RU2240619C1 - High-voltage vacuum switch - Google Patents

Abstract

FIELD: electrical engineering; switching ac power circuits.

SUBSTANCE: proposed switch has arc-control chamber mounted in vertical insulating case built of two parts. Air is admitted through ventilation port into bottom part of case for cooling down heated current-carrying parts of switch so as to prevent their overheating and is discharged to bottom part of case through ports in top part of case wherein it is mixed up with cold air admitted through ventilation port. Air flows up over annular ventilation duct and cools down arc-control chamber and upper lead. Then air flows through ventilation ports to space formed by nozzle, cools down the radiator, and flows out of switch.

EFFECT: enhanced cooling efficiency, enlarged functional capabilities of switch at heavy currents.

11 cl, 3 dwg

Description

The invention relates to electrical engineering and is intended for switching power energy circuits of alternating current.

Known high-voltage vacuum circuit breaker containing at least one vacuum arcing chamber with movable and fixed contacts, installed in a vertically located insulating body, dielectric traction (RU 2144232 C1 from 1998.05.12, IPC N 01 N 33/66).

The disadvantage of this device is the low dielectric resistance.

Known high-voltage vacuum circuit breaker containing at least one arcing chamber with movable and fixed contacts mounted in a vertically located insulating housing with fins on the outer surface, dielectric traction, the lever of the common shaft of the switch (prospectus of JSC "Rivne High-Voltage Equipment Plant", Ukraine, Exactly, Belaya St., 16, 2002).

The disadvantage of this device is the insufficient cooling of the live parts of the circuit breaker.

The objective of the proposed technical solution is to improve the cooling of the circuit breaker and thereby increase the current throughput of the high voltage vacuum circuit breaker. In addition, this solution allows to reduce bending loads on the vacuum chamber and thereby increase the reliability of its operation.

This problem is solved due to the fact that in the upper ends of both parts of the housing there are internal flanges, on which the upper terminal and the vacuum arcing chamber are fixed respectively on the upper, the lower terminal on the lower, in addition, the central holes are made in the inner flanges, and in the upper flange - additionally ventilation holes on the periphery, and the surface area of the lower terminal located in the projection of the central hole of the lower inner flange is smaller than the area of this hole, and the inner the diameter of the upper part of the insulating casing is made larger than the outer diameter of the arcing chamber. At the lower end of the upper part of the insulating casing, a ventilation hole is made in its lateral surface. The cooling radiator is installed at the upper end of the vacuum interrupter chamber. The upper fin part of the radiator is located above the additional ventilation openings. In the upper part of the insulating casing, a nozzle of insulating material is installed in which the cooling radiator is located. A radial groove is made on the inner flange of the lower part of the insulating casing, in which a guide pin is mounted, mounted on the lower terminal. On the inner flange of the lower part of the insulating casing a cylindrical protrusion is made, facing the lower end of the insulating casing. The movable contact rod and the insulation rod are connected by a hinge with the possibility of swinging the insulation rod on the axis of the joint. A hole is made in the lower terminal in which the conical sleeve is located, and in turn, a spacer sleeve is installed in it, the conical sleeve being connected by a flexible conductive connection to the sleeve fixed to the movable contact rod.

Located vertically, coaxially to the conveying chamber, the upper outlet consists of several cylindrical sections, the first of which is fixed with its lower end to the upper end of the vacuum arcing chamber, with its upper end pressed against the inner flange of the upper part of the insulating casing, the second section is located in the central hole of the inner flange, and the third section - in the nozzle of insulating material. On the periphery of the first section of the upper terminal, ribs are made.

The invention is illustrated by drawings.

Figure 1 shows a longitudinal section of a switch; figure 2 is a transverse section aa; figure 3 is a variant with a vertical arrangement of the upper output.

