SU1019568A1 - Am-phase electric power supply converting system - Google Patents

Abstract

1. 2m FAZNAI converter power system comprising three phase step-down transformer, the primary of which is connected with bmotka vyuodami for connecting the mains, ie two-phase converter unit, each consisting of m-phase transformer connected to its windings vtorichnmi vtr mitelny '1 and bridges, the outputs of which are connected to the output pins, and a compensating device in the form of a three-phase reactor and a three-phase capacitor battery connected to it, connected between the secondary circuit with a three-phase step-down transformer, the first and second converter units, in order to simplify, the compensator device of the compensating device is made with three three-phase windings, and the secondary three-phase winding of the step-down transformer made with the Treugshnnyk connection scheme with continued beginnings and the ends of the phase windings, and the conclusions of the beginnings of the phase windings of this transformer through the first three-phase winding of the compensating reactor are connected to the primary winding -phase transformer of the first t-phase converter unit, the conclusions of the ends of the phase transformers through the second three-phase o6M6T Of. reactor,. A compensating device is connected to the primary winding of the transformer of the second T-phase converter unit, and to the third, connected in a star, three-phase winding of the reactor, a connected in a star three-phase capacitor is connected. battery 2. The power supply system according to claim 1, from l and tha with the fact that the first three-phase winding of the reactor of the compensating device is connected according to the Zigzag scheme, which shifts the phase voltages by the angle of el.grad, and the second three-phase winding of this reactor is connected according to the Zigzag scheme, (L shear phase voltages at the angle of el.grad. 3. The power supply system according to claim 1 from L and the fact that the first three-phase winding of the reactor of the compensating device is connected in a triangle circuit with doped beginnings of phase windings, shear 10- , SP O1 Sliver Phase Vol. and the electric winding of the second winding of this reactor is connected according to a triangle with the other ends of the phase windings, 00 shifting the phase voltages by l el degrees 2 t 4. The power supply system according to claim 1, wherein that, in order to limit the short-circuit current in the t-phase converter units, the secondary three-phase winding of the step-down transformer was split into two parts, with one part extended to the | Chala phase windings. and the other: the ends of the phase syncope.

