RU105524U1 - THREE-PHASE TRANSFORMER - Google Patents

Abstract

 1. Three-phase transformer containing a core magnetic core, clamped by two parallel yokes, each core of the magnetic core is located at an equal distance from each other and is covered by the same primary winding and a group of secondary windings, characterized in that the upper and lower radiators are introduced into it, made with understatements internal surfaces and interconnected by fasteners, while each secondary winding is made in the form of a coil in a monolithic insulating casing with symmetrical through grooves on the external end surfaces of the housings passing through the axes of the inner central holes, parallel yokes being placed on one side in the grooves of the housings, and on the other hand, in the understatements of the upper and lower radiators with installation on a heat-conducting compound, while the gaps between the primary winding and the core of the magnetic circuit and between the primary winding and the secondary winding are filled with an insulating heat-conducting compound. ! 2. The three-phase transformer according to claim 1, characterized in that the symmetrical through grooves are U-shaped, the width of which is commensurate with the central inner cylindrical hole of the primary winding and the understatements made on the inner surfaces of the upper and lower radiators. ! 3. The three-phase transformer according to claim 1, characterized in that the understatement on the inner surfaces of the upper and lower radiators is rectangular in plan and commensurate with the yokes. ! 4. The three-phase transformer according to claim 1, characterized in that the secondary coil is multi-sectional.

Description

The utility model relates to the field of electronics and can be used in the design of three-phase transformers.

A three-phase transformer is known from the prior art (Utility Model Certificate RU No. 71811, published March 20, 2008, IPC: H01F 30/12; H01F 27/34) containing a flat magnetic system consisting of three O-shaped magnetic cores wound from tapes of transformer steel and located in one plane, three primary and three secondary windings located on the frame. In order to reduce the no-load current, the wound magnetic circuits are made integral, and the frame for the windings is made integral.

The disadvantage of this device is that the three-phase transformer is not compact enough and has a low electrical and mechanical strength.

A three-phase transformer is known from the prior art (Application RU No. 20011114198, published May 10, 2003, IPC: H01F 27/25, H01F 30/12) containing a magnetic circuit and three coil blocks. The magnetic circuit contains two spaced apart parallel plate-like elements and three spaced apart in space parallel columnar elementary chains. Moreover, each column is made with the possibility of carrying the corresponding one of the three coil blocks and servicing the corresponding one of the three phases, the columns being almost perpendicular to the plate-shaped elements and enclosed between them, with the possibility of forming a structure spatially symmetric with respect to the central axis of the transformer.

The disadvantages of this device include inefficient heat removal from the magnetic circuit and windings.

The closest in technical essence and the achieved results to the proposed technical solution is a transformer (RU Patent for the invention No. 2396625, published on 08/10/2010, IPC: H01F 30/12). The transformer contains a core magnetic core, clamped by two parallel yokes, each rod is located at an equal distance from each other and is covered by the same primary winding and a group of secondary windings, which contains two counter secondary windings with the number of turns Nk ₀ , two secondary windings with the number of turns Nk ₁ and two of the same counter secondary windings, two secondary windings with the number of turns Nk ₂ and two of the same counter secondary windings, two secondary windings with the number of turns Nk ₃ and two of the same counter secondary windings, g de N is the maximum number of turns, k is the coefficient of the number of turns, and k ₀ = 1, k ₁ = (1 + 1/3 ^1/2 ) / (2cos15 °), k ₂ = 1/3 ^1/2 , k ₃ = 1 (2 · 3 ^1/2 cos15 °). Moreover, one secondary winding with the number of turns Nk _{3 of the} first rod is connected in series with a counter secondary winding with the number of turns Nk _{3 of the} second rod, and the second with the same winding of the third rod facing it. One secondary winding with the number of turns Nk _{1 of the} second rod is connected in series with the secondary winding of the counter winding with the number of turns Nk _{3 of the} first rod, and the second with the same counter winding of the third rod. One secondary winding with the number of turns Nk _{1 of the} third rod is connected in series with the secondary winding of the counter winding with the number of turns Nk _{3 of the} first rod, and the second one with the same counter winding of the second rod. Similarly, the remaining counter secondary windings are connected with the number of turns Nk ₁ and Nk ₃ . One secondary winding with the number of turns Nk _{2 of the} first rod is connected in series with the secondary winding of the counter winding with the number of turns Nk _{2 of the} second rod, and the second with the same winding of the third rod facing it. One secondary winding with the number of turns Nk _{2 of the} second rod is connected in series with the secondary winding of the counter winding with the number of turns Nk _{2 of the} first rod, and the second with the same counter winding of the third rod. One secondary winding with the number of turns Nk _{2 of the} third rod is connected in series with the secondary winding of the counter winding with the number of turns Nk _{2 of the} first rod, and the second with the same winding of the second rod that meets it, forming zigzag connections, the free leads of which, as well as and secondary windings with a number of turns Nk ₀ , form a sequence of multiphase transformer outputs. In this case, the transformer magnetic core is made flat four-core, with the cross-sectional area of the extreme rods being half the area of the rods located between them, and all windings covering one extreme rod are connected in series and in accordance with the same windings covering the other extreme rod.

