SU817975A1 - Thyristorized converter control device - Google Patents

Description

one

The invention relates to electrical engineering and is intended to control thyristor AC converters with forced pulse switching.

A device for controlling an AC thyristor converter is known, comprising a synchronization unit, control phase control elements, intermediate and amplifying elements, and transformer output stages 1.

The mode of operation of the load provided by this control is characterized by a low value of the power factor.

The closest to the proposed invention is a device for controlling an thyristor AC converter with forced pulse switching, comprising a voltage transformer, a synchronization unit, positive and negative half-voltage supply drivers of a supply voltage, a logic unit, a preprocessing driver, and a switching phase regulator of the first bridge , phase switch on control of the second bridge, phase switch off of one of the bridges, start start trigger, controls, Pulse enable and disable pulse drivers and control pulse amplifiers connected via output transformers to the control inputs of an AC thyristor converter 2.

The disadvantage of the device is a low power factor load.

The purpose of the invention is to increase the power factor of the load and reduce the effects on communication lines with varying parameters of the supply network.

This goal is achieved by the fact that the known device for controlling an thyristor AC converter is equipped with a derivative of current in the secondary winding of the transformer, a trigger for measuring the time interval between the first and second bridge, a capacitor, a charge amplifier with a decoupling diode, a discharge amplifier with a deflecting diode, a driver for the range of varying the phase of switching on the first bridge for a positive half-wave, a driver for the range of changing the phase of switching on of the first bridge for the negative half-wave, formers of the beginning of the first bridge off zone for the positive and negative half-wave, formers of the range of variation of the switching phase of the first bridge for the positive and for the negative half-wave of the supply voltage, additional regulator of the turn-on phase of the second bridge, preparatory pulse generator regulators of the phase of switching on of the second bridge and the pulse shaper of the preparation of regulators. the phase cutoff of the first bridge, whereby the driver of preparation of the turn-on phase regulator of the second bridge is connected to the output of the turn-on phase controller of the first bridge, and the output is connected to the input of the charge amplifier and to the inputs of the Ignition and Starting of both controllers of the second bridge, the output of the additional phase controller of the second bridge is connected to the input of the pulse generator of the second bridge, the control input is connected to the output of the sensor derived from the current i5o of the secondary winding of the transformer, The trigger for measuring the time interval between switching on the first and second bridge inputs is connected to the outputs of the switching amplifiers of the first and second bridges, and the output through the discharge amplifier and the diode to the negative capacitor plate connected to the control input of the first bridge switching phase regulator and through the diode to to the output of the charge amplifier, the pulse former of the preparation of the off phase controller for the first bridge is connected to the inputs of the “Recharge and start up of the off phase controller of the first bridge”, and the inputs through the The controllers for the changeover phases of the first bridge, connected by outputs to the inputs of the logic unit, and through the formers of the start of the first bridge deactivation zones are connected to the outputs of the synchronization trigger, the formers of the switching intervals of the first bridge for the positive and negative half of the inputs are connected to the outputs of the positive and negative formers half-voltages, and outputs to the inputs of the logic unit. FIG. 1 shows a circuit diagram of the device; in fig. 2 is a diagram of a known thyristor converter controlled by the device; in fig. 8Time diagram of the device.

The device (Fig. 1) contains a transformer 1 voltage, connected by the primary winding to the supply voltage, and the secondary one - to the synchronization block 2, synchronization trigger 3, outputs connected to the positive half-wave former 4 and to the driver 5

The device works as follows.

