UA102354C2 - Electric three-phase transductor reactor - Google Patents

Abstract

The invention relates to electrical engineering and may be used in an electrical circuit for reactive power compensation, voltage stabilization, etc. The reactor comprises three upper and three lower vertical rods. Two section windings arc disposed on the rods. Horizontal yokes have two middle and two end sections, and four magnetic shunts in the form of rectangular frames. The horizontal sections of the shunts are disposed on the ends of the windings along the upper, middle and lower yokes, and the vertical sections are disposed along the lateral yokes. The reactor windings are connected to a three-phase circuit and to controllable semiconductor transducers. Non-magnetic gaps are formed in the sections of the middle horizontal yoke. Each magnetic shunt has two additional vertical sections between the windings. The ratio of the sizes of the non-magnetic gaps of the middle yoke in the end sections Δand in the middle sections Δis 1.5<( Δ/ Δ)<3, that between the cross section of the steel of the middle sections of the middle yokes S; and the cross section of the rods S is 0.9<(S/S)<1.3, that between the cross section of the steel of all other sections of the yokes Sand S is 0.7<(S/S)<0.9, and that between the cross section of the steel of all parts of the magnetic shunts S, and S is 0.07<(S/S)<0.3.

Description

rectangular three-window frame.

Fig. 6 shows the electrical diagram of the reactor.

The magnetic system of the reactor, charged from sheets of electrotechnical steel, consists of the main magnetic circuit and four magnetic shunts.

The reactor magnet wire (Fig. 1-4) contains six coaxial rods - three upper ones 1, 2, Z and three lower ones 4, 5, 6. On each rod there is a winding consisting of two sections 7 and 8. There are two side vertical yokes 9 and 10, as well as three horizontal yokes - the upper yoke 11, the lower yoke 12, and the middle yoke 13. The cross-section of the steel of the rods - 5, the cross-section of the steel of all yokes except the middle yoke - sia, the cross-section of the steel of the middle yoke - Oser. ravine.

Each of the horizontal ravines 11, 12 and 13 has four sections: two extreme and two middle.

All sections of the middle horizontal yoke 13 have non-magnetic gaps 14 (the size of the gap in the middle sections Lmiddle) and 15 (the size of the gap in the extreme sections LAext.).

Each of the four magnetic shunts 16 is made in the form of a rectangular three-window frame (Fig. 5).

The horizontal parts of the shunts are located on the ends of the windings (between the ends of the windings 7 and 8 and the pressing beam 17, Fig. 3). Shunts 16 have two middle vertical parts 18 located between the windings.

All parts of the magnetic shunts have a section of steel 5 mm.

The electrical diagram of the reactor (Fig. 6) contains three phase inputs of network A, B and C.

Two sections 7 and 8 of the winding on the upper rod 1 of phase A have taps A1-A2 and AZ-A4, on the lower coaxial rod 4 - taps A5B-Ab and A7-AB8. Two winding sections on the upper rod 2 of phase B have taps B1-B2 and B3-8B4, on the lower coaxial rod 5 - 85-86 and B7-B8. Two sections of the winding on the upper rod of phase C have taps C1-C2 and C3-C4, on the lower coaxial rod 6 - C5-Sb and C7-C8.

The windings are connected in a scheme of two triangles and connected to the three phase inputs of the network A, B and C.

Between each two sections of the windings of each rod, a converter is connected, which consists of a diode D and a resistor AB connected in parallel: a converter Pa is connected between taps A2 and AZ, a converter Pg is connected between taps Ab and A7, between taps B2 and VZ - a converter

Half, between taps Vb and B7 - converter Pgv, between taps C2 and C3 - converter Pis, between taps Sb and C7 - converter Pgs. The terminals of the converters are marked in the same way as the taps of the parts of the windings to which they are connected. In all B-type converters, diodes D and resistors B are the same.

