Shunt reactors in thermal power plant

1. Reactors
in
power system
M.G.Morshad / ACM ( Elect.)
Transformer Mtce. Division / TS II

2. References
1. REPORT - SYSTEM PLANNING & PROJECT APPRAISAL DIVISION – CEA
2. LOAD GENERATION BALANCE REPORT 2010-11 – CEA
3. INSTALLED CAPACITY - CEA
4. JOURNAL - TECH NEWS – AREVA
5. HV SHUNT REACTOR SECRETS FOR PROTECTION ENGINEERS -
Zoran Gajić , Birger Hillström, Fahrudin Mekić ABB Sweden, Västerås, Sweden
6. IEEE Guide for the Protection of Shunt Reactors
7. APPLICATION OF NUMERICAL RELAYS FOR HV SHUNT REACTOR
PROTECTION –
Z. Gajić, B. Hillstrőm, M. Kockott , ABB Automation Technologies ,Sweden
8. TRANSIENTS DUE TO SWITCHING OF 400 KV SHUNT REACTOR
Ivo Uglešić, Sandra Hutter University of Zagreb Miroslav Krepela Siemens Božidar
Filipović- Grčić Croatian National Electricity Franc Jakl University of Maribor
9. IS 5553 ( Part 2) 1990
10. IS 2026 ( Part 1 & 3)
11. Installation & commissioning of shunt reactor - BHEL

3. Reactors in power system
REACTORS
Series
REACTOR
Shunt
REACTOR
PURPOSE
To reduce short
circuit current
PURPOSE
To reduce over
voltage
Z
Z
Acts as inductive load
and reduce high voltage
by absorbing MVAR.
Acts as inductance and
opposes the flow of short
circuit current.
AREA OF
APPLICATION
Tie Lines
AREA OF
APPLICATION
Bus , Lines,
Tertiary winging of
ICT

4. Classification of shunt reactors
Shunt Reactors
Dry Type
(system voltage
Below 72.5 KV)
Oil immersed Type
(system voltage 72.5
KV & above)
Core less Gapped Core
Air Core
•Star connected with neutral
grounding
• Range 30 to 300 MVAR
•Connected at the terminals of
transmission line
• Delta connected
• Range below 30 MVAR
•Connected at the tertiary
winding of transformer
Switch on / off type Permanently connected
type with thyristor
controlled

5. Back ground for
installing shunt
reactor

6. Reason for high grid voltage in
Southern grid during off peak
period – As per CEA report
Availability
28450
MW
Peak Load
demand 34224
MW
Off Peak Load
demand 13000
MW
Installed
Capacity
44220 MW
Grid voltage higher
than rated (Max
1.05PU or 441KV)
Grid voltage lower
than rated (Max
0.95PU or 399 KV)
11Hrs 15Hrs 22
Hrs
03
Hrs

7. Effect of high grid voltage
High over voltage cause –
• Difficulty in regulating load flow through
HVDC line
• Difficulty in synchronization inter grid
transmission line
• instability in generator due to operation of
generator in under excitation zone near the
pole slip region.
• Increase in line loss
Present practice to overcome
overvoltage situation
• Keeping all 64 Nos Reactors (56 Nos Line &8
Nos Bus) are in service during off peak period
• Switching off all lightly loaded lines

8. Extract of PGCIL report (2006)
• With existing reactors and opening of the lines as per
existing practice , the study reports indicate high
voltage profile throughout the grid (the voltage ranges
between 416 kV and 445 kV).
• Addition of 15 numbers of reactors of 63 MVAR each is
not adequate to control the voltages under acceptable
limits even with some of the transmission lines switched
off.
• Even large generating stations like Ramagundam,
Neyveli, Vijayawada, Raichur TPS are not able to hold
their voltages as these are crossing reactive power
absorption limit. As such these stations may also be
considered for installation of bus reactors.
• With 10 more reactors (making it 25 ), the results
indicate that when lightly loaded transmission lines are
out of service, the voltages at various buses are
generally controlled and are less than 420 kV and with
the above lines in, the voltages are higher going up to
431 kV.
• Therefore, it is concluded that provision of large number
of reactors are required to control the high voltages
situation in the grid.

9. Calculation of grid reactive power
About 27 numbers of 63 MVAR shunt reactor are required in southern grid
to absorb reactive power for bringing down grid voltage from 441 KV to
416 KV during off peak period
Formula Data
System Voltage Skv 420 KV
Fault Current level FkA 40 KA
Short Ckt MVA Scc= 1.732 X Skv X FkA 29097 MVA
Max Bus voltage V1 = 441 KV or (441/420) PU 1.05 PU
Acceptable Bus
voltage
V2 = 416 KV or (416/420)PU 0.99 PU
Total reactive
power
Sr = Scc{ ( V2 – V1)/V1} 1763 MVAR
Standard capacity Sst 63 MVAR
Nos of reactor
required
Sr / Sst 27 Nos

10. Recommended location for
additional 25 Nos reactors

11. Advantages of installing reactor
Technical
1. Limited voltage rise on transmission lines at the time of
light loads or after load shedding
2. Prevention of self excitation on generator on leading PF
load.
3. Reduction of over voltage on sound phases during a line
to ground fault.
4. Reduction of switching over voltage due to initial
charging of lines.
Commercial
1. Being a capital item, investment on this equipment will
be adjusted in the fixed cost portion of tariff so that
entire amount ( capital + interest ) will return within the
operating period of the reactors.

12. Basic operating
principle

13. Basic operating principle
System
Voltage, (V)
1. Initial charging current (i) produces pulsating flux in the coil
2. Induced voltage (e) = L (di / dt) is produced in opposite direction of
the coil due to pulsating flux
3. As a result of two opposite voltages current equal to (V-e) / R
passes through the coil
Shunt Reactor acts as inductive load
when it is connected to Bus/Line and
draws current for active & reactive load.
The reactive portion of current creates
pulsating flux in the core and the power
required for this purpose is known as
reactive power (KVAR).
KVAR = Current X system voltage X SinΦ
The active portion of current causes
I2R loss and the power loss due to
heating is known as active power (KW).
KW = Current X system voltage X Cos Φ
Induced
Voltage, (e)
Initial charging current.
Operating current (V-e) / R.
System
Voltage
Operating
current (I)
Active current (I x Cos Φ )
to active load (KW)
Reactivecurrent(IxSinΦ)
toreactiveload(KVAR)
Φ

