1. A tap changer is a device fitted to power
transformers for regulation of the output
voltage to required levels.
On-load tap-changers (OLTCs) are
indispensable in regulating power
transformers used in electrical energy
networks and industrial applications

2.  Tap changer alters the turn
ratios of the transformer on the
system by altering the number
of turns in one winding of the
appropriate transformer.
 Tap changers offer variable
control to keep the supply
voltage within these limits.
 Tap changers are of two types
◦ Off load
◦ On load
However since the offload tap
changer causes interruption in
the supply on load tap
changers are more preferred
in in today power system.

3.  By the transformation
ratio
V1/V2= N1/N2
V2=N2/N1×V1
From the above equation
by altering the turn ratio
to suitable values the
secondary voltage can be
adjusted desired level.
 Lets – N1=2750,
N2=100, turn ratio=
N1/N2=2750/100=27.5
why we choose this turn
ratio - V1=11 KV,
V2= 400Volt
Transformation ratio
V1/V2=
11000/400=27.5

4.  Each tap corresponds to different
transformation ratio. For Initial
installation we need to choose a
suitable tap as per our voltage levels.
 Tap changers provides 5 to 20 %
voltage range for voltage regulation.

6.  An on load tap changer
has 3 major steps
a. Tap selector- it selects
the appropriate tap
b. Fixed contact- These
contacts hold a fixed
position
c. Moving contact- This
contact moves to open/
close the appropriate
taps.

7.  Based on the AVR
feedback the suitable
tap is selected fig (a) to
(c)
 After the tap is selected
the moving contact
moves and it closes both
taps for a while. It
moves further and finally
completely opens to
earlier tap and closes to
the next tap fig (d) to (i)

8.  The moving contact closes two taps
for a while during the tap changing,
due to which a circulating current
starts to flow. This current needs to
be minimized. For limiting this
current resistor or reactors are used.
 The moving contact is operated by
charged spring tension and it
completes the process within 30 to
70ms. The spring is charged by
motor drives.
 While opening and closing the
contacts sparks are produced due to
arising recovery voltage. The
contacts are kept in oil or SF6 gas ,
which work as insulation medium as
well as arc quenching.

9. Tap
selector
Diverter
switch / Oil
compartment
MDU

10.  Motor drive unit (MDU)- This unit has got a
motor diver and other necessary controls.
Motor charges the spring to rapidly perform
the switching. Power is transferred via shaft &
gear mechanism.
 Diverter switch /Oil compartment- This has
the diverter switch, which has moving and
fixed contacts. It is filled with oil or SF6 gas
to avoid the sparking & quenching during
opening and closing of the contacts.
 Tap selector- It has different tap
combinations as specified by the customer
requirements and different standards.

12.  Due to opening closing of contacts the sparks
produce and the oil degrades over the time. The oil
test & analysis needs to be done in lab at regular
interval
 The contacts wear over the time after number of
operations.
 The oil seals damage over the time and leakage
happens. Maintaining the oil level is must. For
condition monitoring its must to check for oil leak
and level regularly.
 Oil dripping is dangerous for environment as well.
 OLTC includes a lot of gear, spring and mechanical
parts which have a usual wear and tear, that need to
be taken care as an when required.

13.  Vacuum type OLTC use the vacuum interrupters
which has some advantages over oil / SF6.
 It is hermetically sealed and has no interaction
with surrounding medium despite the arc.
 Contacts wear is lower than OIL/SF6.
 No aging or quenching medium is required.
 Its more environment friendly.
 Vacuum interrupters perform up to 600000
operation with out replacement.
 Has low maintenance cost and greater reliability.

14. Vacuum OLTC Vacuum interrupter

15.  A dual voltage transformer can be defined as
the one which is capable of providing two
types of voltage.
 A dual voltage transformer has two windings
in primary and two other windings in
secondary.
 By connecting the both windings either of
primary or secondary in series or parallel two
different voltages are produced.

16.  From the figure two
primary windings and
two secondary
windings are
connected in series
resulting in 240 volt
input and 24 volt out
put voltage.

17.  From the adjacent
figure the primary and
secondary windings are
connected in parallel,
resulting 120 volt
input and 12 volt out
put voltage.
 There can be either
type of arrangements
as per requirement.

18.  The details in the
adjacent figure shows
the winding arrangement
of a dual transformer. It
produces 33/7.1 and
33/11 kV voltages
according to
arrangement of winding.
 The unit produces
different outputs, based
on the connections as
advised in the name plate
details.
 Upon simplifying the
connection diagrams
they turn out to be series
connected winding for
33/11 kv output and
combination of series
and parallel for 33/7.1
kv output.