Page 1 SMV800 Series HART/DE Option User’s Manual 34-SM-25-06 Revision 6.0 July 2019 Honeywell Process Solutions...
Page 2 In no event is Honeywell liable to anyone for any indirect, special, or consequential damages. The information and specifications in this document are subject to change without notice.
Page 3 Experion Knowledge Builder.  Honeywell’s TotalPlant Solutions (TPS): you will need to supplement the information in this document with the data in the PM/APM SmartLine Transmitter Integration Manual, which is supplied with the TDC 3000 book set. (TPS is the evolution of the TDC 3000).
Page 4 Patent Notice The Honeywell SMV800 SmartLine Multivariable Transmitter family is covered by one or more of the following U. S. Patents: 5,485,753; 5,811,690; 6,041,659; 6,055,633; 7,786,878; 8,073,098; and other patents pending. Support and Contact Information For Europe, Asia Pacific, North and South America contact details, see back page or refer to the...
Page 5: Table Of Contents
Contents SMV800 Physical and Functional Characteristics ................. 1 Overview ..........................1 Features and Options ......................1 1.2.1 Physical Characteristics ....................2 1.2.2 Functional Characteristics ....................3 Series, Model Series, Model and Number ................3 Safety Certification Information ..................... 4 Transmitter Adjustments ......................4 Local Display Options ......................
Page 6 Device Configuration ......................23 5.5.3 Transmitter Tag Name and PV1 Priority ..............23 5.5.4 General Configuration ....................23 5.5.5 DPConf Configuration - PV1 ..................25 5.5.6 SP Conf Configuration - PV2 ..................29 5.5.7 TempConf Configuration - PV3 ................31 5.5.8 FlowConf Configuration - PV4 .................
Page 7 Calibrating Range Using a Configuration Tool ..............139 7.5.3 Conditions for Input Calibration................. 139 7.5.4 Input Calibration Procedures Description ..............139 DE Input Calibration Procedure ..................140 7.6.5 DP Input Cal ....................... 140 7.6.6 Correct DP Input at the Lower Range Value (LRV) ..........141 7.6.7 Correct DP Input at URV ...................
Page 8 Comparison of configuration options from DD host vs DTM ..........200 Flow Engineering Units Configuration for SMV800 HART and DE ........201 13.1 SMV800 HART configuration using Pactware: ..............201 13.1.1 For Standard Flow Condition (Temperature: 15 °C, Pressure: 1.01325 barA): ..201 13.1.2 For Normal Flow Condition (Temperature: 0 °C, Pressure: 1.01325 barA): .....
Page 9 List of Figures Figure 1 – SMV800 Major Assemblies ....................2 Figure 2 – Electronics Housing Components ..................2 Figure 3 –Typical Name Plate Information .................... 3 Figure 4 – DE Communication through SCT ..................7 Figure 5 – DE Mode Value Scaling ....................... 8 Figure 6 –...
Page 10 List of Tables Table 1 – Features and Options......................1 Table 2 – Available Display Characteristics ..................5 Table 3 – User Manual Related Topics ....................11 Table 4 - Making SCT 3000 Hardware Connections ................17 Table 5 - Making SCT 3000 On-line Connections ................18 Table 6 - PV Type Selection for SMV Output ..................
Page 11 Table 51 - Communication Status Message Table ................227 Table 52 - Information Message Table....................229 Table 53 - SFC Diagnostic Message Table ................... 230 Table 53 – HART Critical Details ...................... 232 Table 54 - Non-Critical 1 Diagnostic Details ..................239 Table 55 - Non-Critical 2 Diagnostic Details ..................
Page 12 This page has been intentionally left blank SMV800 Series HART/DE Option User’s Manual Page xii Revision 6.0...
Page 13: Smv800 Physical And Functional Characteristics
1 SMV800 Physical and Functional Characteristics Overview This section is an introduction to the physical and functional characteristics of Honeywell’s family of SMV800 SmartLine Multivariable Transmitters. Features and Options The SMV800 SmartLine Multivariable Transmitter type SMV800 HART supports six device...
Page 14: Physical Characteristics
Physical Characteristics As shown in Figure 1, the SMV800 is packaged in two major assemblies: the Electronics Housing and the Meter Body. The elements in the Electronic Housing respond to setup commands and execute the software and protocol for the different pressure measurement types: DP (Differential Pressure), SP (Static Pressure), PT (Process Temperature) and MBT (Meter body Temperature).
Page 15: Functional Characteristics
An optional 3-button assembly is available to set up and configure the transmitter via the Display. In addition, a Honeywell MCT404/MCT202 Toolkit is available for configuration of HART models. The SCT SmartLine Configuration Tool (not supplied with the Transmitter) can facilitate setup and configuration for DE devices.
Page 16: Safety Certification Information
* This feature is only available in HART R120 device. You can also use the Honeywell MCT404 Configuration Tool – FDC application to make any adjustments to an SMV800 Transmitter with HART. For DE models the SCT3000 PC tool application can be used to configure the device.
Page 17: Local Display Options
Local Display Options The SMV800 Multivariable Transmitter has an Advanced display; see Table 2. Table 2 – Available Display Characteristics  Screen Format Large process variable (PV) PV with bar graph PV with trend (1-24 hours, configurable)  PV Selection ...
Page 18: Universal Temperature Sensor Option Licensing
Universal Temperature Sensor Option Licensing In a standard device, only RTD Temperature sensor types may be used for measuring Process Temperature. The Universal Temperature Sensor option can be enabled after the transmitter is shipped by purchasing and activating a license, to expand the selection of temperature sensor types to include thermocouples.
Page 19: Communication Modes
2 Communication Modes Overview The SMV800 SmartLine Multivariable Transmitter is available with either Honeywell's Digitally Enhanced (DE) or HART revision 7 communications protocols. This manual addresses the processes to configure and calibrate a Transmitter for DE and HART communication. DE Mode Communication...
Page 20: Figure 5 - De Mode Value Scaling
Figure 5, output values of process variables, as well as communications are transferred to a receiving device digitally. The digital coding is Honeywell proprietary, which requires the use of DE-capable Honeywell control equipment. The use of DE mode offers several advantages: ...
Page 21: Hart Mode Communication
Transmitters with HART 7 capability have features that vary among manufacturers and with the characteristics of specific devices. The FDC software application executing on the MCT404/MCT202 supports the HART Universal, Common Practice and Device Specific Commands which are implemented in the Honeywell Transmitters. As indicated in Figure 6, the output of a Transmitter configured for HART protocol includes two primary modes: Figure 6 –...
Page 22 SMV800 Series HART/DE Option User’s Manual Page 10 Revision 6.0...
Page 23: Configuration Tools And Interfaces
Honeywell MC Toolkit or MCT202/MCT404 and the PC tool SCT3000 application. Furthermore, we assume that the reader is intimately familiar with the SMV800 family of SmartLine Multivariable Transmitters and thoroughly experienced in the type of process application targeted for Transmitter deployment.
Page 24: Toolkit Participation
 SCT3000 tool. This application is used for configuring, calibrating, monitoring, and diagnosing Honeywell Digitally Enhanced (DE) devices. For more information see section 3.5 SmartLine Configuration Toolkit (SCT 3000) Details for working with the MC Toolkit are provided in the MC Toolkit User Manual, document #34-ST-25-50 (MCT404).
Page 25: Mc Toolkit-Transmitter Electrical/Signal Connections
MC Toolkit–Transmitter Electrical/Signal Connections Figure 7 displays how to connect the MC Toolkit directly to the terminals of a HART-only Transmitter. Figure 7 – MC Toolkit-Transmitter Electrical/Signal Connections SMV800 Series HART/DE Option User’s Manual Revision 6.0 Page 13...
Page 26: Smartline Configuration Toolkit (Sct 3000)
SmartLine Configuration Toolkit (SCT 3000) SmartLine Configuration Toolkit for use with DE models Honeywell’s SCT 3000 SmartLine Configuration Toolkit is a cost-effective means to configure, calibrate, diagnose, and monitor the SMV800 and other smart field devices. The SCT 3000 runs on a ®...
Page 27: Considerations For Sct 3000
Considerations for SCT 3000 SCT 3000 Requirements The SCT 3000 consists of the PC application and the Honeywell DE Modem hardware interface used for connecting the host computer to the SMV transmitter. Be certain that the host computer is loaded with the proper operating system necessary to run the SCT program.
Page 28: Setting Up Communications With The Sct3000
SCT Hardware Connections A PC or laptop computer (host computer) which contains the SCT application is connected to the wiring terminals of the SMV transmitter and other smart field devices via the Honeywell DE Modem. Figure 9 shows the hardware components of the SCT.
Page 29: Sct 3000 On-Line Connections To The Smv
ATTENTION Connecting the host computer to an SMV for on-line communications requires SmartLine Option Module consisting of a DE Modem connection. SCT 3000 On-line Connections to the SMV Table 4 provides the steps to connect the assembled SCT 3000 hardware between the host computer and the SMV for on-line communications.
Page 30: Establishing On-Line Communications With The Smv
Establishing On-line Communications with the SMV Table 5 lists the steps to begin an on-line session with the loop-connected SMV and upload the database configuration from the transmitter. Table 5 - Making SCT 3000 On-line Connections Step Action Make sure that 24V dc power is applied to the proper SMV transmitter SIGNAL terminals.
Page 31: Checking Communication Mode And Firmware Version
A transmitter in the digital (DE) mode can communicate in a direct digital Mode fashion with a Universal Station in Honeywell’s TPS and TDC 3000 control systems. The digital signal can include all four transmitter process variables and its secondary variable as well as the configuration database.
Page 32: 5 De Transmitter Configuration
5 DE Transmitter Configuration Configuration Personnel Requirements The configuration processes in this section reflect the assumption that you will use the Honeywell SCT3000 Configuration Tool to configure an SMV800 SmartLine DE Transmitter. The other tools that support DE Transmitter configuration are Honeywell’s Experion or TPS/ TDC 3000.
Page 33: Configuration Summary
The SMV templates contain the configuration forms (or tab cards) necessary to create the database for an SMV transmitter. When using a Honeywell-defined SMV template, you should choose a file template for the temperature range and model of SMV that you wish to configure.
Page 34: Using The Sct For Smv800 Configuration
Using the SCT for SMV800 Configuration The SCT template files have tab cards that contain data fields for the SMV parameters which you fill in. You start with the Device tab card to enter the device tag name (Tag ID) and other general descriptions.
Page 35: Device Configuration
Device Configuration Transmitter Tag Name and PV1 Priority Tag ID field is found on the Device tab card. Tag ID - Enter an appropriate tag name for the transmitter containing up to eight ASCII characters which uniquely identifies the transmitter. NOTE: It is suggested that when you create a database configuration file for the transmitter, you make the file name the same as the transmitter tag ID.
Page 36: Table 7 - Smv Analog Output Selection
Process Manager. You cannot integrate the SMV800 with a control system using an STDC card or an STI IOP module for the Smart Transmitter interface. Contact your Honeywell representative for information about possibly upgrading an existing STI IOP to an STIMV IOP.
Page 37: Dpconf Configuration - Pv1
Line Filter (DE only) When using the process temperature (PV3) input, select the input filter frequency that matches the power line frequency for the power supply.  50 Hz  60 Hz Factory setting. The line filter helps to eliminate noise on the process temperature signal input to the transmitter. Make a selection to indicate whether the transmitter will work with a 50 Hz or 60 Hz line frequency.
Page 38 LRV and URV The Lower Range Value and the Upper Range Value fields for PV1 are found on the DPConf tab card. PV1 (DP) Range Values Configure the LRV (which is the process input for 4 mA dc* (0%) output) and URV (which is the process input for 20 mA dc* (100%) output) for the differential pressure input PV1 by typing in the desired values on the SCT configuration.
Page 39 You can use these formulas to manually calculate the percent of flow for comparison purposes. • 100 = %P Where, ÄP = Differential pressure input in engineering units Span = Transmitter’s measurement span (URV – LRV) %P = Pressure input in percent of span •...
