MCGG MANUAL RELAY.pdf
Short Description
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Description
Type MCGG 22, 42, 52, 53, 62, 63 & 82 Overcurrent Relay for Phase and Earth Faults
Type MCGG 22, 42, 52, 53, 62, 63 & 82 Overcurrent Relay for Phase and Earth Faults
Figure 1: Relay type MCGG 62 withdrawn from case.
Features • Choice of 4 inverse time curves and 3 definite time ranges by switched selection.
• Accurately follows time curves to BS142 and IEC60255. • High resetting ratio. • Fast resetting time.
• Wide setting range of 0.05 x In to 2.4 x In in steps of 0.05 x In.
• Positive, calibrated settings by means of switches.
• Time multiplier range 0.05 to 1 on all seven characteristics.
• Internal dc auxiliary power supply operating over a wide input range.
• Separate LED indicators provided on each measuring board to show time delayed and instantaneous operations. • LED start indicators provided to facilitate testing. • Separate output contacts provided for time delayed phase fault, instantaneous phase fault, time delayed earth fault and instantaneous earth fault operations. • Low ac burden. • Suitable for use with separate direction relay.
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• Separate test mode with trip test feature. • Indication of power to the measuring board. • Non-volatile memory for time delayed and instantaneous LED indicators.
MCGG 53 Two phase overcurrent (with polyphase measurement) plus earth fault with instantaneous elements.
Models available MCGG 22 Single phase overcurrent with instantaneous element.
MCGG 62 Three phase overcurrent with instantaneous elements.
MCGG 42 Two phase overcurrent with instantaneous elements.
Associated publications: Midos System R6001 Directional Relay R6003
MCGG 63 Three phase overcurrent (with polyphase measurement), with instantaneous element.
MCGG 52 Two phase overcurrent plus earth fault with instantaneous elements.
3 phase 2 phase Single phase Measuring overcurrent overcurrent or earthfault boards † inst † inst † inst
Model MCGG MCGG MCGG MCGG MCGG MCGG MCGG
MCGG 82 Three phase overcurrent plus earth fault with instantaneous elements.
22 42 52 53 62 63 82
Application The relay can be used in applications where time graded overcurrent and earth fault protection is required. The relay can be used to provide selective protection for overhead and underground distribution feeders. Other applications include back-up protection for transformers, generators and HV feeder circuits and the protection of neutral earthing resistors. With all the current/time characteristics available on one relay, a standard relay can be ordered before detailed coordination studies are carried out – a distinct advantage for complex systems. Also, changes in system configuration can be readily accommodated.
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For applications where the instantaneous earth fault element is required to have a sensitive setting whilst remaining stable on heavy through faults the use of a stabilising resistor is recommended. The current transformers for this application must satisfy the criteria detailed under ‘Current transformer requirements’ in Technical Data. The total impedance of the relay and the series stabilising resistor is usually low enough to prevent the current transformers developing voltages over 2kV during maximum internal faults, but in some applications a non-linear resistor is required to limit this voltage. Non-standard resistance values and non-linear voltage limiting devices are available.
An instantaneous element with low transient overreach is incorporated within each phase or earth fault measuring board. This can be easily disabled in applications where it is not required.
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1 2 3 2 3 1 4
Case size 4 6 8 8 6 6 8
Description This range of MCGG relays is designed so that versions are available with separate measuring boards for each phase or earth fault input; alternatively, phase inputs may be combined on to one board for polyphase measurement (see table). These boards, together with the other circuits of the relay, are contained in a single plug-in module which is supplied in a size 4, 6 or 8 Midos case. The case incorporates one or two terminal blocks for external connections. Removal of the module automatically short circuits the current transformer connections by means of safety contacts within the case terminal block. For added security, when the module is removed, the CT circuits are short circuited before the connections to the output contacts and the dc supply are broken. The relay uses solid state techniques, each measuring board utilising a microcomputer as a basic circuit element. The current measurement, whether performed on a single phase or polyphase input, is performed via an analogue-to-digital converter. Application diagrams are provided in Figures 2 to 8 (inclusive) showing typical wiring configurations.
Each measuring board has a built-in ‘power off’ memory feature for the time delayed and instantaneous LED indicators. Power to each measuring board may be tested whilst the relay is in service, without affecting the current measurement. A test mode is also available to carry out a trip test on the output relays. During this test, current measurement is inhibited. When required, directional control can be exercised over the relay by connecting an output contact from direction relay type METI to the terminals provided. Separate output contacts, capable of circuit breaker tripping, are provided for time delayed phase faults, instantaneous phase faults, time delayed earth fault and instantaneous earth fault operations.
