RU2520558C2 - Twelve-phase transformer-coupled phase converter - Google Patents

Abstract

FIELD: electricity.

SUBSTANCE: invention is related to converter equipment and may be used for manufacturing of rectifiers for direct and alternating-current electric controlled drives in order to improve their operational speed. Twelve-phase transformer-coupled phase converter consists of a three-phase converter having three wye- (or delta-) connected coils of the primary winding coupled to the three-phase network with zero wire, six interconnected coils of the secondary windings with taps from turns. Each coil of the secondary winding of the transformer is a side of the hexagon circuit that converts a symmetric three-phase system of voltage into six-phase system of voltage. Each tap of the secondary winding coil turn is one of outputs of the symmetric twelve-phase voltage system of the converter. Voltage of the twelve-phase voltage system depends on a voltage value of the six-phase system and is related to it as per the following ratio: U₁₂=U₆Cos30°/Cos15°=0.897U₆.

EFFECT: reduction of converter dimensions and weight, simplification of its design and manufacturing technology and reduction of its cost.

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Description

The invention relates to a conversion technique and can be used to create rectifiers for controlled electric drives of direct and alternating current for machines to increase their speed, as well as in converter substations for powering electrified railways, in the electrometallurgical and chemical industries to reduce the ripple of the rectified voltage and reduce the content of higher harmonic components in the AC curve in a three-phase network.

From the prior art, a three-phase AC to multi-phase converter based on Scott transformers is known (GN Vorfolomeev, SV Myatezh, NI Shurov “Five-phase bridge rectifier unit based on the Scott circuit” / Bulletin of KSTU. Transport. Issue. 39. Krasnoyarsk: Publishing House of KSTU, 2005, p.21-25).

A disadvantage of the known converters is the complex circuit of the transformer, due to the need to obtain the corresponding shift of the secondary phase voltages.

Three-phase AC to multi-phase converters are also known, using a zigzag circuit in which the transformer is equipped with an additional group of secondary windings. The groups of secondary windings are connected with the opposite phases of the additional secondary windings (Kazakov V. “Power supplies. Multiphase power transformers-converters and rectifiers” / Power Electronics, No. 4, 2006, pp. 7-15).

The disadvantage of such devices is the large number of secondary windings, which greatly complicates the design of the converter, the technology of its manufacture, leads to cost overruns and an increase in its cost.

The closest solution in technical essence and the achieved result is a phase number converter used to obtain a multiphase voltage, consisting of three single-phase transformers, each containing one primary winding, and requiring several groups of secondary windings. The well-known converter requires a three-phase network, three single-phase transformers with three primary windings connected to a three-phase network, and thirteen secondary windings that create twelve outputs of the twelve-phase voltage system (GN Vorfolomeev et al., “Overview of circuit designs for phase number converters transformers. Improving the technical means of electric transport "/ Collection of scientific papers. Issue 2. Novosibirsk, 2001, pp. 78-96).

A disadvantage of the known device is the fact that a group three-phase transformer is inferior to a three-phase three-rod transformer in terms of weight and dimensions, and the converter has a large number of secondary windings with various parameters, which greatly complicates the design of the converter, its manufacturing technology and leads to cost overruns and an increase in its cost .

The technical result of the claimed invention is the creation of such a converter architecture, which allows to reduce the consumption of active materials when replacing a three-phase group transformer with a three-rod one, which ultimately allows to improve the overall dimensions of the converter, simplify the design of the converter, its manufacturing technology and reduce its cost.

The technical result is solved due to the fact that in a twelve-phase converter of the number of phases, which is a three-phase transformer consisting of three primary coils and six secondary coils with twelve outputs of a symmetric twelve-phase voltage, according to the invention, each of the secondary coils is made with two tap spaced from the beginning and end of the coil by the number of turns equal to 0.5 (1-Tg60 ° Tg15 °) of the part from the turns of the secondary coil and connected together m nodes in one circuit in the form of a "hexagonal" so that the voltage between the nodes form a symmetric six-phase voltage system and branch line, dividing the number of secondary winding turns of each coil in relation to 0.268: 0.464: 0.268 and represent outputs symmetrical dvenadtsatifaznoy inverter voltage system.

The claimed invention is illustrated by graphic materials, where:

- figure 1 presents a diagram of a twelve-phase converter of the number of phases;

- figure 2 is a vector diagram of potentials on the secondary windings of the Converter.

