RU2321146C2 - Method for controlling a gate-controlled thyristor - Google Patents

Abstract

FIELD: electric engineering, possible use in power supplies based on current inverters for inductive heating plants and for plasma-chemical synthesis of ozone.

SUBSTANCE: method for controlling a gate-controlled thyristor includes alternating injection of opening and closing control current impulses to controlling electrode of gate-controlled thyristor. Anode current of gate-controlled thyristor is measured, current level is set, measured anode current is compared to set current level. Before injecting the closing control impulse into control electrode of gate-controlled thyristor, anode current is reduced to given level of current at given speed by means of opposite discharge of capacitor charged in advance onto gate-controlled thyristor through a throttle. Closing impulses of control current is injected into control electrode of gate-controlled thyristor at the moment when measured anode current is equal to given current level.

EFFECT: increased reliability of operation of gate-controlled thyristor in current inverters.

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Description

The invention relates to electrical engineering and can be used in power sources based on current inverters for installations of induction heating and plasma-chemical synthesis of ozone.

A known method of controlling a two-stage thyristor, which consists in alternately supplying the control electrode with a two-stage thyristor with unlocking and locking control current pulses, simultaneously with the supply of a blocking control current pulse with the control electrode of the two-stage thyristor, interrupts the anode current by locking an additional high-frequency low-voltage transistor connected in series with the two-stage thyristor ( Chin S., Chen D. A GTO circuit using IGT and MOSFET as gate driver // Conf. Rec. IEEE Ind. Appl. Soc. 22 ng Annu. Meet., O ct. 18-23, 1987 .-- New York, 1987 .-- P.483-492).

The disadvantage of the control method of a two-stage thyristor is the low reliability of the two-stage thyristor in current inverters, which is caused by high levels of overvoltage when the device is turned off, technical complexity when using an additional high-frequency low-voltage transistor, significant electrical losses in the structure of a two-stage thyristor when large control current pulses are applied to the control electrode amplitude, the need to use unreliable damps ruyuschih circuits and high-power drivers.

A known method of controlling a two-stage thyristor, which consists in alternately applying to the control electrode of a two-stage thyristor the unlocking and locking pulses of the control current, the unlocking and locking pulses of the control current, has a high slew rate and a value comparable to the anode current of the two-stage thyristor (Voronin P.A. Power semiconductor switches : Families, Characteristics, Application. - M.: Dodeka-XXI Publishing House, 2001. - P.96).

The control method is called hard (HD) control. The disadvantage of the method of controlling a two-stage thyristor is the low reliability of the two-stage thyristor in current inverters, which is caused by high levels of overvoltage when the device is turned off, significant electrical losses in the structure of the two-stage thyristor when large-amplitude control current pulses are applied to the control electrode, and the need to use unreliable damping circuits and drivers high power.

The closest in technical essence to the invention is a method of controlling a two-stage thyristor, which consists in alternately supplying the control electrode of the two-stage thyristor with unlocking and locking control current pulses (Williams B. Power electronics: devices, application, control. Reference manual: Transl. From English - M .: Energoatomizdat, 1983.- P.126).

The known method is considered as a prototype.

The disadvantage of the method of controlling a two-stage thyristor is the low reliability of the two-stage thyristor in current inverters, which is caused by high levels of overvoltage when the device is turned off, significant electrical losses in the structure of the two-stage thyristor when large-amplitude control current pulses are applied to the control electrode, and the need to use unreliable damping circuits and drivers high power.

The invention is aimed at solving the problem of improving the reliability of the dual-operation thyristor in current inverters, which is the purpose of the invention.

This goal is achieved by the fact that in the method of controlling a two-stage thyristor, which consists in alternately supplying control and current pulses of control current to the control electrode of a two-stage thyristor, the anode current of the two-stage thyristor is measured, the current level is set, the measured anode current is compared with a given current level, before applying the blocking current the current pulse of the control to the control electrode of the two-stage thyristor, the anode current is reduced to a given current level at a given speed by meeting compression discharge to dvuhoperatsionny thyristor previously charged capacitor through the inductor, the latch pulse supplied control current to the control electrode of the thyristor at the time dvuhoperatsionnogo equality of the measured anodic current to a predetermined level of current.

A significant difference that characterizes the invention is to increase the reliability of the two-operation thyristor in current inverters by reducing the voltage levels when the device is turned off, reducing switching losses and electrical losses in the structure of the two-operation thyristor when applying blocking current pulses of a lower amplitude to the control electrode, which can be strictly constant, independent of the operating mode of the two-operation thyristor, the exclusion of possible modes of localization of the anode about current in parts of the structure of the device, lowering the temperature of the structure, using more reliable damping circuits and drivers for less power.

Improving the reliability of the dual-operation thyristor in current inverters is the obtained technical result due to new actions, the order of their implementation, that is, the hallmarks of the invention. Thus, the distinguishing features of the inventive current inverter are essential.

Figure 1 shows a diagram of a device for implementing a method of controlling a two-stage thyristor, figure 2 is a timing diagram of the currents of the control electrode of a two-stage thyristor and its anode circuit, explaining the principle of control.

The control method of a two-operation thyristor is implemented by the following actions. The control electrode of the two-stage thyristor is supplied with turn-on and turn-off control current pulses alternately. In this case, the anode current of the two-stage thyristor is measured, the current level is set, the measured anode current is compared with a given current level. Before applying a blocking pulse of the control current to the control electrode of the two-stage thyristor, the anode current is reduced to a predetermined current level at a given speed by counter-discharge to the two-stage thyristor of a pre-charged capacitor through the inductor. A locking impulse of the control current is supplied to the control electrode of the two-stage thyristor at the moment the measured anode current is equal to the given current level.

