User’s Manual Model DY Vortex Flowmeter Model DYA Vortex Flow Converter FOUNDATION Fieldbus Communication Type IM 01F06F00-01EN IM 01F06F00-01EN 7th Edition
i Model DY Vortex Flowmeter Model DYA Vortex Flow Converter FOUNDATION Fieldbus Communication Type IM 01F06F00-01EN 7th Edition Contents 1. INTRODUCTION........................................................................................ 1-1 1.1 Using This Instrument Safety .......................................................................... 1-2 1.2 Warranty ............................................................................................................. 1-3 1.
ii 6. 7. EXPLANATION OF BASIC ITEMS ........................................................... 6-1 6.1 Setting and Changing Parameters for the Whole Process .......................... 6-1 6.2 Transducer Block Parameters ......................................................................... 6-2 6.3 AI Function Block Parameters......................................................................... 6-4 6.4 Parameters of DI Function Block ..........................................................
iii APPENDIX 5. INTEGRATOR (IT) BLOCK .......................................................A5-1 A5.1 Schematic Diagram of Integrator Block ..................................................... A5-1 A5.2 Input Process Section ................................................................................... A5-2 A5.3 A5.2.1 Determining Input Value Statuses ...................................................A5-2 A5.2.2 Converting the Rate ............................................................
iv APPENDIX 7. LINK MASTER FUNCTIONS ....................................................A7-1 A7.1 Link Active Scheduler.................................................................................... A7-1 A7.2 Link Master ..................................................................................................... A7-1 A7.3 Transfer of LAS .............................................................................................. A7-2 A7.4 LM Functions ................................
v APPENDIX 11. SOFTWARE DOWNLOAD (Option /EE) ..............................A11-1 A11.1 Benefits of Software Download...................................................................A11-1 A11.2 Specifications................................................................................................A11-1 A11.3 Preparations for Software Downloading ....................................................A11-1 A11.4 Software Download Sequence ..........................................................
1-1 <1. INTRODUCTION> 1. INTRODUCTION Thank you for purchasing FOUNDATION Fieldbus communication type of digitalYEWFLO vortex flowmeter. To ensure correct use of the instrument, please read this manual thoroughly and fully understand how to operate the instrument before operating it. This manual describes only those topics that are required for operation of the FOUNDATION Fieldbus communication type. For other topics, please refer to User’s Manual for vortex flowmeter (IM 01F06A00-01EN).
<1. INTRODUCTION> 1.1 Using This Instrument Safety (1) Installation WARNING • Installation of the vortex flowmeter must be performed by expert engineer or skilled personnel. No operator shall be permitted to perform procedures relating to installation. • The vortex flowmeter must be installed within the specification conditions. • The vortex flowmeter is a heavy instrument.
<1. INTRODUCTION> 1.2 1-3 Warranty • The terms of this instrument that are guaranteed are described in the quotation. We will make any repairs that may become necessary during the guaranteed term free of charge. • Please contact our sales office if this instrument requires repair. • If the instrument is faulty, contact us with concrete details about the problem and the length of time it has been faulty, and state the model and serial number.
<1. INTRODUCTION> 1.3 1-4 ATEX Documentation This is only applicable to the countries in European Union.
<2. AMPLIFIER FOR FIELDBUS COMMUNICATION> 2. 2-1 AMPLIFIER FOR FIELDBUS COMMUNICATION Refer to IM 01F06A00-01EN for the details of the amplifier. This section encompasses topics applicable to only the Fieldbus communication type. (1) The Fieldbus communication type has no local key access function. (2) The Fieldbus communication type has no BT200 (BRAIN TERMINAL) connection pin. (3) The Fieldbus communication type has a simulation function. The SIMULATE_ENABLE switch is mounted on the amplifier.
3-1 <3. ABOUT FIELDBUS> 3. 3.1 ABOUT FIELDBUS Outline Fieldbus is a bi-directional digital communication protocol for field devices, which offers an advancement in implementation technologies for process control systems and is widely employed by numerous field devices. The Fieldbus communication type of the digitalYEWFLO employs the specification standardized by the Fieldbus FOUNDATION, and provides interoperability between Yokogawa devices and those produced by other manufacturers.
<3. ABOUT FIELDBUS> 3.
4-1 <4. GETTING STARTED> 4. GETTING STARTED Fieldbus is fully dependent upon digital communication protocol and differs in operation from conventional 4 to 20 mA transmission and the BRAIN communication protocol. It is recommended that novice users use fieldbus devices in accordance with the procedures described in this section. The procedures assume that fieldbus devices will be set up on a bench or in an instrument shop. 4.
4-2 <4. GETTING STARTED> 4.2 Host Setting 0x00 Not used To activate Fieldbus, the following settings are required for the host. 0x0F 0x10 Bridge device 0x13 0x14 IMPORTANT Do not turn off the power immediately after setting. When the parameters are saved to the EEPROM, the redundant processing is executed for the improvement of reliability. If the power is turned off within 60 seconds after setting is made, the modified parameters are not saved and the settings may return to the original values.
4-3 <4. GETTING STARTED> Unless otherwise specified, the following settings are in effect when shipped from the factory. If no digitalYEWFLO is detected, check the available address range. If the node address and PD Tag are not specified when ordering, default value is factory set. If two or more digitalYEWFLOs are connected at a time with default value, only one digitalYEWFLO will be detected from host as digitalYEWFLOs have the same initial address.
<4. GETTING STARTED> 4.7 4-4 Generation of Alarm If the host is allowed to receive alarms, generation of an alarm can be attempted from the digitalYEWFLO. In this case, set the reception of alarms on the host side. The digitalYEWFLO’s VCR-7 is factory-set for this purpose. For practical purposes, all alarms are placed in a disabled status; for this reason, it is recommended that you first use one of these alarms on a trial basis. Set the value of link object-3 (index 30002) as “0, 299, 0, 6, 0”.
<5. CONFIGURATION> 5. CONFIGURATION This chapter describes how to adapt the function and performance of the digitalYEWFLO to suit specific applications. Because multiple devices are connected to Fieldbus, it is important to carefully consider the device requirements and settings when configuring the system. The following steps must be taken. (1) Network design Determines the devices to be connected to Fieldbus and checks the capacity of the power supply.
<5. CONFIGURATION> The node addresses are used to locate devices for communication purposes. Since a PD tag is too long a data value, the host substitutes the node addressed for PD tags in communication. Node addresses can be set to numbers in a range of decimal 20 to 247 (hexadecimal 14 to F7). Assign devices having link master functionality (i.e., LM devices) from the smallest address number (0x14) in order, and other devices (i.e., basic devices) from the largest (0xF7).
5-3 <5. CONFIGURATION> Table 5.3 Index 269 (SM) 276 (SM) 277 (SM) 278 (SM) to 289 (SM) Function Block Execution Schedule of the digitalYEWFLO Setting (Factory Setting in Parentheses) MACROCYCLE_ Repetition period of control DURATION or measurement, i.e., macrocycle; to be set as a multiple of 1/32 ms (32000 = 1 second) FB_START_ENTRY.1 Start time of the AI1 block represented as the elapsed time from the start of each macrocycle; to be set as a multiple of 1/32 ms (0 = 0 ms) FB_START_ENTRY.
