RU36061U1 - PIN LINE INSULATOR - Google Patents

Description

PIN LINE INSULATOR.

The utility model relates to the electric power industry, namely to high-voltage linear pin insulators designed to isolate wires and fasten them to metal, reinforced concrete and wooden poles on overhead power lines and switchgears of stations and substations of constant and alternating current with an industrial frequency of 50 Hz

Known pin linear insulators made of high-voltage porcelain or glass, consisting of one insulating element for voltages up to 20 kV inclusive ((Line insulators, A.I. Zimberov, Energy, M. 1976, p.6-8, Fig. 1 , a-g) and from several elements. Famous insulators are made in accordance with the general technical conditions in accordance with GOST 1232-82. According to the technical requirements of this GOST, insulators from insulating glass are subjected to heat treatment - annealing.

The closest technical solution, taken as a prototype, is a 35 kV porcelain insulator type SHF35-B (Linear insulators, A.I. Zimberov, Energia, M. 1976, p.6-8, Fig. 1).

The pin linear insulator is made of two concentrically installed insulating parts made of porcelain, interconnected by a sand-cement bond. The inner insulating part is equipped with a threaded hole for the pin for mounting it to the traverse (support).

6 H 01 at 17/32

On the head of the upper insulating part of the pin insulator there are grooves for attaching the wire. Grooves are located at the top and side of the head.

A disadvantage of the known pin linear insulator is that in the event of a breakdown, it is impossible to visually determine the state of integrity of the insulator, because visible destruction of the insulator does not occur. To find the breakdown insulator, it is necessary to carry out instrumental control of all insulators on the power transmission line.

The technical task of the utility model is to develop the design of a pin linear insulator that provides quick visual detection of a defective insulator and its replacement.

The problem is solved in such a way that in the well-known pin linear insulator, containing two concentrically installed and interconnected sand-cement bundles insulating parts, one of which is made of porcelain, according to a utility model, the second insulating part is made of tempered glass. Tempered glass has an inner insulating part. Tempered glass has an outer insulating part.

The implementation of one of the two insulating parts from tempered glass provides the insulator in the event of a breakdown with the destruction of the glass insulating part (equally with its internal or external location) and quick visual detection of the defective insulator. At the same time, due to the rest of the glass in the power unit of the upper porcelain insulating part, the wire is reliably held in working condition.

The inventive device has differences from the prototype and does not follow explicitly from the studied prior art, i.e. meets the criteria of novelty and technical level. In addition, the proposed device can be manufactured on an industrial scale and will find application in electrical engineering on high-voltage power lines.

The essence of the claimed technical solution is illustrated by drawings, where: in Fig. 1 is a general view of an insulator with an internal insulating part made of tempered glass; in FIG. 2 is a general view of an insulator with an outer insulating part of tempered glass.

The pin insulator comprises a first porcelain insulating part 1 (outer in FIG. 1 or inner in FIG. 2), a second tempered glass insulating part 2 (inner in FIG. 1 or outer in FIG. 2). The parts are interconnected by a sand-cement bond 3. In the inner insulating part, a threaded hole 4 is made for the mounting pin. The manufacture of the insulating part 2 is carried out by pressing from a melt of insulating glass with subsequent heat treatment by tempering.

The assembly of the insulator is as follows.

First, the inner part 2 or 1 is introduced into the outer insulating part 1 (in FIG. 1) or 2 (in FIG. 2) with a binder material 3, respectively, of FIG. 1, 2 .. After this, the ligament 3 is compressed by vibration. The composition of the ligament is known in the art. The use of a threaded hole for mounting the support pin can be carried out by any method known in the art.

At the South Ural reinforcement-insulator plant, prototypes of insulators with an internal glass insulating element were tested for heat resistance, mechanical failure, breakdown voltage.

Samples were tested at a temperature difference of 70. They completed the test without damage - no destruction was found.

Testing with breakdown voltage in an insulating medium showed that at a voltage of 200 kV insulators did not break

It has been experimentally proved that when installing this insulator on the mounting pin with a lateral bending load applied in the installation zone of the wire, the destruction occurred with a force of 26.95 kN, instead of an allowable force of 12 kN.

The tests were performed at a temperature of 25, humidity 47%, pressure 758 mm Hg column (environmental parameters)

Claims (3)

1. A linear pin insulator containing two concentrically installed and interconnected sand-cement bond insulating parts, one of which is made of porcelain, characterized in that the second insulating part is made of tempered glass. 2. The pin linear insulator according to claim 1, characterized in that the inner insulating part is made of tempered glass. 3. The pin linear insulator according to claim 1, characterized in that the outer insulating part is made of tempered glass.