RU2563027C1 - Method to control multi-phase rectifying unit - Google Patents

Abstract

FIELD: electricity.

SUBSTANCE: method to control a multi-phase rectifying unit is carried out by smooth regulation of rectified voltage, which is realised by variation of output voltage of a three-phase autonomous voltage inverter with width-pulse modulation, connected by AC terminals to an inlet of a low-frequency filter (L-shaped), output terminals of which are connected to the primary winding of the three-phase matching transformer, which by secondary phase windings is connected in series with the circuit winding of the converting transformer. Smooth regulation of rectified voltage is carried out by variation of phases and amplitudes of the first harmonics of output voltage of a three-phase autonomous voltage inverter with pulse-width modulation.

EFFECT: simplified rectifying unit and its control circuits, with provision of electric energy recuperation from a DC circuit into a power supply circuit.

7 cl, 2 dwg

Description

The invention relates to techniques for converting electrical energy of alternating current into direct current energy using valve converters with smooth regulation of the rectified voltage.

There is a method of thyristor control of rectifier units (Bobkov V.A., Bobkov A.V. Reconstruction of converter substations for supplying aluminum electrolysis cells. // Power Electronics. Thematic supplement to the journal "Components and Technologies". - 2006. - No. 4. - p. . 66-68). When applying this method, the regulation of the rectified voltage of the units is carried out by changing the control angles of the thyristors of the rectifier blocks (phase control).

This method provides smooth control of the rectified voltage of the unit, however, it has a number of disadvantages. Very serious drawbacks are the complexity of the design of the rectifier unit, the large installed power of controlled semiconductor devices (thyristors), and the complexity of the control system. This is due to the fact that all controlled semiconductor devices are included in the secondary high-current circuits of rectifier units (from the side of the valve windings of the transformer transformers). With increasing power of the units, with the implementation of deep bushings at high voltage substations, these shortcomings are exacerbated. The currents of the primary circuits of rectifier transformers are tens and hundreds of times less than the currents in the secondary circuits, so it is more advisable to control the rectifier units from the primary side of the transformers. In addition, when using this control method, the power factor of the units is reduced to values that are unacceptable for powerful converters (the power factor decreases in proportion to the increase in the depth of regulation). The latter is a particularly serious problem, for example, in the conditions of aluminum electrolysis, since in this case rectifier units work most of the time in the regulated mode (under reduced voltage) and open only for the duration of the anode effect (flash) in the bathtubs.

A known method for smoothly controlling a multiphase diode rectifier unit using an additionally introduced three-phase autonomous voltage inverter with pulse-width modulation, the input terminals of which are connected to the DC terminals of the additionally introduced three-phase diode rectifier bridge, which are connected by input terminals to the three-phase valve winding of an additional transformer, is a three-phase the network winding of which is connected to the mains (patent 2402143. Russian Federation I. The way to control a multiphase rectifier unit. / Yu.I. Khokhlov., D.V. Gizzatullin, A.G. Osipov // Bull. Inventory - 2009, No. 29). This control method, selected as the closest analogue, while maintaining smooth control provides a significant simplification of the rectifier unit, increasing the power factor and improving its main technical characteristics. However, this control method does not allow the recovery of electric energy from a direct current network through an autonomous inverter to the supply network and, in addition, requires the use of an additional auxiliary transformer.

The basis of the invention is a technical problem, which consists in simplifying the rectifier unit and its control circuits, as well as providing the possibility of recovering electric energy from a direct current circuit to the supply network while maintaining the inherent advantages of the closest analogue.

This problem is solved by applying a method for controlling a multiphase rectifier unit with at least one pair of six-phase converter blocks included in a twelve-phase conversion circuit, each of which contains a network winding, as well as a three-phase valve winding with the corresponding connection circuit of the converter transformer, to which a diode rectifier bridge is connected , DC outputs connected with the load, consisting in the fact that to ensure the required operating mode The direct current voltage regulator smoothly regulates the rectified voltage. The rectified voltage is continuously controlled by changing the output voltage of a three-phase autonomous voltage inverter with pulse-width modulation, which is connected to the input of a low-pass filter (L-shaped) by the AC terminals, the output terminals of which are connected to the primary winding of the three-phase matching transformer, which is connected in series with the secondary phase windings with a network winding of a converter transformer. According to the invention, the DC terminals of a three-phase autonomous voltage inverter are connected via a DC link to the DC terminals of an additional input pulse-width modulated voltage converter, the AC terminals of which are connected to the input of a low-pass filter, which are connected by output terminals to an additional secondary three-phase winding of the converter transformer.