5-4 <5. CONFIGURATION> In each digitalYEWFLO, the PD tag and node address are set to “FT1003” and 242 (hexadecimal F2), respectively, before shipment from the factory unless otherwise specified. To change only the node address, clear the address once and then set a new node address. To set the PD tag, first clear the node address and clear the PD tag, then set the PD tag and node address again.
5-5 <5. CONFIGURATION> Table 5.4 VCR Static Entry SubParameter index 1 FasArTypeAndRole 2 3 4 5 FasDllLocalAddr FasDllConfigured RemoteAddr FasDllSDAP FasDllMaxConfirm DelayOnConnect 6 FasDllMaxConfirm DelayOnData 7 FasDllMaxDlsduSize 8 9 10 11 12 13 Description Indicates the type and role of communication (VCR). The following 4 types are used for the digitalYEWFLO. 0x32: Server (Responds to requests from host.) 0x44: Source (Transmits alarm or trend.
5-6 <5. CONFIGURATION> 5.6 Block Setting 5.6.2 Trend Objects Set the parameter for function block VFD. 5.6.1 Link Objects A link object combines the data voluntarily sent by the function block with the VCR. Each digitalYEWFLO has 40 link objects. A single link object specifies one combination. Each link object has the parameters listed in Table 5.6. Parameters must be changed together for each VCR because the modifications made to each parameter may cause inconsistent operation. Table 5.
<5. CONFIGURATION> System Management Information Base (SMIB) digital YEWFLO Alert FBOD Trend #1 Link object #1 VCR DI2 OUT DI1 OUT AI2 OUT Resource Transducer AI1 OUT block block Network Management Information Base (NMIB) 5-7 #2 #3 #4 #8 #3 #6 #7 DLSAP 0xF8 0xF3 0xF4 0xF7 0xF9 0x20 DLCEP #2 #5 0x07 Fieldbus Cable Host 1 Host 2 Device F0505.ai Figure 5.5 Example of Default Configuration 5.6.3 View Objects View objects are used to group parameters.
5-8 <5. CONFIGURATION> Table 5.
5-9 <5. CONFIGURATION> Table 5.
5-10 <5.
5-11 <5. CONFIGURATION> Table 5.13 Relative Index 1 2 3 4 5 6 7 8 9 10 11 12 13 14 15 16 17 18 19 20 21 22 23 24 25 26 27 28 29 30 31 32 33 34 35 36 37 38 39 40 View Objects for Each AI Function Block Table 5.
5-12 <5. CONFIGURATION> Table 5.
5-13 <5. CONFIGURATION> Table 5.
5-14 <5. CONFIGURATION> Table 5.17 Relative Index Table 5.
6-1 <6. EXPLANATION OF BASIC ITEMS> 6. EXPLANATION OF BASIC ITEMS This chapter describes basic TR (Transducer block), AI, and DI function block parameter setting, displays of the integral indicator. For detailes of the function blocks, refer to APPENDIX. This chapter contains information on how to adapt the function and performance of the digitalYEWFLO to suit specific applications.
6-2 <6. EXPLANATION OF BASIC ITEMS> 6.2 Transducer Block Parameters The transducer block sets functions specific to the flow rate measurement of the digitalYEWFLO. For each block parameter in digitalYEWFLO, refer to APPENDIX 1 “LIST OF PARAMETERS FOR EACH BLOCK OF digitalYEWFLO.” The following describes important parameters and how to set them. For the METHOD of TR block, refer to APPENDIX 10.1 “Transducer Block”. Operation Conditions Relative Index Table 6.
<6. EXPLANATION OF BASIC ITEMS> (2) Explanations of Parameters 1) PRIMARY_VALUE_TYPE (Relative Index 13) Indicates the type of the measured item represented by PRIMARY_VALUE. For the digitalYEWFLO, the value of PRIMARY_ VALUE_TYPE is 100 and 101 as follows: 100 = Mass flow 101 = Volumetric flow 65535 = Other Default: 101 (Volumetric flow) 2) PRIMARY_VALUE_FTIME (Relative Index 30) Defines the damping time constant for the flow rate to be input to the flow rate calculation.
<6. EXPLANATION OF BASIC ITEMS> 17) K_FACTOR_UNIT (Relative Index 67) Selects the unit of the K factor. Setting range: 1 (=p/L) Default: 1 (=p/L). 18) K_FACTOR (Relative Index 68) Sets the K factor of the combined detector at 15C. Setting range: 0.00001 to 32000 Unit: As selected in K_FACTOR_UNIT Default: 68.6 19) LOW_CUT_FLOW (Relative Index 69) Sets the low cutoff flow rate level. Setting range: Minimum flow rate × 0.5 to XD_SCALE.EU_100 Unit: As selected in PRIMARY_VALUE_ RANGE.
6-5 <6. EXPLANATION OF BASIC ITEMS> Table 6.
6-6 <6. EXPLANATION OF BASIC ITEMS> 6.4 Parameters of DI Function Block 6.5 DI function blocks work based on the limit switch signals generated by the transducer block where DI1 is based on those signals on the flow rate and DI2 on the temperature (with the option /MV). Table 6.5 MODE_BLK Supports O/S, Auto, and Manual modes. The DI block does not function in the O/S mode, does not update the measured value in the Manual mode, and updates the measured value in the Auto mode.
<6. EXPLANATION OF BASIC ITEMS> 6-7 Voluemetric Flow Rate at Normal Condition Nm3/s(1522), Nm3/m(1523), Nm3/h(1524), Nm3/d(1525), NL/s(1532), NL/m(1533), NL/h(1534), NL/d(1535), Sm3/s(1527), Sm3/m(1528), Sm3/h(1529), Sm3/d(1530), SL/s(1537), SL/m(1538), SL/h(1539), SL/d(1540), SCFM(1360), SCFH(1361) N: Normal, S: Standard. Percentage %(1342) (1) Display Style In case of plus display Example : AR OUT_RANGE. EU_100 : 1 Example : AR OUT_RANGE. EU_100 : 0.
<7. IN-PROCESS OPERATION> 7. IN-PROCESS OPERATION This chapter describes the procedure performed when changing the operation of the function block of the digitalYEWFLO in process. 7.1 Mode Transition When the function block mode is changed to Out_ Of_Service, the function block pauses and a block alarm is issued. When the function block mode is changed to Manual, the function block suspends updating of output values.
<7. IN-PROCESS OPERATION> Table 7.1 LCD 7-2 Alarm Indications and Alarm Mask Switches Error Detail Alarm Mask SW (default) AL-01 The EEPROM(S) failed. Not provided AL-02 The serial communication circuit in the amplifier failed (type 1 error). Not provided AL-03 The serial communication circuit in the amplifier failed (type 2 error). Not provided AL-04 The EEPROM(F) failed. Not provided AL-05 The flow sensor failed. Provided (ON) AL-06 The input circuit in the amplifier failed.
7-3 <7. IN-PROCESS OPERATION> 7.2.2 Alarms and Events 7.3 Each digitalYEWFLO can report the following alarms and events as alerts.
