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Review of unit protection schemes for auto-transformers
Conference Paper · April 2011
DOI: 10.1109/CPRE.2011.6035628
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Moscow, 7–10 September 2009
191
Application of Unit Protection Schemes
for Auto-Transformers
Z. GAJIC´
ABB AB, SA Products
Sweden
zoran.gajic@se.abb.com
S. HOLST
ABB AB, SA Products
Sweden
stig.holst@se.abb.com
KEYWORDS
Auto-transformer, protective relaying, differential protection.
1. INTRODUCTION
The application of the unit protection schemes for auto-transformers is somewhat special because such
scheme can be arranged in a number of different ways. An auto-transformer is a power transformer in which
at least two windings have a common part [1]. For standard auto-transformer design this common part is the
common winding. Typically auto-transformers are used to interconnect two electrical networks with similar
voltage levels (e.g. system intertie transformer). In practice auto-transformer tertiary delta winding is normally
included. It serves to limit generation of third harmonic voltages caused by magnetizing currents and to lower
the zero sequence impedance for five-limb core constructions or for auto-transformers built from three single
phase units. Standard practice is to size the tertiary delta winding for at least one third of the rated total through
power of the auto-transformer. This is done in order to achieve adequate short-circuit withstand strength of
the delta winding during earth fault in the HV systems.
Unit protection schemes for auto-transformers can be arranged in a number of ways:
– Based on autotransformer ampere-turn balance
– Based on the first Kirchhoff’s law between galvanically interconnected parts
– Based on zero-sequence currents (restricted earth-fault protection)
– Dedicated unit protection schemes for only tertiary delta winding.
Most commonly used auto-transformer unit protection schemes will be described in this document and
advantages and disadvantages of the schemes will be discussed.
One auto-transformer will be used as an example for all presented differential protection schemes in this
document. This auto-transformer has the following rating: 400/400/130 MVA; 400/231/10.5 kV; YNautod5
in accordance with [1]. The phase angle displacement between the tertiary delta winding and the other two
windings is 150°, as shown in Figure 1.
It can be shown that power is transferred in two different ways through an auto-transformer. One part of the
power is transferred by galvanic connection and the other part is transferred via magnetic circuit (i.e. trans-
former action) [1], [4]. This can be represented for the example auto-transformer by the following equation:
S = √3 × U220
×I220
= √3 × U220
× (I400
+ ICW
) = √3 × U220
×I400
+ √3 × U220
×ICW
= SG
+ ST
,
where: S is the auto-transformer total throughput power; U220
is the voltage on the 220 kV side; I220
is the current
on the 220 kV side; I400
is the current on the 400 kV side; ICW
is the current in the common winding; SG
is one
A ctu a l T ren d s in D ev elopmen t of P ower Sy stem P rotection a n d A u toma tion
192
part of the total throughput power transferred by galvanic connection; ST
is the second part of total throughput
power transferred by magnetic circuit (transformer effect).
F ig. 1: R a tin g d a ta fo r A u to - tra n s fo rm e r u s e d a s a n e x a m p le tra n s fo rm e r th ro u g h o u t th is d o c u m e n t
Obviously only one part of the auto-transformer total throughput power (i.e. ST
) is transferred by magnetic
circuit (transformer effect). Thus, the whole auto-transformer active part can be sized accordingly. Conse-
quently auto-transformer can be design with less active material (i.e. copper and steel) in comparison with a
standard two-winding power transformer design for the same rated voltages and rated throughput power. It
can be shown that this rated power of the auto-transformer active part can be calculated for the example auto-
transformer by using the following equation:
Thus, example auto-transformer has rated throughput power of 400 MVA, but its active part is designed
for 16 9 MVA only. Therefore, the advantages of auto-transformers compared with equivalent two-winding
transformers of the same voltage ratio and through power consist basically in their smaller size, lower losses,
greater efficiency, easier transportation and lower cost [4].
SrT
=
Ir_ 220
– Ir_ 400
× Sr
=
Ur_ 400
– Ur_ 220
× Sr
=
400 – 231
× 400 = 16 9 M V A
Ir_ 220
Ur_ 400 400
Moscow, 7–10 September 2009
193
D
E
L
T
A
C
O
M
M
O
N
S
E
R
I
A
L
UHV
UMV
ULV
M
A
G
N
E
T
I
C
C
O
R
E
a
)3-
wi
n
d
i
n
gt
r
a
n
s
f
o
r
me
r b
)Au
t
o
-
t
r
a
n
s
f
o
r
me
r c
)Au
t
o
-
t
r
a
n
s
f
o
r
me
r
It is also interesting to notice the difference in physical winding arrangements between equivalent three-
winding power transformers with vector group Yyd, shown in Figure 2a, and auto-transformers with tertiary
delta winding shown in Figure 2b and Figure 2c.
F ig. 2 : T y p ic a l p h y s ic a l w in d in g a rra n g e m e n ts fo r c o re ty p e , p o w e r tra n s fo rm e rs
Another special thing for auto-transformers is the possible CT locations. In Figure 3 the possible CT loca-
tions are shown. Note that in this document it is assumed that for every differential protection scheme all used
CTs are star (i.e. wye) connected and have their star point towards the protected zone. Such practices follows
the well established principles used by many relay manufactures which are based on traditional practice used
with older types of differential relays [7 ] and [8 ].
For auto-transformer applications, such practice will actually cause that for different differential protec-
tion schemes CTs installed at the same place need to be star differently. For actual examples see CT5 and CT6
installed at the auto-transformer star point or CT8 and CT9 installed inside the tertiary delta winding, as shown
in Figure 3. Note that in further text it is clearly shown which of these CTs need to be used for which type of
the auto-transformer differential protection scheme.
2 . DIF F ERENTIAL PROTECTION
BASED ON AM PERE-TURN BALANCE
L ow impedance, biased, differential protection for power transformers has been used for decades. It is based
on ampere-turn-balance of all windings mounted on the same magnetic core limb. Well-known ampere-turn
balanced equation for a two-winding, single phase transformer can be written in the following way:
N1
× I1
+ N2
× I2
= 0 o r I1
+
N2
× I2
= 0,
N1
A ctu a l T ren d s in D ev elopmen t of P ower Sy stem P rotection a n d A u toma tion
194
Where: N1
is the number of turns in the first winding; I1
is the current in the first winding; N2
is the number of
turns in the second winding; I2
is the current in the second winding.
Note that power transformer magnetizing currents are neglected in this equation. For a particular power
transformer the following properties affect this kind of differential protection:
1. E xact number of turns in every winding is not known. Instead the rated no-load voltages of each winding
are used because they are directly proportional to the number of turns. These voltages are readily available on
power transformer rating plate.
2. Current transformers are used to step down the primary current to the standard 1 A or 5 A secondary level
for the differential protection. Thus if the main CT ratios are not matched on all sides the secondary current
magnitudes can be different on different sides of the power transformer.
L1 L2 L3
L1 L2 L3
L1
L2
L3
400kV
220kV
10.
5kV
IL1_400_CT1
IL2_400_CT1
IL3_400_CT1
IL3_10.
5_CT7
IL2_10.
5_CT7
IL1_10.
5_CT7
IL3_10.
5_CT8
IL2_10.
5_CT8
IL1_10.
5_CT8
IL1_N_CT5
IL2_N_CT5
IL3_N_CT5
IL1_220_CT2
IL2_220_CT2
IL3_220_CT2
IN_CT4
IL1_N_CT6
IL2_N_CT6
IL3_N_CT6
IL1_10.
5_CT3
IL2_10.
5_CT3
IL3_10.
5_CT3
IL1_10.
5_CT9
IL2_10.
5_CT9
IL3_10.
5_CT9
CT1;
800/
1A
CT3;
7000/
5A
CT5;
500/
1A
CT6;
500/
1A
CT7;
4000/
1A
CT8;
4000/
1A
CT9;
4000/
1A
CT4;
1000/
1A
CT2;
1200/
1A
F ig. 3 : P o s s ib le C T lo c a tio n fo r e x a m p le A u to - tra n s fo rm e r
Moscow, 7–10 September 2009
195
3. Different connections of the three-phase windings (e.g. star, delta or zig-zag) introduce a possible phase
angle shift between two power transformer sides.
4. Z ero sequence currents may follow through star or zig-zag connected windings, but such currents are
trapped by delta connected windings making current unbalance on the two power transformer sides.
Consequently, in order to correctly apply transformer differential protection for the three-phase power
transformers the following compensations shall be provided:
– current magnitude compensation of the secondary CT current
– transformer phase angle shift compensation
– zero sequence current compensation (i.e. zero sequence current elimination).
With modern numerical transformer differential relays all above compensations are provided in the relay
software. Typically matrix equations are used to present calculations performed by numerical differential relays
[2], [3] and [5].
Additional application difficulties arise from the fact that power transformer ampere-turn based differential
schemes are affected by tapping of on-load tap-changer. The reason is that such tapping will change number
of turns within one winding and will cause unbalance and false differential current will be seen by the differ-
ential relay. Traditionally the differential schemes were only balanced for the mid-tap position. Some modern
differential protection relays [5] can read actual tap-changer position and on-line compensate for the position
of up to two OL TCs.
2 .1. Base v alues for transformer differential protection
The only common electrical quantity for power transformer windings is electrical power which flows through
them. Therefore for the transformer differential protection the maximum apparent power among all power
transformer windings is typically selected as the base quantity [8 ]. That was the reason why interposing CTs for
the solid-state relays were as well calculated using this maximum power as a base [7 ]. Note that the maximum
value among all windings, as stated on the protected power transformer rating plate, is typically selected. This
can be simply written as following equation:
SB a se
= SM a x
[M V A].
When the base power is known the base primary current on each power transformer side can be calculated
by using the following equation:
where: IB a se P ri_ Wi
is the winding base current in primary amperes in A; SB a se
is the defined base apparent power
for this application in MVA; Ur_ Wi
is the winding rated phase-to-phase, no-load voltage in kV. It is proportional
to the number of turns in the winding. The value for each transformer winding is typically stated on the power
transformer rating plate.
For a star connected main CT the corresponding base current value on the CT secondary side is easily
obtained by using the following equation:
where: IB a se Se c _ Wi_ CT= Y
is the winding base current in secondary amperes for a wye connected main CT; IB a se P ri_ Wi
is the defined winding base current in primary amperes; CTR Wi
is the actual CT ratio used on that power trans-
former side.
IB a se P ri_ Wi
[A] =
1000 × SB a se
[M V A]
,
√3 × Ur_ Wi
[k V ]
IB a se Se c _ Wi_ CT= Y
=
IB a se P ri_ Wi
,
CTR Wi
A ctu a l T ren d s in D ev elopmen t of P ower Sy stem P rotection a n d A u toma tion
196
As explained previously auto-transformer actually has two ratings. One total throughput power (i.e.
400 MVA for the example auto-transformer) and the other for its active part (i.e. 16 9 MVA for the example auto-
transformer). The following two tables summarize possible base quantities for the example auto-transformer.
Winding/Side Base ph-ph no load voltage Base current in primary Amperes
400 kV side 400 kV
220 kV side 231 kV
Delta side (outside delta) 10.5 kV
Delta side (inside delta) √3 × 10,5 = 18 ,18 7 kV
Table 1: B a s e q u a n titie s fo r to ta l ra tin g o f 4 0 0 M V A
Winding/Side Base ph-ph no load voltage Base current in primary Amperes
Serial winding 400 – 231 = 16 9 kV
Common winding 231 kV
Delta winding (inside delta) √3 × 10,5 = 18 ,18 7 kV
* Note that exactly this amount of current will also flow through the serial and the common winding when the auto-
transformer is loaded with rated 400 MVA
Table 2 : B a s e q u a n titie s fo r th e ra tin g o f th e a c tiv e p a rt (i.e . 16 9 M V A )
Obviously, for every auto-transformer differential protection application, correct selection of the base power
is crucial. Additionally, based on the location of the CTs on the tertiary side, it is also necessary to correctly
select rated no-load voltage and vector group for every winding. Correct selection of base power, no-load volt-
age and vector group for different auto-transformer differential protection scheme will be presented in this
document.
3 . AUTO-TRANSF ORM ER DIF F ERENTIAL PROTECTION SCHEM ES
APPLIED AS F OR AN EQ UIV ALENT STANDARD
POWER TRANSF ORM ER
3 .1. Auto-transformer with not Loaded Tertiary Delta Winding
Q uite often the auto-transformer tertiary winding is not loaded and it is used only as a delta-connected
equalizer winding, as defined in [1]. Such auto-transformer can actually be protected as an equivalent two-
400 MVA
= 21 9 9 4 A
√3 × 10,5 kV
400 MVA
= 1000 A
√3 × 231 kV
400 MVA
= 57 7 A
√3 × 400 kV
400 MVA
= 12 6 9 8 A
√3 × 18 ,18 7 kV
16 9 MVA
= 57 7 A*
√3 × 16 9 kV
16 9 MVA
= 422 A*
√3 × 231 kV
16 9 MVA
= 536 5 A
√3 × 18 ,18 7 kV
Moscow, 7–10 September 2009
197
winding Yy0(d) power transformer [1]. For such application differential relay with two restraint inputs is re-
quired.
The relevant application data to set up such differential protection for the example auto-transformer are
given in Table 3. The zero sequence current must be eliminated from the two sides because the zero sequence
current can circulate inside tertiary delta winding, but its magnitude is not available to the differential protec-
tion.
Winding W1 W2
Base P ower [MVA] 400 400
P h-P h, No-L oad Voltage [kV] 400 231
Base P rimary Current [A] 57 7 1000
Vector G roup Y y0
Z ero Sequence Current E limination Yes (Mandatory) Yes (Mandatory)
Connected to CT (See Figure 3) CT1 CT2
Base current on CT secondary side [A] 0.7 21 0.8 33
Table 3 : D iffe re n tia l p ro te c tio n u s in g C T 1 a n d C T 2
For such protection scheme the differential currents in per-unit can be calculated in accordance with the
following matrix equation:
(1)
Ad v a n ta g e s o f th is so lu tio n :
• No CTs required on the tertiary delta side of the protected auto-transformer
D isa d v a n ta g e s o f th is so lu tio n :
• R educed protection sensitivity for turn to turn and internal ground faults due to mandatory zero sequence
current reduction
• L ow sensitivity for internal earth faults located close to the star point of the auto-transformer common
winding
• P ossible lower sensitivity for faults in the tertiary delta winding due to auto-transformer impedance between
windings
3 .2 . Auto-transformer with Loaded Tertiary Delta Winding
Sometimes the auto-transformer tertiary delta winding is loaded. Connected equipment/objects to the
tertiary delta winding vary quite a lot across the world. In some countries it is common to connect either shunt
reactors or shunt capacitors to the tertiary delta winding in order to provide reactive power support to the rest
of the power system. In some other countries tertiary winding can be used to supply station auxiliary services
and/or local communities in the substation surroundings. Finally, generators can be connected to the tertiary
winding and then the auto-transformer is used as a step-up transformer. For such differential protection ap-
plication the auto-transformer is protected as an equivalent three-winding power transformer with vector group
Yyd [1]. Thus the differential relay with three restraint inputs is required. The zero sequence current must be
eliminated from the two high-voltage sides because the zero sequence current can circulate inside the tertiary
2 -
1 -
1 2 -
1 -
1
_ 1 1_ 4
00 _ 1 1_ 220 _ 2
1 1 1 1
_ 2 -
1 2 -
1 -
1 2 -
1
2 _ 4
00 _ 1 2
0.
7
21 3 0.
8
33 3
_ 3 -
1 -
1 2 -
1 -
1 2
3_ 4
00 _ 1
I I
Id L L CT L CT
Id L I I
L CT L
Id L
I
L CT
= ⋅ ⋅ ⋅ + ⋅ ⋅ ⋅
 
