CC-LINK Interface: SR83 Digital Controller
CC-LINK Interface: SR83 Digital Controller
CC-LINK Interface: SR83 Digital Controller
CC-LINK Interface
Instruction Manual
Thank you for purchasing our product. Please check that the delivered product is the actual item you ordered. Please do
not begin operating this product until you read this instruction manual thoroughly and understand its contents.
Please ensure that this instruction manual is made easily accessible to the final user of the instrument.
SR80CC-1AE
July 2001
Safety Rules
(Read the following information before you begin to use the apparatus.)
In using this product, please be very careful and observe safety by handling the instrument properly. Only operate this
product by following the instructions presented in this instruction manual and in the related manuals referred to herein.
The safety rules are limited to those that are directly related to the operation of this product. For safety rules
concerning the product as a sequencer system, please refer to the user's manual for the CPU unit made by Mitsubishi
Electric Corporation.
The safety rules are divided between "warnings" and "cautions" reflecting the seriousness of the notice in question.
Warning This heading indicates that improper handling could create a hazardous situation that
could result in severe injury or even death.
Caution This heading indicates that improper handling could create a hazardous situation that
could result in injury or damage to the product or surroundings.
Note that even those matters designated by "caution" could lead to a more serious outcome depending on the
circumstances.
As both headings signify a matter demanding the utmost care and attention, please pay close attention to these notices.
Keep this manual at the work site to be referred to readily whenever necessary and ensure that it is always accessible by
the end user.
Warning
● Should the data link go out of communication, data of the master unit is retained.
In a sequence program, an interlocking circuit should be formed so that the system works on the
safety side by the use of communication status information.
Caution
● Control lines and communication cables should not be bundled with the main power supply cable
and/or power lines or installed adjacently to the latter.
They should be spaced apart by more than 100 mm as a guideline.
Unfamiliar noises may signify an erroneous action.
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Contents
Safety Rules . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 1
Contents ......................................................................2
Chapter 1 Outline
1.1 Outline . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 3
Chapter 2 Specifications
2.1 General specifications . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 3
2.2 Performance specifications . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 3
Chapter 3 Connection
3.1 Special cable for CC-Link. . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 4
3.2 Maximum transmission distance . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 4
3.3 Wiring of data link cable . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 4
3.3.1 Connection of special cable for CC-Link . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 4
3.3.2 Notes on cable connection . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 4
3.4 Wiring . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 5
3.4.1 Wiring for SR83 . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 5
3.4.2 Matters to be attended to in wiring . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 5
3.5 Maintenance and inspection . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 6
Chapter 4 Setting before operation and procedure
4.1 Sequencer setting. . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 7
4.2 SR83 parameter setting . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 7
4.3 Linking to sequencer . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 8
4.3.1 Sequencer areas used for CC-Link . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 8
4.3.2 Notes on sequencer programming . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 8
4.4 Remote input and output signals . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 9
4.4.1 Remote input and output functions . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 9
4.4.2 List of remote input and output signals. . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 10
4.4.3 Details of remote input and output signals . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 11
4.5 Remote register . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 12
4.5.1 Remote register function. . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 12
4.5.2 Allocation of remote register . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 12
4.6 Extended display and extended setting . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 13
4.6.1 Outline of extended display and extended setting . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 13
4.6.2 Extended display/extended setting table. . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 16
Chapter 5 Troubleshooting
5.1 Extended display/extended setting data error codes . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 21
5.2 Lamps for CC-Link communication . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 21
5.3 Lamps for CC-Link communication abnormality . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 21
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Chapter 1 Outline
This instruction manual describes the specifications, names of parts and setting of a CC-Link remote device, that is, the SR83, to
be used in combination with a MELSEC series sequencer CPU made by Mitsubishi Electric Corporation.
1.1 Outline
(1) This instruction manual describes the specifications, handling, programming method, etc., of the SR83 digital controller
(hereinafter to be referred to as the SR83) for use as a remote device station of the CC-Link system.