14. Operating function of shunt reactors
(System voltage – Induced voltage)
1. Current drawn by each phase =
(Resistance per phase winding)
2. Induced voltage (e) depends upon the construction and magnetization characteristic of
the core
3. Shunt reactor is a device with the fixed impedance value. Therefore the individual phase
current is directly proportional to the applied phase voltage (i.e. I=U/Z).
4. For balance three phase current (Ir + Iy + Ib = 0), no current flows through the neutral.
5.Only during fault when phase current becomes un balance (Ir + Iy + Ib ≠ 0), current less
than 1 PU passes through the neutral. It is due to the fact that positive sequence
reactance(X1) is more or less equal to zero sequence reactance (x0) in five limbs core
configuration (Normally X1/Xo = 0.9).
6. During operation heat is produced as a result of copper loss ( due top I2R) and core
Loss ( due to Hysteresis and eddy current)
7. Typical total core & copper loss (KW)= rating of reactor (MVAR) x 0.2%
8. Typical core loss & copper loss = 75% & 25% of total loss respectively
Ir Iy Ib

15. Induced voltage and
Magnetizing
characteristic of the
core

16. Characteristics of the induced voltage
The magnitude of the inductive voltage (e) developed in the
reactor coil due to pulsating flux depends upon -
1. Flux density in the core ( Concentration of flux in the core )
2. Magnetization characteristic of the core ( Ability of the core
to produce flux)
1. Flux density in the core
•The coil provided with iron core always have higher flux
concentration than the coil without core (Air core).
•As higher concentration of pulsating flux creates higher
induced voltage (e) in the coil, iron core is used for higher
voltage (> 72.5KV ) Reactor and air core is used for lower
voltage (< 72.5KV ) Reactor
Reactor - 72.5 KV and above
•Star connected with solid / reactor
grounding
•Oil cooled , gapped core
•Rating 30 to 300 MVAR
•Directly connected to bus /
transmission line
Reactor - Below 72.5 KV
•Delta connected
•Air cooled , Air core
•Rating below 30 MVAR
•Directly connected to tertiary
winding of transformer

17. 2. Magnetization characteristic
V – I
linearity
range
•The flux produced by the core remains proportional to the current passes through the coil
till the core gets saturated.
•After saturation of core it can not produce flux further with the increase of current.
•Because of this magnetic saturation of the core, reactor coil can not develop inductive
voltage (e) further.
•In such condition impedance of the coil becomes lower with respect to the applied
voltage and higher current drawn by the winding causing high I2R loss ( heat generation)
or earth fault.

18. Components of Reactor
WTI
OTI
1. 400KV,1250 Amps OIP HV bushings (3 Nos)
2. 145 KV ,1250 amps neutral bushing (1No)
3. Air cell type conservator tank with silica gel breather
4. Radiator banks (8 Nos) with ONAN type cooling
5. Buchholtz relay, Pressure relief valve and sudden pressure valve for protection
6. Floor mounted marshalling box for providing WTI,OTI and required control circuit for
protection
7. Provision of line side and neutral side CT terminals in each phase
8. Two numbers treated earth pit for earthing neutral through steel flat
9. Two number earth grid terminals for earthing reactor tank and other metal structure.

19. Components of reactor
Five limbed core construction is adopted to achieve high zero
sequence impedance. In addition to the three gapped core limbs with
windings, there are two continuous outer return limbs. The two unwound
side limbs help in achieving zero sequence impedance approximately
equal to the positive sequence impedance

20. Gapped core construction is preferred for high system voltages over
coreless construction due to the high energy density that can be achieved in
gapped core construction
The core sections between consecutive air gaps are moulded in epoxy
resin to prevent movement between individual laminations. The spacers
forming the air gaps are blocks of ceramics with a high modules of elasticity
and the whole stacking of core modules is cemented together during the
assembly to form a solid column without possibility of rocking , or rubbing
between individual parts.
The core segments are of radial laminated configuration. The radial
laminations prevent fringing flux from entering flat surfaces of core steel which
would result in eddy current overheating and hot spots.

21. Interleaved disc winding has been used for rated voltages 220 KV
and above. This type of winding configuration provides better impulse
voltage
distribution. For lower voltage classes a continuous disc winding or a multi
layer helical winding are used.
M 6M 5M 4
Loss in Watt / Kg
CRGO Steel StripHi-B grade
Thickness 0.3- 0.5 mm , Flux Density 1.6 Tesla Frequency 50 Hz,
Gray colour ,E Carlite insulating laminated core
23
M0H
ZDKH
0.89
1.11
0.74
0.66
0.57
0.97
27
M0H
Grading of core according to loss

22. Vibration in reactor
1. As a result of magnetization of core, a
magnetic attraction force (F=107
xB2
)/8π
N / m2
) approximately equal to
(107
x1.62)/8π N/m2 or 104 Ton / m2 is
produced in the air gap between the core
sections.
2. This force pulsates at double frequency
(2 X 50 Hz = 100 Hz) due to sinusoidal
flux of frequency 50 Hz.
3. Because of this double frequency
pulsating force in the core sections, high
vibration and noise is observed in reactor
during operation.
To reduce the vibration within the limit ( 200 micron) following measures are
taken during construction – 1. Air gap are filled with ceramic materials 2.

23. Earthing of Reactor
Treated earth pit
To earthing gridTo earthing grid LA LA LA
1. Neutral earthing – To provide return path for the fault / unbalance
current, the neutral of the reactor is grounded to two separately
treated earth pit
2. Tank earthing – To avoid heating of tank due to circulation of
eddy current as result of voltage build up on tank due to continuous
passing of fractional portion of main flux through it, the potential of the
tank is made zero by connecting with earth grid.
3. Steel structure earthing – To avoid damaging of steel structure
from lighting strike, entire steel structure is grounded through earth
grid.

24. Cooling of reactor
Approximate heat generation
during operation of reactor
due to core and copper loss =
0.2% x MVAR rating =
120 KW
Core loss due to hysteresis & eddy
current is about 75% of total loss i.e.
0.75X120 = 90 KW
Copper loss due to I2
R loss is
about 25% of total loss i.e.
0.25X120 = 30 KW
The loss of 120 KW is converted to heat
50000 Litre of oil absorb the heat and rise the
top oil temperature to maximum 45 Deg C
8 nos radiator banks reduces oil temperature
to 15 Deg C by ONAN cooling process.

