Introduction:
·
For supplying a load in
excess of the rating of an existing transformer, two or more transformers may
be connected in parallel with the existing transformer. The transformers are
connected in parallel when load on one of the transformers is more than its capacity.
The reliability is increased with parallel operation than to have single larger
unit. The cost associated with maintaining the spares is less when two
transformers are connected in parallel.
·
It is usually economical
to install another transformer in parallel instead of replacing the existing
transformer by a single larger unit. The cost of a spare unit in the case of
two parallel transformers (of equal rating) is also lower than that of a single
large transformer. In addition, it is preferable to have a parallel transformer
for the reason of reliability. With this at least half the load can be supplied
with one transformer out of service.
Condition for Parallel Operation of
Transformer:
·
For parallel connection
of transformers, primary windings of the Transformers are connected to source
bus-bars and secondary windings are connected to the load bus-bars.
·
Various conditions that
must be fulfilled for the successful parallel operation of transformers:
1.
Same voltage Ratio
& Turns Ratio (both primary and secondary Voltage Rating is same).
2.
Same Percentage
Impedance and X/R ratio.
3.
Identical Position of
Tap changer.
4.
Same KVA ratings.
5.
Same Phase angle shift
(vector group are same).
6.
Same Frequency rating.
7.
Same Polarity.
8.
Same Phase sequence.
·
Some of these conditions
are convenient and some are mandatory.
·
The convenient are: Same
voltage Ratio & Turns Ratio, Same Percentage Impedance, Same KVA Rating,
Same Position of Tap changer.
·
The mandatory conditions
are: Same Phase Angle Shift, Same Polarity, Same Phase Sequence and Same
Frequency.
·
When the convenient
conditions are not met paralleled operation is possible but not optimal.
1.
Same voltage Ratio & Turns Ratio (on each tap):
·
If the transformers connected in parallel have
slightly different voltage ratios, then due to the inequality of induced emfs
in the secondary windings, a circulating current will flow in the loop formed
by the secondary windings under the no-load condition, which may be much
greater than the normal no-load current.
·
The current will be
quite high as the leakage impedance is low. When the secondary windings are
loaded, this circulating current will tend to produce unequal loading on the
two transformers, and it may not be possible to take the full load from this
group of two parallel transformers (one of the transformers may get
overloaded).
·
If two transformers of
different voltage ratio are connected in parallel with same primary supply
voltage, there will be a difference in secondary voltages.
·
Now when the secondary
of these transformers are connected to same bus, there will be a circulating
current between secondary’s and therefore between primaries also. As the
internal impedance of transformer is small, a small voltage difference may
cause sufficiently high circulating current causing unnecessary extra I2R
loss.
·
The ratings of both
primaries and secondary’s should be identical. In other words, the transformers
should have the same turn ratio i.e. transformation ratio.
2. Same percentage
impedance and X/R ratio:
·
If two
transformers connected in parallel with similar per-unit impedances they will
mostly share the load in the ration of their KVA ratings. Here Load is mostly
equal because it is possible to have two transformers with equal per-unit
impedances but different X/R ratios. In this case the line current will be less
than the sum of the transformer currents and the combined capacity will be
reduced accordingly.
·
A difference in the
ratio of the reactance value to resistance value of the per unit impedance
results in a different phase angle of the currents carried by the two
paralleled transformers; one transformer will be working with a higher power
factor and the other with a lower power factor than that of the combined
output. Hence, the real power will not be proportionally shared by the
transformers.
·
The current shared by two transformers running in parallel
should be proportional to their MVA ratings.
·
The current carried by these transformers are inversely
proportional to their internal impedance.
·
From the above two
statements it can be said that impedance of transformers running in parallel
are inversely proportional to their MVA ratings. In other words percentage
impedance or per unit values of impedance should be identical for all the
transformers run in parallel.
·
When connecting
single-phase transformers in three-phase banks, proper impedance matching
becomes even more critical. In addition to following the three rules for
parallel operation, it is also a good practice to try to match the X/R ratios of the
three series impedances to keep the three-phase output voltages balanced.
·
When single-phase
transformers with the same KVA ratings are connected in a Y-∆ Bank, impedance
mismatches can cause a significant load unbalance among the transformers
·
Lets examine following
different type of case among Impedance, Ratio and KVA.