Insulating three-winding transformers Ta, Tv and Ts are installed between the control system (SC) and the converters. Each primary sectioned winding of the transformer is connected by its terminals (Utd-Ugla, Uiv-Ugv and Uis-Ugs) to the SC. Each of the two secondary windings is connected to the taps of the sections of the control windings and the terminals of the converters. In transformer Ta, one secondary winding is connected to taps A2 and Ab and at the same time to the terminals of the converter A2g and Ab, the second - to taps AZ and A7 and at the same time to the terminals of the converter AZ and A7. In transformer Tv, one secondary winding is connected to taps B2 and Vb and terminals B2 and Vb, the second - to taps VZ and B7 and terminals VZ and B7. Transformer Tc has one secondary winding connected to taps C2 and Сb and terminals

C2 and C6, the second - with leads NW and C7 and terminals NW and C7.

Converters and isolating transformers are placed on the assembly panel 19, fixed on the removable part (Fig. 2). The removable part - the magnetic system of the reactor (magnet wire and shunts) with windings and structural elements of pressing - is placed in a tank with oil.

Consider the operation of the reactor.

The reactor is connected to the three-phase network through inputs A, B and C, and the network voltage is applied to the reactor windings.

To transfer the reactor to the minimum power mode - idling mode - the SC control system provides minimum resistance at the terminals Uid-Ugl, Uiv-Ugv and Uis-Ugs. Since the isolating transformers TA, Tv and Ts are in the short-circuit mode, and their leakage resistance is small, the taps of the sections of the windings A2 and AZ, Abi A, B2 and B3, Vb and B7, C2 and C3, Сb and C7 are practically short-circuited in pairs . At the same time, each of the converters Pd and Pol, Piv and Pov, Pis and Pos is practically short-circuited, and there is no magnetization of the magnetic cores.

In the case when the SC control system connects the maximum resistance to the Utd-Uga, Uyiv-U2v and U1s-U2s taps, the reactor switches to the maximum power mode - the mode of full-cycle saturation of the rods. This happens due to the fact that diodes D of the converters Pid, Pol, Piv, Pgv, Pis and Pes are connected to the taps of the sections of the windings A2 and AZ, AZ and A7, B2 and VZ, Vb and B7, C2 and C3, Sb and C7.

Intermediate modes from idling mode to maximum power mode are provided by the IC control system according to a given program (for example, to stabilize the network voltage) or with manual adjustment. At the same time, the nominal power mode is usually set for one of the intermediate modes - the reactor mode with semi-periodic saturation. In this mode, the steel of each reactor rod is in a saturated state for half of the period. This mode is characterized not only by minimal (theoretically zero) distortion of the reactor current by higher harmonics, but also by optimal consumption of active materials and optimal losses in the windings.

Isolating transformers are installed between the SC (it is located on the control panel in the room) and the converters, which ensure the absence of galvanic contact and increased safety of personnel and low-voltage equipment from the possible impact of high network voltage on the SC (for example, in emergency situations). The converters together with the isolating transformers are placed on panel 19 in the reactor tank located on the open site of the substation.

Non-magnetic gaps 14 and 15 are made in the sections of the middle horizontal yoke 13 of the magnet wire. These gaps are necessary in order to expand the limits of reactor power regulation. The size of the non-magnetic gaps should be minimal, during the design of the reactor, it is chosen based on the technological possibilities of production and is usually fractions or units of millimeters.

In the magnetic circuit, the value of the non-magnetic gap at the extreme parts of the middle Akrain yoke. should be smaller than the value of the non-magnetic gap in the middle sections of this yoke Asredn. In (1.5--33) times, i.e. 1.5 " (Average / Extreme) "3.

The upper limit should not be exceeded, otherwise the magnetic flux dissipation on the extreme vertical parts of the shunt will be reduced, and on the middle ones will be increased. Also, the lower limit must be observed, otherwise the magnetic leakage flux will be increased at the extreme vertical parts of the shunt, and will be reduced at the middle vertical parts of the shunt. The implementation of the optimal ratio of the sizes of the gaps makes it possible to obtain a favorable distribution of magnetic inductions on the rods, yokes and shunts, as well as minimal consumption of steel with maximum efficiency of the shunts from the point of view of unloading the main magnetic conductor of the reactor and reducing additional losses in the structural elements and the tank wall.

