SU904150A1 - Controllable thyristorized ac voltage converter - Google Patents

Description

one

The invention relates to electrical engineering and can be used in devices for phase voltage control of electrical apparatus, electrical machines, resistance furnaces, and the like.

There are regulators that allow phase control of the voltage across the load.

A known AC voltage regulator contains a bridge rectifier, zener diodes, a single junction transistor, auxiliary thyristors, clock and pulse transformers, resistors and capacitors l.

The disadvantages of this regulator are its bulkiness due to the presence of a synchronizing transformer and a small range of regulation.

The closest to the present invention is an adjustable AC voltage thyristor converter containing a thyristor connected in series between a power source and a load, a phase-shifting device made in the form of a parallel-connected trimmer, a chain of a series-connected diode and a capacitor, and a chain of a series-connected zener diode and a second capacitor, with the cathode of the Zener diode connected to the cathode of the diode and through the threshold element connected to the control unit ktrodu thyristor, the total point of the second capacitor and the anode of the diode is connected to one terminal of the power supply, to the second terminal through which a series connection of a second diode and resistor connected point total anode of the zener diode and the first condenser 2.

Claims (2)

This regulator does not allow an alternating voltage on the load, so the range of regulation of its output voltage is limited. The purpose of the invention is to obtain an alternating voltage on the load and expand the range of output voltage control. This goal is achieved by the fact that an adjustable thyristor converter of alternating voltage, containing a thyristor connected in series between a power source and a load, a phase-shifting device made in the form of parallel-connected trimming resistor, is a chain of sequences. but a diode, and a capacitor and a chain of a series-connected zener diode and a second capacitor, the cathode of the zener diode connected to the cathode of the diode and connected through a threshold element to the у control electrode of the thyristor, the common point of the second capacitor and the diode anode is connected to one of the terminals power supply, to the second output of which a common point of the Zener diode and the first capacitor is connected to the second diode and the resistor in series, is equipped with additional phase-shifting devices An additional thyristor and one of the diodes are connected in series with each other and counter-parallel to the main thyristor, while the second additional diode shunts the control electrode and the anode of the additional thyristor, the additional phase-shifting device Zener diode, the threshold element and the diodes are connected in the opposite direction to the main device, and the cathode of the first diode is connected to the control electrode of the additional thyristor, the output threshold Vågå device is connected to the cathode of auxiliary thyristor and the anode of the second diode - to the second power supply you water. The drawing shows the electrical circuit of the proposed device. A single-phase thyristor converter contains a phase-shifting circuit 1, which is formed by parallel-connected chains of series-connected first diode 2 and first capacitor 3, the junction point of which is connected to a threshold element — a dynistor, and a chain of series-connected zener diodes 5 and a second capacitor 6, Anode the zener diode 5 and one plate of the first capacitor 3 are connected via the first resistor 7 to the anode of the second diode 8. The second plates of the above-mentioned capacitors 3 and 6 are connected between themselves, and the second resistor 9 is connected in parallel to both chains. In the additional phase-shifting circuit 10, the zener diode 5, the dynistor C and the diodes 2 and 8 are connected in the direction opposite to the direction in the main circuit. In addition, the converter contains a main thyristor 11, two pins 12 and 13 of the alternating voltage source, an additional thyristor 14 and additional first and second diodes 15 and 16. The load 17 is connected to the anode of the main thyristor 11 and the second output 13 of the alternating voltage source. The cathode of the thyristor 11 is connected to the anode of the first diode 2 and to the first output 12 of the alternating voltage source. The control electrode of the thyristor 11 is connected to the cathode of the dynistor f, and the anode of the thyristor 11 to the cathode of the second diode 8 and the second output 13 of the alternating voltage source. Additional thyristor None of the diodes 15 are connected in series with each other and counter-parallel to the main thyristor 11. The cathode of the first diode 2 of the additional phase-shifting circuit TO is connected to the control electrode of the additional thyristor and through the second additional diode 16 to the first output 12 of the alternating voltage source wives The anode of the dynistor k of the additional phase-shifting circuit 10 is connected to the cathode of the additional thyristor H, and the anode of the second diode 8 of the same circuit is connected to the second terminal 13 of the alternating voltage source. A single-phase thyristor converter operates as follows (its work is considered on the example of the operation of an additional phase-shifting circuit 10, a thyristor H, and two diodes 15 and 16). With a positive voltage half-wave at the second output 13 of the alternating voltage source, the storage capacitor 3 is charged along the circuit: diode 8 - resistor 7 - diode 2 diode 16 - output 12. At this, capacitor 6 is charged with a low voltage the voltage drop across diode 2. The voltage on capacitor 3 is limited by the zener diode 5. The charge on capacitor 3 stops at the time point, KOI- and the voltage on it reaches the stabilization voltage level of the zener diode 5. At that point in time source variable of voltage becomes less than voltage rail or a charged capacitor 3 (is meant a positive half-wave voltage at pin 13), diodes 8, 2 and 16 are closed. From this moment on, capacitor 3 is discharged through variable resistor 9 to capacitor 6, recharging it. Since the voltage on the capacitor 3 is constant and equal to the voltage of the Zener diode 5, the charge of the capacitor 6 does not depend on the fluctuations of the supply voltage and is determined only by the values of the capacitors 3 and 6 and the value of the variable resistor 9 12 and 13 of the alternating voltage source, the diodes 8, 2 and .16 remain closed, therefore, the operation of the phase-shifting circuit 10 does not depend on the voltage of the power source and the state of the power circuit. At a certain point in time (with a positive optimum at pin 12 of the source voltage, the voltage across the capacitor 6 becomes equal to the voltage of the breakdown of the source k, the resistance of the dynistor C drops sharply and the capacitor 6 is discharged through the open distor to the thyristor control transition and the thyristor 1C is applied to a positive half-wave (relative to output 13) of the alternating voltage source, the switching angle of which is controlled by a variable resistor E in the range of 0-180 ° e. hail. The discharge of the capacitor 6 passes until the voltage on it becomes equal to the residual voltage drop across the dynistor k, while the dynistor k is turned off. After that, some charge of the capacitor 6 from the capacitor 3 through the variable 06 resistor 9 occurs again. The capacitance 3 of the capacitor 3 is chosen such that the voltage on the capacitor 6 does not reach the voltage of the dynistor when it is charged again. At the next positive half-wave at the output 13 of the alternating voltage source, the capacitor 6 is recharged to a low voltage due to a direct voltage drop across an open diode 2. Diodes 8 and 16 are opened and capacitor 3 is charged until the voltage of stabilization of Zener diode 5 is completed. Further, the processes described above are repeated. Similar processes occur in the phase-shifting circuit 1, working in conjunction with the main thyristor 11. Additional diodes 15 and 16 uncover phase-shifting circuits 1 and 10. To obtain a symmetric alternating voltage at load 17 with manual control of the trimming resistors 9. Adjusted resistors can be combine into one dual variable resistor, using, for example, resistors type SP-3 and SP-. Photoresistors, resistor optocouplers, and other elements can be used as trim resistors 9. When a converter is operated with low voltages of a power source, phase-shifting circuits can be connected via a step-up transformer (not shown). The proposed converter can be widely used in regulating the voltage on the windings of electrical apparatus, electrical machines, etc. Its use allows one to obtain an alternating voltage on the load, the value of which can be adjusted from zero to the nominal value of the alternating voltage source. Claims of the invention Adjustable thyristor converter of alternating voltage, containing thyristor connected in series between input and output terminals, phase shifting device made in the form of parallel-connected trimming resistor, a chain of a series-connected diode and a capacitor and a chain