow rate •...
Page 128 Troubleshooting Table 11-3 Process variables problems and remedies continued Symptom Cause Suggested remedy Erratic non-zero flow rate under Leaking valve or seal • Check pipeline. no-flow conditions Slug flow • See Section 11.14. Plugged flow tube • Check drive gain and tube frequency. Purge the flow tubes.
Page 129: 11.14 Checking Slug Flow
Troubleshooting Table 11-3 Process variables problems and remedies continued Symptom Cause Suggested remedy Inaccurate density reading Problem with process fluid • Use standard procedures to check quality of process fluid. Bad density calibration factors • Verify characterization. See Section 6.2. Wiring problem •...
Page 130: 11.15 Checking The Sensor Tubes
Troubleshooting If slug flow occurs: • Check the process for cavitation, flashing, or leaks. • Change the sensor orientation. • Monitor density. • If desired, enter new slug flow limits (see Section 8.7). Raising the low slug flow limit or lowering the high slug flow limit will increase the possibility of slug flow conditions.
Page 131: Obtaining The Test Point Values
Troubleshooting 11.19.1 Obtaining the test point values To obtain the test point values: • With the display, configure the required test points as display variables. See Section 8.9.5. • With ProLink II a. Click ProLink > Diagnostic Information b. Observe or record the values displayed for Tube Frequency Left Pickoff Right Pickoff...
Page 132: Drive Gain Problems
Troubleshooting 11.19.3 Drive gain problems Problems with drive gain can appear in several different forms: • Saturated or excessive (near 100%) drive gain • Erratic drive gain (e.g., rapid shifting from positive to negative) • Negative drive gain See Table 11-6 for a list of possible problems and remedies. Table 11-6 Drive gain problems, causes, and remedies Cause...
Page 133: 11.20 Checking Sensor Circuitry
Troubleshooting 11.20 Checking sensor circuitry Problems with sensor circuitry can cause several alarms, including sensor failure and a variety of out-of-range conditions. Testing involves: • Inspecting the cable that connects the transmitter to the sensor • Measuring the resistances of the sensor's pin pairs and RTDs •...
Page 134 Troubleshooting Figure 11-2 Exploded view of transmitter and connection to sensor Transmitter housing cover User interface module Transmitter Sensor cable for feedthrough connection Snap clip Transmitter housing Clamp Feedthrough pins (inside housing) Feedthrough (mounted on sensor) 5. If the problem is not resolved, unplug the cable from the feedthrough by removing the snap clip (see Figure 11-2), then pulling the connector away from the feedthrough.
Page 135 Troubleshooting Figure 11-3 Accessing the feedthrough pins Transmitter (side view) Sensor cable for feedthrough connection Feedthrough connector Snap clip (assembled) Feedthrough pins Pull tab to remove 6. Using a digital multimeter (DMM), check the sensor internal resistances for each flowmeter circuit.
Page 136 Troubleshooting Table 11-8 Nominal resistance ranges for flowmeter circuits continued Circuit Pin pairs Nominal resistance range 100 Ω at 0 °C + 0.38675 Ω / °C Flow tube temperature sensor RTD + and RTD – LLC/RTD 300 Ω at 0 °C + 1.16025 Ω / °C •...
Page 137 Troubleshooting With the DMM set to its highest range, there should be infinite resistance on each lead. If there is any resistance at all, there is a short to case or a short between pins. See Table 11-9 for possible causes and solutions. If the problem is not resolved, contact Micro Motion (see Section 11.3).
Page 138 ® ™ Micro Motion Model 2400S Transmitters for DeviceNet...
Page 139: Appendix A Default Values And Ranges
Appendix A Default Values and Ranges Overview This appendix provides information on the default values for most transmitter parameters. Where appropriate, valid ranges are also defined. These default values represent the transmitter configuration after a master reset. Depending on how the transmitter was ordered, certain values may have been configured at the factory.
Page 140 Default Values and Ranges Table A-1 Transmitter default values and ranges continued Type Setting Default Range Comments Density Density damping 1.28 sec 0.0–40.96 sec User-entered value is corrected to nearest value in list of preset values. Density units g/cm Density cutoff 0.2 g/cm 0.0–0.5 g/cm 0.00000...
Page 141 Default Values and Ranges Table A-1 Transmitter default values and ranges continued Type Setting Default Range Comments Display Backlight on/off Backlight intensity 0–63 Update period 200 milliseconds 100–10,000 milliseconds Variable 1 Mass flow rate Variable 2 Mass total Variable 3 Volume flow rate Variable 4 Volume total...
Page 142 ® ™ Micro Motion Model 2400S Transmitters for DeviceNet...
Page 143: Appendix B Menu Flowcharts
