Machine Protection Setting Exercises
Exercise 1: Single line diagram 3∼ 110 kV, 50 Hz
7UM62 . side 1 iL1,2,3
300/1A, 20VA 5P20, Rct=1.2 -T1 50 MVA, YNd11 110 ±5·2.5% ±5·2.5% / 11 kV uT(1) = 8 %
Q7
300/1A, 20VA 5P20, Rct=1.2 11 kV 3
0.1 kV 3
sensitive current input only!! Q8
0.1 kV
uL1,2, 3
3
3000/1A, 20VA 5P20, Rct=12 -G1 46.6 MVA 11kV ±7.5% 50Hz
7XR6004
G 3~
7XT71
Excit.
11 kV/ 3 500V
7XT34 400/5A
7XT33 20Hz Gen.
~ 5/2
Ucontr . Umeas .
TD1
(REF)
TD2
(REF)
TD3
(
side 2 iL1,2,3
3PP1326
3000/1A, 20VA 5P20, Rct=12
IEE2
UE IEE1
SEF (20Hz) SEF
Exercise 1: Neutral transformer transformer circuits
Protection cubicle
max. 3A (20Hz)
20 Hz Bandpass
20 Hz Generator
7XT34
7XT33
1B1 1A4
1B4
4A1
660 660
.. mA
11 kV/ 3
660 660
RL
500V
P2 S2
400/5A 1FS5 15VA
1A1
1A2 P1
20Hz
330 330 1A3 4A3
S1
7UM62. Burden < 0.5
R13
UE
R14 J8 J7
IEE1
Exercise 1: Required protection elements --
Threshold supervision (for Decoupling)
64G 64 G-1
90% Stato ator Ea Earth Fa Fault U0 U0> (ca (callculat lated)
64G 64 G-2
100% Stat Stato or Ear Eartth Fau Faullt (20 (20H Hz pr princ inciple) le)
64R
Rotor Earth Fault (1-3Hz principle)
87
Differential Protection
46
Unbalanced Load (negative sequence)
40
Under excitation
49
Thermal Overload (Stator)
24
Overexcitation (V/Hz)
21
Impedance Protection
78
1) Out of Step (loss of synchronism)
1) Option
Exercise Exercis e 1: Device configuration (partly)
for Decoupling
for Decoupling
Exercise 1: Power System Data 1 (1/4)
1)
0275 Factor R SEF = (ratio Neutral Transf.) 2 ⋅
11000V/ 3 0275 Factor R SEF = 500V
2
1) Neutral transformer is high resistive
⋅
5/2 400/5
ratio (U divider )
=
ratio (CT) 5.04
Exercise 1: Power System Data 1 (2/4)
Exercise 1: Power System Data 1 (3/4)
Refer to Setting Options for the UE Input and their Impact on the Protection Functions (refer to slide No. 10)
0224 Factor UE
=
0224 Factor UE
=
U VTprim U Esec
U NTprim
=
U NTsec /ratio(U divider )
11000 V/ 3 500 V/(5/2)
=
31.7
Exercise 1: Power System Data 1 (4/4)
Setting Options for the UE Input and their Impact on the Protection Functions
Exercise 2: Generator Electrical Data (1/2)
Exercise 2: Generator Electrical Data (2/2)
Exercise 2.1: Calculation of load resistor and neutral transf. (1/3)
90% (K=0.1)
ULV
CK
UHV
11 kV/ 3
1L1
500V 1L2 1L3
RL
CG
UE
CL
IE prim
CK = 10 nF UHV = 110 kV ULV = 11 kV
equivalent circuit CK
7UM62.