Page 40: Figure 11 - Square Root Dropout Points For Pv 1
Figure 11 - Square Root Dropout Points for PV 1 Damping Adjust the damping time constant for Differential Pressure (PV1) to reduce the output noise. We suggest that you set the damping to the smallest value that is reasonable for the process. The damping values (in seconds) for PV1 are: 0.00 , 0.16, 0.32, 0.48,...
Page 41: Sp Conf Configuration - Pv2
SP Conf Configuration - PV2 Engineering Units The SP Conf tab card displays the Lower Range Value (LRV), Lower Range Limit (LRL), Upper Range Value (URV) and Upper Range Limit (URL) for PV2 in the unit of measure selected in the Engineering Units field.
Page 42 PV2 (AP/GP or SP) Range Values (LRV and URV) The Lower Range Value and the Upper Range Value fields for PV2 are found on the AP/GPConf tab card. Set the LRV (which is the process input for 0% output) and URV (which is the process input for 100% output) for the static pressure input PV2 by typing in the desired values on the SCT tab card.
Page 43: Tempconf Configuration - Pv3
TempConf Configuration - PV3 Engineering Units The TempConf tab card displays the Lower Range Value (LRV), Lower Range Limit (LRL), Upper Range Value (URV) and Upper Range Limit (URL) for PV3 in the unit of measure selected in the Engineering Units field. Selecting PV3 Engineering Units Select one of the preprogrammed engineering units in Table 10...
Page 44: Table 11 - Sensor Types For Pv3 Process Temperature Input
Background Every thermocouple requires a hot junction and a cold junction for operation. The hot junction is located at the point of process measurement and the cold junction is located in the transmitter (internal) or at an external location selected by the user. The transmitter bases its range measurement on the difference of the two junctions.
Page 45 T/C Fault Detect WARNING To accurately set the device status and Analog Output, it is highly recommended to enable T/C or RTD fault detection. The behavior of the device and process values is explained below when this setting is OFF vs ON to explain why it is recommended to configure this setting ON always.
Page 46: Figure 12 - Rtd Range Configuration
PV3 (Temperature) Range Values (LRV and URV) The Lower Range Value and the Upper Range Value fields for PV3 are found on the TempConf tab card. Configure the LRV and URV (which are desired zero and span points for your measurement range) for the process temperature input PV3 by typing in the desired values on the TempConf tab card.
Page 47: Figure 13 - Current Range Settings
Figure 13 - Current Range Settings Damping Adjust the damping time constant for Process Temperature (PV3) to reduce the output noise. We suggest that you set the damping to the smallest value that is reasonable for the process. The damping values (in seconds) for PV3 are: 0.00 , 0.3, 0.7, 1.5, 3.1, 6.3, 12.7, 25.5, 51.1, 102.3...
Page 48: Flowconf Configuration - Pv4
FlowConf Configuration - PV4 Engineering Units The FlowConf tab card displays the Lower Range Value (LRV), Lower Range Limit (LRL), Upper Range Value (URV) and Upper Range Limit (URL) for PV4 in the unit of measure selected in the Engineering Units field. PV4 Engineering Units Select one of the preprogrammed engineering units for display of the PV4 measurements, depending upon type of flow measurement configuration.
Page 49: Table 13 - Pre-Programmed Mass Flow Engineering Units For Pv4
Table 13 - Pre-programmed Mass Flow Engineering Units for PV4 Engineering Unit Meaning Kg/sec Kilograms per Second Kg/min Kilograms per minute Kg/h Kilograms per Hour lb/min Pounds per Minute lb/h Pounds per Hour lb/sec Pounds per Second Tonnes per Hour (Metric Tons) t/min Tonnes per Minute (Metric Tons) t/sec...
Page 50: Figure 14 - Typical Volumetric Flow Range Setting Values
About LRV and URV The LRV and URV set the desired zero and span points for your calculated measurement range as shown in the example in Figure 14. Figure 14 - Typical Volumetric Flow Range Setting Values ATTENTION • The default engineering units for volumetric flow rate is cubic meters per hour and tonnes per hour is the default engineering units for mass flow rate.
Page 51: Figure 15 - Low Flow Cutoff
Figure 15 gives a graphic representation of the low flow cutoff action for sample low and high limits in engineering units of liters per minute. ATTENTION If the flow LRV is not zero, the low flow cutoff output value will be calculated on the LRV and will not be 0 %.
Page 52: Using Custom Engineering Units
Using Custom Engineering Units Using Custom Units for PV4 Flow Measurement The SCT contains a selection of preprogrammed engineering units that you can choose to represent your PV4 flow measurement. If you want the PV4 measurement to represent an engineering unit that is not one of the preprogrammed units stored in the SCT, you must select custom units and enter a tag that identifies the desired custom unit.
Page 53: Flow Compensation Wizard (De Only)
Flow Compensation Wizard (DE only) A Flow Compensation Wizard is provided with the SCT 3000 which is used to configure PV4, the flow variable of the SMV800 Multivariable Transmitter. The flow compensation wizard will guide you in configuring the PV4 output for either a standard flow equation or a dynamic compensation flow equation.
Page 54 Dynamic Compensation Equation The dynamic compensation flow equation for mass applications is: Which provides compensation dynamically for discharge coefficient, gas expansion factor, thermal expansion factor, density, and viscosity. For details on configuring Flow algorithm refer to the SCT 3000 online User manual, #34-ST-10-08 SMV800 Series HART/DE Option User’s Manual Page 42 Revision 6.0...
Page 55: Using The Sct3000 Tool To Configure Local Display Screens On Smv800
Using the SCT3000 Tool to Configure Local Display Screens on SMV800 Display Screen Configuration Instructions 1. From Local Display tab, select a screen number and select OK button to read the current configuration for the selected Screen X. After the current Screen parameters are read, user can edit the Screen Format and other parameters one by one, and select OK each time to accept the selection.
Page 56 3. Press ‘Enter’, or click the OK button. If the Screen Format was chosen as ‘PV & Bar’ or ‘PV & Trend’, the Display Low Lim and Display High Lim textboxes should become accessible. If ‘PV & Trend’ was selected, the ‘Trend Hours’ textbox will become accessible, shown below.
Page 57 4. Select an option in the PV Selection dropdown. 5. Press ‘Enter’, or click the OK button. This selection will affect the options available in the PV Scaling and Engineering Units dropdown lists. The available options directly reflect the available options on the Advanced Display using DE. 6.
Page 58 9. If PV Scaling is selected as Linear, or if the PV Scaling is selected as Square Root with Units set to Custom, the Scaling Low and Scaling High Limit boxes will be enabled. Enter a value for each, one at a time, pressing enter or ‘OK’ in between. 10.
Page 59 Common Parameter Configuration There are four common parameters that are currently configurable: Language, Screen Rotate, Sequence Time, and Contrast. 1. The common parameters can be configured in any order. After making a change to any of the accessible parameters, confirm that change by clicking ‘OK’. This will write that parameter down to the device.
Page 60: Display Screen Configuration Parameters
Screen Units (see below Table Decimal (see below Table PV Scaling (see below Table Display High Limit (Honeywell Float Format) Display Low Limit (Honeywell Float Format) Scaling Low Limit (Honeywell Float Format) Scaling High Limit (Honeywell Float Format) Trend Hours (see below Table...
Page 61: Table 16 - Display Screen Configuration Parameters Details
Display Screen configuration parameters in detail: Table 16 - Display Screen configuration parameters details Name Size Description Screen Format View display format: 0 – None 1 – Large PV 2 – Bar Graph (Applicable for only Advance Display) 3 – Horizontal Trend (Applicable for only Advance Display) 1 –...
Page 62 PV Scaling 0 - None 1 - Convert Units 2 - Linear 3 – Square Root None, Convert Units, Linear Not Applicable to Sensor 1 Resis Loop Output None, Linear applicable to % Output None, Linear, Convert Units applicable to Diff Press, Gauge/Absolute Press, Temp, Meter Body Temp, Mass/Volume Flow, Sensor1, Totalizer When Convert Units is selected, the selected PV Selection parameter will...
Page 63: Saving, Downloading And Printing A Configuration File
Saving, Downloading and Printing a Configuration File Once you have entered the SMV parameter values into the SCT tab cards, you save the database configuration file. If you are configuring the SMV on-line, you can save and then download the configuration values to the transmitter.
Page 64: Hart Transmitter Configuration
Toolkit and is intimately familiar with the SMV800 family of Transmitters. Therefore, detailed procedures are supplied only in so far as necessary to ensure satisfactory configuration. The other HART configuration Tools are Honeywell Experion in conjunction with FDM, DTMs running on FDM or Pactware, and Emerson 375/475. Refer to Table 19 - HART Transmitter Parameters.
Page 65: Overview Of Fdc Homepage
Overview of FDC Homepage The FDC homepage consists of links for Online Configuration, Offline Configuration, Manage DDs, and Settings. See below. Figure 16 – FDC Homepage Table 17 lists the items that appear on the FDC homepage and its descriptions. Table 17 - FDC homepage elements Items Description...
Page 66: Settings
With this option enabled, FDC creates necessary log files for troubleshooting and diagnostics. These files are stored in SD Card\FDC folder. Note: You must not enable this option unless suggested by Honeywell TAC because this may impact the application performance.
Page 67: Manage Dds
Manage DDs Using this feature, you can manage the DD files installed with FDC. A DD file contains descriptive information about the functionality of a device. By default, a set of DD files are installed with FDC. However, if you do not have a DD for a given device, you can install it using the “Add DD” feature. Similarly, you can uninstall a DD file or a set of DD files using “Delete DD”...
Page 68 Delete a DD file Using this option, you can delete a particular version of a DD file. To delete a DD file for a device, perform the following steps. From the FDC homepage, tap Manage DDs > Select. The Manage DDs dialog box appears. You can choose to delete DD(s) in one of the following ways: By device manufacturer –...
Page 69: Online Configuration
Online configuration Using online configuration, you can configure, calibrate, monitor and diagnose a HART device which is connected to MCT404 Toolkit. FDC provides the features to perform these functions through the various constructs offered through the DD file of the device. Besides there are certain other features available under this link for you to conveniently work with a HART device with live communication.
Page 70: Overview Of Device Homepage
Overview of Device Homepage Once the device is detected and loaded successfully, you can view the device homepage for the identified device. The workspace area on the device homepage consists of 4 tabs on the left-hand side. Selecting a tab displays functions/information associated with that tab on the right-hand side.
Page 71  Functions tab: This tab provides various options which you may use for navigating through the device specific user interface and some standard features offered by FDC across all devices. For the sake of explanations, the right-side options under this tab shall be referred as “Entry points”...
Page 72: Using Fdc For Various Device Operations
snapshot of the device variables. This snapshot is saved in a format which can be later imported as a history record in FDM. Using FDC for various device operations Typical operations with a smart field device involve configuration, calibration, monitoring, and diagnostics.
Page 73 Online Device Entry Point: When you tap on to open the Online tab, the device configuration screen appears as shown below. Alternately you can access the full EDDL features by selecting the “My Device” Tab Navigate through the Menus to access various functions. See Table 19 to view lists of all the parameters in the SMV800.
Page 74: Table 19 - Hart Transmitter Parameters
Table 19 lists descriptions of all parameters for a HART Transmitter with the Online tab menu path. The same parameters may be accessed via the Shortcuts menu under the My Device tab. Note on Flow Primary Elements in SMV800 device: The SMV800 is compatible with and provides dynamic calculation capabilities.
Page 75 Configuration Menu: Provides entry points for below listed pages. Refer SMV800 Series HART/DE Option User’s Manual Revision 6.0 Page 63...
Page 76: Table 20 - Configuration Menu
Menu Table 20 - Configuration for details  Device Info:  Pressure:  Meter Body Temperature:  Process Temperature:  Flow:  Advanced Flow Setup: See section Advanced Flow Setup (for DTM only)  Total Flow:  4-20mA Output:  Display Setup: ...
