FAULT CALCULATIONS AND STABILITY STUDIES     273

              for economic or technical reasons, a choice of MCC ratings may become critically dependent on
              fault ratings. In such a situation, the resistances and reactances of the LV components should be
              used in the fault calculations.
           c) When designing modifications or uprated systems it is essential that both the resistances and reac-
              tances of the LV components are used in the fault calculations, otherwise the existing equipment
              might be exposed to fault currents higher than expected and a dangerous situation could ensue.
              This is particularly the case when the HV system is being uprated, e.g. by adding more generators
              or transformers, and it is too easy to ignore the effects on the LV part of the system. Uprated
              system design can be more difficult in practice than new system design.
           d) Fault currents can be contributed by LV generators and LV motors and so care must be taken to
              allow for this possibility. This subject will be discussed in detail in later pages.


           11.4 NON-CONSTANT VOLTAGE SOURCES – ALL VOLTAGE LEVELS

           So far it has been assumed that the source impedance and the source voltage remain constant during a
           fault situation. This is the case for power systems that do not contain rotating machines, i.e. generators
           and motors. Motors, and especially generators, exhibit peculiar reactance and voltage characteristics
           during fault situations and these are generally grouped into three types:-

           • Sub-transient effects.
           • Transient effects.
           • Steady state (or synchronous) effects.


                 For installations that have self-contained power generation plants, e.g. offshore platforms and
           onshore gathering stations, proper allowance must be made for the presence of generators and motors,
           especially at the generator switchboard. This subject is a complicated one and so it is now necessary
           to give due attention to the design and dynamic characteristics of firstly the generators and secondly
           the motors.
                 A synchronous generator (and a synchronous motor) can be represented by many induc-
           tances and reactances to account for transformer-type induction, rotational induction, mutual coupling
           between windings, leakage and self-induction, magnetising and excitation induction and the effects
           of the pole-face damper windings. Extremely complex equivalent circuits have been developed for
           synchronous machines, see References 1 and 2 as examples.
                 For most hand calculations in power systems, only three of the generator reactances are of
           particular interest:


           • The sub-transient reactance X .
                                      d

           • The transient reactance X .
                                   d
           • The synchronous reactance X sd .
           The suffix ‘d’ relates to the ‘direct axis’ values, i.e. those that can be represented along the pole axis
           of the excitation winding. Occasionally, the ‘quadrature axis’ reactances are encountered and these are
           denoted by the suffix ‘q’. See Chapter 3 for a further discussion of the ‘d’and ‘q’ axis parameters.