3.1 GENERAL
The excitation of a
generator’s field system has already been mentioned in Chapter 2, as it is not
possible to describe a.c. generators without referring to their field system
and excitation. This chapter discusses
the three practical methods of field excitation which may be encountered.
FIGURE 3.1
A.C. GENERATOR
EXCITATION (1)
3.2 CONVENTIAL EXCITATION
Figure
3.1(a) shows the ‘conventional’ method described in the manual ‘Fundamentals of
Electricity 2’, where a driven d.c.
exciter (in this case belt-driven) feeds its d.c. output through sliprings to the main
generator field.
The
output voltage is sensed by an automatic voltage regulator (AVR), which
regulates the exciter’s field so that the exciter output holds the main field
at whatever level is necessary to maintain the generator output voltage
constant. AVRs are discussed later in
this chapter. It will be seen that the
control of voltage is a closed loop, and, like any other closed loop servo
mechanism, it is subject to certain errors.
3.3 STATIC EXCITATION
Figure
3.1(b) shows a development where the rotating d.c. exciter is replaced by a static
electronic exciter, which usually incorporates the AVR. Voltage sensing and excitation power are
derived from the main generator output; excitation current is controlled by the
AVR, rectified and fed into the main field through sliprings, just as in the
‘conventional’ case. This is called the
‘static exciter’ method, and it should be noted that it still requires brushes
and sliprings. It is not found on
platforms but is widely used onshore, although not to any great extent in oil
installations.
3.4 BRUSHLESS EXCITATION (GENERAL CASE)
A
further significant development is shown in Figure 3.1(c). Here the shaft-driven rotating exciter has
been restored, but it now takes the form of an a.c. generator of the
fixed-field type mounted on the main shaft itself. Its a.c. output is taken through connections
inside the shaft, through a diode bridge which rotates with the shaft, to the
main rotating field of the generator. The
field is thus excited by d.c.
without the need for brushes and sliprings. It will be seen that this exciter cannot be
belt-driven; it must be integral with the main shaft.
As with
static excitation, voltage sensing and excitation power are derived from the
main generator output. Excitation
current is controlled by the AVR, rectified and fed into the fixed field of the
a.c. exciter. The a.c. output of the
exciter follows the AVR signal, and its output current is rectified by the
diodes which rotate with the shaft; the d.c.
output from them is in turn passed to the generator’s main field. The field current thus follows the AVR signal
almost exactly.
It will
be seen that the only link between the fixed and moving parts is the magnetic
one between the exciter field and its rotating armature: no sliprings and
brushes are needed. The method is for
this reason called ‘brushless excitation’, and it will be found, in one form or
another, on all platform and onshore main and auxiliary generators.
The
principal advantage of brushless excitation over the other two types is that
the absence of brushgear and sliprings greatly eases the maintenance problem.
3.5 BEHAVIOUR UNDER SHORT CIRCUIT
In the
conventional case (Figure 3.1(a)) excitation power is derived from a separate d.c. generator which is
not affected by the voltage on the main generator’s output lines. However, with both static excitation and the
brushless excitation described above (Figures 3.1(b) and (c)) excitation power
(as well as sensing) is derived from the output of the generator itself - true
‘shunt excitation’.
Under
normal conditions this is quite satisfactory, but under short-circuit
conditions the generator’s output voltage will drop heavily - it might even
vanish. Under this low-voltage output
situation the AVR will try to force up the excitation, but, just at the moment
it wishes to do so, it has no power available.
Under these conditions a collapse of system voltage is possible.
To
overcome this a method is employed which makes use of the short-circuit
currents themselves to provide the missing excitation.
FIGURE 3.2
A.C. GENERATOR EXCITATION (2)
3.6 BRUSHLESS EXCITATION (WITHOUT PILOT EXCITER)
Three
heavy current transformers are arranged in the generator output lines as shown
in Figure 3.2(a). Their secondary
outputs are rectified and passed to the main exciter’s field either in parallel
with the normal excitation (as shown) or sometimes to a separate field winding
in the exciter. Although they take the
form of current transformers, these units, when used in this application, are
referred to as ‘short-circuit CTs’.
Under
short-circuit conditions when the generator output voltage is very low, the
short-circuit CTs pick up the heavy short-circuit currents and, after they have
been rectified, use them to boost the main exciter field, and so the main field. This serves to maintain the generator output
voltage under short-circuit conditions - a necessary requirement in network
operation so that protection may operate reliably.
