DE8513937U1 - Encapsulated, pressure gas-insulated high-voltage system - Google Patents

Description

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Encapsulated, pressure-insulated high-voltage system.

The invention relates to an encapsulated, pressurized gas-insulated high-voltage system with electrical conductors, in particular busbars, which have an interruption point with two ends facing each other, which can be connected to each other by axial displacement of a conductor part in or out of

Can be brought into engagement, wherein this displaceable conductor part is held in a central recess of one conductor end, into which it is fully inserted in a first end position, and in which the other conductor end engages in a hollow cylindrical coupling contact with spring-mounted strontia blades, the inner diameter of which corresponds to the outer diameter of the front contact surface of the displaceable conductor part, which in its second end position rests with its front contact surface on the current blades.

Such a high-voltage system is known from DE-OS 33 18 344. In these high-voltage systems, there is sometimes a need, particularly for assembly or disassembly purposes, to create an interruption point in the course of a current-carrying conductor, which must be removable, i.e. bridgeable. The dielectric strength of the high-voltage system must not be impaired by this interruption point. In the known high-voltage system, the interruption points are located in the power supply to the interrupter units of each pole of a circuit breaker and enable the mechanical separation of the power supply from the circuit breaker pole so that it can be removed for maintenance and repair purposes. Since such maintenance can be necessary relatively frequently, in the known high-voltage system the movable conductor part of the interruption point is connected via a

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coaxial shaft with an external thread^ whereby this shaft can be rotated with the help of a bevel gear and a tool inserted from the outside. This results in a relatively complex construction of the known interruption point.

The invention is based on the object of creating such an interruption point for use in the course of busbars, which enables the dielectric strength of the new system components to be tested before commissioning in the case of system extensions, without the old system components having to be switched off.

To solve this problem, an encapsulated, compressed gas-insulated high-voltage system of the type described at the beginning is designed according to the invention in such a way that in a high-voltage system with multiple busbars, an interruption point is arranged in each busbar, in which both conductor ends are each surrounded by a rounded shield, the end faces of which in the first end position of the movable conductor part delimit an isolating distance, the dielectric strength of which corresponds to the specified dielectric strength of the voltage level of the high-voltage system, that the other conductor end runs out inside the coupling contact in front of its contact surface to the current lamellae to form a hollow cylinder, in which, adjacent to the end face, an insulating sleeve is inserted, the inner diameter of which corresponds to the outer diameter of a front-side attachment on the movable conductor part,

that in the second end position of the movable conductor part, the front side of the insulating sleeve rests on the shoulder between the front contact surface to the current lamellas and the front-side attachment and
that the movable guide part is provided with engagement surfaces for displacement on its front side and on its outer surface.

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Each interruption point is designed in terms of construction and voltage like the isolating gap of a circuit breaker. In the first end position of the movable conductor part, i.e. with an open isolating gap, the movable conductor part is located entirely within the shield. Since in the high-voltage system with multiple busbars such an interruption point is provided in each busbar between the old and new system parts, in this first end position of all movable conductor parts the old system parts can continue to be operated via a busbar if a voltage test is carried out on the new system parts via a different busbar. The test voltage is applied to a busbar in the new system part that is opposite an earthed busbar in the old system part. As a result, at this interruption point the shield that carries the test voltage can only be opposite an earthed shield, just as at another interruption point the shield that carries the operating voltage is opposite an earthed shield. However, the isolating distance of each interruption point is designed with regard to its dielectric strength for the maximum possible voltage difference, since its dielectric strength corresponds to the specified dielectric strength of the high-voltage system.

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In the second end position of the movable conductor part, the isolating strip is bridged. The hollow cylinder with the inserted insulating sleeve ensures perfect central guidance and a precisely defined end position of the movable conductor part, which provides insulated stops and guide surfaces. The current transfer from the movable conductor part therefore only takes place in the area of the system provided for this purpose on the current lamellas. The movable conductor part bridging the isolating strip is made possible by the fact that the outer surface, i.e. accessible from the isolating strip, or on the front

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flat, i.e. accessible in the first end position, attack surfaces are provided for a tool for displacement.