In the initial state, the supply voltage to the device is applied, the primary winding of the transformer 1 is connected to the transfer voltage supplied to the motors through the thyristor converter. ahead of the negative half-wave, shaper b of preparation pulses, phase shift controller 7 of the first bridge, phase shifter 8 of the turn-on phase variation of the first bridge for a positive half wave, phase shift generator 9 of the first bridge's phase shift change for a negative half-wave, trigger trigger 10, control preparation pulse shaper 11 the torus 12 of the turn-on phase of the second bridge and the regulator 13 of the turn-on phase of the second bridge, the launch control unit 14, the driver of 15 switching-on pulses of the first bridge, the driver 16 turn-on pulses of the second bridge, switch 17, pin 18 for connecting the positive pole of the power source, shaper 19 and shaper 20 of the first turn-off zone of the first bridge, respectively, for a positive and negative voltage half-wave, shaper 21 and shaper 22 of the range of switching off the first bridge phase for positive and negative voltage half-wave, shaper 23 preparatory pulses of the off phase controller 24 of the first bridge, shaper 25 of the shutdown pulses of the first bridge, a magic unit 26, consisting of elements I 27-32 connected to the ten inputs of the unit and outputs connected to the inputs of amplifiers 33 -38 of switching-on power thyristors of the converter, charge amplifier 39 connected through a separate diode 40 k the capacitor 41 and the input U of the controller 24 and through the separating diode 42 to the output of the amplifier 43 bits connected by its input to the output of the trigger 44 measuring the time interval between the first and second bridges, and the inputs of the trigger 44 are connected to the outputs of the drivers 15 and 16. Date chick 45 derived from the current in the secondary winding of the transformer 46 (see FIG. 2) is connected by an output to the input U, the regulator 13 of the turn-on phase of the second bridge. Capacitor 47 is connected to the transformer 46 secondary winding pins, to which semi-controlled rectifier bridges 48, 49, consisting of diodes 50-53, and thyristor switches 54-57, which can be turned on and forcibly turned off at any moment of the corresponding half-wave, are also connected. power supply sinusoids. To the outputs of bridges through reactors 58, 59, DC motors are connected with windings of the cores 60, 61 and excitations 62, 63.

the switch 17 is closed, the potential from pin 18 is fed to the trigger trigger input 10 and to the corresponding input of logic unit 26, all elements AND 27-32 are locked, there are no pulses at the outputs of amplifiers 33-38, keys 54-57- are off, current in engines x is zero.

When the switch 17 is opened, the prohibition is removed from the input of the trigger 10, however, a positive potential remains at its output and the logic block 26 is locked.

At each transition of a sinusoidal voltage across zero (see Fig. 3), short pulses are sent from synchronization unit 2 to different inputs of synchronization trigger 3, switching it to different positions. Potentials from trigger outputs 3 are fed to inputs of logic unit 26, which synchronize off the second bridge . The concept of the second and first bridge can refer both to bridge 48 and to bridge 49 and only means the turn-on sequence. Simultaneously with the positive edges of the trigger signals 3, the formers 4 and 5 are switched, forming negative pulses with a width of approximately 170 e. hail. On the positive edges of signals 4 and 5, respectively, the formers 8 and 9 of the switching range of the switching on phase of the first bridge are triggered, while providing negative signals at the inputs of the And 27, 30 elements of the logic unit 26, which synchronize the switching on of the first bridge. Receiving these negative pulses using shapers allows you to eliminate spurious switch on converter keys, which are possible during synchronization from a trigger, because a trigger in the absence of synchronizing voltage constantly sends resolution to one of its outputs to logic unit 26, which can cause a failure synchronization during voltage recovery. The formers 8 and 9, when there is no synchronization voltage, produce positive potentials at the outputs simultaneously, and when power is restored, only the corresponding half-wave converter is triggered.