(2) The SR83 takes in thermocouple, R.T.D., voltage or current input, allows comparison with set temperature and outputs
control signals to an operating device. It is also capable of reading and writing measured temperature values, output values
and various parameter settings.
(3) CC-Link is an abbreviation of "control and communication link" and the abbreviated form is used throughout this instruction
manual.
The CC-Link is a system to connect an input/output unit, an intelligent function unit, a special function unit, and the like
which are installed dispersedly and allows them to be controlled from a sequencer CPU.
1) When various units of a system are installed in a dispersed configuration, wiring for the entire system can be accomplished
economically.
2) ON/OFF information concerning input and output of each unit and numerical data can be received/transmitted easily and
quickly.
3) When a plurality of sequencer CPU's are connected, a simple dispersed system can be constructed.
4) As it is possible to connect various devices produced by the associated manufacturer, customers' systems can be extended
or modified to meet a number of requirements.
Master station
Sequencer
CPU
SR83
Chapter 2 Specifications
This chapter deals with general specifications and performance specifications of the SR83 CC-Link.
Terminal DA DA DA Terminal
resistance DB DB DB resistance
DG DG DG
SLD Special cable SLD Special cable SLD
FG for CC-Link FG for CC-Link FG
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3.4 Wiring
Matters to be noted in wiring and an example of SR83 connection are shown.
SR83 controller 2
21 DA
22 DB
23 DG
24 SLD
25 FG
SR83 controller N
21 DA
22 DB
23 DG
24 SLD
25 FG
Warning
● The SR83 should be used in environmental conditions as stated in the general specifications in its instruction manual.
If it is used in any environment other than that noted in the general specifications, this could cause an electric
shock, fire, erroneous operation, damage to the product or deterioration of its functionality.
● Do not directly touch a conductive part or an electronic component of the SR83 while it is energized.
This could create an electric shock, erroneous operation or other failure.
Caution
● Make sure to ground the FG terminal using the D type (the 3rd grade) or higher grounding. If not, erroneous
operation could result.
● Wire the SR83 correctly after confirming the rated voltage of the product and the terminal arrangement.
Connection to a power source with voltage different from the rated one or with erroneous wiring will create a fire
hazard or failure of the apparatus.
● Tighten the terminal screws within a torque range of M3.5 1.0N•m (10kgf•cm).
(1) If a terminal screw is not sufficiently tightened, it will lead to a short or erroneous operation.
(2) If a terminal screw is tightened excessively, the screw will be broken and it will lead to a short or erroneous
operation.
● Take care not to allow foreign matter, such as the cutting powder from wire chips, to get into the unit. This can
lead to fire, failure or erroneous operation.
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3.5 Maintenance and inspection
Although there is no particular inspection item for the SR83, check the inspection items as described in the Mitsubishi Electric
Corporation Sequencer CPU User's Manual so that your system can always be used under optimal conditions.
Warning
● Do not touch a terminal while the instrument is energized.
This can result in an electric shock or erroneous operation.
● Before cleaning or tightening a terminal screw further, make sure to externally turn off power for all phases.
Without cutoff in all phases, trouble or erroneous operation of the SR83 can result.
Caution
● Do not disassemble or remodel the SR83.
This can lead to trouble, erroneous operation, an injury or a fire.
● The case of the SR83 is made of a plastic resin. It should not be allowed to fall or receive impact shock.
This could result in serious damage to the SR83.
● Mount or remove the SR83 on/from the panel only after turning power off externally for all phases.
Without cutoff in all phases, trouble or erroneous operation of the SR83 could be the result.
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Chapter 4 Setting before operation and procedure
4.1 Sequencer setting
When SR83 setting is carried out through the CC-Link, the SR83 has to be regarded as a remote device occupying one station.
Accordingly, CC-Link setting should be carried out in consideration of the number of units to be connected and the number of
possessory stations.
PV
SV ˚C
SV2 RUN
RUN
OUT1 OUT2 EV1 EV2 EV3 AT MAN SB REM STBY COM COM
AT ENT
SR83 SHIMADEN
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4.3 Linking to sequencer
(1) The SR83, as a remote device, is allocated for I/O in the relay/register area with the master unit.