It is particularly advantageous if one end of the conductor also ends in a second hollow cylindrical coupling contact with spring-loaded current lamellae, which is located inside the shield and which is closed at the front with an insulating bearing ring, whereby the inner diameter of the bearing ring corresponds to the outer diameter of the rear contact surface of the movable conductor part which comes into contact with these current lamellae in the second end position. Here too, there is then a clearly defined current transfer, limited by the insulating bearing ring, from the other end of the conductor via the current lamellae to the rear contact surface of the movable conductor part which is in its second end position. Since the inner diameter of the bearing ring corresponds to the outer diameter of the rear contact surface, it serves to centrally guide the movable conductor part on the same side.

It is also recommended that, when the conductor part is being moved, a rounded clamping ring is pushed onto it as soon as it is in the isolating gap and that it is secured in such a way that it is a short distance from the front face of the shielding of the other conductor end and thus only allows a small movement of the movable conductor part in the axial direction, so that an unintentional departure from the second end position due to unexpectedly occurring shock loads is avoided. If the rounded clamping ring is made of conductive material, it is advisable to place an insulating disk between the clamping ring and the front face of the shielding so that an undesirable current transfer to the shielding is avoided.

In the following, the invention will be explained with reference to the embodiment shown in Figures 1 to 3 of the drawing.

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explained in more detail. Figure 1 shows a longitudinal section through a busbar conductor of an encapsulated, compressed gas-insulated high-voltage system, with the first end position of the slidable conductor part indicated in dashed lines in the lower half. Figure 2 shows, rotated, a section along the line II/II in Figure 1. Figure 3 shows the basic circuit diagram of the high-voltage system during a voltage test.

An encapsulated, compressed gas-insulated high-voltage system with a double busbar contains busbar sections for conducting current between switchgear panels. In these, the conductor 1 either passes through arc-proof bushing insulators 2 or is supported on support insulators 3 opposite the metallic, earthed, tubular encapsulation (not shown) and is thus kept at a distance from it.

I If, for each of the two busbars of the double busbar, for example, the bushing insulator 2 belongs to an old part of the system that is to be expanded using new switchgear panels, two conductor ends facing each other are provided in the conductor area to the next support insulator 3, between which an interruption point is formed.

can be bridged. One conductor end 4 is solid, attached to the bushing insulator 2 via the conductor 1 and has a long central recess 5.

The other conductor end 6 is located on the support insulator 3 and is attached there to the conductor 1. The other conductor end 6 engages in a hollow cylindrical coupling contact 7 with spring-loaded current blades 8, against which it rests with its contact surface 9. Inside the coupling contact 7, the other conductor end 6 runs out to a hollow cylinder 10, in which an insulating sleeve 12 is inserted, adjacent to the end face 11 and extending beyond it. This

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The entire other conductor end 6 is surrounded by a rounded shield 13, which completely encloses the conductor end 6.

A rounded shield 14 is also provided on the conductor end 4, which surrounds all parts connected to the conductor end 4, as well as the movable conductor part 15, when the latter is in its first end position. In this first end position, the movable conductor part is completely inserted into the central recess 5 of the conductor end 4 (see the position indicated by dashed lines in the lower half of Figure 1) and its front surface 16 is still inside the shield 14.

This conductor end 4 also ends in a second hollow-cylindrical coupling contact 17 with spring-loaded current blades 18, which is located inside the shield 14. This coupling contact 17 is closed at the front with an insulating bearing ring 19.

