Ogden ETR-8300 User manual
PK488-OMC57
Model ETR-8300
Microprocessor Based
SMARTER LOGIC®Temperature Control
INSTRUCTION MANUAL
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Warning SymbolWarning Symbol
Use the ManualUse the Manual
This Symbol calls attention to an operating procedure, practice, or the like, which, if not correctly performed or
adhered to, could result in personal injury or damage to or destruction of part or all of the product and system.
Do not proceed beyond a warning symbol until the indicated conditions are fully understood and met.
This Symbol calls attention to an operating procedure, practice, or the like, which, if not correctly performed or
adhered to, could result in personal injury or damage to or destruction of part or all of the product and system.
Do not proceed beyond a warning symbol until the indicated conditions are fully understood and met.
Installers
Basic Function User
Enhanced Function User
System Designer
Expert User
Installers
Basic Function User
Enhanced Function User
System Designer
Expert User
Read Chapter 1, 2
Read Chapter 1, 3, 5
Read Chapter 1, 3, 4, 5
Read All Chapters
Read Page 11
Read Chapter 1, 2
Read Chapter 1, 3, 5
Read Chapter 1, 3, 4, 5
Read All Chapters
Read Page 11
3
CONTENTS
Chapter 1 OverviewChapter 1Overview
1-1 Features
1-2 Ordering Code
1-3 Programming Port and DIP Switch
1-4 Keys and Displays
1-5 Menu Overview
1-6 System Modes
1-7 Parameter Description
1-1 Features
1-2 Ordering Code
1-3 Programming Port and DIP Switch
1-4 Keys and Displays
1-5 Menu Overview
1-6 System Modes
1-7 Parameter Description
Page NoPage No Page NoPage No
Chapter 2 InstallationChapter 2Installation
2-1 Unpacking
2-2 Mounting
2-3 Wiring Precautions
2-4 Power Wiring
2-5 Sensor Installation Guidelines
2-6 Thermocouple Input Wiring
2-7 RTD Input Wiring
2-8 Linear DC Input Wiring
2-9 CT / Heater Current Input Wiring
2-10 Event Input wiring
2-11 Output 1 Wiring
2-12 Output 2 Wiring
2-13 Alarm 1 Wiring
2-14 Alarm 2 Wiring
2-15 RS-485
2-16 RS-232
2-17 Analog Retransmission
2-18 Programming Port
2-1 Unpacking
2-2 Mounting
2-3 Wiring Precautions
2-4 Power Wiring
2-5 Sensor Installation Guidelines
2-6 Thermocouple Input Wiring
2-7 RTD Input Wiring
2-8 Linear DC Input Wiring
2-9 CT / Heater Current Input Wiring
2-10 Event Input wiring
2-11 Output 1 Wiring
2-12 Output 2 Wiring
2-13 Alarm 1 Wiring
2-14 Alarm 2 Wiring
2-15 RS-485
2-16 RS-232
2-17 Analog Retransmission
2-18 Programming Port
Chapter 3 Programming the Basic FunctionChapter 3Programming the Basic Function
3-1 Input 1
3-2 OUT1 & OUT2 Types
3-3 Rearrange User Menu
3-4 Heat Only Control
3-5 Cool Only Control
3-6 Heat - Cool Control
3-7 Dwell Timer
3-8 Process Alarms
3-9 Deviation Alarms
3-10 Deviation Band Alarms
3-11 Heater Break Alarm
3-12 Loop Break Alarm
3-13 Sensor Break Alarm
3-14 SP1 Range
3-15 PV1 Shift
3-16 Failure Transfer
3-17 Bumpless Transfer
3-18 Self-tuning
3-19 Auto-tuning
3-20 Manual Tuning
3-1 Input 1
3-2 OUT1 & OUT2 Types
3-3 Rearrange User Menu
3-4 Heat Only Control
3-5 Cool Only Control
3-6 Heat - Cool Control
3-7 Dwell Timer
3-8 Process Alarms
3-9 Deviation Alarms
3-10 Deviation Band Alarms
3-11 Heater Break Alarm
3-12 Loop Break Alarm
3-13 Sensor Break Alarm
3-14 SP1 Range
3-15 PV1 Shift
3-16 Failure Transfer
3-17 Bumpless Transfer
3-18 Self-tuning
3-19 Auto-tuning
3-20 Manual Tuning
Chapter 4 Programming the Full FunctionChapter 4Programming the Full Function
4-1 Event Input
4-2 Second Set Point
4-3 Second PID Set
4-4 Ramp & Dwell
4-5 Remote Set Point
4-6 Differential Control
4-7 Output Power Limits
4-8 Data Communication
4-9 Analog Retransmission
4-10 Digital Filter
4-11 Sleep Mode
4-12 Pump Control
4-13 Remote Lockout
4-1 Event Input
4-2 Second Set Point
4-3 Second PID Set
4-4 Ramp & Dwell
4-5 Remote Set Point
4-6 Differential Control
4-7 Output Power Limits
4-8 Data Communication
4-9 Analog Retransmission
4-10 Digital Filter
4-11 Sleep Mode
4-12 Pump Control
4-13 Remote Lockout
Chapter 5 ApplicationsChapter 5Applications
5-1 Pump / Pressure Control
5-2 Variable Period Full Wave SSR ( VPFW SSR )
5-3 Heat Only Control
5-4 Cool Only Control
5-5 Heat - Cool Control
5-6 Ramp & Dwell
5-7 Remote Set Point
5-8 Differential Control
5-9 Dual Set Point / PID
5-10 RS-485
5-11 RS-232
5-12 Retransmit
5-1 Pump / Pressure Control
5-2 Variable Period Full Wave SSR ( VPFW SSR )
5-3 Heat Only Control
5-4 Cool Only Control
5-5 Heat - Cool Control
5-6 Ramp & Dwell
5-7 Remote Set Point
5-8 Differential Control
5-9 Dual Set Point / PID
5-10 RS-485
5-11 RS-232
5-12 Retransmit
Chapter 6 CalibrationChapter 6Calibration
Appendix
Chapter 7 Error Codes & Troubleshooting
Chapter 7Error Codes &Troubleshooting
Chapter 8 SpecificationsChapter 8Specifications
A-1 Menu Existence Conditions
A-2 Factory Menu Description
A-3 Glossary
A-4 Index
A-5 Memo
A-6 Warranty
A-1 Menu Existence Conditions
A-2 Factory Menu Description
A-3 Glossary
A-4 Index
A-5 Memo
A-6 Warranty
3-21 Signal Conditioner DC Power Supply
3-22 Manual Control
3-23 Display Mode
3-24 Heater Current Monitoring
3-25 Reload Default Values
3-21 Signal Conditioner DC Power Supply
3-22 Manual Control
3-23 Display Mode
3-24 Heater Current Monitoring
3-25 Reload Default Values
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Chapter 1 OverviewChapter 1 Overview
1 1 Features1 1 Features
The ETR 8300
Fuzzy Logic
SEL1 to SEL5
- Fuzzy Logic plus PID microprocessor-based controller, incorporates a
bright, easy to read 4-digit LED display, indicating process value. The
technology enables a process to reach a predetermined set point in the shortest time,
with minimal overshoot during power-up or external load disturbance. The units are
housed in a 1/4 DIN case, measuring 96 mm x 96 mm with 53 mm behind panel depth.
