DE2948622A1 - EXHAUST GAS SWITCH - Google Patents

Abstract

A tubular, moving contact piece (11) is surrounded by a blasting nozzle (27) which moves with it and is connected on the inlet side to the outlet (17) of a pump cylinder (19) which moves with it, can be displaced on a pump piston (21) that is supported in a fixed position, and contains extinguishing gas. The blasting nozzle (27) has a very narrow point (30), which is supported at a distance in front of the free end (12) of the contact piece (11) and is closed in the switched-on position of the switch by a fixed-position switching pin (35) which at the same time engages in the moving contact piece (11). The contact piece (11), which passes through the pump piston in a sealing displaceable manner, has blasting-out openings (16), which originate from its internal space (44), at a distance from its free end (12). In order that the extinguishing gas which is located in the internal space (44) as well as that in the pump cylinder (19) is precompressed at the start of the switching-off stroke, and in order that the extinguishing gas which is in consequence uniformly precompressed largely constrains the return flow of heated and ionised extinguishing gases directly into the pump space (22) at the start of the period during which the switching arc (45) is burning, the distance (41) between the blasting-out openings (16) and the base (18) of the pump cylinder (19) is shorter than the length of the switching stroke (40), while the thickness (43) of the pump piston (21) at the point (24) through which the moving contact piece (11) passes is of approximately the same size as the size (42) of the blasting-out openings (16), measured in the longitudinal direction of the moving contact piece (11). <IMAGE>

Description

Gas pressure switch

The invention relates to a gas pressure switch in the preamble of Claim 1 mentioned Art.

Such a switch is for example from CH-PS 588.154 or from this largely corresponding DE-PS 2329 501 known.

In this known switch, the movable, tubular contact piece in a tubular, on the pump piston facing away from the pump chamber of the pump cylinder Side molded guide hub out. This guide hub is also radial continuous openings, with which the exhaust openings only in the course of the switch-off stroke get in alignment. The distance between the exhaust openings in the movable, tubular The contact piece from the bottom of the pump cylinder is greater than the length of the switching stroke.

This means that the blow-out holes in the movable contact piece in the on position in any case and also at the beginning of the switch-off stroke remain closed by the guide hub.

If a switch-off stroke now takes place, what is located in the pump cylinder is informed Extinguishing gas with the known switch a precompression. That inside the moving In contrast, the extinguishing gas located in the contact piece experiences no or no significant Pre-compression as long as the switch pin still engages in the moving contact piece, because the connection between the pump chamber and the interior of the movable contact piece is prevented or at least severely throttled. Just before the moving contact piece leaves the switch pin, so there is a pressure gradient from the pump chamber to the interior of the movable contact piece. As soon as the movable contact piece is the contact pin leaves, the arc ignites, which immediately causes a considerable increase in pressure (and Ionization) of the gas in the air nozzle. As long as the narrowest point the nozzle is still closed, due to the pressure drop mentioned (and also because of the increase in pressure mentioned) a strong gas flow into the interior of the moving contact piece until the pressures in the pump cylinder and in the moving contact piece are balanced. But this also means that part of the pre-compression is lost only then should come fully into play when the blow nozzle is released from the contact pin will.

In addition, (at least as long as the air nozzle still is not released) some of the stressed and ionized by the arc Gases pushed back into the blow channels and the front part of the pump chamber), so that after the release of the blower nozzle and thus the possibility of discharging the extinguishing gas first heated and ionized for a comparatively longer period of time Gas flows through the nozzle and through the movable contact piece, which is a rapid Cooling and extinguishing the arc is detrimental.

In this prior art, one purpose of the invention is therein see to create a pressure gas switch of the type mentioned, in which also in the "critical" Moment, namely when the movable contact piece leave the switch pin but the narrowest point of the air nozzle is still closed by the switch pin and ionized gases are pushed back into the pump chamber, these into the butt Part of the pumping chamber are pushed and a subsequent cooling and extinguishing do not obstruct the arc.

This purpose is achieved in the proposed switch according to the invention achieved in that the distance between the blowout openings from the bottom of the pump cylinder is less than the length of the switching stroke, while the thickness of the pump piston increases the point penetrated by the movable contact piece is approximately the same size as the dimension of the exhaust openings measured in the longitudinal direction of the movable contact piece.

The interior of the movable contact piece is thus above the blow-out openings in the switch-on position but also in connection at the beginning of the switch-off stroke with the pumping room, so that the extinguishing gas both in the pumping room and is pre-compressed in the moving contact piece to the same extent. In the mentioned The "critical" moment is the pressure wave emanating from the arc both in the pump chamber as well as practically the same pressure inside the movable contact piece. This is particularly the case when the distance between the blow-out openings and the bottom of the pump cylinder about until reaching the minimum erase distance between the contact pin and the part of the switching stroke to be covered corresponds to the movable contact piece.