Switch position (0) (1) ● ● ●
Operating characteristic Trip test
● ● ●
Standard inverse
t=
0.14 (I0.02 – 1)
sec SI
Very inverse
t=
13.5 (I – 1)
sec VI
●
Extremely inverse
t=
80 (I2 – 1)
sec EI
● ●
Long time earth fault t =
120 (I – 1)
sec LT
● ● ● ● ●
● ● ●
Definite time 2 seconds
D2
Definite time 4 seconds
D4
Definite time 8 seconds
D8
● ● ● ● ● ● ●
Table1: Operating time characteristics with corresponding switch positions.
Relay settings Separate setting switches for each measuring board are provided on the relay frontplate. These are used to select the required time/current characteristic, current and time multiplier settings. Selection of time characteristics
The current/time characteristic selection is carried out by means of three switches (identified by symbol on the nameplate). Table 1 gives the basic operating characteristic and the settings of the switches. Time multiplier setting
The time given by each of the operating characteristics must be multiplied by the time multiplier to give the actual operating time of the relay. This control is marked xt = Σ where Σ is the sum of all the switch positions. The range of multiplication is from 0.05x to 1.0x in steps of 0.025.
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This acts as a conventional time multiplier on the current dependent characteristics and gives the following time ranges for the definite time characteristics. Operating characteristics s 2 4 8
Time range s 0.1 to 2.0 in 0.05s steps 0.2 to 4.0 in 0.1s steps 0.4 to 8.0 in 0.2s steps
Trip test
Current setting
Current measurement is inhibited by setting the curve selection switches to 111. This causes all three LEDs to flash once per second. If the reset push button is then pressed for approximately six seconds, both output relays associated with that measuring board will operate.
Time delayed element
The current setting control is marked Is = Σ x In where Is is the current setting in amps, Σ is the sum of all the switch positions and In is the relay rated current in amps. Each measuring board provides a setting range of 0.05 x In to 2.4 x In in steps of 0.05 x In.
Power supply healthy test
If, whilst the relay is in service, the reset button is pressed, all the LEDs are illuminated, indicating that there is power to the measuring boards. The LEDs are reset on releasing the push button. During this test, normal current measurement is not inhibited.
Instantaneous element
The setting control of the instantaneous element is marked Iinst = Σ x Is where Σ is the sum of the switch positions and Is is the time delayed element setting. When all switches are set to the left (at zero), or when the lowest switch is set to infinity regardless of the positions of the other five switches, the instantaneous feature is rendered inoperable. The range of adjustment of finite settings is from 1x to 31x in unity steps.
A
S2
A
P1
P2
B
Figure 2: Type MCGG 22 nameplate
S1 B
C
C
Phase rotation
Directional control PhA (See Note 4)
TMS setting
24
Inst setting
Curve selection
23
(See Note 2)
27
IA
Time delayed trip Inst. trip
µC PhA
Is
Indicator reset
RL1–1
28
Input circuit Ph
Current setting Ph
I>Is
5
RL1 2
Case earth 1
2
5
6
7
8
9
10
13
14
15
16
Vx
+VE –VE
13 14 26
Output circuits Ph
Power supply circuits
RL2 2 Case earth connection
23
24 26
27
(See Note 3)
28
Module terminal block viewed from rear
(b) (c)
RL1–2
2
CT shorting links make before (b) and (c) disconnect. Short terminals break before (c). Long terminals
2. When directional control is required the contacts of the directional relays should be connected as shown. Contacts must close to inhibit overcurrent relay. 3. Earthing connections (CTs) are typical only. 4. CT connections are typical only.