The units feature three touch keys to select the various control and input parameters.
Using a unique function, you can place 5 parameters in front of the user menu by using
contained in the setup menu. This is particularly useful to OEM's as the
controller’s menu can be set to suit the specific application.
The ETR 8300
Fuzzy Logic
SEL1 to SEL5
- Fuzzy Logic plus PID microprocessor-based controller, incorporates a
bright, easy to read 4-digit LED display, indicating process value. The
technology enables a process to reach a predetermined set point in the shortest time,
with minimal overshoot during power-up or external load disturbance. The units are
housed in a 1/4 DIN case, measuring 96 mm x 96 mm with 53 mm behind panel depth.
The units feature three touch keys to select the various control and input parameters.
Using a unique function, you can place 5 parameters in front of the user menu by using
contained in the setup menu. This is particularly useful to OEM's as the
controller’s menu can be set to suit the specific application.
The ETR 8300
ETR 8300
18-bit A to D fast sampling rate ETR 8300
- is powered by a 90 - 264 VAC or 11-26 VAC/VDC supply, incorporating dual
2 amp. output control relays and dual 2 amp. alarm relays as standard. Alternative output
options include SSR drive, triac, 4 - 20 mA and0-10volts. The - is field
programmable for PT100, thermocouple types J, K, T, E, B, R, S, N, L, 0 - 20mA, 4 -20mA
and voltage signal inputs, with no need to modify the unit. The input signals are digitized
by using an converter. Its allows the - to control
fast processes such as pressure and flow. A standard feature, self- tune can be used to
optimize the control parameters as soon as an undesired control result is observed.
Unlike auto-tune, Self-tune will produce less disturbance to the process during tuning and
can be used any time.
The ETR 8300
ETR 8300
18-bit A to D fast sampling rate ETR 8300
- is powered by a 90 - 264 VAC or 11-26 VAC/VDC supply, incorporating dual
2 amp. output control relays and dual 2 amp. alarm relays as standard. Alternative output
options include SSR drive, triac, 4 - 20 mA and 0 - 10 volts. The - is field
programmable for PT100, thermocouple types J, K, T, E, B, R, S, N, L, 0 - 20mA, 4 -20mA
and voltage signal inputs, with no need to modify the unit. The input signals are digitized
by using an converter. Its allows the - to control
fast processes such as pressure and flow. A standard feature, self- tune can be used to
optimize the control parameters as soon as an undesired control result is observed.
Unlike auto-tune, Self-tune will produce less disturbance to the process during tuning and
can be used any time.
High accuracy 18-bit input A D
High accuracy 15-bit output D A
Fast input sample rate ( 5 times / second)
Two complexity level choices
Easy to use menus
Pump control
Fuzzy + PID microprocessor-based control
Automatic programming
Differential control
Auto-tune function
Self-tune function
Sleep mode function
" Soft-start " ramp and dwell timer
Programmable inputs( thermocouple, RTD, mA, VDC )
Analog input for remote set point and CT
Event input for changing function & set point
Programmable digital filter
Hardware lockout + remote lockout protection
Loop break alarm
Heater break alarm
Sensor break alarm + Bumpless transfer
RS-485, RS-232 communication
Analog retransmission
Signal conditioner DC power supply
A wide variety of output modules available
Safety UL / CSA / IEC1010 1
EMC / CE EN61326
High accuracy 18-bit input A D
High accuracy 15-bit output D A
Fast input sample rate ( 5 times / second)
Tw o complexity level choices
Easy to use menus
Pump control
Fuzzy + PID microprocessor-based control
Automatic programming
Differential control
Auto-tune function
Self-tune function
Sleep mode function
"Soft-start " ramp and dwell timer
Programmable inputs( thermocouple, RTD, mA, VDC )
Analog input for remote set point and CT
Event input for changing function & set point
Programmable digital filter
Hardware lockout + remote lockout protection
Loop break alarm
Heater break alarm
Sensor break alarm + Bumpless transfer
RS-485, RS-232 communication
Analog retransmission
Signal conditioner DC power supply
Awide variety of output modules available
Safety UL / CSA / IEC1010 1
EMC / CE EN61326
Unique
Valuable
Unique
Valuable
4
Although PID control has been used and proven to be an efficient controlling method by
many industries, PID tuning is difficult to achieve with some sophisticated systems such
as second and higher order systems, long time-lag systems, during set point change
and/or load disturbances. The PID principle is based on a mathematic model which is
obtained by tuning the process. Unfortunately, many systems are too complex to pre-
cisely describe in numerical terms. In addition, these systems may vary from time to time.
In order to overcome the imperfection of PID control, Fuzzy Technology was introduced.
What is Fuzzy Control? For example, take an automobile driver. Under different
speeds and circumstances, he can control a car well based on prior experience. The
driver does not need an in depth knowledge in the applied science of kinetic theory.
Fuzzy Logic like our driver from above uses a linguistic control which is different from the
numerical PID control. It controls the system based on experience and does not need to
analyze process metrics as does PID.
Although PID control has been used and proven to be an efficient controlling method by
many industries, PID tuning is difficult to achieve with some sophisticated systems such
as second and higher order systems, long time-lag systems, during set point change
and/or load disturbances. The PID principle is based on a mathematic model which is
obtained by tuning the process. Unfortunately, many systems are too complex to pre-
cisely describe in numerical terms. In addition, these systems may vary from time to time.
In order to overcome the imperfection of PID control, Fuzzy Technology was introduced.
What is Fuzzy Control? For example, take an automobile driver. Under different
speeds and circumstances, he can control a car well based on prior experience. The
driver does not need an in depth knowledge in the applied science of kinetic theory.
Fuzzy Logic like our driver from above uses a linguistic control which is different from the
numerical PID control. It controls the system based on experience and does not need to
analyze process metrics as does PID.
5
Digital communications RS-485, RS-232 or 4 - 20 mA retransmission are available as an
additional option. These options allow the ETR-8300 to be integrated with a supervisory
control system and software, or alternatively drive a remote display, chart recorder or
data-logger.
Digital communications RS-485, RS-232 or 4 - 20 mA retransmission are available as an
additional option. These options allow the ETR-8300 to be integrated with a supervisory
control system and software, or alternatively drive a remote display, chart recorder or
data-logger.
Three different ETR 1.
2.
3.
methods can be used to program the -8300: Use the ETR keys on
the front panel to program the unit manually, Use a PC and setup software to program
the unit via an RS-485 or RS-232 COMM port or Use the P12A, a hand-held program-
mer, to program the unit via programming port.
