DE1228698B - Gas pressure switch - Google Patents

Description

FEDERAL REPUBLIC OF GERMANY GERMAN 4WIW> PATENTAMT Int. Cl .:

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EDITORIAL

German class: 21 c - 35/10

Number: 1228 698

File number: S 84313 VIII d / 21 c

Filing date: March 22, 1963

Opening day: November 17, 1966

A pressure gas switch is known, its movable, with a fixed counter-contact piece cooperating shift pin is hollow. The counter-contact consists of contact fingers that are in the On position rest on the outside of the hollow switching pin, and a burn-off pin surrounded by this, which protrudes into the interior of the switch pin.

The counter-contact is surrounded by an insulating body, so that a kind of chamber is created, which can be connected to a source of pressurized gas via a valve. The insulating body has a substantially tubular part and a disk-like part angled approximately perpendicularly thereto Part.

In the switched-on position, the hollow switch pin protrudes through an opening in the disk-like part of the Insulating body into the chamber. The edge of the opening is semicircular in cross section. Of the The diameter of the semicircle is about a quarter of the diameter of the switch pin. During the switch-off movement the switch pin is pulled out of the chamber. In the direction of the switch-off movement the compressed gas also flows out of the chamber.

The burn-off pin of the known switch sits eccentrically with respect to the contact fingers surrounding it. Its tip is about the diameter of the switch pin in front of the disk-like one Part of the insulating body.

The invention is also concerned with a pressure gas switch with a hollow movable one Switching pin and a fixed counter-switching piece, which consists of contact fingers and one of them surrounded There is a burn-off pin, as well as with an insulating body surrounding the counter-contact piece an opening through which the switch pin protrudes in the on position and the compressed gas in Switch-off direction of the switching pin flows off.

In contrast to the known switch, the invention provides that the opening is a has a cylindrical shape that the inner cross section of the insulating body in the direction of the Opening tapers steadily and that the tip of the burn-off pin is concentric in the area of the transition of the tapered part of the insulating body lies in the cylindrical opening.

In the switch according to the invention, the opening works together with the continuously tapering one Part of the insulating body in terms of flow as a nozzle. A largely laminar, i.e. H. low-loss gas flow. The burn-off pin on which the Arc transferred from the contact fingers

Applicant:

Siemens-Schuckertwerke Aktiengesellschaft,

Berlin and Erlangen,

Erlangen, Werner-von-Siemens-Str. 50

Named as inventor:
Dr. Ernst Slamecka,
Bruno Müller, Berlin

will. Its tip is located in the area of the transition to the cylindrical opening, ie immediately in front of the narrowest cross-section of the nozzle, in which the velocity of the flow is at its maximum achieved. There is also a radial component of the flow in this area. Thereby are optimal conditions for extinguishing the arc are given.

The mentioned greatest speed in the cylindrical opening prevails practically over the whole Length of opening. This means that the arc plasma is applied from the burn pin side is discharged from the switching path at high speed.

The new switch has not only proven itself in trials, but also in practice proven. He is z. B. been used in rail operations, where because of the high frequency of short circuits and the low frequency and thus long half-wave time (= arc duration) is well known special requirements are placed on the performance. Despite these high demands was shown due to the flow-favorable shape of the switching path with low compressed gas consumption a high switching capacity results, even after years of use, there is hardly any burn-off on the contact pieces. This represents a considerable technical advance compared to known railway switches, which require a contact piece change after just a few short-circuit disconnections. From this can one can also infer the inventive features of the new switch. Although individual features were known to those skilled in the art from other switches prior to the invention, these features became apparent not in the way according to the invention to build

609 727/334

a switch is used that has a low compressed gas consumption with a high switching capacity and therefore undoubtedly meets a great need.

The ratio of the diameter of the cylinder of the opening to the length of the cylinder is preferably 1 to 2. Switch according to the invention with such nozzle dimensions that in another context are known per se, have proven themselves well.

The contact fingers can be surrounded by a metallic guide body which, for. B. with liquid switches is known per se. The guide body can be used together with the insulating body form an annular channel for the gas supply. But it can also be beneficial not just to let the pressurized gas through to allow the annular channel to flow between the guide body and the insulating body, but rather at the same time also through the space between the contact fingers and the guide body, because this the commutation of the arc is supported by the contact fingers on the arcing pin can.