Page 77  Module diagnostics Table 25 - Temperature for more details  date MB Install date: See Table 26 - Write Tx Install for more details  date Temperature module install date: See Table 27 - Write TM Install for more details ...
Page 78 Table 20 - Configuration Menu Configuration parameters Key: Plain = Read only Bold = Configurable Bold underline = Method Bold italic = Table or graph Pages Group Parameter Description Enter Tag ID name up to 8 characters Long Tag Enter Tag ID name up to 32 characters Descriptor Enter any desired or useful descriptor of the transmitter.
Page 79 Pages Group Parameter Description Manufacturer Manufacturer of the transmitter Model Device model (ST 800, SMV800 etc) or Device Type of SMV800 Transmitter MB Type Measurement type. Type of measurement application this device is intended to be used Manufacturing with MB ID The serial number of the Meter Body Device ID HART unique ID of the SMV800 Transmitter...
Page 80 Pages Group Parameter Description Diagnostics Standard Diagnostics is the only selection available Write Protect Identifies the hardware write protect configuration ordered with the device (On or Off) Configuration Failsafe Identifies the analog failsafe configuration selections ordered with the device (High or Low burnout) Hi Lo Output Limits Identifies the configured high and low analog output range (Standard or Namur)
Page 81 ● inH2O (68 DP Unit inHg (0 ● ● ftH2O (68 ● mmH2O (68 ● mmHg (0 ● ● ● mbar g/cm2 ● ● kg/cm2 ● ● ● Torr ● inH2O@60 ● ● ● inH2O@4 C (39.2 ● mmH2O@4 C (39.2 DP Value The current value of the Differential Pressure input...
Page 82 Description Pages Group Parameter ● inH2O (68 ● inHg (0 ftH2O (68 ● ● mmH2O (68 mmHg (0 ● ● ● ● mbar ● g/cm2 SP Unit ● kg/cm2 ● ● ● Torr ● ● inH2O@60 ● Static ● inH2O@4 C (39.2 Pressure Pressure...
Page 83 Description Pages Group Parameter ● degC PT Unit ● degF ● degR ● Kelvin PT Value The current value of the Process Temperature input PT UTL The Upper Transducer Limit for the Process Temperature input PT URL The Upper Range Limit for the Process Temperature input PT URV The Upper Range Value for the Process Temperature...
Page 84 Description Pages Group Parameter Mass units Volume units g/sec m3/h ● ● ● g/min ● m3/min ● ● m3/sec ● kg/sec ● m3/day ● kg/min ● gal/min ● kg/h ● gal/h ● t/min [Metric ● gal/day tons] l/min ● t/h [Metric ●...
Page 85 Description Pages Group Parameter Allows configuring Flow unit. All the units are self-Explanatory. Custom Unit: When this unit is selected, Tools will populate Flow Custom Tag Flow Base Unit : Base unit is unit from which custom unit is derived Flow Conver.
Page 86: Table 21 - Flow Calculation Setup
Description Pages Group Parameter Flow This Page is populated in a DD Host. Flow Output Calculation Table 21 - Flow Calculation Setup selections setup parameters Advanced This Page is populated in a DTM Host Flow Setup Using DTMs for details Table 21 - Flow Calculation Setup Simulation parameters Failsafe, Reverse Flow,...
Page 87 Description Pages Group Parameter This is the Totalized Flow for Forward flow only. The Positive Totalizer will increment Positive Totalizer when the Flow Rate is a forward flow (positive flow value). Negative Totalizer This is the Totalized Flow for Reverse flow only.
Page 88 Description Pages Group Parameter This is a user configurable value indicating the maximum Totalizer value. When the Totalizer Value reaches this maximum value, it automatically resets to zero and continues totalizing. It also increments the Exceed Counter. On a Negative Totalizer Max value, with a decreasing Total Flow value, Totalizer will Totalizer Max.
Page 89 Description Pages Group Parameter PV is The process variable currently selected as the Primary Variable. Options are:  Differential Pressure  Static Pressure  Process Temperature  Flow  Totalizer SV is The process variable currently selected as the secondary Variable. Options are: ...
Page 90 Pages Group Parameter Description NAMUR Select to enable or disable the Namur option for the output. Refer to 4-20mA dc output and failsafe leveI Selection mageto see the effect on output signal. Analog output alarm type – defines how the analog AO Alrm type output will respond when the field device detects that the analog output may not be tracking the associated...
Page 91 Pages Group Parameter Description Display Type Identifies the type of Display connected to the device (only Advanced Display is available for SMV devices) Display Only when Display is connected to the device, this Installation detail parameter will show type of display ad Adv. Otherwise, it will show None.
Page 92 Pages Group Parameter Description Select the screen to be configured:  Screen 1 to 8 Select the screen format:  None   PV & bargraph  PV & trend Enter high and low limits for trend or bargraph, if PV & trend or PV &...
Page 93 Menu Table 20 - Configuration ) and Maintenance (Table 30 - Maintenance Menu) SMV800 Series HART/DE Option User’s Manual Revision 6.0 Page 81...
Page 94 Table 21 - Flow Calculation Setup Flow Calculation Setup Parameters Key: Plain = Read only Bold = Configurable Bold underline = Method Bold italic = Table or graph Group 1. Values Description Parameter  No Flow Output  Ideal Gas Actual Volume Flow When Fluid type = Gas ...
Page 95 Values Group Parameter Description Absolute Static pressure at design conditions (Always enter in Absolute even if the device is SMG/Gauge type). 1.flowing density is calculated using this parameter, Design Temperature, Design density, Process Design Pressure Temperature and Process Static pressure. 2. This parameter is used as substitute value for flow Calculations when Static pressure fails and Absolute Pressure Comp...
Page 96 Group Parameter Values Description The Absolute Pressure at nominal or default process conditions. If failsafe for the flow output is not needed when a pressure sensor fails, the Nominal values for pressure will be Nominal used in the flow calculation and the Absolute flowrate would continue to be pressure...
Page 97 Group Parameter Values Description PV2 Process Input: If the PV2 input becomes good, device needs a power cycle to return to normal. PV2 Sim Input: If the PV2 input becomes good, device returns to normal without a power cycle. Case 2: This Switch ON: When PV4 is mapped to output, bad PV2 (Process input or Sim value) makes PV4 bad, device goes to burnout.
Page 98 Group Parameter Values Description Check this if flow output is required to go to failsafe when there is a Temperature failure. If failsafe is not required, Uncheck this to use the Nominal or Design Temperature values in flow calculations when there is a Temperature failure.
Page 99 Group Parameter Values Description PV4 calculated: If the PV3 input becomes good (Process input or Sim value), device needs a power cycle to return to normal. PV4 Simulated: PV3 input good or bad (Process input or Sim value), PV4 is not dependent on PV3. If PV4 sim input is Bad, device goes to Burnout.
Page 100 Group Parameter Values Description Example: Check this setting if reverse flow is expected so that flow is non zero when DP <0. When this flag is checked, absolute value of DP is used for flow calculations when DP < 0. For some Flow Elements and Algorithm Standards, Reverse Flow may not be applicable.
Page 101 Group Parameter Values Description Manual input flowing density: If Flowing Density value is available in the Flow element calculation report, check manual input and enter the value. Otherwise uncheck manual input. Flowing density will be calculated using Design Density Manual i/p or density coefficients that will be density auto-calculated for the selected...
Page 102 Group Parameter Values Description Manual input temperature expansion factor. Check this to enter temperature expansion factor Manual i/p Fa from flow calculation report. (Tempe exp Uncheck this to have the device factor) auto calculate Fa. Fa is a Correction factor for the error resulting from thermal effects on the Flow element diameter.
Page 103 Group Parameter Values Description Temperature compensation switch: Applicable to ASME1989/SMV3000 Standard algorithms, when temperature failsafe switch is unchecked. When temperature compensation switch is checked, Design Temperature is used for Gas Equations and Nominal Temperature is used for Liquid equations when Temperature fails. When failsafe switch is checked, failure of temperature will put the device to burnout when flow is...
Page 104 Group Parameter Values Description 0,1,1,2,2-TETRAFLUOROETHANE, 1,1,1,2-TRICHLOROETHANE, 2,1,2,4-TRICHLOROBENZENE, 3,1,2-BUTADIENE, 4,1,3,5-TRICHLOROBENZENE, 5,1,4-DIOXANE, 6,1,4-HEXADIENE, 7,1-BUTANAL, 8,1-BUTANOL, 9,1-BUTENE, 10,1-DECANAL, 11,1-DECANOL, 12,1-DECENE, 13,1-DODECANOL, 14,1-DODECENE, 15,1-HEPTANOL, 16,1-HEPTENE, 17,1-HEXADECANOL, 18,1-HEXENE, 19,1-NONANAL, 20,1-NONANOL, 21,1-OCTANOL, 22,1-OCTENE, This parameter is 23,1-PENTADECANOL, currently not used in 24,1-PENTANOL, the DD tool. If using 25,1-PENTENE, other tools like 26,1-UNDECANOL,...
Page 105 55,ETHYLBENZENE, 56,ETHYLENE OXIDE, 57,ETHYLENE, 58,FLUORENE, 59,FURAN, 60,HELIUM-4, 61,HYDROGEN CHLORIDE, 62,HYDROGEN CYANIDE, 63,HYDROGEN PEROXIDE, 64,HYDROGEN SULFIDE, 65,HYDROGEN, 66,ISOBUTANE, 67,ISOPRENE, 68,ISOPROPANOL, 69,m-CHLORONITROBENZENE, 70,m-DICHLOROBENZENE, 71,METHANE, 72,METHANOL, 73,METHYL ACRYLATE, 74,METHYL ETHYL KETONE, 75,METHYL VINYL ETHER, 76,n-BUTANE, 77,n-BUTYRONITRILE, This parameter is 78,n-DECANE, currently not used in 79,n-DODECANE, the DD tool.
Page 106 Group Parameter Values Description Manual input flowing Density value density value When Manual i/p density if off, Density coefficients 1 through 5 are auto- calculated for the selected fluid. Order of polynomial determines the number of coefficients generated. Table 43 - Density Density Coefficients: Dependency coefficient 1...
Page 107 Group Parameter Values Description Viscosity Manual input flowing viscosity value value When Manual i/p viscosity if off, viscosity coefficients 1 through 5 are auto- calculated for the selected fluid. Order of polynomial determines the number of coefficients generated. Viscosity Table 42 - Viscosity Coefficients: coefficient 1 through 5 Dependency to Algorithm...
Page 108 Group Parameter Values Description Orifice ASME-MFC-3-2004 Flange Pressure Taps Orifice ASME-MFC-3-2004 Corner Pressure Taps Orifice ASME-MFC-3-2004 D and D/2 Pressure Taps Orifice ISO5167-2003 Flange Pressure Taps Orifice ISO5167-2003 Corner Pressure Taps Orifice ISO5167-2003 D and D/2 Pressure Taps Orifice GOST 8.586-2005 Flange Pressure Taps Orifice GOST 8.586-2005 Corner Pressure Taps...
Page 109 Venturi ISO5167-2003 Rough-Welded Sheet-Iron Convergent Section Venturi GOST 8.586-2005 Cast Upstream Cone Part Venturi GOST 8.586-2005 Machined When Algorithm Upstream Cone Part Options = Advanced Venturi GOST 8.586-2005 Welded Algorithms Upstream Cone Part made of Sheet Steel Averaging Pitot Tube Standard V-Cone with Macrometer method Standard V-Cone with ASME method...
Page 110 Group Parameter Values Description Nozzle GOST 8.586-2005 ISA 1932 Nozzles Venturi ASME-MFC-3-2004 “As-Cast” Convergent Section Venturi ASME-MFC-3-2004 Machined Convergent Section Venturi ASME-MFC-3-2004 Rough- Welded Convergent Section Venturi ISO5167-2003 “As-Cast” Convergent Section Venturi ISO5167-2003 Machined Convergent Section Venturi ISO5167-2003 Rough-Welded Sheet-Iron Convergent Section When Algorithm Flow element Venturi GOST 8.586-2005 Cast...