Figure 3: Application diagram (10 MCGG 22 02): static modular overcurent relay type MCGG 22. Single phase with instantaneous element. 5
Phase fault time delayed trip output contacts
1
RL2–1
8 10 9
RL2–2
16 15
MCGG 22
Notes: 1. (a)
7 6
Phase fault instantaneous trip output contacts
A
A
P2
P1
S2
B
S1
Directional control PhA
C C
B Phase rotation (See Note 4)
TMS setting
Inst setting
Curve selection
Indicator reset
49 50
(See Note 2)
21
IA
Is
RL1 2
Time delayed trip Inst. trip
µC PhA
Input circuit Ph
23
Current setting Ph
I> Is
45
25 29
30
6
33
34
7
8
35
36
9
10
37
38
11
12
13
14
41
42
15
16
1
2
3
4
5
IC
Inst setting
Curve selection
18
45
46
19
20
47
48
21
22
49
50
23
24
25
26
27
28
Input circuit Ph
27
+VE –VE
28 13
1
38
RL2–2
41
Phase fault instantaneous trip output contacts
I> Is
MCGG 42
CT shorting links make before (b) and (c) disconnect. Short terminals break before (c). Long terminals
(b) (c)
36
42
Current setting Ph
Case earth connection
Module terminal block viewed from rear (with integral case earth strap)
Phase fault time delayed trip output contacts
Power supply circuits
14
(See Note 3) Notes: 1. (a)
29
37
Time delayed trip Inst. trip
µC PhC
Is
RL2–1
26
Vx
17
34
RL1–2
30 TMS setting
46 Case earth
35 33
RL2 2
24
Directional control PhC
RL1–1
Output circuits Ph
22
2. When directional control is required the contacts of the directional relays should be connected as shown. Contacts must close to inhibit overcurrent relay. 3. Earthing connections are typical only. 4. CT connections are typical only.
Figure 4: Application diagram (10 MCGG 42 03): static modular overcurent relay type MCGG 42. Two phase with instantaneous element.
P2
A A
P1 S2
B
S1
C
Directional control PhA
TMS setting
49
Inst setting
Curve selection
Indicator reset
50
B
C
(See Note 2)
(See Note 4)
Phase rotation
21
IA
Is 22
Input circuit Ph
23
Directional control PhC
Current setting Ph
RL1 2
Time delayed trip
µC PhA
Inst. trip
I >I s
RL1–1
Output circuits Ph
33
RL2 2
34
RL1–2
TMS setting
45
Inst setting
Curve selection
RL2–1
IC
Is
26
29
Directional control E/F
30
2
3
4
5
6
33
34
7
8
35
36
9
10
37
38
11
12
Input circuit Ph
13
14
41
42
16
43
44
17
18
45
46
19
20
47
48
21
22
49
50
23
24
25
26
27
28
38
RL2–2
RL3–1 Inst setting
Curve selection
Notes: 1. (a) (b) (c)
–VE
7
5
13 14 17
Power supply circuits
Input circuit
Current setting
Inst. trip
RL3–2
I >I s
RL4–1 RL4 2
8
9 16 15
3. Earthing connections are typical only. 4. CT connections are typical only.
Figure 5: Application diagram (10 MCGG 52 03): static modular overcurent relay type MCGG 52. Two phase plus earth fault with instantaneous elements. 6
Earth fault time delayed trip output contacts
10
MCGG 52
2. When directional control is required the contacts of the directional relays should be connected as shown. Contacts must close to inhibit overcurrent relay.
2 1
Output circuits
RL4–2
Case earth connection
CT shorting links make before (b) and (c) disconnect. Short terminals break before (c). Long terminals
RL3 2
Time delayed trip
µC
Is 28
Vx
Phase fault instantaneous trip output contacts
6
27
+VE
42 41
I >I s
44
(See Note 3)
Module terminal block viewed from rear (with integral case earth strap)
Current setting Ph
TMS setting
43
E/F
15
µC PhC
36 37
Time delayed trip Inst. trip
25
1
29
Phase fault time delayed trip output contacts
30
24
46
Case earth
35
Earth fault instantaneous trip output contacts
P2
A A
P1 S2
B
Directional control PhA
S1
C
49
TMS setting
Inst setting
Is
µC Ph
Indicator reset
Curve selection
50
B
C
(See Note 2)
(See Note 4)
Phase rotation
21
IA
RL1 2
Time delayed trip Inst. trip
22
Current setting Ph
23
Directional control PhC
RL1–1
35
Output circuits Ph
I >I s
33
RL2 2
34
RL1–2
29 30
24
RL2–1
45
36 37
46
38
25
RL2–2
IC
41
26
29
30
6
33
34
7
8
35
36
9
10
37
38
11
12
13
14
41
42
15
16
43
44
17
18
45
46
19
20
47
48
2
3
4
5
21
22
23
24
25
26
27
Directional control E/F
RL3–1 Inst setting
27
Curve selection
5
RL3 2
Time delayed trip
µC
E/F
49
Inst. trip
Is 13
+VE
14
–VE
17
50
Module terminal block viewed from rear (with integral case earth strap
CT shorting links make before (b) and (c) disconnect. Short terminals break before (c). Long terminals
(b) (c)
Input circuit
Current setting
I >I s
2
RL4–1
Earth fault time delayed trip output contacts
8
RL4 2
10 9
RL4–2
Case earth connection
(See Note 3)
28
Power supply circuits
RL3–2
1
Output circuits
28
Notes: 1. (a)
7 6
TMS setting
43 44
Vx
Phase fault instantaneous trip output contacts
42
Input circuit Ph
Case earth 1
Phase fault time delayed trip output contacts
16
Earth fault instantaneous trip output contacts
15
MCGG 53
2. When directional control is required the contacts of the directional relays should be connected as shown. Contacts must close to inhibit overcurrent relay.