 
   
 
 
   
 
 
   
 
 
     
     
 
 
_ 220 _ 2
3_ 220 _ 2
CT
I
L CT
 
 
 
 
 
 
 
A ctu a l T ren d s in D ev elopmen t of P ower Sy stem P rotection a n d A u toma tion
198
delta winding, but its magnitude is not available to the differential protection. The relevant application data to
setup such differential protection for the example auto-transformer are given in Table 4.
Winding W1 W2 W3
Base P ower [MVA] 400 400 400
P h-P h, No-L oad Voltage [kV] 400 231 10.5
Base P rimary Current [A] 57 7 1000 219 9 4
Vector G roup Y y0 d5
Z ero Sequence Current E limination Yes (Mandatory) Yes (Mandatory) No / (Yes)
Connected to CT (See Figure 3) CT1 CT2 CT3
Base current on CT secondary side [A] 0.7 21 0.8 33 15.7 1
Table 4 : D iffe re n tia l p ro te c tio n u s in g C T 1, C T 2 a n d C T 3
For such protection scheme the differential currents in per-unit can be calculated in accordance with the
following matrix equation:
(2)
Ad v a n ta g e s o f th is so lu tio n :
• Most commonly used solution because all needed CTs are readily available in the standard substation
switchgear arrangements.
D isa d v a n ta g e s o f th is so lu tio n :
• R educed protection sensitivity for turn to turn and internal ground faults due to mandatory zero sequence
current reduction
• L ow sensitivity for internal earth faults located close to the star point of the auto-transformer common
winding.
4 . AUTO-TRANSF ORM ER BUILT F ROM THREE SINGLE
PHASE UNITS WHEN ONLY ONE CT SET IS USED INSIDE
THE TERTIARY DELTA WINDING
Sometimes, due to easier transportation and possibility to have a fourth spare transformer or even sometimes
for historical reasons, the auto-transformer is built from three single-phase transformer units. In such applica-
tion the already shown differential protection schemes can also be applied. However, very often for such single
phase auto-transformer design bushing CTs in the common winding star point and inside the tertiary delta
winding are available and can be used for the differential protection.
4 .1. Scheme 1 based on the auto-transformer total throughput power
This differential protection scheme shown is similar with the scheme presented in Table 4. The only differ-
ence is that all three individual currents within the tertiary delta winding are available to the relay. Note that
the tertiary delta winding can be loaded with such arrangement. The relevant application data to set up such
differential protection for the example auto-transformer are given in Table 5.
2 -
1 -
1 2 -
1 -
1
_ 1 1 _ 4
00 _ 1 1 _ 220 _ 2
1 1 1 1
_ 2 -
1 2 -
1 -
1 2 -
1
2 _ 4
00 _ 1 2 _ 220 _ 2
0.
7
21 3 0.
8
33 3
_ 3 -
1 -
1 2 -
1 -
1 2
3 _ 4
00 _ 1
I I
Id L L CT L CT
Id L I I
L CT L CT
Id L
I I
L CT
= ⋅ ⋅ + ⋅ ⋅ ⋅
 
   
   
   
   
   
   
     
 
 
-
1 0 1 1 _ 10.
5_ 3
1 1
1 -
1 0
2 _ 10.
5_ 3
15
.
7
1 3
0 1 -
1
3 _ 220 _ 2 3 _ 10.
5_ 3
I
L CT
I
L CT
I
L CT L CT
+ ⋅ ⋅ ⋅
   
 
   
 
   
 
   
 
   
   
Moscow, 7–10 September 2009
199
1 0 0 1 0 0
_ 1 1 _ 4
00 _ 1 1 _ 220 _ 2
1 1
_ 2 0 1 0 0 1 0
2 _ 4
00 _ 1 2 _ 220 _ 2
0.
7
21 0.
8
33
_ 3 0 0 1 0 0 1
3 _ 4
00 _ 1 3 _ 220 _ 2
I I
Id L L CT L CT
Id L I I
L CT L CT
Id L
I I
L CT L CT
= ⋅ ⋅ + ⋅ ⋅
   
  
   
 
  
   
 
  
   
 
  
     
  
   
1 0 0 1 _ 10.
5_ 7
1
0 1 0
2 _ 10.
5_ 7
3.
17
5
0 0 1
3 _ 10.
5_ 7
I
L CT
I
L CT
I
L CT
+ ⋅ ⋅
 
  
 
  
 
  
 
  
 
  
 
Winding W1 W2 W3
Base P ower [MVA] 400 400 400
P h-P h, No-L oad Voltage [kV] 400 231 √3 × 10,5 = 18 ,18 7 kV*
Base P rimary Current [A] 57 7 1000 126 9 8
Vector G roup Y y0 y0*
Z ero Sequence Current E limination No / (Yes) No / (Yes) No / (Yes)
Connected to CT (See Figure 3) CT1 CT2 CT7
Base current on CT secondary side [A] 0.7 21 0.8 33 3.17 5
* Influenced by CT location within tertiary delta winding
Table 5 : D iffe re n tia l p ro te c tio n u s in g C T 1, C T 2 a n d C T 7
For such protection scheme the differential currents in per-unit can be calculated in accordance with the
following matrix equation:
(3)
Ad v a n ta g e s o f th is so lu tio n :
• Increased sensitivity for turn to turn and internal ground faults because the zero sequence current reduc-
tion is not required
• Somewhat increased sensitivity for internal earth faults located close to the star point of the auto-trans-
former common winding
• Clear indication of the faulty phase because the differential current strictly correspond to windings located
on the same magnetic limb (i.e. all three matrixes are unit matrixes in the above equation)
• Increased sensitivity for internal faults located inside tertiary delta winding.
D isa d v a n ta g e s o f th is so lu tio n :
• Necessity for a CT inside the tertiary delta winding.
4 .2 . Scheme 2 based on the rating of the auto-transformer activ e part
This scheme is quite different from previously presented differential protection schemes. From the CT
location point of view such application is most similar to the standard power transformer differential protec-
tion, because the currents are measured inside each individual winding present in the auto-transformer (see
Figure 2).
Currents are directly measured in all windings which are located around one magnetic core limb. Conse-
quently the zero sequence current shall not be eliminated from any side. The relevant application data to set
up such differential protection for the example auto-transformer are given in Table 6 .
Winding W1 W2 W3
Base P ower [MVA] 16 9 16 9 16 9
P h-P h, No-L oad Voltage [kV] 16 9 231 √3 × 10,5 = 18 ,18 7 kV*
Base P rimary Current [A] 57 7 422 536 5
A ctu a l T ren d s in D ev elopmen t of P ower Sy stem P rotection a n d A u toma tion
2 0 0
1 0 0 1 0 0
_ 1 1 _ 4
00 _ 1 1 _ _ 5
1 1
_ 2 0 1 0 0 1 0
2 _ 4
00 _ 1 2 _ _ 5
0.
7
21 0.
8
4
4
_ 3 0 0 1 0 0 1
3 _ 4
00 _ 1 3 _ _ 5
I I
Id L L CT L N CT
Id L I I
L CT L N CT
Id L
I I
L CT L N CT
= ⋅ ⋅ + ⋅ ⋅ +
   
   
   
 
   
   
 
   
   
 
   
     
   
   
1 0 0 1 _ 10.
5_ 7
1
0 1 0
2 _ 10.
5_ 7
1.
34
1
0 0 1
3 _ 10.
5_ 7
I
L CT
I
L CT
I
L CT
⋅ ⋅
 
 
 