The switch pin is expediently pneumatically operated in the switch according to the invention, such as is also known per se. For this purpose, one can be located behind the opening in the direction of flow Pistons may be provided. The piston can only set the switch pin in motion when a Pressurized gas flow is present through the opening. Switching off when the blowing pressure is insufficient is thus excluded.

As has been shown in tests, the switch according to the invention is particularly suitable for the known use of sulfur hexafluoride (SF ₆ ) as a compressed gas. The fluidically favorable arrangement according to the invention comes into its own with this gas, since sulfur hexafluoride is a relatively heavy gas and is therefore particularly sensitive to irregularities in the flow. A vigorous flow is also obtained for sulfur hexafluoride in the switch according to the invention at low pressures. Because of the well-known good extinguishing effect of sulfur hexafluoride, this results in a very high switching capacity with little energy.

To explain the invention in more detail, an exemplary embodiment is shown below with reference to the Description of the drawing in which, for the sake of simplicity, only one switching path is shown. The shelter the switching path in a housing carried by a post insulator or a grounded one Metal container is not shown. There are also details of the compressed gas system, e.g. a connection the switching path to a high pressure tank and possibly a connection with a low. pressure vessel and a compressor to form a closed gas circuit for the sake of clarity not drawn.

The switching path sits in an insulating tube 1 and consists of the movable switching pin 2 and the stationary mating contact piece 3. The moving switching pin 2 is hollow and has a piston 6 provided, which slides along the inner wall of the tube 1. In the side wall of the piston is a Seal 7 inserted. The tip of the switching pin facing the counter contact piece 3 carries in itself a known manner a burn-off ring 4 made of arc-proof material.

The counter-contact piece 3 has a number of contacts distributed around the circumference of a circle as contact fingers Contact blades 12, which are under the action of compression springs 13 and 14. The compression springs are supported against a metallic guide body 25. They press the lamellae 12 in the illustrated Switch-off position of the switch at 15 and 16 against a metal body 17. In the switch-on position are the lamellas with the designated 18

ίο the edge on the outside of the switch pin 2.

An essentially cylindrical burn-off pin 20 is seated centrally to the lamellae 12. The burn-off pin is screwed into the metal body 17 at 22. Its free end is also provided with a cap 21 provided in a known manner made of arc-proof material. It tapers to about the tip half the diameter of the cylindrical part.

The counter contact piece 3 is surrounded by an insulating body 30, which with screws 31 on a Flange plate 32 is attached. In the flange plate is the metal body 17 is also screwed in at 33. As a result, the insulating body 30 is also related set on the metal body 17.

Starting from the flange plate, the insulating material body 30 initially has a cylindrical shape. He forms an annular channel 40 with the guide body 25. As the distance from the flange plate increases the inner cross-section of the insulating body tapers continuously in a concave region 26, i. H.

without steps or kinks that could create eddies. The area 26 is followed by a convex one Area 27 which forms the transition to a cylindrical opening 37. In this area and the adjoining cylindrical part, the insulating body 30 consists of a tubular part 35 Polytetrafluoroethylene, which in the other, z. B. made of cast resin part 34 screwed at 36 is. The opening 37 has a length to diameter ratio of 1.5.

With the bore 38 of the metal body 17, the switching path is connected to a high-pressure accumulator, not shown connected. Bores 39 in the metal body 17 lead from the bore 38 to the annular space 40 between the guide body 25 and the insulating body 30. Through further bores 42 the bore 38 is also connected to the space 43 between the burn-off pin and the guide body, in which the slats 12 are located.

In the switched-on position, the switching pin 2 protrudes through the cylindrical opening 37 so that it is in contact with the lamellae 12 of the counter-switching piece 3. If it is to be switched off, the switching path is connected to the high-pressure container by opening a valve (not shown). The sulfur hexafluoride (SF ₆ ) used as compressed gas with a pressure of 5 atm or more flows through the bores 38, 39 and 42 and passes through the annular gap between the inner wall of the opening 37 and the outer wall of the switching pin 2 into the space 44 in front of the piston 6. Pressure builds up on piston 6 and the switch pin is set in motion in the disconnection direction.

