RU2035776C1 - High-voltage transformer - Google Patents

Abstract

FIELD: electrical engineering. SUBSTANCE: high-voltage voltage transformer has porcelain body installed on base which carries active part enclosed in body and put on pressing supports. Active part is composed of laminated rectangular magnetic core with yoke, with upper and lower horizontal legs on which windings are located. On top of body there put metal cover in which line lead-in is arranged. Transformer is supplemented with special shields (central, upper, lower and capacitive). Capacitive shield is placed above active part with the aid of suspension elements attached to cover and is electrically connected to line lead-in. Axis of shield matches vertical axis of magnetic core. Central, upper and lower shields are mounted on magnetic core. Central side shields are manufactured in the form of bent clamp, attached to studs of yoke and embrace each yoke separately on two sides. On protruding upper butt of central shields there are put upper shields, each having quasi-spherical shape and covering angles of upper leg with itself. Each shield incorporates several elements arranged butt to butt. One of elements can be removed from central shield. Lower shields have hemispherical shape, they are installed between supports, cover angles of lower leg and are fixed to supports with the help of insulation material. EFFECT: expanded application field. 6 cl, 2 dwg

Description

 The invention relates to electrical engineering, in particular to the design of cascade voltage measuring transformers.

 The known voltage transformer [1] consists of steps located on two magnetic cores.

 In the well-known cascade voltage transformer, equalization of the lightning impulse voltage distribution is achieved by creating an additional electric capacitance between the linear input and the magnetic circuit, electrically connected and interconnected by two identical windings located on two rods of the same magnetic circuit. An additional electric capacitance is created by open cylindrical electrostatic screens located on top of the windings and electrically connected to the magnetic circuit of the stage on which the windings are located.

 The disadvantages of the known design are the need for the introduction of additional insulating material between the screen and the winding to ensure the electrical strength of the gap, which is affected by half of the operating voltage (as well as test voltage of industrial frequency and lightning impulses): complex structure; reduced reliability; increased labor intensity; the need for additional solid insulation.

 The known voltage transformer [2] consists of an active part mounted on a base plate and covered with a porcelain cylindrical tire, which is filled with transformer oil. From above, the tire is covered by an oil conservator body, on which an oil level indicator, a contact input and a breathing plug are installed. The interlayer insulation of the windings is done with cable paper.

 The disadvantage of the transformer is the complexity and unreliability of the design; high fire hazard due to the use of transformer oil; overspending of solid insulation due to uneven distribution of overvoltage between the windings; the possibility of a local increase in the electric field strength, which causes an increase in partial discharges (decomposition of the insulation characteristics) and leads to breakdown of the magnetic circuit; the likelihood of impulse stresses on more stressed sections of the main insulation is not excluded decrease in insulation strength, since the strength of the input zone of the transformer is reduced.

 The aim of the invention is to simplify and improve the design, increase reliability, reduce material consumption (decrease the volume of insulating material by uniform distribution of voltage in the windings).

 The goal is achieved in that the high voltage voltage transformer contains a porcelain case mounted on a base on which an active part enclosed in the case is located on the pressing racks, consisting of a lined rectangular magnetic core with yokes, upper and lower horizontal rods on which the windings are located, on top of the case a metal cover is installed on which the linear input is located.

 The transformer is additionally equipped with special screens middle, upper and lower and capacitive screen.

 A capacitive screen is mounted above the active part by means of suspension elements that are fixed to the cover and electrically connected to a linear input, the axis of the screen coinciding with the vertical axis of the magnetic circuit.

 The middle, upper and lower screens are mounted on the magnetic circuit, while the middle screens, made in the form of a curved bracket, are fixed to the studs with a jerk and individually cover each yoke from two sides, and upper screens are installed on the protruding upper end of the middle screens, each of which is made quasispherical in shape and covers the corners of the upper rod and consists of individual elements that are facing each other and one of the elements is configured to be removed from the middle screens; hemispherical lower screens are installed between the uprights and close the corners of the lower rod and are fixed to the uprights using insulating material; self-sealing detachable joints are installed between the contacting surfaces of the housing with the lid and the base. The capacitive screen has a plate shape with rounded edges.

 One of the elements of the upper screen is connected to the middle side screen by welding, and the removable element is made with spring grips. The lower screens are made with a recess, which serves to lay the insulating material. The interlayer insulation of the two upper coils of the windings is made using a lavsan film.

 Self-sealing detachable joints consist of two gaskets made of rubber, between which a liquid mass sealant is introduced.

