AUBER INSTRUMENTS
WWW.AUBERINS.COM
2020.06 P1/10
SYL-5342P-S USB Ramp and Soak PID Temperature Controller
Version 1.0 (June 2020)
Caution
•
This controller is intended to control equipment under normal operating
conditions. Failure or malfunction of the controller may lead to abnormal
operating conditions, which result in personal injury or damage to the
equipment or other property. Devices (limit or safety controls) or systems
(alarm or supervisory) intended to warn of or protect against failure or
malfunction of the controller must be incorporated into and maintained as part
of the control system.
•
Installing the rubber gasket supplied will protect the controller front panel from
dust and water splash (IP54 rating). Additional protection is needed for higher
IP rating.
•
USB data cable on terminal 11 & 12 must be secured and isolated from
the power input cable on terminal 9 & 10. Otherwise high voltage AC
power from the power input cable may damage your USB adapter and/or
your computer
.
•
This controller carries a 90-day warranty. This warranty is limited to the
controller only.
1.
Features
•
By provided software and USB adapter, user can get access to the controller
via Windows computer.
•
32 programmable ramp steps and 32 programmable soak steps (total of 64
steps)
•
High flexibility in program and operation. User can use its keypad to change
the running status of program, such as run, hold and stop.
•
This controller has two alarm relay outputs. Alarm relay 1 is used for
temperature alarm. Alarm relay 2 is used for program ending alarm, to notify
the operator that the whole program is completed.
•
The safety-start feature may allow the program to run more efficiently. Four
power-off/power-on event handling modes are available, which can prevent
the program control from being adversely affected by unexpected power
interruptions.
2.
Specifications
Table 1. SYL-5342P-S specifications.
Input type
Thermocouple (TC): K, E, J, T, S, R;
RTD (Resistance Temperature Detector): Pt100, Cu50
Input range
Please see section 5.3.10 for detail.
Accuracy
± 0.5% Full scale: RTD and thermocouple input with ice
point compensation or Cu50 copper compensation.
± 0.5% Full scale or ± 2ºC: Thermocouple input with
internal automatic compensation.
Response time
≤
0.5 s (when FILt = 0)
Display
resolution
1° C, 1° F; or 0.1° C, 0.1° F
Control mode
Fuzzy logic enhanced PID control
On-off control
Output mode
Relay contact (NO): 250VAC/7A, 120V/10A, 24VDC/10A
Alarm relay
rating
Relay contact (NO): 250VAC/1A, 120VAC/3A, 24V/3A
Alarm function
Process high alarm, process low alarm, deviation high
alarm, and deviation low alarm
Power supply
85 ~ 240 VAC / 50 ~ 60 Hz
Power
consumption
≤
5 Watt
Ambient
environment
0 ~ 50ºC, 32 ~ 122ºF;
≤
85% RH;
No corrosive gas, no strong EMI
Dimension
48 x 48 x 100 mm (W x H x D)
Mounting cutout
45 x 45 mm
3.
Terminal Wiring
1
2
3
13 14 6
7
8
9
10
4
5
AL2
AC
85~240V
R
R
W
TC
-
+
11 12
RTD
RS485
A+
B-
AL1
SYL-
5342P-S
Out
Figure 1. Wiring terminals of SYL-5342P-S.
3.1.
Sensor connection
Please refer to Table 3 for the input sensor type (Sn) setting codes. The initial
setting for input is for a K type thermocouple. Set Sn to the right sensor code if
another sensor type is used.
3.1.1.
Thermocouple
The thermocouple should be connected to terminals 4 and 5. Make sure that the
polarity is correct. There are two commonly used color codes for the K type
thermocouple. US color code uses yellow (positive) and red (negative). Imported
DIN color code uses red (positive) and green/blue (negative). The temperature
reading will decrease as temperature increases if the connection is reversed.
When using ungrounded thermocouple that is in touch with a large conductive
subject, the electromagnetic field picked up by the sensor tip might be too large
for the controller to handle, i.e., the temperature display will change erratically.
In that case, connecting the shield of thermocouple to terminal 5 (circuit ground
of the controller) might solve the problem. Another option is to connect the
conductive subject to terminal 5.
3.1.2.
RTD sensor
For a three-wire RTD with standard DIN color code, the two red wires should be
connected to the terminals 4 and 5, and the white wire should be connected to
terminal 3. For a two-wire RTD, the wires should be connected to terminals 4
and 5. Jump a wire between terminals 3 and 4. Set controller input type Sn to
Pt1 or Pt2.
3.2.
Power to the controller
The power cables should be connected to terminals 9 and 10. Polarity does not
matter. It can be powered by 85-240V AC power source. Neither a transformer
nor jumper is needed to wire it up. For the sake of consistency with the wiring
example described later, we suggest you connect the hot wire to terminal 9 and
neutral to 10.
Instruction Manual
