RU2317609C1 - Vacuum switch - Google Patents

Abstract

FIELD: vacuum switches, primarily outdoor ones.

SUBSTANCE: proposed vacuum switch has chamber installed in insulating tank accommodating vacuum arc chute installed in first insulating case, fixed contact coupled with first current-carrying bushing of switch, and movable contact connected to second current-carrying bushing. Current-carrying bushings are partially disposed in tank and partially are brought out of tank through cover. Space between outer surface of vacuum arc chute and inner surface of first case is filled with insulating material. Second insulating case made in the form of cylinder with two longitudinal ribs is installed outside the first case coaxially with the latter. Second case is mounted on first one in such manner that current-carrying bushings are disposed on opposite ends of second case relative to ribs. Rib width in direction perpendicular to longitudinal axis of case is chosen to ensure reliable air insulation between current-carrying bushings.

EFFECT: enhanced reliability of outdoor insulation, simplified design, easy maintenance in operation, and enhanced environmental friendliness due to dispensing with liquid insulation in switch design.

6 cl, 4 dwg

Description

The invention relates to the field of electrical engineering and for the design of vacuum circuit breakers, mainly outdoor installation.

A vacuum circuit breaker according to the patent of the Russian Federation No. 2126184 is known, which includes at least one vacuum interrupter installed horizontally in a reservoir filled with a dielectric, the fixed contact of which is connected to one input of the switch, and the movable contact is connected by a flexible connection to another input and by means of a contact clamping mechanism with a camera control mechanism. At the same time, the bushings are equipped with current-carrying brackets rigidly connected to each other by insulating elements, a vacuum arcing chamber is mounted on the switch inputs, while its fixed contact is rigidly fixed to the current-carrying bracket of one input, and the movable contact is connected via a flexible connection to the current-carrying bracket of another input, on which The camera control mechanism is rigidly installed.

Known vacuum circuit breaker of the VVU series, manufactured by Karpinsky Electric Machine Building Plant OJSC (operation manual ZhAYE.674153.001.RE), selected for the prototype. Known switch consists of one or three poles. Each pole is assembled on a separate cover. With a three-pole design, all the poles of the switch are interconnected by interpolar couplings. The switch cover is mounted on a welded (from the angular profile) frame. The cover is the main bearing part, to which all other elements of the pole of the switch are attached. Through openings in the cover pass live inputs. The circuit-breaker chamber contains a vacuum arrester placed in an insulating casing of the type KDVR-35-25 / 1600 UHL2 or KDV2-35-25 / 1600 UHL2 or Siemens with movable and fixed contacts, a slip ring with flexible connections mounted on the movable contact, a contact a spring, a traverse, an insulating rod, a live busbar mounted on a fixed contact of the chamber. The insulating body is made in the form of a fiberglass cylinder. The vacuum interrupter chamber is attached to the housing by means of studs mounted on epoxy adhesive through an insulating sleeve. The circuit breaker chamber and partially current-carrying bushings are placed in tanks filled with liquid dielectric - transformer oil. From the tank through the lid, the upper parts of the current-carrying bushings are brought out. The transformer oil also filled the cavity of the chamber body (fiberglass cylinder). Thus, by using a liquid dielectric, the dielectric strength of the external insulation of the chamber and the vacuum interrupter chamber is ensured. To drain the oil in the tank, an oil drain plug with a ball is provided; tanks are equipped with an oil indicator. In addition, for heating oil in the cold season, heating devices are installed at the bottom of the tank - heating elements.

The disadvantages of the known designs of vacuum circuit breakers are:

- the complexity of the design, due to the presence of additional nodes for pouring the dielectric into the tank, to drain it, to control the level of the dielectric, to heat the dielectric;

- unreliability and instability of the properties of the external insulation of the circuit breakers, due to the instability of the properties of a liquid dielectric when the ambient temperature changes, with prolonged use of a liquid dielectric, etc .;

- inconvenience in operation associated with the need to replace and dispose of a liquid dielectric;

- possible environmental pollution during disposal of liquid dielectric.

The problem solved by the invention is to increase the reliability of the external insulation of the circuit breaker; simplification of the design, improving ease of use and environmental friendliness associated with the absence of a liquid dielectric circuit breaker in the design.