CE
RL prim
IC prim
~
CTr
UE0
CE = CG + CL + CTr neglected RL prim << 1/(ω·CK)
protected zone (stator) = 90% K = (100%-90%)/100% = 0.1
Exercise 2.1: Calculation of load resistor and neutral transf. (2/3) Formula symbols and definitions used: UE0
Displacement voltage on HV side of unit transformer
Fe
Earthi Earthing ng factor, factor, here: here: solid earthed Fe = 0.8
ICprim
Interference current on neutral transformer primary side
ICsec
Interference current on neutral transformer secondary side
CK
Total capacitance (3x phase capacitance) between HV and LV side of unit transformer (coupling capacitance)
f
Rated frequency
TRNT
Transformation ratio of the neutral transformer
UNTPrim Primary Primary rated voltage voltage of of neutral neutral transformer transformer UNTSec Secondary rated voltage of neutral transformer RL
Load resistor
K
Protected zone factor
FS
Safety factor FS = 2
SNT(20s) Required output of neutral transformer when burdened by RL for 20 s IRLmax Current of load resistor R at 100 % UE
Exercise 2.1: Calculation of load resistor and neutral transf. (3/3)
U E0
=
Fe ⋅ U HV / 3
I C prim = U E0 ⋅ 2 ⋅ π ⋅ f ⋅ C K TR
NT
=
U NTsec K
0.8 ⋅ 110 kV/ 3
I C prim = 50800V
U NTprim TR
I C sec = I C prim ⋅ TR RL =
=
U E0
⋅
Fs
NT
U NTsec
NT
I C sec
11000 V/ 3
0.1 2
S NT(20s) = I RLmax
=
RL
[VA ]
U NTsec RL
S NT(20s) = I RLmax
=
⋅
500 V 2.03 A
2
U NTsec
⋅ 2 π ⋅ 50s
500 V = 0.16 A ⋅ 12 . 7
RL =
I C sec
=
500 2 V 2 12.3 500 V
=
12.3
=
=
50.8 kV -1
⋅ 10 ⋅ 10
−9
As
=
V
= 12.7
2.03 A
= 12.3
[VA ] = 20.3
kVA
40.65 A
Earth fault at generator terminals : I E prim
=
U NTsec R L ⋅ TR NT
I E prim
=
500 V 12.3 ⋅12.7
=
3.2 A
< 10A
⇒ ok
0.16 A
Exercise 2.2: Decoupling Decoupling - Example with Threshold Threshold supervision supervision (1/3) (1/3) It can be assumed that the Generator will run out of step in case a three-phase short circuit circuit close to the power power station will will last for (example) (example) more than 150ms. 150ms. This situation can be described by the following AND logic. If the fault is not cleared immediately the unit will be decoupled from the net after 150 ms. CFC MV2<, 8503, 8504
-dP -dP (-50 (-50%) %)
07961 T
07963
0113
I>> (3·IN, p.u.)
Q
R
Q
8602: t = 0.15s
&
MV4<, 8507, 8508
0
S
01808
04526 External Trip 1
Exercise 2.2: Decoupling Decoupling - Example with Threshold Threshold supervision supervision (2/3) (2/3)
Exercise 2.2: Decoupling Decoupling - Example with Threshold Threshold supervision supervision (3/3) (3/3)
Settings: primary values
Exercise Exercise 2.3 2.3:: Settings Settings for 90% Stator Stator Earthfaul Earthfaultt - U0>calcul U0>calculated ated (1/2) (1/2) L1 L2
UL3
L3 90%
Settings (primary value): 5002: U0prim> = 100% - 90% = 10.0 %
UL1
5003: T = 0.30 sec
Fuse Failure Monitor (FFM) to be enabled to block 90% SEF Element via CFC
UL2
Exercise Exercise 2. 2.3: 3: Setting Settings s for 90% 90% Stator Stator Earthfau Earthfault lt - U0>calcu U0>calculated lated (2/2)
Settings: primary values
Exercise 2.4: Settings for unbalanced load (1/3)
(from Manufacturer)
Exercise Exercis e 2.4: Settings for unbalanced load (2/3)
Settings in primary values: 1702: I2prim> = I2perm prim / IN Machine = 8.0 % 1704: Kprim = (I2 /IN)2·t = 20 s 1705: tCooldown = Kprim /(I2perm prim /IN Machine)2 = 20s/0.082 = 3125 s 1706: I2prim>> = 60.0% 1707: T I2>> = 3.00 sec
Conversion to secondary values: 1702: I2sec> = I2prim> · IN Machine /IN CT = 8.0 8.0% % · 2446A/3 2446A/3000A 000A = 6.5 % 1704: Ksec = Kprim · (IN Machine /IN CT)2 = 20s·(2446A/3000A)2 = 20s·0.664 = 13.30 s 1706: I2sec>> = I2prim>> · IN Machine /IN CT = 60.0% 60.0% · 2446A/3 2446A/3000 000A A ≈ 49 %
Exercise 2.4: Settings for unbalanced load (3/3)
Settings: primary values
Exercise Exercis e 2.5: Settings for under excitation protection (1/4) Generator capability diagram
Exercise Exercis e 2.5: Settings for under excitation protection (2/4) Settings in primary values (from Capability Diagram) 3002:
1/xd1prim = 0.58
tan(α1) = 0.7/0.2 = 3.5 , arctan(α1) = 1.292 3003: α1 ≈ 74° 3005:
1/xd2prim = 0.44
3006:
α2
= 90°
Conversion to secondary values: 1
1
=
x dsec
x dMach
I NMACH
⋅
U NMACH
⋅
I NMACH U NMACH
U N VTprim I N CTprim
=
⋅
UNMACH = 11kV , UN VTprim = 11 kV INMACH = 46600kVA/(√3·11kV) = 2446A IN CTprim = 3000A
U N VTprim I N CTprim
2446 A ⋅ 11 kV 11k V ⋅ 3000 A
=
0.815
3002: 1/xd1sec = 0.58·0.815 ≈ 0.47 3005: 1/xd2sec = 0.44·0.815 ≈ 0.36
Exercise 2.5: Settings for under excitation protection (3/4) Protection cubicle 7XT71
7XR6004 20 k k
A 3
G 3~
A6
TD1
27 19 21
1)
Excit.