(2) The allocated I/O area is treated as areas divided by channel. Data are exchanged between the connected SR83 and the
master unit.
RX(n+1)8 1 3
Initial data processing request
RY(n+1)8 2 5
Initial data processing finish
RX(n+1)B 4
Remote READY
RY(n+1)9 1 4
Initial data setting request
RX(n+1)9 3 5
Initial data setting finish
RX(n+1)B
2 6
Remote READY
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4.4 Remote input and output signals
Allocation of input and output signals and the respective functions are described in the following.
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4.4.2 List of remote input and output signals
For data exchange with the master unit, the SR83 uses 32 input points and 32 output points.
Table 4.1 shows the allocation of input and output signals and names of signals.
"RX" in the device numbers indicates that they input signals from the SR83 to the master unit and "RY" indicates that they are output
signals from the master unit to the SR83.
For details of signals, see 4.4.3 "Details of remote input and output signals."
Direction of signal: SR83 → Master unit Direction of signal: Master unit → SR83
Device No. Name of signal Device No. Name of signal
RXn0 Event 1 alarm status* RYn0 [Extension] number setting for display b0
RXn1 Event 2 alarm status* RYn1 b1
RXn2 Burnout status RYn2 b2
RXn3 Heater break alarm status* RYn3 b3
RXn4 PID/AT RYn4 b4
RXn5 RYn5 b5
RXn6 RYn6 [Extension] number setting for setting b0
RXn7 Unused RYn7 b1
RXn8 RYn8 b2
RXn9 RYn9 b3
RXnA Communication mode status RYnA b4
RXnB SV setting remote register selection status RYnB b5
RXnC Extended display finish RYnC Extended display flag
RXnD Extended setting finish RYnD Extended setting flag
RXnE Remote register (RWwm) error flag RYnE Unused
RXnF RYnF
RX(n+1)0 RY(n+1)0
RX(n+1)1 RY(n+1)1
RX(n+1)2 RY(n+1)2
RX(n+1)3 Unusable RY(n+1)3 Unusable
RX(n+1)4 RY(n+1)4
RX(n+1)5 RY(n+1)5
RX(n+1)6 RY(n+1)6
RX(n+1)7 RY(n+1)7
RX(n+1)8 Initial data processing request flag RY(n+1)8 Initial data processing finish flag
RX(n+1)9 Initial data setting finish flag RY(n+1)9 Initial data setting request flag
RX(n+1)A Error status flag RY(n+1)A Error reset request flag
RX(n+1)B Remote READY RY(n+1)B
RX(n+1)C RY(n+1)C
RX(n+1)D RY(n+1)D Unusable
Unusable
RX(n+1)E RY(n+1)E
RX(n+1)F RY(n+1)F
n: Address given to the master unit by station number setting
Turning an unused device ON and OFF, will create no problems for the SR83.
In case an unusable device is turned ON and OFF in a sequence program, the proper functioning of the SR83 will not be
guaranteed.
* Unable to be used unless the optional function is added.
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4.4.3 Details of remote input and output signals
The functions of remote input and output signals are shown in table 4.2.
RYn0 ~ 5 [Extension] number setting for display To set an item desired to be displayed in [extension] area of RWr by
binary notation.
RYn6 ~ B [Extension] number setting for setting To set an item desired to be set in [extension] area of RWw by
binary notation
When display in [extended] area of RWr is intended, this flag turns
RYnC Extended display flag ON upon setting [extended] setting No. for display. It turns OFF upon
confirmation that (RXnC) turns ON when extended display finishes.
When display in [extended] area of RWr is intended, this flag turns
RYnD Extended setting flag ON upon setting [extended] setting No. for display. It turns OFF upon
confirmation that (RXnD) turns ON when extended display finishes.
RY(n+1)8 Initial data processing finish flag To turn ON upon applying power, hardware resetting or finishing of
initial data processing
RY(n+1)9 Initial data setting request flag To turn ON when initial data is to be set or changed
RY(n+1)A Error reset request flag When error reset flag is turned ON, error status flag turns OFF.
n: Address given to master unit by station No. setting
* Unable to be used unless optional function is added.