 In FIG. 1 shows a voltage transformer, general view; in FIG. 2, view A in FIG. 1; in FIG. 3 section BB in FIG. 2; in FIG. 4 node I in FIG. 1; in FIG. 5 node II in FIG. 2; in FIG. 6, section BB in FIG. 2; in FIG. 7, 8 capacitive screen and its mount; in FIG. 9 node III in FIG. 1; in FIG. 10 node IV in FIG. 1; in FIG. 11-13 the middle side screen of the magnetic circuit in the form of a curved bracket; in FIG. 14, 15 a middle screen connected by welding to one of the elements of the upper screen; in FIG. 16, 17 a removable top screen member; in FIG. 18, 19 welded element of the upper screen; in FIG. 20, 21 bottom screen; in FIG. 22 circuit diagram of a voltage transformer.

The proposed high-voltage voltage transformer consists of a porcelain case 1, a cap 2, a metal cover 3 and an active part 4. The transformer is filled mainly with SF6 gas (SF ₆ ) 5.

 Inside the porcelain case 1, on the base 2, the active part 4 is installed, which consists of a lined rectangular magnetic circuit 6 and windings 7 and 8. The windings 7 and 8 are spaced on the magnetic circuit 6 on the upper and lower horizontal rods 9. The yoke 10 of the magnetic circuit 6 is pulled together by thick pressing (wooden ) uprights 11 using the tie rods 12, passed through the holes in the yokes 10.

 To increase the input electric strength in the two upper coils 13 (K and H) of the windings 7 and 8, interlayer insulation is performed using the lavsan film 14, which increases the strength of the input zone and eliminates the breakdown of insulation. In the remaining coils 15 (from A to 3) of the windings 7 and 8, interlayer insulation is performed by cable paper 16.

 From above, the porcelain case 1 is closed by a metal cover 3, to the inside of which a metal capacitive screen 18 is attached by means of suspension elements 17 to equalize the pulse voltage between the windings 7 and 8. The capacitive screen 18 has a plate shape with rounded edges; the axis of the screen 18 coincides with the vertical axis of the magnetic circuit 6.

 The dish-shaped capacitive screen 18 overlaps the circular cross-sectional area of the housing 1. The linear input 19 of the transformer is located on the cover 3.

 The smaller side of the suspension element 17 is fixed to the capacitive screen 18, i.e., the screen 18 is suspended above the active part 4 and is connected rigidly to the cover 3 and has the potential of a linear input 19 by connecting the metal pipe 20 to the winding 7. The pipe 20 is mounted vertically along the linear axis input 19. Practically dish-shaped capacitive screen 18 is made with a hole, and it fits onto the pipe 20.

 To increase the electrical strength of the main insulation and reduce the level of partial discharges, the magnetic circuit 6 is closed with special screens middle 21, upper 22 and lower 23.

 The middle side screens 21 are made in the form of a curved staple, on the edges of which an insulating cable paper 24 is located. In this case, the middle screens 21 are mounted on the tie rods 12 of each yoke 10 of the magnetic circuit 6, covering it from two sides; the upper ends of the middle screens 21 protrude above the magnetic circuit 6.

 At the junction of the middle screen 21 with the stud 12, a hemispherical nut 25 is placed to shield the sharp angles of the studs 12. The upper screens 22 are a quasispherical element that closes the corners of the upper rod 9 of the magnetic circuit 6 and the sling plates (not shown) mounted on the active part 4 .

 The upper quasispherical screen 22 consists of two separate elements 26 and 27, which are installed by the ends to each other.

 The element 26 is welded from the inside (i.e., is connected by welding at several points) to the protruding upper ends of the middle screens 21.

 The element 27 is removable and mounted on the other side on the protruding upper ends of the middle screens 21 and is fixed to them using spring grips 28.

 Element 26, adjacent to element 27, creates a common surface of a quasispherical shape, screening the angles of the upper rod 9 of the magnetic circuit 6.

 The grips 28 consist of a plate 29 and a spring 30 and are attached to the element 27 with rivets 31.

 The corners of the lower rod 9 of the magnetic circuit 6 are closed by lower hemispherical screens 23 mounted between the wooden posts 11 of the active part 4, which are mounted on the base 2.

 Each hemispherical screen 23 is fixed with a kiper tape 32 (insulating material), which struts are strung 11. The recess 33, which is made in each screen 23, serves to lay the kiper tape 32 in it.

 The mechanical connection of the cover 3 with the upper part of the porcelain body 1 is as follows.