The problem is solved in that in a vacuum circuit breaker including a chamber installed in a tank of insulating material, containing a vacuum arrester installed in the first housing of insulating material, the fixed contact of which is connected to the first current-carrying input of the circuit breaker, the movable contact of the vacuum arrester is connected to another current-carrying by input, current-carrying inputs are partially located in the tank, and partly exit the tank through the lid, according to the invention The distance between the outer surface of the vacuum interrupter chamber and the inner surface of the first housing is filled with insulating material, the second housing is made coaxially with the second housing of insulation material, made in the form of a cylinder with two longitudinal ribs, the second housing is mounted on the first housing so that current-carrying inputs were located on the sides of the second casing opposite to the ribs, the width of the ribs in the direction perpendicular to the longitudinal axis of the casing was chosen from loviya ensure reliable air insulation between live inputs.

In the inventive switch, the space between the outer surface of the vacuum interrupter chamber and the inner surface of the first insulating switch housing can be filled with silicone rubber.

In the inventive switch, the second insulating case of the switch can be made of silicone rubber.

In the inventive switch along the inner surface of the first housing, a ring insulating insert with protrusions can be installed coaxially with it.

In the inventive switch, the height of the second housing, it is advisable to choose from the condition of ensuring the location of live elements located in the first housing, within the boundaries of the second housing.

In the inventive switch, a part of each current-carrying input placed in the tank may be filled with silicone rubber.

Thus, the problem is solved mainly due to the design features of the outer insulation of the circuit breaker chamber, consisting of the first and second insulating bodies and the insulation between the outer surface of the vacuum interrupter chamber and the inner surface of the first insulating body.

According to the claimed design, the vacuum circuit breaker can be assembled both in a three-pole design and in a single-pole design, since each pole of the circuit breaker is assembled as an independent circuit breaker assembly, and in a three-pole design, all circuit breaker poles are connected to each other into one common set via interpolar couplings.

In this application, referring to the vacuum circuit breaker, the applicant refers to the pole of the vacuum circuit breaker (based on the considerations that, as mentioned above, the circuit breaker may have a single-pole design).

The inventive vacuum circuit breaker contains a reservoir of insulating material in which the chamber is located. The camera body is made of insulating material, such as fiberglass.

A second insulating housing is installed close to and coaxially outside the first chamber housing, the height of which is selected from the condition of all current-carrying elements of the chamber (with the exception of a flexible current lead connected to the current collector block, which extends outside the chamber and provides electrical connection between the vacuum circuit breaker and the current-carrying input) within a second insulating casing to provide calculated insulating gaps over the air and along the circuit breaker casing. A hole is made in both cases, providing a flexible current lead (flexible connection) to the outside of the collector block.

The second camera body is made in the form of a cylinder with two longitudinal ribs located, for example, opposite each other.

The current-carrying inputs of the circuit breaker are placed opposite each other, each input is placed between the ribs from the sides of the second case opposite from the ribs.

The width of the ribs in the direction perpendicular to the longitudinal axis of the housing is selected from the condition of ensuring reliable air insulation between current-carrying inputs and is set by calculation.

The distance from each input to the ribs does not matter, the main thing is to ensure reliable air insulation between both current-carrying inputs, provided by the choice of the width of the ribs. The approximate width of the ribs in the above direction can be selected from the following condition: both current-carrying bushings and ribs are placed inside a circle passing along the outer end surfaces of both longitudinal ribs. However, the observance of this condition is not mandatory, by calculation, confirmed experimentally, you can always choose the width of the ribs, eliminating the breakdown between the live inputs.

The second housing is installed on the first housing with a certain rotation of the ribs relative to the inputs only on the basis of ensuring the placement of the chamber and the inputs inside the tank, i.e. the relative position of the ribs and current-carrying inputs is determined by the configuration of the tank in which the circuit breaker chamber is installed and current-carrying inputs are partially placed, which are brought out (partially) through the lid that covers the tank.

The second circuit breaker housing is also made of insulating material, such as silicone rubber.

The space between the first chamber body and the outer surface of the arcing chamber is filled with insulating material, for example, silicone rubber, which ensures the reliability of the outer insulation of the vacuum arcing chamber.

