SU1226593A1 - A.c.voltage-to-a.c.voltage converter - Google Patents

Abstract

The invention is intended to be supplied by a controlled pulse voltage with a non-linear inductance. The purpose of the invention is to expand the functionality. The converter contains thyristors 1, 2 connected between the corresponding input 15, 16 and output 17, 18 terminals, and a resistor-capacitive driver of control pulses, including diodes 5-8, non-temporary resistors (PR) 9, 10, capacitors 11, 12, and 13, 14. PR 9 is connected between the cathodes of diodes 5, 6. PR 10 is connected between the connection point of the anodes of diodes 7, 8 and the movable contact of PR 9. The cathodes of diodes 7, 8 through resistors 19, 20 and dynistors 13, 14 are connected respectively to control electrodes of thyristors 1, 2. Anodes of diodes 5, 6 are connected respectively With input pins 15, 16. By alternately or simultaneously varying the resistance values of the PR 9 and 10, a symmetrical, asymmetrical and combined adjustment of the output voltage in terms of amplitude, phase and pulse frequency for each polarity and current pulses while maintaining or a change in its mean value and a constant component with a reverse. This ensures that the goal is achieved. 1 il. I ate to O5 cd with so

Description

The invention relates to electrical engineering and can be used to convert an alternating voltage into an adjustable pulse, for example, to adjust the amplitude, phase angle and frequency of the excited efforts of an electromagnetic vibrator in an optimal relationship between electrical and mechanical parameters.

The purpose of the invention is the expansion of functional capabilities.

The drawing shows the principle of the device.

The AC to AC converter contains two thyristors 1 and 2, shunted by power diodes 3 and 4, a resistor-capacitive driver for controlling pulses, containing diodes 5-8, variable resistors 9 and 10, capacitors 41 and 12, and dinistors 13 and 14. At the same time, the cathodes of thyristors 1 and 2 are connected to input pins 15 and 16, and the anodes to output pins 17 and 18, each of the limiting resistors 19-22 bypasses the transition of the corresponding thyristor or limits the current through the dynistor, damping RC-chains containing resistors 23 and 24 and konde Satoru 25 and 26, eliminate the overvoltage and connected to the output terminals 27 Chen load inductance with a nonlinear (e.g., an electromagnetic vibrator).

The variable voltage to variable converter operates as follows.

During the positive half-cycles of the mains voltage, corresponding to the positive potential at the input terminal 16, the current through diode 6, the input part Ri of the variable resistor 9, the resistive resistor 10 and the diode 7 charge the capacitor 11 until the voltage of the switching of the distor 13 is applied to the control electrode of the thyristor 1. In this case, the latter is unlocked, and the current pulse passes through the power diode 4, load 27 and thyristor 1. Similarly, when changing the power supply field, corresponding to a positive potential at the input terminal 15, the current through diode 5 is entered The second part R2 of the variable resistor 9, the variable resistor 10 and the diode 8 charges the capacitor 12 until the switching voltage of the dyistor 14 is controlled, and the thyristor electrode 2 is unlocked and the current pulse passes through the power diode 3, the load 27 and thyristor 2.

The working phases of thyristors 1 and 2 and dynosters 13 and 14, respectively, are matched in phase and dividing diodes 5-8 ii iBo produce charging of capacitors 11 and 12 until the voltage of the dynistors is triggered by switching on the corresponding resistance values of the resistors 9 and 10 in the charge circuit of the driver control pulse both in each period of the mains voltage and with the passage of the corresponding number

0

0 5

0

five

0

half periods, which in turn allows adjusting the voltage, phase and frequency of the current pulse in the load, equal to 50, 25, 16, 7, ..., 50 / n Hz, where n - 1, 2, .. for each polarity of pulses. Due to the load of an inductive nature, the operation of the device is considered at angles of control that are somewhat large than the angle of the delay in the flow of current after the voltage zero across.

The proposed device allows voltage formation by thyristors 1 and 2 in each half-wave of the network voltage, firstly, by decreasing (increasing) resistance by a variable resistor 10 at a constant position of the variable resistor 9's motor, the thyristor unlocking angles decrease (increase), which provides voltage with a change in its average value, and the constant component remains almost equal to or equal to zero at equal angles of unlocking the thyristors - this is the resistor K) is considered symmetric, and secondly, the change in the position of the moving contact of the variable resistor 9 with the constant value of the variable resistor 10 entered unchanged; the unlocking angle of the thyristor 1 is smaller than the unlocking angle of the thyristor 2, and the unlocking angle of the thyristor 1 is larger than that of the thyristor 2, at that, which provides asymmetrical voltage regulation with practically keeping its mean value, but changing the constant component with the reverse of the latter, therefore, the center of gravity of the current curve shifts within ± 2 relatively zero sinusoids of the network voltage, and, thirdly, the regulation of the voltage on the load by changing the positions of the engines of both variable resistors 9 and 10 (t. e. a combination of the first two cases — symmetrical and asymmetrical adjustment), the corresponding values of the average voltage, constant component (with reversal) and phase within ± 1/2 with respect to zero of the voltage sine wave are achieved.

 The device also allows voltage thyristors 1 and 2 to be formed in the respective half-waves of the network voltage with a certain number of positive and negative network voltage half-periods skipped, and corresponding resistance values are applied by a variable resistor 10 (symmetrical regulation) and a variable resistor 9 (asymmetrical regulation). Such a voltage regulation allows the amplitude, phase and pulse frequency to be adjusted to be 50 / n Hz, where; r 1, 2, ..., for each polarity of the current pulses in the load. However, the most interesting case of voltage regulation is associated with the omission of a certain

the number of periods of the network voltage, achieved by adjusting the variable resistor 10, and the variable resistor 9 achieves the necessary asymmetry or symmetry of the phases of the regulated voltage in the corresponding period of nagf. Similarly, in this case, the resistor 10 regulates (at a certain value of n) the average voltage, while the constant component retains its value, and the resistor 9 (moving the moving contact to the extreme position does not switch the frequency level, i.e. does not change the value of n) —constant power component with constant mean value.

Claims (1)

Invention Formula The converter is variable to voltage to alternating, containing two thyristors, each of which is shunted by a power diode and connected between the respective input and output terminals, and a resistance-capacitive driver of control pulses, containing four diodes, two capacitors, two dynodors and two variable resistors , the first of which is connected between the cathodes of the first and second diodes, the anodes of which and the first terminals of the capacitor are connected to the input terminals, and each of the cathodes of the third and fourth diodes is connected through a dynistor Is connected with the control electrode of the corresponding thyristor, characterized in that, in order to expand the functional capabilities, the anodes of the third and fourth diodes are connected via a second variable resistor to the moving contact of the first variable resistor, and the cathodes of these diodes are connected respectively to the second capacitor terminals.