RU154337U1 - HIGH VOLTAGE VACUUM CIRCUIT BREAKER FOR VOLTAGE 220 KV - Google Patents

Abstract

1. Three-pole vacuum circuit breaker containing a frame base mounted on the basis of three phase poles, each of which contains two arcing chambers enclosed in insulators, each of which has a fixed contact, designed to connect an external busbar, and a movable contact that is electrically connected to the movable the contact of another arcing chamber, and kinematically through a distribution mechanism placed in the housing, and an insulating rod with a common spring-loaded circuit breaker d a frame base, characterized in that the pole distribution mechanism is mounted on a support insulator, inside of which an insulating rod is placed, and finned insulators with arc chambers are mounted on the distribution mechanism cantilever to the support insulator. 2. The switch according to claim 1, characterized in that the kinematic connection of the movable contact of the arcing chamber with the distribution mechanism is made in the form of a rod fixed with the possibility of movement along the axis of the movable contact. 3. The switch according to claim 2, characterized in that the electrical connection between the movable contacts of the chambers is made by means of a spring-loaded current collector fixed to the movable contact, sliding in a sleeve installed in the end face of the insulator from the side of the distribution mechanism, and a current path connecting these bushings of the two chambers placed in the housing distribution mechanism. 4. The switch according to claim 2, characterized in that the rod is additionally fixed in bearing bearings with the possibility of movement.

Description

Technical field

The utility model relates to the electric power industry and may find application in high voltage vacuum circuit breakers.

State of the art

Known three-pole vacuum circuit breaker containing a housing mounted on the housing three phase poles, each of which contains two arcing chambers enclosed in insulators, each of which has a fixed contact, designed to connect an external busbar, and a movable contact, which is electrically connected to the movable contact of the other arc chamber, and kinematically through a distribution mechanism and an insulating rod with a common spring-loaded circuit breaker, located under the housing [patent RU 112500 U1].

The disadvantage of the prototype is that the vertical dimensions of the 220 kV circuit breaker based on two arcing chambers in the 110 kV pole each, made in accordance with the prototype design scheme, make it difficult to operate and install on existing high-voltage substations.

Utility Model Disclosure

The technical result of the utility model is to reduce the vertical dimensions and increase ease of use.

The object of the utility model is a three-pole vacuum circuit breaker containing a frame base, three phase poles installed on the base, each of which contains two arcing chambers enclosed in insulators, each of which has a fixed contact, designed to connect an external busbar, and a movable contact, which is electrically connected with a movable contact of another arcing chamber, and kinematically through a distribution mechanism placed in the housing, and an insulating rod with a common spring circuit vodom switch placed under the carcass basis, characterized in that the dispensing mechanism is mounted on a pole supporting insulator, inside which is placed an insulating rod, and insulators with arcing chambers secured on the housing of the nozzle assembly in cantilever fashion to a support insulator.

The utility model has developments related to particular cases of its implementation, consisting in the fact that:

- the kinematic connection of the movable contact of the interrupter chamber with the distribution mechanism is made in the form of a rod fixed with the possibility of movement along the axis of the movable contact;

- the electrical connection between the movable contacts of the chambers is made by means of a spring-loaded current collector fixed to the movable contact, sliding in a sleeve installed in the end face of the insulator from the side of the distribution mechanism, and a current path connecting these bushings of the two cameras, located in the housing of the distribution mechanism;

- the rod is additionally fixed in bearing bearings with the possibility of movement.

Brief Description of the Drawings

FIG. 1 illustrate a general structural diagram of a circuit breaker; FIG. 2 - construction of the high-voltage part of the pole, FIG. 3 - kinematics of moving contacts.

Implementation of a utility model, taking into account its development

In FIG. 1 shows a frame base 1, three phase poles 2 installed on the base 1. Each of the pole 2 contains two arcing chambers 4 enclosed in finned insulators 3 (see FIG. 2). Each chamber 4 has a fixed contact 5, designed to connect the external busbar, and a movable contact 6, which is electrically connected to the movable contact 6 of the other arcing chamber 4, and kinematically through a distribution mechanism 7, placed in the housing 8, and an insulating rod 9 with a common a spring actuator 10 of the switch located under the base 1 (Fig. 1). The distribution mechanism 7 of the pole 2 is mounted on a finned supporting insulator 11, inside of which an insulating rod 9 is placed, and the finned insulators 3 with arc chambers 4 are mounted on the housing 8 of the distribution mechanism 7 cantilever to the supporting insulator 11.

The kinematic connection of the movable contact 6 of the arcing chamber 4 with the distribution mechanism 7 is made in the form of a rod 12 (see Fig. 3), fixed with the possibility of movement along the axis of the movable contact 6.

The electrical connection between the movable contacts 6 of the chambers 4 is made by means of a spring-loaded current collector 13 mounted on the movable contact 6, sliding in a sleeve 14 mounted at the end of the finned insulator 3 from the side of the distribution mechanism 7 and the current lead 15 connecting these bushings 14 of the two chambers 4, located in the housing 8 distribution mechanism 7.

The rod 12 is additionally fixed in the bearing bearings 16 with the possibility of movement.

The device operates as follows.

When a supply voltage is applied to the switch, the spring drive 10 is automatically wound up.

Upon receipt of a command to turn on the drive 10 due to the energy stored by its springs at the factory, turns on the switch. In this case, the drive 10 synchronously acts on the rods 9 through the transmission mechanism (not shown in the figures), located (similar to the prototype) inside the frame base 1. The transmission mechanism consists of three control mechanisms interconnected by a composite connecting shaft, and transfers the force from the drive 10 to rods 9 of three poles 2.

If there is a supply voltage on the actuator 10 after the switching operation, the automatic switching on of the switching springs takes place. In the absence of supply voltage, it is possible to manually wind the springs and manually turn on and off the circuit breaker.

When a trip command is received due to the energy of the drive springs, the switch returns to the off position.

Corresponding movements of the movable contacts 6 in the arc suppression chambers 4 of the poles 2 are provided by the distribution mechanism 7.

Claims (4)

1. Three-pole vacuum circuit breaker containing a frame base mounted on the basis of three phase poles, each of which contains two arcing chambers enclosed in insulators, each of which has a fixed contact, designed to connect an external busbar, and a movable contact that is electrically connected to the movable the contact of another arcing chamber, and kinematically through a distribution mechanism placed in the housing, and an insulating rod with a common spring-loaded circuit breaker d frame base, characterized in that the pole distribution mechanism is mounted on a supporting insulator, inside of which an insulating rod is placed, and finned insulators with arc chambers are mounted on the distribution mechanism cantilever to the supporting insulator. 2. The switch according to claim 1, characterized in that the kinematic connection of the movable contact of the arcing chamber with the distribution mechanism is made in the form of a rod fixed with the possibility of movement along the axis of the movable contact. 3. The switch according to claim 2, characterized in that the electrical connection between the movable contacts of the chambers is made by means of a spring-loaded current collector fixed to the movable contact, sliding in a sleeve installed at the end of the insulator from the side of the distribution mechanism, and a current path connecting these bushings of the two chambers, placed in the housing of the distribution mechanism. 4. The switch according to claim 2, characterized in that the rod is additionally fixed in bearing bearings with the possibility of movement.

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