RU2485616C1 - Gas-filled switchgear apparatus - Google Patents

Abstract

FIELD: electrical engineering.

SUBSTANCE: gas-filled switchgear apparatus contains a grounded gas-filled body, a stationary contact, a movable contact and a receptacle; connected to the cavity formed by the stationary contact inner surface and the movable contact are additional means for delivery of an insulation gas into such cavity; one ensures that the pressure inside the gas-filled body cavity p1 exceeds that in the stationary contact cavity p2 provided the movable is plugged in.

EFFECT: reduction of the apparatus cost and overall dimensions and possibility of per phase control due to manufacture ease improvement.

7 cl, 2 dwg

Description

The invention relates to high-voltage equipment, in particular to electrical switching devices of a combined type with the possibility of grounding.

A known disconnector (RU 2101794) containing movable and fixed contacts enclosed in a metal housing, the fixed contact is made of two parts, electrically connected to each other by a newly introduced resistor located either outside or inside the movable contact.

The disadvantages of this solution are high manufacturing accuracy, assembly complexity, large size, and the need for customization.

Known disconnector (RU 2159971) containing a liquid resistor, a movable contact and a fixed contact with two screens, electrically connected by a resistor, placed in a metal casing filled with gas. The disadvantage of this disconnector is the design of the resistor, which does not allow adjustment of the resistance value: the resistor is made as a solid cylinder.

The disadvantages of this solution are high manufacturing accuracy, assembly complexity, large size, and the need for customization.

Known gas-filled disconnector and ground electrode, which contain a gas-filled housing, a fixed contact and a movable contact (High-voltage electrical apparatus with gas insulation, St. Petersburg, Energoatomizdat, St. Petersburg branch, 2002, p. 382, p. 422).

The disadvantages of this solution are high manufacturing accuracy, assembly complexity, large size, and the need for customization.

The technical problem to which the invention is directed is to create a new type of switching apparatus, which provides a reduction in the cost and dimensions of the apparatus and the possibility of phase-by-phase control by improving manufacturability due to the fact that insulating gas is chosen as the driving medium.

The solution of the technical problem is provided by the fact that in a gas-filled switching apparatus containing a grounded gas-filled housing with insulating gas, a fixed contact, a movable contact, a socket, additional means are connected to the cavity of the fixed contact formed by the inner surface of the fixed contact and the movable contact insulating gas, while ensuring the excess pressure in the cavity of the gas-filled housing p1 over the pressure in the cavity of the stationary contact P2 subject to the inclusion of a movable contact in the socket.

Means for supplying insulating gas to the cavity include an insulating gas supply device comprising a commutator, a receiver equipped with a pressure sensor, an insulating gas pump for pumping and an insulating gas source, wherein the pressure in the receiver p3 is less than the pressure in the cavity of the stationary contact p2.

Means for supplying insulating gas to the cavity can be installed inside or outside the housing.

Inside the housing of the fixed contact, a channel can be made pneumatically isolated from the cavity of the housing with the possibility of supplying insulating gas to it through the receiver, pressure sensor and switch.

In the housing of the fixed contact to ensure reliable retention of the moving contact, a latch having a piston and rod cavities can be located, the piston cavity communicating with the cavity of the housing, and the rod cavity with a channel for supplying insulating gas, while the cavity of the channel, the cavity of the stationary contact and the gas-filled cavity corps not communicated.

An insulating gas source can be used to select the interior of the housing.

The use of insulating gas to drive a movable contact provides the possibility of abandoning conventional drive systems that require high manufacturing accuracy, are difficult to assemble, and need to be configured. A necessary condition for the use of insulating gas is the use of the ratio of the pressure difference in the cavity of the main body, in the cavity of the stationary contact and in the source of insulating gas. The latch is used in the proposed solution for reliable fixation of the movable contact in the on position.

The invention is illustrated in figures 1 and 2, which shows a gas-filled disconnector and its operation scheme. The principle of construction and the operation scheme of a gas-filled ground electrode system are similar.

