Delta Electronics DTV Prospecto

Mode

Alarm Type

Alarm Output Operation

Standby upper/lower limit alarm: Alarm will be enabled when the PV reaches SV and
exceeds SV + AL-H or falls below SV – AL-L.

OFF

AL-L

AL-H

Upper limit standby alarm: Alarm will be enabled when the PV reaches SV and exceeds
SV + AL-H.

OFF

AL-H

Lower limit standby alarm: Alarm will be enabled when the PV reaches SV and falls below
SV – AL-L.

OFF

AL-L

Upper limit hysteresis alarm: Alarm will be enabled when the PV exceeds SV + AL-H.
Alarm will be disabled when the PV falls below SV + AL-L.

OFF

AL-L

AL-H

Lower limit hysteresis alarm: Alarm will be enabled when the PV falls below SV – AL-H.
Alarm will be disabled when the PV exceeds SV – AL-L.

OFF

AL-L

AL-H

Programmable STOP: Alarm will be enabled when the program is in STOP status.

Programmable RAMP UP: Alarm will be enabled when the program is in RAMP UP
status.

Programmable RAMP DOWN: Alarm will be enabled when the program is in RAMP
DOWN status.

Programmable SOAK: Alarm will be enabled when the program is in SOAK status.

Programmable RUN: Alarm will be enabled when the program is in RUN status.

Note: AL-H and AL-L include AL1H, AL2H and AL1L, AL2L. There is no mode 13 (reserved for CT function).

PID Programmable Control

Functions and Parameter Setting:
The PID programmable control includes 8 patterns (Pattern 0 ~ 7). Each pattern contains 8 steps (Step 0 ~ 7) and
parameters: link pattern, cycle and the number of steps.
Start Pattern

: This parameter can be set in the operation mode. The user can set up which pattern is the start

pattern for the programmable control. This function is only available when the program is in STOP status.
Step: Includes the settings of the two parameters, set point X and execution time T, indicating that the set point (SV)
has to rise to temperature X after the period of execution time T. If the result of the set point X is the same as that of
the previous setting, the process is called Soak; otherwise, it is called Ramp. Therefore, the programmable control is
also known as Ramp/Soak control.
The default setting of the first step program is Soak control. The temperature will first rise to the set point X and
remain at X. The total execution time is T.

Link Pattern: For example, if the parameter

is set as 2, it refers to the execution of pattern 2 will follow the

execution of pattern 0. If the link pattern is set as

, it refers to the program will end after the execution of the

pattern is completed and the temperature will remain at the SV for the last step.

Cycle: The additional number of cycles for a pattern. For example, if the parameter

is set as 2, it refers to

pattern 4 has to execute twice additionally, totaling the executions to 3 times including the original one.

The Number of Steps: The number of steps in each pattern (range: 0 ~ 7). For example, if the parameter

set as 2, it refers to pattern 7 will execute step 0 ~ step 2 and other steps will not be executed.
The Execution:
1. When the parameter

is set as

, the program will start its execution from step 0 of the start pattern.

2. When the parameter

is set as

, the program will stop and the control output will be disabled.

3. When the parameter

is set as

, the program will stop and the temperature will stop at the SV before

the program stops. When you select

again, the program will execute again from step 0 of the start pattern.

4. When the parameter

is set as

, the program will stop and the temperature will stop at the SV before

the program stops. When you select

again, the program will resume the step before the program stops

and execute by the remaining time.

Display:
In PID programmable control, some SVs are re-set as P-XX. P refers to the current pattern and XX refers to the
current step. Press

to modify the display.

Select

and press

. SV will display the target temperature for the current step.

Select

and press

. SV will display the remaining time of the current step.

PID Control

In PID control, you can select any one of the 4 groups of PID parameter (P, I, D, IOF). After auto-tuning, the PID value
and the temperature SV will be stored into the selected PID parameter.

: PIDn, n = 0 ~ 4. 0 ~ 3 are the corresponding selected PID parameter.

refers to

auto-selected PID and the program will automatically select a most useful PID parameter based on the current SV. SV
displays will be

corresponding to n = 0 ~ 3.

: The SV for the selected PID parameter, can be set by the user or auto-generated by auto-tuning.