8-1 <8. DEVICE STATUS> 8. DEVICE STATUS In a digitalYEWFLO, the current device statuses and error details are represented by parameters DEVICE_STATUS_1 to DEVICE_STATUS_5 (indexes 1045 to 1049) inside the resource statuses. Table 8.1 Hexadecimal 0x04000000 0x02000000 0x01000000 0x00800000 0x00400000 0x00080000 0x00008000 0x00004000 0x00002000 0x00001000 0x00000800 0x00000400 0x00000200 0x00000100 0x00000080 0x00000040 0x00000020 0x00000010 0x00000008 0x00000004 0x00000002 0x00000001 Table 8.
<8. DEVICE STATUS> Table 8.3 Hexadecimal 0x10000000 0x02000000 0x01000000 0x00800000 0x00400000 0x00200000 0x00100000 0x00040000 0x00020000 0x00010000 0x00004000 0x00002000 0x00001000 0x00000400 0x00000200 0x00000100 0x00000040 0x00000020 0x00000010 0x00000004 0x00000002 0x00000001 Table 8.
<8. DEVICE STATUS> Table 8.5 8-3 Contents of DEVICE_STATUS_5 (Index 1049) Hexadecimal 0x08000000 0x04000000 0x02000000 0x00800000 0x00400000 0x00200000 0x00080000 0x00040000 0x00020000 0x00010000 Display through DD AI3 in O/S mode (AL-28) IT in O/S mode (AL-29) AR in O/S mode (AL-30) AI3 in MAN mode (AL-77) AI3 in simulate active (AL-78) AI3 not scheduled (AL-79) IT in MAN mode (AL-80) IT not scheduled (AL-81) IT Total not saved (AL-82) IT Conf.
9-1 <9. GENERAL SPECIFICATIONS> 9. 9.1 GENERAL SPECIFICATIONS Standard Specifications For items other than those described below, refer to GS 01F06A00-01EN. Applicable Models: All the models of DY and DYA with Fieldbus communication functions (Output code: F).
9-2 <9.
9-3 <9. GENERAL SPECIFICATIONS> Functional Specifications: Functional specifications for Fieldbus communication conform to the standard specifications (H1) of FOUNDATION fieldbus. FOUNDATION Fieldbus specifications (ITK 5.0.1) grant the interoperability of the field instruments. Function blocks: Block name AI 9.
9-4 <9. GENERAL SPECIFICATIONS> Item Factory Mutual (FM) ATEX Description Code FM explosion-proof Approval Applicable Standard: FM3600, FM3611, FM3615, FM3810, Including Supplement 1 ANSI/NEMA 250 Type of Protection: Explosionproof for Class I, Division 1, Groups A, B, C, and D; Dust-ignitionproof Class II/III, Division 1, Groups E, F, and G. “SEAL ALL CONDUITS WITHIN 18 INCHES.” “WHEN INSTALLED IN DIV.2, SEALS NOT REQUIRED.
9-5 <9. GENERAL SPECIFICATIONS> Item Description Canadian Standards Association (CSA) Code CSA explosion-proof Approval Applicable Standard: C22.1-98, C22.2 No.0, C22.2 No.0.4, C22.2 No.0.5, C22.2 No.25, C22.2 No.30, C22.2 No.94, C22.2 No.142, C22.2, No.61010-1, ANSI/ISA-12.27.01 Type of Protection: explosion-proof for Class I, Groups B, C and D; Class II, Groups E, F and G; Class III. For Class I, Division 2 locations“FACTORY SEALED, CONDUIT SEAL NOT REQUIRED.
<10. EXPLOSION PROTECTED TYPE INSTRUMENT> 10. 10-1 EXPLOSION PROTECTED TYPE INSTRUMENT In this section, further requirements and differences for explosion proof type instrument are described except JIS Flame proof. For explosion proof type instrument, the description in this chapter is prior to other description in this Instruction Manual. WARNING • Only trained persons use this instrument in industrial locations. 10.1 ATEX WARNING • Only trained persons use this instrument in industrial locations.
10-2 <10.
10-3 <10. EXPLOSION PROTECTED TYPE INSTRUMENT> Maintenance and Repair WARNING • The instrument modification or parts replacement by other than authorized representative of Yokogawa Electric Corporation is prohibited and will void the certification.
<10. EXPLOSION PROTECTED TYPE INSTRUMENT> Screw Marking The type of electrical connection is stamped near the electrical connection port according to the following codes. Screw size Marking ISO M20 X 1.5 female ! M ANSI 1/2-14NPT female ! N or ! A F1003.
<10. EXPLOSION PROTECTED TYPE INSTRUMENT> 10.2 FM Technical Data • Explosion Proof Applicable Standard: FM3600 2011, FM3611 2004, FM3615 2006, FM3810 1989, Including Supplement 1 1995, ANSI/NEMA 250 1991 Type of Protection: Explosion proof for Class I, Division 1, Groups A,B, C and D; Dust-ignition proof for Class II/III, Division 1, Groups E, F,and G. “SEAL ALL CONDUITS 18 INCHES.” “ WHEN INSTALLED IN DIV.
<10. EXPLOSION PROTECTED TYPE INSTRUMENT> 10-6 Operation • Explosion proof WARNING • Note a warning label worded as follows. Warning: OPEN CIRCUIT BEFORE REMOVING COVER. INSTALL IN ACCORDANCE WITH THE INSTRUCTION MANUAL (IM) IF6A1-01E. • Take care not to generate mechanical spark when access to the instrument and peripheral devices in hazardous locations.
10-7 <10.
<10. EXPLOSION PROTECTED TYPE INSTRUMENT> 10-8 • FISCO rules The FISCO Concept allows the interconnection of intrinsically safe apparatus to Safety Barrier not specifically examined in such combination.
10-9 <10. EXPLOSION PROTECTED TYPE INSTRUMENT> [ Integral type ] Vmax = 32 Vdc Ci = 3.52 nF /L ȝ+ Terminator DY (Flowmeter) [ Remote type ] Vmax = 32 Vdc Ci = 3.
<10. EXPLOSION PROTECTED TYPE INSTRUMENT> 10-10 NOTE 1. Dust-tight conduit seal must be used when installed in Class II and Class III environments. 2. Installation should be in accordance with the National Electrical Code® (ANSI/NFPA 70) Sections 504 and 505. 3. The configuration of Associated Nonincendive Field Wiring Apparatus must be FM Approved. 4. Associated Nonincendive Field Wiring Apparatus manufacturer’s installation drawing must be followed when installing this equipment. 5.
<10. EXPLOSION PROTECTED TYPE INSTRUMENT> 10.3 IECEx Special conditions for safe use 1. For process temperatures above 250°C the flow meters of the /HT version must be used. WARNING Installation • Only trained persons use this instrument in industrial locations. • Electrostatic charge may cause an explosion hazard. Avoid any actions that cause the generation of electrostatic charge, such as rubbing with a dry cloth on coating face of product.
10-12 <10. EXPLOSION PROTECTED TYPE INSTRUMENT> Operation Name Plate [Integral type, Flameproof] WARNING • Wait 3 min. after power is turned off, before opening the covers. • Take care not to generate mechanical spark when access to the instrument and peripheral devices in hazardous locations.
