software im (foundation fieldbus) rotamass ti coriolis mass flow … · 2020-01-08 · this device...

User's Manual

IM 01U10S02-00EN-R

IM 01U10S02-00EN-R, 2nd edition, 2019-12-09

ROTAMASS Total InsightCoriolis Mass Flow and Density MeterSoftware Instruction ManualFOUNDATION Fieldbus

Table of contents

2 / 544 IM 01U10S02-00EN-R, 2nd edition, 2019-12-09

Table of contents1 Introduction................................................................................................................................................ 8

1.1 Scope of application ......................................................................................................................... 81.2 Contact information........................................................................................................................... 81.3 Starting conditions ............................................................................................................................ 8

2 Functions of transmitter and configuration example ............................................................................ 102.1 Functions of transmitter .................................................................................................................... 10

2.1.1 Measuring function............................................................................................................... 102.1.2 Display function.................................................................................................................... 102.1.3 Signal IO function................................................................................................................. 102.1.4 Totalizer ............................................................................................................................... 102.1.5 Event management.............................................................................................................. 102.1.6 Backup and restore.............................................................................................................. 112.1.7 Diagnosis ............................................................................................................................. 11

3 Operating options...................................................................................................................................... 123.1 Display .............................................................................................................................................. 123.2 Fieldbus communication getting started ........................................................................................... 15

3.2.1 Outline.................................................................................................................................. 153.2.2 Internal structure of Rotamass TI: Function block ............................................................... 153.2.3 Logical structure of each block ............................................................................................ 163.2.4 Wiring system configuration................................................................................................. 173.2.5 Connection of Devices ......................................................................................................... 173.2.6 Host Setting ......................................................................................................................... 183.2.7 Bus Power ON ..................................................................................................................... 193.2.8 Integration of DD.................................................................................................................. 203.2.9 Reading the Parameters ...................................................................................................... 213.2.10 Continuous Record of Values .............................................................................................. 213.2.11 Generation of Alarm............................................................................................................. 21

3.3 Fieldbus communication configuration ............................................................................................. 213.3.1 Outline.................................................................................................................................. 213.3.2 Network Design.................................................................................................................... 223.3.3 Network Definition................................................................................................................ 223.3.4 Definition of Combining Function Blocks ............................................................................. 233.3.5 Setting of Tags and Addresses............................................................................................ 253.3.6 Communication Setting........................................................................................................ 263.3.7 Block Setting ........................................................................................................................ 29

Link Object ...................................................................................................................... 29Trend Object ................................................................................................................... 29View Object ..................................................................................................................... 30

3.4 microSD card .................................................................................................................................... 55

4 System configuration and operation ....................................................................................................... 564.1 Operation level.................................................................................................................................. 56

4.1.1 Select operation level........................................................................................................... 564.2 Measuring function ........................................................................................................................... 574.3 Pulse/Frequency signal output ......................................................................................................... 624.4 Totalizer ............................................................................................................................................ 65

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IM 01U10S02-00EN-R, 2nd edition, 2019-12-09 3 / 544

4.5 Easy setup wizard............................................................................................................................. 664.5.1 Installation configuration ...................................................................................................... 674.5.2 Standard device variables.................................................................................................... 70

Configure Standard device variables .............................................................................. 704.5.3 Pulse/Frequency output ....................................................................................................... 71

Configure Pulse/Frequency output.................................................................................. 71Configure Single Pulse and Frequency output................................................................ 71

4.5.4 Totalizer ............................................................................................................................... 74Configure Totalizer.......................................................................................................... 74

4.5.5 Display select ....................................................................................................................... 75Configure Display select ................................................................................................. 75

4.5.6 Date/Time ............................................................................................................................ 76Configure Date/Time ....................................................................................................... 76

4.6 Event management........................................................................................................................... 784.6.1 Event setting ........................................................................................................................ 784.6.2 Event history ........................................................................................................................ 79

Call up Event history menu ............................................................................................. 794.6.3 Monitoring history................................................................................................................. 794.6.4 Data logging......................................................................................................................... 82

Set data logging functions............................................................................................... 82Enable Additional function menu..................................................................................... 82Show trend charts on main display ................................................................................. 83

4.6.5 Possible events and related settings and behavior.............................................................. 83System alarms ................................................................................................................ 84Process alarms ............................................................................................................... 85Setting alarms ................................................................................................................. 86Warnings ......................................................................................................................... 88Information ...................................................................................................................... 89

4.6.6 Change log........................................................................................................................... 894.7 Backup and restore........................................................................................................................... 90

4.7.1 Backup ................................................................................................................................. 904.7.2 Restore ................................................................................................................................ 91

4.8 Concentration and petroleum measurement .................................................................................... 934.8.1 Standard concentration calculation...................................................................................... 934.8.2 Advanced concentration calculation .................................................................................... 954.8.3 Net Oil Computing (NOC), Gas Void Fraction (GVF)........................................................... 95

Calculation of oil density ................................................................................................. 98Calculation of water density ............................................................................................ 98Calculation of Net Oil .................................................................................................... 100

4.9 Diagnosis .......................................................................................................................................... 1034.9.1 Slug detection ...................................................................................................................... 1034.9.2 Empty pipe detection ........................................................................................................... 1044.9.3 Corrosion detection.............................................................................................................. 1044.9.4 Tube health check................................................................................................................ 105

Principle of the function................................................................................................. 105Recommended conditions when performing this function............................................. 105Before first use – Getting reference value..................................................................... 105Performing a tube health check .................................................................................... 106

4.10 Explanation of basic items on Analog input Function Block ............................................................. 109

Table of contents


5 Menu description....................................................................................................................................... 1155.1 Language.......................................................................................................................................... 1185.2 Process variables ............................................................................................................................. 119

5.2.1 Device variables................................................................................................................... 1195.2.2 Sensor and transmitter......................................................................................................... 120

5.3 Diag/Service ..................................................................................................................................... 1215.3.1 Status/Self test ..................................................................................................................... 122

Detailed device status ................................................................................................... 122Event history ................................................................................................................. 126

5.3.2 Time stamp .......................................................................................................................... 1275.3.3 Output test ........................................................................................................................... 1275.3.4 Display indication ................................................................................................................. 1295.3.5 Autozero............................................................................................................................... 1305.3.6 Alarm/Event behavior settings ............................................................................................. 132

Alarm/Event additional parameters ............................................................................... 132Process alarms ............................................................................................................. 132Standard diagnostics..................................................................................................... 132Warnings/Information .................................................................................................... 134Event setting lock status ............................................................................................... 137

5.3.7 Standard diagnostics ........................................................................................................... 138Slug detection ............................................................................................................... 138Empty pipe detection..................................................................................................... 140Corrosion detection ....................................................................................................... 141Tube leakage detection................................................................................................. 142

5.3.8 Total health check................................................................................................................ 144Total health check ......................................................................................................... 144Tube health check......................................................................................................... 144

5.3.9 Data logging......................................................................................................................... 1575.3.10 Parameter backup/restore ................................................................................................... 1615.3.11 Calibration date.................................................................................................................... 164

5.4 Easy setup wizard............................................................................................................................. 1655.4.1 Installation configuration ...................................................................................................... 1665.4.2 Standard device variables.................................................................................................... 168

Mass flow ...................................................................................................................... 168Density .......................................................................................................................... 170Temperature.................................................................................................................. 172Volume flow................................................................................................................... 173