Additional measures can prevent the hot gases in the front part of the pump chamber are further inhibited. You can do this be arranged in the inlet of the nozzle means that a gas flow from the narrowest Block the nozzle towards the pump cylinder.

The not completely avoidable penetration of the heated and ionized Gases in the rear part of the pumping chamber is of little importance because the The arc is extinguished and cooled in the front part of the pump chamber cold extinguishing gas is pressed through the extinguishing arrangement.

Further features of preferred embodiments are the dependent Claims 4-7 can be found.

An embodiment of the invention is shown below with reference to the drawing described in more detail, in the single figure an axial section through essential components of a pressurized gas switch are shown, on the left in the switch-on Position, right in that position of the switch-off stroke where the switching distance is approximately the minimum Delete distance corresponds.

The illustrated components of the gas pressure switch 10 are in one not shown and filled with an extinguishing gas (for example SF6) under pressure Housing arranged.

The moving parts that go from top right to left marked below hatching are include a elongated, tubular contact piece 11, the free end of which by a ring resilient contact finger 12 is formed. The contact piece 11 has an axial bore 13, which extends up to the upper, conical end of a pressed-in stopper 14 extends.

The conical end face 15 of this stopper 14 is used, as is still the case will show as a guide surface for the through the contact piece 11 in the axial direction flowing gas, so that this to in the contact piece 11 at a distance from the contact fingers 12 formed exhaust openings 16 and is passed through them. That lower end of the contact piece 11 is coupled to a drive (not shown), this together with the moving component in the axial direction for execution the switching strokes shifts.

As can be seen from the drawing, the contact piece extends 11 by a movable bottom 18 of a pump cylinder, which is provided with passages 17 19 made of metal, on a pump piston supported in a stationary manner on a support tube 20 21 is displaceable. The pump cylinder 19 thus encloses between its base 18 and the pump piston 21 a pump chamber 22. The one provided with a suction valve 23 Pump piston 21 has a short guide hub 24 with a guide bore in its center 25, in which the contact piece 11 is guided in a sealing manner, however, displaceably. At the bottom At the end of the pump cylinder 19, a ring of resilient guide contacts 26 is mounted, which on the outer jacket surface of the also conductive support tube 20 to grab.

On the side facing away from the pump chamber 22 is on the floor 18 by means a snap ring 28, a blow nozzle 27 made of an insulating material, the nozzle chamber into a jacket-shaped inlet section which communicates with the passages 17 29, into an adjoining narrowest point 30 and then into a difusor-like expanding outlet 31 is structured. At the one facing away from the pump chamber 22 Side is also on the floor 18, the nozzle 27 surrounding a ring of power Contact springs 32 are mounted, which in turn are covered by an electrical hood 33 (for equalization of the electric field) are surrounded.

The power contact springs 32 relating to the contact fingers 12 are set back, engage in the on position (drawing on the left) on the outer jacket surface of a fixed contact tube 34. This contact tube 34 surrounds a tubular, fixed contact pin 35 arranged coaxially therein, whose outside diameter is essentially the inside diameter of the narrowest point 30 in the nozzle 27 and in the on position in the wreath of the contact fingers 12 intervenes. The free end 36 of the contact pin 35 projects over the end of the contact tube 34 before, so that in the course of the switch-off stroke, the contact springs 32 first disengage with the contact tube 34 and only then the contact fingers 12 except Intervention get with the contact pin 35, which in turn at the beginning of the switch-off stroke Blow nozzle 27 keeps closed.

The radially inner wall of the jacket-shaped inlet section 29 in the nozzle 27 is formed by a sleeve 37, which in turn forms the ring of the contact fingers 12 surrounds.

The inlet section is thus essentially smooth walls limited, which favor the formation of a gas flow. In this inlet section internals are advantageously arranged that allow a return flow, i.e. a flow from the narrowest point 30 back to the passages 17 and thus into the pump chamber 22 inhibit. These internals can, as shown in the drawing on the left, through inclined valve tongues 38 may be formed, the lower ends of which are attached to the sleeve 37 are attached and with their upper end on the outer inner wall of the inlet section 29 are resilient and can be lifted off.

The internals can, however, also be provided with rings that are wedge-shaped in cross section 39 (on the right in the drawing), which are attached to the outer inner wall of the Inlet section 29 and / or are attached to the outer wall of the sleeve 37 that the tip of its cross section points towards the passages 17. Through the valve tongues 38 (which form a kind of flutter valve) and / or through the rings 39 is on all If a gas flow to the passages 17 is more inhibited than a gas flow from the passages 17 to the narrowest point 30.

The length of the switching stroke corresponds approximately to the clear distance between the piston 21 and the bottom 18 in the on position of the switch (drawing on the left) and is indicated by the arrow 40. The (constant) distance between the exhaust openings 16 from the bottom 18 is smaller than the length of the switching stroke 40 and is indicated by the arrow 41 specified. The dimension of the blow-out openings measured in the longitudinal direction of the contact piece 11 16 is indicated by the arrow 42 and corresponds approximately to the length of the guide bore 25 (arrow 43) in piston 21.