25. Significance of parameters
1. Capacity (S) – As reactor is used as inductive load which only absorb
reactive power, it capacity is given in MVAR .
Rated Voltage 1 PU ( 420 KV) 1.05 PU (441KV)
Rated Capacity 63 MVAR 69.45 MVAR
Current ( MVARx100)/(1.732xKV) 86.6 Amps 90.92 Amps
2. Impedance / Positive sequence Impedance (X1) – It is the per phase
AC resistance of the winding which decides the magnitude of per phase
current. X1 = U / I = {420000/(1.732X86.6)} =2800 Ohms
3. Zero sequence Impedance (X0) – It is the AC resistance of the neutral
path which decides the magnitude of earth fault current through neutral.
The value of X0 depends on the construction of core. For five limbs core,
the value of X0 lays between 90% and 100% of positive sequence
impedance (X1). Therefore X0 = 0.9 . X1 = 0.9 X 2800 =2520 Ohms.
Because of high zero sequence impedance earth fault current is restricted
within 1 PU
4. Winding resistance (R) – It is the per phase DC resistance of the
winding which decides copper loss (I2R). Measured winding resistance
per phase = -2.570 Ohms at 38 Deg C
5. Total loss – It is the total active power consumed by the reactor and
converted in to heat. Total loss (core and copper loss) = 110KW
6. Power Factor – CosΦ = 110 / 63000 =
0.17%
110KW
630000KVAR630000KVA
Φ

26. Operation

27. Position of Bus reactors in ts ii
Stage I Gen
(3 X 210MW)
Stage II Gen
(4 X 210MW)
400KV
Bus
400KV
Extension
Bus
Reactor II
Tie Line to
TS II Expn
ICT
Power Grid
Feeder
Power Grid
Feeder
Tie Line
230KV
Bus Mines Feeder
State Grid Feeder
Tie Line to TS
I
Reactor I
Power Grid
Feeder
TS II Expansion
Gen (2 X 250MW)
400KV
Bus

28. voltage compensation methods in power
system
Switchyard Bus
395 – 415KV
R
E
C
C
A
P
Delivers reactive
power to boost up
voltage
Absorb reactive
power to reduce
bus voltage
Increasing tap
to deliver reactive power for
increasing bus voltage
Decreasing tap
to absorb reactive power for
decreasing terminal voltage
Over excitation
to deliver reactive power
for increasing terminal
voltage
Under excitation
to absorb reactive power for
decreasing terminal voltage
Capacitive loading
Inductive loading
Current
Leading
MVAR
Lagging
MVARCurrent
105% Grid Voltage (445KV)
100% Grid Voltage (420KV)
95% Grid Voltage (380KV)
1. Reduce excitation 2. Reduce GT
tap 3. Switch on reactor 4. Disconnect
lines 5. Reduce Gen load
1. Increasing excitation 2. Increase GT
tap 3. Switch on Capacitor 4. Reduce
gen load

29. Operation of bus reactor
Switching ON : Whenever bus voltage goes to 4% higher
than rated voltage i.e. 400 x104/100 = 416 KV
Switching Off : Whenever bus voltage goes to 2% less than
rated voltage i.e. 400x98/100 = 392 KV
However switching On & Off are to be carried out as per
the direction of SRLDC
 With the switching on of bus Reactor, Station MVAR will
increase depending upon the grid voltage
 Since Reactor is a fixed impedance equipment , when
grid voltage is lower , reactor will absorb lower current
and generate lower MVAR Load.
 Similarly when grid voltage is higher , reactor will absorb
higher current and generate higher MVAR Load.
GRID VOLTAGE REACTOR CURRENT REACTIVE LOAD
400 KV 85 Amps 60 MVAR
420 KV 87 Amps 63 MVAR
441 KV 90 Amps 69 MVAR

30. Observation of
parameters during
switching on reactor
Switchyard parameters Time
Grid
voltage
Station
MVAR
Reactor
current ( As
per Meter)
Reactor
MVAR ( As
per Meter)
Reactor II
(SL No 6007011
Location 17th
Bay)
Before
charging
10:05 Hrs 413 KV 295 MVAR 0 0
After
charging
10:15 Hrs 411KV 335 MVAR 85 Amps 63 MVAR
Reactor I
(SL No 6007012
Location 16th
Bay)
Before
charging
12:10 Hrs 414 KV 254 MVAR 0 0
After
charging
12:17 Hrs 411KV 331 MVAR 87 Amps 63 MVAR
UCB IV Parameters Time
Gen
Terminal
Voltage
MVAR
Bus
Voltage
PF
Reactor II
(SL No 6007011
Location 17th
Bay)
Before
charging
10:15
Hrs
15.9 KV 50 MVAR 410 KV 0.98
After
charging
10:06
Hrs
15.9 KV 55 MVAR 405KV 0.98
Reactor I
(SL No 6007012
Location 16th
Bay)
Before
charging
12:10
Hrs
16 KV 40 MVAR 408 KV 0.99
After
charging
12:17
Hrs
16 KV 60 MVAR 405 KV 0.99
Site Parameters
Running
Hours
OTI WTI
Ambient
Temp
Noise &
Vibration
Label
Reactor II
(SL No 6007011
Location 17th
Bay)
Switched On:
10:13 Hrs
Switched Off:
11:15 Hrs
1Hour 30 Deg C 34 Deg C 28 Deg C Normal
Reactor I
(SL No 6007012
Location 16th
Bay)
Switched On:
12:15 Hrs
Switched Off:
13:10 Hrs
1 Hour 33 Deg C 34 Deg C 33 Deg C Normal

31. Behavior of shunt reactor
during operation

32. Switching on of shunt reactor
Typical inrush current 3 to 5.5 times of rated current.
Due to closing of breaker poles in three phases at different point of
cycle, unsymmetrical current is developed in three phases which
persist for approximately 1 sec
Closing point of BRK for Lowest
inrush current .
Closing point of BRK for Highest
inrush current .
As a result of unsymmetrical current, 3rd
harmonic current passes
through the neutral that may cause spurious tripping on earth fault.
Due to unsymmetrical current, DC off set current is produced
which decrease slowly because of low loss in reactor and may
cause saturation of CT
N R Y B

33. waveform of inrush current with dc off set
current during switching in
DC Off set
current
Wave form of 3rd
harmonic current through
neutral during Switching in

