DE2039240C3 - Compressed gas switch with a device for generating a flow of extinguishing gas - Google Patents

Description

The invention relates to a gas pressure switch with a device for generating a Extinguishing gas flow, in particular a blow piston switch, with a fixed and a movable contact piece, in the closed position of a blow nozzle firmly connected to the movable contact piece are surrounded.

The French patent 15 16 913 deals with a pressure gas switch of this type, in which the The arc between the contact pieces is extended until the moment of its extinction away from each other. It has been found that these gas pressure switches with a switching chamber of limited volume the expansion of the arc ionized the occurrence of a very large volume Favors gas that creates a strong overpressure, which tends to oppose the flow of regenerated extinguishing gas required for extinguishing the Arc is essential.

The invention has the object, in a gas pressure switch of the type mentioned, an unnecessary elongation of the Avoid arcing and create a gas pressure switch with increased switching capacity.

This is achieved in that the blower nozzle is made of electrical power at least on its inside Has conductive material, which is arranged insulated from the movable contact piece and with is electrically conductively connected to the stationary contact piece at least during the extinguishing phase.

The arc, i.e. drawn between the separating contact pieces, quickly attaches itself to the electrically conductive part of the nozzle and to the associated movable contact piece, its lower Maintain distance and remains constant during the opening process of the gas pressure switch. The distance of the Arc root points remain constant and the volume of the generated ionized gas is limited as a result.

The extinguishing gas (an extinguishing liquid can also be used), in particular electronegative, 7. B. sulfur hexafluoride, flows axially into the nozzle. It is understandable that in the case of the known gas pressure switches with an arc extending axially between the contact pieces, the extinguishing effect is not optimal. According to the invention, the arc lying on the conductive part of the blower nozzle is made to assume its transverse position with respect to the flow of the extinguishing gas, which is particularly favorable for deionization.

A known type of compressed gas switch, which extinguish the arc with flowing compressed gas, avoids the expansion in that the nozzle is designed as an annular chamber, which is the movable Contact piece and contains gas channels inside, which divide the gas flow into two partial flows. The one The gas flow blows the arc drawn between the fixed and moving contact in the direction on two fixed auxiliary electrodes, one of which is connected to one of the two contact pieces Connection. There are then two partial arcs between the ring chamber and the two Auxiliary electrodes, which are extinguished by the first in connection with the second partial gas flow. These Type of switches achieve the quick extinguishing of the arc only through a very complicated design the arc extinguishing system, which is expensive and difficult to maintain (DRP 6 62 215).

Another known circuit breaker is used with arc quenching by flowing pressurized gas two tubular movable contact pieces, both of which are driven by an annular piston to generate the gas pressure are surrounded. Inside the movable, tubular

gen contact pieces are axially displaceable against the pressure of a spring each a tubular contact piece arranged as an arcing contact, the Lei closed switch is enveloped by the main contact piece. With this switch, the arc is drawn in length, but due to the arrangement of the arcing contacts, which are under spring pressure, the contact point only opens when the contact pieces have already assumed a high speed under their double drive. The two annular pistons also create sufficient gas pressure that blows the arc into the tubular contact pieces and extinguishes it. These switches also achieve rapid extinguishing of the arc only with considerable effort (DE-AS 11 56 143).

Advantageous further developments of the subject matter of claim 1 can be found in the subclaims.

In a known pressure gas switch with arc quenching A blow nozzle is provided by flowing gas, which is fixed to the fixed contact connected is. The end of the nozzle is made of conductive material and the nozzle body is made of resistance material. In this way, the arc that initially occurs between the fixed and the moving Contact piece burns, be pulled over onto the nozzle, the current flowing through the resistor is limited (DE-AS 11 94 949).

Embodiments of the invention are shown in the figures. It shows

F i g. 1 shows an axial section of a pressurized gas switch in the closed position,

F i g. 2 a fig. 1 corresponding section, with the gas pressure switch during the opening process is shown, and

3 shows an axial section of a further exemplary embodiment of a compressed gas switch in FIG. 2 accordingly; n position.

