SU1302391A2 - Discrete phase-shifting device - Google Patents

Abstract

The invention relates to a converter technique, can be used to control the phase of the control pulses of the thyristor converters, and is additional to the author. No. 978291, Emitter 18 emits luminous flux in the presence of a difference between the voltage set by the output parameter setpoint and the voltage of the output parameter sensor. The photodetector 17 is illuminated, its resistance changes, and with it the amount of current flowing through the control circuit of the pulse-pulse generator 16. This determines the number of pulses produced by the generator during the period to enter the input of the reverse register 5, and the value of the number in it will change to as long as the setpoint and sensor voltages are equal. Thus, the control pulse phase is corrected. 1 il. with IS K)

Description

The invention relates to a conversion technique, can be used in devices for adjusting the phase of control pulses of thyristor voltage converters and is an improvement of the device according to the author. No. 978291.

The purpose of the invention is to expand the functionality of the device.

The drawing shows a block diagram of a discrete phase shifter.

The device consists of a generator of 1 clock pulses, which is connected through an interdiction element 2 to the input of a counter of 3 clock pulses. The output of the counter 3 is connected to the first input of the code comparison unit 4, the second input of which is connected to the reversing shift register 5. The code comparison unit 4 is connected with the output to the first input of the reset trigger 6, the second input of which is connected to the zero-organ output 7. The decoder 8 of the angle CI —.- Connected by its input to the output of the counter 3, and the output to the first input of the reset trigger 6.

Operational amplifier 9 has inputs for connecting to a mains voltage source through a thermistor 10 and a voltage source. The output of amplifier 9 is connected to element 11, the first input of which is connected to the output of amplifier 9, the second input to inverse trigger output

6sbrops, and the output - with the second input element 2 of the ban.

The input of the reverse shift register 5 is connected to the optocouplers of the addition 12 and subtraction 13, the emitters of which in the form of LED 14 and 15 are switched on anti-parallel. Null organ

7 is also connected to a number-pulse generator 16, to the input of which is connected a photoresistance 17. A reader 18 (for example, a miniature incandescent bulb) is connected to the output of amplifier 19, to which the LED parts 14 and 15 of the optrons are also connected. Output elements of optocouplers 12

and 13 are connected to the input of register 5 via amplifiers 20 and 21,

The device works as follows.

The input of the zero-body 7 receives the voltage of the corresponding phase. The signal appearing at the output of the zero-body 7 sets the trigger 6 of the reset to one state.

At the output of the operational amplifier 9, the signal appears only when the voltage proportional to the voltage of the network becomes greater than the reference. The signal L, appearing at the output of the operational amplifier 9, opens element I I1 and, thus, gives the command to allow the counter to be filled with 3 pulses of the reference frequency from generator I through element 2.

Register 5 is executed in the form of a reverse shift register and is intended for storing a code corresponding to a certain value of the opening angle of the thyristor. The counting input of the register 5 is connected to the output of the number-pulse, generator 16, synchronized with the network.

Register code 5 and counter code 3 are compared using block 4 compare codes. When the codes at the output of block 4 coincide, a pulse appears, which is then used to control the formation of pulses to control the thyritors. At the same time, this pulse arrives at the input of the reset trigger 6 and sets it to the zero state. As a result, a logical zero appears at the output of AND 11, and the prohibition element 2 closes. After the appearance of the voltage of the same phase at the output of the null organ 7, the cycle is completely repeated.

The parameters of the thyristor are largely dependent on temperature. To account for its effect, a temperature-dependent element is connected to the circuit, for example, a thermistor 10, which is mounted on the thyristor's radiator. At the nominal temperature, the signal at the input of the amplifier 9 enables the unlocking of the thyristor at N „.,, When the temperature changes in

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the side of its increase changes the characteristic of the thyristor and the element 10 provides the shift of the permission signal for unlocking in the direction of "decreasing the angle ct.

The stability of operation, for example, an electric drive, depends on maintaining at the same level its basic parameters, for example, speed. This parameter introduces feedback on a parameter based on amplifier 19, the first input of which is connected to the parameter sensor, and the second input is connected to the sensor.

sensor (speed, current, voltage, etc.). The output of the amplifier 19 is connected to the LEDs 14-15, which are turned on anti-parallel and are elements of an optocoupler. They are used as reference elements for generating correction control signals, for example, engine speed. In this case, the property of optocouplers is used to transmit a signal only when a current of a certain direction passes through it.

Thus, during a voltage, the luminous flux emits the LED part 1A and there is an addition (shift to the right) in register 5, and in the case of V, the LED part 15 emits light and there is a subtraction (shift to the left) in the register 5. Emitter 18 emits a luminous flux if there is a difference between the set point voltage and the sensor voltage, regardless of the sign of this difference. Photodetector I7 is illuminated, its resistance changes, and with it the amount of current flowing through the control circuit of the pulse-pulse generator 16. This determines the number of pulses produced by the generator during the period received at the input of the reversing register 5, Therefore, in register 5 the period changes until the setpoint and sensor voltages are equal, as a result, the phase of the thyristor control pulse is corrected in time depending on the actual set value of the parameter a.

Compiled by V. Bunakov Editor I. Derbak Tehred A. Kravchuk

Order T222754 TYrazh 6bT Subscription VNISHI of the USSR State Committee for Inventions and Discoveries, 113035, Moscow, Zh-35, 4/5 Raushsk nab.

Correct

Production and printing company, Uzhgorod, Projecto st. -, 4

023914

When the voltage at the output of the amplifier 19 is equal to zero, the voltage at the output of yc and l 20 and 21 is also zero. These signals prohibit the counting of oscillator pulses 16, as a result of which the state of register 5 does not change even if the register 5 receives pulses from the oscillator 16. This eliminates the influence of the final value of the photoresistance on the device operation at zero voltage at the amplifier output. nineteen.

Claims (1)

f5 claims Discrete phase-shifting device according to auth.St. No. 978291, characterized in that, in order to expand its functionality, it is equipped with a number-pulse generator, a first and second optrons with emitters in the form of LEDs, a resistor optroi, whose emitter is made in the form of an incandescent lamp, and a second operating an amplifier whose inputs are intended to be connected to the source of the driving voltage and to the output of the sensor of the adjustable parameter, and re-. The control unit hister is made in the form of a reverse shift register, the counting input of which is connected to the output of the pulse number generator, the control inputs are connected via the first and second optocouplers to the output of the second operating amplifier, ate, and the number of the pulse generator is connected to the output of the second operating amplifier through resistor optocoupler. Proofreader A. Obruchar