The movable conductor part 15 is provided with a projection 20 on its front side. The outer diameter of this front-side projection 20 corresponds to the inner diameter of the insulating sleeve 12, which is arranged in the hollow cylinder 10 of the other conductor part 6. This achieves a central guidance of the movable conductor part 15 in the insulating sleeve 12 without a current transfer occurring there. Behind the front-side projection 20 is the front contact surface 21 of the movable conductor part 15, the outer diameter of which corresponds to the inner diameter of the spring-mounted current blades 8 of the coupling contact, against which this front contact surface 21 comes to rest in the second end position of the movable conductor part 15. *

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The movable conductor part 15 also has the rear contact surface 22, the outer diameter of which corresponds to the inner diameter of the current lamellae 18 of the second coupling contact 17 and the inner diameter of the insulating ring 19. In the second end position of the movable conductor part 15, this rear contact surface 22 rests against the current lamellae 18 and the insulating bearing ring 19. As a result, the current transfer between the solid conductor end 4 and the current lamellae 18 on the movable conductor part 15 is limited to a precisely defined area. In addition, the bearing ring 19 serves to centrally guide the movable conductor part 15.

In this second end position of the movable conductor part 15, the front-side projection 20 is also guided centrally by the insulating sleeve 12. In addition, the front side 23 of this insulating sleeve 12 comes to a stop on the shoulder 24 between the front contact surface 21 to the current lamellae 8 and the front-side projection 20, so that the second end position of the movable conductor part is also clearly defined in the axial direction.

The movable conductor part 15 is also provided with a hole 25 on its outer surface 26 and with a central hole 27 with a thread on its front surface 16. These form contact surfaces for receiving a tool with which the movable conductor part 15 can be moved. In the first end position of the movable conductor part 15, the hole 27 on the front surface 16 is accessible. The hole 25 on the outer surface 26 is arranged in such a way that it is accessible before the front surface 16 enters the shield 13.

The front surface 28 of the shield 12 and the front surface of the shield 14 limit the distance indicated by arrows in the first end position of the movable conductor part 15.

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Isolating distance 30, the dielectric strength of which corresponds to the specified dielectric strength of the voltage level of the high-voltage system

-' position. The high-voltage system has a double

*■ busbar with the two busbars 31 and 32 available

the one in which an interruption point is provided in each busbar 31, 32 between the old system parts 33 and the new system part 34 (see Figure 3), the isolating gap 30 of which is open in the first end position of the movable conductor part 15. In order to carry out a voltage test on the new system part 34, the busbar 31 is now earthed via the earthing switch 35 in the area of the old system part 33. The isolating switches 36, 37 located in the branch of this busbar 31 and leading to the system parts 33 are open. On the other hand, the earthing switch 38 is open on the other busbar 32 and the isolating switches 39, 40 leading to the system parts 33 are closed. The old system parts can thus be operated via the busbars 32.

The test voltage for the voltage test, indicated by the symbol 41, is now fed to the busbar 31' in the new system part 34, whose earthing switch 42 is open. The other busbar 32' in the new system part 34 is earthed via the closed earthing switch 43. The isolating switch 44 leading from the busbar 32' to the new system part 34 is open, while the one leading to the busbar 31'

Disconnector 45 is closed. The voltage test of the new system part 34 can thus be carried out from the busbar 31'. At the upper interruption point 46 between the busbar 31 and the busbar 31' at the open isolating distance 30, the shield 13 surrounding the conductor end 6, which carries the test voltage, and the shield 14 surrounding the conductor end 4, which is earthed, are opposite each other. In the course of the busbar 32, 32', on the other hand, the lower interruption point AV is located. At * 4-

^!( ; 35 this is the shield 14' surrounding the conductor end 4', the operating voltage of the old system components 33

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leads to the shield 13' surrounding the conductor end 6 ¹ , which is earthed* Since the isolating distance 30 of both interruption points 46, 47 corresponds in terms of its dielectric strength to the specified voltage strength of the extra-high voltage system, the old system parts 33 in operation are not endangered during the voltage test of the new system part 34, even if a flashover were to occur at the interruption point 46, at which the test voltage is applied, as a result of a construction or assembly error.

