SU1520606A1 - Oil-column switch - Google Patents

Abstract

The invention relates to the field of electrical engineering, namely, to designs of multi-ampere high-voltage low-oil circuit breakers, designed for high rated currents (2000 A and above). The aim of the invention is to increase the durability of the circuit breaker, improve switching conditions, reduce shock loads and increase reliability. The switch contains two parallel current-carrying circuits for each phase - the arcing circuit located inside the insulating cylinder, and the main current-carrying circuit located outside this cylinder, made in the form of a movable contact rod installed with the possibility of reciprocating movement, and a fixed contact socket with a through a hole in the base, through which a spring-loaded pusher is passed, which interacts at the end of switching on and at the beginning of switching off with a movable contact rod it. An additionally inserted insulating sleeve with longitudinal grooves on the outer surface of the outlet lamellae and an annular collar in the upper part is installed inside the contact socket of the main current-carrying circuit. A cylindrical spring is installed coaxially with the sleeve inside, the upper end abutting against the annular collar of the insulating sleeve, and the lower end - into the ring stop of the head fixed at the bottom of the spring-loaded pusher. The head is made mainly of insulating material. 3 il.

Description

The invention relates to multi-amperage high-voltage low-oil circuit breakers designed for high rated currents (2000 A and above).

The purpose of the invention is to increase the durability of the circuit breaker, improve switching conditions, reduce shock loads and increase reliability.

 FIG. depicts a multi-amber low-oil circuit breaker with two parallel circuits for each phase, front view; figure 2 - the same.

side view; in fig.Z - switch pole, section.

The switch consists of three phase poles, which are made in the form of vertical autonomous columns 1 - 3 mounted on a welded trolley 4. With wheels 5. The trolley 4 also has an actuator 6, designed to actuate the moving elements of the switch, i.e. turn it on and off.

The switch contains on. two parallel current-carrying circuits for each phase - arcing circuit and main circuit.

The arcing current-conducting circuit is located inside the insulating cylinder 7 of the switch pole filled with transformer oil, and made in the form of a movable contact rod 8 (FIG. 3) and a fixed contact socket 9, the arc-suppressing chamber 10 and roller current removal 1 1. The lowering of the ground pin. Gage 8 is installed with the possibility of reciprocating movement and is connected with the help of the rod 12 and a lever (not shown) with the shaft 13 of the pole.

The main circuit is located outside the insulating cylinder 7 in the open air and is fixed to the current-carrying outlets 14 and 15 of the switches, which are installed respectively on the upper and lower current-carrying parts of the switch pole. Each of the specified current-carrying wires consists of two women. Moreover, on the upper outboard 14 (in between), the housing of the fixed contact socket 16 is installed, and on the lower in terminal 15 (also in the interval between the buses), a roller toggle 17 of the main current-carrying circuit is installed. The movable contact rod 18 of the main current-carrying circuit is installed with the possibility of reciprocating movement and is connected by means of the rod 19 and the lever 20 to the shaft 13 of the pole. Thus, the movable contact rods of the arcing and main current-carrying circuits are associated with one and. with the same shaft 13. The last one, through a cross beam (not shown), is connected to the shafts 21 and 22 of the two other poles (figure 1) and through levers 23, 24 and t tu 25 with a drive 6 (figure 2).

ABOUT

0

Inside the movable contact socket 16 of the main current-carrying circuit, an insulating sleeve (holder) 26 with longitudinal slots is installed, in which the lamella 27 of the socket, spring-loaded plate spring 28 (Fig. 3), are located. The sleeve 26 in its upper part has an annular flange 29, which is adjacent to the base 30 of the outlet. Moreover, a coil spring 31 is installed coaxially with the sleeve 26, which with its upper end abuts the annular collar 29 of the insulating sleeve 26, pressing it against the base 30, which reliably prevents the spring from flowing through it of electric current and, therefore, overheating. The lower end of the spring 31 rests on an annular abutment 32 on the lower part of the pusher 33, which has passed through the cylindrical spring 31 and the opening 34, which is mounted in the base 30 of the socket contact. The pusher 33 in the upper part is provided with a locking element 35, which is made in the form of a nut with a locknut. The pusher 33 can be made integral or composite (in the form of the actual pusher 33 and separately the head 36 screwed onto it with an annular abutment 32). The diameter of the head 36 is equal to or slightly smaller (by 0.5-1.0 mm), the diameter of the rod 18. The head 36 may be made of an insulating material.

When the switch is turned on, the contacts of the arcing circuit, i.e. movable pin.

I -

The rod 8 enters the contact socket 9. Then the movable contact rod 18 of the main circuit, acting on the head 36 of the pusher and moving it upwards, enters the contact socket 16 with the slats 27, i.e. The main current path is closed.

Since the coil spring 31 is compressed when the pusher 33 is moved to the highest position, the part of the kinetic energy of the moving elements turns into potential and the shock loads in the switch are significantly reduced. In the on position, the movable elements are held by the locking device of the drive.

When you turn off the switch, the pusher 33 under the action of potential

the energy of the compressed cylindrical spring .31, acting on the contact rod 18, accelerates its output from the contact socket, helping the disconnecting springs 37 to open the switch. In this way, switching conditions are improved, reliability and efficiency of the arc suppression is increased. In this case, the contacts of the main current-leading circuit are opened (the contact is erased, the gin 18 is completely disconnected from the socket 16), and then the contacts of the arcing circuit are opened. Since the lamellae 27 of the contact socket are located in the longitudinal grooves of the insulating sleeve 26, their movement towards the center (i.e., convergence) is limited to an acceptable value, which, when switched on again, reduces the mechanical ones. strikes rod 18 on the lamella 27 sockets.

Claims (1)

Invention Formula A small oil circuit breaker containing two parallel current-carrying circuits for each phase — an arcing circuit located inside the switch cylinder isolate and a main current-carrying circuit contour located outside of it,. cylinder, made in the form of an iodine contact rod, installed with the possibility of reciprocating | and a fixed contact socket with a through hole in the base, through which a spring-loaded pusher, which interacts at the end of switching on and beginning of switching off with a movable contact rod, is passed, in order to reduce shock loads, to increase long-lasting . Thus, -4 improving the conditions of switching and reliability, inside the contact socket of the main current-carrying circuit, an additionally inserted insulating sleeve is installed with longitudinal grooves on the outer surface for the socket lamellae and a ring-shaped bur. A cylindrical spring is installed in the upper part, coaxially with the sleeve, inside it, with the upper end abutting the annular shoulder of the insulating sleeve and the lower end into the ring stop of the head fixed at the lower part of the said pusher and made of insulating material. Rig.} r FIG. 2 Edited by A. Motyl Compiled by V.Popova Tehred M. Morgental  faa.S Proofreader A. Obruchar