RU2282910C2 - Waterproof pass isolator - Google Patents

Abstract

FIELD: electric engineering, in particular, explosion-proof electric equipment.

SUBSTANCE: waterproof pass isolator consists of conducting rod and porcelain isolating bushing, reinforced on the outside by metallic flange. At portions of conducting rod, positioned inside aforementioned isolation bushing, except the portion, reinforced by metallic flange, compensating bushings, tightly pressed to rod, are provided. Hollow between compensating bushings and isolation bushing (in ends of bushing), between conducting rod and isolation bushing (at the portion of porcelain bushing in area, reinforced by metallic flange) is filled with epoxide compound.

EFFECT: increased reliability and lifetime of waterproof pass isolator.

1 dwg

Description

The invention relates to electrical engineering, in particular to explosion-proof electrical apparatus.

A known design of the bushing [1], consisting of a porcelain insulating sleeve, in which there is a current-carrying rod, a metal flange designed for fastening the bushing. The metal flange is connected to the insulating body (porcelain sleeve) using various types of reinforcement: cements, various compositions of bundles, such as epoxy compounds. For products of general industrial use, the current-carrying rod passing inside the porcelain sleeve is laid freely and has an external dimension smaller than the passage opening of the porcelain sleeve. But for special-purpose products, for example, an explosion-proof switchgear, to prevent the explosion from passing through the gap between the insulating sleeve and the current-carrying rod, it must also be sealed using the methods mentioned above [2]. It turns out the unit, which is a system: current-carrying copper rod - casting mass (epoxy compound) - porcelain sleeve - casting mass - metal flange. The materials in this system have different linear expansion coefficients. Porcelain has the smallest coefficient, copper the largest. The disadvantage of this system is that even with climatic (daily and seasonal) temperature changes, stable mechanical stresses arise in the reinforcement unit. Stresses increase significantly when the rod is heated by electric current passing through it, while the temperature of other elements of the system remains much lower.

The closest analogue, selected as a prototype, is a bushing of the explosion-proof complete switchgear for a voltage of 6 kV [2].

The insulator is a porcelain sleeve, externally using an epoxy compound, hermetically reinforced with a metal flange for installing the insulator in an explosion-proof partition in compliance with explosion protection requirements, and a current-carrying rod sealed with an epoxy compound passes inside the sleeve.

With such reinforcement, explosion protection is provided when electric power is transferred from one compartment of the switchgear to another, but climatic changes in temperature, and especially heating of the current-carrying rod during the passage of electric current due to different values of the coefficient of linear expansion of the system materials, cause cracking of porcelain bushings.

The objective of the invention is to increase the reliability of sealed bushing insulators by reducing the voltage in the reinforcement unit with a climatic change in temperature and with the heating of a current-carrying rod.

To do this, in the known insulator, made in the form of a porcelain sleeve, reinforced externally with a flange having a current-carrying rod, sealed inside the porcelain sleeve with an epoxy compound, it is proposed to tightly fit (or spray-coat) the current-carrying bushings on both sides of the current-carrying rod, and the rod section in Leave the outer flange areas for sealing without expansion sleeves. Fill the free spaces between the insulating sleeve and the rod in its middle part and between the compensating bushings and the insulating sleeve at the ends of the sleeve with an epoxy compound.

The proposed essential features are necessary and sufficient to achieve the task in all cases of using the invention.

The drawing shows a sealed bushing.

The bushing consists of a porcelain sleeve 1, a current-carrying rod 2, compensating bushings 3, a flange 4, an epoxy casting compound 5.

The bushing is mounted in a flameproof partition using a flange 4 and provides explosion protection, as the flange has hermetic filling 5 between the flange and the porcelain sleeve, and the current-carrying rod has hermetic filling with epoxy compound in the area between the compensating bushings 3 (in the remaining parts of the current-carrying rod there is a layer of compound between the porcelain and compensating bushings). With climatic changes in temperature, as well as with the heating of a current-carrying rod, the diameter of the rod increases. Porcelain sleeve 1, having the lowest coefficient of linear expansion, perceives the pressure of the expanding rod. Compensating bushings are deformed and reduce the pressure of the current-carrying rod from the inside to the ends of the porcelain bush. The tensile strength of the porcelain sleeve is the lowest at the ends, and the sleeve is the most durable in the middle part, this determines the choice of this part of the sleeve for sealing. In addition, reinforcing it with a metal flange reinforces it.

In the area between the compensating bushings, where the conductive rod is sealed, the forces on the sleeve from the inside will be maximum. But in this place the sleeve is able to withstand large mechanical loads.

Such a sealed bushing is able to withstand heating of the current-carrying rod to 105 ° C or more without cracking the porcelain sleeve.

Information sources

1. Electrical insulators. / N.S. Kostyukov, N.V. Minakov, V.A. Knyazev and others. Ed. N.S. Kostyukova. - M .: Energoatomizdat, 1984. - 296 p.

2. The device is complete distribution type KRUV-6V-UHL5. Technical description and instruction manual. IMShB.674511.011TO, 1989

Claims (1)

A tight bushing insulator consisting of a porcelain insulating sleeve reinforced with a metal flange and a current-carrying rod, sealed with an epoxy compound, characterized in that on the parts of the current-carrying rod located inside the insulating sleeve, except for the section in the flange area, there are compensating bushings .