The disadvantages of this device include insufficient compactness, electrical and mechanical strength, as well as inefficient heat removal from the magnetic circuit and windings.

The technical result, to which the claimed technical solution is directed, is to increase the efficiency of heat removal from the magnetic circuit and windings, ensuring compactness, electrical and mechanical strength of a three-phase transformer.

The technical result is achieved by the fact that the three-phase transformer contains a core magnetic core, clamped by two parallel yokes, each core of the magnetic core is located at an equal distance from each other and is covered by the same primary winding and a group of secondary windings, as well as upper and lower radiators, made with understatements on the internal surfaces and interconnected by fasteners. Moreover, each secondary winding is made in the form of a coil in a monolithic insulating casing with symmetrical through grooves on the outer end surfaces of the housings passing through the axes of the inner central holes, parallel yokes being placed on the one hand in the grooves of the housings, and on the other hand, in understating the upper and lower radiators with installation on a heat-conducting compound. In this case, the gaps between the primary winding and the core of the magnetic circuit and between the primary winding and the secondary winding are filled with an insulating heat-conducting compound.

Moreover, in this three-phase transformer, symmetrical through grooves are made in a U-shape, the width of which is comparable with the central inner cylindrical hole of the primary winding and the understatements made on the inner surfaces of the upper and lower radiators. The understatement on the inner surfaces of the upper and lower radiators is rectangular in plan and commensurate with the yokes. The secondary coil is multi-sectional.

The essence of the utility model is illustrated by drawings, where

Figure 1 - General view of a three-phase transformer;

Figure 2 is a General view of a three-phase transformer from above;

Figure 3 - General view of the upper and lower radiator;

4 is a General view of the primary winding;

5 is a General view of the primary and secondary windings;

Fig.6 is a view a of Fig.5;

7 is a General view of the secondary winding;

Fig is a General view of the rod;

Fig.9 is a General view of the coil (top view).

The three-phase transformer (Figs. 1–9) contains an upper radiator 1, a lower radiator 2, fixed with fasteners 3, a core magnetic core placed between them, made in the form of three parallel rods 4 installed in one plane and clamped by two parallel yokes 5, each rod 4 is covered by a coil 6 formed by the same primary winding and a group of secondary windings.

The upper 1 and lower 2 radiators (Figs. 1, 2, 3) are made in the form of brackets of heat-conducting material, with understatements 7 of a rectangular shape on the inside, commensurate with yokes 5, for their placement and fixation, with a depth of, for example, 1/4 of the height of the yoke . Radiators 1, 2 have holes 8 for fasteners 3, as well as holes 9 for mounting a transformer on an object (Figure 3).

The parallel rods 4 of the magnetic circuit (Figs. 8, 9) are made in a stepped form from separate steps 10 and 11. Each step is composed of plates of the same width of a rectangular shape.

The upper and lower yoke 5 (Figs. 1, 2) are made in the form of a parallelepiped and are assembled from plates of the same width.

Each coil 6 (Figs. 1, 2, 9) is multi-sectional, has a concentrically placed primary winding 12 (Figs. 4, 5) and a secondary winding 13 (Figs. 5, 7). Each primary winding 12 (Fig. 4, 5) is made without a frame in the form of a multi-row winding made by wire 14 with insulation 15 of the inner and outer surface of the winding.

The gap between the primary winding 12 and the core 4 of the magnetic circuit is filled with insulating heat-conducting material 16 (Figure 9) in the form of a compound.

Each secondary winding is made in the form of a coil 13 (Figs. 5, 6, 7, 9), containing a multi-section frame 17, with multi-row windings made by a wire 18, with symmetrically located bushings-insulators 19 for the leads 20 of the windings placed along the height of the housing 21 cylindrical shape made of compound.

On the end surfaces 22, 23 of the housing 21 of the coil 13 are made through symmetrical grooves 24 (6, 7) U-shaped shallow depth, intersecting the axis of the Central inner cylindrical hole.

The grooves 24 form a symmetrical locking elements 25 (Fig.6) for the upper and lower yoke 5, placed in the grooves 24 and partially in the understatements 7 of a rectangular shape made in the upper radiator 1 and lower radiator 2 (Figs. 1, 3, 7).

The width of the through grooves 24 (Fig.7) is proportional to the Central inner cylindrical hole of the primary winding 12 (Fig.4, 5) and the width of the upper and lower yoke 5.

The gap between the core 4 of the magnetic circuit and the primary winding 12, as well as between the primary winding 12 and the secondary winding 13 is filled with insulating heat-conducting material 16 (Figure 9) in the form of a compound.

Filling the gap between the primary winding 12 and the core 4 of the magnetic circuit and between the primary winding 12 and the secondary winding 13 with an electrical insulating heat-conducting compound 16 (Fig. 9) increases the electric strength, the heat sink efficiency and the mechanical fixation strength of the core 4 of the magnetic circuit and the windings.

