Study of O/C, E/F Relay Settings and Tripping Characteristics Formula to Calculate Operating Time in case of IEC Overcurrent IDMT Curves: k x B t = ___________ (I/Is)^a - 1 where t = operating time (sec) k = TMS (time multiplier settings) I = measured current value (A) Is= set current value a B Normally Inverse 0.02 0.14 Very Inverse 1.0 13.5 Extremely Inverse 2.0 80.0 Long Time Inverse 1.0 120.0 NI = 3/10, VI = 1.2/10, EI = 0.8/10, LTI = 12/10. You can also refer to BS142.1966 or IEC 255-4.
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Study of O/C, E/F Relay Settings and Tripping Characteristics
Formula to Calculate Operating Time in case of IEC Overcurrent IDMT Curves: k x B t = ___________ (I/Is)^a - 1 where t = operating time (sec) k = TMS (time multiplier settings) I = measured current value (A) Is= set current value a B Normally Inverse 0.02 0.14 Very Inverse 1.0 13.5 Extremely Inverse 2.0 80.0 Long Time Inverse 1.0 120.0 NI = 3/10, VI = 1.2/10, EI = 0.8/10, LTI = 12/10. You can also refer to BS142.1966 or IEC 255-4.
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Technical Bite
Understanding The IEC Based IDMT Settings of Phase Over-current (51) Protection forSEPAM Protective Relay
Protective Relay Settings
SEPAM RelayTo set the IDMT characteristic of a SEPAM relay, thefollowing parameters should be considered:
1) Type of current transformer and its rated currentThe primary and secondary rated current of the CTs (1Aor 5A), will be determined in the general settings of therelay.
2) A/B group settingsThe phase over-current functions of a SEPAM relaycomprises 4 independent elements which are dividedequally into 2 groups (A & B). Having 2 groups (A & B)of settings cater to a changing network configuration.
Example: In a specific network� Group A settings are for the network, supplied by the
utility� Group B settings are for the network, supplied by a
backup generator
Hence for a network that connects only to the utility,it is normal to use group A settings and to disable groupB settings.
3) Threshold current in A or kAThreshold current refers to the current setting at whichthe relay starts to operate (Is). This current is based onthe primary current and it is not necessary to do a currenttransformation. This is because the CT ratios have beendetermined in the general settings of the relay.
Example:For a CT of 100/5A, if the relay is set to operate at 50A,Is will be set as 50A. This setting is equivalent to a P.Sof 50%
However, for an electromechanical relay, it is interestingto note that both I and Is are referring to the secondarycurrent of the CTs. In other words, the ratio of I/Is isequivalent to the multiples of plug setting current.
Figure 1 shows a range of normal inverse, or standardinverse curves at various TMS, which ranges from 0.1 to1.
By varying the α and K values in the same formula, fourstandard curves, the normal inverse, very inverse, extremelyinverse and the long-time inverse are available.
IntroductionPhase over-current protection is a common and widelyused protection scheme that is implemented in high voltageand low voltage networks. As we are more familiar withsettings based on how we set the electromechanical relays,this section describes the ways to set the SEPAM relayfor phase over-current protection, in close relation to thesettings in an electromechanical relay.
IDMT Electromechanical RelayInverse Definite Minimum Time (IDMT) is affected by theinverse proportional relationship between the operatingtime of the relay and the function of current. For theelectromechanical relay, there are two adjustments:
1) Plug Setting (P.S)The plug setting determines the current at which the relaywill start to operate. It is seen by adjusting the position ofa plug in a plug bridge.
Example:For a 100/5A CT, if the relay is set to operate at 5A, theplug setting will be:
P.S (%) = (Relay current setting)/5A = 5A/5A = 100%.Likewise, for the relay to operate at 2.5A,P.S (%) = 2.5A/5A = 50%.
2) Time Multiplier Settings (TMS)The time multiplier setting controls the relay’s discmovement. The position of the moving contact is usuallyadjusted by turning the time multiplier knob, which rangesfrom 0.1 to 1.0. Hence, the appropriate choice of TMSsettings will provide grading of a network protection system.
For both electromechanical and microprocessor - basedrelays, the IDMT characteristics are derived from a formulathat complies with BS142 and IEC 60255 standards. Itis generally defined as:
Table 1. Values of α and K determine the degree ofinverse in the IDMT curves
where T = operating time in sTMS = time multiplier settingI = value of actual secondary currentIs = value of relay current settingα and K are constants.