 
 
 
 
 
 
 
 
Winding W1 W2 W3
Vector G roup Y y0 y0*
Z ero Sequence Current E limination No / (Yes) No / (Yes) No / (Yes)
Connected to CT (See Figure 3) CT1 CT5 CT7
Base current on CT secondary side [A] 0.7 21 0.8 44 1.341
* Influenced by CT location within the tertiary delta winding
Table 6 : D iffe re n tia l p ro te c tio n u s in g C T 1, C T 5 a n d C T 7
For such protection scheme the differential currents in per-unit can be calculated in accordance with the
following matrix equation:
(4)
Ad v a n ta g e s o f th is so lu tio n :
• Increased sensitivity because the zero sequence current reduction is not required
• Increased sensitivity for earth faults located close to the star point of the auto-transformer common wind-
ing since the current is measured exactly there
• Clear indication of the faulty phase because the differential current strictly correspond to the windings
located on the same magnetic limb (i.e. all three matrixes are unit matrixes in above equation)
• Increased sensitivity for faults inside the tertiary delta winding.
D isa d v a n ta g e s o f th is so lu tio n :
• L ow sensitivity for internal winding faults located close to the 220 kV side connection point
• All faults on the 220 kV conductor are seen as external faults (e.g. such differential scheme will not operate
for faults in the 220 kV side bushing).
5 . AUTO-TRANSF ORM ER BUILT F ROM THREE SINGLE
PHASE UNITS WHEN TWO CT SETS ARE USED INSIDE
THE DELTA WINDING ( ONE ON EACH SIDE)
When an auto-transformer is made from three single-phase units the CTs on both sides of the tertiary delta
winding are often available. Thus, it is possible to connect two CT sets from inside of the delta winding to the
differential protection scheme. This will increase the sensitivity for internal faults within the tertiary delta
winding [2].
5 .1. Scheme 1 based on the auto-transformer total throughput power
This scheme is very similar to the scheme given in Table 5. The only difference is that two CT inputs are
available from the tertiary delta winding. Thus the differential relay with four restraint inputs is required. The
relevant application data to set up such differential protection for the example auto-transformer are given in
Table 7 .
Moscow, 7–10 September 2009
2 0 1
Winding W1 W2 W3 W3
Base P ower [MVA] 400 400 400 400
P h-P h, No-L oad Voltage [kV] 400 231
Base P rimary Current [A] 57 7 1000 2539 6 2539 6
Vector G roup Y y0 y0 y0
Z ero Sequence Current E limination No / (Yes) No / (Yes) No / (Yes) No / (Yes)
Connected to CT (See Figure 3) CT1 CT2 CT7 CT8
Base current on CT secondary side [A] 0.7 21 0.8 33 6 .349 6 .349
* Influenced by existence of two CTs located within the tertiary delta winding
Table 7 : D iffe re n tia l p ro te c tio n u s in g C T 1, C T 2 , C T 7 a n d C T 8
For such protection scheme the differential currents in per-unit can be calculated in accordance with the
following matrix equation:
(5)
Ad v a n ta g e s o f th is so lu tio n :
• Increased sensitivity because the zero sequence current reduction is not required
• Increased sensitivity for faults inside the tertiary delta winding
• Clear indication of the faulty phase because the differential current strictly correspond to windings located
on the same magnetic limb (i.e. all three matrixes are unit matrixes in the above equation)
D isa d v a n ta g e s o f th is so lu tio n :
• Necessity for two CT sets inside the tertiary delta winding
5 .2 . Scheme 2 based on the rating of the auto-transformer activ e part
This scheme is very similar to the scheme given in Table 6 . The only difference is that two CT inputs are avail-
able from the tertiary delta winding. Thus the differential relay with four restraint inputs is required. The relevant
application data to set up such differential protection for the example auto-transformer are given in Table 8 .
Winding W1 W2 W3 W3
Base P ower [MVA] 16 9 16 9 16 9 16 9
P h-P h, No-L oad Voltage [kV] 400 231
Base P rimary Current [A] 57 7 422 107 30 107 30
Vector G roup Y y0 y0 y0
Z ero Sequence Current E limination No / (Yes) No / (Yes) No / (Yes) No / (Yes)
Connected to CT (See Figure 3) CT1 CT5 CT7 CT8
Base current on CT secondary side [A] 0.7 21 0.8 44 2.6 8 3 2.6 8 3
* Influenced by existence of two CTs located within tertiary delta winding
Table 8 : D iffe re n tia l p ro te c tio n u s in g C T 1, C T 5 , C T 7 a n d C T 8
1 0 0 1 0 0
_ 1 1 _ 4
00 _ 1 1 _ 220 _ 2
1 1
_ 2 0 1 0 0 1 0
2 _ 4
00 _ 1 2 _ 220 _ 2
0.
7
21 0.
8
33
_ 3 0 0 1 0 0 1
3 _ 4
00 _ 1 3 _ 220 _ 2
I I
Id L L CT L CT
Id L I I
L CT L CT
Id L
I I
L CT L CT
= ⋅ ⋅ + ⋅ ⋅
   
   
     
   
     
   
     
     
  
   
1 0 0 1 _ 10.
5_ 7 1 _ 10.
5_ 8
1
0 1 0
2 _ 10.
5_ 7 2 _ 10.
5_ 8
6
.
34
9
0 0 1
3 _ 10.
5_ 7 3 _ 10.
5_ 8
I I
L CT L CT
I I
L CT L CT
I I
L CT L CT
+
+ ⋅ ⋅ +
+
 
   
   
   
 
  
 
√3
10,5
= 9 ,09 3 kV*
2
√3
10,5
= 9 ,09 3 kV*
2
√3
10,5
= 9 ,09 3 kV*
2
√3
10,5
= 9 ,09 3 kV*
2
A ctu a l T ren d s in D ev elopmen t of P ower Sy stem P rotection a n d A u toma tion
2 0 2
1 0 0 1 0 0
_ 1 1 _ 4
00 _ 1 1 _ _ 5
1 1 1
_ 2 0 1 0 0 1 0
2 _ 4
00 _ 1 2 _ _ 5
0.
7
21 0.
8
4
4 2.
6
_ 3 0 0 1 0 0 1
3 _ 4
00 _ 1 3 _ _ 5
I I
Id L L CT L N CT
Id L I I
L CT L N CT
Id L
I I
L CT L N CT
= ⋅ ⋅ + ⋅ ⋅ +
   
   
     
   
     
   
     
     
   
   
1 0 0 1 _ 10.
5_ 7 1 _ 10.
5_ 8
0 1 0
2 _ 10.
5_ 7 2 _ 10.
5_ 8
8
3
0 0 1
3 _ 10.
5_ 7 3 _ 10.
5_ 8
I I
L CT L CT
I I
L CT L CT
I I
L CT L CT
+
⋅ ⋅ +
+
 
   
   
   
   
 
For such protection scheme the differential currents in per-unit can be calculated in accordance with the
following matrix equation:
(6 )
Ad v a n ta g e s o f th is so lu tio n :
• Increased sensitivity because the zero sequence current reduction is not required
• Increased sensitivity for the earth faults located close to the star point of the auto-transformer common
winding since the current is measured exactly there
• Increased sensitivity for faults inside the tertiary delta winding
• Clear indication of the faulty phase because the differential current strictly correspond to windings located
on the same magnetic limb (i.e. all three matrixes are unit matrixes in the above equation).
D isa d v a n ta g e s o f th is so lu tio n :
• L ow sensitivity for internal winding faults located close to the 220 kV side connection point
• All faults on the 220 kV conductor are seen as external fault (e.g. such differential scheme will not operate
for faults in the 220 kV side bushing).
Note that the rated no-load voltage of the tertiary delta winding was intentional reduced by one half in order
to compensate for “ double current measurement” within the delta winding for the two differential protection
schemes presented in this section.
6 . DIF F ERENTIAL PROTECTION BASED
ON THE F IRST KIRCHHOF F ’S LAW
Due to a galvanic connection between the serial and the common winding (see Figure 1) it is possible to
arrange a bus-like differential protection for auto-transformers. This differential protection is based on the First
Kirchhoff’s L aw which says that the sum of all currents flowing into one common node shall be zero. Such
protection arrangement can be achieved by using either low or high impedance differential protection [6 ].
6 .1. Low-impedance, phase segregated bus-lik e differential
protection for auto-transformers
Note that for such scheme the rated current for 220 kV side (i.e. the biggest of the three measured cur-
rents) is typically selected as the base current. Z ero sequence current reduction is not at all required for such
scheme. The relevant application data to set up such low-impedance differential protection for the example
auto-transformer are given in Table 9 .
Winding W1 W2 W3
Base P ower [MVA] 400 400 400
P h-P h, No-L oad Voltage [kV] 231 231 231
Base P rimary Current [A] 1000 1000 1000
Vector G roup Y y0 y0
Z ero Sequence Current E limination No No No
Connected to CT (See Figure 3) CT1 CT2 CT6
Base current on CT secondary side [A] 1.25 0.8 33 2.00
Table 9 : D iffe re n tia l p ro te c tio n u s in g C T 1, C T 2 a n d C T 6
Moscow, 7–10 September 2009
2 0 3
For such protection scheme the differential currents in per-unit can be calculated in accordance with the
following matrix equation:
(7 )
Ad v a n ta g e s of such phase segregated, low or high impedance, bus-like differential protection scheme:
• P rotects common and serial winding against internal short circuits and earth faults
• Increased sensitivity for faults located close to the star point of the auto-transformer common winding
since currents are measured exactly there
• Not affected by auto-transformer inrush currents
• Clear indication of the faulty phase because the differential current strictly corresponds to windings located
on the same magnetic core limb.
D isa d v a n ta g e s of this bus-like phase segregated differential protection scheme:
• The tertiary delta winding is not protected at all with such scheme (i.e. this scheme protects only the serial
and the common windings)
• It will not detect any turn to turn fault inside the serial and the common windings
• P hase segregated CTs are required in the common winding star point
• Dedicated CT cores with equal ratios and magnetizing characteristics shall be used when a high impedance
differential relay is used.
6 .2 . Restricted earth fault protection for auto-transformers
R estricted earth fault (R E F) is a zero-sequence current based differential scheme. It is also based on the
First Kirchhoff’s L aw which is as well valid for zero-sequence currents. It will detect all earth faults within the
common and serial winding of the protected auto-transformer.
The relevant application data to set up such R E F differential protection for the example auto-transformer
are given in Table 10.
Winding W1 W2 N eutral P oint
Base P rimary Current [A] 1000 1000 1000
Connected to CT (See Figure 3) CT1 CT2 CT4
Base current on CT secondary side [A] 1.25 0.8 33 1.00
Table 10 : L o w im p e d a n c e R E F p ro te c tio n u s in g C T 1, C T 2 a n d C T 4
For such low-impedance R E F protection scheme the differential current in per-unit can be calculated in
accordance with the following matrix equation:
(8 )
The R E F protection for an auto-transformer can also be arranged as a high impedance scheme [6 ].
Ad v a n ta g e s of the auto-transformer R E F protection schemes:
1 0 0 1 0 0
_ 1 1 _ 4
00 _ 1 1 _ 220 _ 2
1 1
_ 2 0 1 0 0 1 0
2 _ 4
00 _ 1 2 _ 220 _ 2
1.
25 0.
8
33
_ 3 0 0 1 0 0 1
3 _ 4
00 _ 1 3 _ 220 _ 2
I I
Id L L CT L CT
Id L I I
L CT L CT
Id L
I I
L CT L CT
= ⋅ ⋅ + ⋅ ⋅
   