34. Typical problem during switching in
One of the principal difficulties with shunt reactor protection scheme is
false tripping during reactor energizing.
This false tripping typically occurs within some hundreds of millisecond
or even 1 to 2 seconds after closing of circuit breaker. It also happens
randomly and not with every reactor switching attempt
Most of the time, it trips on Restricted Ground Fault protection /
Differential Protection / Ground fault protection during switching in
 It should be noted that HV shunt reactors are typically switched in and
out at least once per day or even more often depending on the power
system loading patterns.
 During switching in of shunt reactor relatively high and long lasting dc
current component appears in one or more phases. This current
waveform moves the operating point of CT magnetic core on the
hysteresis curve in one direction and when the dc component diminish
it leaves the main CT with certain level of residual (i.e. remnant) flux.
 During normal operation reactor current is always around 1pu and
therefore of a relatively low magnitude, which is never big enough to
move the operating point towards the origin.
 Therefore when next switching attempt comes, depending on the
moment of switching, residual flux in the CT core can increase or
decrease. Thus this mechanism will sooner or later cause CT
saturation during reactor switch in operation.
 This CT saturation then causes problems for protective relays, which
lose the correct information about the primary current and therefore
cause false operation of protective relays.
Cause for tripping during switching in

35. Switching off
During switching off operation of reactor high transient over
voltage is developed due to breaking of inductive current.
This switching transients are inversely proportional to the shunt
reactor rated power
Typical over voltage in 400 KV reactors
* ( Sav – Steepness of voltage)
Switching transients overvoltage can be reduced considerably by
installing surge reactor and control switching operation i.e switching
off during zero crossing.
Frequent transients overvoltage due to switching off operation
always have the impact on the dielectric life of reactor and breakers.

36. Electrical faults in
shunt reactors

37. Phase to ground
fault at line side
Faults in shunt reactor
Internal fault External fault
Phase to ground
fault
Phase to ground
fault at neutral side
Phase to phase
short circuit fault
Inter turn short
circuit fault
Over load due to
over voltage and
harmonics

38. Phase to earth fault - out side the reactor
•
•Shunt reactor is a device with the fixed impedance value. Therefore the
individual phase current is directly proportional to the applied phase voltage
(i.e. I=U/Z). During external fault voltage of the faulty phase becomes lower
than other phases and a result of that unbalance is created in the phase
current. Because of unbalance phase current , zero seq. current less than 1
PU passes through the neutral.
N R Y B
Zero seq
current
(<1 PU)
Un balance in
phase current
Unbalance in phase
current due to external
earth fault
Low zero sequence
current through neutral
due to unbalance in the
phase current

39. Phase to earth fault - at the line side
1. Short circuit current flow through the line side
faulty phase and causes unbalance in the phase
current
2. Zero sequence current typically 1 PU flow through
the neutral due to unbalance phase current
N R Y B
Zero seq
current
Un balance in
phase current

40. Phase to earth fault – at the neutral side
Rated current
passes through the
line side phase
High current passes
through neutral side due
to transformer action
N R Y B
Rated current in the
line side

41. Turn to turn short
Shunt reactor winding impedance is approximately proportional
to the square of the number of active turns.
Short circuit between some number of turns will cause the
decrease of the winding impedance only in the faulty phase and
corresponding small raise of the shunt reactor neutral point
current.
Currents during turn-to-turn fault are of the small magnitude and
they will not produce any sufficient unbalance voltage.
Sufficient unbalance voltage is produced only when number of
turn-to-turn short is high. In such condition it is possible to detect
turn to turn fault with the help of sensitive directional zero seq
relay connected on the HV side of the reactor.

42. Summary – protection
CAUSES EFFECTS RESULTS IN PROTECTION ACTUATES
Switching ON Unsymmetrical
inrush current
•Zero sequence 3rd
harmonic current
through the neutral
•Saturation of CT due to
slow decaying of DC
offset current
•Restricted Earth fault
with time delay
•Diff protection
Switching
OFF
Transient over
voltage
High voltage stress on
the dielectric of the
reactor & circuit breaker.
No protection is
recommended for this
purpose.
External
phase to
ground fault
Lower than
rated current
through the
faulty phase
•Unbalance in three
phase line current
•Low zero sequence
current ( 1PU) passes
through the neutral
•Line side residual current
protection
•Differential protection
Internal
phase to
ground fault
at line side
High current at
line side in the
faulty phase
Unbalance in three
phase line current
•Low zero sequence
current 1PU) passes
through the neutral
•Line side residual current
protection
• line side over current
protection
•Differential protection
Internal
phase to
ground fault
at neutral
side
High current at
line neutral
side
•Rated current at line
side phases
•High current at neutral
side
•Neutral side over current
protection
•Differential protection
Internal
Phase to
phase short
circuit
As the chance of this fault is very remote due constructional feature of
the reactor , protection for this fault is not recommended.
Inter turn
fault
Low magnitude
voltage unbalance
Small rise in neutral
side current
No protection is
recommended since the
magnitude of fault is very
low

43. Electrical
Protection& relay
scheme

44. Reactor protection
PURPOSE OF SHUNT REACTOR PROTECTION
The purpose of the protection relaying is to disconnect the reactor and limit damage in
case of internal short circuits, earth faults, inter turn faults and over voltage or over load.
The reactor forms certain impedance for rated frequency, and as it is shunt connected, as
over load may be caused by over voltage or harmonics in voltage and current.
PROTECTION DEVICES INBUILT OR MOUNTED ON REACTOR
a) Oil immersed reactor usually have a gas detector and oil surge detector (Buchholz
alarm & trip devices), which are excellent for detecting internal faults.
b) Temperature monitors for oil & winding provide good over load protection.
c) Pressure relief device is provided to safe guard the reactor from high pressures.
REACTOR DIFFERENTIAL PROTECTION
It is widely used as instantaneous protection for short circuit faults with in the differential
zone. this is treated as main-1 protection for reactor. It can be of high impedance type or
of a sensitive current stabilized type. High impedance differential protection relays require
an equal CT turns ratio on the phase and neutral side. Sensitivity is 5% of nominal reactor
CT current.
BACK-UP PROTECTION
A variety of relays are available
a) Over current & earth fault protection. ( 50, 50N, 51, 51N, 67, 67N – any combination of
these)
b. Under impedance / distance ( z<)(21r).
c. Neutral displacement protection (un>)
RESTRICTED EARTH FAULT PROTECTION
If, for some reason, a sensitive differential protection not chosen, a restricted earth fault
protection can be utilized.
LINE PROTECTION – I, LINE PROTECTION – II