These measures ensure that in the on position and at the beginning of the switch-off stroke, the pump chamber 22 always passes through the blow-out openings 16 remains in flow connection with the interior 44 of the contact piece 11. While of the switch-off stroke, the same pressure prevails in the pump chamber 22 and in the interior for so long 44, when the blowout openings 16 have not yet passed through the guide bore 25 are. This pressure equalization initially takes place in the pre-compression phase, namely as long as the contact pin 35 is still in engagement with the contact fingers 12 (until then there is no arc), but also immediately afterwards, namely for as long when the contact pin 35 still holds the narrowest point 30 closed. Then he has Arc 45 has already been ignited, and the pressure surge emanating from this can develop thanks to the valve tongues 38 resp.

the rings 39 spread only inhibited in the direction of the passages 17, but uninhibited in the direction of the blow holes 16 out, from where it is first in the vicinity of the piston 21, that is to say at that of the passages 17 propagates furthest point in the pump chamber 22 and thus for a (desired) Pressure increase in the pump chamber 22 ensures.

But as soon as the switch-off stroke reaches approximately the minimum extinguishing distance has covered the corresponding distance (arrow 40 'or 48) (in the drawing on the right or shown on the left), the exhaust openings 16 are through the guide bore 25 passed through, and thus the interior space 44 is surrounded by a support tube 20 Blow-out space 46 connected, in which no pressure increase has taken place. Already before but the arc 45 is also caused by the contact pin 35 before reaching the minimum extinguishing distance released nozzle 27 has been blown through, wherein the heated extinguishing gases, as far as they have passed the narrowest point 30, partly through the switching pin 35 through and partly in one enclosed by the contact tube 34 Blow off the blow-out space 47.

With the described gas pressure switch, there is a guarantee that that no loss of pre-compressed extinguishing gas occurs when the contact fingers 12 leave the switch pin 35, and also ensure that just in the initial phase the switch-off stroke as little heated and ionized gases as possible through the passages 17 are displaced directly back into the pump chamber 22, so that in the area the Passages 17 always have "uncontaminated" extinguishing gas available for blowing the sheet 45 stands.

Claims (7)

PATENT CLAIMS Compressed gas switch with a tubular, movable Contact piece (11) which is surrounded by a blow nozzle (27) which can move with it is, which in turn is moved on the inlet side to the outlet (17) of a, on a stationary supported pump piston (21) displaceable, containing an extinguishing gas Pump cylinder (19) is connected, the blow nozzle (27) one of the free end (12) of the movable contact piece (11) at a distance in front of the narrowest point (30), which in the on position by a stationary, at the same time into the movable contact piece (11) engaging switching pin (35) is closed, wherein the movable, but sealingly penetrating the pump piston (21) Contact piece (11) at a distance from its free end (12) from its interior (44) having outgoing blow-out openings (16), characterized in that the distance (41) of the blow-out openings (16) from the bottom (18) of the pump cylinder (19) less than the length of the switching stroke! 40), while the thickness (43) of the pump piston (21) increases that of the movable Contact piece (11) interspersed point (24) about is the same size as that measured in the longitudinal direction of the movable contact piece (11) Measure (42) of the exhaust openings (16). 2. Compressed gas switch according to claim 1, characterized in that that in the switched-on position the distance (47) between the outlet bores (16) and the pump piston (21) approximately until the minimum erase distance between the contact pin is reached (35) and the movable contact piece (11) to be covered part (40 ') of the switching stroke (40) corresponds. 3. Compressed gas switch according to one of the preceding claims, characterized in that means (38; 39) are arranged in the inlet (29) of the blow nozzle (27) are that a gas flow from the narrowest point (30) to the pump cylinder (19) inhibit. 4. Compressed gas switch according to one of the preceding claims, characterized in that inside (44) of the movable contact piece (11) Deflection surfaces (15) located in front of the blow-out openings (16) are provided are, which in the said interior (44) forming, axial gas flow in the deflect substantially radially towards the exhaust openings (16). 5. Pressure gas switch according to one of the preceding claims which the free end of the movable contact piece (11) is resilient by a ring Contact finger (12) is formed, which in the switched-on position on the outer circumference of the contact pin (35) attack, characterized in that the wreath of springy Contact finger (12) is surrounded by a sleeve (37) with its outside the jacket-shaped inlet (29) of the blow nozzle (27) delimits the inside. 6. Compressed gas switch according to claim 3, characterized in that that the backflow of the gas in the inlet (29) of the blower nozzle (27) inhibit Means formed by valve tongues (38) acting in the manner of a flutter valve are. 7. high pressure gas switch according to claims 5 and 6, characterized in that that the valve tongues (38) at their narrowest point (30) facing away from the blower nozzle (27) Ends on the outside of the sleeve (37) are attached and with their narrowest Point (30) facing ends resilient and liftable on the opposite wall of the inlet (29).