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4.5 Remote register
The SR83 has a remote register for exchanging data with the master unit. The allocation of the remote register and the structure of
data are described in the following.
Direction of
data transfer Address Description Default value
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4.6 Extended display and extended setting
(1) For extended display and extended setting, the remote output area and the extended area in the remote register are used and
changing of set values and reading of data are carried out from the master unit.
(2) A set value is changed or data is read once for the SR83 in response to each request for extended display or extended setting.
(3) When display or setting is carried out, parameters should be set in the remote register.
(4) A setting number and parameters should be set before scanning to be carried out simultaneously when the "extended display
flag" or the "extended setting flag" is turned ON.
For details of parameters, see 4.6.2 "List of extended display/extended setting."
RYn0 ~ 5 1
Setting an [Extension] No. for display
RYnC 2 5
Extended display flag
RXnC 4 6
Extended display finish flag
RX(n+1)B 3 11
Remote READY
RX(n+1)A 7 9
Error status flag
RY(n+1)A 8 10
Error reset request flag
RWrn+3 12
Extended display
∗ Note: Proceed to the next processing only after confirming that the "remote READY" RX(n+1)B is turned ON.
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● Procedure of extended display
The following is basic timing of extended display.
1 A desired extension number selected from the list of extended setting numbers is written, in the binary notation, by a higher
sequence in the "extended setting numbers" RYn6 ~ RYB of remote I/O.
2 The higher sequence writes data of setting in "extended setting" RWwn+3 of remote register.
3 The higher sequence turns the "extended setting flag" RYnD ON.
4 The SR83 turns the "remote READY" RX(n+1)B of remote I/O OFF.
5 The SR83 turns the "extended setting finish flag" RXnD ON.
6 After confirming that the "extended setting finish flag" RXnD has been turned ON, the higher sequence turns the "extended
setting flag" RYnD OFF.
7 The SR83 turns the "extended setting finish flag" RXnD OFF.
8 If an error arises, the SR83 turns the "error status flag" RX(n+1)A of remote I/O ON. In case it is not turned ON, proceed to 12 .
9 When the "error status flag" RX(n+1)A is ON, the higher sequence turns the "error reset request flag" RY(n+1)A ON.
10 The SR83 turns the "error status flag" RX(n+1)A OFF.
11 The higher sequence turns the "error reset request flag" RY(n+1)A OFF. (To know the contents of the error, read an error
code on an extended display.)
12 The SR83 turns the "remote READY" RX(n+1)B of remote I/O ON.
RYn6 ~ 8 1
Setting of [Extension] No. for setting
RWwn+3 2
Extended setting
RYnD 3 6
Extended setting flag
RXnD 5 7
Extended setting finish
RX(n+1)B 4 12
Remote READY
RX(n+1)A 8 10
Error status flag
RY(n+1)A 9 11
Error reset request flag
∗ Note: Proceed to the next processing only after confirming that the "remote READY" RX(n+1)B is turned ON.
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● Procedure of reading error code during extended display/extended setting
In the event an error arises on an extended display, the previous extended display value remains in the remote register
RWrn+3. (In the case of start-up, it will be 0.)
If an error arises in the extended setting, there will be no writing. Data in the remote register RWwn+3 remains unchanged.
1 The extended display number 61 is written, in the binary notation, by a higher sequence in the "extended display numbers"
RYn0 ~ RYn5 of remote I/O.
2 The higher sequence turns the "extended display flag" RYnC ON.
3 The SR83 turns the "remote READY" RX(n+1)B of remote I/O OFF.
4 The SR83 turns the "extended display finish flag" RXnC ON.
5 After confirming that the "extended display finish flag" RXnC has been turned ON, the higher sequence turns the "extended
display flag" RYnC of remote I/O OFF.