   
   
 
  
   
 
  
   
 
  
     
  
   
1 0 0 1 _ _ 6
1
0 1 0
2 _ _ 6
2.
0
0 0 1
3 _ _ 6
I
L N CT
I
L N CT
I
L N CT
+ ⋅ ⋅
 
 
 
  
 
  
 
  
 
  
 
[ ] [ ]
1_ 4
00_ 1 1_ 220_ 2
2_ 4
00_ 1 2_ 220_ 2 _ 4
3_ 4
00_ 1 3_ 220_ 2
1 1 1
_ 1 1 1 1 1 1
1.
25 1.
25 1.
0
L CT L CT
L CT L CT N CT
L CT L CT
I I
Id REF I I I
I I
   
   
= ⋅ ⋅ + ⋅ ⋅ + ⋅
   
   
   
A ctu a l T ren d s in D ev elopmen t of P ower Sy stem P rotection a n d A u toma tion
2 0 4
• P rotects the common and the serial winding against internal earth faults
• Increased sensitivity for earth faults located close to the star point of the auto-transformer common wind-
ing since current is measured exactly there
• Not affected by auto-transformer inrush currents
• The protection scheme requires just one single CT in the common auto-transformer star point.
D isa d v a n ta g e s of the auto-transformer R E F protection schemes:
• The tertiary delta winding is not protected at all with such scheme (i.e. this schemes protects only the serial
and the common windings against earth faults)
• It will not detect any turn to turn or short-circuit faults within the serial and the common windings
• Dedicated CT cores with equal ratios and magnetizing characteristic shall be used for high impedance
R E F schemes.
7 . UNIT PROTECTION SCHEM ES
F OR THE TERTIARY DELTA WINDING
As mentioned before, standard auto-transformer differential protection schemes might have limited sensitiv-
ity for short-circuits in the tertiary delta winding. The main reasons are the auto-transformer self impedance
and reduced rating of the tertiary delta winding. In order to improve the sensitivity for tertiary winding faults
dedicated differential schemes are sometimes used.
7 .1. Dedicated differential protection scheme for the tertiary delta winding
When an auto-transformer is consisting of three single-phase units then CTs on both sides of the tertiary
delta winding are often available. In such installations it is possible to arrange dedicated, bus-like differential
protection scheme for every phase of the delta winding.
As this is a scheme based on the First Kirchhoff’s L aw, it is not necessary to deduct the zero sequence current
on any side. Note that the rated current of the tertiary delta winding shall be used as the base current because
this differential scheme is a dedicated protection for that winding only. The relevant application data to set up
such differential protection for the example auto-transformer are given in Table 11.
Winding W3 W3
Base P ower [MVA] 130 130
P h-P h, No-L oad Voltage [kV] √3 × 10,5 = 18 ,18 7 kV* √3 × 10,5 = 18 ,18 7 kV*
Base P rimary Current [A] 4127 4127
Vector G roup Y y0
Z ero Sequence Current E limination No No
Connected to CT (See Figure 3) CT7 CT9
Base current on CT secondary side [A] 1.032 1.032
Table 11: D iffe re n tia l p ro te c tio n u s in g C T 7 a n d C T 9
For such protection scheme the differential currents in per-unit can be calculated in accordance with the
following matrix equation:
(9 )
1 0 0 1 0 0
_ 1 1_10.
5_ 7 1_10.
5_ 9
1 1
_ 2 0 1 0 0 1 0
2 _10.
5_ 7 2 _10.
5_ 9
1.
032 1.
032
_ 3 0 0 1 0 0 1
3_10.
5_ 7 3_10.
5_
I I
Id L L CT L CT
Id L I I
L CT L CT
Id L
I I
L CT L
= ⋅ ⋅ + ⋅ ⋅
 
   
   
   
   
   
   
     
 
     
 
  9
CT
 
 
 
 
 
 
 
Moscow, 7–10 September 2009
2 0 5
Ad v a n ta g e s o f th is so lu tio n :
• Increased sensitivity for faults in the tertiary delta winding because the differential scheme can be sized
in accordance with the rating of the tertiary delta winding and not on the rating of the whole auto-trans-
former
• Clear indication of the faulty phase within the delta winding.
D isa d v a n ta g e s o f th is so lu tio n :
• Two set of CTs are required within the tertiary delta winding
• Such scheme will not detect internal earth faults if the tertiary delta winding or connected power system
is not grounded
• This scheme will not detect any turn to turn faults inside the delta winding.
It is also possible to arrange such differential protection as a high impedance scheme.
7 .2 . Dedicated earth fault protection scheme
for a not-loaded tertiary delta winding
When a tertiary delta winding is not loaded it is possible to solidly ground one corner of the delta winding
as shown in Figure 4. If a CT is positioned in this grounding connection a simple overcurrent relay can be used
to protect the tertiary delta winding against any earth fault. Typical pickup value for such overcurrent relay is
around 150A primary.
Ad v a n ta g e s o f th is so lu tio n :
• Increased sensitivity for earth faults in the tertiary delta winding.
D isa d v a n ta g e s o f th is so lu tio n :
• Not clear indication of the faulty phase inside the delta winding
• R equirement to have access to one of the corners of the delta winding
• This scheme will not detect any short-circuits or turn to turn faults inside the delta winding.
IE
Aut
o-
t
r
ansf
or
mer
Ter
t
i
ar
y,del
t
a-
connect
ed
W i
ndi
ng
F igure 4 : D e d ic a te d e a rth - fa u lt p ro te c tio n s c h e m e fo r a n o t- lo a d e d te rtia ry d e lta w in d in g
A ctu a l T ren d s in D ev elopmen t of P ower Sy stem P rotection a n d A u toma tion
2 0 6
a
)
5
0 100 15
0 200 25
0
5
00
0
5
00
1 10
3
I
L1
I
L2
I
L3
4
00k
V Cu
r
r
e
n
t
W a
v
e
f
o
r
ms
Ti
me[
ms
]
[
P
r
i
ma
r
y
Amp
e
r
e
s
]
b
)
5
0 100 15
0 200 25
0
1.
5 10
3
1 10
3
5
00
0
5
00
1 10
3
I
L1
I
L2
I
L3
220k
V Cu
r
r
e
n
t
W a
v
e
f
o
r
ms
Ti
me[
ms
]
[
P
r
i
ma
r
y
Amp
e
r
e
s
]
8 . F IELD RECORDINGS
The example transformer is an actual auto-transformer where the tertiary delta winding is not loaded. In the
existing installation the following CTs are available: CT1, CT2, CT4 and CT7 in accordance with designations
shown in Figure 3. By using the first Kirchhoff’s law it is also possible to calculate the common winding currents
(i.e. CT5) for any external fault from captured recordings. Due to space limitation only one captured recording
will be presented here. This is an external L 2-G nd fault which before clearing evolved into a L 2-L 3-G nd fault.
In Figure 5 the following traces, either captured or calculated, are shown for this external fault:
a) 400kV side current waveforms (i.e. CT1) in primary amperes (recorded)
b) 220kV side current waveforms (i.e. CT2) in primary amperes (recorded)
c) Common winding side current waveforms (i.e. CT5) in primary amperes (calculated)
d) Waveforms for current inside the tertiary delta winding (i.e. CT7 -note that just one phase is shown
because the delta winding is not loaded) and the neutral point current (i.e. CT4) in primary amperes (both
recorded)
e) Calculated differential current R MS values in percent for the differential protection scheme in accor-
dance with Table 3 and equation (1)
f) Calculated differential current R MS values in percent for the differential protection scheme in accordance
with Table 5 and equation (3)
g) Calculated differential current R MS values in percent for the differential protection scheme in accor-
dance with Table 6 and equation (4)
h) Calculated differential current R MS value in percent for the low-impedance R E F protection scheme in
accordance with Table 10 and equation (8 )
Moscow, 7–10 September 2009
2 0 7
c
)
5
0 100 15
0 200 25
0
4
00
200
0
200
4
00
I
L1
I
L2
I
L3
Co
mmo
nW i
n
d
i
n
gCu
r
r
e
n
t
W a
v
e
f
o
r
ms
Ti
me[
ms
]
[
P
r
i
ma
r
y
Amp
e
r
e
s
]
d
)
5
0 100 15
0 200 25
0
3 10
3
2 10
3
1 10
3
0
1 10
3
2 10
3
I
_i
n
_De
l
t
a
I
N
Ze
r
oS
e
q
u
e
n
c
eCu
r
r
e
n
t
W a
v
e
f
o
r
ms
Ti
me[
ms
]
[
P
r
i
ma
r
y
Amp
e
r
e
s
]
e
)
100 200 300 4
00
0
0.
5
1
1.
5
I
D_L1
I
D_L2
I
D_L3
RMSDi
f
f
e
r
e
n
t
i
a
l
Cu
r
r
e
n
t
s(
CT1 & CT2)
Ti
me[
ms
]
Cu
r
r
e
n
t
[
%]
A ctu a l T ren d s in D ev elopmen t of P ower Sy stem P rotection a n d A u toma tion
2 0 8
f
)
100 200 300 4
00
0
0.
5
1
1.
5
I
D_L1
I
D_L2
I
D_L3
RMSDi
f
f
e
r
e
n
t
i
a
l
Cu
r
r
e
n
t
s(
CT1,
CT2 & CT7
)
Ti
me[
ms
]
Cu
r
r
e
n
t
[
%]
g
)
100 200 300 4
00
0
0.
5
1
1.
5
I
D_L1
I
D_L2
I
D_L3
RMSDi
f
f
e
r
e
n
t
i
a
l
Cu
r
r
e
n
t
s(
CT1,
CT5& CT7
)
Ti
me[
ms
]
Cu
r
r
e
n
t
[
%]
h
)
100 200 300 4
00
0
0.
5
1
1.
5
I
D_REF
REFF
u
n
c
t
i
o
n
Ti
me[
ms
]
Cu
r
r
e
n
t
[
%]
F ig. 5 : E v a lu a tio n o f c a p tu re d d is tu rb a n c e file fro m th e e x a m p le a u to - tra n s fo rm e r in s ta lla tio n
From Figure 5 it can be seen that for all presented differential protection schemes calculated differential
current will be less than 1.5% during the entire external fault. Thus all presented schemes are correctly balanced
and consequently correctly applied for the protection of the example auto-transformer.
Moscow, 7–10 September 2009
2 0 9
9 . CONCLUSION
Different types of auto-transformer differential protection schemes have been presented. Once more note
that the following data are crucial for proper application of the selected differential protection scheme:
• Which base quantities (i.e. power, no load voltage and current) shall be used
• Which vector group shall be entered
• Whether or not zero sequence current elimination shall be enabled.
Once this important data is known instruction for the particular relay make shall be followed to derive relay-
specific settings. Actual implementation for all of these differential protection schemes for a particular relay
model can be found in reference [6 ].
Which particular scheme that will be used is mostly determined by availability of the main CTs in a specific
installation and possibly previous experience of a particular utility. It is recommended that in addition to the
standard differential protection scheme (e.g. as shown in Table 3 or Table 4) additional differential scheme is
applied which is sensitive for faults close to the common winding star point (e.g. as for example shown in Table
6 , Table 8 or Table 10). Other possible solution is to combine two differential schemes which have different
properties (e.g. as for example two schemes shown in Table 5, Table 4 and Table 6 ). Due to size and importance
of auto-transformers in modern power system (e.g. mostly used as system intertie transformers) full duplication
of such protection scheme can also be justified.
REF ERENCES
[1] P ower transformers – International Standard IE C 6 007 6 , E dition 2.1.
[2] IE E E G uide for P rotecting P ower Transformers, IE E E Standard C37 .9 1-2008 .
[3] Z . G ajiс ´, “ Differential P rotection for Arbitrary Three-P hase P ower Transformer” , P hD Thesis, L und
University, Sweden, February 2008 , ISBN: 9 7 8 -9 1-8 8 9 34-47 -5; available at:
http://www.iea.lth.se/publications/pubphd.html
[4] G . Bertagnolli, “ Short-Circuit Duty of P ower Transformers” , Appendix 10, ABB Book, L egano – Italy,
December 19 9 6 .
[5] ABB R E T 6 7 0 Technical reference manual, Document ID: 1MR K 504 08 6 -UE N.
[6 ] ABB Application Note, “ Differential P rotection Schemes for Auto-Transformers” , Document ID:
SA2008 -000519 ; available at: http://www.abb.com/substationautomation
[7 ] ABB R ADSB User’s G uide, Document ID: 1MR K 504 002-UE N.
[8 ] “ Instruction for P lanning Differential P rotection Schemes” , Document ID: CH-E S 53-10 E , BBC J anu-
ary 19 8 0.
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1 mrg000577 en_application_of_unit_protection_schemes_for_auto-transformers1