·
If single-phase
transformers are connected in a Y-Y bank with an isolated neutral, then the
magnetizing impedances should also be equal on an ohmic basis. Otherwise, the
transformer having the largest magnetizing impedance will have a highest
percentage of exciting voltage, increasing the core losses of that transformer
and possibly driving its core into saturation.
Case
1: Equal Impedance, Ratios and Same kVA:
·
The
standard method of connecting transformers in parallel is to have the same turn
ratios, percent impedances, and kVA ratings.
·
Connecting
transformers in parallel with the same parameters results in equal load sharing
and no circulating currents in the transformer windings.
·
Example:
Connecting two 2000 kVA, 5.75% impedance transformers in parallel, each with
the same turn ratios to a 4000 kVA load.
·
Loading on the
transformers-1 =KVA1=[( KVA1 / %Z) / ((KVA1 / %Z1)+ (KVA2 / %Z2))]X KVAl
·
kVA1 = 348 / (348 + 348)
x 4000 kVA = 2000 kVA.
·
Loading on the
transformers-2 =KVA1=[( KVA2 / %Z) / ((KVA1 / %Z1)+ (KVA2 / %Z2))]X KVAl
·
kVA2 = 348 / (348 + 348)
x 4000 kVA = 2000 kVA
·
Hence KVA1=KVA2=2000KVA
Case 2: Equal Impedances, Ratios and Different kVA:
·
This Parameter is not in
common practice for new installations, sometimes two transformers with
different kVAs and the same percent impedances are connected to one common bus.
In this situation, the current division causes each transformer to carry its
rated load. There will be no circulating currents because the voltages (turn
ratios) are the same.
·
Example:
Connecting 3000 kVA and 1000 kVA transformers in parallel, each with 5.75%
impedance, each with the same turn ratios, connected to a common 4000 kVA load.
·
Loading on
Transformer-1=kVA1 = 522 / (522 + 174) x 4000 = 3000 kVA
·
Loading on
Transformer-1=kVA2 = 174 / (522 + 174) x 4000 = 1000 kVA
·
From above calculation
it is seen that different kVA ratings on transformers connected to one common
load, that current division causes each transformer to only be loaded to its
kVA rating. The key here is that the percent impedances are the same.
Case 3: Unequal Impedances but Same Ratios & kVA:
·
Mostly used this
Parameter to enhance plant power capacity by connecting existing transformers
in parallel that have the same kVA rating, but with different percent
impedances.
·
This is common when
budget constraints limit the purchase of a new transformer with the same
parameters.
·
We need to understand is
that the current divides in inverse proportions to the impedances, and larger
current flows through the smaller impedance. Thus, the lower percent impedance
transformer can be overloaded when subjected to heavy loading while the other
higher percent impedance transformer will be lightly loaded.
·
Example: Two
2000 kVA transformers in parallel, one with 5.75% impedance and the other with
4% impedance, each with the same turn ratios, connected to a common 3500 kVA
load.
·
Loading on Transformer-1=kVA1 = 348 / (348 + 500) x 3500 = 1436 kVA
·
Loading on Transformer-2=kVA2 = 500 / (348 + 500) x 3500 = 2064 kVA
·
It can be seen that
because transformer percent impedances do not match, they cannot be loaded to
their combined kVA rating. Load division between the transformers is not equal.
At below combined rated kVA loading, the 4% impedance transformer is overloaded
by 3.2%, while the 5.75% impedance transformer is loaded by 72%.
Case 4: Unequal Impedances & KVA Same Ratios:
·
This particular of
transformers used rarely in industrial and commercial facilities connected to
one common bus with different kVA and unequal percent impedances. However,
there may be that one situation where two single-ended substations may be tied
together via bussing or cables to provide better voltage support when starting
large Load.
·
If the percent
impedances and kVA ratings are different, care should be taken when loading
these transformers.
·
Example:
Two transformers in parallel with one 3000 kVA (kVA1) with 5.75% impedance, and
the other a 1000 kVA (kVA2) with 4% impedance, each with the same turn ratios,
connected to a common 3500 kVA load.
