GE Multilin
G60 Generator Protection System
5-315
5 SETTINGS
5.9 TRANSDUCER INPUTS AND OUTPUTS
5
•
If the
RRTD 1 APPLICATION
setting is “Group 1” or “Group 2”, then a value of “Other” is written to the RRTD device.
An RRTD actual value of –43°C implies that the
RRTD 1 FUNCTION
setting is “Enabled” but the corresponding
RRTD 1 APPLI-
CATION
setting is
“
None
”
.
If the RRTD communication link with the G60 is broken, then the last temperature actual values are retained until the RRTD
communication failure is detected. When this occurs, a RRTD COMM FAILURE self-test alarm and target message is gen-
erated, and an event is logged in the event recorder and the temperature actual values reset to 0. When the link is re-estab-
lished, the
RRTD 1 APPLICATION
and
RRTD 1 TYPE
settings are read from the RRTD to re-synchronize the device.
•
RRTD 1 FUNCTION
: This setting enables and disables the remote RTD. If set to “Disabled”, no actual value is created
for the remote RTD.
•
RRTD 1 ID
: This setting is used to assign alphanumeric ID is assigned to the remote RTD. This ID will be included in
the remote RTD actual values. It is also used to reference the remote RTD input to features using the remote RTD.
•
RRTD 1 TYPE
: This setting specifies the remote RTD type. Four different RTD types are available: 100
Ω
Nickel, 10
Ω
Copper, 100
Ω
Platinum, and 120
Ω
Nickel.
The RRTD converts resistance to temperature as per the values in the following table. The G60 reads the RTD temper-
atures from the RRTD once every five seconds and applies protection accordingly. The RRTDs can be used to provide
RTD bias in the existing thermal model.
An RRTD open condition is detected when actual RRTD resistance is greater than 1000 ohms and RRTD open is dis-
played as “250°C” in the G60.
Table 5–37: RTD TEMPERATURE VS. RESISTANCE
TEMPERATURE
RESISTANCE (IN OHMS)
°C
°F
100 OHM PT
(DIN 43760)
120 OHM NI
100 OHM NI
10 OHM CU
–40
–40
84.27
92.76
79.13
7.49
–30
–22
88.22
99.41
84.15
7.88
–20
–4
92.16
106.15
89.23
8.26
–10
14
96.09
113
94.58
8.65
0
32
100
120
100
9.04
10
50
103.9
127.17
105.6
9.42
20
68
107.79
134.52
111.2
9.81
30
86
111.67
142.06
117.1
10.19
40
104
115.54
149.79
123
10.58
50
122
119.39
157.74
129.1
10.97
60
140
123.24
165.9
135.3
11.35
70
158
127.07
174.25
141.7
11.74
80
176
130.89
182.84
148.3
12.12
90
194
134.7
191.64
154.9
12.51
100
212
138.5
200.64
161.8
12.9
110
230
142.29
209.85
168.8
13.28
120
248
146.06
219.29
176
13.67
130
266
149.82
228.96
183.3
14.06
140
284
153.58
238.85
190.9
14.44
150
302
157.32
248.95
198.7
14.83
160
320
161.04
259.3
206.6
15.22
170
338
164.76
269.91
214.8
15.61
180
356
168.47
280.77
223.2
16
190
374
172.46
291.96
231.6
16.39
200
392
175.84
303.46
240
16.78
Summary of Contents for Multilin g60
Page 10: ...x G60 Generator Protection System GE Multilin TABLE OF CONTENTS INDEX ...
Page 32: ...1 22 G60 Generator Protection System GE Multilin 1 5 USING THE RELAY 1 GETTING STARTED 1 ...
Page 160: ...4 30 G60 Generator Protection System GE Multilin 4 3 FACEPLATE INTERFACE 4 HUMAN INTERFACES 4 ...
Page 486: ...5 326 G60 Generator Protection System GE Multilin 5 10 TESTING 5 SETTINGS 5 ...
Page 518: ...6 32 G60 Generator Protection System GE Multilin 6 5 PRODUCT INFORMATION 6 ACTUAL VALUES 6 ...
Page 532: ...7 14 G60 Generator Protection System GE Multilin 7 2 TARGETS 7 COMMANDS AND TARGETS 7 ...
Page 748: ...D 10 G60 Generator Protection System GE Multilin D 1 IEC 60870 5 104 APPENDIX D D ...
Page 760: ...E 12 G60 Generator Protection System GE Multilin E 2 DNP POINT LISTS APPENDIX E E ...