PROTECTIVE RELAY COORDINATION      323

           unearthed; but in such cases earthing of the power system is provided artificially at the busbars to
           which the generators are connected.
                 The star-point connection to earth is provided with a current transformer and a sensitive relay.
           The relay (5I G) is of a definite time delay or inverse time delay type so that it can be graded as
           back-up protection to earth fault relays at downstream feeders and consumers.
           The choice of the current setting depends upon several factors:-

           • High or low impedance earthing.
           • Level of continuous third harmonic current that will flow in the impedance.
           • Capacitance of downstream feeders, i.e. AC charging current.
           • Earth fault relay settings of downstream relays.
           • Differential current relay (87) settings of the generator.


                 Up until about 1985 it was common practice to limit the fault current in the stator windings
           and neutral earthing resistor to between 50% and 100% of the full-load current. However, there has
           been a move away from choosing such high levels of current and it is not uncommon to choose
           values in the range 20 to 50 amps, and occasionally as low as 10 amps. This later approach is due
           to research by machine manufacturers which has shown that serious burning damage to the iron core
           begins to occur at about 20 amps, see References 2, 5, 6 and 7.
                 The thermal withstand time for the neutral earthing resistors are usually specified as 10 seconds
           for the duration of the fault current. This allows adequate time for main and back-up protection relays
           to operate and clear the fault. The standby earth fault relay (5I G) time-current characteristic must
                               2
           be chosen so that its I t curve is lower than that for the neutral earth resistor and the connecting
                       2
           cables. (The I t curve is derived directly from the I-t data, and not by integrating the curve.)
                 In some generating schemes e.g. drilling rigs, emergency supplies, where the nominal system
           voltage is less than 1000 volts, it is possible to operate them as ‘unearthed’ systems. This occasion-
           ally applies to low-voltage systems, which do not use the neutral as a 4-wire method of supplying
           unbalanced loads (unbalanced loads are taken between the lines, often by using a step-down trans-
           former). However, the normal practice in these schemes is to use an earth leakage detection relay
           which has sensitivity between a few milliamps and 0.5 amp. The relay normally gives an alarm so
           that the operator of the system is aware that a fault is present somewhere in the system, and this
           can then be located at a convenient time. If a second earth fault occurs on a different phase then
           the overcurrent relays will see the fault as a phase-to-phase short circuit and will trip an appropriate
           circuit breaker, or a fuse in the system will operate.


           12.2.7.2 Restricted earth fault relay

           In order to restrict the detection of earth faults to those within the stator winding, and those from the
           stator terminals to the switchgear current transformers, a sensitive relay (64) is used. Three current
           transformers are used in the stator live lines and one in the star to NER connection. All four current
           transformers are connected in parallel such that any unbalance in the currents due to an ‘internal’ fault
           is detected by the restricted earth fault relay (64). A sensitive high impedance relay is used to achieve
           an instantaneous response. However, if a high impedance is connected across a current transformer
           it is possible that very high voltages will appear across the impedance. This is due to the action of