·
Loading on Transformer-1=kVA1 = 522 / (522 + 250) x 3500 = 2366 kVA
·
Loading on Transformer-2=kVA2 = 250 / (522 + 250) x 3500 = 1134 kVA
·
Because the percent
impedance is less in the 1000 kVA transformer, it is overloaded with a less
than combined rated load.
Case 5: Equal Impedances & KVA Unequal Ratios:
·
Small differences in
voltage cause a large amount of current to circulate. It is important to point
out that paralleled transformers should always be on the same tap connection.
·
Circulating current is
completely independent of the load and load division. If transformers are fully
loaded there will be a considerable amount of overheating due to circulating
currents.
·
The Point which should
be Remember that circulating currents do not flow on the line, they cannot be
measured if monitoring equipment is upstream or downstream of the common
connection points.
·
Example:
Two 2000 kVA transformers connected in parallel, each with 5.75% impedance,
same X/R ratio (8), transformer 1 with tap adjusted 2.5% from nominal and
transformer 2 tapped at nominal. What is the percent circulating current (%IC)
·
%Z1 = 5.75, So %R' = %Z1
/ √[(X/R)2 + 1)] = 5.75 / √((8)2 + 1)=0.713
·
%R1 = %R2 = 0.713
·
%X1 = %R x (X/R)=%X1=
%X2= 0.713 x 8 = 5.7
·
Let %e = difference in
voltage ratio expressed in percentage of normal and k = kVA1/ kVA2
·
Circulating current %IC = %eX100 / √ (%R1+k%R2)2 + (%Z1+k%Z2)2.
·
%IC = 2.5X100 / √ (0.713
+ (2000/2000)X0.713)2 + (5.7 + (2000/2000)X5.7)2
·
%IC = 250 / 11.7 = 21.7
·
The circulating current
is 21.7% of the full load current.
Case 6: Unequal Impedances, KVA & Different Ratios:
·
This type of parameter
would be unlikely in practice.
·
If both the ratios and
the impedances are different, the circulating current (because of the unequal
ratio) should be combined with each transformer's share of the load current to
obtain the actual total current in each unit.
·
For unity power factor,
10% circulating current (due to unequal turn ratios) results in only half
percent to the total current. At lower power factors, the circulating current
will change dramatically.
·
Example: Two
transformers connected in parallel, 2000 kVA1 with 5.75% impedance, X/R ratio
of 8, 1000 kVA2 with 4% impedance, X/R ratio of 5, 2000 kVA1 with tap adjusted
2.5% from nominal and 1000 kVA2 tapped at nominal.
·
%Z1 = 5.75, So %R' = %Z1
/ √[(X/R)2 + 1)] = 5.75 / √((8)2 + 1)=0.713
·
%X1= %R x (X/R)=0.713 x
8 = 5.7
·
%Z2= 4, So %R2 = %Z2 /√
[(X/R)2 + 1)]= 4 / √((5)2 + 1) =0.784
·
%X2 = %R x (X/R)=0.784 x
5 = 3.92
·
Let %e = difference in
voltage ratio expressed in percentage of normal and k = kVA1/ kVA2
·
Circulating current %IC = %eX100 / √ (%R1+k%R2)2 + (%Z1+k%Z2)2.
·
%IC = 2.5X100 / √ (0.713
+ (2000/2000)X0.713)2 + (5.7 + (2000/2000)X5.7)2
·
%IC = 250 / 13.73 =
18.21.
·
The circulating current
is 18.21% of the full load current.
1.
3. Same polarity:
·
Polarity of transformer
means the instantaneous direction of induced emf in secondary. If the
instantaneous directions of induced secondary emf in two transformers are
opposite to each other when same input power is fed to the both of the
transformers, the transformers are said to be in opposite polarity.
·
The transformers should
be properly connected with regard to their polarity. If they are connected with
incorrect polarities then the two emfs, induced in the secondary windings which
are in parallel, will act together in the local secondary circuit and produce a
short circuit.
o Polarity of all transformers run in parallel
should be same otherwise huge circulating current flows in the transformer but
no load will be fed from these transformers.
o If the instantaneous directions of induced
secondary emf in two transformers are same when same input power is fed to the
both of the transformers, the transformers are said to be in same polarity.