Three different ETR 1.
2.
3.
methods can be used to program the -8300: Use the ETR keys on
the front panel to program the unit manually, Use a PC and setup software to program
the unit via an RS-485 or RS-232 COMM port or Use the P12A, a hand-held program-
mer, to program the unit via programming port.
PROCESS
PID
FUZZY
MV PV
_
+
SV
+
+
Fuzzy Rule
Fuzzy Inference
Engine
DefuzzifierFuzzifier
Digital
information
Language
information
Digital
information
Figure 1.1
Fuzzy PID System Block
Figure 1.1
Fuzzy PID System Block
The function of Fuzzy(Smarter) Logic is to adjust the PID parameters internally in order
to manipulate the output value (MV) and adapt to various processes.
The function of Fuzzy(Smarter) Logic is to adjust the PID parameters internally in order
to manipulate the output value (MV) and adapt to various processes.
The Fuzzy Rule works like this:
If temperature difference is large, and temperature rate is large, then MV is large.
If temperature difference is large, and temperature rate is small, then MV is small.
The Fuzzy Rule works like this:
If temperature difference is large, and temperature rate is large, then MV is large.
If temperature difference is large, and temperature rate is small, then MV is small.
PID + FUZZY CONTROLPID + FUZZY CONTROL
Warm Up Load Disturbance
PID control with properly tuned
PID + Fuzzy control
Set point
Temperature
Time
Figure 1.2 Fuzzy PID
Enhances Control
Stability
Figure 1.2 Fuzzy PID
Enhances Control
Stability
6
PID + Fuzzy Control has been proven to be an efficient method to improve process
stability as shown by the comparison curves below:
PID + Fuzzy Control has been proven to be an efficient method to improve process
stability as shown by the comparison curves below:
Accessories
CT94-1 =0-50Amp. AC Current Transformer
OM95-3 = Isolated4-20mA/0-20mAAnalog Output Module
OM95-4 = Isolated1-5V/0-5VAnalog Output Module
OM95-5 = Isolated 0 - 10V Analog Output Module
OM94-6 = Isolated 1A / 240VAC Triac Output Module ( SSR )
DC94-1 = Isolated 20V / 25mA DC Output Power Supply
DC94-2 = Isolated 12V / 40mA DC Output Power Supply
DC94-3 = Isolated 5V / 80mA DC Output Power Supply
CM94-1 = Isolated RS-485 Interface Module
CM94-2 = Isolated RS-232 Interface Module
CM94-3 = Isolated4-20mA/0-20mARetransmission Module
CM94-4 = Isolated1-5V/0-5VRetransmission Module
CM94-5 = Isolated 0 - 10V Retransmission Module
CC94-1 = RS-232 Interface Cable (2M)
= ETR-8300 User's Manual
CT94-1 = 0 - 50 Amp. AC Current Transformer
OM95-3 = Isolated 4 - 20 mA / 0 - 20 mA Analog Output Module
OM95-4 = Isolated 1 - 5V / 0 - 5V Analog Output Module
OM95-5 = Isolated 0 - 10V Analog Output Module
OM94-6 = Isolated 1A / 240VAC Triac Output Module ( SSR )
DC94-1 = Isolated 20V / 25mA DC Output Power Supply
DC94-2 = Isolated 12V / 40mA DC Output Power Supply
DC94-3 = Isolated 5V / 80mA DC Output Power Supply
CM94-1 = Isolated RS-485 Interface Module
CM94-2 = Isolated RS-232 Interface Module
CM94-3 = Isolated 4 - 20 mA / 0 - 20 mA Retransmission Module
CM94-4 = Isolated 1 - 5V / 0 - 5V Retransmission Module
CM94-5 = Isolated 0 - 10V Retransmission Module
CC94-1 = RS-232 Interface Cable (2M)
=ETR-8300 User's Manual
Power InputPower Input
4: 90 - 264 VAC, 50/60 HZ
5: 11 - 26 VAC or VDC
4: 90 - 264 VAC, 50/60 HZ
5: 11 - 26 VAC or VDC
0: None
1: RS-485
2: RS-232
3: Retransmit 4-20mA
/0-20mA
4: Retransmit1-5V
/0-5V
5: Retransmit0-10V
0: None
1: RS-485
2: RS-232
3: Retransmit 4-20mA
/0-20mA
4: Retransmit 1 - 5V
/0 - 5V
5: Retransmit 0 - 10V
Communications
1: Standard Input
Input 1 - Universal Input
Thermocouple: J, K, T, E, B,
R, S, N, L
RTD: PT100 DIN, PT100 JIS
Current: 4 - 20mA,0-20mA.
Voltage:0-1V,0-5V,1-5V,
0 - 10V
Input2-CTandAnalog Input
CT:0-50Amp. AC Current
Transformer
Analog Input:4-20mA,
0 - 20mA,0-1V,0-5V,
1-5V,0-10V.
Input 3 - Event Input ( EI )
1: Standard Input
Input 1 - Universal Input
Thermocouple: J, K, T, E, B,
R, S, N, L
RTD: PT100 DIN, PT100 JIS
Current: 4 - 20mA, 0 - 20 mA.
Voltage: 0 - 1V, 0 - 5V, 1 - 5V,
0- 10V
Input 2 - CT and Analog Input
CT: 0 - 50 Amp. AC Current
Transformer
Analog Input: 4 - 20 mA,
0- 20mA, 0 - 1V, 0 - 5V,
1- 5V, 0 - 10V.
