RU2503078C1 - Sf6 circuit breaker - Google Patents

Abstract

FIELD: electricity.

SUBSTANCE: SF6 circuit breaker comprises an arc-quenching device made of two coaxially arranged contacts, at least one of which is mobile, and of an electric insulating arc-quenching nozzle arranged coaxially around contacts and made of separate elements made of different materials. The arc-quenching device of the circuit breaker additionally comprises a support tubular element fixed on one of the contacts. The electric insulating arc-quenching nozzle and a support tubular element represent a single device made of separate elements of an arc-quenching nozzle fixed on the inner surface of the support tubular element.

EFFECT: increased switching resource and switching capacity of a circuit breaker, higher strength and reliability in operation of arc quenching nozzles, simplified technology of their manufacturing.

2 cl, 1 dwg

Description

The invention relates to electrical engineering, in particular to high-voltage electrical apparatus, in particular to SF6 circuit breakers.

Known SF6 circuit breaker / 1 / (US Patent No. 201032411, class H01H 9/32. Publ. 02/11/2010), containing an arcing device, consisting of two contacts, coaxially located along the axial line, and at least one of of them is movable, from an electric insulating extinguishing nozzle located coaxially around the contacts inside the tubular electrical insulating element (hereinafter - the tubular element), mounted on one of the contacts.

In this case, the arcing nozzle (hereinafter referred to as the nozzle) is fixed to the same contact as the tubular element.

The tubular element performs two functions. Firstly, it changes the electric field between the contacts, as a result of which the restored electric strength of the contact gap increases. Secondly, in a switch with two movable contacts, it performs traction functions, transmitting movement from the first movable contact to the second.

The disadvantage of this switch is that the tubular element is not used to change other characteristics of the arcing device, such as switching ability, switching resource, increasing the mechanical strength of the nozzle, as well as in the technology of creating nozzles consisting of dissimilar materials.

It is known that gas-insulated switches are used for extinguishing nozzles made of electrical insulating materials with heterogeneous properties. In them, the areas subjected to the greatest erosion from the side of the electric arc have the greatest arc resistance / 2 ÷ 6 /.

The disadvantage of such solutions is the lack of proven manufacturing technology (assembly) of such nozzles.

Closest to the proposed solution is the SF6 circuit breaker / 7 / (US patent No. 4420662, publication of 12/13/83, class H01H 33/70) with an arcing device consisting of two contacts coaxially located along the axial line of at least one of which is movable, from an electric insulating extinguishing nozzle located coaxially around the contacts and consisting of individual elements made of different materials.

One of these elements is an annular insert in the tapering part of the nozzle, made of a dielectric material capable of changing the electric field and, therefore, the recovering electric strength of the contact gap.

When using such inserts from other materials, it is possible to increase the erosion resistance of nozzles and gas evolution from them, thereby increasing the switching resource and breaking capacity of the switch.

The disadvantage of this solution is the lack of manufacturing technology of the nozzle with the specified insert. In the general case, there are no descriptions of the technology for manufacturing arc suppression nozzles from materials with heterogeneous properties, in which the mechanical strength and reliability of the product would not be reduced.

The technical result of the proposed solution is to increase the switching resource and switching ability of the gas-insulated circuit breaker, increasing the strength and reliability of the operation of the extinguishing nozzles, as well as simplifying the technology for their manufacture.

This result is achieved by the fact that in an SF6 circuit breaker containing an arcing device consisting of two contacts coaxially arranged along an axial line, at least one of which is movable, from an electrical insulating arcing nozzle located coaxially around the contacts and consisting of separate elements, made of different materials, it is new that the arcing device of the switch further comprises a supporting tubular element mounted on one of the contacts, and The insulating extinguishing nozzle and the supporting tubular element are one device made of separate elements of the extinguishing nozzle mounted on the inner surface of the supporting tubular element.

The supporting tubular element is made of insulating material.