Page 111 Group Parameter Values Description Pipe Diameter Pipe diameter Bore Bore Diameter in inches. In case of diameter/ Average Pitot Tube, this parameter is Probe width Pitot Tube Probe Width (APT) Pipe diameter measuring Temperature Enter the value in the unit selected in the Unit Configuration screen.
Page 112: Table 38 - Configuration Of Materials, Flowing Temperature And Thermal Expansion Coefficients
Group Parameter Values Description When Flow Calc Standard is other than GOST 304 Stainless Steel 316 Stainless Steel Table 38 - Configuration of Materials, 304/316 Stainless Steel Flowing Temperature and Thermal Pipe material Carbon Steel Expansion Coefficients Hastelloy to understand the relationship Monel 400 between Pipe Material, Flowing Other...
Page 113 Group Parameter Values Description Value is set based on the Bore Material selected. RULE: When Algorithm = ASME 1989 Algorithms, for Pitot Tube Element, Bore Thermal Expansion Coefficient = Pipe Thermal Expansion Coefficient Pipe thermal exp. Coefficient Table 38 - Configuration of Materials, Flowing Temperature and Thermal Expansion Coefficients understand the relationship between...
Page 114 device will calculate the value. See the below parameter. Group Parameter Values Description Flow Coefficient for WEDGE. This parameter represents values based on Algorithm Option and Flow KUser/Flow Calculation Standard. Advanced coeff./Calib. Algorithms: For WEDGE, Averaging factor(Fc) Pitot Tube and Integral Orifice, this parameter represents Flow Coefficient.
Page 115 Table 22 - Monitoring Menu Monitoring Menu Parameters Key: Plain = Read only Bold = Configurable Bold underline = Method Bold italic = Table or graph Page Group Parameter Description PV is The process variable currently selected as the Primary Variable. Options are: ...
Page 116 SMV800 Series HART/DE Option User’s Manual Page 104 Revision 6.0...
Page 117 Page Group Parameter Description PV % rnge The percentage value representation of the device output based on the configured Process Variable range (LRV to URV) Loop current Displays the current value of the analog output current in milliamperes Comm module Temp Communication module temperature CJT Value Cold junction temperature value...
Page 118 Table 23 – Communication module diagnostics Communication module diagnostics parameters Key: Plain = Read only Bold = Configurable Bold underline = Method Bold italic = Table or graph Page Group Parameter Description Service life Percent of Communication Module service life spent in stressful conditions. Indicates the % of service life where Comm Stress Life one or more of processor core...
Page 119 Communications board Electronics Upper operating limit Temperature (ET) highest operating limit from specification. Communications board Electronics Lower operating limit Temperature (ET) lowest operating limit from specification. The total number of minutes that the Total time above upper Communications board Electronics limit Temperature (ET) has exceeded the upper stress limit (ET Upper Limit)
Page 120: Table 24 - Meter Body (Mb) Diagnostics
Table 24 - Meter Body (MB) diagnostics Service life parameters Key: Plain = Read only Bold = Configurable Bold underline = Method Bold italic = Table or graph Page Group Parameters Description MB Install Date The Pressure Module Installation Date Percent of Pressure Sensor module service life spent in stressful conditions.
Page 121 Pressure Module Electronics Temperature Maximum ET (ET) highest measured value Pressure Module Electronics Temperature Min ET Value (ET) lowest measured value The total number of minutes that the Total time above upper Pressure Module Electronics Temperature limit (ET) has exceeded the upper stress limit MB Electronics The total number of minutes that the Total time below lower...
Page 122: Table 25 - Temperature Module Diagnostics
Table 25 - Temperature Module diagnostics Service life parameters Key: Plain = Read only Bold = Configurable Bold underline = Method Bold italic = Table or graph Page Group Parameter Description Temp module Install Date The Temperature Module Installation Date One-time writable installation date for the Sensor Install Date thermocouple or RTD sensor for measuring...
Page 123 Page Group Parameter Description Maximum Value Maximum measured difference between the Temperature Processor Core temperature (CT) and the Cold Junction temperature (CJ) Minimum Value The total number of minutes that the Temperature Processor Core temperature (CT) has been less than the Cold Junction temperature (CJ) Delta Value Currently measured difference between the...
Page 124: Table 26 - Write Tx Install Date
Page Group Parameter Description Maximum voltage Displays the highest recorded value of the Temperature Sensor Supply Voltage (AVDD) Minimum voltage Displays the lowest recorded value of the Temperature Sensor Supply Voltage (AVDD) Sensor supply Time since above max Displays the time elapsed since the voltage voltage Temperature Sensor Supply Voltage last...
Page 125: Table 30 - Maintenance Menu
Table 30 - Maintenance Menu Maintenance menu Parameters Key: Plain = Read only Bold = Configurable Bold underline = Method Bold italic = Table or graph Page Group Parameter Description MB Install date One-time writable installation date for the Meter Body. Temp Module install One-time writable installation date for the date...
Page 126 Page Group Parameter Description Tamper Mode Enable or disable tampering detection (outside attempts to change device configuration when Write Protect is enabled). When enabled, the “Tamper Counter” will keep track of the number of times an attempt is made. After the configured “Max Attempts”, an alarm status is generated.
Page 127 Page Group Parameter Description Perform an analog output calibration at 4.00 and 20.00 mA (0% and 100% output). Prompts the user to connect a reference meter to calibrate the DAC 4-20 ma output. D/A trim The output is first set to 4ma and the user enters the actual current measured to calibrate the DAC zero.
Page 128 Page Group Parameter Description SP Zero trim Perform an input calibration correction by applying process input at zero SP URV correct URV Correct: perform an input calibration correction by applying process input at the configured URV level SP LRV correct LRV Correct: perform an input calibration correction by applying process input at the configured LRV...
Page 129: Table 31 -Device Status
Table 31 –Device Status Device Status Indication Key: Plain = Read only Bold = Configurable Bold underline = Method Bold italic = Table or graph DAC Failure Refer to Section 10 Troubleshooting and Config Data Corrupt Maintenance for details on Critical SIL Diagn Failure Diagnostic messages...
Page 130 Maintenance Required Refer to Section 10 Ext Dev Status Device Variable Alert Troubleshooting and Maintenance Critical Power Failure for details on Diagnostic messages Additional Status Refer to Section 10 Troubleshooting and Maintenance DAC Failure Temp Above 100C for details on Additional Status Temp Above 140C messages DAC Under Current Status...
Page 131 Pressure Low Sensor Supply Meter body Failure Sensor Characterization Corrupt DP/MBT/SP/PT/Flow Bad / Totalizer Suspect Input Sensor RAM Corrupt Sensor Code Corrupt Sensor Flow Failure / Totalizer bad Pressure Excess Zero Correction Excess Span Correction Char Calc Error Sensor Overload Sensor RAM DB Fault Pressure No Factory Calibration Pressure Unreliable Comm...
Page 132: Table 32 - Flow Units
Table 32 – Flow Units When Flow Output Type is Mass When Flow Output Type is Flow: Volume Flow: ● g/sec ● m3/h g/min m3/min ● ● ● ● m3/sec ● kg/sec ● m3/day ● kg/min ● gal/min kg/h gal/h ●...
Page 133: Procedure To Enter The Transmitter Tag
Table 33 – Tamper Reporting Logic Implementation with Write Protect Configuration Write Protect Write Protect Change Jumper Status Software Status Allowed? ON or OFF OFF (or missing) OFF (or missing) Tamper Reporting Tamper Alerted Posted? Status Note that Tamper Reporting is independent of Write Protect status. The sections below give some examples as to how to edit the configuration parameters and execute Methods.
Page 134 Table 20 - Configuration Menu / 4-20mA Output/ mapping the device variables. Engineering units affect the values of the LRV, URV and the LRL and the URL. After changing the PV engineering units to the Transmitter, verify changes to the units parameter, the LRV, and the URV.
Page 135: Selecting Pressure Units
Selecting Pressure Units If Differential Pressure or Static Pressure is mapped to PV, the pressure measurement can be displayed in one of the pre-programmed engineering units. 1. From My Device menu, make the following menu selections: Device Setup > Device Variable Mapping > PV Units 2.
Page 136: Selecting Flow Units
6. Click Send. The Send to Device screen will be displayed. 7. Select the PV Unit check box. 8. Click Send to download the change to the Transmitter or Return to continue making changes. Similarly if Temperature is mapped to SV, TV, QV, follow the same procedure by accessing the relevant variable unit.
Page 137: Setting Range Values For Applied Pressure For Dp
The LRV and URV values can be entered with the Toolkit keypad or by applying the corresponding pressure values directly to the Transmitter. Use the following procedure to key in the range values. The procedure uses an example of 5 to 45 referenced to inH ...
Page 138: Setting Urv, And Lrv Range Values (For Static Pressure Values)
Setting URV, and LRV Range Values (for Static Pressure Values) SMV800 Transmitters are calibrated at the factory with ranges for PV, SV, TV, QV The LRV and URV values can be entered with the Toolkit keypad or by applying the corresponding Range values directly to the Transmitter.
Page 139: Setting Urv, And Lrv Range Values (For Temperature Values)
Setting URV, and LRV Range Values (for Temperature Values) SMV800 Transmitters are calibrated at the factory with ranges for PV, SV, TV, QV The LRV and URV values can be entered with the Toolkit keypad or by applying the corresponding Range values directly to the Transmitter.
Page 140: Entering Urv, And Lrv Range Values (For Flow Values)
Entering URV, and LRV Range Values (for Flow Values) SMV800 Transmitters are calibrated at the factory with ranges for PV, SV, TV, QV The LRV and URV values can be entered with the Toolkit keypad or by applying the corresponding Range values directly to the Transmitter.
Page 141: Exporting Device History Records To Fdm
Note: The device can be identified with History Record Name and Device Tag in FDM, once the record is imported in FDM, provided the device is not already present in the FDM network. Select the Format. The following are the available formats: ...
Page 142: Exporting Device History Records To Documint
Exporting device history records to DocuMint To export device history from FDC and import it in FDM, perform the following steps. Connect your MCT404 Toolkit handheld to your computer as described earlier. Browse to the folder on your computer, SD Card > FDC > Resources > History. The FDC history records are named as per the following convention for the primary name: DeviceTag_ManufacturerIDDeviceTypeDeviceRevisionDDRevision_DeviceID...
Page 143 Note: To view the custom views, tap My View 1 > Select. The My View 1 page appears. Edit the parameters that are Read / Write and select Send. For more details on any of the FDC features, refer the “MC Toolkit User Manual, document #34-ST-25-50 (MCT404).”...
Page 144: Offline Configuration
Offline Configuration Overview Offline Configuration refers to configuring a device when the device is not physically present or communicating with the application. This process enables you to create and save a configuration for a device, even when the device is not there physically. Later when the device becomes available with live communication, the same configuration can be downloaded to the device.
Page 145 Deleting offline configuration Using this feature you can delete an offline configuration template. To delete an offline configuration, perform the following steps. On the FDC homepage, tap Offline Configuration > Select. The Offline Configurations page appears. Select the required offline configuration template from the list. Tap Options >...
Page 146 Note: If the variables are downloaded successfully, status appears as SUCCESS in green color; and if failed, status appears as FAILED in red color. Tap Finish to return to FDC Homepage. SMV800 Series HART/DE Option User’s Manual Page 134 Revision 6.0...
Page 147: 7 De Calibration
Calibration Recommendations If the Transmitter is digitally integrated with a Honeywell Total Plant Solution (TPS) system, you can initiate range calibration and associated reset functions through displays at the Universal Station, Global User Station (GUS), and Allen-Bradley Programmable Logic Controllers (PLCs). However, a range calibration using the SCT3000 application with the Transmitter removed from service is recommended.