Appendix B Menu Flowcharts Overview This appendix provides the following menu flowcharts for the Model 2400S DN transmitter: • ProLink II menus Main menu – see Figure B-1 Configuration menu – see Figures B-2 and B-3 • Display menus Off-line menu: Top level – see Figure B-4 Off-line maintenance: Version information –...
Page 144 Menu Flowcharts Figure B-1 ProLink II main menu File View Connection ProLink Tools Plug-ins Load from Xmtr to File Connect to Device Meter Verification Save to Xmtr from File Disconnect Options License · ProLink II Language · Error Log On Preferences Configuration Data Logging...
Page 145 Menu Flowcharts Figure B-2 ProLink II configuration menu ProLink > Configuration Flow Density Temperature Pressure · Flow direction · Density units · Temp units · Flow factor · Flow damp · Density damping · Temp cal factor · Dens factor ·...
Page 146 Menu Flowcharts Figure B-3 ProLink II configuration menu continued ProLink > Configuration Display Transmitter options Alarm Sensor simulation · Var1 · Meter fingerprinting · Alarm Enable simulation mode · Var2 · Cryogenic modulus · Severity · … compensation Mass flow ·...
Page 147 Menu Flowcharts Figure B-4 Display menu – Off-line menu, top level Scroll and Select simultaneously for 4 seconds SEE ALARM OFF-LINE MAINT EXIT Scroll Scroll Select CONFG ZERO SENSOR VERFY EXIT Scroll Scroll Scroll Scroll (1) This option is displayed only if the meter verification software is installed on the transmitter. Figure B-5 Display menu –...
Page 148 Menu Flowcharts Figure B-6 Display menu – Off-line maintenance – Configuration Scroll and Select simultaneously for 4 seconds Scroll OFF-LINE MAINT Select Scroll CONFG Select UNITS MTR F DSPLY IRDA EXIT Scroll Scroll Scroll Scroll Scroll Select Select Select Select Select MASS START ZERO...
Page 149 Menu Flowcharts Figure B-7 Display menu – Off-line maintenance – Zero Scroll and Select simultaneously for 4 seconds Scroll OFF-LINE MAINT Select Scroll ZERO Select CAL ZERO RESTORE ZERO EXIT Scroll Scroll Select Select ZERO/YES? Current zero display Scroll Select Scroll ………………….
Page 150 Menu Flowcharts Figure B-8 Display menu – Off-line maintenance – Meter verification Scroll and Select simultaneously for 4 seconds Scroll OFF-LINE MAINT Select Scroll SENSOR VERFY OFF-LINE EXIT Scroll Select OUTPUTS (1) Either Unstable Flow or Unstable Drive Gain may be Select Scroll displayed, indicating that the standard deviation of the...
Page 151: Appendix C Device Profile
Appendix C Device Profile Overview This appendix documents the most commonly used portions of the Model 2400S DN transmitter’s device profile, including class/instance/attribute information and required codes. The following object classes and instances are documented: • Analog Input Point Object (0x0A), Instance 1 (mass flow) – see Table C-1 •...
Page 152: Analog Input Point Object (0X0A)
Device Profile Analog Input Point Object (0x0A) Table C-1 Analog Input Point Object (0x0A) – Instance 1 (mass flow) Attrib Name Data type Service Description Comments Value REAL Current value of mass Based on Attribute 8 flow process variable Status BOOL Point status •...
Page 153 Device Profile Table C-2 Analog Input Point Object (0x0A) – Instance 2 (liquid volume flow) Attrib Name Data type Service Description Comments Value REAL Current value of liquid Based on Attribute 8 volume flow process variable Status BOOL Point status •...
Page 154: Gas Standard Volume Object (0X64)
Device Profile Table C-3 Analog Input Point Object (0x0A) – Instance 3 (density) continued Attrib Name Data type Service Description Comments Damping REAL Density damping value Unit = seconds Cutoff REAL Value below which density will be reported as 0 Meter factor REAL A multiplier to the...
Page 155: Calibration Object (0X65)
Device Profile Table C-5 Gas Standard Volume Object (0x64) – Instance 1 continued Attrib Name Data type Service Description Comments Enable gas BOOL Enable or disable gas • 0 = Disabled standard volume standard volume • 1 = Enabled measurement Gas standard REAL Value below which gas...
Page 156 Device Profile Table C-6 Calibration Object (0x65) – Instance 1 continued Attrib Name Data type Service Description Comments REAL The line-condition density Unit = g/cm of D2 calibration service REAL The line-condition density Unit = g/cm of FD calibration service REAL The line-condition density Unit = g/cm...
Page 157: Diagnostics Object (0X66)
Device Profile Diagnostics Object (0x66) Table C-7 Diagnostics Object (0x66) – Instance 1 Attrib Name Data type Service Description Comments Fault behavior USINT Specifies the behavior of • 0 = Upscale the process variables • 1 = Downscale when the device is in a •...
Page 158 Device Profile Table C-7 Diagnostics Object (0x66) – Instance 1 continued Attrib Name Data type Service Description Comments Alarm status 1 UINT A collection of status bits • 0x0001 = NV error (CP) • 0x0002 = RAM error (CP) • 0x0004 = RTI failure •...