The use of individual nozzle elements made of different materials with increased erosion resistance and / or with increased gas generating ability allows using the simplified technology to separately or simultaneously increase the switching resource of the circuit breaker and its switching ability. The use of a tubular element as a supporting structure for individual nozzle elements improves the strength and reliability of the resulting combined nozzle and simplifies its manufacturing technology.

Figure 1 shows the arrester of the gas-insulated circuit breaker according to the proposed solution.

The gas-insulated switch contains an arcing device (Fig. 1), which consists of a movable 1 and a fixed 2 contacts. Of these, 1a and 2a are the main contacts, and 1b and 2b are arc suppressors. The main fixed contact 2a is mounted on a cylindrical current lead 2b, which, in turn, is electrically and mechanically connected to the fixed arc suppression contact 2b by a jumper 2d. A similar connection of the movable main and arcing contacts is not shown in the figure. Contacts 1a, 1b, 2a and 2b are located coaxially along the axial line 3. In this case, the movable arcing contact 1b is hollow and represents an additional nozzle through which gas can flow out of the intercontact space. The fixed arc contact 2b is a solid pin.

The main extinguishing nozzle 4 is located coaxially around the extinguishing contacts 1b and 2b inside the supporting tubular element 5, which is made of insulating material and fixed in the main movable contact 1a (however, it can be fixed to a fixed contact, and a design with two movable contacts is possible; it is also possible the implementation of the supporting tubular element is only partially made of electrical insulating material, for example, with metal inserts reinforced at its ends; these options are not shown in Fig. 1).

The supporting tubular element and the extinguishing nozzle are one device made of separate nozzle elements 4a-4e assembled into a set and fixed on the inner surface of the supporting tubular element. The individual nozzle elements are made mainly of electrical insulating material, namely, fluoroplastic with various filler additives.

The arcing device contains a chamber for generating high pressure gas 6 (hereinafter referred to as the chamber), where during the shutdown process the gas necessary for extinguishing the electric arc is accumulated, and an annular channel 7 located between the arcing contact 1b and the nozzle 4. Gas from the chamber 6 can flow through the annular channel 7 and then through the hollow arc suppression contact 1b and the nozzle neck 8.

The assembly of the nozzle of such a device is as follows. The supporting tubular element 5 is fixed at one end from the outside by a threaded connection in the main movable contact 1a. At this end, an internal protrusion is made, which serves as a stop for individual nozzle elements, which, in a certain sequence, are laid inside the tubular element. First, the inlet part of the nozzle 4a is inserted, made of an insulating material, not necessarily arc-resistant, because it is not exposed to arc radiation. Then - the main part of the neck of the nozzle 4b, made of a material with increased gas separation under the influence of arc radiation and, therefore, low erosion resistance. This can be, for example, fluoroplastic with the addition of molybdenum sulfide powder. Spacer elements 4g and 4d are placed in it to increase the strength of the nozzle. These elements are not exposed to the action of an electric arc, so they are not made of fluoroplastic, but, for example, from getinaksa. Further on the main part of the nozzle throat is placed its exhaust part 4c, made of fluoroplastic with increased erosion resistance, which is achieved by adding powder of boron nitride to it. All elements in a single unit - the nozzle - are pulled together by a threaded ring 4e, which can be made of metal. The nozzle neck 8 is formed by the main 4b and exhaust part 4c.

In the proposed solution, the manufacture of the nozzle of the extinguishing device of the gas-insulated circuit breaker is provided by the simplest technological operations.

In the prototype there is no description of the manufacture of the nozzle. Although it is known that for the manufacture of such nozzles, its elements must be laid in the mold together with powdered fluoroplastic for subsequent joint molding and then sintering. All this requires the development of special technology.