Short-circuit
CTs are used generally with medium-sized generators with either static or
brushless excitation where no ‘pilot exciter’ is fitted (see below) and where
excitation power is drawn from the generator’s output. This applies to most basic services
generators on platforms and to some main sets.
3.7 BRUSHLESS EXCITATION (WITH PILOT EXCITER)
With
large brushless generators a different method is used. Instead of drawing excitation power from the
generator output, the AVR has only a voltage-sensing connection. The arrangement is shown in Figure 3.2(b).
The
exciter’s field is powered independently from a separate high-frequency
inductor-type generator called a ‘sub-exciter’ or ‘pilot exciter’. It has permanent magnets as rotating field
and is driven by the main shaft. It also provides operating power to the AVR
itself. Only the voltage-sensing leads
to the AVR are taken from the main generator output. The AVR regulates and rectifies the power
from the pilot exciter to the main exciter field. This in turn regulates the a.c. exciter
output, and thence the d.c.
rectified input to the main field through the diodes, to hold the generator
output voltage constant.
The
pilot exciter is mounted on the main shaft, usually immediately next to the
main exciter (not exactly as in Figure 3.2(b) which is schematic only). It is usually arranged in a single enclosure
with the main exciter and the diode plates. Figure 3.3 shows this arrangement.
As in
the conventional case, the excitation of the generator is now independent of
the generator’s output voltage and so is maintained even under short-circuit
conditions and without the use of short-circuit CTs. This is the arrangement on almost all
platform main generators.
3.8 THE DIODE BRIDGE
In
Figures 3.1(c) and 3.2(a) and (b) the diodes are shown for clarity as inside
the shaft between the exciter and the main generator. The exciter output is
3-phase, and the diodes are in fact a 3-phase full-wave bridge, requiring six
diode elements. Clearly they cannot be buried in the middle of the shaft, and
in practice they are mounted on a rotating plate on the extreme end of the
shaft at the exciter end, as shown in Figure 3.3 in green. This makes them
easily accessible for inspection, testing or replacement.
FIGURE 3.3
GENERATOR AND DIODE PLATE
A point
on the use of diodes should be noted. If
one of the six should fail, either by open-or short-circuiting, harmonic
currents flow in the main field circuit.
These harmonics are reflected into the field circuit of the main exciter
and are detected by a ‘diode failure’ relay tuned to respond to the principal
harmonic frequency; the alarm (or trip) signal from this relay is time-delayed
by 10 or 15 seconds to prevent false operation.
A diode
failure would have no discernible effect, from the consumer’s point of view, on
the generator’s output voltage. The
reduced d.c.
output from the diode bridge with one diode faulty would lower the main field’s
d.c. current
slightly, and with it the main generator’s output voltage. This would be immediately detected by the
AVR, which would increase the excitation until the voltage was restored, and
the consumer would not be aware of it.
However, the remaining healthy diodes might then be somewhat overloaded,
and the situation should be corrected.
With an
open-circuited diode the condition would not be serious. The increase of exciter field current would
be about 15%, which can be
provided by the AVR and carried by the exciter field for some time. Nevertheless, it should be corrected as soon
as possible. A short-circuited diode
however is more severe, calling for a much greater increase of exciter field
current. The AVR and exciter could well
be damaged if this condition were allowed to persist.
It is
usual for the diode failure relay to give an alarm only, not to trip the
breaker and shut down the set. When this
alarm appears, generation should be transferred to another machine as soon as
opportunity offers; the faulty set should then be stopped and the failed diode
replaced. On some sets, however, the
diode failure relay actually trips the set.
CAUTION WHEN MEGGER TESTING A GENERATOR FIELD SYSTEM, ALL DIODES
MUST FIRST BE DISCONNECTED OR SHORT-CIRCUITED TO PREVENT THE MEGGER VOLTAGE
BEING APPLIED ACROSS THEM AND BREAKING THEM DOWN.
3.9 REGULATION RESPONSE TIME
A
further important point resulting from the use of diodes should be noted. When output voltage falls, it is sensed by
the AVR and the exciter field is increased.