The material of all insulating bodies, including the tank in which the chamber with the inputs is installed, is not fundamental, the choice of material is based on the dielectric strength of the material and the optimality of the material used in terms of its manufacturability in manufacturing and cost parameters.

In General, the insulation of the chamber, consisting of the first and second insulating bodies, the insulation between the first body and the arcing chamber provides reliable external and internal insulation of the inventive vacuum circuit breaker, necessary to ensure reliable and safe operation. Reliability and sufficiency of insulation is confirmed by test results.

The inventive design of the vacuum circuit breaker made it possible to exclude the use of such an insulating element as a liquid dielectric - transformer oil, and eliminate all the disadvantages associated with its use, increase the reliability of the circuit breaker, simplify its design, improve the usability of the circuit breaker and eliminate possible environmental pollution associated with disposal of oil.

The presence in the design of the switch of the second camera body and the insulation between the first camera body and the outer surface of the vacuum interrupter chamber does not significantly complicate the design of the switch, because All these structural elements have a simple manufacturing technology and, when installed, the circuit breaker chamber is a single monolithic unit.

If necessary, the insulation of the circuit breaker can be enhanced by placing in the inner cavity of the chamber along the inner surface of the first housing one or more insulating inserts with protrusions (for example, insulating rings with ribs), to increase the creepage distance along the inner surface of the first housing of the circuit breaker. The need for these additional insulating inserts is determined mainly by the operating conditions of the circuit breaker (humidity, ambient temperature, pollution, etc.).

To strengthen the insulation gaps through the air between the current-carrying bushings, parts of the bushings placed in the chamber are filled with insulation, for example, silicone rubber.

To minimize the overall dimensions of the switch, the tank can be made oval.

The claimed invention is illustrated by drawings.

Figure 1 presents a General view of a vacuum circuit breaker.

Figure 2 shows the camera switch.

Figure 3 shows a section aa.

Figure 4 shows the relative position of all the insulating enclosures of the chamber, current-carrying inputs and the tank of the switch (top view in section).

The inventive switch is intended for switching electrical circuits under normal and emergency conditions in three-phase alternating current networks of frequency 50 Hz in open switchgears, in single-phase alternating current networks of frequency 50 Hz for traction substations of electrified railways, section posts and points of parallel connection of the contact network.

The circuit breaker is controlled by a direct current electromagnetic drive or a spring drive.

The pole of the inventive vacuum circuit breaker is assembled on the cover 1. The cover 1 is mounted on a welded (from the angular profile) frame 2. On the plate 3, welded to the frame 2, the cabinet 4 with the drive controlling the circuit breaker control mechanism is mounted. Cover 1 is the main supporting element to which all other elements of the switch pole are attached. Current-carrying bushings 5 pass through openings in the lid. The reservoir 6 of the switch is a casing of oval-shaped insulating material and is attached to the lid 1.

An external busbar is connected to the upper ends of the bushings 5.

A current-carrying bus 8 is attached to the lower end of one input 5 through a contact block 7, and a flexible connection 9 is connected to the lower end of another input 5 through a contact block 7. A flexible connection 9 is connected to a movable contact of a vacuum arcing chamber 11 through a current-collecting block 10, and a current-carrying bus 8 is connected to a fixed contact (not shown in the drawings) of the vacuum interrupter chamber 11.

The camera 12 of the switch is installed in the tank 6. Inside the camera 12 is installed a vacuum arcing chamber 11 with movable and fixed contacts. The camera 11 is installed in the first housing 13 of insulating material (for example, fiberglass) and attached to it. The space between the outer surface of the vacuum interrupter chamber 11 and the inner surface of the housing 13 is filled with insulating material 14, for example, silicone rubber. Outside the first housing 13, a second housing 15 of insulating material (organosilicon rubber) is coaxially mounted with it. The housing 15 is made in the form of a cylinder with two longitudinal ribs 16. The housing 15 is mounted on the housing 13 so that the current-carrying bushings 5 are located opposite from the ribs of the sides of the second housing 15. The width of the ribs 16 in the direction perpendicular to the longitudinal axis of the housing 15 is selected from conditions for ensuring reliable air insulation between current-carrying inputs 5 in order to exclude the possibility of breakdown of the air gap between inputs 5 during operation of the switch. An insulating rod 17 is connected to the movable contact of the chamber 11, connected on one side to the control mechanism of the switch, and on the other hand, to the collector block 10.

