SU1107248A1 - Control device for three-phase inverter - Google Patents

Abstract

A THREE-PHASE INVERTER CONTROL DEVICE, containing a scaling circuit on four cells, made according to an asymmetrical auto-oscillator circuit with an output transformer with an additional winding, the primary winding of which has an average output, dividing its turns in a 1: 2 ratio, connected to the first power output, the extreme lead that divides its coils in a 1: 2 ratio, connected to the first power output, the end pin leading to the first power output, 1 windings through transistors are connected to the second power output, to which the opposite terminals of the two basic windings are connected, the other terminals of which are connected through resistors base of transistors of own cell, master oscillator connected to two frequency dividers with transformer output interconnected, output transformer winding of the first frequency divider by an average output through a resistor connected to the second power output, the first extreme output is connected to the first output, additional winding of the first cell , and the second extreme output - with the first output of the additional winding of the second cell, the base of the first transistors of the odd cells are connected via diodes with the second output and additional windings of the subsequent cells, the bases of the second transistors of the even cells are connected via diodes to the second terminals of the additional windings of the previous cells, two transistors and two resistors, so that, in order to improve the weight and size characteristics and reliability of it thanks to I1.; yucheniyu one cell and one output transformer cell, it introduced the second additional winding on each transformer cells and two additional windings on the output transformer of the second frequency divider, the first the outputs of which are connected respectively to the first and second B1 tods of the output winding of the transformer of the first frequency divider, and the second leads to the emitters of these transistors and through resistors and two series-connected second additional windings of the second, third, fourth and first cells to the bases of the technical transistors, collector the first of which is connected via counter-connected diodes to the bases of the second transistor of the first cell and the first transistor of the fourth cell, the collector of the second transis ora connected through diodes counter included with the bases of the first transistor of the second cell and the third cell of the second transistor.

Description

one

The invention relates to electrical engineering, namely to control devices for electrical energy converters, and can be used for controlling three-phase inverters with pulses of a duration of 120 e. hail.

Control devices are known, for example, containing a wired generator with an output transformer, the output windings of which are connected to a three-phase inverter made on three autogenerator cells with a transformer output 1.

One CG on the output windings of the transformers forms a symmetrical voltage shifted by 120 e, hail, one relative to the other. To obtain asymmetrical control pulses, it is necessary to have a variable ring, which complicates the device and reduces its reliability.

A three-phase inverter is known, in which the control unit is executed in the form of a scaling ring with synchronization from the master oscillator 2.

The disadvantage of this device is the complexity and, as a result, the low reliability of the control unit.

The closest to the invention to the technical essence is a three-phase inverter control device containing a scaling circuit on six cells made according to an asymmetrical auto-oscillator circuit with an output transformer with an additional winding, the primary winding of which has an average output dividing its turns in a 1: 2 ratio, connected to the first power output, the extreme conclusions of the primary winding through transistors are connected to the second power output, to which the opposite terminals of the two basic ones are connected windings, other outputs of which are connected via resistors to the bases of the transistors of their own cell, specifying a generator with a transformer output, the middle output of the output winding of which is connected through a resistor to the second supply output, its first extreme output is connected to the first conclusions more 082 i82

The second terminal of the transformer is odd, the second terminal of the additional winding of all cells is connected via diodes to the base of the first transistor of the previous one and the base of the second transistor of the next NW cell.

10 A disadvantage of the known device is the presence of a large number of coil products and transistors, which reduces the weight and dimensions and reliability of the device.

The purpose of the invention is to improve the mass and size parameters and reliability by eliminating one cell and one cell transformer.

The goal is achieved

By the fact that in the control device a three-phase inverter containing a scaling circuit on four cells, executed in an asymmetrical auto-oscillator circuit with an output transformer with an additional winding, the primary winding of which has an average output dividing it

.... coils in the ratio of 1: 2, connected to the first power output, the extreme conclusions of the primary winding through transistors are connected to the second power output, to which the opposite terminals of two are connected

 base windings, other outputs of which are connected through resistors to the bases of the transistors of their own cell, the master oscillator connected to two frequency dividers with a transformer output connected to each other, the output winding of the transformer of the first frequency divider is connected to the second power output first through the resistor through the second power supply terminal the output is connected to the first output of the additional winding of the first cell, and the second extreme output to the first output of the additional winding of the second cell, the base of the first trans stories odd cells are connected via diodes to second terminals of the windings subsequent additional cells, base second transistors even cells