45. CBIP Guidelines on shunt reactor
Protection
Reactor Differential protection
I) Shall be Triple Pole Type.
ii) Have an operating current sensitivity at least 10% of nominal current.
iii) Shall be tuned with system frequency.
iv) Have an operating time not grater than 30 m sec at 5 times of setting.
v) Have a suitable non-linear resistor to limit the peak voltage during in-zone faults in
case of high impedance type.
vi) Shall be high or low impedance Principle type.
Reactor REF Protection.
I) shall be single Pole.
ii) Have an operating current sensitivity at least 10% of nominal current.
iii) Shall be tuned with system frequency.
iv) Have a suitable non-linear resistor to limit the peak voltage during in-zone faults in
case of high impedance type.
v) Shall be high or low impedance Principle type.
vi) Connection of restricted earth fault protection on the neutral side shall be from
residually connected Bushing CTs or from the ground side CT.
Reactor Backup Protection (Impedance type)
I) Shall be Triple pole type.
ii) Shall be single step Polarized ‘MHO’ or Impedance Distance relay suitable for
Measuring Phase to Ground and Phase to Phase to faults.
iii) Shall grounds a Characteristic angle between 60-80 deg.
iv) Shall have adjustable definite time delay with setting range of 0.2 to 2.0 sec.
v) Shall have a suitable range for covering 60% of Reactor impedance.
vi) Typical setting : Reach - 60% of Reactor Impedance, Time setting - 1 sec
OR
Reactor Backup Protection (Definite Time O/L & E/F).
i) Shall be single stage Definite Time 3 Pole, Over Current relay with adjustable
current and Time.
ii) Shall be connected for 2 O/C and 1 E/F connection and shall be non-directional
with reset ratio and low Transient Overreach.
iii) Typical settings of o/c relays are: Current Setting- 1.3 x Rated current , Time
setting - 1 sec

46. Protection of bus reactor for double
bus & transfer bus scheme
51N
21
87U
Bus I
Bus II
Transfer bus
87BB1
R
E
A
C
T
O
R
II
51N
21
87U
87BB1
R
E
A
C
T
O
R
I
87BB287BB2
To Bus Bar
protection
To Bus Bar
protection

47. 1. Differential protection
U1 V1 W1
U2 V2 W2
N
DP
87
1s1
1s2
1s1
1s2
1s1
1s2
1s1
1s2
1s1
1s2
1s1
1s2
CT Specification
1. Ratio: 200/1A
2. Class: PS
3. Knee point voltage: 200V
4. Magnetizing current: 40 mA
5. Secondary resistance: 1 Ohms
Purpose :Internal / external phase to ground fault.
Line side CT 1
Neutral side CT 1

48. Typical Relay connection for Differential protection
Type of relay : High impedance differential relay
Setting : operating current sensitivity at least 10% of nominal current.
operating time not grater than 30 m sec at 5 times of setting.

49. 2. Residual earth fault protection
U1 V1 W1
U2 V2 W2
N
Instantaneous
Residual over
Current Relay (50N)
Or
AC Time residual
Over Current relay
(51N)
1s1
1s2
1s1
1s2
1s1
1s2
CT Specification
1. Ratio: 200/1A
2. Class: PS
3. Knee point voltage: 200V
4. Magnetizing current: 40 mA
5. Secondary resistance: 1
Ohms
Assigned Protection
1. External phase to ground fault.( Unbalance phase current)
2. Internal phase to ground fault at line side .( Unbalance phase current)
3. Circuit breaker pole discrepancy.( Unbalance phase current)
Typical relay setting
•Set low set to 20% with time delay in between0.6s and 1s or even longer.
•Use 2nd harmonic blocking.
•Set high set to 175% with time delay of 0.1s.

50. 4. Back up impedance protection
Assigned Protection
Internal phase to ground fault at line side
Typical relay setting
•Set low set to 130% with time delay in between 0.6s and 1s.
•Set high set to 250% with time delay of 0.1s.
U1 V1 W1
U2 V2 W2
N
21R – 3Ph, REACTOR
BACKUP IMPEDANCE
RELAY OF SUITABLY
SHAPED CHARECRESTICS
EITHER SINGLE / DOUBLE
ZONE TYPE
1s1
1s2
1s1
1s2
1s1
1s2
CT Specification
1. Ratio: 200/1A
2. Class: PS
3. Knee point voltage: 200V
4. Magnetizing current: 40 mA
5. Secondary resistance: 1
Ohms

51. Typical Relay connection for back up impedance
protection

52. 5. Line protection main & backup
U1 V1 W1 Line Side
U2 V2 W2
Neutral Side
N
Bus Bar protection I
& II
1s1
1s2
1s4
1s3
500/1A
1000/1A
2000/1A
1s1
1s2
1s4
1s3
500/1A
1000/1A
2000/1A
1s1
1s2
1s4
1s3
500/1A
1000/1A
2000/1A
Assigned Protection
Bus bar protection

53. Electrical Test on
reactor
Prepared by
M. G. Morshad / Additional Chief Manager ( Elect.)
Transformer Maintenance Division
Thermal Power Station II
Neyveli Lignite Corporation Ltd

54. Electrical test as per IS 5553
Routine Test ( To confirm the operating criteria)
1. Measurement of WR
2. Measurement of IR & PI
3. Measurement of impedance by bridge methods
4. Measurement of loss and current at rated voltage and ambient temperature
5. Isolation test
Dielectric Test ( To confirm the dielectric strength of the insulation)
1. Separate source voltage withstand test at 230 KV for one minute
2. Induced over voltage withstand test with PD indication at 364 KV AC (1.5/√3 PU ) for
30 minutes during which the PD level shall not exceed 500pc
3. Full wave lighting impulse voltage withstand test at 1300 KVp on line terminal
4. Switching impulse voltage withstand test at 1050 KVp on line terminal
Type Test ( To confirm the design criteria)
1. Temperature rise test along with DGA before and after test
2. Full wave lighting impulse voltage withstanding test at 550 KVp on neutral terminal
3. Measurement of zero sequence reactance
4. Measurement of acoustic noise level
5. Magnetizing curve test / knee voltage measurement
6. Measurement of capacitance and tan delta between winding and tank
Special Test ( To confirm design and operating criteria )
1. FRA test
2. DGA test before and after electrical test
3. Jacking test on reactor tank
4. Vacuum test on reactor tank
5. Oil leak test
6. Snap back test on HV bushing