Page 148: De Output Calibration
DE Output Calibration Output Calibration Preparation This procedure applies to DE Transmitters operating in analog (current) mode only. First, verify the integrity of the electrical components in the output current loop. Make the connections shown in Figure 18, and establish communication with the Transmitter. Connect the SCT3000 as indicated, and establish communication with the transmitter.
Page 149: Output Calibration Using Sct3000
Figure 19 – DE Analog Mode Scaling and Test Connections Output Calibration using SCT3000 1. Start the SCT3000 application such that the DE MAIN MENU is displayed. 2. Select the Output Calibration tab for DP OutCal, AP OutCal, Temp Outcal or Flow OutCal. 3.
Page 150 b. Verify that the loop is in manual control. In output mode, output current is fixed at the 0% or 100% level as selected in the TRIM DAC CURRENT box in the previous step. c. Select Yes, and observe the loop current level. A meter reading of 4 mA corresponds to 1 volt as measured across the precision 250 ohm loop resistor.
Page 151: Calibrating Range Using A Configuration Tool
Calibrating Range Using a Configuration Tool The range calibration involves two procedures, one to calibrate the input, the other to calibrate the output. This section provides both procedures. Conditions for Input Calibration Calibrate Transmitter input only when necessary, and under conditions that will ensure accuracy: ...
Page 152: De Input Calibration Procedure
Figure 20 – Input Calibration Connections DE Input Calibration Procedure Start the SCT3000 application such that the DE MAIN MENU is displayed. Select the Input Calibration tab for DP InCal, AP InCal, Temp Incal or Flow InCal. DP Input Cal Select the Input Calibration tab for DP InCal.
Page 153: Correct Dp Input At The Lower Range Value (Lrv)
Correct DP Input at the Lower Range Value (LRV) 1. After the LRV and URV have been entered, select the Correct LRV button on the CALIBRATION display. (See Step 4 in the previous procedure to bring the CALIBRATION screen to the display.) 2.
Page 154 6. When the Transmitter has completed the LRV correction, this message appears: 7. Select Yes to acknowledge. SMV800 Series HART/DE Option User’s Manual Page 142 Revision 6.0...
Page 155: Correct Dp Input At Urv
Correct DP Input at URV 1. Select the URV button. This message appears. 2. Adjust the PV input pressure to the exact value of the URV entered in the DE CONFIGURE display. 3. Select the Correct button; this message appears: 3.
Page 156 4. When the transmitter has completed the URV correction, this message appears. 5. Select Yes to acknowledge. SMV800 Series HART/DE Option User’s Manual Page 144 Revision 6.0...
Page 157: Ap Input Calibration
AP Input Calibration Select tab AP InCal AP Input Cal LRV (Lower Range Value) Correct_ SMV800 Series HART/DE Option User’s Manual Revision 6.0 Page 145...
Page 158: Ap Input Cal Urv (Upper Range Value) Correct
AP Input Cal URV (Upper Range Value) Correct Screens will show URV. Reset Corrects Resets all Corrects to factory defaults. Select Ok to confirm reset. SMV800 Series HART/DE Option User’s Manual Page 146 Revision 6.0...
Page 159: Temperature Input Calibration
Temperature Input Calibration Select tab Temp InCal Process Temperature LRV (Lower Range Value) Correct_ SMV800 Series HART/DE Option User’s Manual Revision 6.0 Page 147...
Page 160: Process Temperature Urv (Upper Range Value) Correct
Process Temperature URV (Upper Range Value) Correct Screens will show URV. Reset Corrects Resets all Corrects to factory defaults. Select Ok to confirm reset. SMV800 Series HART/DE Option User’s Manual Page 148 Revision 6.0...
Page 161: Hart Calibration
8 HART Calibration About This Section This section provides information about calibrating a Transmitter’s analog output and measurement range. It also covers the procedure to reset calibration to the default values as a quick alternative to measurement range calibration. This section includes the following topics: ...
Page 162: Analog Output Signal Calibration
Analog Output Signal Calibration With a Transmitter in its constant current source mode, its analog output circuit can be calibrated at its 0 (zero) % and 100% levels. It is not necessary to remove the Transmitter from service. The following procedure is used for analog output signal calibration. You can calculate milliamperes of current from a voltage measurement as follows: Dc milliamps = 1000 X voltage/resistance IMPORTANT: Be sure that the accuracy of the resistor is 0.01% or better for current...
Page 163: Calibrating Range
Calibrating Range The SMV800 Transmitter supports two-point calibration. This means that when two points in a range are calibrated, all points in that range adjust to the calibration. The procedures in this section are used to calibrate differential pressure (DP) of SMV800 Transmitter to a range of 0 to 200 inH O for example purposes.
Page 164: Figure 21 - Setup To Manually Set The Pv Lrv And Urv
8. When prompted, adjust the pressure source to apply pressure equal to the URV (100%), and press OK. 9. When pressure stabilizes, press OK. 10. When prompted, remove the pressure. 11. On the next prompt – “Please enter Calibration Date in MM/DD/YYYY format, for example “05/27/2009,”...
Page 165: Resetting Calibration For Differential Pressure
Resetting Calibration for Differential Pressure SmartLine HART Transmitter can erase incorrect calibration data by resetting the device back to final factory calibration, which is performed per the ordered range. The Corrects Reset command returns the zero and span calibration factors to the original precise factory calibration. The following procedure is used to reset calibration data to factory calibrated range using the communicator.
Page 166: Correcting The Lower Range Value (Urv) For Temperature
15. On the next prompt – “Please enter Calibration Date in MM/DD/YYYY format. Enter the Calibration date (for example “05/27/2009”) and press Enter. On the next prompt - "Please enter the current calibration time in 24 Hr format (Hours Field)", enter the Hours field HH (for example, "12"), and press ENTER 17.
Page 167: Resetting Calibration For Temperature
Resetting Calibration for Temperature SMV800 SmartLine HART Temperature Transmitter can erase incorrect calibration data by resetting the device back to final factory calibration, which is performed per the ordered range. The Corrects Reset command returns the zero and span calibration factors to the original precise factory calibration.
Page 168: Dual / Triple Calibration
Dual / Triple Calibration The transmitter will have the required calibration set as selected by the user when the transmitter is purchased; either single, dual or triple calibration for Differential Pressure and Static Pressure.  Calibration A (Cal A) standard ...
Page 169: Hart Advanced Diagnostics
9 HART Advanced Diagnostics About This Section This section provides information about the Advanced Diagnostic features in the SMV800 Transmitter. Advanced Diagnostics Table 34 – Viewing Advanced Diagnostics What you want to view What to do  Select Start/FDC to Launch the Install dates for the Meter Body / Device and for the FDC application on the MCT404...
Page 170: 10 Troubleshooting And Maintenance
10 Troubleshooting and Maintenance Troubleshooting Using the SCT Using the SCT in the on-line mode you can check the transmitter status, identify diagnostic messages and access troubleshooting information so you can clear fault conditions. The SMV diagnostic messages fall into any one of the following general categories: ...
Page 171: 11 Using Dtms
Download 2: HART Communication DTM\ Download from http://www.codewrights.biz/ Download 3: Honeywell HART DTM Library Download from HPS web site Procedure to Install and Run the DTM 1. Install the Download 1, 2, or 3 above. 2. Connect the Transmitter to the 30 V DC power supply with a 250 ohm loop resistor.
Page 172: Smv800 Online Parameterization
SMV800 Online Parameterization On selecting Parameter/Online Parameterization, the DTM home page is displayed as shown below. The home page has 4 top level menus: Configuration, Monitoring, Diagnostics, Maintenance Configuration Menu: Provides entry points for below listed pages. For all the below items refer to SMV800 Series HART/DE Option User’s Manual Page 160 Revision 6.0...
Page 173: Monitoring Menu
Table 20 - Configuration Menu (except where shown)  Device Info:  Pressure:  Meter Body Temperature:  Process Temperature:  Flow:  Advanced Flow Setup: See section Advanced Flow Setup (for DTM only)  Total Flow:  4-20mA Output: ...
Page 174: Maintenance Menu
 Table 25 - Temperature Module diagnostics for more details  MB Install date: See Table 26 - Write Tx Install date for more details  Temperature module install date: See Table 27 - Write TM Install date for more details ...
Page 175: Advanced Flow Setup (For Dtm Only)
Advanced Flow Setup (for DTM only) Advanced Flow Setup allows the user to configure the Flow setup in an easy and intuitive way. Engineering Units Provides option to select U.S Units, S.I. Units or predefined All units (standard units list) for Differential Pressure, Static Pressure, Temperature, Flow, Viscosity, Density and Length parameters.
Page 176: Table 36 - Unit Configuration
Table 36 – Unit Configuration Unit Configuration Parameters Key: Plain = Read only Bold = Configurable Bold underline = Method Bold italic = Table or graph Units Selection Group Parameters U.S. Units S.I. Units All Units  inH2O (68  inHg (0 ...
Page 177 Units Selection Group Parameters U.S. Units S.I. Units All Units  Degrees Fahrenheit Degrees Degrees Celsius ° ° (°F) Fahrenheit (  Degrees Celsius (°C) Temperature  Kelvin  Degrees Rankine (°K) lb/sec when g/sec when Flow Table 32 – Flow Units Flow output output type is for Mass Flow and Volume...
Page 178: Flow Calculation Setup
Flow Calculation Setup Configure Flow Setup parameters SMV800 Series HART/DE Option User’s Manual Page 166 Revision 6.0...
Page 179: Table 37 - Setup Flow Calculation
Table 37 – Setup Flow Calculation Flow Calculation Setup Parameters Key: Plain = Read only Bold = Configurable Bold underline = Method Bold italic = Table or graph Group 1. Values Description Parameter 1,2,3 – applicable when: 2. Gas Algorithm Options = Advanced 3.
Page 180 Group Parameter Values Description Orifice Nozzle Venturi When Algorithm Options Pitot Tube = Advanced Algorithms Flow VCone Element Wedge Type Orifice Nozzle When Algorithm Options Venturi = ASME 1989 Algorithms Pitot Tube Venturi ISO5167-2003 Machined Convergent When Algorithm Options Section = Advanced Algorithms Venturi ISO5167-2003 Rough-Welded Sheet- Iron Convergent Section...
Page 181 Group Parameter Values Description ASME-MFC-3M When Algorithm Options = ISO5167 Advanced Algorithms GOST Automatically set based on AGA3 Primary Element type and VCONE/WAFER CONE Primary Element Flow ASME-MFC-14M Element Flow Calc WEDGE type / Standard AVERAGE PITOT TUBE Standard INTEGRAL ORIFICE CONDITIONAL ORIFICE CONDITIONAL ORIFICE ASME 1989...
Page 182 Group Parameter Values Description Bore diameter measuring Temperature Enter the value in the unit selected in the Unit Configuration screen. For SMV3000 algorithms, this value Bore is fixed at 68degF. For SMV800 Diameter Algorithms, user entered Reference Measuring Temperature will be used to Temp calculate the adjusted Diameter.
Page 183 Group Parameter Values Description 30X13 10X14Г14H14T 08X18H10 12X18H9T 12X18H10T 12X18H12T 08X18H10T 08X22H6T 37X12H8Г8MФБ 31X19H9MBБT 06XH28MдT 20Π 25Π Pipe Value is set based on the Pipe Thermal Exp Material selected Coefficient_ alpha_D Table 38 - Configuration of Materials, Flowing Temperature and Thermal Expansion Coefficients to understand the relationship between Pipe Material,...
Page 184 Group Parameter Values Description 18X2H4MA Bore Material = Pipe 38XH3MФA Material. 08X13 12X13 30X13 10X14Г14H14T 08X18H10 Bore 12X18H9T Material 12X18H10T (continued) 12X18H12T 08X18H10T 08X22H6T 37X12H8Г8MФБ 31X19H9MBБT 06XH28MдT 20Π 25Π Value is set based on the Flow Bore Material selected. Element Properties RULE: When Algorithm = ASME 1989 Algorithms,...