6 The SR83 turns the "extended display finish flag" RXnC OFF.
7 The SR83 turns the "remote READY" RX(n+1)B of remote I/O ON.
8 You can read the error codes read into the remote register RWrn+3 by the high sequence. For the error codes, refer to "Table
5.1 Error code list."
RYn0 ~ 5
1
Setting of [Extension] No. for display
RYnC 2 5
Extended display flag
RXnC 4 6
Extended display finish flag
RX(n+1)B 7
3
Remote READY
RWrn+3 8
Extended display
∗ Note: When power supply to the apparatus is turned OFF, the error codes turn to "0".
RYn6 ~ B
1
Setting of [Extension] No. for setting
RWwn+3 2
Extended setting
RYnD 3 6
Extended setting flag
RXnD 5 7
Extended setting finish
RX(n+1)B 4 8
Remote READY
∗ Note: When power supply to the apparatus is turned OFF, the extension table No. turns to "0."
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4.6.2 Extended display/extended setting table
[Extension] Table (Common to display and setting) Extension table No. [0]
Setting
TBL No. Description Parameter Details of parameter
0 0 Measured temperature value [Setting not possible] PV
0 1 Control output 1 output value [Setting not possible] OUT1
0 2 CT measured value *1 [Setting not possible] HB_A
0 3 Set temperature value SV1 Within SV setting limiter range
(Writing without selecting SV setting remote register for
extended setting results in write mode error.)
0 4 PID/AT AT 0: AC stop: 1: AC in execution
(Writing when AT is allocated for DI results in write mode
error)
0 5 SV1 proportional band (OUT1) P 0(OFF), 0.0 ~ 999.9%
0 6 SV1 integral time (OUT1) I 0(OFF), 1 ~ 6000s
0 7 SV1 derivative time (OUT1) D 0(OFF), 1 ~ 3600s
0 8 PV bias PV_b -1999 ~ 1999Unit
0 9 Event 1 set value *1 EV1_S Higher limit absolute value alarm:
Within range of measured value (PV)
Lower limit absolute value alarm:
Within range of measured value (PV)
0 10 Event 2 set value *1 EV2_S Higher limit deviation value alarm: -1999 ~ 9999Unit
Lower limit deviation value alarm: -1999 ~ 9999Unit
Deviation alarm (inside): 0 ~ 9999Unit
Deviation alarm (outside): 0 ~ 9999Unit
0 11
0 12
0 13 Unusable
0 14
0 15
0 16 Communication mode Comm 0: LOCAL, 1: COMMU (Writing possible even in local mode)
LOC/COMM RUN flag switching
0 17 Stand-by switching StbY 0: EXEC, 1: STNBY
EXE/STBY RUN flag switching (Writing when standby switching is allocated for DI results in
write mode error since DI is given priority.)
0 18 Manual switching Man 0: AUTO, 1: MANUAL
AUTO/MAN RUN switching (Writing when manual switching is allocated for DI results
in write mode error since DI is given priority.)
0 19 SV switching *1 SV_S 0: SV1, 1: SB, SV2
SV1/SB, SV2 RUN flag switching (Writing when SV switching is allocated for DI results in write
mode error since DI is given priority.)
0 20 Remote switching *1 Rem 0: LOCAL, 1: REMOTE
LOC/REM RUN flag switching (Writing when remote switching is allocated for DI results in
write mode error since DI is given priority.)