The high-voltage vacuum circuit breaker contains a vacuum arcing chamber 1 with a movable 2 and a fixed 3 contacts. The vacuum arcing chamber 1 is installed in a vertically located insulating casing 4. The insulating casing 4 consists of two parts - the lower part 5 and the upper part 6, which are connected via a connector in a plane perpendicular to the axis of the insulating casing 4. A ventilation hole is made on the side surface of the insulating casing 4 7, and above it - ribs 8. At the upper end of the lower part 5 of the insulating casing 4, an internal flange 9 is made on which the lower terminal 10 is fixed. The lower terminal 10 is fixed relative to the flange 9 s and due to the pin 11 installed in the radial groove 12. In the upper part 6 of the insulating casing 4, an inner flange 13 is made on which the upper terminal 14 and the vacuum arcing chamber 1 are fixed on the inner side.

The inner diameter of the upper part 6 of the insulating casing 4 is made larger than the outer diameter of the arcing chamber 1, an annular ventilation channel 15 is formed between them. In the inner flange 13, additional ventilation holes 16 are made on its periphery.

The ventilation hole 17 is also made at the lower end of the upper part 6 of the insulating housing 4. In the inner flanges 9 and 13 are made of the Central holes 18 and 19.

The transverse dimensions of the lower terminal 10 are smaller than the diameter of the central hole 18, in addition, the lower terminal 10 has a wedge shape in plan, therefore, the surface area of the lower terminal 10 located in the projection of the central hole 18 of the inner flange 9 is smaller than the area of this hole, and Windows 20 and 21 communicate with the cavity of the lower 5 and upper 6 parts of the housing 4.

At the upper end of the vacuum interrupter chamber 1, coaxially to it, in the central hole 19 of the inner flange 13, a cooling radiator 22 is mounted, which is mounted on the upper terminal 14. The finned section of the cooling radiator 22 is located above the ventilation holes 16. The cooling radiator 22 is closed by a nozzle 23 from an insulating material, which is mounted on the upper part 6 of the insulating casing 4, for example, using a threaded connection.

The rod 24 of the movable contact 2 is connected to the drive levers (not shown) by an insulating rod 25, and its connection with the rod 24 is made in the form of a hinge 26.

A hole 27 is made in the lower terminal 10, coaxial to the central hole 18. A conical sleeve 28 is placed in this hole, and a spacer sleeve 29 is installed in it. Both bushings are fixed with the nut 30 to the lower terminal. A sleeve 31 is installed on the stem 24, which is connected by a flexible current-carrying connection 32 with sleeve 28.

On the inner flange 9 of the lower part of the insulating body 5, a cylindrical protrusion 33 is made, facing the lower end 34 of the insulating body 5.

In the connectors between the nozzle 23 and the upper part 6 of the housing 4, as well as between the upper 6 and lower 5 parts of the housing 4, elastic dielectric pads 35 and 36 are installed, for example, of silicone.

Figure 3 presents a design variant in which the upper terminal 37 is located vertically, coaxial to the switch and consists of several cylindrical sections of different diameters. The first section 38 is fixed with its lower end 39 on the upper end of the vacuum interrupter chamber 1, which, in turn, is fixed with screws 40 on the inner flange 41 in the upper part of the insulating casing 6. The upper end 42 is pressed against the inner flange 41. The second section 43 is located in the Central hole 44, and the third 45 in the nozzle of insulating material 46. The annular channel 47 formed by the nozzle 46 and the upper terminal 37 is connected by openings 48 to the annular channel 15.

The device operates as follows.

To cool the heated current-carrying parts of the circuit breaker and prevent their overheating, air enters through the ventilation hole 7 into the cavity of the lower part 5 of the housing 4 and through the windows 20 and 21 into the cavity of the upper part 6 of the housing 4. Cold air entering it through the ventilation hole 17 is mixed here. Rising along the annular ventilation channel 15, the air cools the arcing chamber 1 and the upper terminal 14. Further, the air through the ventilation holes 16 enters the cavity formed by the nozzle 23, cooling the radiator 22, and you walks out of the switch.