  • 1. See discussions, stats, and author profiles for this publication at: https://www.researchgate.net/publication/271498844 Review of unit protection schemes for auto-transformers Conference Paper · April 2011 DOI: 10.1109/CPRE.2011.6035628 CITATIONS 5 READS 2,206 2 authors, including: Some of the authors of this publication are also working on these related projects: RET670 View project Transient EF View project Zoran Gajic Hitachi ABB Power Grids Sweden AB; Grid Automation Products 88 PUBLICATIONS   389 CITATIONS    SEE PROFILE All content following this page was uploaded by Zoran Gajic on 23 April 2015. The user has requested enhancement of the downloaded file.
  • 2. Moscow, 7–10 September 2009 191 Application of Unit Protection Schemes for Auto-Transformers Z. GAJIC´ ABB AB, SA Products Sweden zoran.gajic@se.abb.com S. HOLST ABB AB, SA Products Sweden stig.holst@se.abb.com KEYWORDS Auto-transformer, protective relaying, differential protection. 1. INTRODUCTION The application of the unit protection schemes for auto-transformers is somewhat special because such scheme can be arranged in a number of different ways. An auto-transformer is a power transformer in which at least two windings have a common part [1]. For standard auto-transformer design this common part is the common winding. Typically auto-transformers are used to interconnect two electrical networks with similar voltage levels (e.g. system intertie transformer). In practice auto-transformer tertiary delta winding is normally included. It serves to limit generation of third harmonic voltages caused by magnetizing currents and to lower the zero sequence impedance for five-limb core constructions or for auto-transformers built from three single phase units. Standard practice is to size the tertiary delta winding for at least one third of the rated total through power of the auto-transformer. This is done in order to achieve adequate short-circuit withstand strength of the delta winding during earth fault in the HV systems. Unit protection schemes for auto-transformers can be arranged in a number of ways: – Based on autotransformer ampere-turn balance – Based on the first Kirchhoff’s law between galvanically interconnected parts – Based on zero-sequence currents (restricted earth-fault protection) – Dedicated unit protection schemes for only tertiary delta winding. Most commonly used auto-transformer unit protection schemes will be described in this document and advantages and disadvantages of the schemes will be discussed. One auto-transformer will be used as an example for all presented differential protection schemes in this document. This auto-transformer has the following rating: 400/400/130 MVA; 400/231/10.5 kV; YNautod5 in accordance with [1]. The phase angle displacement between the tertiary delta winding and the other two windings is 150°, as shown in Figure 1. It can be shown that power is transferred in two different ways through an auto-transformer. One part of the power is transferred by galvanic connection and the other part is transferred via magnetic circuit (i.e. trans- former action) [1], [4]. This can be represented for the example auto-transformer by the following equation: S = √3 × U220 ×I220 = √3 × U220 × (I400 + ICW ) = √3 × U220 ×I400 + √3 × U220 ×ICW = SG + ST , where: S is the auto-transformer total throughput power; U220 is the voltage on the 220 kV side; I220 is the current on the 220 kV side; I400 is the current on the 400 kV side; ICW is the current in the common winding; SG is one
  • 3. A ctu a l T ren d s in D ev elopmen t of P ower Sy stem P rotection a n d A u toma tion 192 part of the total throughput power transferred by galvanic connection; ST is the second part of total throughput power transferred by magnetic circuit (transformer effect). F ig. 1: R a tin g d a ta fo r A u to - tra n s fo rm e r u s e d a s a n e x a m p le tra n s fo rm e r th ro u g h o u t th is d o c u m e n t Obviously only one part of the auto-transformer total throughput power (i.e. ST ) is transferred by magnetic circuit (transformer effect). Thus, the whole auto-transformer active part can be sized accordingly. Conse- quently auto-transformer can be design with less active material (i.e. copper and steel) in comparison with a standard two-winding power transformer design for the same rated voltages and rated throughput power. It can be shown that this rated power of the auto-transformer active part can be calculated for the example auto- transformer by using the following equation: Thus, example auto-transformer has rated throughput power of 400 MVA, but its active part is designed for 16 9 MVA only. Therefore, the advantages of auto-transformers compared with equivalent two-winding transformers of the same voltage ratio and through power consist basically in their smaller size, lower losses, greater efficiency, easier transportation and lower cost [4]. SrT = Ir_ 220 – Ir_ 400 × Sr = Ur_ 400 – Ur_ 220 × Sr = 400 – 231 × 400 = 16 9 M V A Ir_ 220 Ur_ 400 400
  • 4. Moscow, 7–10 September 2009 193 D E L T A C O M M O N S E R I A L UHV UMV ULV M A G N E T I C C O R E a )3- wi n d i n gt r a n s f o r me r b )Au t o - t r a n s f o r me r c )Au t o - t r a n s f o r me r It is also interesting to notice the difference in physical winding arrangements between equivalent three- winding power transformers with vector group Yyd, shown in Figure 2a, and auto-transformers with tertiary delta winding shown in Figure 2b and Figure 2c. F ig. 2 : T y p ic a l p h y s ic a l w in d in g a rra n g e m e n ts fo r c o re ty p e , p o w e r tra n s fo rm e rs Another special thing for auto-transformers is the possible CT locations. In Figure 3 the possible CT loca- tions are shown. Note that in this document it is assumed that for every differential protection scheme all used CTs are star (i.e. wye) connected and have their star point towards the protected zone. Such practices follows the well established principles used by many relay manufactures which are based on traditional practice used with older types of differential relays [7 ] and [8 ]. For auto-transformer applications, such practice will actually cause that for different differential protec- tion schemes CTs installed at the same place need to be star differently. For actual examples see CT5 and CT6 installed at the auto-transformer star point or CT8 and CT9 installed inside the tertiary delta winding, as shown in Figure 3. Note that in further text it is clearly shown which of these CTs need to be used for which type of the auto-transformer differential protection scheme. 2 . DIF F ERENTIAL PROTECTION BASED ON AM PERE-TURN BALANCE L ow impedance, biased, differential protection for power transformers has been used for decades. It is based on ampere-turn-balance of all windings mounted on the same magnetic core limb. Well-known ampere-turn balanced equation for a two-winding, single phase transformer can be written in the following way: N1 × I1 + N2 × I2 = 0 o r I1 + N2 × I2 = 0, N1
  • 5. A ctu a l T ren d s in D ev elopmen t of P ower Sy stem P rotection a n d A u toma tion 194 Where: N1 is the number of turns in the first winding; I1 is the current in the first winding; N2 is the number of turns in the second winding; I2 is the current in the second winding. Note that power transformer magnetizing currents are neglected in this equation. For a particular power transformer the following properties affect this kind of differential protection: 1. E xact number of turns in every winding is not known. Instead the rated no-load voltages of each winding are used because they are directly proportional to the number of turns. These voltages are readily available on power transformer rating plate. 2. Current transformers are used to step down the primary current to the standard 1 A or 5 A secondary level for the differential protection. Thus if the main CT ratios are not matched on all sides the secondary current magnitudes can be different on different sides of the power transformer. L1 L2 L3 L1 L2 L3 L1 L2 L3 400kV 220kV 10. 5kV IL1_400_CT1 IL2_400_CT1 IL3_400_CT1 IL3_10. 5_CT7 IL2_10. 5_CT7 IL1_10. 5_CT7 IL3_10. 5_CT8 IL2_10. 5_CT8 IL1_10. 5_CT8 IL1_N_CT5 IL2_N_CT5 IL3_N_CT5 IL1_220_CT2 IL2_220_CT2 IL3_220_CT2 IN_CT4 IL1_N_CT6 IL2_N_CT6 IL3_N_CT6 IL1_10. 5_CT3 IL2_10. 5_CT3 IL3_10. 5_CT3 IL1_10. 5_CT9 IL2_10. 5_CT9 IL3_10. 5_CT9 CT1; 800/ 1A CT3; 7000/ 5A CT5; 500/ 1A CT6; 500/ 1A CT7; 4000/ 1A CT8; 4000/ 1A CT9; 4000/ 1A CT4; 1000/ 1A CT2; 1200/ 1A F ig. 3 : P o s s ib le C T lo c a tio n fo r e x a m p le A u to - tra n s fo rm e r
  • 6. Moscow, 7–10 September 2009 195 3. Different connections of the three-phase windings (e.g. star, delta or zig-zag) introduce a possible phase angle shift between two power transformer sides. 4. Z ero sequence currents may follow through star or zig-zag connected windings, but such currents are trapped by delta connected windings making current unbalance on the two power transformer sides. Consequently, in order to correctly apply transformer differential protection for the three-phase power transformers the following compensations shall be provided: – current magnitude compensation of the secondary CT current – transformer phase angle shift compensation – zero sequence current compensation (i.e. zero sequence current elimination). With modern numerical transformer differential relays all above compensations are provided in the relay software. Typically matrix equations are used to present calculations performed by numerical differential relays [2], [3] and [5]. Additional application difficulties arise from the fact that power transformer ampere-turn based differential schemes are affected by tapping of on-load tap-changer. The reason is that such tapping will change number of turns within one winding and will cause unbalance and false differential current will be seen by the differ- ential relay. Traditionally the differential schemes were only balanced for the mid-tap position. Some modern differential protection relays [5] can read actual tap-changer position and on-line compensate for the position of up to two OL TCs. 2 .1. Base v alues for transformer differential protection The only common electrical quantity for power transformer windings is electrical power which flows through them. Therefore for the transformer differential protection the maximum apparent power among all power transformer windings is typically selected as the base quantity [8 ]. That was the reason why interposing CTs for the solid-state relays were as well calculated using this maximum power as a base [7 ]. Note that the maximum value among all windings, as stated on the protected power transformer rating plate, is typically selected. This can be simply written as following equation: SB a se = SM a x [M V A]. When the base power is known the base primary current on each power transformer side can be calculated by using the following equation: where: IB a se P ri_ Wi is the winding base current in primary amperes in A; SB a se is the defined base apparent power for this application in MVA; Ur_ Wi is the winding rated phase-to-phase, no-load voltage in kV. It is proportional to the number of turns in the winding. The value for each transformer winding is typically stated on the power transformer rating plate. For a star connected main CT the corresponding base current value on the CT secondary side is easily obtained by using the following equation: where: IB a se Se c _ Wi_ CT= Y is the winding base current in secondary amperes for a wye connected main CT; IB a se P ri_ Wi is the defined winding base current in primary amperes; CTR Wi is the actual CT ratio used on that power trans- former side. IB a se P ri_ Wi [A] = 1000 × SB a se [M V A] , √3 × Ur_ Wi [k V ] IB a se Se c _ Wi_ CT= Y = IB a se P ri_ Wi , CTR Wi