0 21 Set temperature value (SV2) *1 SV2 Within SV setting limiter range
0 22 Set value bias (SB) *1 Sb -1999 ~ 9999Unit
0 23 Remote input value *1 [Setting not possible] REM
0 24 OUT1 output value in manual operation OUT1 0.0 ~ 100.0%
(Reading and writing possible only in manual operation)
0 25 OUT2 output value in manual operation OUT2 0.0 ~ 100.0%
(Reading and writing possible only in manual operation)
0 26 OUT2 output value *2 [Setting not possible] OUT2
0 27 Hysteresis DF 1 ~ 1000Unit
0 28 Target value function SF 0.00 ~ 1.00
0 29 Manual reset MR -50.0 ~ 50.0%
0 30 SV1 proportional band (OUT2) *2 P_2 0(OFF), 0.0 ~ 999.9%
0 31 SV1 integral time (OUT2) *2 I_2 0(OFF), 1 ~ 6000s
0 32 SV1 derivative time (OUT2) *2 D_2 0(OFF), 1 ~ 3600s
0 33 SV1 hysteresis (OUT2) *2 DF_2 1 ~ 1000Unit
0 34 SV1 dead band (OUT2) *2 DB_2 -1999 ~ 5000Unit
0 35 SV1 target value function (OUT2) *2 SF_2 0.00 ~ 1.00
0 36 SB, SV2 proportional band (OUT1) *1 *2 P21 0(OFF), 0.0 ~ 999.9%
0 37 SB, SV2 integral time (OUT1) *1 *2 I21 0(OFF), 1 ~ 6000s
0 38 SB, SV2 derivative time (OUT1) *1 *2 D21 0(OFF), 1 ~ 3600s
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Setting
TBL No. Description Parameter Details of parameter
0 39 SB, SV2 hysteresis (OUT1) *1 *2 DF21 1 ~ 1000Unit
0 40 SB, SV2 target value function (OUT1) *1 *2 SF21 0.00 ~ 1.00
0 41 SB, SV2 manual reset (OUT1) *1 *2 MR21 -50.0 ~ 50.0%
0 42 SB, SV2 proportional band (OUT2) *1 *2 P22 0(OFF), 0.0 ~ 999.9%
0 43 SB, SV2 integral time (OUT2) *1 *2 I22 0(OFF), 1 ~ 6000s
0 44 SB, SV2 derivative time (OUT2) *1 *2 D22 0(OFF), 1 ~ 3600s
0 45 SB, SV2 hysteresis (OUT2) *1 *2 DF22 1 ~ 1000Unit
0 46 SB, SV2 dead band (OUT2) *1 *2 DB22 -1999 ~ 5000Unit
0 47 SB, SV2 target value function (OUT2) *1 *2 SF22 0.00 ~ 1.00
0 48 Event 1 action type *1 E1_M 0: Higher limit absolute value alarm
1: Lower limit absolute value alarm
2: Higher limit deviation value alarm
3: Lower limit deviation value alarm
4: Deviation alarm (inside)
5: Deviation alarm (outside)
6: Scaleover
(Changing the type of event 1 action will change the set value
of event 1.)
0 49 Event 1 hysteresis *1 E1_d 1 ~ 1000Unit
0 50 Event 1 stand-by type *1 E1_I 0: Without stand-by
1: With stand-by (upon applying power)
2: With stand-by (upon applying power and upon switching from
stand-by to execution
3: With stand-by (upon applying power, upon switching from
stand-by to execution and upon changing SV)
4: With stand-by (at the time of scaleover, alarm action turned
OFF during stand-by)
0 51 Event 1 delay time *1 E1_t 0(OFF), 1 ~ 9999sec
0 52 Event 2 action type *1 E2_M 0: Higher limit absolute value alarm
1: Lower limit absolute value alarm
2: Higher limit deviation value alarm
3: Lower limit deviation value alarm
4: Deviation alarm (inside)
5: Deviation alarm (outside)
6: Scaleover
(Changing the type of event 2 action will change the set value
of event 2.)
0 53 Event 2 hysteresis *1 E2_d 1 ~ 1000Unit
0 54 Event 2 stand-by type *1 E2_I 0: Without stand-by
1: With stand-by (upon applying power)
2: With stand-by (upon applying power and upon switching from
stand-by to execution
3: With stand-by (upon applying power, upon switching from
stand-by to execution and upon changing SV)
4: With stand-by (at the time of scaleover, alarm action turned
OFF during stand-by)
0 55 Event 2 delay time *1 E2_t 0(OFF), 1 ~ 9999sec
0 56 Event 3 action type *1 E3_M 0: Higher limit absolute value alarm
1: Lower limit absolute value alarm
2: Higher limit deviation value alarm
3: Lower limit deviation value alarm
4: Deviation alarm (inside)
5: Deviation alarm (outside)
6: Scaleover
(Changing the type of event 3 action will change the set value
of event 3.)