Input 3 - Event Input ( EI )
Signal InputSignal Input
0: None
1: Relay 2A/240VAC
2: Pulsed voltage to
drive SSR, 5V/30mA
3: Isolated
4-20mA/0-20mA
4: Isolated1-5V/0-5V
5: Isolated0-10V
6: Triac Output
1A / 240VAC,SSR
C: Pulsed voltage to drive
SSR 14V / 30mA
0: None
1: Relay 2A/240VAC
2: Pulsed voltage to
drive SSR, 5V/30mA
3: Isolated
4- 20mA / 0 - 20mA
4: Isolated 1 - 5V / 0 - 5V
5: Isolated 0 - 10V
6: Triac Output
1A / 240VAC,SSR
C: Pulsed voltage to drive
SSR 14V / 30mA
Output 1Output 1
2A / 240VAC2A / 240VAC
1: Form C Relay1: Form C Relay
0: None0: None
Alarm 1Alarm 1
1 2 3 4 57
0: None
1: Relay 2A/240VAC
2: Pulsed voltage to
drive SSR, 5V / 30mA
3: Isolated4-20mA/0-20mA
4: Isolated1-5V/0-5V
5: Isolated0-10V
6: Triac Output, 1A / 240VAC, SSR
7: Isolated 20V / 25mA DC
Output Power Supply
8: Isolated 12V / 40 mA DC
Output Power Supply
9: Isolated 5V / 80mA DC
Output Power Supply
C: Pulsed voltage 14V / 30mA
0: None
1: Relay 2A/240VAC
2: Pulsed voltage to
drive SSR, 5V / 30mA
3: Isolated 4 - 20mA / 0 - 20mA
4: Isolated 1 - 5V / 0 - 5V
5: Isolated 0 - 10V
6: Triac Output, 1A / 240VAC, SSR
7: Isolated 20V / 25mA DC
Output Power Supply
8: Isolated 12V / 40 mA DC
Output Power Supply
9: Isolated 5V / 80mA DC
Output Power Supply
C: Pulsed voltage 14V / 30mA
Output 2Output 2
ETR-8300-
1 2 Ordering Code1 2 Ordering Code
ETR-8300-4111101
90 - 264 operating voltage
Input: Standard Input
Output 1: Relay
Output 2: Relay
Alarm 1: Form C Relay
RS- 485 Communication Interface
ETR-8300-4111101
90 - 264 operating voltage
Input: Standard Input
Output 1: Relay
Output 2: Relay
Alarm 1: Form C Relay
RS- 485 Communication Interface
SNA10B = Smart Network Adaptor for BC-Net
Software, Converts 255 channels
of RS-485 or RS-422 to RS-232
Network
VPFW20 = 20 Amp. Variable Period Full
Wave SSR AC Power Module
VPFW50 = 50 Amp. Variable Period Full
Wave SSR AC Power Module
VPFW100 =100 Amp. Variable Period Full
Wave SSR AC Power Module
SNA10B = Smart Network Adaptor for BC-Net
Software, Converts 255 channels
of RS-485 or RS-422 to RS-232
Network
VPFW20 = 20 Amp. Variable Period Full
Wave SSR AC Power Module
VPFW50 = 50 Amp. Variable Period Full
Wave SSR AC Power Module
VPFW100 =100 Amp. Variable Period Full
Wave SSR AC Power Module
P12A = Hand-held Programmer for ETR
Series Controller
P12A = Hand-held Programmer for ETR
Series Controller
SNA10A = Smart Network Adaptor for Third
Party Software, Converts 255
channels of RS-485 or RS-422 to
RS-232 Network
SNA10A = Smart Network Adaptor for Third
Party Software, Converts 255
channels of RS-485 or RS-422 to
RS-232 Network
Example
7
Related ProductsRelated Products
Range set by front keyboard
Need to order an accessory CT94-1 if
Heater Break detection is required.
Range set by front keyboard
Need to order an accessory CT94-1 if
Heater Break detection is required.
**
**
**
*
*
*
*
*
6
2A / 240VAC2A / 240VAC
1: Relay1: Relay
0: None0: None
Alarm 2Alarm 2
Front
Panel
Rear
Terminal
1 3 Programming Port and DIP Switch1 3 Programming Port and DIP Switch
Figure 1.3 Access Hole
Overview
Figure 1.3 Access Hole
Overview
Table 1.1 DIP Switch
Configuration
Table 1.1 DIP Switch
Configuration
TC, RTD, mV
0-1V, 0-5V, 1-5V, 0-10V
0-20 mA, 4-20 mA
Input 1
Select
Input 1
Select
All parameters are Unlocked
Only SP1, SEL1 SEL5 are unlocked
Only SP1 is unlocked
All Parameters are locked
Lockout
1234
DIP SwitchDIP Switch
:ON :OFF
Factory Default SettingFactory Default Setting
8
*
*
The programming port is used for off-line automatic setup and testing
procedures only. Don't attempt to make any connection to these pins when the
unit is used for a normal control purpose.
The programming port is used for off-line automatic setup and testing
procedures only. Don't attempt to make any connection to these pins when the
unit is used for a normal control purpose.
When the unit leaves the factory, the DIP switch is set so that TC & RTD are selected for input
1 and all parameters are unlocked.
When the unit leaves the factory, the DIP switch is set so that TC & RTD are selected for input
1 and all parameters are unlocked.
Lockout function is used to disable the adjustment of parameters as well as operation of
calibration mode. However, the menu can still be viewed even under lockout condition.
Lockout function is used to disable the adjustment of parameters as well as operation of
calibration mode. However, the menu can still be viewed even under lockout condition.
SEL1- SEL5 represent those parameters which are selected by using SEL1, SEL2,...SEL5
parameters contained in the Setup menu. Parameters selected are then allocated at the
beginning of the user menu.
SEL1- SEL5 represent those parameters which are selected by using SEL1, SEL2,...SEL5
parameters contained in the Setup menu. Parameters selected are then allocated at the
beginning of the user menu.
Access Hole
The programming port is used to connect to
the P12A hand-held programmer for automatic
programming, also can be connected to ATE
system for automatic testing & calibration.
The programming port is used to connect to
the P12A hand-held programmer for automatic
programming, also can be connected to ATE
system for automatic testing & calibration.
ON DIP
1234
Process Unit IndicatorProcess Unit Indicator
Upper Display,
to display process value,
menu symbol and error code etc.
Upper Display,
to display process value,
menu symbol and error code etc.
Lower Display,
to display set point value,
parameter value or control
output value etc.
Lower Display,
to display set point value,
parameter value or control
output value etc.
3 Buttons for ease of control
setup and set point adjustment.
3 Buttons for ease of control
setup and set point adjustment.
Output 1 IndicatorOutput 1 Indicator
Table 1.2 Keypad OperationTable 1.2 Keypad Operation
For a number with decimal point the
display will be shifted one digit right:
For a number with decimal point the
display will be shifted one digit right:
-19999 will be displayed by:-19999 will be displayed by:
45536 will be displayed by:45536 will be displayed by:
-9999 will be displayed by:-9999 will be displayed by:
The unit is programmed by using three keys on the front panel. The available key functions are listed in following table.The unit is programmed by using three keys on the front panel. The available key functions are listed in following table.
Press and release quickly to increase the value of parameter.
Press and hold to accelerate increment speed.
Press and release quickly to decrease the value of parameter.
Press and hold to accelerate decrement speed.
Select the parameter in a direct sequence.
Allow access to more parameters on user menu, also used to Enter manual
mode, auto-tune mode, default setting mode and to save calibration data
during calibration procedure.
Select the parameter in a reverse sequence during menu scrolling.
Select the operation Mode in sequence.
Reset the front panel display to a normal display mode, also used to leave
the specific Mode execution to end up the auto-tune and manual control
execution, and to quit the sleep mode.
The controller enters the sleep mode if the sleep function ( SLEP ) is enabled
( select YES ).
By entering correct security code to allow execution of engineering programs.
This function is used only at the factory to manage the diagnostic reports.
The user should never attempt to operate this function.
Press
for at least 3 seconds
Press
for at least 6 seconds
Press
Press
Press
Press
Press
for at least 3 seconds
Up Key
Down Key
Scroll Key
Enter Key
Start Record Key
Reverse Scroll Key
Mode Key
Reset Key
Sleep Key
Factory Key
TOUCHKEYS FUNCTION DESCRIPTION
Reset historical values of PVHI and PVLO and start to record the peak process
value.