An annular insert 18 made of organosilicon rubber is installed coaxially with the inside of the housing 13, providing an increase in the creepage distance along the inner surface of the housing 13.

The principle of operation of the circuit breaker is based on the extinction in vacuum of an electric arc that occurs when the contacts of the vacuum interrupter are opened 11. Due to the high electric strength of the vacuum gap and the absence of a medium that supports the burning of the arc, when the contacts open, the electrical strength of the contact gap increases rapidly, which ensures reliable circuit disconnection circuit breaker.

The switch is turned on and off by a control mechanism (not shown in the drawing), which, through an insulating rod 17 connected to a block 10, which, in turn, is connected to the movable contact of the camera 11, drives the movable contact of the camera 11.

The external insulation of the circuit breaker chamber, consisting of two buildings 13 and 15 and insulation 14, eliminated the use of transformer oil (liquid dielectric) in the design of the switch. The tank 6 is thus intended primarily to isolate the chamber and the lower parts of the current-carrying bushings 5 located in the tank 6 from the effects of precipitation and pollution.

The Karpinsky Electric Machine-Building Plant OJSC has developed technical documentation for the vacuum circuit breaker of the VVUS series in accordance with the claimed design; TU and operation manual are developed (ZhAYE.674241.003). The prototypes of the circuit breaker were issued and its tests were carried out. The VVUS series circuit breakers are recommended for use at the facilities of JSC FGC UES (Federal Grid Company of the Unified Energy System) - see the Acceptance Certificate for Design and Development and the installation series of the VVUS-35II * -25 / 1000UHL1 vacuum circuit breaker.

In accordance with the protocol No. 471/05 of the tests carried out by the testing center for high-voltage electrical equipment (EC VEO ENIN, accreditation certificate No. POCC. RU. 0001.21 MB 02) dated March 23, 2005, the electrical strength of the insulation of the VVUS circuit breaker was tested for compliance with GOST 1516.3- 96 (subclauses 8.1, 8.3, 8.4) and testing for heating with rated current for compliance with GOST 687-78 (clause 3.3.1a) and GOST 8024-90. According to the test results, it was found that the vacuum circuit breaker of the VVUS type meets the requirements of GOST 1516.3-96 (clauses 8.1, 8.3, 8.4), imposed on the dielectric strength during testing by lightning impulse voltage and voltage of industrial frequency, and meets the requirements of GOST 687- 78 (p. 3.3.1a) and GOST 8024-90 for heating with rated current.

Thus, in the design of the inventive vacuum circuit breaker while maintaining all the requirements for the dielectric strength of the insulation gaps, etc. the use of a liquid dielectric with all the advantages arising from this circumstance is completely excluded.

Claims (6)

1. A vacuum circuit breaker comprising a chamber installed in a reservoir of insulating material, comprising a vacuum arrester installed in a first housing of insulating material, the fixed contact of which is connected to the first current-carrying input of the circuit breaker, the movable contact of the vacuum arcing chamber is connected to another current-carrying input, the current-carrying inputs are partially placed in the tank, and partially go outside the tank through the lid, characterized in that the space between the outer surface of the tank a smart arcing chamber and the inner surface of the first housing is filled with insulating material, the second housing of insulating material, made in the form of a cylinder with two longitudinal ribs, is installed coaxially with the outside of the first housing, the second housing is installed on the first housing so that current-carrying inputs are located from opposite relative to the ribs of the sides of the second casing, the width of the ribs in the direction perpendicular to the longitudinal axis of the casing is selected from the condition of providing reliable air isolation between live inputs. 2. The switch according to claim 1, characterized in that the space between the outer surface of the vacuum interrupter chamber and the inner surface of the first insulating switch housing is filled with silicone rubber. 3. The switch according to claim 1, characterized in that the second insulating housing of the switch is made of silicone rubber. 4. The switch according to claim 1, characterized in that along the inner surface of the first housing, an annular insulating insert with protrusions is installed coaxially with it. 5. The switch according to claim 1, characterized in that the height of the second housing is selected from the condition of ensuring the location of live elements located in the first housing, within the boundaries of the second housing. 6. The switch according to claim 1, characterized in that a part of the current-carrying input located in the tank is filled with silicone rubber.

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