HARMONIC VOLTAGES AND CURRENTS       405

           ‘gate’. It cannot be turned ‘off’ by the control signal. It can only be turned ‘off’ by forcing the
           anode current to zero, which is achieved by a special circuit that is connected across the anode and
           cathode, see References 6 and 9. This was the first type to be developed. In recent years a second
           type has been developed that can be turned ‘off’ by applying a reversed polarity control signal to
           the gate. This device is usually called a ‘gate turn off’ thyristor or GTO. Both devices are either in
           their fully ‘on’ state or their fully ‘off’ state when operating in normal bridge circuits. There is not
           an intermediate state such as found with transistors.
                 Thyristor bridges are used where the DC output voltage needs to be varied. For example for
           control purposes such as varying the speed of motors or for protective purposes such as limiting the
           maximum DC output current that can flow when an external short circuit occurs.
                 The basic circuit of a thyristor bridge is almost the same as that for a diode bridge. The
           essential differences are the replacement of the diode elements by thyristor elements, the inclusion
           of a controlled firing system for the thyristor gates, and in some cases the application of forced
           commutation circuits, see Figure 15.1.


           15.2.2.1 Commutation
           The commutation processes for Mode 1 operation of delay and current transfer are essentially the
           same as the diode bridge, except that the delay angle α is now controlled instead of occurring naturally
                                         ◦
                                 ◦
           and can be extended to 90 from 60 . The current transfer occurs in the same manner and gives rise
           to the same angle u.
                 Control of the triggering pulses to the thyristors needs to be carefully managed when the
           commutation is in Modes 2 and 3, otherwise the operation of the bridge may become unstable, see
           Chapter 7 of Reference 1.
                                                                         ◦
                 The normal control range of the delay angle α is from zero to 90 , over which the average
           DC output voltage decreases from its maximum value to zero. In a good design of the bridge, with
           an appropriate reactance in the supply transformer and enough inductance in the DC load circuit, the
           practical operating region is ensured to be within the Mode 1 operating range. If the load is a motor
           then it will produce an emf that has a magnitude roughly in proportion to the shaft speed. During
           transient disturbances there may be a wide mismatch between the output voltage of the bridge and
           the emf within the motor. The mismatch will cause a large current to flow, e.g. if the motor suddenly
           stalls, which may drive the bridge into a Mode 2 or 3 operation unless the protective control circuits
           rapidly take corrective action to prevent such operation.


           15.2.2.2 Harmonic components
           The shape of the waveform for the AC current in the supply lines to the bridge will be the same
           as that for the diode bridge. Hence the harmonic analysis will yield the same results for practical
           operating conditions. Table 15.2 shows the harmonic components for the range of u between zero
                 ◦
           and 60 . The fundamental component is taken as reference.

           15.2.2.3 Distortion upstream of the bridge
           The installation of a rectifier bridge that has a relatively high power rating with respect to its supply
           will cause significant distortion to the supply line currents and line voltages.