SU1069104A1 - Frequency converter - Google Patents

Abstract

1. A FREQUENCY CONVERTER containing a master oscillator connected to the counting input of a pulse distributor, a logical node whose outputs are connected to the control inputs of a three-phase inverter through an amplifier converting node. power inputs of which are intended to be connected to the outputs of an external source of the frequency to be converted, as well as a voltage regulator, characterized in that, in order to simplify the converter, increase its reliability, and also increase efficiency by reducing the switching losses of the inverter, a shaper of the pulse generator is introduced into it with direct and inverse outputs, and the inverter is made on keys with one-sided conductivity while the inputs of the generator of synchronizing pulses are connected to the power inputs of t a three-phase inverter, Q and the direct and inverse outputs to the input of the voltage regulator, the output of which (left connected to the clock input of the pulse distributor. c: о о

Description

2. The converter according to claim 1, characterized in that the voltage regulator is made in the form of a counter with a variable conversion factor, in which a binary counter, a decoder, an inverter, a D-flip-flop and a conversion factor patch, are entered, and the counter outputs are bitwise connected with the inputs of the decoder, the outputs of which are connected to the input through the converter of the conversion factor, the inverter, whose code is connected to

the counting input D of the trigger, the setup input of which is connected to the direct output of the synchronizing pulse generator, while the inverse (OUTPUT of the D trigger of the binary counter and the clock input of the pulse distributor, and the information input and the input of the CE trigger of the trigger respectively with positive and negative poles of the power source,

The invention relates to electrical engineering, in particular, to converter equipment, and can be used to control AC motors of various types (synchronous, asynchronous, etc.) when a wide range of speed control is required.

A single-phase to three-phase voltage converter is known that contains a single-phase transformer with three secondary windings made with a tap-off, as well as six three-phase AC switches made in the form of three-phase diode bridges with transistors connected at their outputs. The outputs of the bridges are connected to different turns of each

, from the secondary windings of the transformer 1.

Disadvantages converter

. are the complexity of the structure and the limited functionality due to the inability to control the output frequency, as well as low weight and dimensions due to poor use of the transformer windings.

Closest to the present invention is a frequency converter, containing a master oscillator "associated with the counting input of a pulse distributor, a logic node whose output through an amplifier-decoupling node is connected to the control inputs of a three-phase inverter, the power inputs of which are connected to an external source frequency to be converted, as well as a voltage regulator 2.

However, the known converter has a complex structure of a three-channel voltage regulation and logic node. In addition, a large number of switchings of the key elements of a three-phase inverter during the period of the output voltage

reduces the reliability of the converter and increases the switching losses.

The aim of the invention is to simplify the converter, increasing its

reliability, as well as improving efficiency by reducing the switching losses of the inverter.

The goal is achieved by the fact that the converter, the contents

o master oscillator associated with

the counter input of the pulse distributor, the logic node, the outputs of which are connected to the control inputs through the amplifier-breaker node

a three-phase inverter, the power inputs of which are intended to be connected to an external source of frequency to be converted, and a voltage regulator, is equipped with a synchronizing pulse shaper with and inverse

0 outputs, and the inverter is made on

keys with one-sided conductivity, while the inputs of the clock generator are connected to the power inputs of the three-phase inverter, and

5 direct and inverse outputs to the input of the voltage regulator, the output of which is connected to the clock input of the pulse distributor.

In this case, the voltage regulator is designed as a counter with a variable conversion factor, in which a binary counter, a decoder, an inverter, a 15-trigger and a converter of the conversion factor are entered, and the outputs

5 counter by bit are connected to the inputs of the decoder, the outputs of which | are connected to the input of the inverter, the output of which is connected to the counting input D of the trigger, the setup input of which is connected to the forward output of the generator of the synchronizing pulse, while the inverse output D is trigger connected to reset input