<10. EXPLOSION PROTECTED TYPE INSTRUMENT> 10.4 CSA Dual Seal (Option /CF11) Technical Data • Explosion Proof Applicable Standard: C22.1-98, C22.2 No.0-M1991, C22.2 No.0.4-04, C22.2 No.0.5-1982, C22.2 No. 251966, C22.2 No. 30-M1986, C22.2 No. 94-M1991, C22.2 No. 142-M1987, C22.2 No. 61010-1-04, ANSI/ISA12.27.01-2003 Certificate : 1166201 Type of Protection: Explosion proof for Class I, B, C and D; Class II, Groups E, F and G; Class III.
<10. EXPLOSION PROTECTED TYPE INSTRUMENT> 10-14 10.
A1-1 APPENDIX 1. LIST OF PARAMETERS FOR EACH BLOCK OF digitalYEWFLO Note: The Write Mode column contains the modes in which each parameter is write enabled. O/S: Write enabled in O/S mode. MAN: Write enabled in Man mode and O/S mode. AUTO: Write enabled in Auto mode, Man mode, and O/S mode. —: Write disabled A1.
A1-2 Relative Index Index 18 1018 FEATURE_SEL 0x000a (Soft write lock supported Report supported) 19 1019 CYCLE_TYPE 0x0001(Scheduled) — 20 1020 CYCLE_SEL 0x0001(Scheduled) AUTO 21 1021 MIN_CYCLE_T 3200 — Time duration of the shortest cycle interval of which the resource is capable. 22 1022 MEMORY_SIZE 0 — Available configuration memory in the empty resource. To be checked before attempting a download.
A1-3 Relative Index Index 43 1043 SOFT_DESC 44 1044 SIM_ENABLE_MSG (Spaces) 45 1045 DEVICE_STATUS_1 — — Device status (VCR setting etc.) 46 1046 DEVICE_STATUS_2 — — Device status (failure or setting error etc.
A1-4 Index Relative Index AI1 AI2 AI3 Factory Default Parameter Name Write Mode Explanation 10 4010 4110 4210 XD_SCALE Specified at the O/S time of order (Note 3) (-40 to 260°C for AI2, 0 to 10m3/h for AI3) The high and low scale values, engineering units code, and number of digits to the right of the decimal point used with the value obtained from the transducer for a specified channel. Refer to Section 6.
Index Relative Index AI1 AI2 AI3 Factory Default Parameter Name Write Mode A1-5 Explanation 28 4028 4128 4228 HI_LIM 1. #INF AUTO 29 4029 4129 4229 LO_PRI 0 AUTO Priority of the low alarm. 0, 1, 3 to 15 30 4030 4130 4230 LO_LIM -1. #INF AUTO The setting for the low alarm in engineering units. (Note 2) 31 4031 4131 4231 LO_LO_PRI 0 AUTO Priority of the low low alarm. 0, 1, 3 to 15 32 4032 4132 4232 LO_LO_LIM -1.
A1-6 A1.3 Transducer Block Relative Index Index 0 2000 Block Header 1 2001 ST_REV 2 2002 TAG_DESC (Spaces) AUTO The user description of the intended application of the block 3 2003 STRATEGY 1 AUTO The strategy field can be used to identify grouping of blocks. This data is not checked or processed by the block. 4 2004 ALERT_KEY 1 AUTO The identification number of the plant unit.
A1-7 Relative Index Index 26 2026 SENSOR_CAL _WHO 27 2027 LIN_TYPE linear with input (1) 28 2028 SECONDARY _VALUE 0 O/S Temperature value. 29 2029 SECONDARY _VALUE_UNIT °C (1001) O/S Temperature value unit of AI2. The unit is linked to the unit of XD_SCALE. 30 2030 PRIMARY_ VALU E_FTIME 4s AUTO Sets the time constant of damping for the flow rate calculation. Setting range: 0 to 99 s.
A1-8
A1-9 Relative Index Index 63 2063 SECOND_TEMP _COEF 0 O/S Sets the second temperature coefficient for the density compensation of a liquid. Setting range: –32000 to 32000 Unit: 1/TEMP_UNIT^2 64 2064 SIZE_SELECT 25 mm (2) (Note 5) O/S Selects the flowmeter size: 1 = 15 mm (1/2 in.); 2 = 25 mm (1 in.); 3 = 40 mm (1.5 in.); 4 = 50 mm (2 in.); 5 = 80 mm (3 in.); 6 = 100 mm (4 in.); 7 = 150 mm (6 in.); 8 = 200 mm (8 in.
A1-10 Relative Index Index 82 2082 Parameter Name NOISE_RATIO Factory Default Write Mode — — 1 O/S Explanation Indicates the noise balance ratio. When the value of NOISE_BALANCE_MODE is 1 (Auto), this value cannot be modified. When it is 2 (Manual), the desired value can be set as a fixed ratio. 83 2083 SIGNAL_LEVEL 84 2084 FLOW_VELOCITY — — Sets the signal level. Setting range: 0.1 to 20.
A1-11 A1.4 DI Function Block Index Relative Index DI1 0 6000 6100 Block Header TAG: "DI1" or "DI2" Block Tag Information on this block such as the block tag, DD revision, = O/S and execution time 1 6001 6101 ST_REV 0 DI2 Parameter Name Factory Default Write Mode — Explanation The revision level of the static data of the DI block. The value of this parameter is incremented each time a static parameter value is changed.
A2-1 APPENDIX 2. APPLICATION, SETTING AND CHANGE OF BASIC PARAMETERS A2.1 Applications and Selection of Basic Parameters Setting Item (applicable parameters) Summary Tag numbers (PD-TAG) Set the physical device (PD) tag and block tags. Up to 32 alphanumeric characters can be set for each of these tags. Refer to Section 5.4 “Setting of Tags and Addresses.
A2-2 A2.2 Setting and Change of Basic Parameters AI Transducer Resource Function Block Block Block This section describes the procedure taken to set and change the parameters for each block. Obtaining access to each parameter differs depending on the configuration system used. For details, refer to the instruction manual for each configuration system. Access the block mode (MODE_BLK) of each block.
A2-3 (1)-2. Setting the output scale Access the OUT_SCALE parameter. Set the required unit in Unit Index of OUT_SCALE. Set the output value corresponding to the upper range limit in EU at 100% of OUT_SCALE. Set the output value corresponding to the lower range limit in EU at 0% of OUT_SCALE. Set the decimal point position in Decimal Point of OUT_SCALE. FA0203.ai Example: To set the output range to 0.00 to 100.
A2.4 Setting the Transducer Block To access the digitalYEWFLO-specific functions in the transducer block, the Device Description (DD) for the digitalYEWFLO needs to have been installed in the configuration tool used. For installation, refer to Section 4.4 “Integration of DD.” (1) Setting the damping time constant Access the PRIMARY_VALUE_FTIME parameter. Set the damping time constant (in units of seconds). FA0208.
A2-5 The UPPER_DISPLAY_MODE and LOWER_ DISPLAY_MODE parameter settings in the transducer (TR) block, and the L_TYPE settings in the AI1 and AI2 blocks determine which data items, and their values and units, are displayed on the LCD indicator, as shown in the following tables. Display on Upper Row of LCD Indicator UPPER_DISPLAY_MODE FLOW RATE (%) L_TYPE of AI1 Value FLOW RATE Unit Format L_TYPE of AI1 Percentage calculated from OUT.
