CS238959B1 - Wiring a single or multiphase digital pulse generator for thyristor converters - Google Patents

Abstract

The solution concerns control and regulation and solves the connection of a single or multi-phase generator of switching pulses for thyristor converters. The signal of the desired value of the phase angle is converted to a digital signal. which is limited in the converter. The voltage signals of the individual phases are shaped in shapers. The signals obtained in this way serve to synchronize the digital signal of the instantaneous phase angle using a digital comparator, regulator, controlled generator and comparator. The digital signal of the instantaneous phase angle together with the digital signal of the desired shift angle is processed in an adder, the output signal of which is processed in the output logic circuits, where switching pulses are generated. The invention is used in the control of converters and electric drives.

Description

The solution relates to control and regulation and solves connection of single or multiphase switching pulse generator for thyristor converters. The phase angle setpoint signal is converted to a digital signal. which is limited in the converter. The voltage signals of the individual phases are shaped in the formers. The signals thus obtained are used to synchronize the digital signal of the instantaneous phase angle by means of a digital comparator, a controller, a controlled generator and a comparator. The digital signal of the instantaneous phase angle together with the digital signal of the desired shift angle is processed in a summator whose output signal is processed in the output logic circuits where the trigger pulses are generated.

The invention is used in the control of converters and electric drives.

238 959

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BACKGROUND OF THE INVENTION The present invention relates to a single or multiphase switching pulse generator for thyristor converters.

There is a well-known series of circuit-breaker generators for thyristor converters. The analogue embodiments of these generators, in particular in production, have drawbacks, in particular due to the large number of adjustment points and the temporal instability of the adjustment. The numerical embodiments are quite complex or have similar drawbacks as analog solutions. Both versions cannot solve the situation when the mains frequency of the inverter is unstable within a wide range.

These drawbacks are largely overcome by the wiring of a single or multiphase digital pulse generator for thyristor converters according to the invention. The principle of the invention is that each phase input of the wiring is connected to an input of the associated shaping circuit. The output of each shaping circuit is coupled to the corresponding input of an input logic circuit whose frequency output is coupled to the first input of the frequency comparator. The phase output of the input logic circuit is connected to the first input of the digital comparator, the outputs of which are connected to the corresponding inputs of the controller. The third input of the controller is connected to the output of the frequency comparator. The output of the controller is connected to the input of the controlled generator, the output of which is connected to the second input of the frequency comparator, the fourth input of the digital-to-analog converter and the input of the counter. The counter output is coupled to a second digital comparator input and a second summator input

238 939

The summator output is connected to the input of an output logic circuit, each output of which is connected to the corresponding phase output of the respective phase. · The control input is connected to the first input of the A / D converter. connected to the third input of the D / A converter ·

The advantage of the arrangement according to the invention is that it makes it possible to simplify the adjustment operations in the manufacture of the control circuits for the inverters. Since the wiring comprises two control loops, that is, a phase control loop and a frequency control loop, it allows the inverter controlled by this wiring to cooperate with a highly variable frequency network. · 'V

In this case, the known wiring does not allow the inverter to run at all. The cooperation of the two control loops also ensures high accuracy in maintaining the required phase angle of the trigger pulses while maintaining good dynamic wiring characteristics.

An example of a circuit according to the invention is shown schematically in the attached drawing.

The individual circuit blocks can be characterized as follows. All the forming circuits 1.1 to 1.n are the same and are constructed as analogue logic comparators. They are used to shape the input sine signal of the respective phase. The input logic circuit 2 is made up of logic combinational circuits or ROM.

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Used to generate an auxiliary signal for the 6th frequency comparator and the 2 phase digital comparator. digital comparator 2 3 ^e consisting of integrated circuit or ROM • It compares the phase shift of the instantaneous phase angle at the output of the counter χ with the instantaneous phase angle of the n-phase system at the input input. Generator 2 The controlled generator 6 is formed by an operational amplifier with associated couplings. Together with the previous blocks it generates pulses with a frequency equal to the multiple of the mains frequency. · The frequency comparator 6 consists of a frequency comparison wiring such as a diode integrator, or a gateway, a frequency divider, and As a result of an analog signal, the counter X is formed from integrated circuits and serves to generate a digital signal indicating the instantaneous electric phase angle. Analog-to-digital converter 8 consists of either a feedback connection from a counter and a digital-to-analog converter or from a special integrated or hybrid circuit or a synchronizer · It serves to convert the control analog signal to a digital signal and and serves to produce a digital signal indicating the instantaneous phase angle with addition of the desired phase offset. The output logic circuit 10 is either a ROM or integrated adders. When selecting a suitable digital signal code, it can be made up of simple gates. It is used to create a trigger pulse system for controlling the thyristor rectifier. Individual blocks are connected as follows.