Page 185 Group Parameter Values Description Manual input Coefficient of Discharge. Check the Manual input and enter Coefficient of discharge value from Flow element calculation report. If value is not available, uncheck the Manual input. Device will auto-calculate the Cd value based on fluid type, Flow element Manual input and material selected.
Page 186 Group Parameter Values Description 0.75 Applicable when Algorithm Options = SMV3000 Equation Model = Dynamic. Based on the selected Primary Discharge element, this is auto calculated. Exponent Coefficient of Discharge in the Flow equation is calculated using Discharge Exponent, Reynolds Coefficinet_r1 and Reynolds Coefficinet_r2.
Page 187: Fluid Data Screen
Table 38 - Configuration of Materials, Flowing Temperature and Thermal Expansion Coefficients Pipe / Bore Materials Flowing Temperature Thermal Expansion coefficients in Range (degF) the DTM tool  32 to 212 Auto-populate 304 / 316 Stainless Steel  Select Material as “Other” 304 Stainless Steel Outside this range ...
Page 188: Table 39 - Fluid Data
Table 39 – Fluid Data Fluid Data Parameters Key: Plain = Read only Bold = Configurable Bold underline = Method Bold italic = Table or graph Group Parameter Values Description Absolute Static pressure at design conditions (Always enter in Absolute even if the device is SMG/Gauge type).
Page 189 Group Parameter Values Description The Absolute Pressure at nominal or default process conditions. If failsafe for the flow output is not needed when a pressure sensor fails, the Nominal values for pressure will be Nominal used in the flow calculation and the Absolute flowrate would continue to be Pressure...
Page 190 Group Parameter Values Description ON/OFF Select this to ON to enter KUser value manually. Select this to OFF to have DTM KUser Manual auto calculate the KUser calculation Input value using selected Fluid type, Flow output type, Max Flow Rate and Max Differential Pressure.
Page 191 Group Parameter Values Description 28,2-METHYL-1-PENTENE, 29,ACETIC ACID, 30,ACETONE, 31,ACETONITRILE, 32,ACETYLENE, 33,ACRYLONITRILE, 34,AIR, 35,ALLYL ALCOHOL, 36,AMMONIA, 37,ARGON, 38,BENZALDEHYDE, 39,BENZENE, 40,BENZYL ALCOHOL, 41,BIPHENYL, 42,CARBON DIOXIDE, 43,CARBON MONOXIDE, 44,CARBON TETRACHLORIDE, 45,CHLORINE, 46,CHLOROPRENE, 47,CHLOROTRIFLUOROETHYLENE, 48,CYCLOHEPTANE, 49,CYCLOHEXANE, 50,CYCLOPENTENE, 51,CYCLOPROPANE, List of Fluids for which 52,ETHANE, the Viscosity and Fluid 53,ETHANOL,...
Page 192 Group Parameter Values Description 80,n-HEPTADECANE, 81,n-HEPTANE, 82,n-HEXANE, 83,n-OCTANE, 84,n-PENTANE, 85,NATURAL GAS, 86,NEON, 87,NEOPENTANE, 88,NITRIC ACID, 89,NITRIC OXIDE, 90,NITROBENZENE, 91,NITROETHANE, List of Fluids for which 92,NITROGEN, the Viscosity and 93,NITROMETHANE, Fluid name Density coefficients 94,NITROUS OXIDE, Fluid name will be calculated 95,OXYGE}, 96,PENTAFLUOROETHANE, automatically...
Page 193 Group Parameter Values Description Applicable When Algorithm Option = Advanced Algorithms Manual input flowing viscosity: If viscosity value is available in the Flow element Manual calculation report, check manual input and Input enter the value. Otherwise uncheck manual Viscosity input, and viscosity coefficients will be auto- calculated for the selected fluid under Fluid list.
Page 194 Group Parameter Values Description Applicable When Algorithm Option = Advanced Algorithms Manual input flowing density: If Flowing Density value is available in the Flow element calculation report, check manual input and enter the value. Otherwise uncheck manual input. Flowing density Manual Input will be calculated using Design Density or density Density...
Page 195: Coefficients And Switches Screen
Upper Temperature limit to calculate the density. Configurable when Manual Input Density Switch is unchecked Coefficients and switches Screen Configure Discharge coefficients, compensation and failsafe settings SMV800 Series HART/DE Option User’s Manual Revision 6.0 Page 183...
Page 196: Table 40 - Coefficients And Switches
Table 40 - Coefficients and Switches Coefficients and Switch Parameters Key: Plain = Read only Bold = Configurable Bold underline = Method Bold italic = Table or graph Coefficients Values Description Manual Input (for Expansion Factor_y) Expansion Factor_Y (entry field When Manual Input is ON) Manual Input (for Temp Expansion Factor_Fa)
Page 197 Coefficients Values Description Example: Check this setting if reverse flow is expected so that flow is non zero when DP <0. When this flag is checked, absolute value of DP is used for flow calculations when DP < 0. For some Flow Elements and Algorithm Standards, Reverse Flow may not be applicable.
Page 198 Coefficients Values Description Compensation Switch Absolute pressure compensation switch: Applicable to ASME1989/SMV3000 Standard algorithms, when pressure failsafe switch is unchecked. When pressure compensation is checked, Design pressure is used for Gas Equations, Nominal Pressure is used for Liquid equations when Static pressure fails. When failsafe switch is checked, failure of pressure will put the device to burnout when flow is mapped to AO.
Page 199 Coefficients Values Description Failsafe Switch Check this if flow output is required to go to failsafe when there is a Static pressure failure. If failsafe is not required, uncheck this to use the Nominal or Design Absolute pressure values in flow calculations when Static pressure fails.
Page 200 Coefficients Values Description Check this if flow output is required to go to failsafe when there is a Temperature failure. If failsafe is not required, uncheck this to use the Nominal or Design Temperature values in flow calculations when there is a Temperature failure. All Fluids, Dynamic Algorithms and Liquid Standard Algorithms use Nominal temperature.
Page 201 SMV3000, Standard: Fluid = Gas: Flow equation Uses Design Temperature. Fluid = Liquid: Flow equation Uses Default / Nominal Temperature. Fluid = Steam: Flow equation Uses Design Temperature Failsafe Density. (PV3) Design Temperature = 1. continued SMV3000 or SMV800 Dynamic: Fluid = Gas, Liquid, Steam: Flow equation uses Nominal/Default Temperature...
Page 202: Table 41 - Simulate Process Variables
Table 41 - Simulate Process Variables Simulate Differential Pressure User enters the values as selected in Unit Configuration screen DP value Simulate Static Pressure User enters the values as selected in Unit Configuration screen SP value Simulate Temperature User enters the values as selected in Unit Configuration screen PT value Simulate Mass Flow...
Page 203: Table 43 - Density Coefficients: Dependency To Algorithm Option
Table 43 - Density Coefficients: Dependency to Algorithm option Equation Model and Fluid Type Density Algorithm Options Manual Fluid Custom Auto Manual Density input Selection Fluid calculatio entry d1 Temp density selection n d1 to d5 to d5 Low/High (Fluid != (Fluid = limits Custom)
Page 204: Element Specific Properties Screen
Element Specific Properties screen Configure properties specific to selected Primary Element or Standard: Gost, WEDGE, VCone, and Conditional Orifice Gost standard VCone SMV800 Series HART/DE Option User’s Manual Page 192 Revision 6.0...
Page 205 Wedge Conditional Orifice SMV800 Series HART/DE Option User’s Manual Revision 6.0 Page 193...
Page 206: Table 44 - Element Specific Properties
Table 44 - Element Specific Properties Element Specific Properties Parameters Key: Plain = Read only Bold = Configurable Bold underline = Method Bold italic = Table or graph WEDGE Beta Factor Calculated based on Segment Height H and Pipe Diameter D Segment Height H <...
Page 207 Note: Next Screen summarizes all the Flow configurations under Summary page. User can review the parameters and edit if needed by going back to the Flow Configuration Screen/s before selecting the "Finish" button. Once the "Finish" button is selected, all the Flow Configurations will be written to the device.
Page 208: Figure 22 - Typical Volumetric Flow Range Setting Values
PV4 (Flow) Upper Range Limit (URL) and Range Values (LRV and URV) Set the URL, LRV, and URV for calculated flow rate PV4 output by typing in the desired values on the FlowConf tab card. • URL = Type in the maximum range limit that is applicable for your process conditions. (100,000 = default) •...
Page 209: Figure 23 - Low Flow Cutoff Action
Low Flow Cutoff for PV4 For calculated flow rate (PV4), set low and high cutoff limits between 0 and 30% of Upper Range Limit for PV4 in engineering units. • Low Flow Cutoff: Low (0.0 = default) High (0.0 = default) Background You can set low and high low flow cutoff limits for the transmitter output based on the calculated variable PV4.
Page 210: Saving The Current Online Configuration As Offline Dataset
Saving the current Online Configuration as Offline dataset While in Offline parameterization select Load from Device from the Menu. All the current online parameter values will be set to the Offline dataset. User can export the parameters to an xml file. User can also edit the parameters before exporting to the file. Import Export SMV800 Series HART/DE Option User’s Manual...
Page 211: Smv800 Offline Parameterization
SMV800 Offline Parameterization On selecting Parameter/ Parameterization, the Offline parameter configuration page will be displayed. User can start with a new Offline Configuration from scratch or import from any file from existing Offline Configuration files that have been exported/saved previously. Select Parameter/Parameterization.
Page 212: Comparison Of Configuration Options From Dd Host Vs Dtm
12 Comparison of configuration options from DD host vs DTM Table 45 – Flow Parameters Parameters related to selected DD based Tool DTM based Tool Liquid  Manual entry Automatic Calculation Viscosity coefficients,  Density coefficients,  Visc Coefficient Temperature limits default ...
Page 213: Flow Engineering Units Configuration For Smv800 Hart And De
13 Flow Engineering Units Configuration for SMV800 HART and DE SMV800 HART configuration using Pactware: For Standard Flow Condition (Temperature: 15 °C, Pressure: 1.01325 barA):  Use the HART DTM. Go Online.  Select Advanced flow setup / Unit Configuration ...
Page 214 SMV800 Series HART/DE Option User’s Manual Page 202 Revision 6.0...
Page 215: For Normal Flow Condition (Temperature: 0 °C, Pressure: 1.01325 Bara)
For Normal Flow Condition (Temperature: 0 °C, Pressure: 1.01325 barA):  Advanced flow setup/Unit Configuration  Select Unit Selection: Custom units  Select Flow Unit: Cubic meters per hour (m3/hr)  Select Next  Select Flow Output Type: Ideal Gas Actual volume ...
Page 216: Smv800 De Configuration Using Sct3000
SMV800 DE Configuration using SCT3000 For Standard Flow Condition (Temperature: 15 °C, Pressure: 1.01325 barA):  Launch SCT3000 Tool  Go Online  Select FlowAlg Tab  Select Algorithm: Ideal Gas Actual Vol Flow @ Std Cond For Normal Flow Condition (Temperature: 0 °C, Pressure: 1.01325 barA): ...
Page 217: User Defined Custom Units Selection On Smv 800 De Model
Units list continued in the below screen User can select m3/hr or Nm3/hr to reflect the Flow unit label as Standard or Normal Flow condition to match the Flow Algorithm selected. User defined Custom Units selection on SMV 800 DE Model. Custom units are allowed in SCT3000 tool for SMV800: SMV800 Series HART/DE Option User’s Manual Revision 6.0...
Page 218 Select Flow Alg/Units Mode: Custom Units Under Custom Tag: user can enter any units with 8 characters based on the Primary Element Data Sheet. Under FlowConfig Tab, user selected Custom Units Tag is shown under limits and Range parameters. KUser Factor is used for Engineering unit conversion for Custom Units. When not using the Wizard, user manually enters the KUser factor.
