RU26680U1 - HIGH VOLTAGE INPUT - Google Patents

Description

High voltage input

The utility model relates to electrical engineering, namely, to the inputs of various devices at voltages of 220 kV and higher, having insulation from layers of electrical insulation paper impregnated with epoxy resin.

As external insulation, such bushings are, as a rule, porcelain insulators. One of the disadvantages of porcelain insulators is their fragility. US Pat. No. 3,875,327 bushing. Westinghouse Electric Co. Jerry L. Hildenbrand; Application No. 35120/77, bushing. Stated July 23, 1973, No. 80953/73 f. “Hitachi Seisakuse KK, Ikemoto Tetsuro. In addition, porcelain insulators have a large mass, a large complexity of manufacturing and, consequently, high cost.

The known design of the input high voltage Application No. 291373, Germany, High-voltage input for outdoor installation. Announced on April 5, 1979. No. P2913673.0. f. Felten Guilleaume Carlswerk. Weltgen Josef, containing a central pipe, connection sleeve and cast resin insulator body. The outer surface of the housing is covered with a protective sheath made of plastic or silicone rubber. Between the inner surface of this shell and the insulator body there is a layer of glue. Skirts from the same material from which the shell is made are put on the outer surface of this shell. Skirts are seamlessly bonded to the sheath through joint hot vulcanization. The design does not contain a porcelain insulator, insulating liquids requiring reliable tight seals. The manufacturing and assembly process of this design is greatly simplified while reducing material consumption.

g o 02 11 g 4 g

MKIN01V 17/26

The design has the following disadvantages. The adhesive layer between the inner surface of the shell and the body of the insulator does not prevent the diffusion of moisture from the environment. During operation, this leads to a gradual saturation of the adhesive layer with moisture, followed by a decrease in its dielectric properties. With long-term operation of such a layer in strong electric fields, the process of deterioration of dielectric properties is significantly accelerated, reducing the resource characteristics of the product as a whole.

Similar disadvantages are inherent in the interface between the skirts and the outer surface of the shell, despite the fact that, according to the authors of the design, the skirts are connected to the shell seamlessly through joint hot vulcanization. If the skirts are connected to a pre-fabricated shell, that is, at the next technological stage, then the interface between the shell and the skirts with any connection method cannot be considered as one with both the shell and the skirts. To prevent the diffusion of moisture from the environment, the authors propose the use of seals in the form of gaskets. However, this method cannot be considered effective, since gasket materials operating under compression and temperature cycles have a shorter service life than body materials, sheaths, and skirts.

The objective of the utility model is to create a high-voltage input design with reduced material consumption compared to existing structures, which does not have insulating liquids, which require tightness control in operation, and also has a simplified manufacturing and assembly technology.

The technical result is achieved by the fact that the input of a high voltage containing a Central pipe, a protective shell with skirts, a connecting sleeve, contains screens with potential

the central pipe located at the ends of the input and the insulation made of layers of electrical paper impregnated with epoxy resin, and the protective shell and skirts are made in the form of a monolith, made of liquid silicone rubber stitched at room temperature, as well as a metal clamp forcing the end part of the protective shells to the central pipe.

According to one embodiment of the technical solution, the high voltage input can have a two-sided (relative to the connecting sleeve) protective shell with skirts for working in the air, according to another variant, one-sided, for the part of insulation free from the protective shell in the environment of insulating oil.

The utility model is illustrated in the drawing. Figure 1 presents a section of a General view of the design of the bushings above 220 kV with the designation of external elements; figure 2 - remote sectional elements of a General view of the design of the bushings above 220 kV on an enlarged scale.

As shown in figure 2, the proposed design of the input contains screens 1, a Central pipe 2, insulation from layers of electrical paper impregnated with epoxy resin 3, a protective sheath 4, a metal collar 5, a connecting sleeve 6.

The proposed design provides for the manufacture of a protective shell and skirts in one technological operation simultaneously by casting from liquid silicone rubber, crosslinked at room temperature. In this case, a chemical compound of insulation is formed from layers of electrical insulating paper impregnated with an epoxy resin with a protective sheath. A chemical bond also occurs with the end of the central pipe.

forcibly pressing the end part to the central pipe with a metal clamp. This makes it possible to prevent the diffusion of moisture from the environment.

The manufacturing process of the proposed input consists of two stages: the manufacture of a protective shell with skirts 4 and the assembly of the clamp 5 and screens 1.

Compared with the technology of manufacturing bushings, including modes of manufacturing insulation, porcelain insulators, assembly, etc. the manufacturing time of the proposed input design is reduced by at least 4 times.

The material consumption of the proposed design is reduced 2.1 times for bushings with a double-sided protective shell, and 2.6 times with one-sided.

Claims (2)

1. The input of a high voltage containing a Central tube, a protective shell with skirts, a connecting sleeve, characterized in that it further comprises screens with the potential of the Central pipe located at the ends of the inputs of the insulation made of layers of electrical paper impregnated with epoxy resin, and the protective shell and the skirts are made in the form of a monolith of liquid silicone rubber, crosslinked at room temperature. 2. The input according to claim 1, characterized in that the end part of the protective shell is forcibly pressed by a metal clamp to the central pipe.