The cooling radiator 22 is located directly at the upper end of the vacuum interrupter chamber 1. This improves the heat transfer from the most heat-stressed section of the switch and increases the efficiency of its cooling.

In the vertical arrangement of the upper outlet, the air passing from the annular channel 15 into the holes 48 cools the first section of the outlet 38, and then, passing through the annular channel 47, cools the second 43 and third 45 sections of the upper outlet.

The ribs made on the periphery of the first section 38 of the upper output 37 contribute to its more efficient cooling.

When the switch is turned on and off, the drive shaft lever, making a circular motion, deviates from the axis the lower end of the insulation rod 25, turning it on the axis of the hinge 26, so that the rod 24 and the arcing chamber 1 move only along the axis, without experiencing significant bending loads.

The cylindrical protrusion 33 increases the path length of the leakage current along the inner surface of the housing 5, and the dielectric gaskets 35 and 36 of Selikon increase the insulating strength of the housing 4.

Thus, the use of the invention allowed to increase the cooling efficiency and expand the range of application of the circuit breaker for high currents. In addition, the invention allowed to reduce bending loads on the vacuum interrupter chamber and to increase the reliability of the circuit breaker.

Claims (11)

1. High-voltage vacuum circuit breaker containing at least one vacuum arcing chamber with movable and fixed contacts, mounted in a vertically located insulating casing, consisting of at least two parts - upper and lower, dielectric rod, lever of the common shaft of the switch, upper and lower conclusions, characterized in that in the upper ends of both parts of the housing are made internal flanges, on which are mounted respectively on the upper - the upper terminal and the vacuum arrester, to the bottom it is the lower outlet, in addition, central holes are made in the inner flanges, and peripheral ventilation holes are additionally provided in the upper flange, the surface area of the lower outlet located in the projection of the central hole of the lower inner flange is smaller than the area of this hole, and the inner the diameter of the upper part of the insulating casing is made larger than the outer diameter of the arcing chamber. 2. The high-voltage vacuum circuit breaker according to claim 1, characterized in that a ventilation hole is made at the lower end of the upper part of the insulating housing in its side surface. 3. The high voltage vacuum circuit breaker according to claim 1, characterized in that the cooling radiator is installed at the upper end of the vacuum arc chamber. 4. The high-voltage vacuum circuit breaker according to claim 3, characterized in that the upper finned part of the radiator is located above the additional ventilation openings. 5. The high-voltage vacuum circuit breaker according to claim 1, characterized in that a nozzle of insulating material is installed in the upper part of the insulating body, in which the cooling radiator is located. 6. The high-voltage vacuum circuit breaker according to claim 1, characterized in that a radial groove is made on the inner flange of the lower part of the insulating casing, in which a guide pin is mounted, mounted on the lower terminal. 7. The high-voltage vacuum circuit breaker according to claim 1, characterized in that on the inner flange of the lower part of the insulating casing is made a cylindrical protrusion facing the lower end of the insulating casing. 8. The high voltage vacuum switch according to claim 1, characterized in that the movable contact rod and the insulating rod are connected by a hinge with the possibility of swinging the insulating rod on the axis of the hinge. 9. The high-voltage vacuum circuit breaker according to claim 1, characterized in that a hole is made in the lower terminal in which the conical sleeve is located, and in turn, there is a spacer sleeve, the conical sleeve being connected by a flexible conductive connection to the sleeve fixed to mobile contact rod. 10. The high-voltage vacuum circuit breaker according to claim 1, characterized in that the upper outlet arranged vertically coaxially with the vacuum interrupter chamber consists of several cylindrical sections, the first of which is fixed with its lower end to the upper end of the vacuum arrester, and its upper end is pressed against the inner the flange of the upper part of the insulating body, the second section is located in the Central hole of the inner flange, and the third section is in the nozzle of insulating material. 11. The high-voltage vacuum circuit breaker of claim 10, wherein the ribs are made on the periphery of the first portion of the upper terminal.

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