A 5 binary counter and a clock input of the pulse distributor, and the information input and the reset and on-trigger input are connected respectively to the positive and negative poles of the power source. FIG. 1 shows a block diagram of the converter f in FIG. 2. The principle diagram of the converter in FIG. 3 is timing diagrams explaining its principle of operation. The frequency converter (Fig. 1) contains a master oscillator 1 associated with the counting input of the distributor 2 pulses, the outputs of which are connected to the logical node 3. The logical node 3 with its outputs is connected to a non-stimulating and evaporating node 4. Blocks 2, 3 and 4 form the shaper 5 conversion cycles. The outputs of the amplifier-razvakvkmy node 4 are connected to the control inputs of a three-phase inverter b, the power inputs of which are intended to be connected to the output terminals of the external source 7 of the frequency to be converted, as well as to the inputs of the driver of the 8 s of synchronizing pulses, direct and inverse outputs which is connected to the inputs of the voltage regulator 9. The outputs of inverter B are connected to the phases of the output voltage A, B and C, and the output of the regulator 9 connect the voltage to the clock input to the distribution of the body 2 pulses. Shaper clock pulses 8 (figure 2) contains a trigger 10, the inputs of which through optoelectronic uncoupling 11 and 12 are connected to the terminals of an external source 7 of the converted frequency. As an external source of the converted frequency, both an industrial AC network and an intermediate high frequency link, such as a generator, which sets an independent intermediate high frequency, can be used. The LEDs of the optoelectronic isolators 11 and 12 are interconnected in parallel. The inverse output of the trigger 10 is connected to the counting input of the binary counter 13 of the voltage regulator 9. The voltage regulator circuit 9 is represented by a counter with a variable conversion factor and includes a binary counter 13, a decoder 14, a setpoint switch 15 of the conversion factor, an inverter 16 and a C-trigger 17 counter outputs 13 are connected to inputs the decoder 14, the outputs of which through the setting unit 15 of the conversion factor, are connected to the input of the inverter 16. The output of the inverter 16 is connected to the counting input of the D-flip-flop 17, the installation input of which is connected to the forward output of the synchronizer 8 of the pulse synchronization. The first output of the I-flip-flop 17 is connected to the reset input of the binary counter 13 and to the clock input of the decoder 18 of the pulse distributor 2. The information input and the reset input of the D-trigger 17 are connected to the positive and negative poles of the power supply, respectively. The reference frequency comes from the master oscillator 1, assembled on the inverters 19-21, to the installation input of the trigger 22, and also through the inverter 23 to the counting input of the binary counter 24. The outputs of the counter 24 are bitwise connected to the inputs of the decoder 18, while the sixth output of the decoder 18 through the inverter 25 is connected to the counting input of the trigger 22, the inverse output of which is connected to the reset input of the counter 24. The outputs of the decoder 18 from zero to fifth are connected to the inputs of logic node 3 assembled on two-input circuits AND 26-31 in the following order. The zero output of the decoder 18 is connected to the first inputs of circuits And 26 and 29. The first output is with the second input of the circuit And 29 and the first input of cxeNM And 30. The second output is with the first input of the circuit and 27 and the second input of the circuit And 30, The third output - with the second input of the circuit 21 and the first input of the circuit 28. The fourth output is with the second input of the circuit 28 and the first input of the circuit 31. The fifth output is with the second inputs of circuits 26 and 31. The output of each of the circuits is connected to the anodes of the LEDs switching elements - thyristor optocouplers 32-37. The cathodes and the diode optocouplers 32.1–37.1 are pairwise connected to each other and to the first terminals of the resistors 38-40, the second terminals of which are connected to the negative pole of the power source. The LEDs of the thyristor optocouplers 32.1 37 .1 and the resistors connected to them form an amplifier-unite node 4. The photo thyristors of the optocouple 32.237 .2, which are keys with one-sided conductivity, are connected to a three-phase inverter 6, and the anodes of the thyristors 32.2, 34.2 and 36.2 are connected between each other and with the first terminal of the external source 7 of the frequency to be converted, and the cathodes of thyristors 33.2, 35.2 and 37.2 are connected with each other and with the second terminal of the external source 7 of the frequency to be converted. Phase A of the output voltage is connected to the cathode of the thyristor 32.2 and the anode of the thyristor 33.2, phase B to the cathode of the thyristor 34.2 and the anode of the thyristor 35.2, phase C to the cathode of the thyristor 36.2 and the anode of the thyristor 37.2 of inverter b. The period of each phase of the output voltage is six clock cycles.