When the contact is separated between the switch pin 2 and the contact blades 12, a Electric arc. This is inflated immediately, as the switch pin is only set in motion when a certain minimum pressure at the piston located behind the opening 37 in the direction of flow.

hand is. The blowing takes place initially mainly through the bores 42 and the space 43 and supports the transition of the arc from the contact blades 12 to the burn-off pin 20.

During the further switch-off movement, the tip 4 of the switch-off pin enters the opening 37 the outflow cross-section is also completely released for the gas from the annular channel 40. Of the Arc between the switching pin 2 and the burn-off pin 20 is therefore intensely blown. the There is a flow in the area of the tip of the burn-off pin immediately in front of the one formed by the opening 37 narrowest cross-section a high speed in the axial direction. In the area is also a considerable flow component in the radial direction, d. H. across the arc, present that the arc column is detected in the current zero passage down to the core.

The radial component results from the formation of the mouth of the annular channel 40 in FIG the opening 37, on the other hand, it is determined by the ratio of the diameter of the cylindrical burn-off pin the diameter of the opening 37 is determined. In the exemplary embodiment, the ratio is 0.67. The tapering of the tip of the burn-off pen ensures a smooth transition to that of the The narrowest flow cross-section formed opening and reduces the size of the one behind the burn-off pin dead space (slipstream).

As tests have shown, the arc extinguishes with the switch according to the invention in general, before the tip of the switch pin has passed through the opening 37. The switching gases flow through the hollow switching pin 2 and possibly this downstream, not shown in the drawing Cooler and filter off. In the switched-off position shown, there is great electrical strength along the length the switching path available. To increase the electrical strength, overpressure can be applied to the Switching distance can be maintained, e.g. B. by valves. For a switch with a closed Gas circuit and a compressor you can also set the response value of the compressor on the low pressure side according to the desired minimum pressure in the low-pressure system, to which also the switching path belongs.

The switch is also switched on pneumatically. For this purpose, the switching path is used opposite side of the piston 6 is acted upon with pressurized gas, via lines not shown and on-off valves is supplied. Here, too, pressurized gas can be used before and during the switching movement flow through the hollow switch pin to keep the flashover arc small. Of the Switch according to the invention can also be mechanical, e.g. B. are actuated by springs.

Claims (8)

Patent claims: 1. Compressed gas switch with a hollow, movable switch pin and a fixed counter-switch, which consists of contact fingers and a burn-off pin surrounded by them, as well as with an insulating body surrounding the counter contact piece with an opening through which the switch pin protrudes in the switch-on position and through which the compressed gas in the switch-off direction of the switching pin flows, characterized in that the opening has a cylindrical shape that the inner Cross-section of the insulating body tapers steadily in the direction of the opening and that the tip of the burn-off pin concentrically in the area of the transition of the tapered part of the insulating body lies in the cylindrical opening. 2. Compressed gas switch according to claim 1, characterized in that the diameter of the opening is one to two times the cylinder of the opening. 3. Compressed gas switch according to claim 1, characterized in that the diameter of the burn-off pin is at least half as large as that Diameter of the opening. 4. Compressed gas switch according to claim 3, characterized in that the tip of the burn-off pin rejuvenates. 5. Compressed gas switch according to claim 1, characterized in that the contact fingers of one metallic guide body are surrounded, which together with the insulating body one Forms annular channel for the gas supply. 6. Compressed gas switch according to claim 5, characterized by such a design that the Pressurized gas also flows through the space between the contact fingers and the guide body. 7. Compressed gas switch according to claim 1, characterized in that the switching pin of an in Direction of flow behind the opening piston is pneumatically operated. 8. Compressed gas switch according to claim 1, characterized by the use of sulfur hexafluoride (SF ₆ ) as the compressed gas. Considered publications:
German patents Nos. 566 432, 568 350,
812, 588 693, 590943, 607703. 1 sheet of drawings 609 727V334 11.66 © Bundesdruckerei Berlin