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Similarly, by varying the α and K values in the sameformula, it leads to four standard curves.
Table 2. Values of α, Κ and β which determine thedegree of inversian of the IDMT curve
In comparison with the earlier formula based on TMS, therelationship is T/ β = TMS. This is because the time delayT is the operation time of the relay when the currentreaches 10Is. Hence, the time delay of the IDMT trippingmay be set either by:
� T (s): operation time at 10Is or� TMS: where TMS = T/ β
Example:For 100/5 CT with P.S at 100%, TMS=0.1, using thestandard inverse 3/10 curve, the SEPAM relay will be setbased on the following:Is = 100AType of curve =SIT/AIf the setting mode is set as 10I/Is thenT= β X TMS = 2.97 X 0.1 = 0.297.If the setting mode is set as TMS, then TMS will be setat 0.1.With a primary current of 200A passing through the relay,both modes will provide the same tripping time:
09
Figure 2 shows that there are Type 1 and Type 1.2characteristic curves in SEPAM. For instance, under theSI curve, there is the SIT, which is based on Type 1.2characteristic. The other is the SIT/A, which is based onType 1 characteristic.
4) TMS or 10I/Is settingsIn SEPAM, the IDMT characteristic curve is also derivedfrom the formula that complies with the BS142 and IEC60255 standards. It is mathematically defined as
where Td = operating time in sT = operation time at 10Is,Is = primary threshold current in A or kAI = primary actual current value in A or kAα, Κ and β are constants.
Td(s) = 0.14 X (0.297/2.97) = 1s(200/100)0.02 -1
The Difference Between Type 1 And Type1.2 IDMT CurvesIt is important to distinguish the difference in the initial pickup of the various types of IDMT curves.
Type of curve Type
Standard inverse time (SIT) 1.2Very inverse time (VIT or LTI) 1.2Extremely inverse time (EIT) 1.2Ultra inverse time (UIT) 1.2RI curve 1IEC standard inverse time SIT/A 1IEC very inverse time VIT or LTI/B 1IEC extremely inverse time EIT/C 1IEEE moderately inverse (IEC/D) 1IEEE very inverse (IEC/E) 1IEEE extremely inverse (IEC/F) 1IAC inverse 1IAC very inverse 1IAC extremely inverse 1
Figure 2 Type of IDMT curves
The curve equations are given in the chapter entitled "IDMT protection functions"
Figure 3 shows that for the Type 1 curve, the relay willactivate at 1 X Is, after a certain time delay. However, forType 1.2 curve, the relay will only activate at 1.2 X Is. TheType 1.2 curve characteristic is in accordance with BS142 standard, which has considered the nature of theelectromechanical relay. With a better understanding ofthe IDMT curves and the way the SEPAM relay interpretsthe curves, SEPAM users will better appreciate the flexibilityof the settings for phase over-current (51) protections.
Figure 3. IDMT curves based on Type 1 and Type 1.2
Type 1.2
Type 1t
T
1 1.2 10 20 Ms
REFERENCESElectrical Network Protection, SEPAM Series 20 User Manual.Electrical Network Protection, Protection Guide.
2.4.1 PHASE TIME OVERCURRENT ELEMENT (51P)DIFFERENTIAL UNITS (87-1) (87-2)
A Phase Time Overcurrent unit is provided in the relay. There are three possibilities for the curve selection, depending onthe selected model.
IEC curves comply with the criteria specified in the IEC255-4 Standard and British Standard BS142
ANSI curves comply with ANSI C37.90 standards
IAC curves simulate the behaviour of GE IAC relays.
A time dial can be applied to any of these curves to optimize co-ordination with other devices in the net. Additionally, thereis a possibility to define a User’s Curve, which can be used for both three-phase overcurrent and ground elements.
In order to avoid undesired trips, time overcurrent elements will not pickup till a value of 1.05 * Set value.
Due to design criteria, actual pickup level has been INTENTIONALLY set to +5% over the set value to ensure that even inthe worst case scenario the relay will NEVER TRIP under the intended setting.This meets IEC international standards.
2.4.1.1 IEC CURVES
The general formula for IEC/BS142 curves is as follows:
Where:
D =Time Dial setting (set in the relay by user).
V = I / Ipickup setting > 1.05
2.4.1.2 ANSI CURVES
The general formula for all ANSI curves is as follows:
Where:
M =Time Dial setting (set in the relay by user).