Each clock cycle is characterized by the inclusion of only two defined thyristors in the sequence specified by the shaper with 5 conversion cycles (Fig. 1): 1 clock cycle — thyristors 32 and 35; II cycle - thyristors 35 and 36; ill tact - thyristors 36 and 33; IV tactics 33 and 34; V tact - thyristors 34 and 37; Vi. tact - thyristors 37 and 32.

With such an arrangement of thyristor terminals, the linear voltage of the load connected to terminals A, B and C varies according to the timing diagram (Fig. 3). The resistor 41 changes the frequency of the master oscillator, and therefore the duration of the conversion cycle, which ultimately leads to a change in the output frequency of the converter, and the switch at the converter 15 sets the conversion factor to adjust the voltage at the output of the converter by counting the number of pulses directly from the external the source of the frequency to be converted, or through an intermediate link, and the assortment of each of the 5th outgoing pulses, where 11 is the coefficient of recalculation of the regulator circuit voltage eni

The proposed Converter works as follows.

2 pulses are input to the distributor from a generator 1, rectangular pulses, from which the shaper of 5 conversion cycles generates six frequency conversion steps, characterized by a specific sequence of pairwise switching on the coherence elements with one-way conductivity {: thyristor optocouplers 32-37) of the inverter 6. Under the influence of signals Inverter 6 converts the voltage coming from the terminals of the external source 7 of the frequency to be converted. or intermediate high-frequency link, in three phase

two-stage voltage (fig. 3). Each step of the three-phase voltage is formed by a burst of pulses coming from the source 7 of the frequency being converted. The frequency of the three phase voltages is regulated by changing the frequency of the generator 1 delay.

Shaper 8 clock pulses converts incoming to

0 its input voltage from an external source 7 of the frequency to be converted into rectangular pulses synchronized with it. The sync pulses enter the voltage regulator circuit 9,

5 which does not miss the form, the body of 5 clock cycles every Q is the sync pulse and can be any positive integer (in the proposed converter, n varies from 1 to

Q 10) p is the conversion factor for the voltage regulator and is entered into the circuit using a factor setter 15.

In this way, the voltage of the burst of pulses forming each stage of the output three-phase voltage is regulated.

The converter structure reduces the number of switchings,. key elements of a three-phase inverter, which reduces switching losses and increases the reliability of the circuit. The converter can operate from any external unregulated source of a transformable frequency, 5x both from an industrial AC network and through an intermediate frequency link. In addition, the smoothness of voltage regulation is increased due to the fact that regulation is done not by modulating the width of each level of the output voltage, but by breaking it up into several components, and the intervals between these components are each P of the incoming from an external source of the converted frequency of the pulses, delayed by a voltage regulator.

Claims (2)

1. A FREQUENCY CONVERTER containing a master oscillator connected to the counting input of the pulse distributor, a logical node, the outputs of which are connected through the amplifier-isolating node to the control inputs of a three-phase inverter, the power inputs of which are designed to connect to the outputs of an external frequency source, as well as a voltage regulator, characterized in that, in order to simplify the converter, increase its reliability, as well as increase efficiency by reducing the switching losses of the inverter, a shaper of synchronizing pulses with direct and inverse outputs is introduced into it, and the inverter is made with keys with one-side conductivity, while the inputs of the shaper of synchronizing pulses are connected to the power inputs of a three-phase inverter ^ and the direct and inverse outputs are connected to the input of the voltage regulator, the output of which - <horn is connected to the clock input of the pulse distributor. Ave SU „„ 10691> 2. The Converter according to claim 1, characterized in that the voltage regulator is made in the form of a counter with a variable conversion factor, into which a binary counter, a decoder, an inverter, a D-flip-flop and a conversion factor setter are entered, and the counter outputs are bitwise connected to the inputs a decoder, the outputs of which are connected to the input through an adjuster of the conversion factor (an inverter whose output is connected to the counting input of the D-trigger, the installation input of which is connected to the direct output of the synchronizing pulse former, This inverse output of the D-trigger is connected to the reset input of the binary counter and to the clock input of the pulse distributor, and the information input and the failure input of the 13-trigger are connected respectively to the positive and negative poles of the power source.