into account the physical phenomena

into account the physical phenomena which are
involved in a transient process. To justify the
models used for modelling transformer windings,
a short description of the phenomena that play
an important role when a steep-fronted voltage
surge impinges a transformer terminal follows
(Greenwood, 1991; Chowdhuri, 2004; Bewley,
1951; Heller & Veverka, 1968, Rudenberg, 1968;
Degeneff, 2007):
a) Immediately after the surge enters the
transformer, winding capacitances begin to
charge and the current starts to flow, first in
the dielectric structure, then in the winding.
Flux will not penetrate in the ferromagnetic
core before 1 μs. The inductance is basically
that of an air core, since core losses are negligible.
Transformer losses are basically due
to losses in the conductors and the dielectric.
b) During the transition between 1 μs and 10
μs, the inductance characteristic passes from
air to iron core. Fluxes will have penetrated
the core completely at 10 μs. Current primarily
flows through the capacitance structure,
whose influence is still very important.
However, it also starts to flow in conductors.
c) The behaviour of the transformer becomes
stable after 10 μs. Losses are now occurring
in the conductors, core, dielectric, and transformer
tank. The conductor losses include the
skin and the proximity effects, whereas the
core losses include the eddy current effect.
At power frequency, the voltage transfer for
a transformer depends upon the turns ratio, but
at other frequencies the response can be very
different. When a steep-fronted voltage is applied
to a transformer winding, the voltage that
appears across the other winding can exhibit up
to four components (Palueff & Hagenguth, 1932;
Chowdhuri, 2004):
• A very short duration (i.e., fraction of a
microsecond) voltage component, whose
amplitude depends on the ratio of the capacitance
between the two windings and
that to ground.
• Oscillations induced by the space harmonics
in the primary winding. This induction
process is both electrostatic and magnetic,
and is dependent on the distributed
constants and the turns ratio of the two
windings.
• A free oscillation, whose magnitude depends
on the distributed constants of the
secondary winding.
• A voltage that exponentially rises to peak
and subsequently decays exponentially. It
is generated by magnetic induction, is directly
proportional to the turns ratio and
is a simple function of the short circuit inductance
of the transformer and the surge
impedances of the external circuits.
The two first components are highly damped
out if the secondary winding is connected to a
line or a load.
Although power transformers have a relatively
simple design, their representation can be very
complex due to the different core and winding
designs. An accurate model may consider each
turn of the winding represented by capacitances,
inductances and losses, with coupling to other
turns. The following assumptions and simplifications
are made when deriving the equivalent
circuit of a transformer:
• Under the influence of high frequency excitation
the iron core behaves in a completely
different manner to that when it is
excited at power frequencies. At very high
frequencies (i.e., about 1 MHz and above),
skin effect causes the iron enclosing a stator
coil to act as a barrier to magnetic flux.
The behaviour of the core iron under these
circumstances is like that of an earthed
sheath, and the core may be replaced by
a grounded sheath, which is impenetrable