SU851500A1 - High-voltage partition insulator - Google Patents

Description

(54) IL-VOLTAGE PASSAGE INSULATOR

one

The invention relates to electrical engineering, namely to high-voltage bushings, and can be used in all industries related to electronic welding technology.

Designs of high-voltage bushing insulators are known for electronic welding guns with rubber sealing elements that seal the npOJDta high-voltage cable 1.

However, vacuum rubber seals require thorough tightening; in addition, rubber is aging rapidly as a result of heating, which deteriorates the reliability of the high-voltage bushing.

Designs of high -voltage bushing insulators based on the use of epoxy compounds 2 are also known.

However, the use of such insulators entirely from epoxy compounds is difficult due to their specific use (before the first breakdown) and the high cost of manufacture.

A high-voltage pass-through iso-torus is known, consisting of a metal case with an axial hole, a current lead placed in the hole of the case and connected to it with an epoxy compound. on the case. The insulator operates at temperatures up to only 70s, and in

10, the welding electron gun can be heated to a higher temperature during operation. The isolator cannot be used in high vacuum conditions,. its structure 5 (rectangular grooves) is predisposed to create leaks and leaks, in addition, during thermal expansions, additional

leaks. 20

Closest to the present invention, there is a multi-pin high-voltage lead-in in the pressure volume, holding the insulating block with holes. in which through epoxy compound current-carrying elements C4 are located.

The disadvantage of it is the impossibility of direct use in electronic welding guns.

The purpose of the invention is to increase the reliability of the operation of a high voltage insulator under high vacuum conditions and at elevated temperatures.

This goal is achieved by the fact that the insulator casing is made of a non-polar material, for example, a plexiglass, with a linear expansion coefficient of 10-15% more than the linear expansion coefficient of the epoxy compound, with circular grooves shaped in cross-section in the holes. tail with an angle at the base of the AOR-BOS.

FIG. 1 shows a high-voltage bushing, a general view; FIG. 2 shows section A-A in FIG. one.

The high-voltage bushing consists of a housing 1 with four axial holes, low-current elements 2 placed in the holes of the housing 1 and connected with them with an epoxy compound 3. The axial holes of the housing 1 have ring grooves 4, made in the shape of a dovetail with an angle at the base 30-60 °. The current-carrying elements 2 have cylindrical protrusions 5 with mutually perpendicular chamfers.

The housing 1 is made of a dielectric non-polar material, such as organic glass, which has poor adhesion with the epoxy compound 3. In order to obtain a high degree of reliability when the insulator operates under high vacuum conditions during heating, the epoxy compound 3 is selected so that its coefficient of linear expansion less than the material of the housing 1, 10-15%. Due to this, when the insulator is heated, as a result of the operation of the gun, additional sealing occurs on the sides of the annular grooves 4 of the housing 1.

In the absence of heating of the insulator, its sealing is ensured by seals arising in the grooves having the shape of a dovetail, during shrinkage of the epoxy compound after it has been cast.

Manufacturing the housing from a dielectric non-polar material makes it possible to eliminate breakdowns on the housing of the insulator.

The high-voltage isolator showed good performance when a test voltage of 75,000 V and a working voltage of 50,000 V were applied to it.

Thanks to the presence of annular grooves in the form of a dovetail, the high-voltage insulator can operate at a vacuum of up to 1, 10 mm Hg.

When an insulator is used in a vacuum-atmosphere system when it is heated to wo-c, no depressurization is observed due to the use of materials with different coefficients of linear expansion and the design of the connection of the current lead to the insulator.

Claims (4)

1. Equipment for electron beam welding. Kiev, Naukova Dumka, 1973, p. 122-135. 2.Chern to K.I. Epoxy Compa- uida and their application. L., Sudpromgie, 1959, p. 102-122. 3. In the same place 103, fig. 68 4. USSR author's certificate №514354, cl. H 01 H 17/26, 1976.