The selection of the cross-sectional area of steel of all sections of the magnetic conductor is of great importance.

The ratio between the cross-section of steel sections of the middle Oseryar yoke and the cross-section of rods 5 should be chosen within 0.9 " (Zseryar. /5)-1 Z.

The ratio between the steel cross-section of all other sections of the Bur ravine. and the cross-section of rods 5 - should be chosen within 0.7 " (Zyar/5) " 0.9.

If the cross-section of the yoke steel exceeds the maximum limit, the reactor will have increased consumption of steel in the yokes. If the cross-section of the steel yoke is less than the minimum value, then steel saturation occurs in the reactor yokes in certain modes of its operation. This leads to unfavorable phenomena - an increase in additional losses due to eddy currents in structural elements, an increase in nonlinear distortions in the reactor current.

Magnetic shunts 16 effectively "channel" the magnetic leakage flux that occurs when the current flows in the windings, that is, in all modes when the rods are magnetized. The magnetic leakage flux circulates in the axial direction inside the windings and is closed on the yokes of the magnetic system and on the magnetic shunts. If there are no magnetic shunts 16, then the magnetic flux closes along the structural elements and the tank wall, causing eddy currents, additional losses and unacceptable heating in them. For effective closing of the magnetic flux in the shunts, medium longitudinal vertical sections 18 located between the windings are provided. These two additional (compared to the prototype) vertical sections are necessary for the optimal distribution of magnetic scattering fluxes and the reduction of total steel costs in the shunts and magnetoconductor.

The steel cross-section of the magnetic shunts should be larger, the larger the radial size of the windings, because when the reactor is loaded, there is an increased magnetic leakage flux (compared to the magnetic flux in the rods and yokes of the magnetowire in idle mode).

The ratio between the cross-section of steel of all parts of each of the magnetic shunts Z»sh and the cross-section of the rods

Z must be selected within 0.07 " (Zshsh/5) "0.3.

If the steel section of the magnetic shunts is chosen to be larger than the maximum value of the given ratio, there is an overconsumption of steel. If the steel section of the shunts is less than the minimum value, then the shunts become less effective and do not screen the windings dissipation flow. This leads to unfavorable phenomena - the increase of magnetic induction in the magnetic circuit, the main losses in the steel and additional losses in the structural elements.

The proposed "three-window" shunt design, improved compared to the prototype, ensures optimal distribution of the magnetic fluxes of the reactor, and, therefore, optimal consumption of steel in the magnetic system.

All considered limits of optimal size ratios were determined as a result of the analysis of numerous calculations on mathematical models of magnetization-controlled reactors in a wide range of variation of their parameters. If necessary, the detailed results of these calculations can be provided to the expert.

A high-voltage reactor is usually performed with oil cooling. Removable part -

the magnetic system of the reactor (magnet wire and shunts) with windings and structural elements of pressing - is placed in the oil tank, and the reactor inputs - on the tank cover. Converters and isolation transformers are placed in the same tank on a collection panel fixed on the removable part.

The performance of the proposed reactor and its high technical and economic indicators are confirmed by calculations, physical modeling, and the results of research on prototypes of similar designs. In the proposed reactor, compared to analogs and the prototype, steel consumption is reduced, losses are reduced, reliability is increased, as well as labor costs during manufacturing, dimensions and weight are reduced. Prototypes for serial production are planned for the near future.

Sources of information: 1. Bryantsev A.M. "Electric reactor with magnetization". Patent of the Russian Federation Mo VO 2324251, application: 2006146290/09, 26.12.2006. Published: 05/10/2008. 2. Bryantsev A.M. "Electric reactor with magnetization". Patent of the Russian Federation Mo VI 2324250, application: 2006145299/09, 20.12.2006. Published: 05/10/2008.

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