Description

The invention relates to power converter technology and can be used to power high-power consumers (for example, electrolysis series, electric furnaces, etc., both stationary and non-stationary rectified current. It can also be used for reverse power supply of high-power consumers. Known 2t- phase () non-compensated converter power supply system, containing two twelve-phase converter units connected in output in parallel, each of which consists of a transformer with at least two secondary three-phase windings connected one to a star, and the other to a triangle, each of which is connected to the rectifier of the power supply unit. The primary winding of the transformer of the first unit is connected according to the scheme of the Triangle with continued beginnings of phase windings, providing a secondary shift phase voltage at an angle of +7.5 al.grad. The primary winding of the transformer of the second converter unit is connected according to the Triangle scheme with the extended ends of the phase windings, providing a shift of the secondary phase voltage Angle angle -7.5 al. This system has a good harmonic composition of the mains current and rectified voltage, which meets two to four to four phase conversion modes. However, this system also has significant drawbacks, since it requires a special circuit for connecting the primary windings of transformers for all converters In addition, it, like any uncompensated system, has a rather low power factor of 113 for significant power consumption from the supply network of reactive power. The technical essence of the invention is a 2-phase converter power supply system comprising a three-phase step-down transformer, the primary winding of which is connected to the terminals, for connecting the supply mains, two t-phase converter units, each consisting of a t-phase transformer with connected to its secondary windings - rectifying bridges, the outputs of which are connected to the output terminals, and a compensating device in the form of a three-phase reactor and a three-phase condensate connected to it battery, included by the secondary winding of a three-phase step-down transformer, the first and second pre-3; 3-core HZZ blocks. A disadvantage of the known system is the design complexity, because all TT-transformer units have a special circuit of the primary winding of transformers Triangle with extended sides. In addition, the system usually makes it difficult to regulate the rectified voltage of each of the converter units by switching from the primary windings of the transformer, because the number of turns in the triangle of the primary winding and its continuations must be changed simultaneously. . The disadvantages of the system should be attributed to the complexity of its implementations in existing power supply systems, since this requires the modernization of all converter transformers. The aim of the invention is to simplify the 2-phase inverter power supply system. The goal is achieved by the fact that in a 2-phase converter power supply system, there is a three-phase step-down transformer, the primary winding of which is connected to the terminals for connecting the supply network, two t-phase converter units, each consisting of a t-phase transformer connected to its secondary windings are rectification bridges, the outputs of which are connected to the output terminals, and a compensating device in the form of a three-phase reactor and a three-phase capacitor battery connected to it, the key between the secondary winding of the three-phase step-down transformer, the first and second converter blocks, the compensating device's reactor is made with three three-phase windings, and the secondary three-phase winding of the step-down transformer is connected with a Triangle connection circuit with extended beginnings and ends of the phase windings, and the leads of the phase windings of this transformer the first three-phase winding of the compensating device is connected to the primary winding of the t-phase transformer and the First T-phase converter unit, the outputs of the ends of the phase windings through the second three-phase reactor winding of the compensating device are connected to the primary winding of the transformer of the second T-phase converter unit, and to the third, connected in a star, three-phase winding of the reactor connected to the star in a three-phase transformer capacitor battery. In order to eliminate in rods the reactor magnetic cores of the compensating device the magnetic flux of the first harmonic and, consequently, eliminate the first harmonic current in the capacitors, the first three-phase winding of the compensating device is connected either according to the Zigzag scheme or the Triangle with the continuation of the phase windings, - shifting phase voltages on + j el.grad, and the second is similar winding is connected either according to the Zigzag scheme, or according to the scheme. A triangle with extended ends of the phase windings shifting the phase voltages to the - - electr. Grade To limit the short-circuit currents in the t-phase converter units, the secondary three-phase coupling of the step-down transformer can be split into two parts, with one part continuing the beginning of the phase windings, and the other - the ends of the phase windings. , The rectifying bridges of the t-phase converter units are connected in series or parallel to the load. . Relay bridges are either reversible or non-reversible. All HEEJe transformers are standard systems, without special winding connection diagrams. The drawing shows a schematic diagram of a 2-phase transform. power supply system. The system contains a step-down three-phase transformer 1, a three-phase compensating device 2, the first 3 and the second 4 t-phase converters. blocks, During operation of the t-phase converter power system, a special connection circuit of the secondary winding of the three-phase transformer 1 is provided for shifting the coupling processes in time of the second t-phase converter unit 4 to the first block 3 on. angle el.grad, thanks to which the entire power supply system operates in 2T-phase mode. go transform. When the compensating device 2 is switched on, in its main windings connected to blocks 3 and 4, the current harmonics shifted by e-grad are of the order of Kt ± 1 (K O, 1, 2,., 1). Since the first main winding of the reactor is connected according to the scheme, the phase voltages at + W-el. Degrees, the second - according to the scheme, which shifts the phase voltages to el. Degrees, the first harmonics of the magnetic flux in the rods of the reactor magnetic circuit of the compensating device are absent due to equal to zero on each wiped out Le of the total magnetomotive force of the first and second windings in the first harmonic. Only the harmonics of the flow corresponding to K 1, 3, 5, ..., flow into the rods of the reactor magnetic circuit of the compensating device, since on each rod the total magnetic-driving force of the first and second reactor windings for these harmonics is not equal to zero. These harmonics of the flow induce voltages of the same harmonics in the compensating windings of the xenix device, and hence on the capacitors of the compensating device 2, the voltages on the capacitors are transformed by the EFV into the switching circuits of the gates of blocks 3 and 4 and carry out their artificial switching, thanks to which Works with high power factor. The regulation of the rectified voltage is realized by conventional converter transformers of the system. Additionally, it can be controlled by switching the offsets from the primary winding of the step-down transformer. If there is no need to increase the power factor by compensating the device, the conclusions of the beginnings of the secondary windings of the step-down transformer under1 & directly to the input of the first ha-phase converter unit, the outputs of the ends of the phase windings of the step-down transformer to the input of the second t-phase 6 of the converter unit, Tekhmyko-economic The effect of using the present invention is that. All system transformer transformers are simplified by using primary windings with a conventional wiring diagram (Star or Triangle). The proposed system is easily implemented on existing converter stations, for example, electrolysis in the non-ferrous metallurgy and chemical industry, without reconstructions of a large number of converter transformers. To implement it, only the secondary winding structure of the step-down transformer is needed. In addition, the functionality of the sigma expands because it is possible to simply adjust the rectified voltage, nor can the system not only by

Claims (4)

454) 1. 2-PHASE CONVERTER SYSTEM OF POWER SUPPLY, containing a three-phase step-down transformer, the primary winding of which is connected to the terminals for connecting the mains, two m-phase converter blocks, each consisting of a t-phase transformer with rectifier bridges connected to its secondary windings, the outputs of which are connected to the output terminals, and a compensating device in the form of a three-phase reactor and a three-phase capacitor bank connected to it, connected between the secondary winding phase lowering transformer, the first and second conversion units, which is related to the fact that, for simplicity, the reactor of the compensating device is made with three three-phase windings, and the secondary three-phase winding of the lowering, transformer is made with connection diagram A triangle with extended beginnings and ends of phase windings, and the conclusions of the beginnings of the phase windings of this transformer through the first three-phase winding of the compensating reactor, the devices are connected to the primary winding of the m-phase transform the torus of the first m-phase converter unit, the terminals of the ends of the phase windings through the second three-phase winding of the reactor .. the compensating device is connected to the primary winding of the transformer of the second m-phase converter unit, and the connected to the third, connected to the star, three-phase reactor winding is connected into a three-phase capacitor star. battery. 2. Power supply system according to π. 1, starting with the fact that the first three-phase winding of the reactor of the compensating device is connected according to the Zigzag circuit, which moves the phase voltages by an angle of electric degrees, and the second three-phase winding of this reactor is connected according to the Zigzag circuit, which moves the phase voltages on the corner - electric city. 3. Power supply system according to π. 1, starting with the fact that the first three-phase winding of the reactor of the compensating device is connected in a triangle pattern by the extended beginnings of the phase windings, I shift the phase voltage to + ~ - electric grad, and the second the winding of this reactor is connected according to the triangle scheme with the other ends of the phase windings, ^f shifting the phase voltage by e. hail. 4. The power supply system according to claim 1, characterized in that, in order to limit the short circuit current in the w-phase converter units, the secondary three-phase winding of the step-down transformer. made split into two parts, with one part continuing the beginning of the phase windings, and the other ends of the phase windings.