RU133969U1 - VACUUM CIRCUIT BREAKER - Google Patents

Abstract

A vacuum circuit breaker consisting of a housing, a control unit, a manual shutdown shaft, an electromagnetic drive, a stand and three phase modules, each of which contains a vacuum arcing chamber, a flexible bus, a traction insulator, internal and external insulators, characterized in that it has internal and external motionless insulators mounted on the same axis with labyrinth isolation; the high-voltage part is separated from the electromagnetic drive by a stand, which can be changed in height to increase the rated value of the operating voltage of the switch.

Description

The utility model relates to the field of electrical engineering, namely to the design of vacuum circuit breakers, and can be used in switchgears, transformer substations and as part of other electrical equipment, including explosion-proof. A known vacuum switch containing a base, vacuum chambers with contacts, contact terminals and current collector, support and traction isolation, phase-by-phase actuators with magnetic systems forming magnetic latches containing a stator, armature and winding, and a common synchronizing shaft [RU No. 2020631, class. H01H 33/66, 1992]. The design flaws are large overall dimensions, including a traction insulator, the absence of a controllable drive and independent control of phase poles.

Known vacuum circuit breaker [RU No. 2249874 C2, class. H01H 33/666, 2003]. The switch consists of a housing, three integral phase modules containing phase poles, rigidly mounted on a metal base, inside of which there are magnetic latch drives, synchronizing and locking shafts, and block contacts. The design flaws are the large overall dimensions of the circuit breaker, as well as the implementation of labyrinth isolation on a movable element - a traction insulator.

The closest in design is a vacuum circuit breaker [RU No. 2344506 C1, class H01H 33/00, 2006]. The vacuum circuit breaker consists of phase modules installed in a row, each of which contains a vacuum arcing chamber with embedded live parts, a controlled electromagnetic drive that is sealed and isolated from live parts by an elastic membrane, round tires. The switch contains power supplies and control the electromagnetic drive, a blocking shaft shutdown. The design disadvantages are the reduced reliability of the device due to the technological complexity in providing sealing using a membrane embedded in a traction insulator with an electromagnet rod and a movable contact rod.

The objective of the utility model is to reduce the overall dimensions and increase the reliability of the vacuum circuit breaker.

The technical result provides a reduction in the dimensions of the vacuum circuit breaker and increases operational reliability through the use of phase modules with internal and external fixed insulators.

The technical result is achieved due to the design features of the circuit breaker, namely phase modules with internal and external fixed insulators have labyrinth isolation and increase the electrical insulation capacity of the vacuum circuit breaker.

The problem is solved due to the fact that the known device consists of a housing, a control unit, a manual shutdown shaft, an electromagnetic drive, a stand and three phase modules, each of which contains a vacuum arcing chamber, a flexible bus, traction insulator, internal and external insulators. The internal and external insulators mounted on the same axis, one inside the other, form a labyrinth isolation; the high-voltage part is separated from the electromagnetic drive by a stand, which can be changed in height to increase the rated value of the operating voltage of the switch.

Figure 1 shows a General view of the vacuum circuit breaker, figure 2 - the main components of the circuit breaker.

The vacuum switch consists of three phase modules 1 and the housing 3 (figure 1). Phase module 1 of the vacuum circuit breaker contains (Fig. 2) an upper bus 5, an external insulator 6, an additional insulator 7, a vacuum chamber 8 with a movable contact 9, a cone of a movable contact 10, a flexible bus 11, a lower bus 12, a traction insulator 13, an internal insulator 14, stand 15.

The housing 3 contains the stationary parts of the electromagnetic drive 16, the moving parts of the electromagnetic drive 17, the threaded bushings 2, the terminal block 18, the multifunction screws 19, the external electrical connectors 20, the hinges 21, the manual shut-off shaft 4, the screws 22, the housing cover 23.

The phase module 1 is mounted on the housing 3 and is fixed, for example, using a screw connection. The cone 10 is fixed to the movable contact 9 of the vacuum chamber 8 by means of a screw connection by the traction insulator 13. The flexible bus 11 is pressed into the cone of the movable contact 10 and into the lower bus 12. The lower bus 12 is installed in the inner insulator 14 and fixed, for example, with a self-tapping screw. The internal insulator 14 is pressed by the external insulator 6 through the stand 15 to the housing 3 and is fixed, for example, using a screw connection. An electromagnetic drive, consisting of the fixed part of the electromagnet 16 and the movable part of the electromagnet 17, is installed in the housing 3 coaxially with the phase module 1 and is fixed using the multifunction screws 19. The terminal block 18 with external electrical connections 20 is mounted on the multifunction screws 19. Loop 21 is attached to the movable part of the electromagnet 17. A cover 23 is attached to the housing 3.

The device operates as follows. When the vacuum circuit breaker is turned on, the moving parts of the electromagnetic actuator 17 go to the “On” position along the guide multifunction screws 19, which also restrict their movement. In this case, using the action of the traction insulators 13 on the movable contacts 9, the vacuum chambers 8 are turned on. The manual shut-off shaft is moved to the “On” position by the action of the loops 21 on the screws 22.

When the vacuum circuit breaker is turned off, the moving parts of the electromagnetic actuator 17 are switched to the “off” position by the multi-function screws 19. In this case, the vacuum chambers 8 are turned off by the action of the traction insulators 13 on the movable contacts 9. The return spring of the shaft 24 transfers the manual shutoff shaft 4 off state

With manual shutdown, the shaft 4 is turned to the off position. In this case, the screws of the shaft 22 by means of loops 21 tear off the moving parts of the electromagnetic drive 17 from the fixed parts 16. The manual shut-off shaft 4 is returned using the shaft return spring 24. The support 15 can be increased in height, which allows the rest of the structure to be used without changes at more high voltage.

The inventive switch has a reduced size while increasing the reliability of the vacuum circuit breaker.

Claims (1)

A vacuum circuit breaker consisting of a housing, a control unit, a manual shutdown shaft, an electromagnetic drive, a stand and three phase modules, each of which contains a vacuum arcing chamber, a flexible bus, a traction insulator, internal and external insulators, characterized in that it has internal and external motionless insulators mounted on the same axis with labyrinth isolation; the high-voltage part is separated from the electromagnetic drive by a stand, which can be changed in height to increase the rated value of the operating voltage of the switch.

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