1.
4. Same phase sequence:
·
The phase sequence of
line voltages of both the transformers must be identical for parallel operation
of three-phase transformers. If the phase sequence is an incorrect, in every
cycle each pair of phases will get short-circuited.
o This condition must be strictly followed for parallel operation of
transformers.
1.
5. Same phase angle shift:(zero relative
phase displacement between the secondary line voltages):
·
The transformer windings
can be connected in a variety of ways which produce different magnitudes and
phase displacements of the secondary voltage. All the transformer connections
can be classified into distinct vector groups.
·
Group 1: Zero phase
displacement (Yy0, Dd0, Dz0)
Group 2:180° phase displacement (Yy6, Dd6, Dz6)
Group 3: -30° phase displacement (Yd1, Dy1, Yz1)
Group 4: +30° phase displacement (Yd11, Dy11, Yz11)
Group 2:180° phase displacement (Yy6, Dd6, Dz6)
Group 3: -30° phase displacement (Yd1, Dy1, Yz1)
Group 4: +30° phase displacement (Yd11, Dy11, Yz11)
·
In order to have zero
relative phase displacement of secondary side line voltages, the transformers
belonging to the same group can be paralleled. For example, two transformers
with Yd1 and Dy1 connections can be paralleled.
·
The transformers of
groups 1 and 2 can only be paralleled with transformers of their own group.
However, the transformers of groups 3 and 4 can be paralleled by reversing the
phase sequence of one of them. For example, a transformer with Yd1 1 connection
(group 4) can be paralleled with that having Dy1 connection (group 3) by
reversing the phase sequence of both primary and secondary terminals of the Dy1
transformer.
·
We can only parallel Dy1
and Dy11 by crossing two incoming phases and the same two outgoing phases on
one of the transformers, so if we have a DY11 transformer we can cross B&C
phases on the primary and secondary to change the +30 degree phase shift into a
-30 degree shift which will parallel with the Dy1, assuming all the other
points above are satisfied.
1.
6. Same KVA ratings:
·
If two or more
transformer is connected in parallel, then load sharing % between them is
according to their rating. If all are of same rating, they will share equal
loads
·
Transformers of unequal
kVA ratings will share a load practically (but not exactly) in proportion to
their ratings, providing that the voltage ratios are identical and the
percentage impedances (at their own kVA rating) are identical, or very nearly
so in these cases a total of than 90% of the sum of the two ratings is normally
available.
·
It is recommended that
transformers, the kVA ratings of which differ by more than 2:1, should not be
operated permanently in parallel.
·
Transformers having
different kva ratings may operate in parallel, with load division such that
each transformer carries its proportionate share of the total load To achieve
accurate load division, it is necessary that the transformers be wound with the
same turns ratio, and that the percent impedance of all transformers be equal,
when each percentage is expressed on the kva base of its respective
transformer. It is also necessary that the ratio of resistance to reactance in
all transformers be equal. For satisfactory operation the circulating
current for any combinations of ratios and impedances probably should not
exceed ten percent of the full-load rated current of the smaller unit.
1.
7. Identical tap changer and its
operation:
·
The only important point
to be remembered is the tap changing switches must be at same position for all
the three transformers and should check and confirm that the secondary voltages
are same. When the voltage tap need change all three tap changing switches
should be operated identical for all transformers. The OL settings of the SF6
also should be identical. If the substation is operating on full load
condition, tripping of one transformer can cause cascade tripping of all three
transformers.
·
In transformers Output
Voltage can be controlled either by Off Circuit Tap Changer (Manual tap
changing) or By On - Load Tap Changer-OLTC (Automatic Changing).
·
In the transformer with
OLTC, it is a closed loop system, with following components:
·
(1) AVR (Automatic
Voltage Regulator- an electronic programmable device). With this AVR we can set
the Output Voltage of the transformers. The Output Voltage of the transformer
is fed into the AVR through the LT Panel. The AVR Compares the SET voltage
& the Output Voltage and gives the error signals, if any, to the OLTC
through the RTCC Panel for tap changing. This AVR is mounted in the RTCC.