How to display a 5-digit number ?How to display a 5-digit number ?
9
1 4 Keys and Displays1 4 Keys and Displays
: Characters displayed with symbols: Characters displayed with symbols
Figure 1.4 Front Panel DescriptionFigure 1.4 Front Panel Description
Table 1.3 Character LegendTable 1.3 Character Legend
-199.99 will be displayed by -199.9
4553.6 will be displayed by 4553
-199.99 will be displayed by -199.9
4553.6 will be displayed by 4553
For a number without decimal point
the display will be divided into two
alternating phases:
For a number without decimal point
the display will be divided into two
alternating phases:
AEINSX
BFJOTY
CGKPUZ
cHLQV
?
DhMRW=
Output 2 IndicatorOutput 2 Indicator
Alarm 1 IndicatorAlarm 1 Indicator
Alarm 2 IndicatorAlarm 2 Indicator
ETR-8300
Out1 Out2 Alm1 Alm2
Power OnPower On
All segments of display and
indicators are left off for 0.5
second.
All segments of display and
indicators are left off for 0.5
second.
All segments of display and
indicators are lit for 2 seconds.
All segments of display and
indicators are lit for 2 seconds.
Display program code of the
product for 2.5 seconds.
Display program code of the
product for 2.5 seconds.
The left diagram shows program
no. 3 ( for ETR-8300 ) with version
39.
The left diagram shows program
no. 3 ( for ETR-8300 ) with version
39.
Display Date Code and Serial
number for 2.5 seconds.
Display Date Code and Serial
number for 2.5 seconds.
Display the used hours for 2.5
seconds.
Display the used hours for 2.5
seconds.
The left diagram shows that the
unit has been used for 23456.2
hours since production.
The left diagram shows that the
unit has been used for 23456.2
hours since production.
10
Figure 1.5 Display Sequence of
Initial Message
Figure 1.5 Display Sequence of
Initial Message
Program CodeProgram Code
Program No.Program No.
Program VersionProgram Version
Year (2001)Year (2001)
Month (December)Month (December)
Date (31'st)Date (31'st)
Date CodeDate Code
The left diagram shows Year 2001,
Month May(5),Date 22'nd and
Serial number 192. This means that
the product is the 192 'nd unit
produced on May 22'nd, 2001.
Note that the month code stands for
stands for and
stands for .
A
October, B November C
December
The left diagram shows Year 2001,
Month May ( 5 ), Date 22'nd and
Serial number 192. This means that
the product is the 192 'nd unit
produced on May 22'nd, 2001.
Note that the month code stands for
stands for and
stands for .
A
October, B November C
December
ETR-8300
Out1 Out2 Alm1 Alm2
ETR-8300
Out1 Out2 Alm1 Alm2
ETR-8300
Out1 Out2 Alm1 Alm2
ETR-8300
Out1 Out2 Alm1 Alm2
ETR-8300
Out1 Out2 Alm1 Alm2
PV Value
SV Value
User
Menu
User
Menu
Setup
Menu
Setup
Menu
Hand (Manual)
Control
Mode
Hand (Manual)
Control
Mode
Auto-tuning
Mode
Auto-tuning
Mode
Display
Mode
Display
Mode
Default
Setting
Mode
Default
Setting
Mode
Calibration
Mode
Calibration
Mode
Entering these modes will break the control
loop and change some of the previous
setting data. Make sure that the system will
be stable without the controller if these
modes are accessed.
Entering these modes will break the control
loop and change some of the previous
setting data. Make sure that the system will
be stable without the controller if these
modes are accessed.
RAMP
A2DV
A2SP
A1DV
A1SP
TIME
PB1
SHIF
CPB
REFC
TD1
OFST
TI1
TD2
TI2
PB2
SP2
PL2
PL1
A2HY
A1HY
O1HY
SEL1
SEL5
SEL4
SEL3
SEL2
FILE
To execute the
default setting
program
PVHI
PVLO
PV1
PV2
PB
TD
TI
DV
CJCT
PVR
PVRH
PVRL
H
C
SEL1
AOHI
IN1L
SP1H
SP2F
AOLO
DP1
SP1L
AOFN
IN1U
SPMD
STOP
IN1
IN1H
IN2H
SLEP
PARI
IN2L
SELF
FILT
PVMD
EIFN
SEL2
DATA
DP2
BAUD
IN2U
ADDR
IN2
PROT
COMM
FUNC
O1TY
O2TY
A1MD
A2FT
OUT1
OUT2
A1FN
A2MD
O1FT
O2FT
A2FN
CYC1
CYC2
A1FT
SEL5
SEL4
SEL3
H
C
V2G
MA2G
MA1G
SR1
REF1
CJG
CJTL
V1G
ADG
AD0
for 3 seconds
for 3
seconds
for
3 seconds
Press for 3 seconds to enter
the auto-tuning mode
The flow chart shows a complete listing of all parameters.
For actual application the number of available parameters
depends on setup conditions, and should be less
than that shown in the flow chart. See for the
existence conditions of each parameter.
Appendix A-1
The flow chart shows a complete listing of all parameters.
For actual application the number of available parameters
depends on setup conditions, and should be less
than that shown in the flow chart. See for the
existence conditions of each parameter.
Appendix A-1
*1:
You can select at most 5 parameters put in front of the user
menu by using SEL1 to SEL5 contained at the bottom of
setup menu.
You can select at most 5 parameters put in front of the user
menu by using SEL1 to SEL5 contained at the bottom of
setup menu.
*2:
1 5 Menu Overview1 5 Menu Overview
11
*1
*1
*2
Display ReturnDisplay Return
The menu will revert to the
PV/SV display after
except when in the
.
However, the menu will
revert back to the PV / SV
display at any time by
pressing and .
2 minutes
Display
or Manual Mode Menus
The menu will revert to the
PV/SV display after
except when in the
.
However, the menu will
revert back to the PV / SV
display at any time by
pressing and .
2minutes
Display
or Manual Mode Menus
DB
1 6 System Modes1 6 System Modes
The controller performs close loop control under its normal control mode condition.
The controller will maintain its normal control mode when you are operating user menu,
setup menu or display mode, reloading default values or applying an event input
signal. Under certain conditions the control will transfer to an . The
exception modes include :
and All these modes perform in an open loop control except
the auto-tuning mode which performs ON-OFF plus PID close loop control. The mode
transfer is governed by the priority conditions. A lower priority mode can not alter a
higher priority mode, as shown in Figure 1.6.
Exception Mode
Sleep Mode, Manual Mode, Failure Mode, Calibration
Mode Auto-tuning Mode.
The controller performs close loop control under its normal control mode condition.
The controller will maintain its normal control mode when you are operating user menu,
setup menu or display mode, reloading default values or applying an event input
signal. Under certain conditions the control will transfer to an . The
exception modes include :
and All these modes perform in an open loop control except
the auto-tuning mode which performs ON-OFF plus PID close loop control. The mode
transfer is governed by the priority conditions. A lower priority mode can not alter a
higher priority mode, as shown in Figure 1.6.
