CS243799B1 - Connecting a single-phase thyristor control circuit - Google Patents

Abstract

The solution concerns the connection of a single-phase thyristor control circuit to a DC voltage stabilizer. The essence of the connection is that the thyristor control circuit controls a pair of antiparallel thyristors in the primary winding of the transformer in such a way that a drop in voltage at the source output causes an increase in the thyristor opening angle and a rise in voltage at the source output causes a decrease in the thyristor opening angle. Each circuit has its own mains transformer with at least two secondary windings, from which the circuit is powered and the power thyristors are excited. The mains transformer also provides a signal about the phase voltage and creates a signal corresponding to the thyristor opening angle on the controlled active phase-shifting element. These amplified and shaped signals serve to separate output pulses from the auxiliary oscillator, which are used to switch the thyristors via the thyristor excitation circuits. The output voltage of the stabilizer is sensed and fed to the input of the control deviation amplifier, the output of which is controlled by an active, phase-shifting element, while galvanic separation of the control circuits from the stabilizer output circuits is ensured.

Description

243799

BACKGROUND OF THE INVENTION The present invention relates to the connection of a one-phase control circuit of thyristors of one-way voltage thyristors with a pair of antiparallel-connected thyristors in each phase.

To supply unidirectional variable current power circuits supplied from an external power supply grid, the use of a voltage stabilizer is often needed because the voltage at the output of the rectifier bridge varies depending on the current draw and the fluctuating power supply. For example, in electro-spark devices, the fluctuations in the power supply circuitry vary in the magnitude of the energy magnitude of the individual discharge discharges, which ultimately does not adversely affect the equipment's technological characteristics, such as surface roughness after electroprocessing, and the cutting groove width during machining. In addition, changing the width of the groove during machining causes a deviation from the exact cut of the geometrical shape of the workpiece and affects the resulting accuracy of the electro-spark cutting device.

Stabilize the output voltage of the source by controlling the thyristor opening angle in the primary or secondary winding transformer. For higher power supply sources, it is preferable to control the controlled thyristors in the primary winding of the transformer, because in the primary winding the thicker currents and edges of the thyristor opening in the transformer inductance flow to the secondary side are transmitted with a smaller slope. The level of interfering signals from thyristor switching is lower. Currently, several thyristor opening angle controllers are known. The ignition of thyristors can be inferred from the comparison of the amplified control deviation with the waveform of the synchronous sawtooth with the respective phase-patio course. In particular, the three-phase stabilizer on the patio with a pair of antiparallel-connected emitters in each phase of the voltage makes it difficult to set the necessary timing sequences of the ignition pulses for all thyristors. There is no guarantee of reliable operation of these stabilizers in flight distribution systems with higher fire-emitting signals as well as in the source particles of electro-spark machines.

The above-mentioned drawbacks are alleviated by the technical problem of solving the circuitry of a one-phase control of thyristor stabilizer thyristors according to the present invention, the principle of which is that the primary winding of the mains transformer is connected to the voltage stabilizer input terminals and the secondary transformer winding connected to power diode anodes. Both ends of the secondary winding are bridged by a series engagement resistor and an active phase shift cell. The end of the second secondary winding is connected to the input of the second phase signal amplifier and shaping circuit, and the common sensing resistance node and the active phase of the receiving cell is connected to the input of the first phase signal amplifier and shaping circuit. a resistance parallel to the cathodes of the power diodes, to the input of the first circuit of the thyristor and to the first of the first diode. The indirect outputs of the amplifier and shaping circuits are connected via a second resistor parallel to the cathode power diodes, to the input of the second circuit of the thyristors, and to the anode of the second bag diode. Cathodes of bag diodes parallel to the output of an auxiliary oscillator. The first output of the first thyristor drive circuit is coupled to the first thyristor and to the second thyristor and simultaneously to the first input of the single-phase power source. The second output of the first thyristor drive circuit is connected to a control electrode of the first thyristor. The first output of the second circuit of the thyristor is connected to the cathode of the second thyristor and to the anode of the first thyristor and simultaneously to the input terminal U of the stabilizer. The second output of the second circuit of the thyristor is connected to the control electrode of the second thyristor. The second input of the single-phase power supply is connected to the input terminal N of the voltage stabilizer. The first output of the single-phase power supply is connected to the inverting input of the amplification-control deviation, its non-inverting input being connected to the terminal Ur of the power-supply voltage and its output connected to the input of the active phase of the power-supply element. It is also inherent in the fact that the active phasing element is formed by serial connection of a capacitor with a phototransistor connected in the diode bridge such that the phototransistor co-connector is connected to the cathode and second diodes in the bridge. The photo-transistor emitter is connected to the third and fourth diode anodes in the bridge. The advantages of connecting a single-phase thyristor control circuit of a one-way voltage stabilizer are the possibility of a complete galvanic separation of the single-phase thyristor control circuit from the voltage stabilizer output controllers and the controllers. Full galvanic separation is preferred for three-phase stabilizers. It allows the coupling of a stabilized source controlled by single-phase control thyristors in series with a non-stabilized voltage source such that the output voltage connection of the stabilized and unstabilized source is stabilized.