V = I / Ipickup setting > 1.05
CURVE NAME A P Q B KMod Inverse (IEC Curve A) 0.14 0.02 1 0 0Very Inverse (IEC Curve B) 13.5 1 1 0 0Extremely Inverse (IEC Curve C) 80 2 1 0 0
CURVE NAME A B C D EInverse 0.0274 2.2614 0.3000 -4.1899 9.1272Very Inverse 0.0615 0.7989 0.3400 -0.2840 4.0505Extremely Inverse 0.0399 0.2294 0.5000 3.0094 0.7222
GEK-106237P MIFII Digital Feeder Relay 2-5
2 PRODUCT DESCRIPTION 2.4 OVERCURRENT ELEMENTS
2
2.4.1.3 IAC CURVES
The general formula of IAC Curve is as follows:
Where:
TDM: Time Dial Multiplier (Set in the Relay by User)
I / Ipickup setting > 1.05
2.4.1.4 USER CURVES
The general formula for the user curve is as follows:
Where:
D =Time Dial setting (set in the relay by user).
V =I / Ipickup setting > 1.05
I =Input Current
T =Operate Time (sec.)
A, P, Q, B, K =Constants defined in the standard, as follows:
Settings available for the phase time overcurrent unit allows the user to: enable/disable the unit; set the pickup value(between 0.1 – 2.4 times the rated current in case of 1/5 A ground, or 0.005-0.12 A in case of sensitive ground) and set thecurrent/time operating characteristic (type and time dial).
Note: The relay will use either IEC, IAC or ANSI curves, depending on the model. Refer to Appendix B for a deeperexplanation of the curves.
PARAMETERS A B P O KRange 0 – 125 0-3 0-3 0-2 0-1.999Step 0.001 0.001 0.001 0.001 0.001Unit Sec. Sec. NA NA Sec.Default value 0.05 0 0.04 1 0
2-6 MIFII Digital Feeder Relay GEK-106237P
2.4 OVERCURRENT ELEMENTS 2 PRODUCT DESCRIPTION
2
2.4.2 PHASE(50P1, 50P2)
MIFII provides 2 phase instantaneous overcurrent elements, 50P1 (‘H’ for high pickup) and 50P2 (‘L’ for low pickup). Eachone can be enabled/disabled and set independently. Settings from these elements allow to set the pickup value from 0.1 to30 times the rated current, and the time delay from 0.00 to 600.00 seconds.
2.4.3 GROUND TIME OVERCURRENT ELEMENT (51G)
The Ground Time Overcurrent element offers the same setting possibilities as the Phase Time Overcurrent element. Theground current can be obtained from a residual connection on the CTs. For a more sensitive ground current detection, awindow type (zero sequence) CT, taking the three phases inside its windows can be used. Refer to figure 3-6 for moredetails.
2.4.4 GROUND INSTANTANEOUS OVERCURRENT ELEMENTS (50G1, 50G2)
The MIFII relay provides 2 Ground Instantaneous Overcurrent Elements, 50G1 (‘1’ for High pickup) and 50G2 (‘2’ for Lowpickup). Settings and ranges available for these elements are the same ones described for the Phase InstantaneousOvercurrent Elements, 50P1 and 50P2.
GEK-106237P MIFII Digital Feeder Relay B-1
APPENDIX B B.1 IEC/BS142 CURVES
B
APPENDIX B TIME-CURRENT CURVES FOR 51P AND 51N UNITSB.1IEC/BS142 CURVES
For 1 < V <1.05 the unit will show a pickup signal and generate no trip.
For 1.05 ≤ V <20.00 trip time will be:
For V ≥ 20.00, trip time will be the same as for 20 times the setting:
Where:
D = Time Dial
Table B–1: GE IEC/BS142 INVERSE TIME CURVE CONSTANTS
CURVE NAME A P Q B KExtremely inverse IEC Curve C 80 2 1 0 0Very inverse IEC Curve B 13.5 1 1 0 0Inverse IEC Curve A 0.14 0.02 1 0 0
B-2 MIFII Digital Feeder Relay GEK-106237P
B.1 IEC/BS142 CURVES APPENDIX B
B
Trip times for IEC/BS142 curves are as follows:
Table B–2: TRIP TIMES (IN SECONDS) FOR IEC/BS142 CURVES
For 1 < V < 1.05 the unit will show a pickup signal and generate no trip.
