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88 HANDBOOK OF ELECTRICAL ENGINEERING
more damping feedback will be required. Hence the values of K f and T f 2 will tend towards their
higher values, see Table 4.3.
4.1.4 Main Exciter
The exciter (sometimes called the main exciter) is a synchronous generator that has its stator and rotor
windings inverted. Its field winding is fixed in the stator, and the rotor carries the armature or AC
windings. In addition the rotor carries the semiconductor bridge rectifier that converts the armature
voltages to a two-wire DC voltage system. The AC voltages and currents in the armature are often
alternating at a higher frequency than those in the main generator, e.g. 400 Hz. The higher frequency
improves the speed of response of the exciter. The DC power circuit is coupled to the field of the main
generator by the use of insulated conductors that pass coaxially inside the rotor of the exciter and
the rotor of the main generator. This eliminates the use of slip rings, which were traditionally used
before shaft mounted rectifiers were developed. A slight disadvantage of this technique is that the
derivative feedback cannot be taken from the output of the exciter. However, with modern electronic
devices used throughout the AVR, this can be regarded as an insignificant disadvantage.
The time constant T e of the exciter is mainly related to its field winding.
The saturation block in Figure 4.1 accounts for the magnetic saturation of the iron core of the
exciter, and it is important to represent this because the expected range of the performance of the
exciter is wide. Its terminal voltage may have a value of typically 3.0 per unit when the generator
is fully loaded. This may increase to about 6.5 per unit when the generator needs to maintain a full
short circuit at or near to its terminals. The maximum excitation voltage is called the ‘ceiling voltage’
of the exciter.
4.1.4.1 Pilot exciter
The AVR system requires a source of power for its amplifier, its reference voltage and other electronic
circuits that may be involved e.g. alarms. There are several methods of obtaining this necessary power,
• An external power supply.
• Self-excitation.
• Pilot exciter.
An external supply could be an uninterrupted power supply (UPS) that is dedicated to the
generator. Although this is feasible it is not a method that is used, the main reason being that it
departs from the requirement of self-containment. The equipment involved would require external
cables and switchgear, both of which add a factor of unreliability to the scheme.
The self-excitation method relies upon the residual magnetism in the iron core of the main
generator that remains in the core after the generator is shut down. When the generator is started again
and run up to speed a small emf is generated by the residual magnetism. A special circuit detects
the residual emf at the main terminals and amplifies it to a predetermined level. This amplified
voltage is rendered insensitive to a wide range of emf values and has sufficient power to feed all
the auxiliary requirements of the AVR. The advantage of this method is its low cost compared with
using a pilot exciter. Its main disadvantage is an inferior performance when a short circuit occurs at
or near the main generator. The detected emf, or terminal voltage, when the generator is connected