5.4.3 Pulse/Frequency output ....................................................................................................... 176Pulse/Frequency configuration...................................................................................... 176Pulse output .................................................................................................................. 176Frequency output .......................................................................................................... 182

5.4.4 Totalizer ............................................................................................................................... 184Totalizer 1 – 3 ............................................................................................................... 184

5.4.5 Display select ....................................................................................................................... 1885.4.6 Date/Time ............................................................................................................................ 191

5.5 Detailed setup................................................................................................................................... 1925.5.1 Installation configuration ...................................................................................................... 1935.5.2 Process variables................................................................................................................. 195

Primary Value (Mass flow) ............................................................................................ 196

Table of contents


Additional function......................................................................................................... 197Secondary Value (Density) ........................................................................................... 201Additional function......................................................................................................... 202Temperature.................................................................................................................. 205Additional function......................................................................................................... 207Volume flow................................................................................................................... 208Additional function......................................................................................................... 211Pressure........................................................................................................................ 213Additional function......................................................................................................... 214Reference density ......................................................................................................... 216Additional function......................................................................................................... 217Relative density............................................................................................................. 219Additional function......................................................................................................... 222Corrected volume flow .................................................................................................. 223Additional function......................................................................................................... 224Calorific value................................................................................................................ 226Velocity.......................................................................................................................... 227Concentration................................................................................................................ 227Standard concentration set 1 – 4 .................................................................................. 228Additional function......................................................................................................... 231NOC .............................................................................................................................. 232NOC concentration set 1 – 4......................................................................................... 234Net Mass Flow 1 – 2 ..................................................................................................... 238Additional function......................................................................................................... 240Net Volume Flow 1 – 2.................................................................................................. 241Additional function......................................................................................................... 243Net Corrected Volume Flow .......................................................................................... 246Additional function......................................................................................................... 247Viscosity Value.............................................................................................................. 249Additional function......................................................................................................... 250Drive Current................................................................................................................. 251

5.5.3 Pulse/Frequency output ....................................................................................................... 252Pulse output .................................................................................................................. 252Frequency output .......................................................................................................... 257

5.5.4 Totalizer ............................................................................................................................... 260Totalizer 1 – 3 ............................................................................................................... 260Additional function......................................................................................................... 263Total 1 – 3 24 hours ...................................................................................................... 265

5.5.5 Display ................................................................................................................................. 267Display select ................................................................................................................ 267Additional function......................................................................................................... 271Display format ............................................................................................................... 274Additional function......................................................................................................... 280Display operation configuration..................................................................................... 284Additional function......................................................................................................... 286

5.5.6 Date/Time ............................................................................................................................ 2915.5.7 User access configuration.................................................................................................... 2925.5.8 Proving................................................................................................................................. 2935.5.9 Sensor constants ................................................................................................................. 294

Table of contents


Mass flow ...................................................................................................................... 294Density .......................................................................................................................... 295

5.5.10 Device information ............................................................................................................... 296Order information .......................................................................................................... 296Capability information.................................................................................................... 302Version/Number information ......................................................................................... 302Fieldbus information...................................................................................................... 304

5.5.11 Others .................................................................................................................................. 3135.6 microSD ............................................................................................................................................ 315

5.6.1 microSD property ................................................................................................................. 316

6 Troubleshooting ........................................................................................................................................ 318

7 Appendix .................................................................................................................................................... 3267.1 Firmware change log ........................................................................................................................ 3267.2 Parameter list.................................................................................................................................... 326

7.2.1 Resource Block.................................................................................................................... 3267.2.2 Flow Calibration Block ......................................................................................................... 3497.2.3 LTB Indicator Transducer Block........................................................................................... 3717.2.4 Concentration Transducer Block.......................................................................................... 3987.2.5 Maintenance Transducer Block ........................................................................................... 4117.2.6 Advanced Diagnostics Transducer Block ............................................................................ 4427.2.7 Analog Input 1 – 6 Function Block ....................................................................................... 4697.2.8 Integrator 1 – 3 Function Block ............................................................................................ 4807.2.9 Multiple Analog Output Function Block ................................................................................ 485

7.3 Device Information............................................................................................................................ 4897.4 Units of the parameters .................................................................................................................... 4997.5 Units description ............................................................................................................................... 5067.6 Integrator (IT) Block .......................................................................................................................... 511

7.6.1 Schematic Diagram of Integrator Block ............................................................................... 5127.6.2 Input Process Section .......................................................................................................... 512

Determining the Input Value Statuses........................................................................... 513Converting the Rate ...................................................................................................... 513Converting the Accumulation ........................................................................................ 513Determining the Input Flow Direction ............................................................................ 514

7.6.3 Adder ................................................................................................................................... 514Status of Value after Addition........................................................................................ 514Addition ......................................................................................................................... 514

7.6.4 Integrator.............................................................................................................................. 5157.6.5 Output Process .................................................................................................................... 517

Status Determination..................................................................................................... 517Determining the Output Value....................................................................................... 517Mode Handling .............................................................................................................. 518

7.6.6 Reset.................................................................................................................................... 519Reset Trigger ................................................................................................................ 519Reset Timing ................................................................................................................. 519Reset Process............................................................................................................... 519

7.7 Multiple Analog Output (MAO) Block ................................................................................................ 5217.7.1 Function Block Diagram....................................................................................................... 5217.7.2 Block Mode .......................................................................................................................... 522

Table of contents


7.7.3 Fault State............................................................................................................................ 523Transition to Fault State ................................................................................................ 523Clearing a Fault State ................................................................................................... 523Fault State Operation .................................................................................................... 523

7.7.4 Status Transitions ................................................................................................................ 5247.8 Link Master Functions....................................................................................................................... 524

7.8.1 Link Active Scheduler .......................................................................................................... 5247.8.2 Link Master .......................................................................................................................... 5247.8.3 Transfer of LAS.................................................................................................................... 5257.8.4 LM Functions ....................................................................................................................... 5267.8.5 LM Parameters .................................................................................................................... 527

LM Parameter List......................................................................................................... 527Descriptions for LM Parameters.................................................................................... 529FAQ............................................................................................................................... 533

7.9 Software Download........................................................................................................................... 5357.9.1 Benefits of Software Download............................................................................................ 5357.9.2 Specifications....................................................................................................................... 5357.9.3 Preparations for Software Downloading .............................................................................. 5357.9.4 Software Download Sequence............................................................................................. 5367.9.5 Download Files .................................................................................................................... 5377.9.6 Steps after Activating a Field Device ................................................................................... 5377.9.7 Troubleshooting ................................................................................................................... 5387.9.8 Maintenance Transducer Block’s Parameters Relating to Software Download................... 5387.9.9 System/Network Management VFD Parameters Relating to Software Download............... 5407.9.10 Comments on System/Network Management VFD Parameters Relating to Software

Download .............................................................................................................................541

Software Instruction Manual FOUNDATION FieldbusIntroduction Scope of application


1 Introduction

1.1 Scope of application

These instructions apply to the following Rotamass Total Insight product families withfieldbus communication function:

▪ Rotamass Nano

▪ Rotamass Supreme

▪ Rotamass Giga

▪ Rotamass Prime

▪ Rotamass Intense

▪ Rotamass Hygienic

▪ Rotamass Total Insight transmitter in combination with any Rotamass Total Insightsensor.

1.2 Contact information

For more information or questions, contact your local Yokogawa sales organization.

Additional information available at http://www.yokogawa.com or on the last page of thisdocument.

1.3 Starting conditions

Installation Before starting to use the device, it has to be installed appropriately and all other configu-rations, such as wiring, have to be configured appropriately. For more information about general recommendations for installations and configurationsrefer to the instruction manual.

