Instruction manual
2 7 RTD Input Wiring
2 8 Linear DC Input Wiring
Figure 2.6
RTD Input Wiring
Figure 2.6
RTD Input Wiring
DC linear voltage and linear current connections for input 1 are shown in Figure
2.7 and Figure 2.8 .
DC linear voltage and linear current connections for input 1 are shown in Figure
2.7 and Figure 2.8 .
DC linear voltage and linear current connections for input 2 are shown in Figure
2.9 and Figure 2.10 .
DC linear voltage and linear current connections for input 2 are shown in Figure
2.9 and Figure 2.10 .
Figure 2.7
Input 1 Linear Voltage Wiring
Figure 2.7
Input 1 Linear Voltage Wiring
1 2 3 4
ON
1 2 3 4
ON
DIP Switch
DIP Switch
Two-wire RTD should be avoided, if possible, for the purpose of accuracy. A
0.4 ohm lead resistance of a two-wire RTD will produce a 1 C temperature°
Two-wire RTD should be avoided, if possible, for the purpose of accuracy. A
0.4 ohm lead resistance of a two-wire RTD will produce a 1 C temperature°
RTD
Three-wire RTD
RTD
Two-wire RTD
0~1V, 0~5V
1~5V, 0~10V
0~1V, 0~5V
1~5V, 0~10V
+
26
RTD connections are shown in Figure 2.6, with the compensating lead connected
to
terminal 9. For two-wire RTD inputs, terminals 9 and 10 should be linked. The
three-wire RTD offers the capability of lead resistance compensation provided that
RTD connections are shown in Figure 2.6, with the compensating lead connected
to
terminal 9. For two-wire RTD inputs, terminals 9 and 10 should be linked. The
three-wire RTD offers the capability of lead resistance compensation provided that
12
34
5
8910
11
67
12
13
14
12
34
5
8910
11
67
12
13
14
12
34
5
8910
11
67
12
13
14