Page 219: Example Configuration Of Flow For Below Specification
14 Example Configuration of Flow for below specification: Example:  SMG810  Reference Temperature of 25 C (77  Dynamic compensation  Applicable standards and installations per ASME MFC 3M or ISO 5167-1 for Uncalibrated Orifice; Bigger than 2.8Inch Pipe Diameter ...
Page 220 SP 4500, DP 400, Temp 850 Advanced Flow Setup/Tab5 Check Manual input (Temperature) ON, enter Temperature Deg C Sim PT Advanced Flow Setup/Tab4 Check Manual input (Expansion Factor_Y) ON, enter Expansion Factor_Y Manual Y Advanced Flow Setup/Tab3 Check Manual input (Density) ON, enter Density lbm/ft3 Manual Density...
Page 221 Input values: SP 4500, DP 400, Parameters in DTM Units Parameters Temp 850 Advanced Flow Setup/Tab3/Design Values/ Design Density lbm/ft3 Design density lbm/ft3 Calculated Density 81.00216908 Calculated Flow Values w Auto Density lb/sec Mass Flow 168.7497012 ft3/esc Vol flow 2.083273856 ft3/sec Std Vol flow 168.7497012...
Page 222 Steps: 1. Select the Advanced Flow Setup Tab. Setup the desired Unit for the Flow related parameters: SMV800 Series HART/DE Option User’s Manual Page 210 Revision 6.0...
Page 223: Figure 24 - Engineering Unitstab
Figure 24 - Engineering Units Tab SMV800 Series HART/DE Option User’s Manual Revision 6.0 Page 211...
Page 224: Figure 25- Flow Calculation Setup Tab
2. Select the Algorithm Options as below, select Next Figure 25- Flow calculation setup tab 3. Select the Input types for various parameters, turn on/off Simulation as needed Figure 26 - Coefficients and switches SMV800 Series HART/DE Option User’s Manual Page 212 Revision 6.0...
Page 225: Figure 27 - Simulation Tab
Figure 27 - Simulation tab 4. Select Density, Viscosity parameter choices, Design and Reference values Figure 28 - Fluid data SMV800 Series HART/DE Option User’s Manual Revision 6.0 Page 213...
Page 226: Figure 29 - Flow Calculation Setup
5. Select the Pipe / Bore diameters and other parameters Figure 29 - Flow calculation setup 6. Review your configurations on the Summary page Figure 30- Summary page 7. Select Finish. Flow configuration will be sent to the device. Check the Process variables by selecting the Process Variables tab.
Page 227: 15 Hart Dd Binary File Format Compatibility Matrix
15 HART DD binary file format compatibility matrix Table 47 - HART DD binary file format compatibility matrix "Host - SMV800 - HART DD binary file format" compatibility matrix Host DD file format to be used Experion R410 Experion R400 to R300 Experion below R300 FDM R440 and above Refer the respective Tools’...
Page 228: 16 Security
Honeywell investigates all reports of security vulnerabilities affecting Honeywell products and services. To report potential security vulnerability against any Honeywell product, please follow the instructions at: https://honeywell.com/pages/vulnerabilityreporting.aspx Submit the requested information to Honeywell using one of the following methods: •...
Page 229: 17 Troubleshooting
17 Troubleshooting Diagnostic Messages for DE transmitters The diagnostic text messages that can be displayed on the SCT, SFC Diagnostic Messages or on a TPS/TDC system are listed in the following tables. A description of the probable cause and suggested action to be taken are listed also to help in troubleshooting error conditions.
Page 230: Table 49 - Critical Status Diagnostic Message Table
DE Diagnostic Messages, Continued Table 48 - Critical Status Diagnostic Message Table SMV Status SCT Status Message SFC Display Message TDC Status Message Possible Cause What to Do STATUS A/D FAILURE PV3 • Cycle transmitter power T A G I D . A/D Failure PV3 A/D circuit for PV3 input has failed.
Page 231 DE Diagnostic Messages, Critical Status Diagnostic Message Table, Continued Continued SMV Status SCT Status Message SFC Display Message TDC Status Message Possible Cause What to Do M. B. OVERLOAD OR • Wait for PV1 and PV2 range to return STATUS T A G I D .
Page 232 DE Diagnostic Messages, Critical Status Diagnostic Message Table, Continued Continued SMV Status SCT Status Message SFC Display Message TDC Status Message Possible Cause What to Do OUTP 1 PV3 Input data seems wrong. • Cycle transmitter power OFF/ON. T A G I D . Input Suspect PV3 Sensor reading is extremely SUSPCT INPUT PV3...
Page 233: Table 50 - Non-Critical Status Diagnostic Message Table
DE Diagnostic Messages, Continued Table 49 - Non-Critical Status Diagnostic Message Table SMV Status SCT Status Message SFC Display Message TDC Status Message Possible Cause What to Do BAD AP COMP PV4 STATUS • Verify that absolute/gauge T A G I D . Bad AP Compensation Problem with absolute/gauge pressure input PV2 or input...
Page 234 DE Diagnostic Messages, Non-Critical Status Diagnostic Message Table , continued continued SMV Status SCT Status Message SFC Display Message TDC Status Message Possible Cause What to Do STATUS 3- 6 Density temperature or Either the temperature (PV3) or Check to see if the PV pressure out of range the pressure (PV2) is not within measurement is correct.
Page 235 DE Diagnostic Messages, Non-Critical Status Diagnostic Message Table , continued continued SMV Status SCT Status Message SFC Display Message TDC Status Message Possible Cause What to Do STATUS Excess Zero Correct T A G I D . EX . ZERO COR PV1 ZERO correction factor is outside •...
Page 236 DE Diagnostic Messages, Non-Critical Status Diagnostic Message Table , continued continued SMV Status SCT Status Message SFC Display Message TDC Status Message Possible Cause What to Do INPUT MODE PV2 Input Mode PV2 (AP) STATUS T A G I D . Transmitter is simulating input Exit Input mode: for PV2.
Page 237 DE Diagnostic Messages, Non-Critical Status Diagnostic Message Table , Continued continued SMV Status SCT Status Message SFC Display Message TDC Status Message Possible Cause What to Do OUTPUT MODE PV1 Output Mode PV1 (DP) STATUS T A G I D . Analog transmitter is operating as Exit Output Mode: a current source for PV1 output.
Page 238 DE Diagnostic Messages, Non-Critical Status Diagnostic Message Table , Continued continued SMV Status SCT Status Message SFC Display Message TDC Status Message Possible Cause What to Do STATUS 9-7 • Verify high or low Reynolds Reynolds Number is Out The high or low Reynolds number of Range limit was exceeded.
Page 239: Table 51 - Communication Status Message Table
DE Diagnostic Messages, Table 50 Communication Status Message Table SMV Status SCT Status Message SFC Display Message TDC Status Message Possible Cause What to Do Command Aborted T A G N O . Communications aborted. Retry aborted operation. COMM ABORTED SFC –...
Page 240 DE Diagnostic Messages, continued Communication Status Message Table , continued SMV Status SCT Status Message SFC Display Message TDC Status Message Possible Cause What to Do STATUS Transmitter sent a negative Check configuration and try again. T A G I D . response because it could not NACK RESPONSE process one or more commands.
Page 241: Table 52 - Information Message Table
DE Diagnostic Messages, continued Table 51 - Information Message Table SFC Display TDC Status SMV Status SCT Status Message Possible Cause What to Do Message Message STATUS 2 WIRE TC PV3 Nothing – Information only. However, this may 2 Wire TC PV3 PV3 input is being provided by 2-wire indicate a problem if sensor type does not...
Page 242: Table 53 - Sfc Diagnostic Message Table
DE Diagnostic Messages, continued Table 52 - SFC Diagnostic Message Table SMV Status SCT Status Message SFC Display Message TDC Status Message Possible Cause What to Do ALGPARM Kuser Applicable PV4 algorithm Enter and download desired parameter is set to default value of value to transmitter database.
Page 243 Screen Number Failed - If there is no Display on the No Display present on this device No Response from device, this is expected or Display is not connected Device. Error Code message from the device. properly (105). If the display is present, then make sure that the display is plugged in correctly, no missed pins or no loose connections...
Page 244: Hart Diagnostic Messages
HART Diagnostic Messages lists and describes the HART critical and non-critical HART diagnostic details. Table 53 Table 58 Table 53 – HART Critical Details Additional Status (When a Critical Device HART Status is set, one or more Display DD/DTM of the following statuses Details/Resolutions Status Tools...
Page 245 SPI Failure The inter-processor communications section (SPI) of the Electronics module has a critical failure and the module cannot communicate to the other modules within the device. Resolution: Comm Module Reset the device. If problem persists, Comm Module DAC Failure replace the Electronics Module.
Page 246 Communication: RAM Failure Electronics module is reporting corruption in the Random Access Memory (RAM) Resolution: Reset the device. If the problem persists, replace the Electronics Module. ROM Failure Electronics module is reporting corruption in the Read-only Memory (ROM) SIL Diagn Comm Module Failure Resolution:...
Page 247 Temperature: Sensor NVM Corrupt Temperature module is reporting corruption of the Non-Volatile Memory data (NVM ) Resolution: Reset the device. If the problem persists, replace the Temperature Module. Sensor Char CRC Temperature module is reporting Failure corruption in the temperature Characterization data Resolution: Reset the device.
Page 248 Temperature: Sensor Bad Temperature module is detecting an issue with the process temperature sensor input. The temperature sensor input may be out of range for the sensor type or the input may be open. Resolution: Sensor Critical Check the temperature sensor. If the Failure sensor has failed, replace the sensor.
Page 249 Pressure: Meter Body Failure Pressure module is reporting a critical failure of the pressure sensing measurement within the Meter Body, which may be caused by one of the following:  Meter body failure  Sensor communication timeout  Sensor firmware flow failure Resolution: Reset the device.
Page 250 Bad DP The Differential Pressure input measurement is far outside the specified range. The meter body may be damaged. Resolution: Reset the device. If the problem persists, replace the Meter body. Bad MBT The Meter body Temperature measurement is far outside the specified range.
Page 251: Table 54 - Non-Critical 1 Diagnostic Details
Table 54 - Non-Critical 1 Diagnostic Details Additional Status (When a Non-Critical HART Device Status is set, one or Display DD/DTM more of the following Details/Resolutions Status Tools statuses will be set in the Additional Status menu to Device Status provide clarification of the cause of the failure) Display:...
Page 252 DAC Failure: One or more The temperature measured in the Communications module has exceeded 100C, which exceeds the specification for this device. The module is in danger of Temp Above 100C being damaged. Temp Cal Resolution: Correct Verify the environmental temperature is DP Zero within specifications for the device.
Page 253 The second Analog to Digital Converter (ADC) parts in the Temperature module is not operating correctly. The process temperature measurement may be Temp ADC1 Range affected. Failure Resolution: Reset the device. If the problem persists, replace the Temperature module. The Process Temperature input exceeds the Temperature Upper Range Limit (URL) as determined by the configured Sensor Type.
Page 254 The DP and/or SP pressure URV correction performed by the user is excessive for the given inputs. Resolution: Perform a Reset Corrects on the DP Excess Span Correction and/or SP Pressure Calibration to reset the User calibration to factory default. If One or more required, repeat the Pressure calibrations being careful to ensure that input during...
Page 255 The process input mapped as Primary Variable (PV) is outside of the specified range (LTL to UTL) Resolution: Check the range specifications and, if PV Out of PV Out of required, replace transmitter with one Range Range that has a more suitable range. For Pressure as Primary Variable, Meter Body may have been damaged.
Page 256: Table 55 - Non-Critical 2 Diagnostic Details
Table 55 - Non-Critical 2 Diagnostic Details Additional Status HART (When a Non-Critical Device Status is set, one or more of Display DD/DTM Details/Resolutions the following statuses will be Status Tools set in the Additional Status Device Status menu to provide clarification of the cause of the failure) SET LRV operation using external Zero button was rejected.