According to FIGS. 1 and 2, the gas pressure switch has a switching chamber made of insulating material in the form of a Cylinder 10 closed at its ends by bottoms 12 and 14, one of which is one sliding control rod 16 is penetrated, the outer end of which with a control device, not shown cooperates A blow piston 18 can inside the cylinder IO under the action of the Slide control rod 16, at the end of which it is attached. The edge of the blow piston 18 has a lip seal 20, which slides on the inner wall of the cylinder 10 and a perfect seal in the direction of movement of the blow piston 18, which corresponds to the opening of the gas pressure switch and indicated by the arrow Fder F i g. 2 is marked In the opposite direction, the lip seal 20 allows a free connection between the k; ic! en end faces of the blow piston 18. A blow nozzle 22 is firmly connected to the blow piston 18, which has openings 24 through the Inner part of the blow nozzle 22 connects the two chambers that are formed in the cylinder 10 by the blow piston 18 be delimited. A movable contact piece 26 is arranged concentrically in the interior of the blow nozzle 22, which is arranged at the end of the control rod 16 so that it can perform an axial movement that in with respect to the control rod 16 is limited. For this purpose there is a compression spring 28 between the control rod 16 and the movable contact piece 26 are provided, which this in the direction of the control rod 16 pushes away. In this position, the contact piece 20 held by a stop 30 which cooperates with a shoulder 32 of the control rod 16. One Contact tulip 34 connects the movable contact piece 26 to the control rod 16 electrically, which the movable contact piece 26 serves as a power supply conductor

The upper bottom 12 of the cylinder 10 carries a terminal 35 of the gas pressure switch, which with a fixed contact piece 36 is connected This is formed by a cylindrical rod which is in the Axis of the cylinder 10 and is arranged opposite the movable contact piece 26 with which it cooperates In the closed position of the gas pressure switch according to FIG. 1, the contact pieces 26 and 36 are located against each other, and the contact zone is inside the nozzle 22 - in the direction of flow of the As seen from the extinguishing gas - above a narrowed section 38 of the blowing nozzle 22.

The upper base 12 also carries a tubular cylindrical sleeve 40 which is coaxial with the cylinder 10 and is connected at its base to the terminal 35. The tubular sleeve 40 consists of electrically conductive material and has openings 41 near its base. The other end of the Sleeve 40, which serves as the main contact piece 42, surrounds the blow nozzle 22 concentrically, which is in it with a engages appropriate distances, and operates with main contact pieces 44 in the form of terminals together, which are firmly connected to the blow piston 18 and electrically to the control rod 16. the The passage of the control rod 16 in the bottom 14 is sealed by a bellows 48 or on another Way made.

According to FIG. 1, the blowing nozzle 22 has an upper part 50 made of conductive material, which extends below the narrowed section 38 of the blowing nozzle 22 in an insulating part 52, which connects the part 50 firmly to the blowing piston 18. The conductive member 50 is extended By J ¹ · a conductive ring 51 which is located on the outer wall of the insulating member 52nd Current collectors 46, which are firmly connected to the sleeve 40 and are in contact with the ring 51 of the blow nozzle 22, electrically connect them to the sleeve 40 ii of the engagement position. The current collectors 46 work in succession with the ring 51 and the outer surface of the part 50 in order to electrically connect the latter to the sleeve 40 and thus to the contact piece 36 during a predetermined opening distance of the contact pieces 26 and 36.

In the closed position of the contact pieces according to FIG. i becomes the electrical connection between the terminals 16 and 35 through the interlocking main contact pieces 42, 44 and through the touching contact pieces 26,36, which are used to extinguish the arc, secured. The conductive part 50 of the The blowing nozzle 22 is isolated from the movable contact piece 26 by a part 52 and by the current collector 46 and the sleeve 40 are connected to the fixed contact piece 36. The cylinder 10 is tight and with extinguishing gas, z. B. sulfur hexafluoride, possibly compressed, filled, the pressure is uniform throughout the room.

The gas pressure switch works as follows:

To open the gas pressure switch, one drives the Control rod 16 down in the direction of the arrow Fan, which when it is moved, the blow piston 18, the movable main contact piece 44, the nozzle 22 and the carrier of the contact piece 26 takes along, the

the latter during a first phase of travel the action of the compression spring 28 remains in contact with the fixed contact piece 36. This shift on the one hand causes the separation of the main contact pieces 42, 44, which, however, is still caused by the contact pieces 26,36 are bridged and open without arcing, and on the other hand a compression of the gas in the lower part of the cylinder 10, the volume of which decreases with the lowering of the blow piston 18. The pantograph 46 slide on the conductive parts 50 and 51, making the electrical connection between them and the contact piece 36 maintained. In a second opening phase, the shoulder 32 comes Control rod 16 in contact with the stop 30 of the contact piece 26 and takes this with, with a Separation of contacts 26, 36 with an arcing pattern. The hot ionized gases are through the Blow nozzle 22 and the tubular sleeve 40 extending it in the upper part of the space in a zone conducted, which is removed from the main contact pieces 42, 44. where they come out of the sleeve 40 through the openings 41 escape.