Each phase input 04.1 to 04.n of the wiring is connected to

238,939 the associated shaping circuit 1.1 through 1.n. The output of each shaping circuit is connected to the corresponding input 21.1 to 21.n of the input logic circuit 2, whose frequency output 22 is connected to the first input 6l of the comparator 6 of the trel & The outputs 22, 34 of the digital comparator 2 are connected to the corresponding inputs 41. 42 of the controller 6. The third input 43 of the controller 6 is connected to the output 63 of the frequency comparator 6. The output 44 of the controller 4 is connected to the input 51 of the controlled generator 2. The output 52 of the controlled generator 2 is connected to the second input 62 of the frequency comparator 6, the fourth input 84 of the digital analogue converter 8 and the input 71 of the counter. the second input 32 of the digital comparator 2 and the second input 92 of the summator 2; the output 93 of the summator 2 is connected to the input 100 of the output logic circuit

10. Each output 10.11 to 10 > n2 of the output logic circuit 10 is coupled to a corresponding phase output 00.11 to 00 > n2 of the respective phase. The wiring control input 03 is connected to the first input 81 of the A / D converter 8, whose second input 82 is connected to the first wiring restriction input 01. The second wiring limiting input 02 is connected to the third input 82 of the D / A converter 8. The wiring comprises two control loops. The first control loop is frequency and comprises a frequency comparator 6, a controller 6 and a controlled generator 2. The second control loop is a phase and comprises a digital comparator 2, a controller 4, a controlled generator 2 ^{and a} counter.

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-ΓThe wiring works as follows »single-phase signals come to the corresponding phase inputs 04»! to Q4 »n connection and from there to the inputs of the corresponding shaping circuits 1.1 to ln, in the shaping circuits 1.1 to l» n the periodic mains voltage signal changes to a logical signal of a rectangular waveform. 1, n to the corresponding inputs 21.1 to 21, n of the input logic circuit 2.

An auxiliary frequency signal is generated in the input logic circuit 2, which passes to the first input 61 comparing 6 frequencies. In addition, an instantaneous phase angle digital signal is generated in the input logic circuit 2, which switches from the phase output 23 of the input logic circuit 2 to the first input 31 of the digital comparator 2. At the same time, the signal goes to the second input 32 of the digital comparators 2 «

In the digital comparators 2 ^{, the [alpha] and [} sigma] signals are compared, and at its outputs 33 and 34 there is a logical signal of the sign or equation of the instantaneous phase angles. This pair of signals arrives at the first input 41 and at the second input 42 of the controller J, Ha and the third input 43 of the controller 8 receives an analogue signal of the multiple of the mains frequency and the frequency of the controlled generator 2. The output frequency of the controlled generator 2 is a multiple of the line frequency and the difference between the instantaneous phase angle of the grid and the instantaneous phase angle of the connection is close to zero. The output signal from the output 52 of the controlled generator 2 arrives at the second input 62 of the frequency comparator 6.

The signal, proportional to the difference of the line frequency multiplier and the output frequency of the controlled generator 6, is outputted to the third input 43 of the controller 6. The signal from the output 52 of the controlled generator 6 is simultaneously applied to the fourth input 84 of the DAC 8 as its auxiliary clock frequency signal and to the input 71 of the counter 2 '. it supplies to the second input 32 of the digital comparator 2 and to the second input 92 of the summator 2. · The control input 03 of the inverter receives the setpoint signal of the drive inverter angle, which is the phase shift signal of the output pulse system. 81 digital to analog converter 8 «digital signal corresponding to the maximum shift angle value comes through the first input 01 of connection to the second input 82 of digital analog converter 8. Its third input 83 comes through the second input 02 of connection digital signal minimum angle of phase shift. The converter 8 outputs a digital signal of the desired displacement angle at its output, respecting the limits of its maximum and minimum values. This signal is applied to the first input 91 of the sump 2 ° ^{in the} sump 2. this signal is added to the instantaneous phase angle signal at the second input 92 of the sump. This provides a digital instantaneous phase angle signal of the pulse pulses that is converted from output 93 of the summator 2 to input 100 of the output logic circuit 10.

In the output logic circuit 10, this signal is used to create a system of output pulse pulses, which passes through outputs 10.11 to 10.n2 to the corresponding phase outputs OOoll up to 00.n2 of individual phases.

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The invention will be used in single or multiphase converters, designed to work with mobile AC power and in more complex climatic conditions

Claims (1)

SUBJECT OF THE INVENTION 230 9S9 Connection of single or multiphase digital generator of switching pulses for thyristor transducers, characterized in that each phase input (04.1 to 04.n) is connected to the input of the associated shaping circuit (1.1 to ln), the output of which is connected to the corresponding input (21.1) to 21.n) of an input logic circuit (2), whose frequency output (22) is connected to the first input (61) of the frequency comparator (6) and the phase output (23) of the input logic circuit (2) is connected to the first input (31) a digital comparator (3) whose outputs (33, 34) are connected to corresponding inputs (41, 42) of the controller (4), whose third input (43) is connected to the output (63) of the frequency comparator (6) and the output ( 44) the controller (4) is coupled to the input (51) of the controlled generator (5), the output (52) of which is coupled to the second input (62) of the frequency comparator (6), to the fourth input (84) of the digital-analog converter and enter A counter (7) whose output (72) is connected to a second input (32) of the digital comparator (3) and to a second input (92) of a summator (9) whose output (93) is connected to an input (100). ) of an output logic circuit (10), each output of which (10.11 to 10.n2) is connected to a corresponding phase output (00.11 to 00.n2) of the respective phase and the control input (03) is connected to the first analog-digital input (81) a converter (8), the second input (82) of which is connected to the first limiter input (01) of the circuit, the second limiting input (02) of which is connected to the third input (83) of the digital-analog converter (8).