A2-6 A2.5 Setting the DI Function Blocks DI function blocks output limit switch signals received from the transducer block. Two DI blocks (DI1 and DI2) in each digitalYEWFLO have independent parameters. Set up the parameters of each AI block you use, individually as necessary. The following shows the DI1 setting procedure as an example.
A3-1 APPENDIX 3. OPERATION OF EACH PARAMETER IN FAILURE MODE *1: Standard Type and Multi-variable Type with THERMOMETER_FUNCTION in TR block Set to “Monitor Only” or “Not Use” *2: Multi-variable Type with THERMOMETER_FUNCTION Used for Density Calculation LCD Display AL-01 Alarm Detail AMP. Module Failure 1 (AL-01) RS Block TR Block COM. Circuit Failure 1 (AL-02) — Bad-Device Failure COM.
LCD Display AL-06 Alarm Detail Input Circuit Failure (AL-06) RS Block TR Block AI1 Block AI2 Block AI3 Block *1 Uncertain-Non Other Specific *2 • Default Bad-Non Specific • STATUS_OPTS: Propagate Fault Input Circuit Failure (AL-06) Forward = Active Bad-Device Failure • Default Bad-Non Specific
LCD Display AL-01 AL-02 Alarm Detail AMP. Module Failure 1 (AL-01) COM. Circuit Failure 1 (AL-02) AL-03 COM. Circuit Failure 2 (AL-03) AL-04 AMP. Module Failure 2 (AL-04) AL-05 Flow Sensor Failure (AL-05) DI1 Block DI2 Block • Default Bad-Non Specific • STATUS_OPTS: Propagate Fault Forward=Active Bad-Device Failure
LCD Display AL-06 Alarm Detail Input Circuit Failure (AL-06) DI1 Block DI2 Block *1 • TARGET in TB’s LIMSW = PRIMARY_VALUE Uncertain-Non Specific • TARGET in TB’s LIMSW = SECONDARY_ VALUE • Default Bad-Non Specific • STATUS_OPTS: Propagate Fault Forward=Active Bad-Device Failure *2 • Default Bad-Non Specific • STATUS_OPTS: Propagate Fault Forward = Activez Bad-Device Failure
LCD Display Alarm Detail RS Block TR Block Other • Default Bad-Non Specific • STATUS_OPTS: Propagate Fault Forward = Active Bad-Device Failure *2 • Default Bad-Non Specific • STATUS_OPTS: Propagate Fault Forward = Active Bad-Device Failure • Default Bad-Non Specific • STATUS_OPTS: Propagate Fault Forward = Active Bad-Device Failure
LCD Display Alarm Detail DI1 Block DI2 Block PID Block IT Block AR Block *1 • TARGET in TB’s LIMSW = SECONDARY_VALUE • Default Bad-Non Specific • STATUS_OPTS:Propagate Fault Forward = Active Bad-Device Failure *2 • Default Bad-Non Specific • STATUS_OPTS:Propagate Fault Forward = Active Bad-Device Failure Temp. AL-07 Converter Failure (AL-07)
LCD Display Alarm Detail DI1 Block DI2 Block PID Block IT Block AR Block A3-7 AlarmReset SW* (default) AI1 in O/S AL-23 Mode (AL-23) Provided (ON) AI2 in O/S AL-24 Mode (AL-24) Provided (OFF) DI1 in O/S AL-25 Mode (AL-25) DI2 in O/S AL-26 Mode (AL-26) Out of Service Provided (OFF) (OFF) Bad-Out of Service Out of Service
LCD Display AL-27 Alarm Detail RS Block TR Block AI1 Block AI2 Block AI3 Block PID in O/S Mode (AL-27) A3-8 Alarm Reset SW* (default) Provided (OFF) Out of Service AI3 in O/S AL-28 Mode (AL-28)
LCD Display AL-27 AL-28 Alarm Detail DI1 Block DI2 Block PID Block IT Block AR Block Out of Service PID in O/S Mode (AL-27) A3-9 Alarm Reset SW* (default) Provided (OFF) Bad-Out of Service AI3 in O/S Mode (AL-28) Provided (OFF) Out of Service IT in O/S Mode AL-29 (AL-29) Provided (OFF) Bad -Out of Service Out of Service AR in O/S AL-30 Mode (AL-30)
LCD Display AL-53 Alarm Detail Clogging (AL53) AL-54 Fluctuating (AL-54) AL-61 Indicator Over Range (AL-61) DI1 Block DI2 Block • TARGET in TB’s LIMSW = SECONDARY_VALUE Uncertain-Non Specific (OFF) • TARGET in TB’s LIMSW = SECONDARY_VALUE Uncertain-Non Specific • TARGET in TB’s LIMSW = PRIMARY_ VALUE Uncertain-Non Specific
LCD Display Alarm Detail AL-62 AI1 in Man Mode (AL-62) AL-63 AI1 Simulation Active (AL-63) RS Block Simulation Active TR Block AI1 Block AI2 Block AI2 in Man Mode (AL-65) AL-66 AI2 Simulation Active (AL-66) Alarm Reset SW* (default)
LCD Display Alarm Detail DI1 Block DI2 Block PID Block IT Block AR Block A3-12 Alarm Reset SW* (default) AL-62 AI1 in Man Mode (AL-62) Provided (ON) AL-63 AI1 Simulation Active (AL-63) Provided (ON) AI1 Not AL-64 Scheduled (AL-64) Provided (ON) AL-65 AI2 in Man Mode (AL-65) Provided (OFF) AL-66 AI2 Simulation Active (AL-66) Provided (OFF) AI2 Not AL-67 Scheduled (AL-67) Provided (OFF)
LCD Display Alarm Detail AL-77 AI3 in Man Mode (AL-77) AL-78 AI3 Simulation Active (AL-78) AI3 Not AL-79 Scheduled (AL-79) AL-80 IT in Man Mode (AL-80) RS Block Simulation Active TR Block AI1 Block AI2 Block AI3 Block A3-13 Alarm Reset SW* (default)
LCD Alarm Detail Display DI1 Block DI2 Block PID Block IT Block AR Block A3-14 Alarm Reset SW* (default) AL-77 AI3 in Man Mode (AL-77) Provided (OFF) AL-78 AI3 Simulation Active (AL-78) Provided (OFF) AI3 Not AL-79 Scheduled (AL-79) AL-80 IT in Man Mode (AL-80) Provided (OFF)
A3-15 Alarm Reset Switch Settings Some alarms can be disabled and enabled using switches in parameter ALARM_PERFORM inside the transducer block as explained below. (1) Setting As shown in the following table, the individual bits of ALARM_PERFORM at relative index 45 act as switches to disable and enable particular alarms. Write zeros to the respective bits to disable desired alarms, or write ones to enable them.
A4-1 APPENDIX 4. FUNCTION DIAGRAMS OF FUNCTION BLOCKS A4.1 AI Function Block Transducer AI OUT FA0401.ai Figure A4.1 Input/Output of AI Block FIELD_VAL.Value CHANNEL Simulate Scaling SIMULATE XD_SCALE /100 /100 L_TYPE Ind.Sqr Root Scaling OUT_SCALE Cutoff Filter LOW_CUT PV_FTIME PV Indirect Direct Output OUT MODE Alarms HI/LO FA0402.ai Figure A4.2 Function Diagram of AI Block A4.2 DI Function Block Transducer DI OUT_D FA0403.