Exception Mode
Sleep Mode, Manual Mode, Failure Mode, Calibration
Mode Auto-tuning Mode.
Figure 1.6
System Mode Priority
Figure 1.6
System Mode Priority
? Mode? Mode
Sleep Mode?Sleep Mode?
Failure Mode?Failure Mode?
No
No
No
Yes
Yes
Yes
Manual Mode?Manual Mode?
Request
Normal
Control
Mode
Request
Normal
Control
Mode
Request
Auto-tuning
Mode
Request
Auto-tuning
Mode
Request
Calibration
Mode
Request
Calibration
Mode
Priority
High
Low
The calibration mode, auto-tuning mode and normal control mode are in the same
priority level. The sleep mode is in the highest priority.
The calibration mode, auto-tuning mode and normal control mode are in the same
priority level. The sleep mode is in the highest priority.
System Modes
Sleep Mode :
Manual Mode :
Failure Mode :
Calibration Mode :
Auto-tuning Mode :
Normal Control Mode :
See Section 4-11.
See Section 3-22.
See Section 3-16.
See Chapter 6.
See Section 3-19.
See Section 3-23, 3-25, 4-1
System Modes
Sleep Mode :
Manual Mode :
Failure Mode :
Calibration Mode :
Auto-tuning Mode :
Normal Control Mode :
See Section 4-11.
See Section 3-22.
See Section 3-16.
See Chapter 6.
See Section 3-19.
See Section 3-23, 3-25, 4-1
12
1 7 Parameter Description1 7 Parameter Description
Table 1.4 Parameter DescriptionTable 1.4 Parameter Description
Parameter
Description
Parameter
Description Range Default
Value
Default
Value
Contained
in
Contained
in
Basic
Function
Basic
Function
Parameter
Notation
Parameter
Notation
Display
Format
Display
Format
SP1 Set point 1 SP1L SP1H 100.0 °C
(212.0 °F)
TIME 0 6553.5 minutes 0.0
Dwell Time
A1SP 100.0 °C
(212.0 °F)
Alarm 1 Set point
A1DV Alarm 1 Deviation Value -200.0 °C
(-360.0 °F)
10.0 °C
(18.0 °F)
A2SP Alarm 2 Set point 100.0 °C
(212.0 °F)
A2DV Alarm 2 Deviation Value -200.0 °C
(-360.0 ° F)L
10.0 °C
(18.0 °F)
RAMP Ramp Rate 0 0.0
OFST
REFC
SHIF
PB1
TI1User
Menu
Setup
Menu
TD1
Offset Value for P control
PV1 Shift (offset) Value
Proportional Band 1 Value
Integral Time 1 Value
Derivative Time 1 Value
0
0
0
0
0
25.0
100
CPB Cooling Proportional Band
Value 1100
25.0
-200.0 °C
(-360.0 °F)
10.0 °C
(18.0 °F)
0.0
Reference Constant for
Specific Function 2
Low:
Low:
Low:
Low:
Low:
Low:
Low:
Low:
Low:
Low:
Low:
Low:
Low:
Low:
Low:
Low:
Low:
Low:
High:
High:
Low:
200.0 °C
( 360.0 °F)
500.0 °C
(900.0 °F)
100.0 %
60
200.0 °C
( 360.0 °F)
High:
High:
High:
High:
High:
SP2
PB2
TI2
TD2
O1HY
A1HY
A2HY
PL1
PL2
COMM
PROT
Set point 2
Proportional Band 2 Value
Integral Time 2 Value
Derivative Time 2 Value
Output 1 ON-OFF Control
Hysteresis
Hysteresis Control of Alarm 1
Hysteresis Control of Alarm 2
Output 1 Power Limit
Output 2 Power Limit
Function Complexity Level
Communication Interface
Type
COMM Protocol Selection
0
Low: 0
0
0
0.1
0.1
0.1
0
100
100
100
25.0
37.8 °C
(100.0 °F)
1000 sec
360.0 sec
255 %
500.0 °C
(900.0 °F)
200.0 °C
( 360.0 °F)
High:
High:
High:
High:
High:
High:
1000 sec
500.0 °C
(900.0 °F)
High:
High:
High:
High:
High:
High:
High:
100 %
100 %
360.0 sec
55.6 °C
( 100.0 °F)
10.0 °C
(18.0 °F)
10.0 °C
(18.0 °F)
10.0 °C
(18.0 °F)
0.1
0.1
0.1
FUNC
0Basic Function Mode
:
Full Function Mode
:
1
0:No communication function
:
1RS-485 interface
2:RS-232 interface
:
34 - 20 mA analog retransmission
output
4:0 - 20 mA analog retransmission
output
:
50 - 1V analog retransmission
output
6:0 - 5V analog retransmission
output
:
71 - 5V analog retransmission
output
8:
:
0 - 10V analog retransmission
output
1
1
0
See Table 1.5, 1.6
See Table 1.5, 1.7
See Table 1.5, 1.8
0Modbus protocol RTU mode
13
DB Heating-Cooling Dead Band
Negative Value= Overlap -36.0 0
Low: 36.0 %
High:
Parameter
Description
Parameter
Description Range Default
Value
Default
Value
Contained
in
Contained
in
Basic
Function
Basic
Function
Parameter
Notation
Parameter
Notation
Display
Format
Display
Format
:
:
:
:
:
:
:
:
:
:
:
BAUD
DATA
PARI
STOP
AOFN
Baud Rate of Digital COMM
Data Bit count of Digital
COMM
Parity Bit of Digital COMM
Stop Bit Count of Digital
COMM
Analog Output Function
5
1
0
0
0
1
(0)
AOLO
AOHI
Analog Output Low Scale
Value
Analog Output High Scale
Value
-19999
-19999
45536
45536
ADDR
Address Assignment of Digital
COMM
Low:
Low:
Low:
High:
High:
High:
1 255
0
0
1
1
2
2
3
3
4
4
5
5
6
6
7
8
9
0.3 Kbits/s baud rate
0.6 Kbits/s baud rate
1.2 Kbits/s baud rate
2.4 Kbits/s baud rate
4.8 Kbits/s baud rate
9.6 Kbits/s baud rate
14.4 Kbits/s baud rate
19.2 Kbits/s baud rate
28.8 Kbits/s baud rate
38.4 Kbits/s baud rate
07 data bits
:
:
:
:
:
:
:
:
:
:
:
:
:
1 8 data bits
0
1
0
2
1
Even parity
Odd parity
No parity bit
One stop bit
Two stop bits
0:Retransmit IN1 process value
1:Retransmit IN2 process value
4:Retransmit set point value
5:Retransmit output 1 manipulation
value
6:Retransmit output 2 manipulation
value
2:Retransmit IN1 IN2 difference
process value
3:Retransmit IN2 IN1 difference
process value
7:Retransmit deviation(PV-SV)
Value
0°C
(32.0 °F)
100.0 °C
(212.0 °F)
IN1 IN1 Sensor Type Selection
T type thermocouple
E type thermocouple
B type thermocouple
R type thermocouple
S type thermocouple
J type thermocouple
K type thermocouple
