SU1166240A1 - Method of controlling three-phase bridge thyristor converter - Google Patents

Abstract

METHOD FOR CONTROL phase bridge thyristor converters, comprising the steps of: generating sync pulses in phase with the voltage supply and / AA Af6r in a network form and fed to the thyristor converter control pulses, which are shifted in phase relative to the synchronization pulses to the angle defined by A control signal, characterized in that, with the goal of increasing reliability and stability in the operation of the converter in asymmetrical and incomplete-phase supply voltage modes, the synchronization pulses form From each linear voltage of the power supply network at the moment of its transition through zero, phase shift control pulses are generated from the received synchronization pulses, which are connected to the corresponding thyristors, (L connected to the corresponding-: linear voltage. ;: п About г г

Description

one

The invention relates to electrical engineering and can be used to control multiphase thyristor converters.

A known method of controlling a multiphase thyristor converter, according to which, the reference alternating voltage and rectangular symmetric pulses with a period of 240 el form synchronized with the network. grad, compare the reference voltage and rectangular pulses in magnitude and at the moments when they are equal, form control pulses on the anodic and cathodic groups of the thyristors.

Distribute the control pulses between the individual thyristors in the order defined by the connection circuit of the windings of the transformer and the converter bridge L.

The disadvantage of this method is the instability of the converter operation when the AC mains is unbalanced, since the reference AC voltage is the same for all three phases, which implies full three-phase voltage symmetry, the network. In asymmetric modes, the switching times of the thyristors may not coincide with the appearance on them are stresses whose polarity corresponds to their open state. Because of this, misfiring is possible, which can lead to the breakdown of thyristors. This disadvantage is especially pronounced with close short circuits and with breaks in the AC network, when the disappearance of one of the phase voltages of the network is possible.

The closest to the present invention is a method of controlling a three-phase nostatic thyristor converter, which consists of generating synchronization pulses in-phase with the supply voltage of the network, generating and sending to the thyristors of the converter control pulses that are out of phase with respect to the synchronization pulses by the angle determined by the signal management 21.

The known method has the same drawback as the one described, namely, the instability of the operation of the converter during the asymmetry of the AC mains voltage from the fact that the control pulses

402.

fixed one relative to another.

The purpose of the invention is to increase the stability and reliability of the converter, including ensuring stable and reliable operation in asymmetric modes of the AC network, including a partial phase, as well as simplifying the replacement circuit.

The goal is achieved by the fact that according to the method of controlling a three-phase bridge thyristor converter,

concluding that sync pulses are generated in-phase with the mains voltage, control pulses are generated and fed to the thyristors of the converter, phase-shifted relative to the sync pulses by an angle determined by the control signal, the sync pulses are generated from each linear voltage mains power at the time of its transition through zero, from the received synchronization pulses form the phase-shifted control pulses, which are fed to the corresponding .tiors connected to the phase m of the corresponding linear voltage.

FIG. 1 shows a diagram

three-phase thyristor converter; in fig. 2 - control circuit

a converter; in fig. 3 - time diagram of the converter operation with a symmetric voltage of a three-phase network; Fig. 4 is the same when asymmetrical (there is no phase A voltage),

The converter contains six thyristors 1-6 and a load 7 connected to the rectified voltage.

The converter control circuit (Fig. 2) is divided into three identical independent circuits 8-10, each of which controls four thyristors forming a single phase

bridge connected to one of three line voltages. Thus, the control circuit 8 controls the thyristors 4, forming a single-phase bridge connected to the linear voltage U ,, -, the circuit 9 - to the thyristors 3-6 (the bridge connected to the voltage and, the circuit 10 - to the thyristors 1, 2, 5 and 6 (the bridge connected to each of the control circuits 8-10 consists of a pulse shaper 11 and a master unit time 12. The device operates as follows. The control circuits 8-10 are respectively supplied with voltage Ugj, B shaper 11 pulses Ube "c The lined wave sinusoidal is divided into positive and negative half waves, The signals are converted into square-wave pulses of the synchronization voltage. A positive half-wave voltage is converted into a voltage U (Fig. 4), a negative voltage is converted to a voltage V A positive voltage half-wave Ui is negative to a voltage U , the positive semi-voltage wave is voltage, the negative voltage is voltage, and the voltage Uj - Uig is received during driver blocks 12, where the firing angle of the thyristors is set. The timing of the blocks 12 can be executed as timers counting, the time interval t- equal to the ignition angle from the moment of the appearance of transitional fronts of voltage pulses Uj - s.equalities of the driver 11 pulses. At the output of the time of the master blocks 12, short pulses of the voltage Ujg are formed through time i from the moment when the voltage U () - U is appeared at their inputs. Short pulses) - from the outputs, the time for the devices 12 is fed to the control inputs of the thyristors. The time diagram of the operation of the device with a symmetrical three-phase AC voltage and an ignition angle of 90 e. hail shown in FIG. 3. Voltages 11) -U from the outputs of the formers 11 pulses are shifted on the time axis, at equal intervals of time, corresponding to 60 el. hail. Sootverl. As a matter of fact, at the outputs of the time of the driving devices: STS, short pulses of voltages Ujq - Uj ,, are formed. The time intervals between the appearance of which also corresponds to 60 el. hail. During driver 12, short pulses of voltages Uj; are formed in pairs and fed to the control inputs of the thyristors forming the diagonals of the single-phase bridges, i.e. thyristors 1 and 4 are controlled from the positive half-wave voltage, thyristors 2 and 3 are controlled from negative, respectively, from the voltage of thyristor pair Zi6 and 4 and 5, from voltage Uja, thyristor pair 5 and 2, 6 and 1. On load 7, voltage U has a periodic character with a period of 60 e. hail. The device operates similarly with asymmetrical voltages of the AC network. FIG. Figure 4 shows the time diagram of the device operation in the case of an incomplete AC mains mode — Phase A is disconnected. Voltage 1 remains unchanged, and linear voltages iabi are correspondingly wounded (DC voltage is zero). Since the network voltages are asymmetric, the intervals between the occurrence of voltages Uj | - U (j is not equal to 60 zł. Hail. Accordingly, the voltage - Uj also does not appear at regular intervals, and the voltage UT is periodic in nature with a period corresponding to 180 e. Degree. Due to the fact that control pulses are generated not from a single reference voltage, but from independent three, the omission of ignition of thyristors and their overturning in asymmetrical modes is excluded. Thanks to this increase;

Fig 3

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Ua

Uca

Claims (1)

METHOD FOR CONTROL OF A THREE-PHASE BRIDGE THYRISTOR CONVERTER, which consists in generating synchronization pulses in phase with the supply voltage, generating and supplying control pulses to the converter thyristors, which are phase-shifted relative to the synchronization pulses by an angle determined by the control signal, characterized in that In order to increase the reliability and stability in the operation of the converter in unbalanced and non-phase modes of the supply voltage, synchronization pulses are formed from each line At the moment of its transition through zero, from the received synchronization pulses form phase-shifted control pulses, which are fed to the corresponding thyristors connected to the phases corresponding to :. line voltage. Figure 1 1 166240