Page 257 Pressure: Either the transmitter is installed in a noisy environment or internal Sensor communication quality between the Meter Body Unreliable Electronics Module and Pressure Comm Press Unreliable Comm Comm Sensor is degrading. Resolution: Call service person. Device is in Write Protect Mode and the user tried to change one or more of the parameters.
Page 258 Temperature: The supply voltage to the Temperature Sensing section in the Temperature module is low. Resolution: Check that the power supply and loop Low Sensor Supply resistance are within specification. If possible, try to increase the voltage level of the supply. If supply voltage and loop resistance are adequate and the problem persists, replace the Temperature module.
Page 259: Table 56 - Non-Critical 3 Diagnostic Details
Table 56 - Non-Critical 3 Diagnostic Details Additional Status HART (When a Non-Critical Device DD/DTM Status is set, one or more of Display Tools Details/Resolutions the following statuses will be Status set in the Additional Status Device menu to provide clarification Status of the cause of the failure) Temperature:...
Page 260 Flow: Simulation mode is enabled for the Differential Pressure process input. Simulation mode simplifies testing of flow calculations prior to online operation. DP Simulation DP Simulation Mode Resolution: While conducting testing, the status indicates that simulation is being used. When testing is completed, clear the simulation mode for the inputs to return to true process measurement.
Page 261 Flow / Totalizer: During setup and configuration of the flow algorithm parameters, insufficient configuration or invalid parameter values have been entered which are causing a division by zero math error in the flow calculation Resolution: Carefully review the flow algorithm parameter values that have been configured.
Page 262 During setup and configuration of the flow algorithm parameters, insufficient configuration or invalid parameter values have been entered which are causing a square root of a negative value math error in the flow calculation SqRt of Negative/ Flow Sqrt of Flow bad / Totalizer Resolution: Carefully review the flow algorithm parameter...
Page 263: Table 57 - Non-Critical 4 Diagnostic Details
Table 57 - Non-Critical 4 Diagnostic Details Additional Status HART (When a Non-Critical DD/DTM Device Status is set, one or more of the following Tools Details/Resolutions statuses will be set in the Device Additional Status menu to Status provide clarification of the cause of the failure) The Flow Totalizer is mapped to PV and is Totalizer...
Page 264: Flow Configuration Diagnostics, Messages And Values
Flow Configuration Diagnostics, Messages and Values Tool Diagnostics / (DD Host / Details/Resolutions message DTM Host ) Possible causes: After performing full Flow Configuration using DTM or 475, user has Method switched to use a DD based tool and invokes the Flow Internal DD Host Configuration method again.
Page 265 Tool Diagnostics / (DD Host / Details/Resolutions message DTM Host ) 2. Check if Flow Output is set to "No Flow Output". If Flow Calculation is expected then set the Flow output type to Volume or Mass Flow type. 3. If Reverse Flow is expected and if 'Reverse Flow Calculation' configuration is OFF, set this configuration to ON.
Page 266 Tool Diagnostics / message (DD Host / Details/Resolutions DTM Host ) Possible scenario:  Comm Vcc failure can happen without any other failures when the User has older Temperature Sensor board (Terminal module) that does not have the Vcc regulation mechanism at low and high current conditions that goes to the communication board.
Page 267 Tool (DD Host / Diagnostics / message Details/Resolutions DTM Host ) During “Store To Device” Factory Cal available setting in Offline operation (Offline download), configuration should match with what is in the Screen appears with the device. Say Device has Factory CAL A, and you messages below: are trying to download Factory CAL A&B from Download Failed...
Page 268 Tool Diagnostics / message (DD Host / Details/Resolutions DTM Host ) Field Device Specific Error Communication Timeout between 2 sensors, (CMD: xxxxx RC: 6) Display and communication module. Resolution: Set the HART DTM Communication port settings as shown below: Right click on the Communication Port, select Disconnect if it is in Connect state.
Page 269 Appendix A. Custom Configuration sheets For detailed information on configuration dependencies please refer to The SmartLine Multivariable Configuration sheet, #34-SM-00-06 on the CD or can be located on our web site at: https://www.honeywellprocess.com/en-US/explore/products/instrumentation/pressure-transmitters/smart- multivariable-transmitters/Pages/default.aspx SMV800 Series HART/DE Option User’s Manual Page 257 Revision 6.0...
Page 270 SMV800 Series HART/DE Option User’s Manual Page 258 Revision 6.0...
Page 271 SMV800 Series HART/DE Option User’s Manual Revision 6.0 Page 259...
Page 272 SMV800 Series HART/DE Option User’s Manual Page 260 Revision 6.0...
Page 273 SMV800 Series HART/DE Option User’s Manual Revision 6.0 Page 261...
Page 274 SMV800 Series HART/DE Option User’s Manual Page 262 Revision 6.0...
Page 275 SMV800 Series HART/DE Option User’s Manual Revision 6.0 Page 263...
Page 276 SMV800 Series HART/DE Option User’s Manual Page 264 Revision 6.0...
Page 277 SMV800 Series HART/DE Option User’s Manual Revision 6.0 Page 265...
Page 278 SMV800 Series HART/DE Option User’s Manual Page 266 Revision 6.0...
Page 279 SMV800 Series HART/DE Option User’s Manual Revision 6.0 Page 267...
Page 280 SMV800 Series HART/DE Option User’s Manual Page 268 Revision 6.0...
Page 281 SMV800 Series HART/DE Option User’s Manual Revision 6.0 Page 269...
Page 282 SMV800 Series HART/DE Option User’s Manual Page 270 Revision 6.0...
Page 283 SMV800 Series HART/DE Option User’s Manual Revision 6.0 Page 271...
Page 284 SMV800 Series HART/DE Option User’s Manual Page 272 Revision 6.0...
Page 285 SMV800 Series HART/DE Option User’s Manual Revision 6.0 Page 273...
Page 286 Appendix B — PV4 Flow Variable Equations B1 Overview Appendix Contents This appendix includes these topics: B.1 Overview ………………………………………….. ……….274 B.2 Standard Flow Equation …………………………………. 275 B.3 Dynamic Compensation Flow Equation …………………279 Purpose of this appendix This appendix gives a brief description on the use of the available flow equations for calculating the SMV 3000’s PV4 flow variable.
Page 287 B.2 Standard Flow Equation The Standard Flow Equation (Kuser Model) allows automatic calculation of the Kuser value that is used to configure PV4 flow variable for SMV 3000. The Kuser value is a scaling factor, based on the dynamics of your process, which is used to adjust the flow rate to the desired process parameters, such as dimensional units density...
Page 288: Table 59 - Air Through A Venturi Meter Configuration Example
Table 59 - Air Through a Venturi Meter Configuration Example Step Action Select a template for the SMV 3000 model you have for your flow application. Select standard volume flow in the Algorithm field of the FlowAlg tab and then select the Engineering Units (CFM) on the FlowConf tab card.
Page 289: Table 60 - Superheated Steam Using An Averaging Pitot Tube Configuration Example
The calculated Kuser value appears on the Solutions page of the Kuser Model along with a list of items (with values) that you have configured from previous pages. Review the Wizard values to make sure they are correct. Click Finish to complete the Kuser calculation procedure. Connect SCT to SMV and establish communications.
Page 290 Enter the relevant flow process data from the Averaging Pitot Tube Sizing Data Sheet into the appropriate entry fields on the Process Data page as follows: Normal Flowrate = 45,000 lb/hr Normal DP = 13.21 inches H O @ 39.2 °F Design Density = 0.49659 lbs/ft You can change the engineering units by clicking on the text box with...
Page 291 B.3 Dynamic Compensation Flow Equation Dynamic Compensation Flow Equation The Dynamic Compensation Flow Equation provides algorithms for use in determining a highly accurate PV4 flow variable for SMV 3000. Use dynamic compensation to measure liquids, gases, and steam. Dynamic compensation flow equation compensates for: temperature pressure density...
Page 292: Table 61 - Liquid Propane Configuration Example
Table 61 - Liquid Propane Configuration Example Step Action Select a template for the SMV 3000 model you have for your flow application. Select mass flow in the Algorithm field of the FlowAlg tab and then select the Engineering Units (lb/m) on the FlowConf tab card. Click the Wizard on the SCT/SMV 3000 configuration window to access the Flow Compensation Wizard Equation Model page.
Page 293 Enter the following lower and upper Reynolds number limits in each entry field of the Discharge Coefficient page. These values are used to clamp the discharge coefficient equation at these Reynolds numbers: Lower Limit = 80,000 Upper Limit = 800,000 Click to proceed to the Viscosity Compensation page.
Page 294 Click on the following options for Failsafe Indication on the Flowing Variables page (so that there is an “ ” in each check box). It has been determined that the operator needs the flow output to go to failsafe when there is either a pressure or temperature failure (selecting Abs.
Page 295: Table 62 - Air Configuration Example
Table 62 - Air Configuration Example Step Action Select a template for the SMV 3000 model you have for your flow application. Select Standard Volumetric flow in the Algorithm field of the FlowAlg tab and then select the Engineering Units (CFM) on the FlowConf tab card.
Page 296 Enter the following lower and upper Reynolds number limits in each entry field of the Discharge Coefficient page. These values are used to clamp the discharge coefficient equation at these Reynolds numbers: Lower Limit = 10,000 Upper Limit = 100,000 ...
Page 297 Click on the following options for Failsafe Indication on the Flowing “ ” Variables page (so that there is an in each check box). It has been determined that the operator needs the flow output to go to failsafe when there is either a pressure or temperature failure (selecting Abs.
Page 298: Table 63 - Superheated Steam Configuration Example
SMV Operation in a Steam Application SMV Operation in a When operating the SMV in a steam application there are number of considerations you should be aware of:  Be sure the process is at or above saturation when operating the SMV, since the SMV does not calculate flow when the process is below saturation.
Page 299 Select the fluid state as Steam from the list on the Fluid State page, then click Next proceed to the Pipe Properties page. Enter the relevant information from the Orifice Sizing Data Sheet in each entry field of the Pipe Properties page: Pipe Schedule = 40s Nominal diameter...
Page 300 Click on the following options for Failsafe Indication on the Flowing Variables page (so that there is an “ ” in each check box). It has been determined that the operator needs the flow output to go to failsafe when there is either a pressure or temperature failure (selecting Abs.
Page 301: Glossary
Glossary American Wire Gauge Differential Pressure Digital Enhanced Communications Mode EEPROM Electrically Erasable Programmable Read Only Memory Electromagnetic Interference Field Device Configurator Field Termination Assembly HART Highway Addressable Remote Transmitter HART Communication Foundation Hertz Inches of Water Low Pressure (also, Low Pressure side of a Differential Pressure Transmitter) Lower Range Limit Lower Range Value mAdc...
Page 302 INDEX About This Manual ............iii Field Device Configurator ..........53 Advanced Flow Setup ..........166 aving device history ..........128 Advanced Flow Setup (for DTM only) ..64, 161, 163 Custom Views ............130 AP Input Calibaration ..........145 Exporting device history records to Documint ..
Page 303 Optional 3-Button Assembly ........... 5 TempConf Configuration - PV3 ........31 Output Calibration using SCT3000 ......137 Temperature Input Calibaration ......... 147 Transmitter Adjustments ..........4 Troubleshooting ............217 Troubleshooting and Maintenance ......158 Process Data ............... 175 Using DTMs ..............159 Downloads .............
Page 304 Phone: +(822) 799 6114 Fax: +(822) 792 9015 For more information To learn more about SmartLine Transmitters, visit www.honeywellprocess.com Or contact your Honeywell Account Manager Process Solutions Honeywell 1250 W Sam Houston Pkwy S Houston, TX 77042 Honeywell Control Systems Ltd...

Honeywell SmartLine Multivariable SMV800 Series User Manual

Quick Links

Troubleshooting

Related Manuals for Honeywell SmartLine Multivariable SMV800 Series

Summary of Contents for Honeywell SmartLine Multivariable SMV800 Series

Table of Contents