55. Measurement of WR
Purpose - To measure DC resistance per phase of coil for calculating I2R
loss in the coil, which in turns decides the temperature rise. The
measurement also shows whether the winding joints are in order and the
windings are correctly connected.
Measuring methods -
1. Only at the stable value of current (I), corresponding voltage (V) value
is taken for measuring the value of resistance ( R = V/I).
2. Applied current must not be higher than 15% of the rated current
3. % error in measurement increases with increases of applied current
due to increases in I2R loss at higher current.
4. Value to be measured between (R – N) , (Y-N), and (B-N), and all the
measured value must be equal.
N R Y B
Resistance
measuring Kit
Voltage lead
Current lead
R-N
Y-N
B-N
Room Temp ( 37 Deg C) 75 Deg C
2.570 Ω 2.570 Ω
2.570 Ω 2.570 Ω
2.570 Ω 2.570 Ω

56. Measurement of IR
Minimum IR
value
Below 6.6 KV 6.6 - 11KV 22 – 33 KV Above 66 KV
K = 1.00 30 Deg C 200 MΩ 400 MΩ 500 MΩ 600 MΩ
K = 1.65 40 Deg C 121 MΩ 242 MΩ 303 MΩ 363 MΩ
K = 2.60 50 Deg C 77 MΩ 153 MΩ 192 MΩ 230MΩ
K = 4.20 60 Deg C 47 MΩ 95MΩ 119 MΩ 142 MΩ
K = 6.6 70 Deg C 30 MΩ 60 MΩ 75 MΩ 90 MΩ
K = 10.5 80 Deg C 19 MΩ 38 MΩ 47 MΩ 57MΩ
(Polarization Index) PI Value = (15 minutes IR / 60 minutes IR )
Less than 1 Dangerous
Above 1 to 1.1 Poor
Above 1.1 to 1.25 Questionable
Above 1.25 to 2.0 Fair
Above 2 Good
Purpose - To ascertain minimum insulation strength (IR Value) and dryness
level (PI Value) of the winding required to charge the reactor.
N R Y B
5 KV IR measuring
Kit (Megger)
Procedure – Measure IR and PI value between (R+Y+B +N) – (Tank + E)
with 5 KV Megger and confirm the minimum IR and PI value as per the table
given below.
_ +

57. Isolation test
Purpose - To ascertain that the reactor core is insulated from the tank and
core frame.
G
CL Core BoltCore clamp Core Tank
CL – connected to core lamination
CC – Connected to core clamp
G – Connected to tank ( Earth )
CC
Procedure :
1.Disconnect the closing link that connects the two terminals CL-G.
2.Connect the tank with earth
3. Use a Megger and measure IR value between CL and CC + G by applying
3.5 KV for 1 minute
4. The measured IR value shall be minimum 1000 kohms ( 1 M Ohms)
5. There is no general requirement on the insulation level CC-G .

58. Measurement of impedance by bridge methods
Purpose : To measure the per phase impedance ( AC resistance) of the
winding which controls the flow of current through the windings.
Impedance (Z) = √[(Resistance) 2
+ ( Reactance)2
] = 420KV / 86Amps
Reactor
windings
Temp
(0
C)
U =
100/5
C4
(μF)
M3
(mH)
CN
(pF)
Lx (H) =
(M3/U)X(C4/CN)x1000
X (Ω)
=2∏fLx
U 38 20.00 8.98966 1.0032 50.915 8.856355604 2783.43
V 38 20.00 8.96700 1.0032 50.915 8.834031621 2776.41
W 38 20.00 8.96210 1.0032 50.915 8.829204282 2774.89
Where
U = CT Ratio ( 100/5)
M3 = Mutual inductance = 1.0032 mH
CN= standard capacitance = 50.915 pF
C4= measured bridge capacitance in pF
X= calculated impedance of the winding in Ohms

59. Measurement of loss and current at rated voltage and
ambient temperature
Purpose: To measure the loss ( core & copper loss) in reactor at rated
operating condition.
Reactors
windings
Temp
(0
C)
V =
420/√3
KV
R4
( KΩ)
C4
(μF)
ω =
2∏f
Tan delta = 1000/
(C4xR4xω)
X
(Ω)
Loss ( KW) at rated
voltage =
V2 *(Tan
Delta/X*1000)
U 38 242.49 210.15 8.98966 314.29 0.0016842350 2783.43 35.58
V 38 242.49 201.15 8.96700 314.29 0.0017640389 2776.41 37.36
W 38 242.49 332.75 8.96210 314.29 0.0010669585 2774.89 22.61
Phase
Voltage
(KV)
X
( Ohms)
Phase current =
KV*1000/X ( C )
Rated
Amps ( R )
Calculated loss at
rated voltage
(KW)
Calculated loss at rated
current = KW X ( R/C)2
U 242.49 2783.43 87.12 86.60 35.58 35.16
V 242.49 2776.41 87.34 86.60 37.36 36.73
W 242.49 2774.89 87.39 86.60 22.61 22.20
Total loss at 38Deg C at rated current = (35.16+36.73+22.20) KW = 94.09
KW

60. Purpose of dielectric test
Voltage level as per IS 2072
Normally reactors are operated at the rated operating voltage. During its
operation it is exposed to various transient over voltages like power
frequency over voltage (1.5 x BIL, due to system over voltage), Lighting
impulse (due to lighting), switching impulse (due to switching off). To
avoid abrupt failure of insulation due to these transients, insulation is
designed considering all the aspect. Dielectric test confirms the
capability of the insulation to withstand these transient overvoltage which
is subjected to the reactor during its service life.
Operating
voltage
KV rms
Highest system
voltage (BIL)
KV rms
Power frequency
voltage
(KV rms)
Switching
Impulse
(KV Peak )
Lighting
impulse
(KV Peak )
0.415 1.1 3 - -
3.3 3.6 10 - 20/40
6.6 7.2 20 - 40/60
11 12 28 - 60/75
15 17.5 38 - 75/95
24 50 - 95/125
33 36 70 - 145/170
52 95 - 250
66 72.6 140 - 325
123 185/230 - 450/550
145 230/275 - 550/650
170 230/275/325 - 550/650/750
230 245 325/370/395 - 750/850/950
300 395/460 750/850 950/1050
362 460/510 850/950 1050/1175
400 420 570/360 950/1050 1300/1425