·
(2) RTCC (Remote Tap
Changing Cubicle): This is a panel consisting of the AVR, Display for Tap
Position, Voltage, and LEDs for Raise & Lower of Taps relays, Selector
Switches for Auto Manual Selection... In AUTO MODE the voltage is controlled by
the AVR. In manual Mode the operator can Increase / decrease the voltage by
changing the Taps manually through the Push Button in the RTCC.
·
(3) OLTC is mounted on
the transformer. It consists of a motor, controlled by the RTCC, which changes
the Taps in the transformers.
o Both the Transformers should have same voltage
ratio at all the taps & when you run transformers in parallel, it should
operate as same tap position. If we have OLTC with RTCC panel, one RTCC should
work as master & other should work as follower to maintain same tap
positions of Transformer.
o However, a circulating current can be flown
between the two tanks if the impedances of the two transformers are different
or if the taps of the on-load tap changer (OLTC) are mismatched temporarily due
to the mechanical delay. The circulating current may cause the malfunction of
protection relays.
Other necessary condition for parallel operation
1) All parallel units must be supplied
from the same network.
2) Secondary cabling from the transformers
to the point of paralling has approximately equal length and characteristics.
3) Voltage difference between
corresponding phase must not exceed 0.4%
4) When the transformers are operated in
parallel, the fault current would be very high on the secondary side. Supposing
percentage impedance of one transformer is say 6.25 %, the short circuit MVA
would be 25.6 MVA and short circuit current would be 35 kA.
5) If the transformers are of same rating
and same percentage impedance, then the downstream short circuit current would
be 3 times (since 3 transformers are in Parallel) approximately 105 kA. This
means all the devices like ACBs, MCCBs, switch boards should withstand the
short-circuit current of 105 kA. This is the maximum current. This current will
get reduced depending on the location of the switch boards, cables and cable
length etc. However this aspect has to be taken into consideration.
6) There should be Directional relays on
the secondary side of the transformers.
7) The percent impedance of one
transformer must be between 92.5% and 107.5% of the other. Otherwise,
circulating currents between the two transformers would be excessive.
Summary of Parallel Operation of Transformer:
Transformer
Parallel
Connection Types
|
Equal Loading
|
Unequal Loading
|
Overloading Current
|
Circulating Current
|
Recomm. connection
|
Equal Impedance &
Ratio ,Same KVA
|
Yes
|
No
|
No
|
No
|
Yes
|
Equal Impedance &
Ratio But different KVA
|
No
|
Yes
|
No
|
No
|
Yes
|
Unequal Impedance But
Same Ratio& KVA
|
No
|
Yes
|
Yes
|
No
|
No
|
Unequal Impedance
& KVA But Same Ratio
|
No
|
Yes
|
Yes
|
No
|
No
|
Unequal Impedance
& Ratio But Same KVA
|
Yes
|
No
|
Yes
|
Yes
|
No
|
Unequal Impedance
& Ratio & different KVA
|
No
|
No
|
Yes
|
Yes
|
No
|
The combinations that will operate in parallel:
·
Following Vector group
of Transformer will operate in parallel.
Operative
Parallel Operation
|
||
Sr.No
|
Transformer-1
|
Transformer-2
|
1
|
∆∆
|
∆∆ or Yy
|
2
|
Yy
|
Yy or ∆∆
|
3
|
∆y
|
∆y or Y∆
|
4
|
Y∆
|
Y∆ or ∆y
|
·
Single-phase
transformers can be connected to form 3-phase transformer banks for 3-phase
Power systems.
o Four common methods of connecting three
transformers for 3-phase circuits are Δ-Δ, Y-Y, Y-Δ, and Δ-Y connections.
o An advantage of Δ-Δ connection is that if one
of the transformers fails or is removed from the circuit, the remaining two can
operate in the open-Δ or V connection. This way, the bank still delivers
3-phase currents and voltages in their correct phase relationship. However, the
capacity of the bank is reduced to 57.7 % (1 3) of its original value.
o In the Y-Y connection, only 57.7% of the line
voltage is applied to each winding but full line current flows in each winding.
The Y-Y connection is rarely used.
o The Δ-Y connection is used for stepping up
voltages since the voltage is increased by the transformer ratio multiplied by
3.
The combinations that will not operate in parallel:
·
Following Vector group
of Transformer will not operate in parallel.