Table 1.4 Parameter Description ( continued 2/7 )Table 1.4 Parameter Description (continued 2/7 )
Setup
Menu
14
Low:
Low:
High:
High:
IN2U
DP2
IN2L
IN2H
IN2 Unit Selection
IN2 Decimal Point Selection
IN2 Low Scale Value
IN2 High Scale Value
-19999
-19999
45536
45536
Same as IN1U
Same as DP1
0
1000
2
1
Parameter
Description
Parameter
Description Range Default
Value
Contained
in
Contained
in
Basic
Function
Basic
Function
Parameter
Notation
Parameter
Notation
Display
Format
Display
Format
IN1U
IN1
DP1
IN1L
IN1H
IN1 Unit Selection
IN1 Sensor Type Selection
IN1 Decimal Point Selection
IN1 Low Scale Value
IN1 High Scale Value
-19999
-19999
45536
45536
7
13
4
8
14
5
9
0
15
6
10
1
16
7
11
2
17
12
3
0
0
1
1
2
2
3
N type thermocouple
L type thermocouple
PT 100 ohms DIN curve
PT 100 ohms JIS curve
4 - 20 mA linear current input
0 - 20 mA linear current input
0 - 1V linear Voltage input
0 - 5V linear Voltage input
1 - 5V linear Voltage input
0 - 10V linear Voltage input
Special defined sensor curve
Low:
Low:
High:
High:
0
1000
1
0
(1)
1
(0)
IN2 IN2 Signal Type Selection 1
IN2 no function
Current transformer input
4 - 20 mA linear current input
0 - 20 mA linear current input
0 - 1V linear voltage input
0 - 5V linear voltage input
1 - 5V linear voltage input
0 - 10V linear voltage input
:
:
:
:
:
:
:
:
:
:
:
:
:
:
:
:
:
:
:
:
:
:
:
:
:
:
Degree C unit
Degree F unit
Process unit
No decimal point
1 decimal digit
2 decimal digits
3 decimal digits
Output 1 Function 0
0
OUT1
O1TY
0
1
Reverse (heating ) control action
Direct (cooling) control action
:
:
0
1
2
3
Relay output
Solid state relay drive output
Solid state relay output
4 - 20 mA current module
:
:
:
:
Output 1 Signal Type
Table 1.4 Parameter Description ( continued 3/7 )Table 1.4 Parameter Description (continued 3/7 )
Setup
Menu
15
Parameter
Description
Parameter
Description Range Default
Value
Default
Value
Contained
in
Contained
in
Basic
Function
Basic
Function
Parameter
Notation
Parameter
Notation
Display
Format
Display
Format
4
5
6
7
0 - 20 mA current module
0 - 1V voltage module
0 - 5V voltage module
1 - 5V voltage module
80 - 10V voltage module
:
:
:
:
:
CYC1
O1TY
Output 1 Cycle Time 100.0 sec 18.0
0
0.1
Low: High:
O1FT Output 1 Failure Transfer
Mode
Select BPLS ( bumpless transfer ) or 0.0 ~ 100.0
% to continue output 1 control function as the unit
fails, power starts or manual mode starts.
Select BPLS ( bumpless transfer ) or 0.0 ~ 100.0
% to continue output 2 control function as the unit
fails, power starts or manual mode starts.
BPLS
Output 2 Function
OUT2 0
0
1
3
: PID cooling control
: Output 2 no function
: DC power supply module
installed
O2TY
CYC2
O2FT
Output 2 Signal Type
Output 2 Cycle Time
Output 2 Failure Transfer
Mode
100.0 sec
BPLS
18.0
0
0.1
Same as O1TY
Low: High:
A1FN Alarm 1 Function 2
6IN1 process value high alarm
:
9IN2 process value low alarm
:
0No alarm function
:
4Deviation band out of band alarm
:
1Dwell timer action
:
5Deviation band in band alarm
:
8 IN2 process value high alarm
:
3Deviation low alarm
:
2Deviation high alarm
:
11 IN1 or IN2 process value low
alarm
:
7 IN1 process value low alarm
:
10 IN1 or IN2 process value high
alarm
:
12 IN1 IN2 difference process value
high alarm
:
13 IN1 IN2 difference process value
low alarm
:
:
:
14 Loop break alarm
15 Sensor break or A-D fails
:
:
:
:
1
2
3
0Normal alarm action
Latching alarm action
Hold alarm action
Latching & actionHold
A1MD Alarm 1 Operation Mode 0
Table 1.4 Parameter Description ( continued 4/7 )Table 1.4 Parameter Description (continued 4/7 )
Setup
Menu
16
Output 1 Signal Type
Parameter
Description
Parameter
Description Range Default
Value
Default
Value
Contained
in
Contained
in
Basic
Function
Basic
Function
Parameter
Notation
Parameter
Notation
Display
Format
Display
Format
:
:
SELF Self Tuning Function
Selection
:
:
0
1
Self tune function disabled
Self tune function enabled
SLEP Sleep mode Function
Selection
0Sleep mode function disabled
Sleep mode function enabled
1
0
0
:
:
A1FT
A2FT
A2FN
Alarm 1 Failure Transfer
Mode
Alarm 2 Failure Transfer
Mode
Alarm 2 Function
1
2
0
1
Alarm output OFF as unit fails
Alarm output ON as unit fails
Same as A1FN
Same as A1MD
Same as A1FT
A2MD Alarm 2 Operation Mode 0
1
1
EIFN Event Input Function
3
4
SP2, PB2, TI2, TD2 activated to
replace SP1, PB1, TI1, TD1
Reset alarm 1 output
9
10
Disable Output 1 & Output 2
Lock All Parameters
0Event input no function
:
1 SP2 activated to replace SP1
:
2
PB2, TI2, TD2 activated to replace
PB1, TI1, TD1
:
:
:
5Reset alarm 2 output
:
6Reset alarm 1 & alarm 2
:
7Disable Output 1
:
8Disable Output 2
:
:
:
PVMD PV Mode Selection
:
:
0
1
Use PV1 as process value
Use PV2 as process value
:
2Use PV1 PV2 (difference) as
process value
:
3Use PV2 PV1 (difference) as
process value
0
0
1
2
3
4
0 second time constant
0.2 second time constant
0.5 second time constant
1 second time constant
2 seconds time constant
5 seconds time constant
10 seconds time constant
20 seconds time constant
30 seconds time constant
60 seconds time constant
5
6
7
8
9
:
:
:
:
:
:
:
:
:
:
FILT Filter Damping Time
Constant of PV 2
Table 1.4 Parameter Description ( continued 5/7 )Table 1.4 Parameter Description (continued 5/7 )
Setup
Menu
17
:
:
SP2F Format of set point 2 Value
0
1
set point 2 (SP2) is an actual value
set point 2 (SP2) is a deviation
value
0
Parameter
Description
Parameter
Description Range Default
Value
Default
Value
Contained
in
Contained
in
Basic
Function
Basic
Function
Parameter
Notation
Parameter
Notation
Display
Format
Display
Format
:
:
:
:
:
:
SPMD Set point Mode Selection
0
1
2
3
4
5
Use SP1 or SP2 (depends on EIFN)
as set point
Use minute ramp rate as set point
Use hour ramp rate as set point
Use IN1 process value as set point
Use IN2 process value as set point
Selected for pump control
SEL1 Select 1'st Parameter
0
:
:
:
:
:
:
:
:
:
:
:
:
:
:
:
:
:
:
16
17
18
Parameter PB2 put ahead
Parameter TI2 put ahead
Parameter TD2 put ahead
0
1
2
3
4
5
6
No parameter put ahead
Parameter TIME put ahead
Parameter A1SP put ahead
Parameter A1DV put ahead
Parameter A2SP put ahead
Parameter A2DV put ahead
Parameter RAMP put ahead
Parameter OFST put ahead
Parameter REFC put ahead
Parameter SHIF put ahead
Parameter PB1 put ahead
Parameter TI1 put ahead
Parameter TD1 put ahead
Parameter CPB put ahead
Parameter SP2 put ahead
7
8
9
10
11
12
13
14
15
0
SEL2
SEL3
SEL4
Same as SEL1
Same as SEL1
Same as SEL1
0
0
0
Low:
Low:
High:
High:
SP1L
SP1H
SP1 Low Scale Value
SP1 High Scale Value
-19999
-19999
45536
45536
0°C
(32.0 °F)
1000.0 °C
(1832.0 °F)
Table 1.4 Parameter Description ( continued 6/7 )Table 1.4 Parameter Description (continued 6/7 )
Select 2'nd Parameter
Select 3'rd Parameter
Select 4'th Parameter
Select 5'th Parameter
SEL5 Same as SEL1 0
AD0
ADG
V1G
A to D Zero Calibration
Coefficient
A to D Gain Calibration
Coefficient
Voltage Input 1 Gain
Calibration Coefficient
-360 360
-199.9 199.9
-199.9 199.9
Low:
Low:
Low:
High:
High:
High:
Low: High:
CJTL
Cold Junction Low
Temperature Calibration
Coefficient -5.00 °C 40.00 °C
Calibration
Mode
Menu
Setup
Menu
18
:Parameter DB put ahead
Parameter
Description
Parameter
Description Range Default
Value
Default
Value
Contained
in
Contained
in
Basic
Function
Basic
Function
Parameter
Notation
Parameter
Notation
Display
Format
Display
Format
Low:
Low:
High:
High:
MA2G
V2G
mA Input 2 Gain Calibration
Coefficient
Voltage Input 2 Gain
Calibration Coefficient -199.9
-199.9
199.9
199.9
Low:
Low:
Low:
Low:
High:
High:
High:
High:
CJG
REF1
SR1
MA1G
Cold Junction Gain
Calibration Coefficient
Reference Voltage 1
Calibration Coefficient for
RTD 1
Serial Resistance 1
Calibration Coefficient for
RTD 1
mA Input 1 Gain Calibration
Coefficient
-199.9
-199.9
-199.9
-199.9
199.9
199.9
199.9
199.9
Table 1.4 Parameter Description ( continued 7/7 )Table 1.4 Parameter Description (continued 7/7 )
Calibration
Mode
Menu
Display
Mode
Menu
Low:
Low:
High:
High:
PVHI
PVLO
Historical Maximum Value of
PV
Historical Minimum Value of
PV
-19999
-19999
45536
45536
Low:
Low: High:
High:
MV1
MV2
Current Output 1 Value
Current Output 2 Value
0
0
100.00 %
100.00 %
Low:
Low:
Low:
Low:
Low:
Low:
Low:
Low:
Low:
Low:
High:
High:
High:
High:
High:
High:
High:
High:
High:
High:
DV
PV1
PV2
PB
TI
TD
CJCT
PVR
PVRH
PVRL
-12600
-19999
-19999
12600
45536
45536
0
0
Current Deviation (PV-SV)
Value
IN1 Process Value
IN2 Process Value
Current Proportional Band
Value
Current Integral Time Value
Current Derivative Time
Value
Cold Junction Compensation
Temperature
Current Process Rate Value
Maximum Process Rate Value
Minimum Process Rate Value
0
4000 sec
1440 sec
500.0 °C
(900.0 °F)
19
-40.00 °C
-16383
-16383
-16383
90.00 °C
16383
16383
16383
Table 1.5 Input ( IN1 or IN2 ) RangeTable 1.5 Input (IN1 or IN2 )Range
Table 1.6 Range Determination for A1SPTable 1.6 Range Determination for A1SP
Table 1.8 Range Determination for SP2Table 1.8 Range Determination for SP2
Table 1.7 Range Determination for A2SPTable 1.7 Range Determination for A2SP
Range of A1SP
same as range of
Range of SP2
same as range of
Range of A2SP
same as range of
If A1FN =
If PVMD =
If A2FN =
PV1
IN1
PV2
IN2 IN1, IN2
P1 2, P2 1
20
Exception: If any of A1SP, A2SP or SP2 is configured with respect to
CT input, its adjustment range is unlimited.
Exception: If any of A1SP, A2SP or SP2 is configured with respect to
CT input, its adjustment range is unlimited.
Input Type J_TC K_TC T_TC E_TC B_TC R_TC S_TC
Range Low
Range High
-120 °C
(-184 °F)
1000 °C
(1832 °F)
-200 °C
(-328 °F)
1370 °C
(2498 °F)
-250 °C
(-418 °F)
400 °C
(752 °F)
-100 °C
(-148 °F)
900 °C
(1652 °F)
0°C
(32 °F)
0°C
(32 °F)
0°C
(32 °F)
1820 °C
(3308 °F)
1767.8 °C
(3214 °F)
1767.8 °C
(3214 °F)
Input Type N_TC L_TC PT.DN PT.JS CT Linear ( V, mA)
or SPEC
Range Low
Range High
1300 °C
(2372 °F)
-200 °C
(-328 °F)
-200 °C
(-328 °F)
-250 °C
(-418 °F)
-210 °C
(-346 °F)
700 °C
(1292 °F)
900 °C
(1652 °F)
600 °C
(1112 °F)
0Amp
90 Amp
-19999
45536
PV1.H, PV1.L
IN1
PV2.H,PV2.L
IN2
P1.2.H, P1.2.L
D1.2.H, D1.2.L
IN1, IN2
PV1.H, PV1.L
IN1
PV2.H,PV2.L
IN2
P1.2.H, P1.2.L
D1.2.H, D1.2.L
IN1, IN2
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