  • 7. A ctu a l T ren d s in D ev elopmen t of P ower Sy stem P rotection a n d A u toma tion 196 As explained previously auto-transformer actually has two ratings. One total throughput power (i.e. 400 MVA for the example auto-transformer) and the other for its active part (i.e. 16 9 MVA for the example auto- transformer). The following two tables summarize possible base quantities for the example auto-transformer. Winding/Side Base ph-ph no load voltage Base current in primary Amperes 400 kV side 400 kV 220 kV side 231 kV Delta side (outside delta) 10.5 kV Delta side (inside delta) √3 × 10,5 = 18 ,18 7 kV Table 1: B a s e q u a n titie s fo r to ta l ra tin g o f 4 0 0 M V A Winding/Side Base ph-ph no load voltage Base current in primary Amperes Serial winding 400 – 231 = 16 9 kV Common winding 231 kV Delta winding (inside delta) √3 × 10,5 = 18 ,18 7 kV * Note that exactly this amount of current will also flow through the serial and the common winding when the auto- transformer is loaded with rated 400 MVA Table 2 : B a s e q u a n titie s fo r th e ra tin g o f th e a c tiv e p a rt (i.e . 16 9 M V A ) Obviously, for every auto-transformer differential protection application, correct selection of the base power is crucial. Additionally, based on the location of the CTs on the tertiary side, it is also necessary to correctly select rated no-load voltage and vector group for every winding. Correct selection of base power, no-load volt- age and vector group for different auto-transformer differential protection scheme will be presented in this document. 3 . AUTO-TRANSF ORM ER DIF F ERENTIAL PROTECTION SCHEM ES APPLIED AS F OR AN EQ UIV ALENT STANDARD POWER TRANSF ORM ER 3 .1. Auto-transformer with not Loaded Tertiary Delta Winding Q uite often the auto-transformer tertiary winding is not loaded and it is used only as a delta-connected equalizer winding, as defined in [1]. Such auto-transformer can actually be protected as an equivalent two- 400 MVA = 21 9 9 4 A √3 × 10,5 kV 400 MVA = 1000 A √3 × 231 kV 400 MVA = 57 7 A √3 × 400 kV 400 MVA = 12 6 9 8 A √3 × 18 ,18 7 kV 16 9 MVA = 57 7 A* √3 × 16 9 kV 16 9 MVA = 422 A* √3 × 231 kV 16 9 MVA = 536 5 A √3 × 18 ,18 7 kV
  • 8. Moscow, 7–10 September 2009 197 winding Yy0(d) power transformer [1]. For such application differential relay with two restraint inputs is re- quired. The relevant application data to set up such differential protection for the example auto-transformer are given in Table 3. The zero sequence current must be eliminated from the two sides because the zero sequence current can circulate inside tertiary delta winding, but its magnitude is not available to the differential protec- tion. Winding W1 W2 Base P ower [MVA] 400 400 P h-P h, No-L oad Voltage [kV] 400 231 Base P rimary Current [A] 57 7 1000 Vector G roup Y y0 Z ero Sequence Current E limination Yes (Mandatory) Yes (Mandatory) Connected to CT (See Figure 3) CT1 CT2 Base current on CT secondary side [A] 0.7 21 0.8 33 Table 3 : D iffe re n tia l p ro te c tio n u s in g C T 1 a n d C T 2 For such protection scheme the differential currents in per-unit can be calculated in accordance with the following matrix equation: (1) Ad v a n ta g e s o f th is so lu tio n : • No CTs required on the tertiary delta side of the protected auto-transformer D isa d v a n ta g e s o f th is so lu tio n : • R educed protection sensitivity for turn to turn and internal ground faults due to mandatory zero sequence current reduction • L ow sensitivity for internal earth faults located close to the star point of the auto-transformer common winding • P ossible lower sensitivity for faults in the tertiary delta winding due to auto-transformer impedance between windings 3 .2 . Auto-transformer with Loaded Tertiary Delta Winding Sometimes the auto-transformer tertiary delta winding is loaded. Connected equipment/objects to the tertiary delta winding vary quite a lot across the world. In some countries it is common to connect either shunt reactors or shunt capacitors to the tertiary delta winding in order to provide reactive power support to the rest of the power system. In some other countries tertiary winding can be used to supply station auxiliary services and/or local communities in the substation surroundings. Finally, generators can be connected to the tertiary winding and then the auto-transformer is used as a step-up transformer. For such differential protection ap- plication the auto-transformer is protected as an equivalent three-winding power transformer with vector group Yyd [1]. Thus the differential relay with three restraint inputs is required. The zero sequence current must be eliminated from the two high-voltage sides because the zero sequence current can circulate inside the tertiary 2 - 1 - 1 2 - 1 - 1 _ 1 1_ 4 00 _ 1 1_ 220 _ 2 1 1 1 1 _ 2 - 1 2 - 1 - 1 2 - 1 2 _ 4 00 _ 1 2 0. 7 21 3 0. 8 33 3 _ 3 - 1 - 1 2 - 1 - 1 2 3_ 4 00 _ 1 I I Id L L CT L CT Id L I I L CT L Id L I L CT = ⋅ ⋅ ⋅ + ⋅ ⋅ ⋅                                             _ 220 _ 2 3_ 220 _ 2 CT I L CT              
  • 9. A ctu a l T ren d s in D ev elopmen t of P ower Sy stem P rotection a n d A u toma tion 198 delta winding, but its magnitude is not available to the differential protection. The relevant application data to setup such differential protection for the example auto-transformer are given in Table 4. Winding W1 W2 W3 Base P ower [MVA] 400 400 400 P h-P h, No-L oad Voltage [kV] 400 231 10.5 Base P rimary Current [A] 57 7 1000 219 9 4 Vector G roup Y y0 d5 Z ero Sequence Current E limination Yes (Mandatory) Yes (Mandatory) No / (Yes) Connected to CT (See Figure 3) CT1 CT2 CT3 Base current on CT secondary side [A] 0.7 21 0.8 33 15.7 1 Table 4 : D iffe re n tia l p ro te c tio n u s in g C T 1, C T 2 a n d C T 3 For such protection scheme the differential currents in per-unit can be calculated in accordance with the following matrix equation: (2) Ad v a n ta g e s o f th is so lu tio n : • Most commonly used solution because all needed CTs are readily available in the standard substation switchgear arrangements. D isa d v a n ta g e s o f th is so lu tio n : • R educed protection sensitivity for turn to turn and internal ground faults due to mandatory zero sequence current reduction • L ow sensitivity for internal earth faults located close to the star point of the auto-transformer common winding. 4 . AUTO-TRANSF ORM ER BUILT F ROM THREE SINGLE PHASE UNITS WHEN ONLY ONE CT SET IS USED INSIDE THE TERTIARY DELTA WINDING Sometimes, due to easier transportation and possibility to have a fourth spare transformer or even sometimes for historical reasons, the auto-transformer is built from three single-phase transformer units. In such applica- tion the already shown differential protection schemes can also be applied. However, very often for such single phase auto-transformer design bushing CTs in the common winding star point and inside the tertiary delta winding are available and can be used for the differential protection. 4 .1. Scheme 1 based on the auto-transformer total throughput power This differential protection scheme shown is similar with the scheme presented in Table 4. The only differ- ence is that all three individual currents within the tertiary delta winding are available to the relay. Note that the tertiary delta winding can be loaded with such arrangement. The relevant application data to set up such differential protection for the example auto-transformer are given in Table 5. 2 - 1 - 1 2 - 1 - 1 _ 1 1 _ 4 00 _ 1 1 _ 220 _ 2 1 1 1 1 _ 2 - 1 2 - 1 - 1 2 - 1 2 _ 4 00 _ 1 2 _ 220 _ 2 0. 7 21 3 0. 8 33 3 _ 3 - 1 - 1 2 - 1 - 1 2 3 _ 4 00 _ 1 I I Id L L CT L CT Id L I I L CT L CT Id L I I L CT = ⋅ ⋅ + ⋅ ⋅ ⋅                                     - 1 0 1 1 _ 10. 5_ 3 1 1 1 - 1 0 2 _ 10. 5_ 3 15 . 7 1 3 0 1 - 1 3 _ 220 _ 2 3 _ 10. 5_ 3 I L CT I L CT I L CT L CT + ⋅ ⋅ ⋅                                
  • 10. Moscow, 7–10 September 2009 199 1 0 0 1 0 0 _ 1 1 _ 4 00 _ 1 1 _ 220 _ 2 1 1 _ 2 0 1 0 0 1 0 2 _ 4 00 _ 1 2 _ 220 _ 2 0. 7 21 0. 8 33 _ 3 0 0 1 0 0 1 3 _ 4 00 _ 1 3 _ 220 _ 2 I I Id L L CT L CT Id L I I L CT L CT Id L I I L CT L CT = ⋅ ⋅ + ⋅ ⋅                                                1 0 0 1 _ 10. 5_ 7 1 0 1 0 2 _ 10. 5_ 7 3. 17 5 0 0 1 3 _ 10. 5_ 7 I L CT I L CT I L CT + ⋅ ⋅                            Winding W1 W2 W3 Base P ower [MVA] 400 400 400 P h-P h, No-L oad Voltage [kV] 400 231 √3 × 10,5 = 18 ,18 7 kV* Base P rimary Current [A] 57 7 1000 126 9 8 Vector G roup Y y0 y0* Z ero Sequence Current E limination No / (Yes) No / (Yes) No / (Yes) Connected to CT (See Figure 3) CT1 CT2 CT7 Base current on CT secondary side [A] 0.7 21 0.8 33 3.17 5 * Influenced by CT location within tertiary delta winding Table 5 : D iffe re n tia l p ro te c tio n u s in g C T 1, C T 2 a n d C T 7 For such protection scheme the differential currents in per-unit can be calculated in accordance with the following matrix equation: (3) Ad v a n ta g e s o f th is so lu tio n : • Increased sensitivity for turn to turn and internal ground faults because the zero sequence current reduc- tion is not required • Somewhat increased sensitivity for internal earth faults located close to the star point of the auto-trans- former common winding • Clear indication of the faulty phase because the differential current strictly correspond to windings located on the same magnetic limb (i.e. all three matrixes are unit matrixes in the above equation) • Increased sensitivity for internal faults located inside tertiary delta winding. D isa d v a n ta g e s o f th is so lu tio n : • Necessity for a CT inside the tertiary delta winding. 4 .2 . Scheme 2 based on the rating of the auto-transformer activ e part This scheme is quite different from previously presented differential protection schemes. From the CT location point of view such application is most similar to the standard power transformer differential protec- tion, because the currents are measured inside each individual winding present in the auto-transformer (see Figure 2). Currents are directly measured in all windings which are located around one magnetic core limb. Conse- quently the zero sequence current shall not be eliminated from any side. The relevant application data to set up such differential protection for the example auto-transformer are given in Table 6 . Winding W1 W2 W3 Base P ower [MVA] 16 9 16 9 16 9 P h-P h, No-L oad Voltage [kV] 16 9 231 √3 × 10,5 = 18 ,18 7 kV* Base P rimary Current [A] 57 7 422 536 5