7UM62.
contro l
K13 + K14 TD2
A1 1 B11
generator shaft
B1 8
20 k k
20 k k 20 k k
15 17 B1 4
25 Example: LiYCY LiYCY 4x1.5 4x1.5
7UM62.
3PP1326 1
500 500
TD3 2
500 500 4
3013 : U Exc < 0.5 ⋅
9 k k
3
U EXC 0 k u
UEXC0 = 45V ku (voltag (voltage e divide divider) r) = (0.5 (0.5 k+ 0.5 k + 9 k)/ 0.5 k = 20 3013 U Exc = 0.5· 0.5·45 45 V /20 ≈ 1.13 V
meas.
K15 + K16
10µF 250V
K17 + K18
Exercise 2.5: Settings for under excitation protection (4/4)
Settings: primary values
Exercise 2.6: Settings for (stator-) thermal overload (1/5)
(from Manufacturer)
Exercise 2.6: Settings for (stator-) thermal overload (2/5) Settings in primary values:
1602 16 02::
k-factor: without additional information's the voltage deviation can be taken into account. From Generator electrical data: voltage deviation (-) = 7.5% for nominal load and -7.5% voltage the current will increase to 1.075 p.u. k-F k-Factor (pri prim.) = 1.07 1.07 From generator electrical data: ILoad = 1.3·In t(trip) = 60s at IPreload = 1·In τ=
t 2
I Load I Preload − ⋅ ⋅ k I k I n n ln 2 I Load − 1 ⋅ k I n
2
60s
=
2
1.3 ⋅ I n 1⋅ I n − ⋅ ⋅ 1.07 I 1.07 I n n ln 2 1.3 ⋅ I n − 1 ⋅ 1.07 I n
2
=
60s ln(1.2658)
=
1603:
the herrmal time co const nstant = 255 255 sec
1604:
thermal alarm alarm stage: stage: setting setting must be higher than than 1/k2 = 1/1.072 = 0.873 thermal alarm stage = 90 %
1610A: 1610A: Curren Currentt Over Overloa load d Alar Alarm m Setpo Setpoint int = 107% 107%
60s 0.2357
≈
255s
Exercise 2.6: Settings for (stator-) thermal overload
(3/5)
Settings in primary values: 1612A: 1612A: kt-Facto kt-Factorr when Motor Motor Stops Stops = 1.0
(xxxx)
The thermal Overload should not trip for example before Over current protection 1615A: Maximum Current for Thermal Thermal Replica Replica = 250% 250% 1616A: 1616A: Emergenc Emergency y Time Time = 100 sec sec
(xxxx)
From Generator electrical data: winding temp. rise Stator = 61 K 1605: Temper 1605: Temperat atur ure e Ris Rise e at R Rate ated d Sec. Sec. Cur Curr. r. = 61°C
Conversion to secondary values: 1602 16 02::
k-Fa k-Fact ctor or (sec (sec.) .) = k-F k-Fac acto torr (pr (priim. m.)) · IN Machine /IN CT = 1.0 1.07· 7· 2446A/3 2446A/3000A 000A = 0.8 0.87 7
1610A 1610A:: Cu Curr rrent ent Over Overlo load ad Ala Alarm rm Setp Setpoi oint nt (Sec (Sec.) .) = 1.07· 1.07· IN Machine· IN CT sec /IN CT prim = 2446A·1A/3000A = 0.87 A 1605 16 05::
Temp Temp.. Rise Rise (Sec (Sec.) .) = Tem emp. p. Ris Rise (Prim Prim.) .) · (IN CT /IN Machine)2 = 61°C 61°C · (3000A/2446A) (3000A/2446A)2 = 92°C
Exercise 2.6: Settings for (stator-) thermal overload
(4/5)
10000 t [s]
Trip. characteristic for τ = 255s, k =1.07 and preload = 1·In Trip. characteristic for τ = 255s, k =1.07 and preload = 0
1000
Trip. characteristic from generator electrical data
100
10
1 1
2
3
I/In
4
Exercise 2.6: Settings for (stator-) thermal overload
(5/5)
Settings: primary values
Exercise 2.7: Settings for generator over excitation U/f (1/2) (from Manufacturer)
Exercise 2.7: Settings for generator over excitation U/f
(2/2)
Exercise 2.8: Settings for impedance impedance protection (1/4) t TEND 1*) T2
2*)
T1,T1B Z1 (R1,X1)
X1 ≈ 0.70·X1 Transformer X1 ≥ X1 Transformer
Z Z2 (R2,X2)
G 3~
Z< , 7UM6
BI. (activating (activati ng Z1b)
1*) To be coordinated with net protection 2*) Setting can (must) be higher than the real Z up to the HV C.B.
