CS243799B1 - Thyristors' single-phase control circuit connection - Google Patents

Abstract

The solution concerns the connection of a single-phase circuit thyristor stabilizer control unidirectional strains. The essence of engagement lies in the fact that the circuit thyristor control is a controlled pair antiparamounted thyristors in the primary winding transformer so that drop the voltage at the output of the source causes an overload thyristor opening angle and tension rise at the output of the source causes an angle reduction opening thyristors. Each circuit has its own mains transformer with at least two secondary the windings from which it is secured circuit power and power thyristor excitation. In addition, a network transformer providing a signal of phase voltage progress and on controlled active phase shifting the cell generates a corresponding signal thyristor opening angle. These amplified and the shaped signals serve for decoupling output pulses from the auxiliary oscillator, through thyristor excitation circuits they switch thyristors. Output voltage the stabilizer is sensed and inputted of the control deviation amplifier, the output of which directs an active, phasing article while galvanic separation is provided control circuits from the output circuits stabilizer.

Description

The invention relates to a circuit of a single-phase control of thyristors of a DC voltage stabilizer with a pair of antiparallel connected thyristors at each voltage phase.

A voltage stabilizer is often required for supplying variable-voltage DC power circuits supplied from an external grid with fluctuating voltage, since the voltage at the output of the rectifier bridge fluctuates depending on the current consumption and the fluctuation of the line voltage. For example, in spark-erosion devices, fluctuations in the power supply voltage of the power circuits result in fluctuations in the amount of energy of the individual discharge discharges, which ultimately adversely affects the technological characteristics of the device, such as surface roughness after electro-discharge machining. In particular, the variation in the width of the cutting groove during machining causes an increase in deviation from accurate cutting of the geometrical shape of the workpiece and affects the resulting accuracy of the electro-spark cutting machine.

The output voltage of the power supply can be stabilized by controlling the opening angle of the thyristors in the primary or secondary winding of the transformer. For higher power supply sources, it is preferable to control the controlled thyristors in the primary winding of the transformer, because smaller currents flow in the primary winding and the edges of the opening of the thyristors are transmitted with less steepness in the transformer inductance to the secondary side. The level of interference signals from thyristor switching is lower.

Several methods of controlling the opening angle of thyristors are currently known. The moment of ignition of the thyristors can be derived from a comparison of the amplified regulation deviation with the course of the saw voltage synchronous with the corresponding course of the phase voltage. Especially with a three-phase voltage stabilizer with a pair of anti-parallel-connected thyristors in each voltage phase, it is difficult to set the exact timing sequence of ignition pulses required for all thyristors. Some circuits bypass the setting of the ignition pulse sequence by triggering self-oscillating oscillators throughout the time, corresponding to the opening angle of the thyristors. Reliable operation of these voltage stabilizers is not guaranteed in power distribution systems with a higher level of disturbance signals as well as in the source part of electric spark machines.

The above-mentioned drawbacks are alleviated and the technical problem is solved by the connection of a single-phase control circuit of a DC voltage thyristor according to the present invention, which is that the primary winding of the mains transformer is connected to the input terminals of the voltage stabilizer. diodes. Both ends of the secondary windings are bridged by the series connection of the sensing resistor and the active phase-shifting cell. The end of the second secondary winding is connected to the input of the second amplification and shaping circuit of the phase signal and the common node of the sensing resistor and the active phase shifting cell is connected to the input of the first amplifying and shaping circuit of the phase signal. The direct outputs of the amplifier and shaping circuits are connected via a first resistor in parallel to the cathodes of the power diodes, to the input of the first thyristor excitation circuit, and to the anode of the first product diode. The indirect outputs of the amplifier and shaping circuits are connected via a second resistor in parallel to the cathodes of the power diodes, to the input of the second thyristor excitation circuit, and to the anode of the second product diode. The product diode cathodes are connected in parallel to the output of the auxiliary oscillator. The first output of the first thyristor excitation circuit is coupled to the cathode of the first thyristor and the anode of the second thyristor, and simultaneously to the first input of a single-phase power source. The second output of the first thyristor excitation circuit is connected to the control electrode of the first thyristor. The first output of the second thyristor excitation circuit 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 voltage stabilizer. The second output of the second thyristor excitation circuit 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 control deviation amplifier, its non-inverting input being connected to the terminal U _{r of} the reference voltage source and its output being connected to the input of the active phase shifting cell. It is also essential that the active phase-shifting cell is formed by the series connection of a capacitor with a phototransistor connected in the diode bridge so that the phototransistor collector is connected to the cathodes of the first and second diodes in the bridge. The phototransistor emitter is connected to the anodes of the third and fourth diodes in the bridge.