For 1.05 ≤ V < 20.00, trip time will be
For V ≥ 20.00, trip time will be the same as for 20 times the setting
Where:
M = Time Dial
Table B–3: GE ANSI INVERSE TIME CURVE CONSTANTS
CURVE NAME A B C D EExtremely inverse 0.0399 0.2294 0.5000 3.0094 0.7222Very inverse 0.0615 0.7989 0.3400 -0.2840 4.0505Inverse 0.0274 2.2614 0.3000 -4.1899 9.1272
GEK-106237P MIFII Digital Feeder Relay B-7
APPENDIX B B.2 ANSI CURVES
B
Table B–4: TRIP TIMES (IN SECONDS) FOR ANSI CURVES
For 1<I/Ipickup<1.05 the unit will show a pickup signal and generate no trip
For 1.05<=I/Ipickup<30 trip time will be:
For I/Ipickup >= 30
Where:
TDM: Time Dial
Table B–5: GE IAC INVERSE TIME CURVE CONSTANTS
IAC CURVE SHAPE HMI A B C D EIAC Extremely Inverse Extr Inverse 0.0040 0.6379 0.6200 1.7872 0.2461IAC Very Inverse Very Inverse 0.0900 0.7955 0.1000 -1.2885 7.9586IAC Inverse Mod Inverse 0.2078 0.8630 0.8000 -0.4180 0.1947IAC Inverse Long Inverse Long 0.3754 17.8307 0.32 -23.7187 23.8978IAC Inverse Short Inverse Short 0.0442 0.0482 0.34 0.0223 0.0697
Although the curves tend towards infinite when the current approaches Is (general threshold), the minimum guaranteed value of the operating current for all the curves with the inverse time characteristic is 1.1Is (with a tolerance of ± 0.05Is).
12.1.1 Inverse Time Curves:
The first stage thresholds for phase (earth) overcurrent can be selected with an inverse definite minimum time (IDMT) characteristic. The time delay is calculated with a mathematical formula.
In all, there are eleven IDMT characteristics available.
The mathematical formula applicable to the first ten curves is:
( ) ⎟⎟⎠
⎞⎜⎜⎝
⎛+
−×= L
IIKTtS 1α
Where:
t Operation time
K Factor (see table)
I Value of measured current
Is Value of the programmed threshold (pick-up value)
α Factor (see table)
L ANSI/IEEE constant (zero for IEC and RECT curves)
T Time multiplier setting from 0.025 to 1.5
Type of curve Standard K factor α factor L factor
Short time inverse AREVA 0.05 0.04 0
Standard inverse IEC 0.14 0.02 0
Very inverse IEC 13.5 1 0
Extremely inverse IEC 80 2 0
Long time inverse AREVA 120 1 0
Short time inverse C02 0.02394 0.02 0.01694
Moderately Inverse ANSI/IEEE 0.0515 0.02 0.114
Long time inverse C08 5.95 2 0.18
Very inverse ANSI/IEEE 19.61 2 0.491
Extremely inverse ANSI/IEEE 28.2 2 0.1217
Rectifier protection RECT 45900 5.6 0
The RI curve has the following definition:
( )IsI
K = t 236.0339.0
1
−⋅
K setting is from 0.10 to 10 in steps of 0.05. The equation is valid for 1.1 ≤ I/Is ≤ 20.
Technical Data P12x/EN TD/H86 MiCOM P120/P121/P122/P123
Page 19/38
12.1.2 RXIDG Curves (P122/P123 only):
RXIDG curves can be selected on P122 & P123 with medium earth current sensitivity (corresponding to Cortec model number P12-B-X---X).
The first and second earth thresholds can be selected with dedicated RXIDG curves.
The curves available follow the formula :
t = 5.8 – 1.35 * ln ( 1/ (k * Is/I))
Where:
t = tripping time k = coefficient (from 0.3 to 1, by steps of 0.1) IS = value of the programmed threshold (Pick-up value) I = value of measured current
In order to be compliant with the Netmanagement specifications the relay must be used with :
− An earth current range 0.01 Ion to 8 Ion
− A rated current wiring 1A
− A core balanced CT with a ratio 25/1.
12.1.3 Reset Timer
The first stage threshold for phase and earth overcurrent protection is provided with a timer hold facility "t Reset".
The value that is set for this reset timer corresponds to the minimum time during which the current value needs to be lower than 95% of the phase (or earth) threshold before the corresponding phase (or earth) time delay is reset.