A twelve-phase transformer for converting the number of phases consists of a three-phase transformer having three coils 1, 2 and 3 of the primary winding, which are connected according to the "star" (or "triangle") circuit and are connected to a three-phase network with a zero wire "0", six interconnected coils 4, 5, 6, 7, 8, 9 of the secondary winding having soldering 10, 11, 12, 13, 14, 15, 16, 17, 18, 19, 20, 21 from the turns. The beginning of the secondary coil 4 is connected to the beginning of the secondary coil 8, forming a node A, the end of the secondary coil 8 is connected to the end of the secondary coil 6, forming a node B, the beginning of the secondary coil 6 is connected to the beginning of the secondary coil 5, forming node C, the end of the secondary coil 5 is connected to the end of the secondary coil 9, forming a node D, the beginning of the secondary coil 9 is connected to the beginning of the secondary coil 7, forming node E, the end of the secondary coil 7 is connected to the end m of coil 4 of the secondary winding, forming a node F, and closing the contour of the coils 4, 5, 6, 7, 8, 9 of the secondary windings forming a "hexagon" A, B, C, D, E, F. Each coil 4, 5, 6, 7, 8, 9 of the secondary winding of the transformer is the side of the "hexagon" A, B, C, D, E, F, which converts a symmetric three-phase voltage system into a symmetric six-phase voltage system. Each tap 10, 11, 12, 13, 14, 15, 16, 17, 18, 19, 20, 21 from the turns of coils 4, 5, 6, 7, 8, 9 of the secondary winding is one of the outputs a, b, c , d, e, f, g, h, k, l, m, n of a symmetric twelve-phase voltage system of the converter. The phase angle of a symmetric twelve-phase voltage system can be determined from the expression: 360 °: 12 = 30 °. The voltage of the twelve-phase voltage system depends on the voltage of the six-phase system and is connected with it by the ratio: U ₁₂ = U ₆ Cos30 ° / Cos15 ° = 0.897U ₆ , which follows from the consideration of rectangular triangles (0-С-22) and (0-е- 22) :( 0-22) = U ₆ Cos30 ° = U ₁₂ Cos15 °, where 15 ° = 30 °: 2.

Now we determine the position of the taps 10, 11,12, 13, 14, 15, 16, 17, 18, 19, 20, 21 from the turns of the coils 4, 5, 6, 7, 8, 9 of the secondary windings using the example of the secondary coil 5. To do this, we use the vector diagram (figure 2), taking the number of turns of the coil 5 of the secondary winding in proportion to the length of the voltage vector on the coil 5 of the secondary winding. We take the length of the voltage vector in the phase of the six-phase polygon per unit. Soldering 12 and 13 from the turns of the coil 5 of the secondary winding divide its number of turns in a ratio determined by the ratio of the segments (C-e), (ef) and (fD). Line (C-e) = (fD) = U ₆ Sin30 ° -U ₁₂ Sin15 °. Expressing U ₁₂ through U ₆ after transformations, we obtain: (С-е) = 0,5U ₆ (1-Tg60 ° Tg15 °) and the following ratio of the number of turns from which the soldering is performed: (0,5-Tg60 ° Tg15 °) : (Tg60 ° Tg15 °) :( Tg60 ° Tg15 °) :( 0.5-Tg60 ° Tg15 °) = 0.268: 0.464: 0.268.

The work of the twelve-phase transformer of the number of phases is as follows. When a three-phase transformer is connected to a three-phase network, three magnetic fluxes appear in the rods of the magnetic circuit of the transformer, phase shifted relative to each other by a third of the period or in degree measurement by 120 °. The implementation of the secondary winding for each phase in the form of two coils on the rod of each phase allows you to get two secondary voltage with opposite polarity (with a shift of 180 °). Thus, with three mains voltages phase-shifted by 120 °, six secondary voltages are obtained, phase-shifted relative to each other by 60 °. When connecting six coils 4, 5, 6, 7, 8, 9 of the secondary windings as described above, a six-phase “hexagon” A, B, C, D, E, F is obtained with a symmetric six-phase voltage system on coils 4, 5, 6, 7, 8, 9 of the secondary winding. The analysis showed that on the turns of the coils 4, 5, 6, 7, 8, 9 of the secondary winding, forming a "hexagon", you can find twelve outputs a, b, c, d, e, f, g, h, k, l , m, n, whose potentials are equal in magnitude, but differ in phase by one twelfth of the period (which in the degree measurement is 360 °: 12 = 30 °), and obtain a symmetric twelve-phase voltage system of the converter.

Thus, the claimed architecture allows to reduce the consumption of active materials when replacing a three-phase group transformer with a three-rod one, which ultimately allows to improve the overall dimensions of the converter, simplify the design of the converter, its manufacturing technology and reduce the cost.

The analysis of the claimed technical solution for compliance with the conditions of patentability showed that the characteristics indicated in the independent claim are interrelated with each other with the formation of a stable set of necessary features, unknown at the priority date from the prior art, sufficient to obtain the required synergistic (over-total) technical result.

The properties regulated in the claimed invention are connected by individual features, are well known from the prior art and do not require additional explanation.

Thus, the above information indicates the fulfillment of the following set of conditions when using the claimed technical solution:

- the object embodying the claimed technical solution, in its implementation is intended for use in the creation of adjustable electric drives of direct and alternating current;

- for the claimed object in the form described in the independent claim, the possibility of its implementation using the means and methods known from the prior art on the priority date on the priority date has been confirmed;

- the object embodying the claimed technical solution, when implemented, is able to ensure the achievement of the technical result perceived by the applicant.

Therefore, the claimed object meets the requirements of patentability “novelty”, “inventive step” and “industrial applicability” under applicable law.

Claims (1)

A twelve-phase transformer for converting the number of phases, which is a three-phase transformer consisting of three coils of the primary winding and six coils of the secondary winding with twelve outputs of a symmetric twelve-phase voltage, characterized in that each of the coils of the secondary winding is made with two soldering spaced from the beginning and end of the coil to the number of turns of 0.5 (1-Tg60 ° Tg15 °) of the part from the turns of the secondary coil and connected together by nodes in one circuit in the form of a "hexagon" so that the voltages between the nodes form a symmetric six-phase voltage system, and the soldering, dividing the number of turns of each coil of the secondary winding in the ratio of 0.268: 0.464: 0.268 and represent the outputs of the symmetric twelve-phase voltage system of the Converter.

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