Operation level foroperation andconfiguration

To operate or configure the device, the appropriate Operation level has to be set whenthe device is started. To configure the device or change the configuration, Maintenanceor Specialist has to be selected and set as the Operation level. For more information onconfirming the Operation level and possible operations see Operation level [} 56].

Example ofconfigurationprocedure

The following flow chart is an example for configuring the device and starting to use it.For more detailed information refer to the description of each function and parameters. Toconfigure or change parameter, the Operation level has to be set to Maintenance or Spe-cialist and Target mode in RB/TB/FB has to be set to O/S in many parameters.

http://www.yokogawa.com

Starting conditions

Software Instruction Manual FOUNDATION FieldbusIntroduction


Installation: Refer to IM01U10A00-00 -R

or IM 01U10B00-00 -R

Wiring: Refer to IM01U10A00-00 -R

or IM 01U10B00-00 -R

Date/Time configuration[Easy setup wizard/Detailed setup]

Flow direction configurationInstallation orientation

[Easy setup wizard/Detailed setup]

Mass flow configuration[Easy setup wizard/

Detailed setup]Mass flow unitMass flow LRVMass flow URV

Mass flow Ftime (damping)[Detailed setup]

Additional setup, such as low cut,user unit, etc.

Volume flow configuration[Easy setup wizard/

Detailed setup]Volume flow unitVolume flow LRVVolume flow URV

Volume flow Ftime (damping)[Detailed setup]


Density configuration[Easy setup wizard/

Detailed setup]Density unit Density LRVDensity URV

Density Ftime (damping)[Detailed setup]


Target mode setting: O/S mode[Diag/Service / Easy setup wizard / Detailed Setup]

Display configuration[Easy setup wizard/Detailed setup]

Display select 1 – 4[Detailed setup]

Display select 5 – 20Display format

Other configuration[Easy setup wizard/Detailed setup]

Temperature[Detailed setup]

Other process variables[Easy setup wizard/Detailed setup]

Totalizer[Diag/Service]Diagnostics

Total health checkEvent management

Zero adjustment[Diag/Service]

Autozero execute

Operation

Target mode setting: AUTO mode[Diag/Service / Easy setup wizard / Detailed setup]

Software Instruction Manual FOUNDATION FieldbusFunctions of transmitter and configuration example Functions of transmitter


2 Functions of transmitter and configuration example

2.1 Functions of transmitter

2.1.1 Measuring functionThis device can measure mass flow, density and temperature of fluids. Also, volume flow,velocity, calorific value, concentration and net flow can be obtained by calculation. Fordetails of the measuring function see Measuring function [} 57].

2.1.2 Display functionMeasured or calculated process variables, current or total values, are displayed on theLCD display of the Indicator. On the display, status information is also displayed. Formore detailed information see Display [} 12].

2.1.3 Signal IO functionTo output the value of process variables, the device has a Pulse/Frequency output to out-put a pulse or frequency signal for local calibration. Please don't use the function for plantoperation.

The following table shows the available output signals with their corresponding explana-tion and parameter.

Output signal Overview Parameter

Pulse/Frequency output Pulse/Frequency signal out-put [} 62]Pulse/Frequency output [} 257]

2.1.4 TotalizerA maximum of three totalizers can be used in the device to total flow process variables.For more detailed information see Totalizer [} 260].

2.1.5 Event managementEvent management is a function for managing how events, such as alarm, warning interms of categorization, indication, action and behavior, are handled. The user can definethe following actions of the device when an event occurs. For more detailed informationsee Event management [} 78].

Do not use this function for critical or important events.

Configurable options

Action and Behavior

▪ Ignore it

▪ Record it as an event

▪ Start data logging

Functions of transmitter

Software Instruction Manual FOUNDATION FieldbusFunctions of transmitter and configuration example


2.1.6 Backup and restoreThe user configuration can be stored in the device memory or on a microSD card on theIndicator. Stored user configuration can be restored to the same or another device by at-taching the Indicator or microSD to the target device. For more detailed information seeBackup and restore [} 90].

2.1.7 DiagnosisThe device has the following diagnostic functions to perform diagnoses of the device.When any diagnosis detects an abnormal status, an alarm is activated. For more detailedinformation see Diagnosis [} 103] and Troubleshooting [} 318].

Detection Description

Slug detection

Detection of bubble flow. If a bubble or slug occurs in thefluid, the accuracy or ability to measure process variables isnegatively affected. When slug is detected by this function,alarm No.201 is generated. This function is not available forgas measurement.

Empty pipe detectionDetection of empty pipe. When an empty pipe is detected bythis function, alarm No.202 is generated. This function is notavailable for gas measurement.

Corrosion detectionDetection of corrosion in pipe. When corrosion in the pipe isdetected by this function, alarm No.203 is generated. Thisfunction is not available for gas measurement.

Tube health checkHealth check of measuring tube by detecting a change in thespring constant of the measuring tubes. When the valuereaches a user-defined criteria, alarm No.203 is generated.

Software Instruction Manual FOUNDATION FieldbusOperating options Display


3 Operating options

The Rotamass Total Insight can be operated in different ways:

▪ IR switches on the display

▪ Digital communication (e.g. FOUNDATION Fieldbus using FieldMate)

The section below describes how to operate the system using the IR switches on the dis-play.

The display is a device option and therefore not always available.

3.1 Display

All of the functions described here are also available via digital communication. Numericvalues entered using the display are limited to six digits.

The controls on the display are IR switches. They respond as soon as an object, such asa finger, is in close proximity. It is not necessary to apply pressure to the display surface.

Observe the following instructions to ensure that the IR switches are functional:

▶ Keep the display glass clean.▶ Avoid exposure to direct sunlight.▶ To increase the reflectivity of fingers (e.g., if they are very dirty), place some white

tape on the fingertip.▶ If the IR switches do not work properly, remove the finger from the display and try to

push the switch again.

IR switchfunctions

IR switch Display Function

[SET] [SET]

▪ Apply setting

▪ Enter data

▪ Apply parameter

[SHIFT] [SFT]▪ Move cursor right or to the next position

▪ Change function and display of [SET] and [▼]

[▼] [INC]

▪ Increment parameter or value

▪ Change position of decimal point

▪ Select next menu item

The IR switch function changes as follows when used with the [SHIFT] key:

Key combina-tions

Display Function

[SHIFT] + [SET] [ESC] ▪ Cancel and switch to previous menu

[SHIFT] + [▼] [DEC]▪ Decrement parameter or number

▪ Select previous menu item

Status icons Statusicon

Description Statusicon

Description

System alarm tripped Process alarm tripped

Display

Software Instruction Manual FOUNDATION FieldbusOperating options


Statusicon

Description Statusicon

Description

Settings alarm tripped Warning tripped

Write protection disabled Write protection enabled

Device error (no write access) Device busy (no write access)

microSD card ready Access to microSD card

Error accessing microSD card Process variable has bad status

Upload parameter enabled Download parameter enabled

Total health result: good(only indicated when display totalhealth result is active)

Total health result: warning(only indicated when display totalhealth result is active)

Total health result: bad state(only indicated when display totalhealth result is active)

Tube Health Check with result: OK

Tube Health Check with result:warning

Tube Health Check with result: er-ror

Measuredquantities andidentifications

List of measured quantity abbreviations and identification on the display:

Tab. 1: Regular display

Abbreviation Measured quantityMFL Mass flowDNS DensityTMP TemperatureVFL Volume flowRFD Reference densityRLD Relative densityCVF Corrected volume flowPRS PressureTT1 – TT3 Totalizer 1 – 3TAG Customer-specific identification like HART

LTG Customer-specific identification, long ver-sionVEL VelocityCNC ConcentrationNM1 – NM2 Net mass flow rate 1 – 2NV1 – NV2 Net volume flow rate 1 – 2

Software Instruction Manual FOUNDATION FieldbusOperating options Display


Abbreviation Measured quantityNCV Corrected net volume flow rateDRC Driving currentHT1 24hours totalizer 1HT2 24hours totalizer 2HT3 24hours totalizer 3GVF Gas void fractionVSC Viscosity

Applies only to the trend display of logging data on the microSD card. Refer toData logging display [} 157].