NOTE: There is an exception to this rule when the protection triggers. In fact, in this case, the time delays (tI> and tIe>) are immediately reset.
The value of the Reset Timer depends on the type of timer associated to the pick up first phase (or earth) threshold.
Reset Timer Type of timer associated to the first & second phase (earth)
threshold P120, P121 P122, P123
DMT 0 ms 0 ms
Rectifier, IDMT IEC or RI 50 ms Settable from 0 to 600 ms
RXIDG (*) - Settable from 0 to 600 ms
IDMT IEEE or CO 50 ms Settable from 0 to 600 ms or Inverse Time (choice of 5 IEEE
curves)
(*) first and second earth threshold only
Reset timer on P122 & P123 relays:
The first stage threshold for phase and earth overcurrent protection, negative sequence overcurrent on P122 and P123 are provided with a timer hold facility "t Reset".
It may be set to a definite time value or to an inverse definite minimum time characteristic (IEEE/ANSI curves only). This may be useful in certain applications, for example when grading with upstream electromechanical overcurrent relays that have inherent reset time delays.
The second and third stage thresholds for the earth fault overcurrent protection only have a definite time reset.
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MiCOM P120/P121/P122/P123
A possible situation where the reset timer may be used is to reduce fault clearance times where intermittent faults occur.
An example may occur in a cable with plastic insulation. In this application it is possible that the fault energy melts the cable insulation, which then reseals after clearance, thereby eliminating the cause for the fault. This process repeats itself to give a succession of fault current pulses, each of increasing duration with reducing intervals between the pulses, until the fault becomes permanent.
When the reset time of the overcurrent relay is set to minimum the relay will be repeatedly reset and will not be able to trip until the fault becomes permanent. By using the reset timer hold function the relay will integrate the fault current pulses, thereby reducing fault clearance time.
The mathematical formula applicable to the five curves is:
( ) ⎟⎟⎠
⎞⎜⎜⎝
⎛
−×= α
SIIKTt
1
Where:
t Reset time
K Factor (see table)
I Value of the measured current
Is Value of the programmed threshold (pick-up value)
α Factor (see table)
T Reset time multiplier (RTMS) setting between 0.025 and 1.5.
Type of curve Standard K factor α factor
Short time inverse C02 2.261 2
Moderately inverse ANSI/IEEE 4.850 2
Long time inverse C08 5.950 2
Very inverse ANSI/IEEE 21.600 2
Extremely Inverse ANSI/IEEE 29.100 2
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MiCOM P120/P121/P122/P123
The following curves are given for indication only.
12.3 IEC Curves
IEC & AREVA Curves
(TMS=0,025)
0,001
0,01
0,1
1
10
1 10 100
MULTIPLES OF PICK UP SETTING
Short time inverse (AREVA)Standard Inverse
Very InverseExtremely Inverse
Long Time Inverse (AREVA)
TIM
E IN
SE
CO
ND
S
P0006ENb
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Short Time Inverse (AREVA)
0,001
0,01
0,1
1
10
1 10 100
MULTIPLES OF PICK UP SETTING
TMS=0.025 TMS=0.2 TMS=0.5 TMS=1 TMS=1.25
B
B :
C
C :
D
D :
E
E :
A
A :
TIM
E IN
SE
CO
ND
S
P0007ENb
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MiCOM P120/P121/P122/P123
0,01
0,1
1
10
100
1 10 100