Valve Control

Heaters and coolers can be used to control the temperature and the openness of the valve in order to control the flow
of the medium. Current and voltage can control the openness of the valve; however, the most direct and economic
way to control the openness of the valve is the relay. To control the valve by voltage and current, you can use the DTB
series analog output controller. If you tend to use relay for the control output, you have to choose the valve function in
DTV series. The two control outputs are relay output for the forward/reverse running of the motor to drive the opening
and closing of the valve. Control output1 controls the opening of the valve and control output 2 controls the closing of
the valve in order to adjust the position of the valve. In order to detect the position of the valve, DTV is able to receive
“feedback signal” and “no feedback signal”. When there is no feedback signal and the valve is fully open, control
output 1 will output continuously. If at the moment the valve is fully closed, control output 2 will output continuously. If
the valve you use is with feedback output, you can connect the output of the valve to the feedback part of DTV and set

to On to precisely control the openness of the valve. If there is no feedback signal or the feedback signal is

incorrect, and the pre-set openness of the valve is not reached after twice as long as the time set in the parameter

, the program will automatically switch back to the no feedback state. To ensure the correctness of the valve

control, please make sure that you have set up the parameters below:

: Time required from the valve fully closed to fully open. This parameter has to be correct when the valve is

without feedback signal; otherwise, the accuracy for the temperature control will be affected. The PID control will
correspond to the openness of the valve according to the setting of this parameter.

: DeadBand value of the valve. The parameter is to prevent frequent movement of the valve. For example,

assume the DeadBand is 4%, PID control will correspond to the openness of the valve within 4% and the valve will
not move within the range unless the value is accumulated and exceeds 4%. If the Deadband value is too small and
the valve is set to have feedback signals, moving back and forth of the valve will shorten the life of the valve motor.

: With or without feedback signals.

When

is set as “On”, it refers to “with feedback signals” and the following parameters will be displayed.

: Automatically adjusting the upper/lower limit of the valve feedback. This parameter will only be displayed

when

is set as

. When this parameter is set as On, the relay will enable the forward and reverse

running of the motor in order to calculate the time needed from the valve fully closed to fully open and the
feedback signal of fully closed and open. The feedback signal is the hardware D/A value of the valve control,
which is for the calculation of the valve controller.

: Upper limit of the valve signal. Set

as “On”, can be set automatically or manually.

: Lower limit of the valve signal. Set

as ”On”, can be set automatically or manually.

Auto/Manual Mode Switch

A/M indicator On refers to manual mode; A/M indicator Off refers to auto mode. Besides On/Off, PID, programmable
and manual controls, the valve control is also able to forcibly switch to manual control (fixing the openness of the
valve, unit: % from valve fully closed to fully open) when in PID control mode. You simply need to press

in PID

control mode to switch to manual mode and A/M indicator will be On. Press

again to return to PID control and A/M

indicator will be Off.

Upper/Lower Limits of Valve Openness

Assume we would like the maximum openness of the valve to be 80% and the minimum to be 20%, set the parameter

as 80 and

as 20, and the valve openness of PID control, programmable control and manual control

will fall within this range.

RS-485 Communication

1. Supports transmission speed 2,400bps, 4,800bps, 9,600bps, 19,200bps and 38,400bps; does not support

communication format 7, N, 1/8, E, 2/8, O, 2. Communication protocol: Modbus (ASCII or RTU). Function: 03H
(able to read max. 8 words in the register), 06H (able to write 1 word into the register), 01H (able to read max. 16
bits of data), 05H (able to write 1 bit into the register).

2. Address and content of the data register.

Address

Content

Explanation

1000H

Present temperature value (PV)

Unit: 0.1 degree, updated every 0.4 second.
The read values below indicate the occurrence of errors:
8002H: temperature not acquired yet
8003H: temperature sensor not connected
8004H: wrong sensor type
8006H: unable to acquire temperature, ADC input error
8007H: unable to read/write the memory

1001H

Set point (SV)

Unit: 0.1 degree

1002H

Upper limit of temperature range

The content shall not be bigger than the range.

1003H

Lower limit of temperature range

The content shall not be smaller than the range.

1004H

Input sensor type

See “Types of Temperature Sensors and Temperature Range" table.