A device for implementing a method of controlling a two-stage thyristor contains a single-phase bridge connected through four inductors of the filter 1, 2 to four two-stage thyristors 3-6, in the diagonal of the alternating current of which is connected a series circuit containing a reactor 7, a capacitor 8, shunting the output terminals of the device 9, and a second switching the inductor 10, the control unit 11, the terminals of which are connected to the control electrodes of the two-stage thyristors and the terminals of the current sensors 12, 13 included in the anode circuit are two-stage thyristor cathode group of single-phase bridge.

The device operates as follows. The diagonal pairs of the bridge of two-operational thyristors 3, 6 and 4, 5 turn on and off alternately with a frequency equal to the frequency of the output alternating voltage of the device. The device converts the constant voltage of the power source connected to the input terminals "+" "-" of the device into alternating voltage on the load circuit containing the capacitor 8 and inductor 9. The inductors of the filter 1, 2 have an inductive resistance at the frequency of the output voltage of the device, more than three times higher than the equivalent active resistance of the load, which provides practical smoothing of the current through them and the input current of the bridge on two-operational thyristors 3 - 6. The control unit 11 provides the formation and feeding the unlocking and locking control pulses dvuhoperatsionnymi thyristors 3 - 6. The control unit 11 is performed by any of the known circuit inverter control units on dvuhoperatsionnyh thyristors. Electromagnetic processes in each of the half-periods of the output voltage of the device proceed similarly. In this case, identical currents flow through two-operation thyristors of the anode 3, 5 and cathode 4, 6 groups and the same voltages are applied to them, that is, the device circuit has the property of symmetry. To control the levels of the anode currents of two-operation thyristors of the anode 3, 5 and cathode 4, 6 groups, it is enough to measure the anode current of two-operation thyristors of one of the groups. Current sensors 12, 13 are included in the anode circuit of the dual-operation thyristors of the cathode group 4, 6. They can be made on the basis of Hall elements. The implementation of the method of controlling a two-stage thyristor will be considered using the example of switching current with two-stage thyristors 4, 6. By the time the two-stage thyristor 4 is turned on, the capacitor 8 is charged with the polarity shown in the diagram. A current equal to the input current of the device flows through a two-operation thyristor 6. When applying the unlocking control pulse to the two-stage thyristor 4, the capacitor 8 begins to discharge through the chokes 7, 10 to the two-stage thyristor 6 along the chain: 8-7-12-4-6-13-13-10-8. The discharge current of the capacitor 8 is directed opposite the current of the two-stage thyristor 6. As a result, the current of the two-stage thyristor 6 with a given speed determined by the total inductance of the chokes 7, 10 decreases, and the current of the two-stage thyristor 4 increases. The value of the anode current of the two-stage thyristor 6 is continuously measured by the current sensor 13 and is compared with a predetermined current level in the control unit 11. At the moment the measured anode current of the two-stage thyristor 6 is equal to the given current level, a blocking control current pulse is supplied to the control electrode of the two-stage thyristor 6. The two-operation thyristor 6 is turned off. The predetermined current level is selected from the condition of ensuring minimum levels of losses in the structure of devices and switching overvoltages at a given voltage level on the capacitor 8.

In the timing diagrams presented curves control currents i changes _{U6, U4,} respectively dvuhoperatsionnyh i thyristors 6, 4 and the anode current i _A6 dvuhoperatsionnogo 6. thyristor firing pulses positive locking control current pulses of negative control current. At time t ₁ , a trigger pulse of the control current is supplied to the two-stage thyristor 4. The anode current of the two-stage thyristor 6, when the two-stage thyristor 4 is turned on, decreases at a given speed from the nominal I _H to the specified I _M (lower) level. At time t ₂ , a locking pulse of the control current is supplied to the two-stage thyristor 6. At time t _{3, the} anode current of the two-stage thyristor 6 decreases to zero and the thyristor 6 turns off and restores its control properties. In the next half-cycle of the output voltage of the device for dual-operation thyristors 4, 6, the order of switching on and off is reversed. The switching processes of two-operational thyristors 3, 5 occur similarly to processes for two-operational thyristors 4, 6.

Compared with the prototype, the reliability of the dual-operation thyristor in current inverters is significantly increased. By setting a given current level, it is possible to ensure the practical absence of switching overvoltages. Since switching on and off two-operation thyristors is carried out with a given limited rate of change of the anode current, the probability of localizing the current and local overheating of the structure of the device is reduced. At the same time, the levels of the blocking pulses of the control current are reduced, which reduces the loss and temperature of the structure of the device. For the field of application under consideration, the capabilities of the grid protection of the device cannot be used. In this case, the load compensating capacity can serve as a discharge element. Reducing the levels of overvoltage and blocking pulses of the control current allows you to reduce the installed power of the elements of the damper circuits and control drivers. As a result, the reliability of the dual-operation thyristor also increases.

Additionally, the efficiency of converting devices using the inventive method for controlling a two-operational thyristor can be significantly increased by reducing static and dynamic losses in devices, losses in damping circuits and control units of converting devices, the installed power of elements of converting devices when they are sold at a given output power.

Claims (1)

A method for controlling a two-stage thyristor, which consists in alternately supplying control and unlocking pulses of a control current to the control electrode of a two-stage thyristor, characterized in that the anode current of the two-stage thyristor is measured, the current level is set, the measured anode current is compared with a predetermined current level, before applying a blocking control current pulse on the control electrode of a two-stage thyristor, the anode current is reduced to a given current level at a given speed by means of a counter discharge vuhoperatsionny thyristor previously charged capacitor through the inductor, the latch pulse supplied control current to the control electrode of the thyristor at the time dvuhoperatsionnogo equality of the measured anodic current to a predetermined level of current.

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