0 57 Event 3 set value *1 E3_S Higher limit absolute value alarm: Within measuring range
Lower limit absolute value alarm: Within measuring range
Higher limit deviation value alarm: -1999 ~ 9999Unit
Lower limit deviation value alarm: -1999 ~ 9999Unit
Deviation alarm (inside): 0 ~ 9999Unit
Deviation alarm (outside): 0 ~ 9999Unit
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Setting
TBL No. Description Parameter Details of parameter
0 58 Event 3 hysteresis *1 E3_d 1 ~ 1000Unit
0 59 Event 3 stand-by type *1 E3_I 0: Without stand-by
1: With stand-by (upon applying power)
2: With stand-by (upon applying power and upon switching from
stand-by to execution
3: With stand-by (upon applying power, upon switching from
stand-by to execution and upon changing SV)
4: With stand-by (at the time of scaleover, alarm action turned
OFF during stand-by)
0 60 Event 3 delay time *1 E3_t 0(OFF), 1 ~ 9999sec
0 61 Error code [Setting not possible] For details of error codes, see Table 5.1 Error code list.
0 62 SV setting remote register selection 0: Remote register (RWwm)
1: Extended setting (Setting No.)
SV setting remote register selection can be set even when
communication mode is LOC.
0 63 Extension table No. 0: Extension table No. 0
1: Extension table No. 1
Extension table No. can be set even when communication
mode is LOC.
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[Extension] Table (Common to display and setting) Extension table No. [1]
Setting
TBL No. Description Parameter Details of parameter
1 0 Measured temperature value (PV) [Setting not possible] PV
1 1 Control output 1 output value [Setting not possible] OUT1
1 2 CT measured value *1 [Setting not possible] HB_A
1 3 Set temperature value SV1 Within SV setting limiter range
(Writing without selecting SV setting remote register for
extended setting results in write mode error.)
1 4 PID/AT AT 0: AT stop, 1: AT in execution
(Writing when AT is allocated for DI results in write mode
error)
1 5 SV1 proportional band (OUT1) P 0(OFF), 0.0 ~ 999.9%
1 6 SV1 integral time (OUT1) I 0(OFF), 1 ~ 6000s
1 7 SV1 derivative time (OUT1) D 0(OFF), 1 ~ 3600s
1 8 PV bias PV_b -1999 ~ 1999Unit
1 9 Event 1 set value *1 EV1_S Higher limit absolute value alarm:
Within range of measured value (PV)
Lower limit absolute value alarm:
Within range of measured value (PV)
1 10 Event 2 set value *1 EV2_S Higher limit deviation value alarm: -1999 ~ 9999Unit
Lower limit deviation value alarm: -1999 ~ 9999Unit
Deviation alarm (inside): 0 ~ 9999Unit
Deviation alarm (outside): 0 ~ 9999Unit
1 11
1 12
1 13 Unusable
1 14
1 15
1 16 Communication mode Comm 0: LOCAL, 1: COMMU (Writing possible even in local mode)
LOC/COMM RUN flag switching
1 17 DI1 Type of action *1 Di1 0: NOP, 1: STB, 2: SV(SB), 3: AT, 4: MAN, 5: DA, 6: STP,
1 18 DI2 Type of action *1 Di2 7: REM
1 19 Type of heater alarm *1 Hb_m 0: LOCK, 1: REAL
1 20 Heater break alarm set value *1 Hb_S 0.0 ~ 50.0A
1 21 Heater loop alarm set value *1 HL_S 0.0 ~ 50.0A
1 22 Upward ramping value *1 rP_u 0(OFF), 1 ~ 9999Unit
1 23 Downward ramping value *1 rP_d 0(OFF), 1 ~ 9999Unit
1 24 Ramp unit *1 rP_U 0: sec, 1: min
1 25 Ramp rate *1 rP_r 0: × 1, 1: × 0.1
1 26 Remote bias *1 rE_b -1999 ~ 1999Unit
1 27 Remote filter *1 rE_F 0 (OFF), 1 ~ 100sec
1 28 Remote point *1 rE_P 0 (OFF), 0.1 ~ 50.0%
1 29 Remote hysteresis *1 rE_d 0.1 ~ 10.0%
1 30 Remote lower limit side scaling value *1 rE_L Within measured value (PV) range
1 31 Remote higher limit side scaling value *1 rE_H Within measured value (PV) range
1 32 Type of SV *1 SV_M 0: NON, 1: SV, 2: SB
1 33 SV set value lower limit limiter *1 SV_L Within measured value (PV) range
1 34 SV set value higher limit limiter *1 SV_H Within measured value (PV) range
1 35 Output characteristics ACT 0: REV, 1: DIR
(Writing when output characteristics is allocated for DI
results in write mode error since DI is given priority.)