243799 is shown in the accompanying drawings

FIG. 1 shows a circuit diagram of the single-phase control of the DC voltage stabilizer circuitry; FIG. 2 shows the waveform of the most important circuit nodes; FIG. for controlling the thyristor three phase unidirectional stabilizer, and FIG. 4 shows the engagement of the active phasing cell.

The connection of the single-phase control circuit of the one-way voltage regulators is realized as follows:

The primary winding 1 of the transformer is connected to the input terminals U, N of the stabilizer, and the secondary windings of the 2, 2 ' transformer with the center 23 are connected to the anodes of the power diodes S, 5 '. Both ends of the secondary windings are bridged by serial connection of the sensing resistor 4 and the active phase-shifting element 3. The end of the second secondary winding 2 * is connected to the input 63 * of the second amplifier attenuator circuit 6 * of the phase signal. 4 and the active phase-shifting element 3 are connected to the input 63 of the first phase signal amplifier attenuator circuit 6. Direct outputs 61, 61 * of the amplifier and shaping circuits 6, 6 * are coupled via a first resistor 7 parallel to the cathode power supply 5, 5 * to the input 93 of the first circuit will be the thyristors 9 and to the anode of the first coefficient of the conductor 0. The two outputs 62, 62 * of the amplifier and shaping circuits 6, 6 'are connected to the power diode 5 via a second resistor 7 *. 5 * to the input 93 * of the second thyristor drive 9 * and to the anode of the second product diode 8 '. The cathodes of the product diodes 8, 8 ' are connected in parallel to the output 133. of the auxiliary oscillator 15. The first output 91 of the first thyristor drive circuit 9 is connected to the cathode of the first thyristor 11 and to the anode of the second thyristor 12 and simultaneously to the first input 131 of the single-phase power source. 13. The second output 92 of the first thyristor excitation circuit 9 is connected to the control thyristor of the first thyristor 11. The first output 91 * of the second thyristor exciter circuit 9 * is connected to the cathode of the second thyristor 12 and to the anode of the first thyristor 11 and simultaneously to the input terminal U of the stabilizer. The second output 92 * of the second thyristor energizer 9 * is connected to the control electrode of the second thyristor 12. The second output 182 of the single-phase power supply 13 is connected to the input terminal N of the voltage stabilizer. The first output 133 of the single phase power source 13 is connected to the inverting input 141 of the control deviation amplifier 14.

The non-inverting input 142 of the amplifier of the control deviation 14 is connected to the terminal

WITH

Ur source. the reference voltage and its output 143 is connected to a control input 31 active phasing element 3 is formed by serial connection of the capacitor 17 with a phototransistor 13 connected in the diode. The phototransistor collector 18 is coupled to the cathodes of the first and second diodes 19,20 in the brass, and the emitter of the phototransistor 18 is connected to the anodes of the third and fourth diodes 21, 16 in the bridge.