The advantages of connecting the unidirectional voltage stabilizer single-phase control circuit are the possibility of completely galvanic separation of the single-phase thyristor control circuit from both the voltage stabilizer output terminals and the controlled thyristors. Full galvanic separation is advantageous, in particular with a three-phase voltage stabilizer. It allows to connect a stabilized power supply controlled by single-phase thyristor control circuits in series with a non-stabilized power supply so that the output voltage of the series connection of the stabilized and unstabilized power supply is stabilized.

It is drawn on the attached drawings

243793 circuit of a single-phase control of a DC voltage thyristor where FIG. 1 is a block diagram of a single-phase control circuit of a DC voltage thyristor; FIG. 2 shows the waveforms of the most important nodes of the circuit; FIG. 3 shows a single-phase thyristor control circuit connected to control the thyristors of a three-phase DC voltage stabilizer; and FIG. 4 shows the engagement of an active feed cell.

The connection of the single-phase control circuit of the DC voltage thyristors is realized as follows:

The primary winding 1 of the transformer is connected to the input terminals U, N of the voltage stabilizer, and the secondary windings 2, 2 2 of the 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 the series connection of the sensing resistor 4 and the active downstream cell 3. The end of the second secondary winding 2 * is connected to the input 63 * of the second amplification and shaping circuit 6 * of the phase signal. A common node of the sensor resistor 4 and of the active sliding cell 3 is connected to the input 63 of the first amplification and shaping circuit 6 of the phase signal. The direct outputs 61, 61 * of the amplifying and shaping circuits 6, 6 * are connected via a first resistor 7 in parallel to the cathodes of the power diodes 5, 5 * to the input 93 of the first thyristor excitation circuit 9 and to the anode of the first product diode 0. * the amplification and shaping circuits 6, 6 'are connected via a second resistor 7 * in parallel to the power supply cathodes 5, 5 * to the input 93 * of the second excitation circuit of the thyristors 9 * and to the anode of the second product diode 8'. The dry diode cathodes 8, 8 * are connected in parallel to the output 131 of the auxiliary oscillator 15. The first output 31 of the first thyristor excitation circuit 9 is connected to the cathode of the first thyristor 11 and to the anode of the second thyristor 12. the output 92 of the first thyristor excitation circuit 9 is connected to the control electrode of the first thyristor 11. The first output 91 * of the second thyristor excitation circuit 9 * is connected to the cathode of the second thyristor 12 and the anode of the first thyristor 11. The second output 92 * of the second thyristor excitation circuit 9 * is connected to the control electrode of the second thyristor 12. The second input 182 of the single-phase power source 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 control deviation amplifier input 142 is connected to the terminal

WITH

At the reference voltage source _r and its output 143 is connected to the control input 31 of the active phase, the shifting cell 3 consists of a series connection of a capacitor 17 with a phototransistor 18 connected in the diode bridge. The collector of the phototransistor 18 is connected to the cathodes of the first and second diodes 19, 20 in the bridge and the emitter of the phototransistor 18 is connected to the anodes of the third and fourth diodes 21, 22 in the bridge.

The connection of the unidirectional voltage stabilizer single-phase control circuit for the control of the three-phase unidirectional voltage stabilizer is realized as follows:

The first power input 101 of the first circuit of the single-phase thyristor control 10 is connected to the input terminal U of the voltage stabilizer. The first power input 101 * of the second circuit of the single-phase thyristor control 10 * is connected to the input terminal V of the voltage stabilizer. The first power input 101 "of the third circuit of the single-phase control of thyristors 10 * is connected to the input terminal V of the voltage stabilizer. The second power inputs 102, 102 ', 102 "of the first, second and third circuits of the single-phase control of thyristors 10, 10 * 10" are connected in parallel to the input terminal N of the voltage stabilizer. Pulse inputs 194, 104 *, 104 “of the first, second and third circuits of single-phase control of thyristors 10, 1 , ⁴ , 10“ are connected in parallel to output 151 of the auxiliary oscillator 15, control inputs 153, 103 *, 103 “of the first, second and third circuits single-phase control of thyristors. 10, 10 ', 10 "are connected in parallel to output 143 of control amplifier 14 whose non-inverting input 142 is connected to terminal U _{r of} the reference voltage source and its inverting input 141 is connected to stabilized output 181 of three-phase power source 16. is the same as the one-phase thyristor control circuit for a single-phase DC voltage stabilizer.