3. Earthing connections are typical only. 4. CT connections are typical only.
Figure 6: Application diagram (10 MCGG 53 02): static modular overcurent relay type MCGG 53. Two phase (with polyphase measurement), plus earth fault with instantaneous elements.
P2
A A
P1 S2
B
S1
C
Directional control PhA
TMS setting
49
Inst setting
Curve selection
Indicator reset
50
B
C
(See Note 2)
(See Note 4)
Phase rotation
21
IA 22
Directional control PhB
Input circuit Ph
Current setting Ph TMS setting
47
Time delayed trip
µC PhA
Is
RL1–1
Inst. trip
Inst setting
33
RL1 2
I>Is Curve selection
Output circuits Ph
48 23
IB 24
Case earth 1
13
14
29
30
33
34
35
36
37
38
41
42
45
46
47
48
49
50
Directional control PhC
Input circuit Ph
Current setting Ph
34
RL1–2
TMS setting
38
RL2–2
I>Is
Inst setting
25
IC 26
Vx
22
23
24
25
26
(See Note 3)
27
28
Notes: 1. (a) (b) (c)
+VE –VE
13 14 1
Power supply circuits
Input circuit Ph
Current setting Ph
Case earth connection
Time delayed trip Inst. trip
I>Is
MCGG 62
CT shorting links make 2. When directional control is required the contacts before (b) and (c) disconnect. of the directional relays should be connected as shown. Short terminals break before (c). Contacts must close to inhibit overcurrent relay. Long terminals
3. Earthing connections are typical only. 4. CT connections are typical only.
Figure 7: Application diagram (10 MCGG 62 03): static modular overcurent relay type MCGG 62. Three phase with instantaneous element. 7
41 42
Curve selection
µC PhC
Is
36 37
RL2 2
28 45
29
Phase fault time delayed trip output contacts
30
RL2–1
46
21
Module terminal block viewed from rear (with integral case earth strap)
µC PhB
Is
27
Time delayed trip Inst. trip
35
Phase fault instantaneous trip output contacts
P2
A A
P1 S2
B
Directional control PhA
S1
C
49
TMS setting
Inst setting
Is
µC Ph
Indicator reset
Curve selection
50
B
C
(See Note 2)
(See Note 4)
Phase rotation
21
IA
RL1 2
Time delayed trip Inst. trip
22
Directional control PhB
Current setting Ph
47
RL1–1
Output circuits Ph
I> Is
35 33
RL2 2
34
RL1–2
29
Phase fault time delayed trip output contacts
30
48
RL2–1
23
38
24
Directional control PhC Case earth
36 37
IB RL2–2
41
Phase fault instantaneous trip output contacts
42
45 46
29
25
30
1
2
3
4
5
6
33
34
7
8
35
36
9
10
37
38
11
12 41
42
IC
13
14
15
16
17
18
45
46
19
20
47
48
21
22
49
50
23
24
25
26
27
28
26
Input circuit
27
28
Vx
+VE –VE
13 14 1
Case earth connection
(See Note 3) Notes: 1. (a)
Module terminal block viewed from rear (with integral case earth strap)
Power supply circuits
CT shorting links make before (b) and (c) disconnect. Short terminals break before (c). Long terminals
(b) (c)
MCGG 63
2. When directional control is required the contacts of the directional relays should be connected as shown. Contacts must close to inhibit overcurrent relay.
3. Earthing connections are typical only. 4. CT connections are typical only.
Figure 8: Application diagram (10 MCGG 63 02): static modular overcurent relay type MCGG 63. Three phase (with polyphase measurement) with instantaneous element.
