SU1084932A1 - A.c.voltage-to-d.c.voltage converter - Google Patents

Abstract

CONVERTER AC to DC comprising two three-phase transformer, the primary winding of the first of which is connected of the star, and the secondary windings of both soedi11 transformers Nena sequentially scheme zigzag and connected to the AC diagonal of a three-phase rectifying unit bridge output by a constant which tku connected to the output pins, characterized in that, in order to ensure the regulation of the input voltage, the thyristor keys are entered, each of the free pins being primary the windings of the first transformer through an appropriate thyristor switch connect it to the input terminal for connecting one of the phases of the mains supply, and the primary windings of the second transformer are connected in phase to the primary winding of the first transformer and each of their free terminals is connected to the input terminal relation to the primary winding of the first transformer, the phase of the mains. O 00 CO 00 tc

Description

The invention relates to ctraoBofi converter technology and can be used as a regulated power source for direct current loads with a limited input voltage control range (up to 3: 1) with high energy requirements. An alternating voltage converter with a transformer is known, the secondary winding which is made with taps connected to the output pins via the thyristor keys C1 1. The disadvantage of this device is the limited power. The closest to the invention is an AC voltage to DC converter containing two three-phase transformers, the primary winding of the first of which (connected to a star, and the secondary windings of both transformers are connected in series in a zigzag circuit and connected to a diagonal of an AC three-phase rectifying bridge , the DC output of which is connected to the output terminals 23. He | a drift of the known converter is the impossibility of ensuring the control of the input voltage. Invention is to provide input voltage regulation. The goal is achieved by the fact that the AC voltage to DC converter contains two three-phase transformers, the primary winding of the first of which is connected to a star, and the secondary windings of both transformers are connected sequentially; zigzag and podkoscheny to the diagonal of the alternating current of the three-phase rectifying bridge, the DC output of which is connected to the output pins, thyristor switches are inserted, each of the free terminals of the primary winding of the first transformer through an appropriate thyristor key is connected to the input terminal for connecting one of the phases of the power supply network, and the primary windings of the second transformer are connected phasewise to the primary winding of the first transformer and each of their free terminals is connected to the input terminal for connecting an adjacent, relation to the primary winding of the first transformer, the phase of the mains. Fig. 1 is a schematic diagram of the converter in Fig. 2; vectorial diagrams of the voltage of the converter; FIG. 3 shows one of the possible modifications of the converter when the adjustment range J is changed in FIG. 4; vector diagrams of the converter voltages. The AC voltage to DC converter (Fig. 1) contains an uncontrolled valve bridge 1, the output terminals 2 and 3 (- and +) of which are used to connect the load, and the input terminals 4-6 AC are connected to the output terminals of the secondary winding of the first transformer 7, the input terminals of the primary winding of which are connected to the phase terminals A, B and C of the three-phase supply network through the block of 8 pairs of parallel-counter thyristors (thyristor switches) о The primary phase windings of the transformer 7 are marked A, B and C, and its secondary phase winding - CZ | 2 jb and C2. The primary winding of the transformer 7 is connected in a star, and the free terminals of the phases of its secondary winding are connected to the corresponding phases ("h, bj and Cz) of the secondary winding connected in a star, of the second transformer 9 in a phase-zagzag pattern. The phases of the primary winding (A, E and C;) of the transformer 9 are connected between one phase terminal of the supply network A, B, C and the common connection point of the corresponding pair of parallel-thyristors and the input terminal of the previous phase of the primary winding of the first transformer 7 and 10 12 - secondary winding terminals transformer 9. The converter shown in Fig. 3 is distinguished only by the connection of the secondary winding of the transformer 9 in a triangle. The Converter (figure 1) works as follows. The output voltage level of the gate bridge 1 (respectively, the voltage at terminals 4-6) is controlled by continuously changing the switching angles or the duration of the on state of the thyristors of parallel-opposite pairs of block 8. When the thyristors of the block 8 are off, i.e. in the absence of thyristor unlocking pulses, the primary windings of transformers 7 and 9 are interconnected in series, and the formation of output voltages on the shafts 4-6 corresponds to the vector diagram in FIG. 25, and in FIG. 2o (power supply voltage diagrams are given to match the position of the vectors in Fig. 25 relative to each other. The primary winding of each transformer is supplied with voltage (1 + T3) for less than nominal. With fully turned on (unlocked at their angles natural switching) thyristors of block 8 primary windings of transformers 7 and 9 are connected between themselves in parallel (respectively V .. C - star and A B% triangle), each for its own nominal voltage. In this case, the formation of output voltages at the terminals max A - 6 corresponds to the diagram (Fig. 28). Compared with the diagram of Fig. 2, the lengths of the corresponding stress vectors are increased by (1 + P) times and, moreover, the angle is increased from 2U / 3 (Fig. 25) to 5f / 6 (Fig. 2b) between the two vectors that form each of the voltage vectors at terminals 4-6. This leads to an additional 11.5% increase in the range of adjustment of the output voltage system at terminals 4-6 compared to the adjustment range magnetizing systems of primary windings. The total range of adjustment of the output voltage when the interval of the on state of the thyristors of block 8 changes from zero to the adjustment period is equal to 1.115 (1 + Хз): 1 3.05: 1. Limiting the range of adjustment of the output voltage leads to an increase in the energy indices (power factor) throughout the practically used part of the regulating characteristic and especially at the minimum power consumption. The total installation (typical) power of transformers 7 and 9 in the considered converter is almost equal (exceeds by 3.5%) the maximum current-voltage power at the input of the valve bridge 1. Transformers 7 and 9 have the same typical power and are equally used (among themselves) for all adjustment range. Converter (fig.Z) works in a similar way. The diagrams in FIGS. 4a and b are similar to the diagrams in FIGS. 25 and B and correspond to the case when the secondary windings of the second transformer 9 are connected in triangle. The positive effect of the invention is to increase the energy performance (power factor) of the converter as a whole and increase the efficiency of its transformer equipment, including the identical use of both transformers over the entire control range, which is achieved by a certain scheme of connecting the primary and secondary windings to the elements of the known devices.

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Claims (1)

AC VOLTAGE CONVERTER TO CONSTANT, containing two three-phase transformers, the first winding of the first of which is connected to a star, and the secondary windings of both transformers are connected in series according to the zigzag circuit and connected to the diagonal of the AC three-phase rectifier . I . bridge, output at a constant ¹ ? '- current of which is connected to the output terminals, characterized in that, in order to ensure regulation of the input voltage, thyristor switches are introduced, each of the free terminals of the primary winding of the first transformer through the corresponding thyristor switch nen with an input terminal for connecting one of the phases of the supply network, and the primary windings of the second transformer are connected in phase with the primary winding of the first transformer and each of their free terminals is connected an input terminal for connecting adjacent with respect to the primary winding of the first transformer, the mains phase. With about —..... .... = S and „, .1084932