A5-1 APPENDIX 5. INTEGRATOR (IT) BLOCK OUT.Value = Integration start value + Total Total = Total + Current Integral Current Integral = (x + y) × ∆t x: IN_1 value whose unit has been converted y: IN_2 value whose unit has been converted ∆t: block execution period The Integrator (IT) block adds two main inputs and integrates them for output.
A5-2 A5.2 Input Process Section When executed, the Integrator block first performs input processing in the order of: “Determining input status” “Converting Rate or Accum” “Determining the input flow direction” Switching between Convert Rate and Convert Accum is made using bit 0 (for IN_1) or bit 1 (for IN_2) of INTEG_OPTS. INTEG_OPTS is one of the system parameters and should be set by the user.
A5-3 A5.2.3 Converting Accumulation This following describes an example of accumulation conversion. In accumulation conversion, the difference between the value executed previously and the value executed this time is integrated or accumulated. This conversion applies when the output of a function block used as a counter is input to the input process of the Integrator block.
A5-4 A5.3 Adder A5.4 Integrator When input processing is complete, two arguments that have been rate and accumulate converted will be passed to the adder. The adder adds these two values according to the option. When addition is complete, its result will be passed to the integrator. Integration consists of combinations of a reset method and counting up/down. There are the following seven integration types, which can be set using INTEG_TYPE. 1.
A5-5 Table A5.
A5-6 A5.5 Output Process A5.5.1 Status Determination There are the following three output parameters: 1. OUT 2. OUT_TRIP 3. OUT_PTRIP Parameters OUT_TRIP and OUT_PTRIP are used only when INTEG_TYPE is a value from 1 to 4. In case of Integrator block related memory failed, the status of OUT, OUT_TRIP, OUT_PTRIP becomes “Bad-Device Failure”.
A5.5.2 Determining the Output Value The value of OUT.Value is determined as follows: ● For counting up OUT = integration start value (0) + Total ● For counting down OUT = integration start value (TOTAL_SP) Total Total: Total of integrated values. This value is retained even if INTEG_TYPE is changed during integration (in AUTO).
A5-8 A5.5.3 Mode Handling Mode Action Output Automatic (AUTO) Normal action Normal output Integration calculation is stopped. You may rewrite a value in OUT. If no value is rewritten, the value just before OUT will not be updated unless you running in AUTO is held. When the mode returns to AUTO, integration starts Out of Service (O/S) set a value to it. No reset is accepted. with the written value or the value just before running in AUTO.
A5-9 A5.6.3 Reset Process The basic reset process sequence is as follows: 1. Snapshot 2. Clearing the integrated values 3. Reset count increment 4. Judging OUT_TRIP and OUT_PTRIP 1. Snapshot Saves the following values in the specified parameters before clearing the integrated values. These values will be retained until the next reset is made. STOTAL = Total SRTOTAL = RTotal SSP = TOTAL_SP 2.
A5-10 A5.7 List of Integrator Block Parameters Index Parameter Name 0 BLOCK_HEADER 1 ST_REV 2 TAG_DESC Initial Value TAG: “IT” Write Mode Definition Block Tag Information relating to this function block, such as block tag, =O/S DD revision, execution time 0 — Spaces AUTO The revision level of the set parameters associated with the Integrator block Stores comments describing tag information.
Index Parameter Name Initial Value Write Mode A5-11 Definition Specifies an integration optional function. bit 29 INTEG_OPTS 0x0004 Option Name Description 0 Input 1 accumulate Selects Rate or Accum input of IN_1. 1 Input 2 accumulate Selects Rate or Accum input of IN_2. 2 Flow forward Integrates forward flow (interprets reverse flow as zero).* 3 Flow reverse Integrates reverse flow (interprets forward flow as zero).
A6-1 APPENDIX 6. Enhanced ARITHMETIC (AR) BLOCK The Arithmetic (AR) block switches two main inputs of different measurement ranges seamlessly and combines the result with three auxiliary inputs through the selected compensation function (10 types) to calculate the output. For the METHOD of AR block, refer to APPENDIX 10.2 “Enhanced AR Block.” A6.1 Schematic Diagram of Arithmetic Block The diagram below shows the Arithmetic block schematic.
A6-2 A6.2 Input Section There are five inputs: IN and IN_LO main inputs and IN_1, IN_2, and IN_3 auxiliary inputs. IN and IN_LO are intended to connect devices with different measurement ranges and allow the use of switching a measurement range by selecting the measuring device. However, because there are slight differences between IN and IN_LO values even when the same item is measured, instantaneous switching causes abrupt changes in the output.
A6-3 A6.2.3 INPUT_OPTS INPUT_OPTS has an option that handles an input with “uncertain” or “bad” status as a “good” status input. Bit Function 0 Handles IN as a “good” status input if its status is “uncertain.” 1 Handles IN_LO as a “good” status input if its status is “uncertain.” 2 Handles IN_1 as a “good” status input if its status is “uncertain.” 3 Handles IN_1 as a “good” status input if its status is “bad.
A6.3 Computation Section A6.3.
A6-5 A6.3.3 Compensated Values A6.4 Output Section In computing equations 1) to 5) in APPENDIX 6.3.1 “Computing Equations” and 32) to 38) in APPENDIX 6.3.2 “Enhanced Computing Equations”, the value “f” is restricted by the COMP_ HI_LIM or COMP_LO_LIM parameter.
A6.4.1 Mode Handling Mode A6.4.2 Status Handling Output Auto OUT = PRE_OUT MAN For OUT, the OUT value in the Auto mode just before change to MAN or O/S is retained. O/S In the Manual mode (including O/S), the value of OUT in the Auto mode just before a change to the Manual mode is held or the value written to OUT is output.
A6-7 A6.
A6-8 Relative Index Parameter Write Mode Initial Value Description / Remarks Computation algorithm identification no.
A6-9 Relative Index 50 51 52 53 54 55 56 57 Parameter Write Mode Initial Value AUTO (Space) AUTO (Space) AUTO (Space) AUTO 0 AR_CONFIG_ SOFT_REV AR_CONFIG_ DATE AR_CONFIG_ WHO AR_CONFIG_ STATUS AR_CONFIG_ VSTRING32 AR_CONFIG_ VSTRING16 AR_CONFIG_ OSTRING32 AR_CONFIG_ OSTRING2 Description / Remarks Memo; The version of MV tool which is calculated multinominal approximation coefficient. Memo; The date of multinomial approximation coefficient setting.
A6-10 A6.7 Setting Procedure of the Mass Flow Rate Calculation Mass flow rate calculation, Setting start Choice of calculation method Choose from the following ARITH_TYPE.
A7-1 APPENDIX 7. LINK MASTER FUNCTIONS A7.1 Link Active Scheduler A link active scheduler (LAS) is a deterministic, centralized bus scheduler that can control communications on an H1 fieldbus segment. There is only one LAS on an H1 fieldbus segment. A digitalYEWFLO supports the following LAS functions. 1 PN transmission Identifies a fieldbus device newly connected to the same fieldbus segment. PN is short for Probe Node.
A7-2 A7.3 Transfer of LAS There are two procedures for an LM to become the LAS: (1) If the LM whose value of [V(ST)×V(TN)] is the smallest on a segment, with the exception of the current LAS, judges that there is no LAS on the segment, in such a case as when the segment has started up or when the current LAS has failed, the LM declares itself as the LAS, then becomes the LAS. (With this procedure, an LM backs up the LAS as shown in the following figure.