Shaper 6. training pulses also triggers on the positive fronts of signals 4, 5 and generates short pulses that switch start trigger 10 to a position at which there is a negative potential at its output, allowing the operation of block 26 and, entering input , they switch the trigger to a position with a negative potential at the output, and through the start input provide the discharge of a capacitor in the sawtooth generator. With the appearance of a positive front in signal 6, the timing of regulator 7 begins, the duration of which is determined by the level of the voltage applied to the input of CC. from the launch control unit 14. The rate of change of this voltage determines the start rate and can be set manually or automatically. At the time when the sawtooth voltage is equal to the voltage Ut, the regulator 7 is triggered, the signal changes to a positive one, this ensures that the formers 15 and 11 trigger. A short negative impulse 15 goes to elements 27 and 30. The negative potentials coincide at a positive half-wave element 27 (negative 30), the amplifier 33 (36) triggers and sends a signal to the main thyristor of the key 56 (57), the bridge 48 is turned on. The motor current until the moment of switching on the first bridge closes through diodes 50, 51. After switching on the key 56, a transient oscillatory process occurs with an amplitude equal to half the rectified current, and the current in the transformer winding rises from an insignificant capacitance along the curve i .. At this time, driver 11 The preparation pulses give a negative potential at the output, which has already been triggered by the triggers of the regulators 12 and 13, has depleted their capacitors, but the start-up of the regulators is specifically delayed to prevent the early switching on in orogo bridge from the regulator 13 is triggered at equality of di / dt in the winding of the transformer 46 to zero, since prior to actuation of the first bridge is derived from the current, assuring EMA unit 45 is close to zero.

When the current in the winding of the transformer 46 reaches an amplitude value, which corresponds to the equality of the rectified current, the signal 45 approaches zero, the regulator 13 operates. And through the driver 16, through element 28 (31), through amplifier 34 (37), turns on the key 54 (55). At this moment, the oscillating process in the power circuit is terminated, since the instantaneous value of the oscillation current was equal to the rectified current in. two engines

Claims (2)