  • 11. A ctu a l T ren d s in D ev elopmen t of P ower Sy stem P rotection a n d A u toma tion 2 0 0 1 0 0 1 0 0 _ 1 1 _ 4 00 _ 1 1 _ _ 5 1 1 _ 2 0 1 0 0 1 0 2 _ 4 00 _ 1 2 _ _ 5 0. 7 21 0. 8 4 4 _ 3 0 0 1 0 0 1 3 _ 4 00 _ 1 3 _ _ 5 I I Id L L CT L N CT Id L I I L CT L N CT Id L I I L CT L N CT = ⋅ ⋅ + ⋅ ⋅ +                                                     1 0 0 1 _ 10. 5_ 7 1 0 1 0 2 _ 10. 5_ 7 1. 34 1 0 0 1 3 _ 10. 5_ 7 I L CT I L CT I L CT ⋅ ⋅                       Winding W1 W2 W3 Vector G roup Y y0 y0* Z ero Sequence Current E limination No / (Yes) No / (Yes) No / (Yes) Connected to CT (See Figure 3) CT1 CT5 CT7 Base current on CT secondary side [A] 0.7 21 0.8 44 1.341 * Influenced by CT location within the tertiary delta winding Table 6 : D iffe re n tia l p ro te c tio n u s in g C T 1, C T 5 a n d C T 7 For such protection scheme the differential currents in per-unit can be calculated in accordance with the following matrix equation: (4) Ad v a n ta g e s o f th is so lu tio n : • Increased sensitivity because the zero sequence current reduction is not required • Increased sensitivity for earth faults located close to the star point of the auto-transformer common wind- ing since the current is measured exactly there • Clear indication of the faulty phase because the differential current strictly correspond to the windings located on the same magnetic limb (i.e. all three matrixes are unit matrixes in above equation) • Increased sensitivity for faults inside the tertiary delta winding. D isa d v a n ta g e s o f th is so lu tio n : • L ow sensitivity for internal winding faults located close to the 220 kV side connection point • All faults on the 220 kV conductor are seen as external faults (e.g. such differential scheme will not operate for faults in the 220 kV side bushing). 5 . AUTO-TRANSF ORM ER BUILT F ROM THREE SINGLE PHASE UNITS WHEN TWO CT SETS ARE USED INSIDE THE DELTA WINDING ( ONE ON EACH SIDE) When an auto-transformer is made from three single-phase units the CTs on both sides of the tertiary delta winding are often available. Thus, it is possible to connect two CT sets from inside of the delta winding to the differential protection scheme. This will increase the sensitivity for internal faults within the tertiary delta winding [2]. 5 .1. Scheme 1 based on the auto-transformer total throughput power This scheme is very similar to the scheme given in Table 5. The only difference is that two CT inputs are available from the tertiary delta winding. Thus the differential relay with four restraint inputs is required. The relevant application data to set up such differential protection for the example auto-transformer are given in Table 7 .
  • 12. Moscow, 7–10 September 2009 2 0 1 Winding W1 W2 W3 W3 Base P ower [MVA] 400 400 400 400 P h-P h, No-L oad Voltage [kV] 400 231 Base P rimary Current [A] 57 7 1000 2539 6 2539 6 Vector G roup Y y0 y0 y0 Z ero Sequence Current E limination No / (Yes) No / (Yes) No / (Yes) No / (Yes) Connected to CT (See Figure 3) CT1 CT2 CT7 CT8 Base current on CT secondary side [A] 0.7 21 0.8 33 6 .349 6 .349 * Influenced by existence of two CTs located within the tertiary delta winding Table 7 : D iffe re n tia l p ro te c tio n u s in g C T 1, C T 2 , C T 7 a n d C T 8 For such protection scheme the differential currents in per-unit can be calculated in accordance with the following matrix equation: (5) Ad v a n ta g e s o f th is so lu tio n : • Increased sensitivity because the zero sequence current reduction is not required • Increased sensitivity for faults inside the tertiary delta winding • Clear indication of the faulty phase because the differential current strictly correspond to windings located on the same magnetic limb (i.e. all three matrixes are unit matrixes in the above equation) D isa d v a n ta g e s o f th is so lu tio n : • Necessity for two CT sets inside the tertiary delta winding 5 .2 . Scheme 2 based on the rating of the auto-transformer activ e part This scheme is very similar to the scheme given in Table 6 . The only difference is that two CT inputs are avail- able from the tertiary delta winding. Thus the differential relay with four restraint inputs is required. The relevant application data to set up such differential protection for the example auto-transformer are given in Table 8 . Winding W1 W2 W3 W3 Base P ower [MVA] 16 9 16 9 16 9 16 9 P h-P h, No-L oad Voltage [kV] 400 231 Base P rimary Current [A] 57 7 422 107 30 107 30 Vector G roup Y y0 y0 y0 Z ero Sequence Current E limination No / (Yes) No / (Yes) No / (Yes) No / (Yes) Connected to CT (See Figure 3) CT1 CT5 CT7 CT8 Base current on CT secondary side [A] 0.7 21 0.8 44 2.6 8 3 2.6 8 3 * Influenced by existence of two CTs located within tertiary delta winding Table 8 : D iffe re n tia l p ro te c tio n u s in g C T 1, C T 5 , C T 7 a n d C T 8 1 0 0 1 0 0 _ 1 1 _ 4 00 _ 1 1 _ 220 _ 2 1 1 _ 2 0 1 0 0 1 0 2 _ 4 00 _ 1 2 _ 220 _ 2 0. 7 21 0. 8 33 _ 3 0 0 1 0 0 1 3 _ 4 00 _ 1 3 _ 220 _ 2 I I Id L L CT L CT Id L I I L CT L CT Id L I I L CT L CT = ⋅ ⋅ + ⋅ ⋅                                                1 0 0 1 _ 10. 5_ 7 1 _ 10. 5_ 8 1 0 1 0 2 _ 10. 5_ 7 2 _ 10. 5_ 8 6 . 34 9 0 0 1 3 _ 10. 5_ 7 3 _ 10. 5_ 8 I I L CT L CT I I L CT L CT I I L CT L CT + + ⋅ ⋅ + +                      √3 10,5 = 9 ,09 3 kV* 2 √3 10,5 = 9 ,09 3 kV* 2 √3 10,5 = 9 ,09 3 kV* 2 √3 10,5 = 9 ,09 3 kV* 2
  • 13. A ctu a l T ren d s in D ev elopmen t of P ower Sy stem P rotection a n d A u toma tion 2 0 2 1 0 0 1 0 0 _ 1 1 _ 4 00 _ 1 1 _ _ 5 1 1 1 _ 2 0 1 0 0 1 0 2 _ 4 00 _ 1 2 _ _ 5 0. 7 21 0. 8 4 4 2. 6 _ 3 0 0 1 0 0 1 3 _ 4 00 _ 1 3 _ _ 5 I I Id L L CT L N CT Id L I I L CT L N CT Id L I I L CT L N CT = ⋅ ⋅ + ⋅ ⋅ +                                                 1 0 0 1 _ 10. 5_ 7 1 _ 10. 5_ 8 0 1 0 2 _ 10. 5_ 7 2 _ 10. 5_ 8 8 3 0 0 1 3 _ 10. 5_ 7 3 _ 10. 5_ 8 I I L CT L CT I I L CT L CT I I L CT L CT + ⋅ ⋅ + +                     For such protection scheme the differential currents in per-unit can be calculated in accordance with the following matrix equation: (6 ) Ad v a n ta g e s o f th is so lu tio n : • Increased sensitivity because the zero sequence current reduction is not required • Increased sensitivity for the earth faults located close to the star point of the auto-transformer common winding since the current is measured exactly there • Increased sensitivity for faults inside the tertiary delta winding • Clear indication of the faulty phase because the differential current strictly correspond to windings located on the same magnetic limb (i.e. all three matrixes are unit matrixes in the above equation). D isa d v a n ta g e s o f th is so lu tio n : • L ow sensitivity for internal winding faults located close to the 220 kV side connection point • All faults on the 220 kV conductor are seen as external fault (e.g. such differential scheme will not operate for faults in the 220 kV side bushing). Note that the rated no-load voltage of the tertiary delta winding was intentional reduced by one half in order to compensate for “ double current measurement” within the delta winding for the two differential protection schemes presented in this section. 6 . DIF F ERENTIAL PROTECTION BASED ON THE F IRST KIRCHHOF F ’S LAW Due to a galvanic connection between the serial and the common winding (see Figure 1) it is possible to arrange a bus-like differential protection for auto-transformers. This differential protection is based on the First Kirchhoff’s L aw which says that the sum of all currents flowing into one common node shall be zero. Such protection arrangement can be achieved by using either low or high impedance differential protection [6 ]. 6 .1. Low-impedance, phase segregated bus-lik e differential protection for auto-transformers Note that for such scheme the rated current for 220 kV side (i.e. the biggest of the three measured cur- rents) is typically selected as the base current. Z ero sequence current reduction is not at all required for such scheme. The relevant application data to set up such low-impedance differential protection for the example auto-transformer are given in Table 9 . Winding W1 W2 W3 Base P ower [MVA] 400 400 400 P h-P h, No-L oad Voltage [kV] 231 231 231 Base P rimary Current [A] 1000 1000 1000 Vector G roup Y y0 y0 Z ero Sequence Current E limination No No No Connected to CT (See Figure 3) CT1 CT2 CT6 Base current on CT secondary side [A] 1.25 0.8 33 2.00 Table 9 : D iffe re n tia l p ro te c tio n u s in g C T 1, C T 2 a n d C T 6
  • 14. Moscow, 7–10 September 2009 2 0 3 For such protection scheme the differential currents in per-unit can be calculated in accordance with the following matrix equation: (7 ) Ad v a n ta g e s of such phase segregated, low or high impedance, bus-like differential protection scheme: • P rotects common and serial winding against internal short circuits and earth faults • Increased sensitivity for faults located close to the star point of the auto-transformer common winding since currents are measured exactly there • Not affected by auto-transformer inrush currents • Clear indication of the faulty phase because the differential current strictly corresponds to windings located on the same magnetic core limb. D isa d v a n ta g e s of this bus-like phase segregated differential protection scheme: • The tertiary delta winding is not protected at all with such scheme (i.e. this scheme protects only the serial and the common windings) • It will not detect any turn to turn fault inside the serial and the common windings • P hase segregated CTs are required in the common winding star point • Dedicated CT cores with equal ratios and magnetizing characteristics shall be used when a high impedance differential relay is used. 6 .2 . Restricted earth fault protection for auto-transformers R estricted earth fault (R E F) is a zero-sequence current based differential scheme. It is also based on the First Kirchhoff’s L aw which is as well valid for zero-sequence currents. It will detect all earth faults within the common and serial winding of the protected auto-transformer. The relevant application data to set up such R E F differential protection for the example auto-transformer are given in Table 10. Winding W1 W2 N eutral P oint Base P rimary Current [A] 1000 1000 1000 Connected to CT (See Figure 3) CT1 CT2 CT4 Base current on CT secondary side [A] 1.25 0.8 33 1.00 Table 10 : L o w im p e d a n c e R E F p ro te c tio n u s in g C T 1, C T 2 a n d C T 4 For such low-impedance R E F protection scheme the differential current in per-unit can be calculated in accordance with the following matrix equation: (8 ) The R E F protection for an auto-transformer can also be arranged as a high impedance scheme [6 ]. Ad v a n ta g e s of the auto-transformer R E F protection schemes: 1 0 0 1 0 0 _ 1 1 _ 4 00 _ 1 1 _ 220 _ 2 1 1 _ 2 0 1 0 0 1 0 2 _ 4 00 _ 1 2 _ 220 _ 2 1. 25 0. 8 33 _ 3 0 0 1 0 0 1 3 _ 4 00 _ 1 3 _ 220 _ 2 I I Id L L CT L CT Id L I I L CT L CT Id L I I L CT L CT = ⋅ ⋅ + ⋅ ⋅                                                 1 0 0 1 _ _ 6 1 0 1 0 2 _ _ 6 2. 0 0 0 1 3 _ _ 6 I L N CT I L N CT I L N CT + ⋅ ⋅                           [ ] [ ] 1_ 4 00_ 1 1_ 220_ 2 2_ 4 00_ 1 2_ 220_ 2 _ 4 3_ 4 00_ 1 3_ 220_ 2 1 1 1 _ 1 1 1 1 1 1 1. 25 1. 25 1. 0 L CT L CT L CT L CT N CT L CT L CT I I Id REF I I I I I         = ⋅ ⋅ + ⋅ ⋅ + ⋅            
