11




           Fault Calculations and Stability Studies









           11.1 INTRODUCTION
           When a short circuit occurs in a power supply, larger than normal currents are caused to flow into
           the short circuit. The magnitude of the short-circuit current is determined by the impedance of AC
           systems, or the resistance of DC systems, that exists between the short circuit and the sources of
           voltage. That impedance or the resistance will be called the ‘source impedance’ in the discussions
           that follow. In DC systems the source impedance is often the series addition of the supply cable
           resistance, the rectifier or thyristor internal resistance and any other resistance that may be connected
           in the circuit. The calculation of the short-circuit current in a DC circuit is therefore a reasonably
           simple process once the resistance data are known.
                 For AC systems the calculation of the short-circuit current is more complicated, particularly
           when generators and motors are both present in the system. The simplest calculations occur when
           the source of voltage can be assumed to be of constant magnitude during the fault duration. In
           AC systems the source impedance will be the addition of the cable impedance, busbar impedance,
           transformer internal impedance, the appropriate internal impedance of the generator, the appropriate
           internal impedance of the motors in system and the impedance of the overhead transmission lines.
                 The sub-sections that now follow will begin with the simplest situations and end with the
           more complicated.



           11.2 CONSTANT VOLTAGE SOURCE – HIGH VOLTAGE

           A constant voltage source is one in which the voltage that drives the short-circuit current maintains a
           constant magnitude before, during and after the fault occurs. This is usually considered to be the case
           when the source power capacity is very much greater than the normal power rating of the circuit in
           which the fault has occurred. An example of such a situation is shown in Figure 11.1 for an onshore,
           high voltage transmission network.
                 The cables and busbars connecting the transformers to the switchboards are very short in
           comparison with the length of the transmission lines and the transformer reactances and so their
           impedances may be ignored. Consider the fault being applied to the busbars of the T4 switchboard.
           The fault circuit for the switching configuration shown is through T2 and T4.

           The simple series circuit for this configuration is shown in Figure 11.2.

           Handbook of Electrical Engineering: For Practitioners in the Oil, Gas and Petrochemical Industry.  Alan L. Sheldrake
            2003 John Wiley & Sons, Ltd ISBN: 0-471-49631-6