Tab. 2: Trend display

Abbreviation Measured quantityMFL Mass flowDNS DensityTMP TemperatureVFL Volume flowPRS PressureCNC ConcentrationNM1 Net mass flow rate 1NV1 Net volume flow rate 1PHS Phase shiftFRQ Resonant frequencyDRG Drive gainDRC Driving currentMBT Transmitter temperature

Display formatLCD

The display format on the LCD can be configured, such as the number of lines, contrast,process variables to be displayed, and display format of each process variable. For moredetailed information see Display [} 267].

Typical configuration parameter DescriptionDisplay Select n Process variable to be displayed on line nDisplay Format process variable Decimal point position for process variableDisplay Contrast Contrast of LCDDisplay Line Number of display lines on LCD

Example of display: configured by parameter Display Line of Display operation configu-ration [} 285].

1line (big) 1line 2line 3line 4line1-line displaywith big fonts,without unit

1-line display ofvalue with unit




Fieldbus communication getting started



3.2 Fieldbus communication getting started

3.2.1 OutlineThe fieldbus protocol is a widely used bi-directional digital communication protocol forfield devices that enable the simultaneous output to many types of data to the processcontrol system.

The transmitter of fieldbus communication type employs the specification standardized byThe Fieldbus Foundation, and provides interoperability between Yokogawa devices andthose produced by other manufacturers. The fieldbus protocol comes with software con-sisting of six AI function blocks that enable the flexible implementation of systems.

For information on other features, engineering, design, construction work, startup andmaintenance of fieldbus, refer to "fieldbus Technical Information" (TI 38K03A01-01E).

3.2.2 Internal structure of Rotamass TI: Function blockThe transmitter contains ten function blocks which share the following functions:

▪ Resource block (RB)– Manages the status of transmitter.– Automatically informs the host of any detected faults or other problems.

▪ Flow Calibration block (FCB)– Converts sensor output to mass flow, density, temperature, volume flow etc. sig-

nals, and transfers to the AI function blocks.– Receives external pressure, temperature or calorific value from the MAO function

block.– Performs Zero adjustement.– Performs Standard diagnostics (Slug/Empty/Corossion detection)– Performs three totalizer function.

▪ LCD Indicator Transducer block (LTB)– Controls the display of the indicator.

▪ Concentration Transducer block (CTB)– Calculates process values to concentration (Standard, Advanced or Net Oil Com-

puting), net mass / volume flow etc. signals, and transfers to the AI functionblocks.

– Stores concentration setting up to 4 sets.

▪ Maintenance Transducer block (MTB)– Controls Pulse/Frequency output for local calibration.– Performs data logging, backup/restore.– Displays device information.

▪ Advanced Diagnostic Transducer block (ADTB)– Performs Tube Health Check.

▪ Analog Input (AI) function block– Conditions raw data from the Transducer block.– Outputs mass flow, density, temperature, volume flow etc. signals setting via the

channel.– Carries out scaling and damping.

▪ Integrator (IT) function block– Executes integrator management of signal from other function block.– Outputs totalized signal.

▪ Multiple Analog Output (MAO) function block

Software Instruction Manual FOUNDATION FieldbusOperating options Fieldbus communication getting started


– Receives different possible values from external connected devices, for more in-formation see Multiple Analog Output Function Block [} 311].

– Transfers the value to FCB.

For detailed description see Parameter list [} 326].

3.2.3 Logical structure of each block

Rotamass TI R0

Out

IT3 Integratorblock

Out

IT2 Integratorblock

Out

IT1 Integratorblock

Out

AI6 functionblock

Out

AI5 functionblock

Out

AI4 functionblock

Out

AI3 functionblock

Out

AI2 functionblock

Out

AI1 functionblock

Blocktag

Parameters

Function block VFD

Link master

Blocktag

Parameters

Blocktag

Parameters

System/network management VFD

PD tag

Node address

Function blockexecution schedule

Blocktag

Parameters

Blocktag

Parameters

Communicationparameters

VCR

Software downloadfunctionIndicator

Sensor

Resource block

LTB

CTB

Blocktag

Parameters

FCB

ADTB

MTB

Blocktag

Parameters

In

MAO functionblock

LCD Transducer Block

Configuration Transducer Block

Flow Calibration Block

Advanced Diagnostic Transducer Block

Maintenance Transducer Block

Inpu

tO

utpu

t

Blocktag

Parameters




3.2.4 Wiring system configurationThe number of devices that can be connected to a single bus and the cable length varydepending on system design. When constructing the systems, both the basic and overalldesign must be carefully considered to achieve optimal performance.

3.2.5 Connection of DevicesThe following objects are required for use with fieldbus devices:

▪ Power supply:A dedicated power supply is required. It is recommended that current capacity be wellover the total value of the maximum current consumed by all devices (including thehost). Conventional DC current cannot be used as is.

▪ Terminator:Two terminators are required. Refer to the supplier for details of terminators that areatttached to the host.

▪ Field devices:Connects the fieldbus communication type Rotamass TI R0. Two or more RotamassTI R0 devices or other devices can be connected.

▪ Host:Used for accessing field devices. A dedicated host (such as DCS) is used for an in-strumentation line while dedicated communication tools are used for experimentalpurposes. For operation of the host, refer to the instrucion manual for each host. Noother details on the host are given in this manual.

▪ Cable:Used for connecting devices. Refer to "Fieldbus Technical Informa-tion" (TI 38K03A01-01E) for details of instrumentation cabling. For laboratory or otherexperimental use, a twisted pair cable 2 – 3 meters in length with a cross section of0.9 mm2 or more and a cycle period of within 5 cm (2 inches) may be used. Termina-tion processing depends on the type of device being deployed. For Rotamass TI R0,use an M4 screw terminal claw. Some hosts require a connector.

Refer to Yokogawa when making arrangements to purchase the recommended equip-ment. Connect the devices as shown in the figure below. Connect the terminators at bothends of the trunk, with a minimum length of the spur laid for connection.

The polarity of signal and power must be maintained.

ROTAMASS TI R0 HOST

Fieldbus power supply

Terminator

Terminator

Fig. 1: Cabling

CAUTIONNo CHECK terminal is used for fieldbus communication Rotamass TI R0.Do not connect the field indicator and check meter.

Before using a fieldbus configuration tool other than the existing host, confirm it does notaffect the loop functionality in which all devices have been already insalled in operation.Disconnect the relevant control loop from the bus if necessary.



CAUTIONConnecting a fieldbus configuration tool to a loop with its existing hostmay cause communication data scrambling resulting in a functional disor-der or a system failure.

The fieldbus is connected with I/O 1 +/-. The Rotamass TI device is 4-wire, thereforepower supply is separated and not provided from fieldbus line.