1005H

Control method

0: PID; 1: On/Off; 2: manual control; 3: PID programmable control

1006H

Selecting heating/cooling control

0: heating; 1: cooling

1009H

Proportion band value

0.1 ~ 999.9

100AH

Ti value

0 ~ 9,999

100BH

Td value

0 ~ 9,999

100CH

Default integration value

0 ~ 100%, unit: 0.1%

100DH

Offset compensation value for
proportional control (when Ti = 0)

0 ~ 100%, unit: 0.1%

1010H

SV of output hysteresis

0 ~ 9,999

1012H

Read/write of output percentage

Unit: 0.1%, only applicable in manual control mode

1014H

Upper limit regulation for analog linear
output

1 scale = 2.8μA = 1.3mV

1015H

Lower limit regulation for analog linear
output

1 scale = 2.8μA = 1.3mV

1016H

Temperature offset regulation value

-99.9 ~ +99.9, unit: 0.1

1017H

Analog decimal point setting

0 ~ 3

1018H

Time from valve fully closed to fully open

0.1 ~ 999.9

1019H

DeadBand setting of valve

0 ~ 100%, unit: 0.1%

101AH

Upper limit for valve feedback signal

0 ~ 1,024

101BH

Lower limit for valve feedback signal

0 ~ 1,024

101CH

PID group setting

0 ~ 4

101DH

SV for the corresponding PID setting

In valid range. Unit: 0.1

101EH

Upper limit for control output

Lower limit for control output ~ 100%, unit: 0.1%

101FH

Lower limit for control output

0 ~ Upper limit for control output, unit: 0.1%

1020H

Output mode for alarm 1

See “Alarm Output” section.

1021H

Output mode for alarm 2

See “Alarm Output” section.

1023H

System alarm setting

0: None (default); 1 ~ 2: Set alarm 1 ~ alarm 2

1024H

Upper limit for alarm 1

See “Alarm Output” section.

1025H

Lower limit for alarm 1

See “Alarm Output” section.

1026H

Upper limit for alarm 2

See “Alarm Output” section.

1027H

Lower limit for alarm 2

See “Alarm Output” section.

102AH

Read/write LED status

b0: °F; b1: °C; b2: ALM2; b3: x; b4: OUT1; b5: OUT2; b6: AT; b7: ALM1

102BH

Read/write key status

b0: Set; b1: Select; b2: Up; b3: Down; 0 refers to push.

102CH

Panel lock status

0: normal; 1: lock all; 11: SV adjustable; 111: SV adjustable, A/M

available

102FH

Software version

V1.00 refers to 0x100

1030H

No. of start pattern

0 ~ 7

1040H ~

1047H

Number of steps in a pattern

0 ~ 7 = N refers to the pattern will be executed from step 0 to step N.

1050H ~

1057H

Additional number of cycles for a pattern

0 ~ 99 refers to the pattern will be executed for 1 ~ 100 times.

1060H ~

1067H

No. of the link pattern for the current
pattern

0 ~ 8. 8 refers to end of the program; 0 ~ 7 refers to the next pattern No.
following the current pattern.

2000H ~

203FH

SV temperature for pattern0 ~ 7

SV for pattern 0 is set in 2000H ~ 2007H

-999 ~ 9,999

2080H ~

20BFH

Execution time for pattern 0 ~ 7

Time for pattern 0 is set in 2080H ~

2087H

0 ~ 900 (Every scale = 1 minute)

3. Address and content of the bit register (read bits are stored starting from LAB and written data is FF00H, set the

bit as 1. 0000H sets the bit data as 0.)

0810H

Selecting communication write-in

Communication write-in forbidden: 0 (default), allowed: 1

0811H

Selecting temperature unit

0: °F; 1: °C/linear input (default)

0812H

Position of the decimal point

0 or 1. Available for all modes except for thermocouple type B, S, R.

0813H

Read/write auto-tuning (AT)

0: AT stops (default); 1: AT starts

0814H

RUN/STOP of the control

0: stop; 1: run (default)

0815H

Programmable control RUN/STOP

0: run (default); 1: stop

0816H

Programmable control RUN/PAUSE

0: run (default); 1: pause

0817H

Read/write valve feedback

0: without feedback (default); 1: with feedback

0818H

Read/write AT of valve feedback

0: AT stops (default); 1: AT starts

4. Communication transmission format: command 01: read bit, 05: write bit, 03: read word, 06: write word.

ASCII Mode

Read Command

Read Response Message

Write Command

Write Response Message

Start word

’：’

Start word

’：’ ’：’

Start word

’：’

Start word

’：’

Machine address 1 ‘0’

‘0’

Machine address 1

‘0’

‘0’ Machine address 1 ‘0’

‘0’

Machine address 1 ‘0’

‘0’

Machine address 0 ‘1’

‘1’

Machine address 0

‘1’

‘1’ Machine address 0 ‘1’