The increased exciter output voltage is passed by the diodes to appear
as an increased d.c.
voltage across the main field. This
causes an increase of main field current at a rate depending on the R/L ratio of the whole field/exciter
loop. Therefore the increase is not
instantaneous but, because the exciter resistance is appreciable, R is large enough to allow a reasonably
quick response.
In order
to improve the response time when there is a drop of output voltage, the AVR is
made to give the main exciter field a considerable boost, causing a big jump in
its a.c. output voltage and so a large rise in the d.c. voltage applied through the diodes to
the main field. It helps to overcome the field’s natural sluggishness and to
build it up more quickly. This is known
as ‘field forcing’. When the field has
reached its new value and the output a.c. voltage is restored, the AVR removes
the excess forcing current from the exciter’s field.
However,
if there is an output voltage rise (for example due to the throwing-off of a
large load) it is sensed by the AVR and the exciter field is reduced. The reduced exciter output voltage is now
lower than that of the main field, and it is blocked by the diodes. The main field current, flowing in the highly
inductive field system, ‘flywheels’ round the closed circuit formed by the
field and the diodes. It decays slowly
because it is damped only by the comparatively small resistance of the main
field itself (small R/L ratio, and
therefore longer time constant L/R).
Thus in
a brushless system, whereas the response to a drop in output voltage is
reasonably quick, reaction to a rise is appreciably slower. This is particularly significant after a
short-circuit has been cleared. During
the period of the fault the voltage will have dropped and the AVR will have
forced up the excitation, probably to its limit. When the fault is cleared, this
overexcitation shows as a large overvoltage on the whole system, which is
comparatively slow to recover. This
could involve a risk of burn-out of lamps or delicate apparatus.
3.10 AUTOMATIC VOLTAGE REGULATORS (AVR)
AVRs are
of many different makes, and various types are found on platforms and onshore
installations.
All,
however, have certain features in common when used with brushless
generators. They are nowadays entirely
electronic; they take their operating power from either the main output or the
shaft-driven high-frequency sub-exciter (typically at 400Hz), but they sense
the voltage to be controlled from the output side of the generator before the
circuit-breaker terminals. In
high-voltage generators this sensing circuit is taken through a measuring
voltage transformer of at least Class 0.5 accuracy (see Chapter 4 of the manual
‘Electrical Distribution Equipment, Part B’).
The
detailed electronic circuits are not discussed here, but power from the main
output or the high-frequency sub-exciter is rectified through thyristors, which
are controlled by the voltage-sensing circuits to provide the correct d.c. current to the
field of the main a.c. exciter.
3.11 AVR SET-POINT
Like any
closed-loop servo, an automatic voltage regulating system holds the voltage
constant, within stated errors, at whatever level it has been set. This level is referred to as the ‘set-point’.
In an
electronic AVR the set-point is adjusted by a variable resistance, or rheostat,
in the appropriate part of the circuit.
On some generators this rheostat is outside the AVR proper and is
mounted on the adjacent generator control panel for manual control; it is
usually marked ‘Raise Volts/Lower Volts’.
On other makes of generator it is arranged for remote control from some
distant panel. In such a case the
rheostat is motor-driven, the motor being controlled forward or backward by a
2-way-and-off spring-loaded switch marked as above.
When
used with a single generator the AVR set-point control does indeed regulate the
machine’s voltage output, but when used on a generator running in parallel with
others, the prime function of the AVR control is not so much to regulate
voltage but to adjust the sharing of reactive load between the generators,
despite the marking of the control knob or switch. It does, however, have some effect on voltage
level, but this is only secondary. The
action is fully explained in the manual ‘Electrical System Control’.
3.12 A.C. GENERATOR VOLTAGE REGULATION
When a load is applied to the terminals of a generator previously
running at no load and without AVR control, the terminal voltage will drop by
an amount which depends on the nature of the load. This drop of voltage is called the
‘regulation’ of the generator at that load. It is usually quoted at full rated
load - that is, at the full-load rated current and rated power factor and is
expressed as a percentage of the no-load or system voltage. Thus, if V0
is the no-load voltage and V the
generator terminal voltage at full rated load and power factor and with the
excitation unaltered, then
is the percentage full-load regulation.
In
practice of course the reduced voltage V would
be immediately detected by the AVR, which would increase the excitation until
the terminal voltage was restored to the system value V0 .
The
determination of the generator’s internal voltage drops and their effect on
regulation is covered fully in Chapter 4.
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