L/+

N/-

3

1

4

2

8

7

6

5

9

Fig. 2: Terminal for I/O outputs and power supply in transmitter

1 Power supply connection terminals 6 Connection terminals for I/O2 +/-2 Grounding screw in terminal box 7 Connection terminals for I/O3 +/-3 Grounding terminal 8 Connection terminals for I/O4 +/-4 Locking screw 9 WP: Write-protection terminal5 Connection terminals for I/O1 +/-

3.2.6 Host SettingTo activate fieldbus, the following settings are required for the host.

CAUTIONDo not turn off the power immediately after setting. When the parametersare saved to the EEPROM, the redundant processing is executed for an im-provement of reliability. If the power is turned off within 60 seconds afterthe setting is made, the modified parameters are not saved and the settingsmay return to the original values.

Tab. 3: Operation Parameters

Symbol Parameter Description and Setting

V(ST) Slot-Time

Indicates the time necessary for immediate reply of thedevice. Unit of time is in octets (256 ). Set the maximumspecification for all devices. For Rotamass TI R0, set avalue of 4 or greater.

V(MID) Minimum-Inter-PDU-Delay

Minimum value of communication data intervals. Unit oftime is in octets (256 ). Set the maximum specification forall devices. For Rotamass TI R0, set a value of 4 orgreater.

V(MRD) Maximum-Reply-De-lay

The worst case time elapsed until a reply is recorded.The unit is Slottime; set the value so that V (MRD) x V(ST) is the maximum value of the specification for all de-vices. For Rotamass TI R0, the setting must be a value of12 or greater

V(FUN) First Unpolled-Node Indicates the address next to the address range used bythe host. Set 015 or greater.





V(NUM) Number of consecu-tive Unpolled-Node Unused addess range.

Not used0x00

0x0F0x10

0x130x14

0xF70xF8

0xFB0xFC

0xFF

V(FUN)

Bridge device

BASIC device

LM device

Not used

Default address

Portable device address

V(FUN) + V(NUN)

V(NUN)

Fig. 3: Available Address Range

Note 1: Bridge device: A linking device which brings data from one or more H1 networks.

Note 2: LM device: with bus control function (Link Master function)

Note 3: BASIC device: without bus control function

3.2.7 Bus Power ONTurn on the power of the host and the bus and also the power for the Rotamass TI R0.Where the Rotamass TI R0 is equipped with an LCD indicator, first all segments are lit,then the display begins to operate.

Using the host device display function, make sure that the Rotamass TI R0 is in operationon the bus.

The following settings are in effect when shipped from the factory:

▪ PD tag: FT2004

▪ Node address: 246 (hexadecimal F6)

▪ Device ID: 5945430013xxxxxxxx (xxxxxxxx = a total of 8 alphanumerical characters)



DEVICE INFORMATIONDevice IDPD TagDevice RevisonNode AddressSerial No.Physical Location

5945430013xxxxxxxxFT200420xF6xxxxxxxxxxxxxxxxxxx___________________

Note: ___________________________________________________

Our Device Description Files and Capabilities Files available at http://www.yokogawa.com/fld (English) orhttp://www.yokogawa.co.jp/fld (Japanese)

::::::

DEVICE INFORMATIONDevice IDPD TagDevice RevisonNode AddressSerial No.Physical Location

5945430013xxxxxxxxFT200420xF6xxxxxxxxxxxxxxxxxxx___________________

Note: ___________________________________________________

Our Device Description Files and Capabilities Files available at http://www.yokogawa.com/fld (English) orhttp://www.yokogawa.co.jp/fld (Japanese)

::::::

Fig. 4: Device Information Sheet Attached to Rotamass TI R0

If no Rotamass TI R0 device is detected, check the available address range. If the nodeaddress and PD are not specified when ordering, the default value is factory set asabove. If two or more devices are connected at the same time with default value, onlyone device will be detected from the host as all devices have the same initial address.Separately connect each Rotamass TI R0 device and set a different address for each.

3.2.8 Integration of DDIf the host supports DD (Device Description), the DD of the Rotamass TI R0 needs to beinstalled.

Check if host has the following directory under its default DD directory: 5945430013▪ 594543: manufacturer number of Yokogawa Electric Corporation

▪ 0013: Rotamass TI R0 device number

If this directory is not found, the DD for the Rotamass TI R0 has not yet been installed.

Create this directory and copy the DD files 0m0n.ff5 and 0m0n.sy5 to it (to be suppliedseparately; m and n stand for numerals).

You can also download the the DD files via Internet from http://www.yokogawa.com/fld/

Once the DD is installed in the directory, the name and attribute of all parameters of theRotamass TI R0 are displayed.

Offline configuration is possible using the capabilities file (CFF).

When using a CFF file, make sure you use the right file for the intended device.

Using the wrong CFF file may result in an error when downloading the configured data tothe device. Also, use the right DD files that accommodate the revision of the intended de-vice.

http://www.yokogawa.com/fld/FIELDBUS/fld-fieldbus-01en.htm%20

Fieldbus communication configuration



3.2.9 Reading the ParametersTo read Rotamass TI R0 parameters, select the AI block of the Rotamass TI R0 from thehost screen and read the OUT parameter. The current selected signal is displayed.Check that MODE_BLOCK of the function block and resource block is set to AUTO, andchange the signal input and read the parameter again. A new designated value should bedisplayed.

3.2.10 Continuous Record of ValuesIf the host has a function of continuously recording the indications, use this function to listthe indications (values). Depending on the host being used, it may be necessary to setthe schedule of Publish (the function that transmits the indication on a periodic basis).

3.2.11 Generation of AlarmGeneration of an alarm can be attempted from the Rotamass TI R0. Block alarm, Outputlimit alarm, and Update alarm are informed to the host. When generating alarm, a LinkObject and a VCR Static Entry need to be set. For details of Link Object and VCR StaticEntry, refer to section Link object Link Object [} 29] and section VCR Setting Communi-cation Setting [} 26].

3.3 Fieldbus communication configuration

3.3.1 OutlineThis chapter describes how to adapt the function and performance of the Rotamass TI R0to suit specific applications. Because multiple devices are connected to fieldbus, it is im-portant to carefully consider the device requirements and settings when configuring thesystem. The following steps must be taken:

1. Network Design [} 22]: Determine the devices to be connected to fieldbus and checkthe capacity of the power supply.

2. Network Definition [} 22]: Determine the tag and node addresses for all devices.3. Definition of Combining Function Blocks [} 23]: Determine how function blocks are

combined.4. Setting of Tags and Addresses [} 25]: Set the PD Tag and node addresses for each

device.5. Communication Setting [} 26]: Set the link between communication parameters and

function blocks.6. Block Setting [} 29]: Set the parameters for function blocks.

The use of a dedicated configuration tool significantly simplifies this procedure.Refer to Link Master Functions [} 524] when the Rotamass TI R0 is used as LinkMaster.

The following sections describe in sequence each step of this procedure:

Software Instruction Manual FOUNDATION FieldbusOperating options Fieldbus communication configuration


3.3.2 Network DesignSelect the devices to be connected to the fieldbus network. The following are essential forthe operation of fieldbus:

▪ Power supplyA dedicated power supply is required. It is recommended that the current capacity bewell over the total value of the maximum current consumed by all devices (includingthe host). Conventional DC current cannot be used as is.

▪ TerminatorTwo terminators are required. Refer to the supplier for details of terminators that areattached to the host.