The upper and lower yoke 5 in understatement 7 of the upper radiator 1 and lower radiator 2 are installed on the heat-conducting paste 26.

The fastening elements 3, (Fig.1, 2) fixing the upper radiator 1 and the lower radiator 2, are made, for example, in the form of studs with nuts.

Assembling a three-phase transformer is as follows.

On a multi-section frame 17 (Fig.6, 7) wire 18 perform winding of multi-row windings with the installation of insulators 19. Through the insulators 19 pass the leads 20 of the windings, followed by filling with an insulating compound. This forms a monolithic cylindrical body 21 of the coil of the secondary winding 13 (Figure 5), with through symmetrical grooves 24 of a U-shaped shallow shape, intersecting the Central inner cylindrical hole.

The primary winding 12 (Fig.4, 5) is performed without a wire frame 14, with insulation 15 of the inner and outer surface of the winding. A core 4 of the magnetic circuit is placed in it, followed by filling the gap with an electrical insulating heat-conducting compound 16 (Fig. 9).

Assemble the coil 6 (Figs. 1, 2, 9), concentrically placing in the central hole of the housing 21 (Fig. 7) the secondary winding 13, the primary winding 12 (Fig. 4), with the magnetic core rod 4 placed therein, and filling the gap between the primary winding 12 and the secondary winding 13 of the insulating heat-conducting material 16 (Fig.9) in the form of a compound.

In understatements 7 of a rectangular shape on the inner surfaces of the upper radiator 1 and lower radiator 2, the upper and lower yoke 5 are placed with their installation on a heat-conducting paste 26 or compound. Between the yokes 5 are placed coils 6 with installation in the holes 8 in the radiators 1, 2 of the fasteners 3, with their subsequent fixation, for example, studs with nuts.

Through the holes 9 (Figure 3) in the upper radiator 1 and lower radiator 2, the transformer is fixed to the object.

An example of the use of a three-phase transformer can be a three-phase high-voltage small-sized transformer (Fig. 1-9), which includes an upper radiator 1 and a lower radiator 2 with fasteners 3, a core magnetic circuit between them, made in the form of three parallel rods 4, located in one plane and clamped by two parallel yokes 5. In this case, each of the rods is surrounded by a coil 6 formed by a primary winding and a group of secondary windings.

The upper radiator 1 and lower radiator 2 (Figure 3) are made in the form of brackets made of aluminum alloy, for example Amts, with holes 8 for fasteners 3 (studs) and L-shaped protrusions with holes 9 for mounting the transformer on the object. In the inner surfaces of the radiators 1, 2 are symmetrical, commensurate with the yokes 5, understatement 7, a depth of about 1/4 of the height of the yoke 5 (Figure 3).

Yoke 5 is made in the form of a parallelepiped with dimensions 98 × 13.5 × 12.5, by the method of a set of plates from tape O - 0.1 - III - 49K2FA GOST 10160-75.

The primary winding 12 (Figure 4) is made of wire 14, for example, grade PNET 0.280, without a frame, with insulation 15 of the inner and outer surface of the winding and the core 4 of the magnetic circuit located in it (Fig. 8, 9).

Each rod 4 (Fig. 8, 9) of the magnetic circuit is made of separate steps 10, 11, each step is composed of plates of the same width of a rectangular shape from tape O - 0.1 - III - 49K2FA GOST 10160-75.

The housing 21 (Fig.6, 7) is made by pouring, for example with ZEK-6 compound, with the formation of a central cylindrical hole and through it through symmetrical grooves 24, U-shaped, shallow depth, made on the end surfaces 22, 23 and forming symmetrical locking elements 25 for the upper and lower yoke 5.

The proposed technical solution allows to increase the efficiency of heat removal from the magnetic circuit and windings, to ensure compactness, electrical and mechanical strength of a three-phase transformer.

Claims (4)

1. Three-phase transformer containing a core magnetic core, clamped by two parallel yokes, each core of the magnetic core is located at an equal distance from each other and is covered by the same primary winding and a group of secondary windings, characterized in that the upper and lower radiators are introduced into it, made with understatements on internal surfaces and interconnected by fasteners, with each secondary winding made in the form of a coil in a monolithic insulating casing with symmetrical through grooves on the external end surfaces of the housings passing through the axes of the inner central holes, parallel yokes being placed on one side in the grooves of the housings, and on the other hand, in the understatements of the upper and lower radiators with installation on a heat-conducting compound, while the gaps between the primary winding and the core of the magnetic circuit and between the primary winding and the secondary winding are filled with an insulating heat-conducting compound. 2. The three-phase transformer according to claim 1, characterized in that the symmetrical through grooves are U-shaped, the width of which is commensurate with the central inner cylindrical hole of the primary winding and the understatements made on the inner surfaces of the upper and lower radiators. 3. The three-phase transformer according to claim 1, characterized in that the understatement on the inner surfaces of the upper and lower radiators is rectangular in plan and commensurate with the yokes. 4. The three-phase transformer according to claim 1, characterized in that the secondary coil is multi-sectional.