61. Separate source voltage withstand test
at 230 KV for one minute
PURPOSE : To verify the operating voltage withstanding capacity of the
minor insulation ( paper ) used in line terminals and windings.
NR Y B
50 Hz, AC
Generator
Method Test voltage from a 50 Hz, sinusoidal source is applied
between (HV +N) and (E + Tank) through a step up
transformer
Maximum test voltage ( 400 KV /1.732) or 230 KV rms
Duration of test 60 sec
Measurement of test
voltage
Direct reading for RMS type voltmeter or (Reading / √2) for
Peak type voltmeter (KV)
Confirmation The test is declared to be successful if the test voltage does
not collapse during the test.
KV

62. Induced over voltage withstand test with PD indication
at 364 KV AC (1.5/√3 PU ) for 30 minutes during which the
PD level shall not exceed 500pc ( Method 2)
PURPOSE : To verify the power frequency voltage withstanding capacity of the minor
insulation (Paper ) used in line terminals & windings and the maximum level of PD observed
during the test.
Method Test voltage from a 160Hz ( to avoid saturation of core), sinusoidal source is applied at
line terminals through a step up transformer keeping neutral terminal and tank
grounded. PD is measured by PDD connected with impedance ( z) & capacitors as
shown in the fig
Maximum test voltage ( 1.5 x 420KV /1.732) or 364 KV rms
Duration of test 30 minutes in steps at various voltages level as shown below
Measurement of test
voltage
Direct reading for RMS type voltmeter or (Reading / √2) for Peak type voltmeter (V)
Confirmation The test is declared to be successful if the test voltage does not collapse during the
test. and the PD level is observed within 500pC
364KV
420KV 364KV
5 Minutes
5 Sec
30 Minutes
N
RYB
50 Hz, AC
Generator
KV
Z
PDD

63. Full wave lighting impulse voltage withstand
test at 1300 KVp on line terminal
PURPOSE : To verify the impulse voltage withstanding capacity of the major
insulation ( pressboard) used between the windings, line terminals caused by lighting
strike.
N R Y B
Impulse
Generator
0.1 Ώ
Recorder
-
+
Method Test voltage from an impulse generator is applied at line terminals keeping neutral
grounded through 0.1 Ώ resister and other terminals directly grounded. The sequence for
applying impulse is - one impulse of a voltage between 50% and 75 % of the full test
voltage, and three subsequent impulses at full voltage
Test voltage 1300 KV peak with Front time
Duration of test T1 = 1,2μs ± 30% and Time to half-value T2 = 50 μs ± 20%
Confirmation The test is successful if the test voltage does not collapse during the test.

64. Switching impulse voltage withstand test at
1050 KVp on line terminal
N R Y B
Impulse
Generator
5
0
0
Ώ
Recorder
-
+
Method Test voltage from an impulse generator is applied at line terminals keeping
neutral grounded through 500 Ώ resister and other terminals directly
grounded. The sequence for applying impulse is - one impulse of a voltage
between 50% and 75 % of the full test voltage, and three subsequent
impulses at full voltage
Test voltage 1050 KV peak
Duration of
test
Front time Tp> 100μs , Time above 90% Td> 200μs and Time to the first
zero passage T0> 500μs ( preferably 1000 μs )
Confirmation The test is successful if the test voltage does not collapse during the test.
PURPOSE : To verify the impulse voltage withstanding capacity of the major
insulation (Pressboard) between the winding ,line terminals caused by switching
operation.

65. Type Test
1. Temperature rise test along with DGA before and
after test
2. Full wave lighting impulse voltage withstanding test at
550 KVp on neutral terminal
3. Measurement of zero sequence reactance
4. Measurement of acoustic noise level
5. Magnetizing curve test / knee voltage measurement
6. Measurement of capacitance and tan delta between
winding and tank

66. Temperature rise test
The purpose of the measurement is to check that the temperature rises of
the oil and the windings do not exceed the limits agreed on or specified
by the standards.
(T1)Hot / top oil temp
Cold winding resistance at (T) 38 deg C R1 2.569 Ohms
Hot winding resistance after switched
off (to be derived from graph)
R2 2.743 Ohms
Ambient temperature after switched off Ta 34.23 Deg C
Calculated winding temp at Time of S/D Tw = {R2/R1 (235+T)R1} – 235 (2.743/2.569) x ( 235+ 38)
– 235 = 56.49 Deg C
Average oil temp at S/D T1 55.30 – ½(55.30 – 4425) =
49.22 Deg c
Winding temp gradient Tg = (Tw – T1 ) 56.49 – 49.22 =
7.27 Deg c
Average oil temp rise Td = (T1 - Ta) 49.22 – 34.23 =
14.99 Deg C
Corrected winding temperature Tc = (Tg + Td) 7.27+ 14.99 =
22.26 Deg C
Winding temperature rise (Tc – Ta)
Temp rise
Time
Steady state temp
T 55..30 / B 44.25
T 35.00 / B 33.00
8 Hours

67. Full wave lighting impulse voltage withstanding
test at 550 KVp on neutral terminal
NR Y B
Impulse
Generator
5
0
0
Ώ
Recorder
-
+
Method Test voltage from an impulse generator is applied at neutral terminals
keeping other terminals grounded through 500 Ώ resister and tank
directly grounded. The sequence for applying impulse is - one impulse of a
voltage between 50% and 75 % of the full test voltage, and three
subsequent impulses at full voltage
Test voltage 550 KV peak
Duration of
test
T1 = 1,2μs ± 30% and Time to half-value T2 = 50 μs ± 20%
Confirmation The test is successful if the test voltage does not collapse during the test.
PURPOSE : To verify the impulse voltage withstanding capacity of the major and
minor insulation (Pressboard and paper) used in neutral terminals and side of the winding
caused by switching operation.