A
A B
P2 S2
P1 S1
C C
B
Directional control PhA
TMS setting
50
N
Phase rotation
Indicator reset 49
(See Note 2) 21 (See Note 4)
IA
Is 22
Directional control PhB
Case earth 29
30
6
33
34
7
8
35
36
9
10
37
38
11
12
13
14
41
42
15
16
43
44
17
18
45
46
19
20
47
48
21
22
49
50
1
2
3
4
5
23
24
25
26
27
28
Is 24
TMS setting
25
IC
Is
43
28
2. When directional control is required the contacts of the directional relays should be connected as shown. Contacts must close to inhibit overcurrent relay.
(See Note 3)
–VE
34
RL1–2
29
Phase fault time delayed trip output contacts
30 36 37
Inst. trip
38
RL2–2
I>Is
13 14 17
Inst setting
Power supply circuits
RL3–1
41
Phase fault instantaneous trip output contacts
Is
µC E/F
5
Inst. trip
RL3–2
Time delayed trip Inst. trip
RL3 2
RL4–1
Earth fault time delayed trip output contacts
8 10 9
Output circuits E/F
MCGG 82
Case earth connection
3. Earthing connections are typical only. 4. CT connections are typical only.
Figure 9: Application diagram (10 MCGG 82 03): static modular overcurent relay type MCGG 82. Three phase plus earth fault with instantaneous elements (4 wire system). 8
2 1
Curve selection
I>Is
7 6
Time delayed trip
I>Is Inst setting
Input circuit Current setting E/F E/F
Curve selection
µC PhC
TMS setting
27
Vx
RL2 2
Time delayed trip
µC PhB
35 33
Curve selection
Inst setting
Input circuit Current setting Ph Ph
44
+VE
RL1–1 Output circuits Ph
42 45
26
CT shorting links make before (b) and (c) disconnect. Short terminals break before (c). Long terminals.
Inst. trip
I>Is
Input circuit Current setting Ph Ph
46
Directional control E/F
RL1 2
Time delayed trip
RL2–1
IB
Notes:
(b) (c)
TMS setting
23
Module terminal block viewed from rear (with integral case earth strap)
1. (a)
47
Curve selection
µC PhA
Input circuit Current setting Ph Ph
48
Directional control phase PhC
Inst setting
RL4–2 RL4 2
16 15
Earth fault instantaneous trip output contacts
Technical Data Ratings
AC current (In)
1A or 5A
Frequency
50/60Hz
DC supply (Vx)
24/54V, 48/125V or 110/250V
Burdens
AC Burden
Less than 0.25 VA for 1A relays and less than 0.5VA for 5A relays, at unity power factor and at rated current on any setting. The impedance of the relays over the whole of the setting range (5% to 240% rated current) is less than 0.25Ω for 1A relays and less than 0.02Ω for 5A relays and is independent of current.
DC burden
Relay rating
Relay type MCGG
MCGG
MCGG
MCGG
22, 63
42, 53
52, 62
82
24/54
1.5W
2.5W
3.0W
4.0W
48/125
2.0W
3.0W
3.5W
4.5W
110/250
2.5W
3.5W
4.0W
5.0W
The figures above are maxima under quiescent conditions. With output elements operated they are increased by up to 2.5W per element. Current transformer requirements
Relay and CT secondary rating (A)
Nominal output (VA)
Accuracy class
Accuracy Limiting lead limit current resistance – (X rated current) one way (ohms)
1
2.5
10P
20
1
5
7.5
10P
20
0.15
Note: For 5A applications with longer leads, the CT rating can be increased in steps of 2.5VA where each step of 2.5VA is equivalent to additional 0.06Ω lead resistance. Instantaneous earth fault element
For installations where the earth fault element is required to have a sensitive setting whilst remaining stable on heavy through faults, the use of a stabilising resistor is recommended, the value of which will vary according to the specific application. If assistance is required in selecting the appropriate value, please consult the Applications Department of ALSTOM T&D Protection & Control Ltd.
9
Time delayed settings (Is), phase/ earth fault measuring range: 5% to 240% of In in 5% steps.
Setting ranges
Instantaneous setting (Iinst) 1 x –31 x
Is in 1 x 1s steps
Operating time
Time delayed element Operating characteristics selectable to give:
Shown in Figure 10 Standard inverse IDMT Very inverse IDMT Extremely inverse IDMT Long time earth fault IDMT Definite time 2s, 4s, 8s
Time multiplier setting
0.05 to 1.0 in 0.025 steps (applicable to all time characteristics)
Instantaneous elements
Shown in Figure 11 For settings of 5 x Is and above:
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