Inoperative
Parallel Operation
|
||
Sr.No
|
Transformer-1
|
Transformer-2
|
1
|
∆∆
|
∆y
|
2
|
∆y
|
∆∆
|
3
|
Y∆
|
Yy
|
4
|
Yy
|
Y∆
|
To check Synchronization of Transformers:
·
Synchronization of
Transformer can be checked by either of following steps:
·
Checked by synchronizing
relay & synchro scope.
·
If Secondary of
Transformer is not LT Then we must use check synchronizing relay &
Commission the system properly. After connecting relay. Relay must be charges
with only 1 supply & check that relay is functioning properly.
·
Synchronizing should be
checked of both the supply voltages. This can be checked directly with
millimeter between L1 phases of Transformer 1 and L1 phase of Transformer 2.
Then L2 Phase of Transformer 1 and L2 Phase of Transformer 2. Then L3 Phase of
Transformer 1 and L3 Phase of Transformer 2. In all the cases MultiMate should
show 0 voltages theoretically. These checks must be done at synchronizing
breakers only. We have to also check that breaker out going terminals are
connected in such a way that L1 Terminals of both the Breakers comes to same
Main Bus bar of panel. Same for L2 & L3.
·
Best way to check
synchronization on LT is charge complete panel with 1 source up to outgoing
terminals of another incoming breaker terminal. Then just measure Voltage
difference on Incoming & out going terminals of Incoming Breaker. It should
be near to 0.
·
To check circulating
current Synchronize both the transformer without outgoing load. Then check
current. It will give you circulating current.
Advantages of Transformer Parallel Operation:
1) Maximize electrical system efficiency:
·
Generally electrical
power transformer gives the maximum efficiency at full load. If we run numbers
of transformers in parallel, we can switch on only those transformers which
will give the total demand by running nearer to its full load rating for that
time.
·
When load increases we
can switch no one by one other transformer connected in parallel to fulfil the
total demand. In this way we can run the system with maximum efficiency.
2) Maximize electrical system
availability:
·
If numbers of
transformers run in parallel we can take shutdown any one of them for
maintenance purpose. Other parallel
transformers in system will serve the load without total
interruption of power.
3) Maximize power system reliability:
·
If nay one of the
transformers run in parallel, is tripped due to fault other parallel transformers
is the system will share the load hence power supply may not be interrupted if
the shared loads do not make other transformers over loaded.
4) Maximize electrical system flexibility:
·
There is a chance of
increasing or decreasing future demand of power system. If it is predicted that
power demand will be increased in future, there must be a provision of
connecting transformers in system in parallel to fulfil the extra demand
because it is not economical from business point of view to install a bigger
rated single transformer by forecasting the increased future demand as it is
unnecessary investment of money.
·
Again if future demand
is decreased, transformers running in parallel can be removed from system to
balance the capital investment and its return.
Disadvantages of Transformer Parallel Operation:
·
Increasing short-circuit
currents that increase necessary breaker capacity.
·
The risk of circulating
currents running from one transformer to another Transformer. Circulating
currents that diminish load capability and increased losses.
·
The bus ratings could be
too high.
·
Paralleling transformers
reduces the transformer impedance significantly, i.e. the parallel transformers
may have very low impedance, which creates the high short circuit currents.
Therefore, some current limiters are needed, e.g. reactors, fuses, high impedance buses, etc
Therefore, some current limiters are needed, e.g. reactors, fuses, high impedance buses, etc
·
The control and
protection of three units in parallel is more complex.
·
It is not a common
practice in this industry, since Main-tie-Main is very common in this industry.
Conclusions:
·
Loading considerations
for paralleling transformers are simple unless kVA, percent impedances, or
ratios are different. When paralleled transformer turn ratios and percent
impedances are the same, equal load division will exist on each transformer.
When paralleled transformer kVA ratings are the same, but the percent
impedances are different, then unequal load division will occur.
·
The same is true for
unequal percent impedances and unequal kVA. Circulating currents only exist if
the turn ratios do not match on each transformer. The magnitude of the
circulating currents will also depend on the X/R ratios of the transformers.
Delta-delta to delta-wye transformer paralleling should not be attempted.
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