 The installed clamp 34 on the housing 1 is connected to the cover 3 by means of a tightening bolt 35 having a cracker 36 abutting against the conical portion of the housing 1.

 Self-sealing detachable connections 37 are introduced into the interface of the contacting surfaces between the cover 3 and the upper part of the porcelain case 1 and between the base / plinth plate 2 and the lower part of the case 1.

 Self-sealing detachable connections 37 consist of two gaskets 38 made of rubber and the liquid mass of sealant 39 (white resin) introduced between them, for example VGP-1 OST 38.032-81.

 Rubber gaskets 38 are mounted on a greased sealant surface. The sealant, possessing the property of not hardening in the absence of contact with oxygen, remains in its bulk liquid after assembly, and forms only a rubbery crust on its surface.

 If a transformer is depressurized during its evacuation, a liquid sealant is drawn into the depressurization zone before filling it with SF6 gas, but since in this case it comes into contact with atmospheric oxygen, it cures and the leakproofness of the transformer detachable joints is restored.

 The advantages of this connector design are not only in the ability to self-repair the tightness of detachable joints, but also in the following.

 The requirements are rather low, for example, to the cleanliness of the mating surfaces in the lid, base, porcelain, etc. This is due to the fact that the adhesion of the sealant with a rough surface is better than with a surface with a low roughness; low flatness requirements for mating surfaces, since non-flatness partially eliminates the liquid sealant when it spreads over the surface.

 To simplify the design of the transformer and to eliminate the additional volume of insulating material as a result of the uniform distribution of the lightning impulse voltage across the steps of the cascade, a metal screen 18 is arranged in the area of the linear input 19 of high voltage, having the shape of a plate with rounded edges and electrically connected to the linear input 19.

 The screen 18 creates additional electrical capacitance of potential parts associated with the input of high voltage to the magnetic circuit 6.

The insulation between the shield 18 and the magnetic core 6 is the insulating filling of the transformer (transformer oil, SF6 gas (SF ₆ ). Special additional insulation is not required.

The distribution of the lightning impulse voltage across the elements of the cascade is determined by the ratio of the electric capacitances of the structural elements associated with the input of a high voltage and magnetic circuit C ₁ and magnetic circuit and grounded parts C ₂ .

The voltage across the elements is distributed inversely proportional to the values of these capacities, with C ₁ having a higher voltage. To reduce the voltage across the capacitance C ₁ , and therefore, to equalize the voltage across the elements of the cascade, it is necessary to increase the capacitance C ₂ . For this purpose, an additional screen 18 is installed, forming a capacitance C _e (see. Fig. 22).

 The proposed high voltage voltage transformer allows to simplify and improve the design; increase reliability; reduce material consumption (reduce the volume of insulating material); to make the design fireproof in operation.

Claims (6)

 1. A HIGH-VOLTAGE VOLTAGE TRANSFORMER, comprising a porcelain case mounted on a base on which an active part enclosed in the case is located on the pressing racks, consisting of a lined rectangular magnetic circuit with yokes and upper and lower horizontal rods on which the windings are located, a metal cover is installed on top of the case on which the linear input is located, characterized in that it is equipped with additional screens middle, upper and lower and a capacitive screen, the latter being mounted above the active part with the help of suspension elements that are fixed to the cover, and electrically connected to a linear input, the axis of the screen coinciding with the vertical axis of the magnetic circuit, the middle, upper and lower screens are mounted on the magnetic circuit, while the middle screens made in the form of a curved bracket are fixed to the studs with a jerk and individually cover each yoke from two sides, with the upper screens mounted on the protruding upper end of the middle screens, each of which is made quasispherical and closing it is the corners of the upper rod and consists of two separate elements that are facing each other and one of the elements is removable from the middle screens, the lower screens, made hemispherical in shape, are installed between the racks and close the corners of the lower rod and are fixed to the racks with using insulating material, self-sealing detachable joints are introduced between the contacting surfaces of the housing with the lid and the base.  2. The transformer according to claim 1, characterized in that the capacitive screen has a plate shape with rounded edges.  3. The transformer according to claim 1, characterized in that one of the elements of the upper screen is connected to the middle screen by welding, and the removable element is made with spring grips.  4. The transformer according to claim 1, characterized in that the lower screens are made with a recess, which serves to lay the insulating material.  5. The transformer according to claim 1, characterized in that the interlayer insulation of the two upper coils of the windings is made using a lavsan film.  6. The transformer according to claim 1, characterized in that the self-sealing detachable connections consist of rubber gaskets, between which a liquid mass is introduced into the sealant.

Images