After completion of such a test for the dielectric strength of the new system part 34, the movable conductor part 15 is then removed from its first end position by inserting a tool into the front hole 27, which is provided with a thread, and inserted into the isolating gap. An insulating disk 48 and a rounded clamping ring 49 are now pushed onto the movable conductor part 15 in such a way that the insulating disk 49 rests on the outside of the front surface 29 of the shield 14 in the second end position of the movable conductor part 15 and the clamping ring 49 is located a short distance in front of it. This prevents axial mobility of the movable conductor part 15 in its second end position, so that it is ensured that even in the event of longitudinal displacements as a result of thermal expansion or shock loads, the contact surfaces 22 and 21 respectively rest on the current lamellae 18 and 8 respectively, so that the current transfer is ensured in the areas provided for this purpose. The rounded clamping ring 49 is fixed to the outer surface 26 of the movable conductor part 15 by a screw 50.

In a modification of the illustrated embodiment, it is possible to attach the other conductor end not directly to the support insulator, but in front of it in the course of the busbar

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In this case, an additional shield must be provided around the conductor end alone, outside the shield already present on the support insulator.

5 Claims
2 figures

Claims (5)

a1I 1O33aaa mm ** r a « ■ &igr;&bull;■&bull;1 Il ■ iI 1-Ii- VPA85PA A-claims 1. Encapsulated, compressed gas-insulated high-voltage system with electrical conductors, in particular busbars, which have an interruption point with two ends facing each other, which can be brought into or out of engagement with each other by axial displacement of a conductor part, wherein this displaceable conductor part is held in a central recess of one conductor end, in which it is fully inserted in a first end position, and in which the other conductor end engages in a hollow cylindrical coupling contact with spring-mounted current lamellas, the inner diameter of which corresponds to the outer diameter of the front contact surface of the displaceable conductor part, which in its second end position rests with its front contact surface on the current lamellas, characterized in that in a high-voltage system with multiple busbars, an interruption point (46, 47) is arranged in each busbar (31, 32), in which both conductor ends (4, 6, 4 ¹ , 6 ¹ ) are each a rounded shield (13, 14, 13'14'), the end faces (28, 29) of which delimit a separation distance (30) in the first end position of the displaceable conductor part (15), the dielectric strength of which corresponds to the predetermined dielectric strength of the voltage level of the high-voltage system, that the other conductor end (6) in the interior of the coupling contact (7) in front of its contact surface (9) to the current lamellas (8) runs out to form a hollow cylinder (10) in which, adjacent to the end face (11), an insulating sleeve (12) is inserted, the inside diameter of which corresponds to the outside diameter of an end-side projection (20) on the displaceable conductor part (15), that in the second end position of the movable conductor part (15) the front side (23) of the insulating sleeve (12) rests against the shoulder (24) between the front contact surface (21) to the current lamellas (8) and the front-side projection (20) and · "> "* · I · Il I'M· - · r r &bgr; - 12 - VPA 8 5 P 4 O 3 3 that the displaceable conductor part (15) is provided on its front side (16) and on its outer surface (26) with engagement surfaces (25, 27) for displacement. 2. Encapsulated, compressed gas-insulated high-voltage system according to claim 1, characterized in that one conductor end (4) also ends in a second hollow-cylindrical coupling contact (17) with spring-mounted current lamellae (18), which is located inside the shield (14) and which is closed at the front with an insulating bearing ring (19), the inner diameter of the bearing ring (19) corresponding to the outer diameter of the rear contact surface (22) of the displaceable conductor part (15) which comes to rest on these current lamellae (18) in the second end position. 3. Encapsulated, compressed gas-insulated high-voltage system according to claim 1 or claim 2, characterized in that the contact surfaces on the displaceable conductor part consist of bores (25, 27) which serve to accommodate a tool. 4. Encapsulated, compressed gas-insulated high-voltage system according to claim 1, characterized in that a rounded clamping ring (49) is fastened to the displaceable conductor part (15) located in its second end position, which has a small distance from the end face (29) of the shield (14) surrounding one conductor end (4). 30 5. Encapsulated, compressed gas-insulated high-voltage system according to claim 4, characterized in that an insulating disk (48) is arranged between the clamping ring (49) and the end face (29) of the shield (14) of the conductor end (4).