Page 159 Device Profile Table C-7 Diagnostics Object (0x66) – Instance 1 continued Attrib Name Data type Service Description Comments Alarm status 3 UINT A collection of status bits • 0x0001 = Not used • 0x0002 = Power reset • 0x0004 = Transmitter initializing •...
Page 160 Device Profile Table C-7 Diagnostics Object (0x66) – Instance 1 continued Attrib Name Data type Service Description Comments Alarm status 4 UINT A collection of status bits • 0x0001 = API: Temperature out of range • 0x0002 = API: Density out of range •...
Page 161 Device Profile Table C-7 Diagnostics Object (0x66) – Instance 1 continued Attrib Name Data type Service Description Comments Alarm status 6 UINT A collection of status bits • 0x0001 = Not used • 0x0002 = Not used • 0x0004 = Not used •...
Page 162 Device Profile Table C-7 Diagnostics Object (0x66) – Instance 1 continued Attrib Name Data type Service Description Comments 9-wire cable REAL The resistance of the Unit = ohms RTD resistance 9-wire cable Meter RTD REAL The resistance of the Unit = ohms resistance meter RTD Number of...
Page 163 Device Profile Table C-7 Diagnostics Object (0x66) – Instance 1 continued Attrib Name Data type Service Description Comments Alarm 8 UINT A collection of status bits • 0x0001 = Not used • 0x0002 = Not used • 0x0004 = Not used •...
Page 164 Device Profile Table C-7 Diagnostics Object (0x66) – Instance 1 continued Attrib Name Data type Service Description Comments Meter USINT The reason the meter • 0 = No error verification abort verification routine • 1 = Manual abort code aborted •...
Page 165 Device Profile Table C-7 Diagnostics Object (0x66) – Instance 1 continued Attrib Name Data type Service Description Comments Meter REAL The current inlet stiffness verification – calculated as a mean current inlet stiffness, mean Meter REAL The current outlet verification – stiffness calculated as a current outlet mean...
Page 166 Device Profile Table C-7 Diagnostics Object (0x66) – Instance 1 continued Attrib Name Data type Service Description Comments Meter REAL The inlet mass calculated verification – as a mean during factory current inlet calibration of air mass, factory cal of air, mean Meter REAL The outlet mass...
Page 167: Sensor Information Object (0X67)
Device Profile Table C-7 Diagnostics Object (0x66) – Instance 1 continued Attrib Name Data type Service Description Comments Factory flow REAL The flow signal offset at Unit = microseconds signal offset at zero flow when calibrated zero flow at the factory Discrete event USINT The action that will be...
Page 168: Local Display Object (0X68)
Device Profile Table C-8 Sensor Information Object (0x67) – Instance 1 continued Attrib Name Data type Service Description Comments Sensor material USINT The material of the • 0 = None sensor’s case • 3 = Hastelloy C-22 • 4 = Monel •...
Page 169 Device Profile Table C-9 Local Display Object (0x68) – Instance 1 continued Attrib Name Data type Service Description Comments Display USINT Displays the variable See Table C-15 for variable 2 associated with the code codes. All codes are on the local display valid.
Page 170: Api Object (0X69)
Device Profile Table C-9 Local Display Object (0x68) – Instance 1 continued Attrib Name Data type Service Description Comments Enable offline BOOL Enable or disable the • 0 = Disabled password password requirement to • 1 = Enabled access the offline menu Offline password UINT The offline password for 0–9999...
Page 171: Enhanced Density Object (0X6A)
Device Profile Table C-10 API Object (0x69) – Instance 1 continued Attrib Name Data type Service Description Comments REAL Current value API reference REAL The reference temperature temperature to use in the API calculations API thermal REAL The thermal expansion expansion coefficient to use in the coefficient...
Page 172 Device Profile Table C-11 Enhanced Density Object (0x6A) – Instance 1 continued Attrib Name Data type Service Description Comments Net mass flow REAL Current value inventory Reset Net volume flow REAL Current value rate Net volume flow REAL Current value total Reset Net volume flow...
Page 173: Totalizer And Inventory Measurement Unit Codes
Device Profile Table C-11 Enhanced Density Object (0x6A) – Instance 1 continued Attrib Name Data type Service Description Comments Reset net mass USINT Resets the net mass • 1 = Reset inventory inventory Reset net USINT Resets the net volume •...
Page 174: Process Variable Codes
Device Profile Table C-14 Gas standard volume totalizer and gas standard volume inventory measurement unit codes Code Description 0x0844 Standard cubic feet 0x0845 Normal cubic meters 0x0846 Standard cubic meters 0x0847 Normal liter 0x0848 Standard liter C.11 Process variable codes Table C-15 Process variable codes Code...