▪ Field devicesConnect the field devices necessary for instrumentation. The Rotamass TI R0 haspassed the interoperability test conducted by The Fieldbus Foundation. In order toproperly start fieldbus, it is recommended that the devices used satisfy the require-ments of the test above.

▪ HostUsed for accessing field devices. A minimum of one device with the bus control func-tion is needed.

▪ CableUsed for connecting devices. Refer to "Fieldbus Technical Informa-tion" (TI 38K03A01-01E) for details of instrumentation cabling. Provide a cable suffi-ciently long to connect all devices. For field branch cabling, use terminal boards or aconnection box as required.

Check the capacity of the power supply first. The power supply capacity must begreater than the sum of the maximum current consumed by all devices to be con-nected to fieldbus. The maximum current consumed for the Rotamass TI R0 is15 mA. The cable used for the spur must be of the minimum possible length.

3.3.3 Network DefinitionBefore connection of devices with fieldbus, define the fieldbus network. Allocate PD Tagand node addresses to all devices (excluding such passive devices as terminators).

The PD Tag is the same as the conventional one used for the device. Up to 32 alphanu-meric characters may be used for definition. Use a hyphen as a delimiter as required.

The node address is used to specify devices for communication purposes. Because thisdata is too long for a PD Tag, the host uses the node address in place of the PD Tag forcommunication. A range of 20 – 247 (or hexadecimal 14 – F7) can be set. The device(LM device) with bus control function (Link Master function) is allocated from a smalleraddress number (20) side, and other devices (BASIC device) without bus control functionallocated from a larger address number (247) side respectively.

Place the Rotamass Total Insight in the range of the BASIC device. When the RotamassTI R0 is used as Link Master, place the Rotamass TI R0 in the range of the LM device.Set the range of addresses to be used to the LM device. Set the following parameters.

Tab. 4: Parameters for Setting Address Range

Symbol Parameter Description

V(FUN) First-Unpolled-Node Indicates the address next to the address range used forthe host or other LM device.

V(NUM) Number-of-consecu-tive-Unpolled-Node Unused address range.




The devices within the address range written as Unused in the figure below cannot beused on a fieldbus. For other address ranges, the range is periodically checked to identifywhen a new device is mounted. Care must be taken to keep the unused device range asnarrow as possible so as to lessen the load on the fieldbus.

Not used0x00

0x0F0x10

0x130x14

0xF70xF8

0xFB0xFC

0xFF

V(FUN)

Bridge device

BASIC device

LM device

Not used

Default address

Portable device address

V(FUN) + V(NUN)

V(NUN)

Fig. 5: Available Range of Node Addresses

To ensure stable operation of fieldbus, determine the operation parameters and set themto the LM devices. While the parameters in table below are to be set, the worst-casevalue of all the devices to be connected to the same fieldbus must be used. Refer to thespecification of each device for details. The table below lists Rotamass TI R0 specifica-tion values.

Tab. 5: Operation Parameter Values of Rotamass TI R0 to be Set to LM Devices


V(ST) Slot-Time

Indicates the time necessary for immediate replyof the device. Unit of time is in octets (256 μs).Set maximum specification for all devices. ForRotamass TI R0, set a value of 4 or greater.

V(MID)Minimum-Inter-PDU-Delay

Minimum value of communication data intervals.Unit of time is in octets (256 μs). Set the maxi-mum specification for all devices. For RotamassTI R0, set a value of 4 or greater.

V(MRD) Maximum-Reply-Delay

The worst case time elapsed until a reply isrecorded. The unit is Slottime; set the value sothat V (MRD) × V (ST) is the maximum value ofthe specification for all devices. For RotamassTI R0, the setting must be a value of 12 orgreater.

3.3.4 Definition of Combining Function BlocksThe input/output parameters for function blocks are combined. As required, they can becombined with the input of the control block. The setting is written to the Rotamass TI R0link object. See Block Setting [} 29] for the details. It is also possible to read values fromthe host at proper intervals instead of connecting the Rotamass TI R0 block output toother blocks.

The combined blocks need to be executed synchronously with other blocks on the com-munications schedule. In this case, change the Rotamass TI R0 schedule according tothe following table. The values in the table are example settings.



Tab. 6: Execution Schedule of the Rotamass TI R0 Function Blocks

Index Parameters Setting (example)269(SM) MACROCYCLE_DURATION

Cycle (MACROCYCLE) period of control ormeasurement. Unit is 1/32 ms. (16000 = 0.5 s)

351(SM) FB_START_ENTRY.1

AI1 block startup time. Elapsed time from thestart of MACROCYCLE specified in 1/32 ms. (0 = 0 s)

352(SM) to381(SM)

FB_START_ENTRY.2 toFB_START_ENTRY.31 No setting

A maximum of 20 ms is taken for execution of AI and IT, MAO blocks. For scheduling ofcommunications for combination with the next function block, the execution is so ar-ranged as to start after a lapse of longer than 20 ms. In no case should function blocks ofthe Rotamass TI R0 be executed at the same time (execution time is overlapped).

FIC100

FIC200

FI100

ROTAMASS TI R0#1

ROTAMASS TI R0#2

FI200FC100

Fig. 6: Example of Loop Connecting Function Blocks of two Rotamass TI R0 with other Devices

The following figure shows an example schedule based on the loop shown in the figureabove:




Function BlockSchedule

CommunicationSchedule

ScheduledCommunication

Macrocycle (Control Period)

UnscheduledCommunication

Fig. 7: Function Block Schedule and Communication Schedule

When the control period (macro cycle) is set to more than 4 seconds, set the following in-terval to be more than 1% of the control period:

▪ Interval between “end of block execution” and “start of sending CD from LAS”

▪ Interval between “end of block execution” and “start of the next block execution”

3.3.5 Setting of Tags and AddressesThis section describes the steps in the procedure to set PD Tags and node addresses inthe Rotamass TI R0. There are three states of fieldbus devices as shown in the figure be-low, and if the state is other than the lowest SM_OPERATIONAL state, no function blockis executed.

Rotamass TI R0 must be transferred to this state when an Rotamass TI R0 tag or ad-dress is changed.

UNINITIALIZED(No tag nor address is set)

Tag clear

INITIALIZED(Only tag is set)

SM_OPERATIONAL(Tag and address are retained, and the

function block can be executed.)

Address clear Address setting

Tag setting

Fig. 8: Status Transition by Setting PD Tag and Node Address



Rotamass TI R0 has a PD Tag (FT2004) and node address (246, or hexadecimal 0xF6)that are set upon shipment from the factory unless otherwise specified. To change onlythe node address, clear the address once and then set a new node address. To set thePD Tag, first clear the node address and clear the PD Tag, then set the PD Tag and nodeaddress again.

Devices whose node addresses have been cleared will have the default address (ran-domly chosen from a range of 248 to 251, or from hexadecimal F8 to FB). At the sametime, it is necessary to specify the device ID in order to correctly specify the device. Thedevice ID of the Rotamass TI R0 is 5945430013xxxxxxxx. (The xxxxxxxx at the end ofthe above device ID is a total of 8 alphanumeric characters.)

3.3.6 Communication SettingTo set the communication function, it is necessary to change the database residing in SM- VFD.

VCR SettingSet VCR (Virtual Communication Relationship), which specifies the called party for com-munication and resources. Each Rotamass TI R0 has 38 VCRs whose application can bechanged, except for the first VCR, which is used for management.