SF6 circuit breaker operates as follows. When the current is cut off, contacts 1 and 2 open. In this case, the last exiting arc contacts 1b and 2b, between which an electric arc is formed. In the process of their dilution, the electric arc is lengthened, and its radiation is absorbed by the inner walls of the nozzle 4 — first, the main element 4b, and then the exhaust element 4c. Under the influence of this radiation, the surface layers of these elements begin to decompose. Gaseous decomposition products enter the electric arc and heat up in it. They expand and are partially ejected through the hollow arc suppression contact 1b to the outside, and partially enter the chamber 6 through the annular channel 7. The gas pressure in the chamber 6 rises. After the nozzle 8 has come off the pin of the extinguishing pin 2b, there is an intense gas flow from the chamber 6 through the annular channel 7, blowing the electric arc, and causing it to be extinguished into a natural alternating current zero. A more intense decomposition of the surface layers of the main element 4b contributes to a more intensive increase in pressure in the chamber 6 and, therefore, increase the breaking capacity. At the same time, the reduced decomposition of the exhaust element 4B contributes to an increase in the switching resource.

The supporting tubular element, inside which the nozzle is assembled, is not exposed to an electric arc, therefore it is made of high-strength insulating material, for example, from a composite based on Kevlar (aramid) filaments impregnated with epoxy resin. It perceives all longitudinal and radial loads on the nozzle. As a result of this, the nozzle enclosed inside it withstands higher pressure. This is especially important for disconnecting large currents of 50 kA and more, for which pressures of several megapascals are required at the inlet to the nozzle.

The simplicity of the manufacture of individual typesetting elements and their assembly into a single nozzle ensures high reliability of the operation of the circuit breaker device.

In addition to the above, in some cases, additional benefits may be obtained. Due to the high strength of the material of the supporting tubular element, individual fluoroplastic stacked nozzle elements can be made thin-walled, since they do not carry the main load. As a result, the nozzle can be made lightweight. This is also facilitated by the possibility of creating cavities in it according to an example, as shown in FIG. 1, where the cavities are formed by type-setting elements 4b, 4c, 4g and 4d. Reducing the mass of the moving parts of the circuit breaker allows it to use a less powerful and cheaper drive.

Separate typesetting elements of the nozzle can be made of less durable, compared with monolithic, porous fluoroplastic. Then the above cavities can be filled with a liquid dielectric, which under the action of capillary forces through the pores will enter the inner surface of the nozzle and moisten it. In this case, the gaseous decomposition products will be released not from the structural material - fluoroplastic (polytetrafluoroethylene), but from the film of liquid dielectric, which will further increase the switching resource of the switch.Carbogal - liquid low molecular weight polytetrafluoroethylene can be used as such a dielectric.

The input part of the nozzle 4a, which partially shields the extinguishing contact 1b, can be made of fluoroplastic with a powder filler with a high dielectric constant, for example, barium titanate, which will increase the recovering electric strength of the intercontact gap.

And finally, the increased mechanical strength of the supporting tubular element 5 allows you to fix on it or on a separate threaded ring 4e thrust or other similar devices that transmit movement from the movable contact 1 to the fixed contact 2 (2A and / or 2B), resulting in a fixed Contact may become mobile. All this leads to an increase in the rated voltage of the circuit breaker.

Information sources

1. US patent No.201032411, class H01H 9/32, publ. 02/11/2010.

2. CN patent No. 2412286, class H01H 33/22, publ. 02/27/2000.

3. DE patent No. 102006031217, class H01H 33/70, publ. 01/03/2008.

4. JP patent No. 20033223836, class H01H 33/915, publ. 08/08/2003.

5. JP patent No. 2007373384, class H01H 33/70, publ. 03/02/2007.

6. JP patent No. 20100211966, class H01H 33/70, publ. 09/08/2010.

7. US patent No. 4420662, class H01H 33/24 publ. 12/13/83 (prototype).

Claims (2)

1. An SF6 circuit breaker comprising an arcing device consisting of two contacts coaxially arranged along an axial line, at least one of which is movable, of an electrical insulating arcing nozzle located coaxially around the contacts and consisting of separate elements made of different materials, characterized in that the arcing device of the switch further comprises a supporting tubular element mounted on one of the contacts, moreover, an insulating arcing nozzle and ny tubular element constitute one unit made of individual elements of the quenching nozzle mounted on the inner surface of the tubular support element 2. The gas-insulated switch according to claim 1, characterized in that the supporting tubular element is made of electrical insulating material