  • 15. A ctu a l T ren d s in D ev elopmen t of P ower Sy stem P rotection a n d A u toma tion 2 0 4 • P rotects the common and the serial winding against internal earth faults • Increased sensitivity for earth faults located close to the star point of the auto-transformer common wind- ing since current is measured exactly there • Not affected by auto-transformer inrush currents • The protection scheme requires just one single CT in the common auto-transformer star point. D isa d v a n ta g e s of the auto-transformer R E F protection schemes: • The tertiary delta winding is not protected at all with such scheme (i.e. this schemes protects only the serial and the common windings against earth faults) • It will not detect any turn to turn or short-circuit faults within the serial and the common windings • Dedicated CT cores with equal ratios and magnetizing characteristic shall be used for high impedance R E F schemes. 7 . UNIT PROTECTION SCHEM ES F OR THE TERTIARY DELTA WINDING As mentioned before, standard auto-transformer differential protection schemes might have limited sensitiv- ity for short-circuits in the tertiary delta winding. The main reasons are the auto-transformer self impedance and reduced rating of the tertiary delta winding. In order to improve the sensitivity for tertiary winding faults dedicated differential schemes are sometimes used. 7 .1. Dedicated differential protection scheme for the tertiary delta winding When an auto-transformer is consisting of three single-phase units then CTs on both sides of the tertiary delta winding are often available. In such installations it is possible to arrange dedicated, bus-like differential protection scheme for every phase of the delta winding. As this is a scheme based on the First Kirchhoff’s L aw, it is not necessary to deduct the zero sequence current on any side. Note that the rated current of the tertiary delta winding shall be used as the base current because this differential scheme is a dedicated protection for that winding only. The relevant application data to set up such differential protection for the example auto-transformer are given in Table 11. Winding W3 W3 Base P ower [MVA] 130 130 P h-P h, No-L oad Voltage [kV] √3 × 10,5 = 18 ,18 7 kV* √3 × 10,5 = 18 ,18 7 kV* Base P rimary Current [A] 4127 4127 Vector G roup Y y0 Z ero Sequence Current E limination No No Connected to CT (See Figure 3) CT7 CT9 Base current on CT secondary side [A] 1.032 1.032 Table 11: D iffe re n tia l p ro te c tio n u s in g C T 7 a n d C T 9 For such protection scheme the differential currents in per-unit can be calculated in accordance with the following matrix equation: (9 ) 1 0 0 1 0 0 _ 1 1_10. 5_ 7 1_10. 5_ 9 1 1 _ 2 0 1 0 0 1 0 2 _10. 5_ 7 2 _10. 5_ 9 1. 032 1. 032 _ 3 0 0 1 0 0 1 3_10. 5_ 7 3_10. 5_ I I Id L L CT L CT Id L I I L CT L CT Id L I I L CT L = ⋅ ⋅ + ⋅ ⋅                                             9 CT              
  • 16. Moscow, 7–10 September 2009 2 0 5 Ad v a n ta g e s o f th is so lu tio n : • Increased sensitivity for faults in the tertiary delta winding because the differential scheme can be sized in accordance with the rating of the tertiary delta winding and not on the rating of the whole auto-trans- former • Clear indication of the faulty phase within the delta winding. D isa d v a n ta g e s o f th is so lu tio n : • Two set of CTs are required within the tertiary delta winding • Such scheme will not detect internal earth faults if the tertiary delta winding or connected power system is not grounded • This scheme will not detect any turn to turn faults inside the delta winding. It is also possible to arrange such differential protection as a high impedance scheme. 7 .2 . Dedicated earth fault protection scheme for a not-loaded tertiary delta winding When a tertiary delta winding is not loaded it is possible to solidly ground one corner of the delta winding as shown in Figure 4. If a CT is positioned in this grounding connection a simple overcurrent relay can be used to protect the tertiary delta winding against any earth fault. Typical pickup value for such overcurrent relay is around 150A primary. Ad v a n ta g e s o f th is so lu tio n : • Increased sensitivity for earth faults in the tertiary delta winding. D isa d v a n ta g e s o f th is so lu tio n : • Not clear indication of the faulty phase inside the delta winding • R equirement to have access to one of the corners of the delta winding • This scheme will not detect any short-circuits or turn to turn faults inside the delta winding. IE Aut o- t r ansf or mer Ter t i ar y,del t a- connect ed W i ndi ng F igure 4 : D e d ic a te d e a rth - fa u lt p ro te c tio n s c h e m e fo r a n o t- lo a d e d te rtia ry d e lta w in d in g
  • 17. A ctu a l T ren d s in D ev elopmen t of P ower Sy stem P rotection a n d A u toma tion 2 0 6 a ) 5 0 100 15 0 200 25 0 5 00 0 5 00 1 10 3 I L1 I L2 I L3 4 00k V Cu r r e n t W a v e f o r ms Ti me[ ms ] [ P r i ma r y Amp e r e s ] b ) 5 0 100 15 0 200 25 0 1. 5 10 3 1 10 3 5 00 0 5 00 1 10 3 I L1 I L2 I L3 220k V Cu r r e n t W a v e f o r ms Ti me[ ms ] [ P r i ma r y Amp e r e s ] 8 . F IELD RECORDINGS The example transformer is an actual auto-transformer where the tertiary delta winding is not loaded. In the existing installation the following CTs are available: CT1, CT2, CT4 and CT7 in accordance with designations shown in Figure 3. By using the first Kirchhoff’s law it is also possible to calculate the common winding currents (i.e. CT5) for any external fault from captured recordings. Due to space limitation only one captured recording will be presented here. This is an external L 2-G nd fault which before clearing evolved into a L 2-L 3-G nd fault. In Figure 5 the following traces, either captured or calculated, are shown for this external fault: a) 400kV side current waveforms (i.e. CT1) in primary amperes (recorded) b) 220kV side current waveforms (i.e. CT2) in primary amperes (recorded) c) Common winding side current waveforms (i.e. CT5) in primary amperes (calculated) d) Waveforms for current inside the tertiary delta winding (i.e. CT7 -note that just one phase is shown because the delta winding is not loaded) and the neutral point current (i.e. CT4) in primary amperes (both recorded) e) Calculated differential current R MS values in percent for the differential protection scheme in accor- dance with Table 3 and equation (1) f) Calculated differential current R MS values in percent for the differential protection scheme in accordance with Table 5 and equation (3) g) Calculated differential current R MS values in percent for the differential protection scheme in accor- dance with Table 6 and equation (4) h) Calculated differential current R MS value in percent for the low-impedance R E F protection scheme in accordance with Table 10 and equation (8 )
  • 18. Moscow, 7–10 September 2009 2 0 7 c ) 5 0 100 15 0 200 25 0 4 00 200 0 200 4 00 I L1 I L2 I L3 Co mmo nW i n d i n gCu r r e n t W a v e f o r ms Ti me[ ms ] [ P r i ma r y Amp e r e s ] d ) 5 0 100 15 0 200 25 0 3 10 3 2 10 3 1 10 3 0 1 10 3 2 10 3 I _i n _De l t a I N Ze r oS e q u e n c eCu r r e n t W a v e f o r ms Ti me[ ms ] [ P r i ma r y Amp e r e s ] e ) 100 200 300 4 00 0 0. 5 1 1. 5 I D_L1 I D_L2 I D_L3 RMSDi f f e r e n t i a l Cu r r e n t s( CT1 & CT2) Ti me[ ms ] Cu r r e n t [ %]
  • 19. A ctu a l T ren d s in D ev elopmen t of P ower Sy stem P rotection a n d A u toma tion 2 0 8 f ) 100 200 300 4 00 0 0. 5 1 1. 5 I D_L1 I D_L2 I D_L3 RMSDi f f e r e n t i a l Cu r r e n t s( CT1, CT2 & CT7 ) Ti me[ ms ] Cu r r e n t [ %] g ) 100 200 300 4 00 0 0. 5 1 1. 5 I D_L1 I D_L2 I D_L3 RMSDi f f e r e n t i a l Cu r r e n t s( CT1, CT5& CT7 ) Ti me[ ms ] Cu r r e n t [ %] h ) 100 200 300 4 00 0 0. 5 1 1. 5 I D_REF REFF u n c t i o n Ti me[ ms ] Cu r r e n t [ %] F ig. 5 : E v a lu a tio n o f c a p tu re d d is tu rb a n c e file fro m th e e x a m p le a u to - tra n s fo rm e r in s ta lla tio n From Figure 5 it can be seen that for all presented differential protection schemes calculated differential current will be less than 1.5% during the entire external fault. Thus all presented schemes are correctly balanced and consequently correctly applied for the protection of the example auto-transformer.
  • 20. Moscow, 7–10 September 2009 2 0 9 9 . CONCLUSION Different types of auto-transformer differential protection schemes have been presented. Once more note that the following data are crucial for proper application of the selected differential protection scheme: • Which base quantities (i.e. power, no load voltage and current) shall be used • Which vector group shall be entered • Whether or not zero sequence current elimination shall be enabled. Once this important data is known instruction for the particular relay make shall be followed to derive relay- specific settings. Actual implementation for all of these differential protection schemes for a particular relay model can be found in reference [6 ]. Which particular scheme that will be used is mostly determined by availability of the main CTs in a specific installation and possibly previous experience of a particular utility. It is recommended that in addition to the standard differential protection scheme (e.g. as shown in Table 3 or Table 4) additional differential scheme is applied which is sensitive for faults close to the common winding star point (e.g. as for example shown in Table 6 , Table 8 or Table 10). Other possible solution is to combine two differential schemes which have different properties (e.g. as for example two schemes shown in Table 5, Table 4 and Table 6 ). Due to size and importance of auto-transformers in modern power system (e.g. mostly used as system intertie transformers) full duplication of such protection scheme can also be justified. REF ERENCES [1] P ower transformers – International Standard IE C 6 007 6 , E dition 2.1. [2] IE E E G uide for P rotecting P ower Transformers, IE E E Standard C37 .9 1-2008 . [3] Z . G ajiс ´, “ Differential P rotection for Arbitrary Three-P hase P ower Transformer” , P hD Thesis, L und University, Sweden, February 2008 , ISBN: 9 7 8 -9 1-8 8 9 34-47 -5; available at: http://www.iea.lth.se/publications/pubphd.html [4] G . Bertagnolli, “ Short-Circuit Duty of P ower Transformers” , Appendix 10, ABB Book, L egano – Italy, December 19 9 6 . [5] ABB R E T 6 7 0 Technical reference manual, Document ID: 1MR K 504 08 6 -UE N. [6 ] ABB Application Note, “ Differential P rotection Schemes for Auto-Transformers” , Document ID: SA2008 -000519 ; available at: http://www.abb.com/substationautomation [7 ] ABB R ADSB User’s G uide, Document ID: 1MR K 504 002-UE N. [8 ] “ Instruction for P lanning Differential P rotection Schemes” , Document ID: CH-E S 53-10 E , BBC J anu- ary 19 8 0. View publication stats View publication stats