E : TMS=0.025 D : TMS=0.2 C : TMS=0.5 B : TMS=1 A : TMS=1.25
MULTIPLES OF PICK UP SETTING
TIM
E I
N S
EC
ON
DS
STANDARD INVERSE (IEC)
A
B
C
D
E
P0008ENa
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0,001
0,01
1
10
100
1 10 100
E : TMS=0.025 D : TMS=0.2 C : TMS=0.5 B : TMS=1 A : TMS=1.25
VERY INVERSE (IEC)TIM
E I
N S
EC
ON
DS
MULTIPLES OF PICK UP SETTING
A
B
C
D
E
P0009ENa
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MiCOM P120/P121/P122/P123
EXTREMEMELY INVERSE (IEC)
0,001
0,01
0,1
1
10
100
1000
10000
1 10 100
E :TMS=0.025 D : TMS=0.2 C : TMS=0.5 B : TMS=1 A : TMS=1.25
A
B
C
D
E
TIM
E I
N S
EC
ON
DS
MULTIPLES OF PICK UP SETTING
P00010ENa
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0,1
1
100
1000
10000
1 10 100
E : TMS=0.025 D : TMS=0.2 C : TMS=0.5 B : TMS=1 A : TMS=1.25
LONG TIME INVERSE (AREVA)
AB
C
D
E
TIM
E IN
SE
CO
ND
S
MULTIPLES OF PICK UP SETTING
P0011ENb
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MiCOM P120/P121/P122/P123
12.4 RI Curves
RI CURVES
A
B
C
D
E
0,1
1
10
100
1 10 100
E : k=0.1 D : k=1 C : k=2 B : k=5 A : k=10
TIM
E I
N S
EC
ON
DS
MULTIPLES OF PICK UP SETTING
P0012ENa
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12.5 IEEE/ANSI & CO Curves
ANSI/IEEE & CO curves
(TMS/RTMS=0.025)
0,0001
0,001
0,01
0,1
1
10
100
0,01 0,1 1 10 100
MULTIPLES OF PICK UP SETTING
Short Time Inverse (CO2) Moderately Inverse
Long Time Inverse (CO8) Very Inverse
Extremely Inverse
TIM
E I
N S
EC
ON
DS
P0013ENa
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Page 29/38
12.5 IEEE/ANSI & CO Curves
ANSI/IEEE & CO curves
(TMS/RTMS=0.025)
0,0001
0,001
0,01
0,1
1
10
100
0,01 0,1 1 10 100
MULTIPLES OF PICK UP SETTING
Short Time Inverse (CO2) Moderately Inverse
Long Time Inverse (CO8) Very Inverse
Extremely Inverse
TIM
E I
N S
EC
ON
DS
P0013ENa
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MiCOM P120/P121/P122/P123
SHORT TIME INVERSE (CO2)
0,0001
0,001
0,01
0,1
1
10
100
0,01 0,1 1 10 100
MULTIPLES OF PICK UP SETTING
A
B
C
D
E
A
B
C
D
E
E : TMS/RTMS=0.025 D : TMS/RTMS=0.2 C : TMS/RTMS=0.5
B : TMS/RTMS=1 A : TMS/RTMS=1.25
TIM
E I
N S
EC
ON
DS
P0014ENa
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MODERATELY INVERSE (ANSI/IEEE)
0,01
0,1
1
10
100
1000
0,01 0,1 1 10 100
MULTIPLES OF PICK UP SETTING
A
B
C
D
E
A
B
C
D
E
E : TMS/RTMS=0.025 D : TMS/RTMS=0.2 C : TMS/RTMS=0.5
B : TMS/RTMS=1 A : TMS/RTMS=1.25
TIM
E I
N S
EC
ON
DS
P0015ENa
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MiCOM P120/P121/P122/P123
LONG TIME INVERSE (CO8)
0,001
0,01
0,1
1
10
100
0,01 0,1 1 10 100
MULTIPLES OF PICK UP SETTING
E : TMS/RTMS=0.025 D : TMS/RTMS=0.2 C : TMS/RTMS=0.5
B : TMS/RTMS=1 A : TMS/RTMS=1.25
TIM
E I
N S
EC
ON
DS
A
B
C
D
E
A
B
C
D
E
P0016ENa
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VERY INVERSE (ANSI/IEEE)
0,01
0,1
1
10
100
1000
0,01 0,1 1 10 100
MULTIPLES OF PICK UP SETTING
E : TMS/RTMS=0.025 D : TMS/RTMS=0.2 C : TMS/RTMS=0.5
B : TMS/RTMS=1 A : TMS/RTMS=1.25
TIM
E I
N S
EC
ON
DS
A
B
C
D
E
A
B
C
D
E
P0017ENa
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MiCOM P120/P121/P122/P123
EXTREMELY INVERSE (ANSI/IEEE)
0,001
0,01
0,1
1
10
100
1000
0,01 0,1 1 10 100
MULTIPLES OF PICK UP SETTING
E : TMS/RTMS=0.025 D : TMS/RTMS=0.2 C : TMS/RTMS=0.5
B : TMS/RTMS=1 A : TMS/RTMS=1.25
TIM
E I
N S
EC
ON
DS
AB
C
D
E
A
B
C
D
E
P0018ENa
Technical Data P12x/EN TD/H86 MiCOM P120/P121/P122/P123