SU245863A1 - HIGH VOLTAGE GAS SWITCH - Google Patents

Description

The main design problems encountered when designing high-voltage gas switches for particularly high voltages include, in particular, the difficulty of placing more than two metal arc chambers on one supporting insulator with the achievement of compactness, high mechanical strength, aesthetics and operational reliability of the switches.

High-voltage gas switches are known, each pole element of which contains a supporting insulating structure, for example, a pyramidal tripod, composed of separate insulators with intermediate stiffnesses themselves. On the high-potential insulating support structure, a column is installed, containing metal tanks filled with compressed air or gas, arc suppressors and intermediate insulators between these tanks.

In the proposed switch, in order to reduce the number of supporting insulating structures per pole and reduce the dimensions of the switch on the supporting insulating structure on a high potential rod, an additional column with metal tanks and arc extinguishing devices is installed, installed at an angle

to the first column, with the upper tanks of both columns fastened together by insulating ties. These columns are installed at the same angle to the axis of the supporting insulating structure, and the lower tanks of the columns are separated from the top of the insulating design by insulators designed for half the operating voltage of the intermediate insulators.

To increase the mechanical strength of the pole, its elements are interconnected in pairs so that the columns of the paired elements are located in the same plane, with the outer columns being installed vertically, and

the inner ones are inclined to one another and interconnected by insulating connections. The lower tanks of the outer columns are separated from the upper parts of the supporting insulating structures by insulators equal to the intermediate insulators between the tanks, and the lower tanks of the inner columns are located on the potential of the upper parts of the supporting insulating structures.

FIG. 1 shows the described switch with a pole consisting of one supporting insulating structure; in fig. 2 - the same, with a pole consisting of two supporting insulating structures.

made in the form of a pyramid of rod insulators. Through air ducts placed inside insulator 4, the o-sundust is powered by air or gas and controls the pole of the switch. In order to increase the mechanical strength of the supporting insulating structure, intermediate stiffness saces 5 are used. Screen 6 serves to equalize the distribution of voltage across this structure. In the upper part 7 of the supporting structure in the form of two columns tilted to the outer sides, metallic tanks 8 are installed with pro, intermediate insulators 9 between them, and the smaller column tanks are separated from the upper part of the supporting structure by insulators 10, each of which is designed for half voltage from intermediate insulators.

Additional insulators 77 are installed on the extreme poles of the poles with output contacts 12, which are connected by current-carrying bridges 13 to the inputs of the outer chambers so that the tension of the supply wires is transmitted along the axis of the pole. To increase the mechanical strength of the pole, the upper tanks of the columns are interconnected by mechanical insulating connection 14.

In columns of tanks, in mechanical connections between them, or between intermediate stiffness of support structures themselves, hinges can be introduced to eliminate possible mechanical bending forces.

To eliminate torsional and bending stresses on intermediate insulators of extreme pole columns from drawing power leads to extreme pole tanks in their middle parts with orientation along the axis of the pole, additional insulators are installed with lead contacts from which current-conducting jumpers are made to the inputs extreme arc-breaking discontinuities, or inputs of extreme discontinuities are oriented along the axis of the pole.

FIG. 2, four tanks 8 are located on the clalada of two supporting insulating structures 5, with the lower tanks of the outer columns being separated from the upper parts of the supporting structures by insulators 15 equal to the intermediate insulators 9 between the tanks, while the lower tanks of the inner columns are on the potentials of the upper parts support structures. The upper reservoirs of the columns are interconnected by mechanical insulating connections 16, and the intermediate 5 stiffnesses of the supporting insulating structures are interconnected by mechanical connections 17, which increases the mechanical strength of the supporting insulating construction.

Subject invention

Claims (4)

1. High-voltage gas switch, each pole element of which contains an insulating support structure, for example, a pyramidal tripod, composed of separate insulators with intermediate stiffness themselves, on which there are a high potential column is installed containing metal tanks filled with compressed air or gas, arcing devices and intermediate insulators between tanks, characterized in that, in order to reduce the number of supporting insulating structures per pole and reduce the size of the switch, on the supporting insulating structure The side of the high potential is provided with an additional column with metal tanks and arcing devices installed at an angle to the first column, moreover the upper tanks of both columns are fastened together by insulating ties. 2. The switch according to claim 1, characterized in that the columns are installed by the node with the same angle to the axis of the supporting insulating structure, and the lower tanks of the columns are separated from the top of the insulating structure by insulators designed for half the operating voltage of the intermediate insulators. 3. The switch on and. 1, characterized in that, in order to increase the mechanical strength of the pole, the elements of the latter are interconnected in pairs so that the columns of the paired elements are arranged in the same plane, with the outer columns being installed vertically, and the inner ones are inclined to one another and interconnected by insulating connections. 4. The switch according to claim 3, characterized in that the lower tanks of the outer columns are separated from the upper parts of the supporting insulating structures by insulators equal to the intermediate insulators between the tanks, and the lower tanks of the inner columns are located on the potential of the upper parts insulating support structures. - 3 L ig.1 / 2 73 u2