Changing the output voltage of a stand-alone voltage inverter provides regulation of either phase or amplitude, or both of the first magnitude of the first harmonic of the modulating voltage.

The converter windings of the converter transformer are connected to the alternating current terminals of the rectifier bridges either directly or through the primary windings of the reactors of the compensating device, the secondary windings of which are turned on according to a circuit that provides filtering in switching capacitors of odd-multiple harmonics of the currents of the converter blocks.

The rectifier bridges of the unit from the DC side are connected either in parallel or in series.

Schematic diagrams of options for rectifiers in which the proposed control method is implemented are shown in FIG. 1-2. They contain six-phase converter blocks 1 and 2 with valve windings 3 and 4 of the converter transformer 20, a common network winding 19 for them, and converter bridges 6 and 7, respectively. The winding circuits 3 and 4 provide a twelve-phase conversion mode. In addition to the network 19 and the valve windings 3 and 4, the converter transformer contains an additionally introduced secondary winding 5.

Compensating device 8 (Fig. 2) contains three-phase reactors 9 and 10, as well as a switching capacitor bank 11. An additionally introduced voltage converter 13 connected via a low-frequency L-shaped LC filter 12 to an additionally introduced secondary winding 5 provides an exchange of active power between a DC link 14 and an AC network. A DC link containing a capacitor bank provides power to an autonomous voltage inverter 16 connected through a low-pass filter 17 to the primary winding of the matching transformer 18, the secondary three-phase winding of which is connected in series with the network winding 19 of the transformer transformer 20. The control system 15 sets the switching moments of the power switches of the converters 13 and 16.

The method of controlling a multiphase rectifier unit is implemented as follows. After connecting the rectifier unit to the supply network, a constant voltage is created at the outputs of the converter blocks 1 and 2 with valve windings 3 and 4, the network winding 19, and also rectifier bridges 6 and 7. This voltage corresponds to the twelve-phase conversion mode due to the connection of the valve windings 3 and 4 of the transformer transformer 20 into a star and a triangle. At the same time, a three-phase voltage system is created at the output of the additional secondary winding 5 of the converter transformer 20, which ensures the operation of the voltage converter 13. The voltage converter 13 through the winding 5 provides an exchange of active power between the DC link 14 and the AC network, due to which the link on the capacitor bank DC 14 forms a constant component of the voltage supplied to the DC terminals of the converter 13 and the autonomous inverter 16. In the result those operation control system 15 across the terminals of an AC voltage converter 13 is formed by three phase PWM sequences. The low-pass filter 12 serves to isolate from the PWM sequences the first voltage harmonics supplied to the winding 5. Due to this, a three-phase current system flows through the winding 5, which transfers electric power between the AC network and the DC link 14. In addition, the control system 15 provides formation of 16 three-phase PWM sequences of control voltages on the AC terminals of an autonomous inverter Due to the similar operation of the filter 17, a three-phase system of the first harmonics of the control voltages is supplied to the primary winding of the matching transformer 18. These first harmonics are transformed into the secondary winding of the transformer 18. In view of the series connection of the secondary winding of the transformer 18 with the network winding 19 of the transformer 20, the supply voltage in each phase is added to the control voltage. The resulting voltage is fed to the input of the network winding 19 of the transformer transformer 20, which ensures that the corresponding magnetic fluxes are guided in each core of its magnetic circuit. Due to the fact that the control voltages are regulated by the control system 15, it becomes possible to control the three-phase voltage system supplied to the network winding of the transformer transformer (amplitudes and phases of their first harmonics), and therefore, the rectified voltage of the entire converter unit. In addition, the ability to control the initial phases of the first harmonics of the control voltage system makes it possible to compensate for reactive power by advancing the shift of processes in the rectifier unit with respect to the supply voltage.