‘1’

Machine address 0 ‘1’

‘1’

Command 1

‘0’

Command 1

‘0’

Command 1

‘0’

Command 1

‘0’

Command 0

‘3’

‘1’

Command 0

‘3’

‘1’

Command 0

‘6’

‘5’

Command 0

‘6’

‘5’

‘1’

‘0’

‘1’

‘0’

‘1’

‘0’

‘8’

Length of response

data (byte)

‘4’

‘2’

‘0’

‘8’

‘0’

‘8’

‘0’

‘1’

‘0’

‘1’

‘0’

‘1’

‘0’

‘1’

Read start address

of data/bit

‘0’

‘1’

‘7’

Write data address

‘1’

‘0’

Write data address

‘1’

‘0’

‘F’

‘0’

‘F’

‘0’

‘F’

‘0’

Data content in

1000H/081xH

‘4’

‘1’

‘3’

‘F’

‘3’

‘F’

‘0’

‘E’

‘0’

‘E’

‘0’

Read length of

data/bit (word/bit)

‘2’

‘9’

‘0’

Write data content

‘8’

‘0’

Write data content

‘8’

‘0’

LRC1 check

‘E’

‘D’

‘0’

LRC1

‘F’

‘E’

LRC1

‘F’

‘E’

LRC0 check

‘A’

‘C’

Data content in

1001H

‘0’

LRC

‘D’

‘3’

LRC 0

‘D’

‘3’

End word 1

LRC1 check

‘0’

‘E’

End word 1

End word 0

LRC0 check

‘3’

End word 0

End word 1

CR CR

End word 0

LRC check: Sum up from “machine address” to “data content”, e.g. 01H + 03H + 10H + 00H + 00H + 02H = 16H.
Obtain 2’s complement EA.

RTU Mode

Read Command

Read Response Message

Write Command

Write Response Message

Machine address 01H

01H

Machine address

01H 01H Machine address 01H

01H Machine address 01H

01H

Command 03H

01H

Command 03H 01H

Command 06H

05H

Command 06H

05H

10H

08H

10H

08H

10H

08H

Read start

address of data

00H

10H

Length of response

data (byte)

04H 02H

Write data

address

01H

10H

Write data

address

01H

10H

00H

01H 17H

03H

FFH

03H

FFH

Read length of

data (bit/word)

02H

09H

Data content 1

F4H 01H

Write data

content

20H

00H

Write data

content

20H

00H

CRC low byte

C0H

BBH

03H

CRC low byte

DDH

8FH

CRC low byte

DDH

8FH

CRC high byte

CBH

A9H

Data content 2

20H

CRC high byte

E2H

9FH

CRC high byte

E2H

9FH

CRC low byte

BBH 77H

CRC high byte

15H 88H

CRC (Cyclical Redundancy Check) is obtained by the following steps.
1. Load in a 16-bit register FFFFH as the CRC register.
2. Do an exclusive OR operation of the first byte of the data and low byte of CRC register, and place the operation

result back to the CRC register.

3. Right shift the bits in the CRC register and fill the high bits with “0”. Check the removed lowest bit.
4. If the removed lowest bit is “0”, repeat step 3. Otherwise, do an exclusive OR operation of the CRC register and the

value A001H and place the operation result back to the CRC register.

5. Repeat step 3 and 4 until the 8 bits (1 byte) are all right shifted.
6. Repeat step 2 and 5 and calcualte all the bits to obtain CRC check.
Please be aware of the high/low byte transmission order in the CRC register.

How to Mount

How to Install Mounting Bracket

1. Insert DTV into the panel cutout
2. Insert the mounting bracket into the mounting

groove at the top and bottom of DTV.

3. Push the mounting bracket forward until the

bracket stops at the panel wall.

4. Tighten the screw.

Dimensions

DTV4896 DTV9696

Panel Cutout

Terminals

DTV4896/DTV9696

DTV4896R/DTV9696R

60.0 min.

120

.0 min

110.0 min.

120

.0 min

48*96

96*96

44.5

+0.6

91.

+0.6 0

+0.6

How to Set up Current Input

For normal input (default)

Current input (4 ~ 20mA, 0 ~ 20mA)

JU MPER

PIN HEADER

JP1

DEFAU LT SETTING

J UMPER

PIN HEADER

JP1

The content of this instruction sheet may be revised without prior notice. Please consult our distributors or

download the most updated version at http://www.delta.com.tw/industrialautomation