The connection of the single-phase controller of the one-way stabilizer stabilizers to the thyristors of the three-phase one-way voltage stabilizer is implemented as follows:

The first power input 101 of the first circuit of the one-phase control of the thyristors 10 is connected to the input terminal U of the stabilizeranaptia. The first power input 101 * of the second single-phase thyristor control circuit 10 * is coupled to the input terminal in the voltage stabilizer. The first power input 191 'of the third circuit of the single-phase controllable transistor 10' is connected to the input terminal V of the voltage stabilizer. The second feeders 102, 102 ', 102 "of the first, second, three-phase control circuit of the 10, 10 * 10" single-phase controllers are connected in parallel to the input terminal N of the voltage stabilizer. The input of pulses 194, 104 *, 104 "of the first, second and third ones the circuits of the single-phase control of thyristors 10, 14, 10 'are connected in parallel to the output 151 of the auxiliary oscillator 15. Control inputs 193, 103 *, 103 'of the first, second and third circuits of the single-phase thyristor control. 10, 10 ', 10 ' are parallel connected to the output 143 of the control deviation amplifier 14, whose non-inverting input142 is connected to terminal Ur of the reference voltage source, and its inverting input 141 is connected to the stabilized output of the three-phase power source. The connection of the other circuits is identical to the connection of a single-phase thyristor control circuit for a single-phase one-way stabilizer.

The signal paths in the most important nodes of the circuit illustrate the function of the connection described, the curve A showing the waveform of the pair of antiparallel connected sensors 11, 12. Curve B - the signal output at the direct output 61 * and the curve B * - the waveform at the indirect output 62 * These signals are formed from the course of the phase voltage on the secondary winding 2 * of the transformer. Curve C - signal transmission on direct output B1 and curve C * - signal waveform on indirect output 62 of amplifier and shaping circuit 6. These signals are formed from an intermittent phase voltage controlled by the active phase-shifting element 3.

Claims (2)

SUBJECT 1. Connection of a single-phase DC voltage thyristor control circuit with a pair of antiparallel connected thyristors at each voltage phase, consisting of a mains transformer with at least two secondary windings, an active phase shifting cell, amplifier and welding circuit, thyristor excitation circuit, amplifier oscillator and amplifier characterized in that the primary winding (1j of the transformer is connected to the input terminals (U, N) of the voltage stabilizer and the secondary windings (2, 2 ') of the transformer with the center (23) are connected to the anode of the power diodes (5); 5 ^! ), Both ends of the secondary winding is bridged by a series connection of the sensing resistor (4) and the active fázuposúvajúceho member (3 '), whereas ¹ the end of the second secondary winding (2') is connected to the input (63 *) of the second repeater and ívarovacieho circuit ( 6 ') and a common sensing resistor node (4) and an active phase-shifting cell (3) is connected to the input (63) of the first amplification and shaping circuit (6), the direct outputs (61, 61 *) of both amplification and shaping circuits (6). , ^6:) is via a first resistor (7) connected parallel to the diodes of the cathode power supply (5, 5'j, the inlet (93] of the first drive circuit of thyristors (9) and the anode of first] aND circuit diode (8), wherein the outputs of the indirect ( 62, 62 ') of the amplifier and shaping circuits (6, 6') are connected in parallel through the second resistor (7 ') to the cathodes of the power diodes (5, 5'), the input (93 ') of the second thyristor excitation circuit (9'); to the anode of the second product diode (8 '), wherein the product diodes (8, 8 ') are connected in parallel to the output (151) of the auxiliary oscillator (15), the first output (91) of the first thyristor excitation circuit (9) is connected to the cathode of the first thyristor (11i) ) and also to the first input (131) single-phase power supply (13), wherein the second outlet (92) of the first drive circuit of thyristors (9) is connected to the control electrode of the first thyristor (11), a first outlet ^(91:) of the second drive circuit of thyristors (9 ') is connected to the cathode of the second thyristor (12) and the anode of the first thyristor (11) and simultaneously to the input terminal (U) of the voltage stabilizer, the second output (92') of the second thyristor excitation circuit (9 ') the second thyristor control electrode (12), the second input (132) of the disposable power supply (13) is connected to the input terminal (N) of the voltage stabilizer, the first output (133) of the single-phase power supply (13) is connected to inverting the control deviation amplifier input (141), wherein its non-inverting input (142) is connected to the reference voltage source terminal (U _r ) and its output (143) is connected to the control input (31) of the active phase shifting cell (3). Circuit connection according to Claim 1, characterized in that the active phase-shifting element (3) consists of a series connection of a capacitor (17) with a phototransistor (18) connected in the diode bridge so that the phototransistor collector (18) is connected to the cathodes of the first. a. a second diode (19, 20) in the bridge and a phototransistor emitter (18) is connected to the analogs of the third and fourth diodes (21, 22) in the bridge.