Each Rotamass TI R0 has VCRs of four types:

▪ Server (QUB) VCRA server responds to requests from a host. This communication needs data ex-change. This type of communication is called QUB (Queued User-triggered Bidirec-tional) VCR.

▪ Source (QUU) VCRA source multicasts alarms or trends to other devices. This type of communication iscalled QUU (Queued User-triggered Unidirectional) VCR.

▪ Publisher (BNU) VCRA publisher multicasts outputs of the AI blocks and IT blocks to other function blocks.This type of communication is called BNU (Buffered Network-triggered Unidirectional)VCR.

▪ Subscriber (BNU) VCRA subscriber receives output of another function block(s) by IT and MAO blocks.

A Server VCR is capable to respond to requests from a Client (QUB) VCR after the Clientsuccessfully initiates connection to the Server. A Source VCR transmits data without es-tablished connection. A Sink (QUU) VCR on another device can receive it if the Sink isconfigured so. A Publisher VCR transmits data when LAS requests so. An explicitconnection is established from Subscriber (BNU) VCR(s) so that a Subscriber knows theformat of published data.

Each VCR has the parameters listed in table below. Parameters must be changed to-gether for each VCR because modification of individual parameters may cause inconsis-tent operation.

Tab. 7: VCR Static Entry

Subindex Parameter Description

1 FasArTypeAndRole

Indicates the type and role of communication (VCR):

▪ 0x32: Server (Responds to requests from host.)

▪ 0x44: Source (Transmits alarm or trend.)

▪ 0x66: Publisher (Sends block output to otherblocks.)

▪ 0x76: Subscriber (Receives output of otherblocks.)

2 FasDllLocalAddrSets the local address to specify a VCR in theRotamass TI R0. A range of 20 to F7 in hexadeci-mal.




Subindex Parameter Description

3FasDllConfiguredRemoteAddr

Sets the node address of the called party for com-munication and the address (DLSAP or DLCEP)used to specify VCR in that address. For DLSAP orDLCEP, a range of 20 to F7 in hexadecimal is used.Addresses in Subindex 2 and 3 need to be set to thesame contents of the VCR as the called party (localand remote are reversed).

4 FasDllSDAP

Specifies the quality of communication. Usually, oneof the following types is set:

▪ 0x2B: Server

▪ 0x01: Source (Alert)

▪ 0x03: Source (Trend)

▪ 0x91: Publisher/Subscriber

5FasDllMaxConfirmDelayOnConnect

To establish connection for communication, a maxi-mum wait time for the called party's response is setin ms. Typical value is 60 secounds (60000).

6FasDllMaxConfirmDelayOnData

For request of data, a maximum wait time for thecalled party's response is set in ms. Typical value is60 secounds (60000).

7 FasDllMaxDlsduSize

Specifies maximum DL Service Data unit Size(DLSDU).Set 256 for Server and Trend VCR, and 64 for otherVCRs.

8FasDllResidualActivitySupported

Specifies whether connection is monitored. SetTRUE (0xff) for Server. This parameter is not usedfor other communication.

9 FasDllTimeliness-Class Not used for the Rotamass TI R0

10FasDllPublisherTimeWindowSize

Not used for the Rotamass TI R0

11FasDllPublisherSynchronizaingDlcep


12FasDllSubsriberTimeWindowSize


13FasDllSubscriberSynchronizationDl-cep


14 FmsVfdId

Sets VFD for the Rotamass TI R0 to be used:

▪ 0x1: System/network management VFD

▪ 0x1234: Function block VFD

15FmsMaxOutstandingServiceCalling

Set 0 to Server. It is not used for other applications.

16FmsMaxOutstandingServiceCalled

Set 1 to Server. It is not used for other applications.

17FmsFeaturesSupported

Indicates the type of services in the application layer.In the Rotamass TI R0, it is automatically set accord-ing to specific applications.

The example in the following table contains 38 VCRs:



Tab. 8: VCR List

Index (SM) VCR Number Settings (example)402 1 For system management (Fixed)403 2 Server (LocalAddr = 0xF3)404 3 Server (LocalAddr = 0xF4)405 4 Server (LocalAddr = 0xF7)

406 5 Trend Source (LocalAddr = 0x07, Remote Ad-dress=0x111)407 6 Publisher for AI (LocalAddr = 0x20)

408 7 Alert Source (LocalAddr = 0x07, Remote Ad-dress=0x110)409 8 Server (LocalAddr = 0xF9)410 to 439 9 to 38 Not used.

Function Block Execution ControlAccording to the instructions given in Definition of Combining Function Blocks [} 23], setthe execution cycle of the function blocks and schedule of execution.




3.3.7 Block SettingSet the parameter for function block VFD.

Link ObjectA link object combines the data voluntarily sent by the function block with the VCR. TheRotamass TI R0 has 45 link objects. A single link object specifies one combination. Eachlink object has the parameters listed in table below. Parameters must be changed to-gether for each VCR because the modifications made to each parameter may cause in-consistent operation.

Tab. 9: Link Object Parameters

Subindex Parameters Description

1 LocalIndex Sets the index of function block parameters to becombined; set “0” for Trend and Alert.

2 VcrNumber Sets the index of VCR to be combined. If set to “0”,this link object is not used.3 RemoteIndex Not used in the Rotamass TI R0. Set to “0”.

4 ServiceOperation

Set one of the following:

▪ 0: Undefined

▪ 2: Publisher

▪ 3: Subscriber

▪ 6: Alert

▪ 7: TrendSet only one each for link object for Alert or Trend.

5 StaleCountLimit

Set the maximum number of consecutive stale inputvalues which may be received before the input sta-tus is set to BAD. To avoid the unnecessary modetransition caused when the data is not correctly re-ceived by subscriber, set this parameter to “2” ormore.

Link objects are not factory-set. Set link objects as shown in table below:

Tab. 10: Setting of Link Objects (example)

Index Link Object # Settings (example)30000 1 AI. OUT→VCR#630001 2 Trend→VCR#530002 3 Alert→VCR#730003to30044

4 to 45 Not used

Trend ObjectIn order for a function block to automatically transmit a trend, each Rotamass TI R0 has10 trend objects: 8 for trends of analog parameters and 2 for discrete parameters. Foreach trend object, specify a single parameter whose trend will be transmitted.

Each Trend object has the parameters listed in table below. The first 4 parameters arethe items to be set. Before writing to a Trend object, it is necessary to release theWRITE_LOCK parameter.



Tab. 11: Parameters for Trend Objects

Subindex Parameters Description

1 Block Index Sets the leading index of the function block thattakes a trend.

2ParameterRelative Index

Sets the index of parameters taking a trend by avalue relative to the beginning of the function block.In the Rotamass TI R0, the following three types oftrends are possible:

▪ 7: PV

▪ 8: OUT

▪ 19: FIELD_VAL

3 Sample Type

Specifies how trends are taken. Choose one of thefollowing 2 types:

▪ 1: Sampled upon execution of a function block.

▪ 2: The average value is sampled.

4 Sample IntervalSpecifies sampling intervals in units of 1/32 ms.Set the integer multiple of the function block execu-tion cycle.

5 Last Update The last sampling time.6 to 21 List of Status Status part of a sampled parameter.21 to 37 List of Samples Data part of a sampled parameter.

The following 10 trend objects are not factory-set:

Tab. 12: Trend Object

Index Parameters Factory Setting32000 to 32007 TREND_FLT.1 to TREND_FLT.8 Not set32008 TREND_DIS.1 Not set32009 TREND_DIS.2 Not set

View ObjectView objects are used to group parameters. This reduces the load of data transactions.Each Rotamass TI R0 supports 4 view objects for each of the resource block, 5 trans-ducer blocks, 6 AI blocks, 3 IT blocks and 1 MAO block. Each view object contains agroup of the parameters listed in tables below.