As an example embodiment of the invention, we give a gas-filled disconnector, which contains a grounded gas-filled housing 1, fixed contact 2, movable contact 3, socket 4. To the cavity of the fixed contact 13 formed by the inner surface of the fixed contact 2 and movable contact 3, additional means 5 for supplying insulating gas into it.

Means for supplying insulating gas 5 to the cavity of the stationary contact 13 include a device for supplying insulating gas, comprising a switch 6, a receiver 7 provided with a pressure sensor 8, a pump 9 for pumping insulating gas 10 and a source of insulating gas 11.

Means for supplying insulating gas 5 to the cavity of the stationary contact 13 are installed inside or outside the housing 1.

The movable contact 3 is equipped with a means of holding the contact in the extreme position or in the on position (since the contact is not fixed in the off position, and, accordingly, the latch does not work) - latch 12 having a piston and rod cavity, and the piston cavity is in communication with the cavity 10 of the housing 1, and the rod with a channel 14 for supplying insulating gas.

Inside the housing of the fixed contact 13 is made pneumatically isolated from the cavity 10 of the housing 1 channel 14 with the possibility of supplying insulating gas into it through the receiver 7, the pressure sensor 8 and the switch 6.

The proposed device operates as follows. When you turn on the pump 9, the insulating gas is supplied to the receiver 7, through the pressure sensor 8, which controls the pressure in the system, into the switch 6 and into the cavity 13 (figure 2, the position of the switch 6 is “on”). If the latch 12 is absent, then the movable contact 3 is held by maintaining pressure in the cavity 13.

In order for the latch 12 to extend into the position that reliably holds the movable contact 3, the channels 14 for supplying insulating gas from the switch 6 to the latch 12 are made in the fixed contact 2. When gas is supplied to the channel 14, the latch 12 extends from the cavity 13 and unlocks the movable contact 3 . When the pressure of the gas in the channel 14 (figure 2, the "off" position), the latch 12 under the action of the pressure of the insulating gas in the cavity of the housing 1 enters the cavity 13 and fixes the movable contact in the socket 4.

Means for supplying insulating gas to the cavity 5 can be placed in the cavity of the main body, which further reduces the dimensions of the entire device.

An additional advantage of the proposed solution is the possibility of implementing a phase-by-phase control circuit of the poles of a gas-filled switching apparatus by installing separate switches on each pole.

Claims (7)

1. A gas-filled switching apparatus comprising a grounded gas-filled housing with insulating gas, a fixed contact, a movable contact, a socket, characterized in that additional means are connected to the cavity of the fixed contact formed by the inner surface of the fixed contact and the movable contact and pneumatically isolated from the cavity of the housing the supply of insulating gas into it, while ensuring an excess of pressure in the cavity of the gas-filled housing p1 over the pressure in the cavity of the stationary con p2 act subject to the inclusion of the movable contact into the socket. 2. Gas-filled switching apparatus according to claim 1, characterized in that the means for supplying insulating gas to the cavity include a device for supplying insulating gas, comprising a switch, a receiver equipped with a pressure sensor, a pump for pumping insulating gas and a source of insulating gas, while the pressure in receiver p3, less pressure is selected in the cavity of the stationary contact p2. 3. Gas-filled switching apparatus according to claim 1, characterized in that the means for supplying insulating gas into the cavity are installed inside the housing. 4. Gas-filled switching apparatus according to claim 1, characterized in that the means for supplying insulating gas into the cavity are installed outside the housing. 5. The gas-filled switching apparatus according to claim 1, characterized in that the channel is pneumatically isolated from the cavity of the housing inside the housing of the stationary contact with the possibility of supplying insulating gas to it through the receiver, pressure sensor and switch. 6. The gas-filled switching apparatus according to claim 1, characterized in that a latch having a piston and rod cavities is located in the housing of the stationary contact, the piston cavity communicating with the housing cavity and the rod cavity with a channel for supplying insulating gas, while the channel cavity, the cavity of the stationary contact and the cavity of the gas-filled housing are not communicated. 7. Gas-filled switching apparatus according to claim 1, characterized in that the source of insulating gas is the internal space of the housing.

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