The waveforms at the most important nodes of the circuit illustrate the function of the circuit described, with curve A showing the voltage waveform on a pair of antiparallel connected thyristors 11, 12. Curve B - waveform on direct output S1 * and curve B * - waveform on indirect output 62 * amplifier and the forming circuit 6 *. These signals are formed from the phase voltage on the secondary winding of the 2 * ground transformer. Curve C - waveform of direct output B1 and curve C * - waveform of indirect output 62 of amplifier and shaping circuit 6. These signals are formed from the phase shifted voltage, which is controlled by the active phase shifting cell 3. Curve D - output pulses 151 by means of an oscillator 15. Curve E - pulse time story at input 93 of the thyristor excitation circuit 9, which is formed by the logical product of signals B, C and D, while representing the waveform of thyristor drive pulses 11. Curve E '- pulse time at input 93 'of the thyristor excitation circuit 9', which is formed by the logic product of the signals B ^! , C * and D, and at the same time represents the course of the thyristor drive pulses 12.

By connecting the unidirectional voltage stabilizer thyristor control circuit, the opening angle and the pair of antiparallel connected thyristors in the transformer primary winding are controlled so that a rise in voltage at the output of the unidirectional source causes a decrease in the opening angle and thyristors.

Each unidirectional stabilizer thyristor single-phase control circuit has its own mains transformer with primary winding 1 and at least two secondary windings 2, 2 'of which provide power to the single-phase thyristor control circuit itself and drive thyristors 11, 12 with cathodes of power diodes 5, 5 are the positive pole of the power supply and the center 23 of the secondary windings 2, 2 'of the transformer is the negative field of the power supply. In addition, the mains transformer provides a phase voltage signal which is processed by the amplifier circuit 6 *. The amplification and welding circuit output signals 6 ‘have waveforms according to curves B and B‘, with the direct output signal 61 ‘having a waveform of curve B and an indirect output signal B2‘ having a waveform of curve B ‘.

On the active phase-shifting cell 3, a phase-shifted signal is generated via the sensing resistor 4, which is processed by the amplification and shaping circuit S. The output signals of the amplifying and welding circuit β have waveforms according to curves C and C '. and the signal from indirect output 62 is according to curve C *. The logic product of the output signals B and C at the direct outputs 61, B1 'with the pulses supplied from the auxiliary oscillator 15 according to curve D produces the excitation signal for the thyristor 11 according to curve E. The excitation signal of the thyristor 11 is amplified by the excitation circuit. which directly provides opening of the thyristor 11. The logic product of the output signals B * and G 'on the indirect outputs 62, 62' with pulses supplied from the auxiliary oscillator according to curve D generates an excitation signal for the thyristor 12 according to curve E '. The thyristor excitation signal 12 is amplified by a thyristor excitation circuit 9 ‘, which immediately opens the thyristor 1,2. By shifting the signals according to curves B and C, B * and C * relative to each other, the opening angle and the thyristors 11, 12 change. The relative shifting of signals B and C, B * and C * relative to each other is controlled by controlling the active phase shifting cell 3.

The voltage drop at the output of the single-phase power source 13 is amplified by a control deviation amplifier 14 which, by acting on the active phase-shifting cell 3, reduces the offset relative to one another for the signals B and C, B * and C 'thereby increasing the opening angle and thyristors 11, 12. The voltage rise at the output of the single-phase power source 13 is amplified by a control deviation amplifier 14 which, by acting on the active phase-shifting cell 3, increases the relative displacement of signals B and C, B * and C 'relative to each other thereby reducing the opening angle and thyristors 11, 12. The active phase-shifting cell 3 realized by series connection of capacitor 17 and phototransistor 18 in bridge connection with diodes 19, 20, 21, 22 allows galvanic separation of single-phase control of thyristors from output voltage stabilizer terminals.

In the three-phase DC voltage stabilizer connection, the operation of the connected single-phase thyristor control circuit in each phase is the same as that of the single-phase DC voltage stabilizer.

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.