Z1b (R1b,X1b)
Exercise 2.8: Settings for impedance impedance protection (2/4)
3306 : Z1(prim) Im (Z)
k r
⋅
⋅
U 2N Trf.LV
100% 100%
S N Trf
Protectionzone reach into = 70%)
3307 : T1 = 0.10 sec
X2=Z2
R1= Z1
=
uT
transformer (here : k r
X1b=Z1b
X1=Z1
=
k r
R2=Z2 R1b= Z1b Re (Z)
=
3308 : Z1b(prim)
2
uT
⋅
U N Trf.LV
100%
here : k x
=
S N Trf
⋅ k x
2
3309 : T1b = T1 3310 : Z2(prim) Z Net
→
uT
=
2
⋅
U N Trf.LV
100%
S N Trf
+ Z Net
to be coordinated with net protection
here : Z Net
= 0.0
3311 : T2 → to be coordinated with net protection here : T2 = 0.50 sec 3312 : TEND
→
to be coordinated with net protection
here : TEND
= 3.00 sec
Exercise 2.8: Settings for impedance protection (3/4) Settings in primary values: 70%
=
3306 : Z1(prim)
8%
⋅
⋅
11 kV 2
=
100% 100% 50 MVA 3307 : T1 = 0.10 sec =
3308 : Z1b (prim)
8%
⋅
11 kV 2
100% 50 MVA 3309 : T1b = 0.10sec 3310 : Z2 (prim)
=
8%
⋅
11 kV 2
100% 50 MVA 3311 : T2 = 0.50 sec 3312 : TEND
⋅2 =
0.136
0.387
+ 0 =
0.194
= 3.00 sec
Conversion to secondary values: 3306 : Z1(sec)
k VT
3308 : Z1b (sec) 3310 : Z2
k CT
=
=
=
⋅ Z1(prim) =
k CT k VT
k CT
3000A/1A 11000V/100 V
⋅ Z1b (prim) =
⋅ Z2 (prim) =
⋅ 0.136 =
3000A/1A 11000V/100 V
3000A/1A
3.71
⋅ 0.387 = 10.55
⋅ 0.194 = 5.29
Exercise 2.8: Settings for impedance protection (4/4)
Settings: primary values
Exercise 2.9: Settings for out of step protection (1/3)
Im (Z)
3505 : Zb(prim)
≈
Zd Char. 2
Zd-Zc Zc φP
Za
Re (Z)
3506 : Zc(prim)
≈
k r(OoS)
=
U N,Gen
=
3 ⋅ I N,Gen ⋅
100% 100% ⋅S N,Tr reach of Characteristic 1 intoTransf ormer = 85%)
→ to be coordinated
here : with k sec Zd(prim) Zb
'
⋅ xd
k r(OoS) u T ⋅ U 2N,Tr(LV)
(here : k r(OoS) Zd(prim)
Char. 1
X d'
=
=
k CT k VT
=
with the net !!
I CTpn /I CTsn U VTpn /U VTsn
10 k sec
3507 : Zd(prim) − Zc(prim) 3504 : Za(prim)
=
3508 : ϕ P = 90°
0.289 ⋅ (Zb (prim)
+ Zc(prim) )
Exercise 2.9: Settings for out of step protection (2/3)
Settings in primary values: 3505 : Z b(prim) 3506 : Z c(prim) k sec
=
≈
11000V 3 ⋅ 2446A
0.561
8% ⋅ 11 2 kV 2
85%
⋅ = 0.165 100% 100% ⋅ 50 MVA k CT 3000 A/1 A = = 27.27 k VT 11000 V/100 V
≈
3507 : Z d(prim) - Z c(prim) 3504 : Z a(prim)
⋅ 0.216 =
=
0.367
− 0.165 =
0.289 ⋅ (0.561 + 0.165
=
) =
Z d(prim)
0.202
0.210
=
10
=
27.27
3508 : ϕ P = 90 °
Conversion to secondary values: k sec
=
27.27 (from above)
3505 : Z b(sec) 3506 : Z c(sec) Z d(sec)
= =
k sec ⋅ Z b(prim)
=
27.27 ⋅ 0.561
k sec ⋅ Z c(prim)
=
27.27 ⋅ 0.165
(Z
d(prim)
=
4.50
= 10
3507 : Z d(sec) - Z c(sec) 3504 : Z a(sec)
= 15.30
=
=
k sec
k sec ⋅ Z a(prim)
⋅
=
- Z c(prim)
27.27 ⋅ 0.210
) = 27.27 ⋅ 0.202 = 5.51 =
5.73
0.367
Exercise 2.9: Settings for out of step protection
(3/3)
Settings: primary values