SU598209A1 - Pulse phase shifting arrangement for power-diode converter control - Google Patents

Description

(54) DEVICE OF PHASE SHIFT PULSES FOR CONTROLLING THE VENTILATING VENT,

A disadvantage of the known device of the phase shift of pulses is the low control range caused by the presence of a thyristor in the capacitor discharge circuit and low synchronization accuracy associated with the finite value of the thyristor holding current.

The aim of the invention is to expand the adjustment range and increase the synchronization accuracy.

The goal is achieved by the fact that the proposed pulse phase shift device for controlling a valve converter is additionally equipped with a diode-resistor circuit, a decoupling diode and a diode, shuptiyushushh, the time of the driving circuit capacitor, the reference clock source is in the form of a bipolar voltage driver, formed by three parallel branches, each of which contains a winding of a three-phase transformer connected in series in two branches with diodes and in the third with re the source, the common output of the branches is connected with the output by the time of the master resistive-capacitive circuit through a diode-resistor circuit, the midpoint of which is connected to a controllable diode through the isolating diode, the second output of which is connected to the common point-parallel branches and capacitor chains.

FIG. 1 shows a circuit diagram of a device for phase shift of pulses; in fig. 2, a, b, c - diagrams of his work.

The device contains a pulse shaper 1 connected by an input via a control voltage source 2 to a capacitor 3, the master circuit time, the latter connected via a charging resistor 4 to a stabilized voltage source Uc, is bridged by a diode 5 and connected through a series-connected resistor 6 and a diode 7 s the output of the reference clock voltage source, made in the form of a two-pole voltage driver, formed by three branches, each of which contains a winding of 8-10 three-phase transformer - Consequently, connected in two branches with diodes 11, 12 and in the third with a resistor 13, the common output of the branches is connected to the anode of diode 7, the cathode of which is connected via a decoupling diode 14 to a controllable diode — dynistor 15; is connected to the common point of the parallel branches of the source of the synchronizing voltage source and capacitor 3. The switching circuit of the dynistor 15 is connected to the output of the pulse shaper 1. Control voltage source 2 is presented in the form of EMF Uy and internal resistance.

The device operates synchronously with the network voltage. In the initial state, the input of the pulse driver 1 is de-energized.

The source 2 of the control voltage contained in the input circuit of the driver is switched on opposite to the voltage on the capacitor 3 during the driving circuit. The working stroke begins with. the charge of the capacitor 3 through the resistor 4 from the stabilized voltage Ost is determined by the polarity of the reference clock voltage Uon applied to the diode 7.

The negative value of the reference voltage (bold line in the diagram of Fig. 2, a) is formed from the sections of the sinusoid voltage UIT, yat, izt windings 8-10 three-phase transformer. The duration of the negative value of the reference voltage determines the duration of the voltage across the capacitor IJ, having a shape close to linear. From time point to (Fig. 2a, b) Detects a negative value, diode 7 is locked, and the capacitor is charged by UCT. When the voltage on the capacitor Ud reaches a value that is somewhat larger than the control voltage Uy (time t, in Fig. 2 , b) a current flows through the pulse shaper input, ensuring its start. The pulse UBWX, shown at the output of the driver (Fig. 2, c), includes the distor 15.

The dynistor, including, closes the discharge circuit of the capacitor 3. The latter is quickly discharged through the limiting resistor 6 to an insignificant level, and the flow of current through the input of the driver and, therefore, through the source 2 of the control voltage is stopped.

Holding the dynistor in the on state is carried out by the current flowing from the stabilized voltage UCT.

When changing the sign of the reference voltage Uon (time point ta in Fig. 2, a), associated with a change in the sign of the voltage UST of the transformer 10 winding, the capacitor discharges to zero level. When current flows from the UST voltage along the circuit: resistor 13 — diode 7 — resistor 6 — diode 5 — winding 10 to the series-connected decoupling diode 14 and to the dynistor 15, a reverse voltage is applied, which causes the dynistor 15 to lock up. from time tj to time i3 (Fig. 2, a), the sign of the reference voltage is positive, the value of the voltage across the capacitor, which is close to zero, is due to the shunt diode 5.

At time ts, the sign of the reference voltage changes, so the capacitor is charged again, and then the whole process repeats.

Claims (2)

The instant of operation of the pulse former relative to the beginning of the linear voltage across the capacitor, as can be seen from the diagram of FIG. 2b is regulated by changing the level of the control voltage Uy in the range tper close to 270 ° / W (W is the circular frequency of the network), while due to the fact that the flow of current in the input circuit of the driver of pulses stops after the pulse is issued and the distortion of the control voltage is eliminated, it is possible by increasing the starting current of the driver to reduce the error associated with the final response of the driver, and since the discharge of the capacitor through the reference clock voltage occurs with an insignificant voltage level on the capacitor, the loss in the source reference voltage substantially reduced. Thus, in this device, while ensuring a wide range of phase control of the output pulses, the control voltage level is highly accurate in converting the phase of the pulses, and the power of the onor synchronizing voltage is reduced, which makes it possible to use this device in converters for various purposes. The invention The device is a phase shift of pulses for controlling a valve converter containing a pulse shaper, a source of control voltage, a time for setting a resistive-capacitive circuit, a controlled diode in its capacitor discharge circuit and a source of reference clock voltage, which is caused by , in order to extend the range of pulse control and increase accuracy, it tends to ci; o: -i: c: i (. diode-resistor, initiating a diode and shunting a condeno; 1tor 1-rum back 1K; a common circuit; the source of the reference synchronizing voltage is made in the form of a two-voltage dipstick, three parallel in shape G5et1) mi, each of which contains a winding of a three-phase transformer connected in series in two branches with diodes and in the third with a resistor, the common output of the branches connected to the output through the indicated resistor-capacitor circuit through the indicated diode-resistor circuit, midpoint through which yvayun1y diode controllably coupled to dnodom, the second terminal of which is coupled to the junction of said parallel branches of said capacitor and the time the drive circuit. Sources of information accepted by the RO in the examination: 1. Author's certificate C (CP LI 214657. Cl. 2 / H 02 M 1/04, 19G8. 2. “Reverse K) electr (., GM M. Levin and M. E. Goldsnt, -.“ Energie, ML-L., 1964, p. 69, 74. fig. 41, 44. 3 Author's certificate .№, CL H 03 K 7/04. 1972.