In order to increase the power factor of the rectifier unit, to increase the rigidity of its external characteristics, to ensure hard uniform division of the rectified current between the six-phase units 1 and 2 during their parallel operation, the proposed control method can be implemented in units with a compensating device 8, consisting of two three-phase reactors 9, 10 and three-phase switching battery 11. Compensating device include on the side of the valve windings 3, 4 of the transformer transformer 20. Streamlined currents converter blocks, the primary windings of reactors 9 and 10 of the compensating device 8 are transformed into secondary windings characteristic of six-phase blocks of the first, fifth, seventh, eleventh, thirteenth, etc. harmonics. In relation to the first, eleventh, thirteenth, etc. to the harmonics, the secondary windings of the reactors form a short-circuited circuit (for the indicated harmonics, the reactors 9 and 10 operate in the current transformer mode). The flow of these harmonics along the common secondary circuit of reactors 9 and 10 provides a rigid alignment of the rectified currents of the converter blocks 1 and 2 during their parallel operation (Fig. 2). In relation to the fifth, seventh, etc. For harmonics, reactors 9 and 10 operate in transformer mode operating on a capacitive load, creating the corresponding harmonics voltages on the capacitor bank 11. The voltages on the capacitor bank 11 are advanced artificial switching valves rectifier bridges 6 and 7, which increases the power factor of the rectifier unit and the rigidity of its external characteristics.

The method can be implemented both in rectifier units with a diode rectifier bridge 6 and 7 connected in series with respect to the load (Fig. 1), and in units with parallel connection of the rectifier bridges (Fig. 2).

The technical and economic effect of the proposed method for controlling a multiphase rectifier unit is to simplify the rectifier unit by eliminating from its design an additional transformer that provides power to the autonomous inverter. As in the closest analogue under consideration, the rectified voltage of the converter unit is controlled with the possibility of reactive power compensation by controlling the amplitudes and phases of the first harmonics of the control voltages, which provides an increase in the power factor of the converter unit even in its design without compensating devices. The use of a compensating device with filtering into the switching capacitors of odd-multiple harmonics of the currents of the converter units can significantly increase the power factor of the converter unit without significant loading of the autonomous inverter with reactive current. When using such a compensating device, its installed power is approximately six times less than the power that would be required if the compensating device were traditionally turned on at the frequency of the supply network. In the case of using such a compensating device in the converter unit with parallel connection of the converter bridges relative to the direct current consumer, the currents of the converter blocks are equalized, which makes it possible to exclude special devices designed for this purpose from the unit design. In addition, the use of artificial leading switching valves of the converter bridges can increase the rigidity of the external characteristics of the Converter unit. An additionally introduced voltage converter with pulse-width modulation makes it possible to recover electric energy from a direct current circuit to the supply network, which distinguishes this control method from the closest analogue.

Claims (7)

1. A method for controlling a multiphase rectifier unit with at least one pair of six-phase converter blocks included in a twelve-phase conversion circuit, each of which contains a diode bridge connected to the corresponding valve winding of the common converter transformer and connected to the DC terminals with a load, consisting of the fact that they carry out smooth regulation of the rectified voltage of the unit by changing the three-phase system of output voltages of the three-phase autonomous in A pulse-width modulated voltage generator, which is connected through an low-frequency filter to the primary winding of a three-phase matching transformer via its low-frequency filter, while the secondary phase windings of a matching transformer are connected in series with the mains winding of a common converter transformer, characterized in that the DC terminals of a three-phase autonomous inverter voltage is connected through the DC link to the DC terminals of the additionally introduced pre a pulse width modulator, which is connected to the alternating current terminals via a low-pass filter to an additionally introduced secondary three-phase winding of the converter transformer. 2. The method according to p. 1, characterized in that the smooth regulation of the rectified voltage is carried out by changing the phases of the first harmonics of the control voltages of a three-phase autonomous voltage inverter. 3. The method according to p. 1, characterized in that the smooth regulation of the rectified voltage is carried out by changing the amplitudes of the first harmonics of the control voltages of a three-phase autonomous voltage inverter. 4. The method according to p. 1, characterized in that the rectifier bridges of the converter blocks are connected directly to the valve windings of the converter transformer. 5. The method according to p. 1, characterized in that the rectifier bridges of the converter blocks are connected to the valve windings through the primary windings of the reactors of the compensating device, the secondary windings of which are turned on according to a scheme that filters odd-multiple current harmonics of the converter blocks into the switching capacitor bank. 6. The method according to p. 1, characterized in that the rectifier diode bridges of the converter blocks are connected in parallel with the DC consumer. 7. The method according to p. 1, characterized in that the rectifier diode bridges of the converter blocks are connected in series with respect to the DC consumer.

Images