5 are connected via diodes to the second

the findings of additional windings of the preceding check, two transistors, two resistors, introduced the second additional 3. The ideal winding on each transformer of the cell and two additional windings on the output transformer of the second frequency divider, the first outputs of which are connected to the first and second outputs of the output winding of the transformer, first divide the frequency, and the second terminals to the emitters of these transistors and through resistors and two in series the connected second additional windings of the second, third, fourth and first cells, respectively, to the bases of the same transistors, the collection of the first of which is connected through counter-connected di rows with the bases of the second transistor of the first cell and the first cell transistor of the quat, the collector of the second tran ican connected through diodes counter included with the bases of the first transistor and the second cell transistor vtorog third cell. FIG. 1 shows a device connection diagram for a three-phase inverter; FIG. 2 voltage plots explaining the principle of operation of the device. The device has three units, each of which contains an amplifier 1 power on controlled keys 2 and 3, additional keys 4 AC, a push-pull inverter cell 5, one of the outputs of which is connected in series with the load, and the other through three keys 4 - parallel to the load, the control unit consisting of a master oscillator 6, two dividers 7 and 8 frequencies, cells 9-12, connected to each other and the output of the master multivibrator in a ring circuit together with transistors 14, 15 and resistors 13, 16 and 17. For controlling keys 2- 4 three phases (f Eg. 1) control pulses are needed, which can be obtained by a combination of pulses (Fig. 2) Evd, EVC (, (, EdU2. If they have two key pulses for controlling one phase key, then the third pulse is their sum. If there are two control pulses non identical keys of two different phases, and the third phase key control pulse is the sum of them.Let the outputs of cells 9-13 form the control pulses of the 2-4 inverter key: for phase A, Eud and E d (outputs of cells 9 and 11 ), for phase with Е fj and Е (outputs of cells 10 and 12). To obtain a control pulse using key 4 of phase A, it is necessary to connect in series the outputs of cells 9 and 1 1. Similarly, for phase C, the outputs of cells 10 and 12 are connected in series and connected to the control input of key 4 of phase C. To obtain control pulses of keys 2 and 3 of phase B 2, the outputs of cells 9 and 12 for key 3 and cells 10 and 11 are connected for key 2. To obtain control pulses with key 4 of phase B E g, the sum of control pulses E BZ and E –2 1 ° of the torus is obtained by connecting the outputs 9-12 in series. The device works as follows. To control the keys 2-4 of the three phases, control pulses are needed, which can be obtained by using the combination E of pulses A5 RMS AZ to get a set of pulses. ow on four transformers by synchronizing the autogenerators of cells 9–12 with the help of the divider 7 signal, frequency 2. For this purpose, add two more windings to the divider 8 for the frequency with voltage E-.yg and transistors 14 and .15. Let the first transistor of cell 9 be turned on in the interval O - tj, and the windings of the transformers have a voltage of Ech, dz. At time t, the voltage is added to the voltage E) dz (the additional winding of the cell 9 is connected in series with the output of the frequency divider 7) and turns off the transistor II of the cell 10, while the transistor 1 is turned on and a polarity of voltages is formed on the windings shown in FIG. 2. At the time t2, the voltage E (of the other polarity) is added to the voltage of the additional winding of the cell 10 and the transistor 1 of the cell 9 turns off. At the time t, like the sum of the voltages of the dividers 7 and 8, the transistors I and II of cells 10 and 11 turn on etc. Transistors 14 and 15 are used

To avoid false switching of the transistors of the cells 9-12, If frequency divider 8 is used to switch the transistors of cells 10 and 11 at time t or cells 12 and 9 at time tj, (or 0), at other times the signals of the dividers 7 and 8 frequencies must be: blocked. Consequently, in the portion t.-t, when transistors I and II of cells 10 and 11 have to switch, transistor 15 is opened by summing the voltage Eude VC2 by preparing the switching path for the signal to pass. A similar role is played by the transistor 14, which opens the way for the switching signal of the transistors of the cells 9 and 12 at the moment t (or 0), which opens this transistor in the section

5- Th and closing at the site

As a result, we obtain all the necessary impulses E

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ULEE h, C2. WHEN THIS, two transformers and two transistors are excluded from the circuit, which makes it possible to increase the reliability of the device and reduce its weight and dimensions.

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tz tj t

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t, t. FIG. 2

Claims (1)

THREE-PHASE INVERTER CONTROL DEVICE, containing a conversion circuit in four cells, made according to an asymmetric self-generated circuit with an output transformer with an additional winding, the primary winding of which has an average terminal dividing its turns in a 1: 2 ratio, connected to the first supply terminal, the extreme terminals of the primary supply terminal through transistors connected to the second supply terminal, to which the opposite terminals of the two base windings are connected, the other terminals of which are connected through the resistors to the bases t the resistors of the own cell, the master oscillator connected to two frequency dividers with a transformer output connected to each other, the output winding of the transformer of the first frequency divider by the middle output through a resistor is connected to the second supply terminal, the first extreme terminal is connected to the first terminal, an additional winding of the first cell, and the second extreme conclusion - with the first output of the additional winding of the second cell, the bases of the first odd-cell transistors are connected through diodes to the second terminals of the additional x windings of subsequent cells, the bases of the second even-cell transistors are connected via diodes to the second terminals of the additional windings of the previous cells, two transistors and two resistors, characterized in that, in order to improve the overall dimensions and its reliability due to the extraction of one cell and one output cell transformer, a second additional winding on each cell transformer and two additional windings on the output transformer of the second frequency divider are introduced into it, the first conclusions of which are connected respectively to the first and second terminals of the output winding of the transformer of the first frequency divider, and the second terminals to the emitters of the indicated transistors' and through the resistors and two series-connected second additional windings of the second, third, fourth and first cells, respectively, to the bases of the same transistors, the collector of the first of which is connected through counter-connected diodes to the bases of the second transistor of the neip cell and the first transistor of the fourth cell, the collector of the second transistor is connected through the counter-switch nye diodes with the bases of the first transistor of the second cell and the third cell of the second transistor. _n ”SU _p “ 1107248