A7-3 (3) In the LAS settings of the digitalYEWFLO, set the values of V(FUN) and V(NUN) so that they include the node addresses of all nodes within the same segment. (Refer to Figure A7.3.) ConfiguredLinkSettingsRecord (digitalYEWFLO Index 369 (SM)) Subindex Default Description Value Element 4 FirstUnpolledNodeId 0x25 V (FUN) 7 NumConsecUnpolledNodeId 0xBA V (NUN) A7.4 LM Functions No.
A7-4 A7.5 LM Parameters A7.5.1 LM Parameter List The tables below show LM parameters of a digitalYEWFLO.
A7-6 A7.5.2 Descriptions for LM Parameters The following describes LM parameters of digitalYEWFLO. NOTE: Do not turn off the power to the digitalYEWFLO for 60 seconds after making a change to its parameter settings.
A7-7 (8) DlmeBasicInfo Subindex (11) PlmeBasicInfo Size [bytes] Element Description 1 SlotTime 2 Indicates the capability value for V(ST) of the device. 2 PerDlpduPhlOverhead 1 V(PhLO) 3 MaxResponseDelay 1 Indicates the capability value for V(MRD) of the device.
(14) DlmeScheduleDescriptor This parameter exists for the same number as the total number of domains, and each describes the LAS schedule downloaded to the corresponding domain. For the domain to which a schedule has not yet been downloaded, the values in this parameter are all zeros. Subindex Element Size [bytes] Version 2 Indicates the version number of the LAS schedule downloaded to the corresponding domain.
A7-9 A4-2. Make the parameters in the current LAS match the capabilities parameter in the digitalYEWFLO as follows (Refer to Section 5.2 “Network Definition”): LAS V(ST) V(MID) V(MRD) > > > digitalYEWFLO V(ST) ≥ 4 V(MID) ≥ 4 V(MRD) ≥ 12 A4-3. Check that the digitalYEWFLO is assigned an appropriate address.
A8-1 APPENDIX 8. PID BLOCK A PID block performs the PID control computation based on the deviation of the measured value (PV) from the setpoint (SV), and is generally used for constant-setpoint and cascaded-setpoint control. A8.1 Function Diagram The figure below depicts the function diagram of a PID block.
A8-2 A8.3 Parameters of PID Block NOTE: In the table below, the Write column shows the modes in which the respective parameters can be written. A blank in the Write column indicates that the corresponding parameter can be written in all modes of the PID block. A dash (–) indicates that the corresponding parameter cannot be written in any mode.
36 37 ROUT_OUT TRK_SCALE 38 TRK_IN_D Default (factory setting) 0 100 0 1342 (%) 1 0 39 TRK_VAL 0 40 FF_VAL 0 41 FF_SCALE 42 43 44 45 46 47 FF_GAIN UPDATE_EVT BLOCK_ALM ALARM_SUM ACK_OPTION ALARM_HYS 48 49 50 51 52 53 54 55 56 57 58 59 60 HI_HI_PRI HI_HI_LIM HI_PRI HI_LIM LO_PRI LO_LIM LO_LO_PRI LO_LO_LIM DV_HI_PRI DV_HI_LIM DV_LO_PRI DV_LO_LIM HI_HI_ALM 61 62 Index Parameter Name 100 0 1342 (%) 1 0 Write Valid Range – MAN Switch for output tracking.
A8-4 A8.4 PID Computation Details For PID control, the PID block in a digitalYEWFLO employs the PV-proportional and -derivative type PID control algorithm (referred to as the I-PD control algorithm), or the PV-derivative type PID control algorithm (referred to as the PI-D control algorithm) depending on the mode, as described below.
A8-5 A8.7 Control Action Bypass A8.9 Block Modes The PID control computation can be bypassed so as to set the SP value in the control output OUT as shown below. Setting BYPASS to “On” bypasses the PID control computation. The block mode is set in the parameter MODE_ BLK. MODE_ BLK BYPASS Output CAS_IN RCAS_IN Setpoint Control SP IN Filter Actual Indicates the current mode of the PID block. Permitted Stipulates all the modes that the PID block can enter.
A8.10 Bumpless Transfer Mode Transitions Transition Destination Mode Condition NOT Conditions 1 O/S If O/S is set in MODE_ BLK. target (or if O/S is set in target inside the resource block) 2 IMan If the specified condition is NOT if met (refer to APPENDIX 8.14 condition 1 is “Initialization and Manual met Fallback (IMAN).
A8.12 External-output Tracking • CONTROL_OPTS External tracking is an action of outputting the value of the remote output TRK_VAL set from outside the PID block, as illustrated in the figure below. External tracking is performed when the block mode is LO. Options in CONTROL_OPTS TRK_VAL TRK_SCALE OUT_SCALE OUT This parameter allows BYPASS to be set. SP-PV Track in Man Equalizes SP to PV when MODE_BLK. target is set to Man.
A8-8 A8.15 Manual Fallback A8.16 Auto Fallback Manual fallback denotes an action in which a PID block changes mode to MAN (manual) and suspends the control action. Manual fallback takes place automatically as a means of abnormality handling when the following condition is met: • IN.status is Bad except when the control action bypass is on.
A8-9 Available Setting for SHED_OPT Actions upon Computer Failure A8.18 Alarms Normal shed, normal return Sets MODE_BLK.actual to Cas*, and leaves MODE_BLK.target unchanged. There are two kinds of alarms generated by a PID block: block and process alarms. Normal shed, no return Sets both MODE_BLK.actual and MODE_ BLK.target to Cas*. A8.18.1 Block Alarm (BLOCK_ALM) Shed to Auto, normal return Sets MODE_BLK.actual to Auto**, and leaves MODE_BLK.target unchanged.
A8-10 A8.19 Example of Block Connections AI OUT IN PID BKCAL_IN OUT CAS_IN AO BKCAL_OUT FA0808.ai When configuring a simple PID control loop by combining a digitalYEWFLO with a fieldbus valve positioner that contains an AO block, follow the procedure below to make the settings of the corresponding fieldbus function blocks: 1. Connect the AI block and PID block of the digitalYEWFLO, and the AO block of the valve positioner as shown above. 2. Set MODE_BLK.
A9-1 APPENDIX 9.
A10-1 APPENDIX 10. METHOD A10.1 Transducer Block METHOD is a program to facilitate the parameter settings. Set TR block to “O/S”, for parameter setting by METHOD. (1) Setup Wizard Method Setup Wizard Method Display the start message Auto Check the Mode.
A10-2
A10-3 (2) Noise Balance Wizard Method Noise Balance Wizard Method Display the start message Auto Check the Mode.Actual (automatically judgement) O/S Set the following parameter: NOISE_BALANCE_MODE Auto Manual Tuning at zero Set the following parameters: NOISE_RATIO (automatically judgement) Check the NOISE_BALANCE_ MODE Manual Tuning at zero Display the following parameters: NOISE_BALANCE_MODE NOISE_RATIO TRIGGER_LEVEL Display the end message END FA1003.