68. Measurement of zero sequence
reactance
N R Y B
50 Hz, AC
Generator
V
A
A
Purpose : To measure the AC resistance (Impedance) of neutral path which
controls the earth fault current (zero sequence current) through neutral during
internal or external earth fault.
Method •Two phase AC supply is applied between (R+Y+B)
and( N) through a step up transformer which is fed
by a generator.
•Applied voltage is increased till 70% of the rated
current flow through the neutral .
Zero seq impedance {(3 x Applied voltage) / Neutral current} x { rated
frequency / test frequency}.
Current through neutral = 62.5 Amps
Applied Voltage = 56.40 KV
Test Frequency = 49.80 Hz
Zero Sequence Impedance = [(3 x 56400)/ 62.5] x [50.0/49.8]
= 2718.07 Ohms

69. Measurement of acoustic noise level
and vibration
1 Meter
2 MeterMicrophone for
picking up noise
The purpose of the sound level measurement is to check that the sound level
of the reactor meets the specification requirements given in relevant standards
.
A sound spectrum analyses is used for measuring sound level. The sound
spectrum indicates the magnitude of sound components as a function of
frequency. The sound pressure level is the measured at various points
around at a distance (D) of 30 cm for ONAN or 2 m for ONAF cooling
system spaced at an interval (X) of 1 meter.
Limit
Sound level
Vibration level Within 200 microns
Within 81db

70. Magnetizing curve test / knee voltage
measurement
Test procedure
• Each phase of the reactor is charged one by one with direct current.
• When the maximum test current reached, supply is switched off and the reactor
winding is short-circuited simultaneously by DC current breaker.
• The decaying current in the circuit is registered by a computer assisted data
acquisition system.
• The saturation curve Flux (Ø) / Flux (Ø) nom. versus I / Inom is then determined
using the formula.
Imax Maximum measured current Calculation
Imin Minimum measured current L(I) = (IxR) / (di/dt)
I nom Nominal AC current / √ 2 Ø nom = I nom x L mean
I mean Calculated inductance from I min to I nom Ø (I ) = ∫( Imin L(I)) +(Imean x L mean)
Ø nom Nominal flux at I nom
R Circuit resistance (RL + Rs+ Rc)
I / I nom
Ø / Ø nom
2
2

71. Measurement of capacitance and tan delta
between winding and tank
Angle δ
Capacitance (pF)
[(I/2 f V π) x Cos δ ]
Tan δ = Sin δ =Cos Φ(PF)
Condition of the
insulation
0.0 Deg (I / 3140) x 1.000 0 Pure capacitor
0.5 Deg (I / 3140) x 0.999 0.002 Very good
0.5 Deg (I / 3140) x 0.999 0.004 Good
0.5 Deg (I / 3140) x 0.999 0.006 Fairly good
0.5 Deg (I / 3140) x 0.999 0.007 Acceptable
0.5 Deg (I / 3140) x 0.999 0.008 Not acceptable
90.0 Deg 0 1.0 Pure resistance
N R Y B 10 KV
Tan
Delta
Kit
Purpose : To ascertain the condition of the solid insulation of the windings.
+
+
+
+
-
-
-
-
I
Ic
I
Ir
Ir
V
δ
Φ
I = total current drawn by the capacitor formed
between winding and tank and the value of
capacitance is [(I/2 f V π) x Cos δ ] (pF)
Ic = Capacitor charging current
Ir = Current flow through the capacitor due to
impurities / disintegration of the insulation between
winding and tank. As this current is in phase with
applied voltage, it is dissipated in heat.
Measured Capacitance = 9887 pF, Tan δ = 0.0031 at temp 39 Deg C

72. Special Test
1. FRA test
2. DGA test before and after electrical test
3. Vacuum test on reactor tank
4. Oil leak test
5. Snap back test on HV bushing

73. FRA test
Purpose- Frequency Response Analysis (FRA) is carried out to
detect displacement (or movement) of the windings. Usually the
first measurement in the factory is used as a fingerprint. Results of
later measurements are compared with the first one in the factory.
The software controlled sine wave generator produces output
voltage of max. 4 Vrms with frequency range of 50 Hz to 1 MHz. It
has 75 Ω output impedance. Input impedance is 75 Ω.
Voltage from the generator is applied to the one transformer
terminal (one winding end) and response voltage is measured on
another terminal (the other winding end).

74. FRA test report
Impedance value Z in kΩ versus frequency is plotted on the diagram with
indication of terminals with applied and response voltage.
Or attenuation A (or damping) in dB (20 log (Uoutput / Uinput ) versus
frequency is plotted on the diagram with indication of terminals with
applied and response voltage.
The reactor is said to be healthy if no deviation is observed
between the results taken in factory and field

75. DGA test
5 gms of silver nitrate
(AgNO3) dissolved
in 100 ml distilled
water
A week solution of ammonia in water is
slowly added to 100 ml of solution 1,
until a white curdled precipitate which
forms first disappears in the mixture.
Chemical analysis of gas : The gas analyser loaded with these solution is
connected to the top pet cock. Small quantities of gas collected in the gas
relay (Bucholtz relay) is allowed to pass through the two solutions.

76. Vacuum test on reactor tank
Oil leak test

77. Snap back test on HV bushing
Purpose : Snap back test was carried out on the above bushing to
determine the natural frequency and damping factor.
Following equipment were used to conduct this test.
1: Piezoelectric accelerometer B & K 4371.
2: PL 202 Real Time FFT Analyzer
Methods : Two nos. Piezoelectric accelerometer were mounted 90 degree
apart at the bottom of the bushing, one in the direction of applied force (X)
and other 90 degree to the applied force (Y). A force of 250 Kg was applied
at the top and then it was cut-off. The resulting vibrations were recorded on
the FFT. The recorded signals were analyzed on FFT Analyzer to determine
the natural frequency and damping factor of the bushing.
X
Y
FFT
X
direction
Y
direction
Natural
frequency
From FFT reading 3.25 3.25
Damping
factor
[(100 / 2 π n) * log (Y 1 / Yn+1)] Where: n = No. of cycle
Y n+1 = Amplitude of (n+1) cycle peak Y1 = Amplitude of
1st cycle peak
1.421% 2.03%
The test is successful if no evidence of physical damage is observed on
the bushing after the test

78. Final
Observations

79. Though oil immersed, shunt reactor and power transformer are
viewed alike, there are distinct differences between construction
and operating characteristics of these two devices.
As NLC is going to install two numbers 63 MVAR bus reactor for
the first time in TS II and the operating and maintenance staffs
are not properly exposed to its operating data, following
information need to be collected from any southern grid thermal
power plant ( not from substation) presently operating with
similar capacity bus reactors for successful and trouble free
operation of reactor in TS II –
Average number of switching operation of the reactor per day
Numbers of operating hours achieved since commissioning
Numbers of forced / planned shutdown taken after
commissioning
Protection co-ordinations and its settings
Number of false/actual tripping, if any, since commissioning and
its reasons
Maximum & minimum bus voltage for switching in and out of
reactors
Reduction in leading MVAR and bus voltage after switching in of
the reactor
Any abnormalities observed in generator excitation during
switching in/out
 Average reactor current, winding and oil temperature
Any failure of parts like bushings, LA, gaskets etc since
commissioning
Remarks of the operating staff on the performance of the
reactors

80. Thank you