Page 175: Alarm Index Codes
Device Profile Table C-15 Process variable codes continued Code Description Case temperature Left pickoff amplitude Right pickoff amplitude Board temperature Input voltage External pressure External temperature Enhanced density: Density (Baume) Gas standard volume flow rate Gas standard volume total Gas standard volume inventory Live zero None C.12...
Page 176 Device Profile Table C-16 Alarm index codes continued Code Description Sensor/transmitter communications error Security breach Core processor exception Core processor communications error Invalid board type Low power Meter verification fault alarm Tubes not full Drive overrange Data loss possible Calibration in progress Slug flow Power reset API: Temperature out of limits...
Page 177: Appendix D Display Codes And Abbreviations
Appendix D Display Codes and Abbreviations Overview This appendix provides information on the codes and abbreviations used on the transmitter display. Note: Information in this appendix applies only to transmitters that have a display. Codes and abbreviations Table D-1 lists and defines the codes and abbreviations that are used for display variables (see Section 8.9.5 for information on configuring display variables).
Page 178 Display Codes and Abbreviations Table D-1 Display codes used for display variables Code or abbreviation Definition Comment or reference RDENS Density at reference Enhanced density application only temperature RPO A Right pickoff amplitude Specific gravity units STD V Standard volume flow rate Enhanced density application only STD V Standard volume flow rate...
Page 179 Display Codes and Abbreviations Table D-2 Display codes used in off-line menu Code or abbreviation Definition Comment or reference Event x Refers to Event 1 or Event 2 when setting the setpoint. Select ENABL Enable to enable EXTRN External EVNTx Event x FAC Z Factory zero...
Page 180 ® ™ Micro Motion Model 2400S Transmitters for DeviceNet...
Page 181: Index
Index device settings 74 Alarm digital communications parameters 70 See Status alarm display Alarm severity entering floating-point values 14 See Status alarm severity language 67 Analog Input Point Object 144 parameters 67 Instance 1 (mass flow) 144 precision 69 Instance 2 (liquid volume flow) 145 variables 69 Instance 3 (density) 145 enhanced density application 78...
Page 182 Index Connecting to the transmitter device profile 21, 143 service port connection parameters 18 digital communications hardware switches via IrDA port 20 baud rate 71 via service port clips 18 node address 70 with a DeviceNet tool 21 EDS 22 with ProLink II or Pocket ProLink 18 input assemblies 38 Customer service 6, 112...
Page 183 Index password 14 precision 69 Fault action 73 resetting Fault conditions 114 inventories 49 Fault timeout 74 totalizers 49 Flow calibration parameters 26 See also User interface Flow calibration pressure 84 starting and stopping Flow direction parameter 60 inventories 49 Flow factor 84 totalizers 49 status alarms 44...
Page 184 Index Pickoff voltage 124 MAC ID Pocket ProLink See Node address configuration upload and download 17 Mass flow connecting to Model 2400S DN transmitter 18 cutoff 58 requirements 17, 113 measurement unit saving configuration files 17 configuration 30 Pre-configuration worksheet 4 list 30 Pressure Measurement units 28...
Page 185 Index Service port Transmitter housing cover auto-detection 18 removing and replacing 11 connection parameters 18 Troubleshooting Service port clips 18 calibration 114, 122 connecting from ProLink II or characterization 122 Pocket ProLink 18 communication device 113 Simulation mode 114 DeviceNet cable and connector 113 Slug flow 121 drive gain problems 124 Slug flow parameters 64...
Page 186 Index Volume flow, liquid cutoff 58 measurement unit configuration 30 list 30 Wiring problems 113 Zero calibration 99 failure 114 procedure 100 ® ™ Micro Motion Model 2400S Transmitters for DeviceNet...
Page 188 +31 (0) 318 495 555 +65 6777-8211 +31 (0) 318 495 556 +65 6770-8003 Micro Motion United Kingdom Micro Motion Japan Emerson Process Management Limited Emerson Process Management Horsfield Way 1-2-5, Higashi Shinagawa Bredbury Industrial Estate Shinagawa-ku Stockport SK6 2SU U.K.

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Micro motion 2400s dn

Emerson Micro Motion 2400S Configuration And Use Manual

Chapter 1 Before You Begin

Chapter 2 Flowmeter Startup

Chapter 5 Using a Devicenet Tool

Chapter 9 Pressure Compensation and Temperature Compensation

Chapter 10 Measurement Performance

Chapter 11 Troubleshooting

Appendix A Default Values and Ranges

Appendix B Menu Flowcharts

Appendix C Device Profile

Appendix D Display Codes and Abbreviations

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