SU1096752A1 - Method of separate control of three-phase direct frequency converter with separated power sources - Google Patents

Abstract

A METHOD OF SEPARATED MANAGEMENT OF THREE-PHASE DIRECT-DEPENDABLE FREQUENCY FREQUENCY WITH DIVIDED POWER SOURCES by forming flow cells with phased-phase V P of the first system of pulse sequence, forming second-phase pulse flow cells with the t-phase V P circuit, forming the second flow complex flow patterns with the t-phase V c, forming the second one-phase PPS the formation of control pulses at the moments of coincidence of the pulses of two sequences, different By the fact that, in order to simplify the implementation by refusing to monitor the load current with the corresponding range of variation of the load angle, the duration of the pulses of the second sequence is set to 2L / 3. (L with t§ 7 e: O 35 U1 th

Description

The invention relates to converter equipment and can be used in commercial and industrial frequency-controlled electric drives. A three-phase frequency doubler is known, containing three single-phase bridge thyristor rectifiers connected according to a closed triangle, to the vertices of which a three-phase load is connected. The output voltage of a three-phase frequency doubler is formed from part of the sinusoidal voltage waves of the two phases of the power sources by pairwise turning on the thyristors of each of the rectifiers with a frequency shift of the supply network Lll. The disadvantage of a three-phase frequency doubler is the impossibility of continuously adjusting the frequency of the output voltage. Closest to the invention is a method of controlling a direct frequency converter with m separated power sources to which antiparallel connected gates of zero converters closed in a triangle are connected, to the vertices of which a three-phase load connected to a star is connected. The formation of the output voltage is realized by means of a definite switching on of single-phase converters by comparing the output current curve with the reference signal 2. The disadvantage of this control method is the low reliability of the control system due to its complexity. In addition, the disadvantages include a small range of variation of the output voltage and a greater current load of the valves. The purpose of the invention is to simplify the implementation of the control system by refraining from tracking the load current in the corresponding range of variation of the load angle. The goal is achieved by coordinating the method of separate control of a three-phase direct frequency converter with separate power sources by forming a first-phase pulse sequence system phased with an t-phase voltage, forming a second three-phase pulse sequence with frequency. equal to the output frequency of the converter, comparing the pulse sequences of the first and second systems and generating control pulses at the moments of coincidence of the pulses of the two sequences, the pulse duration of the second sequence being set equal to 2 (/ 3. Figure 1 is a schematic diagram of the power section of the direct frequency converter, realizing - figure 2; a schematic diagram of the power section of the direct single-phase to three-phase frequency converter; e-time diagrams explaining the principle of operation of the converter according to the proposed method. The direct frequency converter carrying out the proposed method with a three-phase power source contains six three-phase rectifying bridges 1-6, each of which has six controlled gates 7-12 , the bridges are pairwise antiparallel connected to the divided power sources 13-15. The outputs of the antiparallel bridges are connected n to a closed triangle, to the vertices of which A, B, C is connected a load 16-18, which is connected in a star. The control method of the direct frequency converter is illustrated by the example of a three-phase supply voltage (FIG. 3a). A three-phase pulse train is formed from the three-phase supply voltage. A1C1 "eiCi e-fCl wb1A1 B1D-" phased with the network (Fig. 36). At the same time, a second phase pulse sequence is formed with a frequency equal to the output frequency of the converter, and with a pulse width of 1-6, equal to 27 (/ 3 (FIG. 3c)). The pulse sequence of the given output frequency of the converter controls bridges 1-6, i.e. During the period of the output frequency of the converter, each of the axle bridges operates 1/3 of the period. Control pulses of 7-12 gates (Fig. 3 d) are formed by comparing the network pulse sequence with a given output sequence of pulses according to and with the following logic: 7%, s / v, v / 4.,. -,. The generated control pulses 7-12 are sent to control aJtiBKTpoflH of those bridge rectifier valves that are currently allowed to work. This is achieved only in the case coincidence of control impulses by bridges 1-6 with control of 1mtsi impulses of veins 7–12. Thus, phase voltages applied to the load with a given frequency are formed (FIG. 3e). In the load, currents flow, 3g, El shifted relative to phase voltages by an angle determined by the coefficient of propagation. The power factor of the consumer must lie within 0 ,. 25 24 When replacing three-phase sources with single-phase ones (FIG. 2), it is possible by the proposed method to convert the voltage of a single-phase line into a three-phase voltage with an adjustable output frequency. The proposed method of separate control of the direct frequency converter and the converter implementing this method can be applied in traction and industrial electric drives. Thus, the proposed method of separate control of a three-phase direct frequency converter significantly simplifies the schematic design of the control devices of the converter, reduces their cost and increases the reliability of operation, and in the case of connection of sets of bridge converters into a triangle, further reduce the current load. power converter valves.

FIG. 2

Claims (1)

SEPARATE CONTROL METHOD three-phase direct frequency converters with divided power source by forming a phased with _{Whitlock-phase} voltage mains system the first pulse sequences form a second three-phase pulse sequence with a frequency equal to the inverter output frequency, comparing pulse patterns of the first and second systems and generating control pulses at the moments of coincidence of pulses of two sequences, characterized in that In order to simplify the implementation by avoiding tracking the load current with a corresponding load angle change range, the pulse width of the second sequence is set to be 2A / 3. FIG. 1 d ή > “H 7 / f-C _g hG * L hg *1 - - g sl_ to g V zMTns