Under actual conditions, the form of the current in the transformer winding is influenced not only by the processes occurring on the side of its secondary winding, but also externally through a voltage in the supply network. Therefore, a random value of the derivative, equal to zero, may occur earlier than the moment of occurrence of the amplitude value of the current in the oscillator circuit of the converter, or this moment may be shifted to the side of lag. In addition, at low load currents, derivative sensor 45 outputs a small signal in which it is difficult to catch the difference between maximum and minimum and regulator 13 may fail to turn on the second bridge. To eliminate this phenomenon, the controller 12 is set to the maximum possible value of the time delay in this network, corresponding to the lowest possible frequency of the oscillatory process in the power circuit. If regulator 13 does not give a signal for the maximum time, regulator 12 will do this. Thus, newly installed blocks 11, 13, 45 and block 12 set to the maximum shutter speed prevent a gross deviation of the moment of switching on of the second bridge from the norm. The imaging unit 11 provides the minimum shutter speed, the regulator 13 performs automatic activation at the moment corresponding to the optimum, and the regulator 12 does not allow the deviation of the moment of switching on of the second bridge to be the maximum possible. When changing the oscillation frequency in the power circuit, it is necessary to change the phase off of the first bridge. It is most expedient to extinguish the current in the winding of the transformer by the time the voltage sine wave passes through zero, for this the switching off impulse of the first bridge should automatically be set to the advance time of the voltage equal to the time between switching on the first and second bridge. For this, the device is equipped with elements 3;) - 44. The negative voltage pulse at the output of the formers 1 of the amplifier 39 is amplified, and through the diode 40 the condenser 41 begins to charge. At the same time as the pulse from the driver 15, the trigger switches to a position where a negative potential is present at its output, the amplifier turns on the capacitor discharge circuit, but since the charge time constant is significantly less than the discharge time constant, the capacitor is charged almost instantly to the voltage level nutrition Simultaneously with the positive front of the pulse 11, the charging circuit is disconnected, and the discharge continues until a negative pulse appears at the output of the driver 16. Depending on the length of the time interval until the second bridge is turned on, a voltage level is established on the capacitor 41, which determines the dwell time of the regulator the torus 24, and its actuation provides, through the driver 25, element I 29 (32) and amplifier 35 (38), to turn on the auxiliary thyristor of the key 56 (57), i.e. turn off the first bridge, and The starting point is ahead of the voltage sine wave transitioning through zero value for a time equal to the interval between switching on the first and second bridges, which corresponds to the current quenching at the voltage sine wave zero. The variation range of the off phase of the first bridge is set for the positive half wave by shaper 21, the negative potential from which goes to the logic block circuit 29 and the beginning of the zone of changing the off phase of the first bridge is set by the positive edge of the pulse at the output of the shaper 19, to the input of which impulses trigger trigger 3. Automatic tracking of the oscillation process frequency in the power circuit allows you to maintain both a high level of magnitude co5o (and the shape factor kr The inventive device for controlling an AC thyristor converter, comprising a synchronization unit connected via a synchronization trigger to the input of a positive half-wave front supply voltage generator, to the negative half-wave front driver input and to logical inputs the block, the phase controller of the first bridge connected by the inputs "Arming and Start" through the pulse shaper preparation for the outputs f rmirovateley advance the positive and negative half-waves of the supply voltage control input. - to the output of the start control unit, and the output is connected via the driver of switching on the first bridge to the corresponding input of the logic unit, the phase controller of switching on the second bridge, the output connected through the driver of switching on the second bridge to the input of logic unit, the phase controller of the first bridge , the output connected via the driver for switching off the first bridge to the input of the logic unit, the start trigger, all of whose inputs are connected to the output of the preparation pulse generator, and the output is connected to its other input and to the input of the logic unit and is connected via a switch to the output for connecting the positive pole of the power supply; the outputs of the logic unit are connected to the terminals for connecting the control circuits of the power thyristors of the converter, in order to increase power factor load and reduce the effects on communication lines, it is equipped with a sensor derived from the current in the secondary winding of the transformer, trigger measuring the time interval between connecting a first and a second bridge, a capacitor, a charge amplifier with a decoupling diode, a discharge amplifier with a decoupling diode, a shaper of the switching phase variation phase of the first bridge for the positive half-wave, a shaper of the switching frequency phase of switching on the first bridge for the negative half wave, the shaper of the beginning of the zone turning off the first bridge for a positive and negative half-wave. formers of the range of changing the phase of switching off the first bridge for a positive and negative negative power supply, its voltage, an additional phase controller for switching on the second bridge, a driver for preparing secondary controller for switching on the second bridge, and a driver for preparing the phase regulator for switching off the first bridge preparation of the phase controller of the second bridge with the input is connected to the output of the phase controller of the first bridge, and the output is connected to the force input the charge body and with the inputs of the “Arming and Starting” of both controllers for switching on the second bridge, the output of the additional phase control switch for the second switch is connected to the input of the switching pulse generator of the second bridge, and the control input is connected to the output of the sensor derived from the current in the secondary winding of the transformer , the trigger for measuring the time interval between the switching on of the first and second bridge inputs is connected to the outputs of the amplifiers of switching on the first and second bridges, and the output through the discharge amplifier and the diode to a negative switch. A capacitor drive connected to the control input of the turn-on phase controller for the first bridge and through a diode to the output of the charge amplifier, the driver for preparing the switch-off phase controller for the first bridge is connected to the Arming and Starting the Off Bridge Phase Controller inputs, and the inputs through the drivers of the switching phase change ranges of the first bridge, connected by outputs to the inputs of the logic unit, and through the drivers of the beginning of the switching zones of the first bridge connected to the outputs of the synchronization trigger, forming For the positive and negative half-wave inputs, the ranges of the switching phases of the switching-on phase of the first bridge are connected to the outputs of the forward and positive half-voltage drivers and the outputs to the inputs of the logic unit. Sources of information taken into account in the examination 1. Thyristors. Technical reference book ed. V. A. Labuntsova, M., “Energie, 1971, p. 259, rice .. 16-6. 2. USSR author's certificate for application No. 2314486/07, cl. H 02 p 13/16, 1976. lA KSdaCHAMf, SOScnon KSiiOCH k55k SIScnoM W