A10-4 (4) Flow Adjust Method Flow Adjust Method Display the start message Auto (automatically judgement) Mode.Actual OOS Set the following parameter: FLOW_ADJUST NOT ACTIVE ACTIVE Do you want to set the following parameters: FLOW_ADJ_FREQ FLOW_ADJ_DATA EXIT FLOW_ADJ_DATA FLOW_ADJ_FREQ Set the following parameter: FLOW_ADJ_FREQ(5 elements) *1 Set the following parameters: FLOW_ADJ_DATA(5 elements) *1 Display the end message END *1: Skip mode including FA1005.
A10-5 A10.2 Enhanced AR Block (1) Density Factor Setup Wizard DENSITY FACTOR SETUP WIZARD Display the start message Not Man/OOS (automatically judgement) Mode.Actual Man/OOS Set the following parameters: ARITH_TYPE FA1006.
A10-6 FA1007.
A10-7 (2) Flow Configuration Method Flow Configuration Coef. method Display the start message Display the following parameters: CONFIG_ELEMENT01-16 Do you want to change the Flow Config Parameters? Yes Not Man/OOS (automatically judgement) Mode.Actual Man/OOS Exit Select the Flow Config Coef. display mode Change Flow Config. Parameters Enter an element number to change Show Flow Config.
A10-8 (3) Configuration Memo 2 Method Configuration Memo 2 method Display the end message FA1009.
A11-1 APPENDIX 11. SOFTWARE DOWNLOAD (Option /EE) A11.1 Benefits of Software Download This function enables you to download software to field devices via a FOUNDATION Fieldbus to update their software. Typical uses are to add new features such as function blocks to existing devices, and to optimize existing field devices for your plant. Update Program I/O New Diagnostics PID AI AI FA1101.ai Figure A11.1 Concept of Software Downloading A11.
NOTE The download tool can not execute downloading during other system connects to the system/ network management VFD of the device. A11.4 Software Download Sequence The flowchart below outlines the software download procedure.
A11-3 The device type is “0009” for the digitalYEWFLO. The software name is “ORIGINAL” or “UPDATE.” The former indicates an original file and the latter an update file. Whenever performing a download to update the device revision, obtain the original file. In general, an addition to the parameters or blocks requires a device revision update. A11.
A11-4 A11.7 Troubleshooting For information on the download tool’s error messages, see also the software’s User’s Manual. Table A11.2 Problems after Software Update Symptom Cause Remedy An error occurs before starting a download, disabling the download. The selected download file is not for the selected field device. An error occurs after starting a download, disabling the download.
A11-5 Table A11.
A11-6 A11.9 System/Network Management VFD Parameters Relating to Software Download A11.9.1 Parameter List Table A11.5 System/Network Management VFD Parameters Write Mode: R/W = read/write; R = read only Index (SM) 400 410 420 430 440 Parameter Name DWNLD_PROPERTY DOMAIN_DESCRIPTOR DOMAIN_HEADER.1 DOMAIN_HEADER.
A11-7 A11.9.2 Descriptions for Parameters IMPORTANT Do not turn off the power to a field device immediately after changing parameter settings. Data writing actions to the EEPROM are dual redundant to ensure reliability. If the power is turned off within 60 seconds after setup, the parameters may revert to the previous settings. (1) DWNLD_PROPERTY Sub Index Element Size (Bytes) Description 1 Download Class 1 Indicates the download class.
A11-8 (2) DOMAIN_DESCRIPTOR Sub Index Element Size (Bytes) Description 1 Command 1 Reads/writes software download commands. 1: PREPARE_FOR_DWNLD (instruction of download preparation) 2: ACTIVATE (activation instruction) 3: CANCEL_DWNLD (instruction of download cancellation) 2 State 1 Indicates the current download status.
A12-1 APPENDIX 12. DEVICEVIEWER WINDOW EXECUTED FROM PRM (Plant Resource Manager) With DeviceViewer, it is possible to display whether or not the hardware status and configuration are normal as the result of self-diagnosis performed by an FF-H1 device. (Please refer to IM 33Y05Q10-11E.) The following figure shows an example of the DeviceViewer window displayed for the digitalYEWFLO module.
A12-2 Table A12.1 Hardware Failure Alarm item AMP. Module Failure 1 (AL-01) Alarm No. Description Parameter AL-01 The EEPROM(S) failed. (AL-01) [Remedy]: Contact the nearest office or service center. RS DEVICE_ STATUS_2 bit0 COM. Circuit Failure 1 (AL-02) AL-02 The serial communication circuit in the amplifier failed (type 1 error). (AL-02) [Remedy]: Contact the nearest office or service center.
A12-3 Table A12.3 Configuration(Mandatory) Alarm item RB in O/S Mode (AL-21) TB in O/S Mode (AL-22) Alarm No. Description Parameter AL-21 Resource Block is in O/S mode. (AL-21) [Remedy]: Change the RB Block Mode. Target (RB.MODE_BLK.Target) to Auto mode. RS DEVICE_ STATUS_1 bit22 AL-22 Transducer Block is in O/S mode. (AL-22) [Remedy]: Change the TB Block Mode. Target (TB.MODE_BLK.Target) to Auto mode.
Alarm item Alarm No. Description A12-4 Parameter DI2 in O/S Mode (AL-26) AL-26 DI2 Block is in O/S mode. (AL-26) [Remedy]: Change the DI2 Block Mode. Target (DI2.MODE_BLK.Target) to Auto or other mode. In addition, check that RB Block Mode. Actual (RB.MODE_BLK.Actual) is set to Auto mode. DI2 in Man Mode (AL-71) AL-71 DI2 Block is in Manual mode. (AL-71) [Remedy]: Change the DI2 Block Mode. Target (DI2.MODE_BLK.
Alarm item Alarm No. Description A12-5 Parameter AR Flow IN NotConnected (AL-89) AL-89 AR Input (AR.IN) is not connected to the volumetric flow. (AL-89) [Remedy]: Connect the volumetric flow data into AR Input (AR.IN). RS DEVICE_ STATUS_5 bit9 AR Temp. IN NotConnected (AL-90) AL-90 AR Input1 (AR.IN_1) is not connected to the temperature. (AL-90) [Remedy]: Connect the temperature data into AR Input1 (AR.IN_1).
i Revision Information Title: Model DY Vortex Flowmeter Model DYA Vortex Flow Converter Fieldbus Communication Type Manual No.
ii Edition Data Page 7th October 2013 Cover Contents 1-1 to 1-4 2-1 3-1 to 3-2 4-1 4-2 to 4-3 4-4 5-1 to 5-5 5-7 to 5-14 5-13 to 5-14 6-2 to 6-7 7-1 to 7-3 8-1 to 8-3 9-1 to 9-5 10-1 to 10-4 10-5 to 10-13 10-14 A1-1 to A1-11 A2-2 to A2-3 A3-1 to A3-15 A5-2 A5-4 A5-8 A5-9 A5-10 A6-1 A6-3 A6-4 to A6-5 A6-6 A6-8 to A6-9 A6-10 A7-1 A7-3 A7-4 A7-6 A7-8 A8-2 to A8-4 A8-5 to A8-8 A10-1 to A10-8 A11-1 to A11-2 A11-4 A12-1 to A12-5 Revised Item · Addition of logos · Correction · Revision of Chapter 1 · Correct