Tab. 13: Purpose of Each View Object

Description

VIEW_1 Set of dynamic parameters required by operator for plant operation(PV, SV, OUT, Mode etc.).

VIEW_2 Set of static parameters which need to be shown to plant operator atonce (Range etc.).VIEW_3 Set of all the dynamic parameters.VIEW_4 Set of static parameters for configuration or maintenance.




View Object for Resource Block (RB)

Rela-tive

Index

Parameter Mnemonic View1 2 3 4

1 ST_REV 2 2 2 22 TAG_DESC3 STRATEGY 24 ALERT_KEY 15 MODE_BLK 4 46 BLOCK_ERR 2 27 RS_STATE 1 18 TEST_RW9 DD_RESOURCE

10 MANUFAC_ID 411 DEV_TYPE 212 DEV_REV 113 DD_REV 114 GRANT_DENY 215 HARD_TYPES 216 RESTART17 FEATURES 218 FEATURE_SEL 219 CYCLE_TYPE 220 CYCLE_SEL 221 MIN_CYCLE_T 422 MEMORY_SIZE 223 NV_CYCLE_T 424 FREE_SPACE 425 FREE_TIME 4 426 SHED_RCAS 427 SHED_ROUT 428 FAULT_STATE 1 129 SET_FSTATE30 CLR_FSTATE31 MAX_NOTIFY 132 LIM_NOTIFY 133 CONFIRM_TIME 434 WRITE_LOCK 135 UPDATE_EVT36 BLOCK_ALM37 ALARM_SUM 8 838 ACK_OPTION 239 WRITE_PRI 140 WRITE_ALM41 ITK_VER 242 COMPATIBILITY_REV43 CAPABILITY_LEV44 FD_VER 245 FD_FAIL_ACTIVE 4 4



46 FD_OFFSPEC_ACTIVE 4 447 FD_MAINT_ACTIVE 4 448 FD_CHECK_ACTIVE 4 449 FD_FAIL_MAP 450 FD_OFFSPEC_MAP 451 FD_MAINT_MAP 452 FD_CHECK_MAP 453 FD_FAIL_MASK 454 FD_OFFSPEC_MASK 455 FD_MAINT_MASK 456 FD_CHECK_MASK 457 FD_FAIL_ALM58 FD_OFFSPEC_ALM59 FD_MAINT_ALM60 FD_CHECK_ALM61 FD_FAIL_PRI 162 FD_OFFSPEC_PRI 163 FD_MAINT_PRI 164 FD_CHECK_PRI 165 FD_SIMULATE 966 FD_RECOMMEN_ACT 2 267 FD_EXTENDED_ACTIVE_168 FD_EXTENDED_ACTIVE_269 FD_EXTENDED_ACTIVE_370 FD_EXTENDED_ACTIVE_471 FD_EXTENDED_ACTIVE_572 FD_EXTENDED_ACTIVE_673 FD_EXTENDED_ACTIVE_774 FD_EXTENDED_ACTIVE_875 FD_EXTENDED_MAP_176 FD_EXTENDED_MAP_277 FD_EXTENDED_MAP_378 FD_EXTENDED_MAP_479 FD_EXTENDED_MAP_580 FD_EXTENDED_MAP_681 FD_EXTENDED_MAP_782 FD_EXTENDED_MAP_8

83 DEVICE_CONDITION_ACTIVE_1










90 DEVICE_CONDITION_ACTIVE_891 SOFTWARE_REV92 WRITE_LOCK_LEVEL

Total bytes 40 30 49 69

View Object for Flow Calibration Block (FCB)

Rela-tive

Index

Parameter Mnemonic View1 2 3-1 3-2 3-3 4-1 4-2 4-3 4-4 4-5 4-6 4-7 4-8 4-9

1 ST_REV 2 2 2 2 2 2 2 2 2 2 2 2 2 22 TAG_DESC3 STRATEGY 24 ALERT_KEY 15 MODE_BLK 4 46 BLOCK_ERR 2 27 UPDATE_EVT8 BLOCK_ALM

9 TRANSDUCER_DIRECTORY10 TRANSDUCER_TYPE 2 2 2 2

11 TRANSDUCER_TYPE_VER 2

12 XD_ERROR 1 1

13 COLLECTION_DIRECTORY14 PRIMARY_VALUE_TYPE 215 PRIMARY_VALUE 5 516 PRIMARY_VALUE_RANGE 11

17 SECONDARY_VALUE_TYPE 2

18 SECONDARY_VALUE 5 5

19 SECONDARY_VALUE_RANGE 11

20 XD_OPTS 421 SENSOR_TYPE 222 SENSOR_RANGE 1123 SENSOR_SN 3224 SENSOR_CAL_METHOD 125 SENSOR_CAL_LOC 3226 SENSOR_CAL_DATE 727 SENSOR_CAL_WHO 3228 BLOCK_ERR_DESC_1 4 429 PRIMARY_VALUE_FTIME 4

30 PRIMARY_VALUE_LOW_CUT_OFF 4

31 PRIMARY_VALUE_TRIM_SEL 1



32 PRIMARY_VALUE_TRIM_OFFSET 4

33 PRIMARY_VALUE_TRIM_GAIN 4

34 SECONDARY_VALUE_FTIME 4

35 SECONDARY_VALUE_LOW_CUT_OFF 4

36 SECONDARY_VALUE_SEL 137 REFERENCE_DENSITY 4

38 SECONDARY_VALUE_TRIM_SEL 1

39 SECONDARY_VALUE_TRIM_OFFSET 4

40 SECONDARY_VALUE_TRIM_GAIN 4

41 TEMPERATURE_VALUE 5 5

42 TEMPERATURE_VALUE_RANGE 11

43 TEMPERATURE_VALUE_FTIME 4

44 TEMPERATURE_VALUE_SEL 1

45 TEMPERATURE_VALUE_FIXED 4

46 TEMPERATURE_VALUE_TRIM_SEL 1

47 TEMPERATURE_VALUE_TRIM_OFFSET 4

48 TEMPERATURE_VALUE_TRIM_GAIN 4

49 VOLUME_FLOW_VALUE 5 5

50 VOLUME_FLOW_VALUE_RANGE 11

51 VOLUME_FLOW_VALUE_FTIME 4

52 VOLUME_FLOW_VALUE_LOW_CUT_OFF 4

53 VOLUME_FLOW_TRIM_SEL 1

54 VOLUME_FLOW_TRIM_OFFSET 4

55 VOLUME_FLOW_TRIM_GAIN 4

56 VELOCITY_VALUE 4

57 VELOCITY_VALUE_UNITS_INDEX 2

58 PRESSURE_VALUE_FIXED 4

59 PRESSURE_VALUE_UNITS_INDEX 2

60 FLOW_DIRECTION 161 BI_DIRECTION 1




62 DENSITY_OFFSET_ORIENTATION 4

63 INSTALL_ORIENTATION 164 AUTOZERO_EXECUTE 165 AUTOZERO_TIME 266 AUTOZERO_VALUE 4

67 AUTOZERO_STAN-DARD_DEVIATION 4

68 CLEAR_AUTOZERO_VALUE 1

69 CLEAR_AUTOZERO_FAILURE 1

70 LAST_CALIBRATION_DATE_1 7

71 LAST_

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