1 36 Control output 1 proportional output cycle O_C 1 ~ 120sec
1 37 Control output 2 proportional output cycle *2 O_2C 1 ~ 120sec
1 38 SV1 control output 1 lower limit output limiter O_L 0.0 ~ 99.9%
1 39 SV1 control output 1 higher limit output limiter O_H 0.1 ~ 100.0%
1 40 SV1 control output 2 lower limit output limiter *2 O_2L 0.0 ~ 99.9%
1 41 SV1 control output 2 higher limit output limiter *2 O_2H 0.1 ~ 100.0%
1 42 SB, SV2 control output 1 lower limit output limiter *1 *2 021L 0.0 ~ 99.9%
1 43 SB, SV2 control output 1 higher limit output limiter *1 *2 021H 0.1 ~ 100.0%
1 44 SB, SV2 control output 2 lower limit output limiter *1 *2 022L 0.0 ~ 99.9%
1 45 SB, SV2 control output 2 higher limit output limiter *1 *2 022H 0.1 ~ 100.0%
1 46 Unused
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Setting
TBL No. Description Parameter Details of parameter
1 47 Unused
1 48 Unused
1 49 Unused
1 50 Unused
1 51 Control output 1 error output O_E 0.0 ~ 100.0%
1 52 Control output 2 error output *2 O_2E 0.0 ~ 100.0%
1 53 PV filter PV_F 0(OFF), 1 ~ 100sec
1 54 AT point AT_P 0 ~ 5000Unit
1 55 Keylock Lock 0(OFF): Keylock release
1: Keylock except SV, AT and MAN
2: Keylock except SV
3: Total keylock
1 56 PV scale lower limit side [Setting not possible] PV_L Measuring (PV) range lower limit value
1 57 PV scale higher limit side [Setting not possible] PV_H Measuring (PV) range higher limit value
1 58 PV decimal point position [Setting not possible] DP Measuring (PV) decimal point position
1 59 RUN flag [Setting not possible] EXE_FLG For details, see below.
1 60 EVENT flag *1 [Setting not possible] EXE_EV For details, see below.
1 61 Error codes [Setting not possible] For details of error codes, refer to Table 5.1 Error code list
1 62 SV setting remote register selection 0: Remote register (RWwm)
1: Extended setting (Setting No. 3)
SV setting remote register can be selected even when
communication mode is LOC.
1 63 Extension table No. 0: Extension table No. 0
1: Extension table No. 1
Extension table No. can be set even when communication mode
is LOC.
• The error codes and the extension No. turn to "0" when power supply to the apparatus is turned OFF.
*1 Unusable unless the optional function is added. (ERR to be displayed)
*2 Unusable unless the instrument is of the two output type. (ERR to be displayed)
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Chapter 5 Troubleshooting
5.1 Extended display/extended setting data error codes
(1) When extended display data is read from the sequencer CPU or data is written in the extended setting, the SR83 checks
specifications, whether or not of optional functions, write mode, execution command, range of data and the like and if an
error arises, it stores an error code in a 16-bit binary value through extended display in the the remote register RWrn+3.
For details of error codes, please refer to Table 5.1 Error code list.
(2) For resetting the error codes, turn the "error reset request" RY(n+1)A ON, and the SR83 turns the "error status flag"
RX(n+1)A OFF.
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MEMO
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MEMO
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