According to FIGS. I and 2, the whole upper portion 50 of the blow nozzle 22 of conductive material and dip electrical connection with the fixed KontHlitsii ^ k it> is prepared by the pantograph 46th It is clear that only a small part of the nozzle 22 can be conductive and that it can be used in any other way, e.g. B by a stranded wire with which the fixed contact piece 36 can be connected. The arrangement is particularly suitable for placing a resistor in series with the arc, whereby the separation of currents ¹

uuiig /.WiSCMCM UiCSCIi rvuiiiaKisiu (.Kcii io, j «mm inside the blow nozzle 22. Under the effect of the increasing pressure with the displacement of the blow piston 18, a flow of the gas inside the blow nozzle 22 is caused to extinguish the arc. As soon as the distance between the contact pieces 26, 36 reaches a predetermined value, the arc leaves the fixed contact piece 36 and jumps over to the conductive part of the blow nozzle 22 that is electrically connected to it under the blowing effect, which continues and acts across the path of the arc, it goes out.

During the extinguishing phase of the arc, the current collectors 26 are in contact with the conductive part 50 the nozzle 22 remained, and only at the end of the opening profile and after the arc extinction they separate to improve the dielectric condition of the interrupter.

It is easy to see that the distance between the arc roots is determined by the structural features of the gas pressure switch remains almost constant at the end of the extinguishing phase. The choice of this distance or more precisely the minimum distance between the contact piece 26 and the conductive part 50 of the blow nozzle 22 in FIG Stagnation zone of the arc is a compromise between the opposing factors of the minimal necessary breakdown distance and the power as well as the flow rate of the extinguishing gas in the deletion zone. Remarkable results have been achieved with distances between 3 and 4 mm, with the Arc base in the vicinity of the narrowed section 38 of the P.lasdüse 22 sets. The blowing takes place across the arc and ensures rapid deionization. The main contact pieces 42,44 outside the nozzle 22 are protected by this, as it is a metal screen for the arc F i g. I and 2 this object is easily achieved in that the conductive part 50 of the blow nozzle 22 is made of a material

> n of coarse power resistance, e.g. B. graphite produced will. It will be understood that once the arc sets on the conductive portion 50, the current is one Resistance track flows through to reach the current collector 46 and the terminal 35. One for them

Γί Arc quenching favorable effect results from the forgetting of this resistance path and thus of the during the displacement of the blow nozzle 22 introduced resistance. The additional resistance can also go into the connect? 'wipe the

S "terminal 35 and the conductive part 50 of the Blowing nozzle 22 are inserted, as can be seen more clearly from the following illustration.

3 shows an exemplary embodiment of a Compressed gas switch, in which the function of the fixed

r> main contact piece and the function of the electrical connection of the conductive part 50 of the blow nozzle with the fixed contact piece are separated. The movable main contact piece 44 cooperates with a fixed contact piece 54, and the conductive part 50 of the

J "nozzle 22 has current collectors 56, which are on a Slide tube 58 which connects the conductive part 50 of the blow nozzle 22 to the terminal 35. The pipe 58 and / or the conductive part 50 of the blow nozzle 22 can be made of a material that is a good electrical conductor, e.g. B. Copper

4- or steel, or in the manner described above consist of a material of high resistivity to create a resistance in the Introduce arc circuit. According to FIG. 3 corresponds to an increase in the resistance e.ner

> n increased length of the pipe, resulting from a Shifting the pantograph 56 results. The main contacts 44 and 54 are completely different from the Blow nozzle 22 independently.

For this purpose 3 sheets of drawings

Claims (9)

Patent claims: 1. Compressed gas switch with a device for generating a flow of extinguishing gas, in particular Plunger switch, with a fixed and a movable contact piece, which is in the The closed position is surrounded by a blow nozzle that is firmly connected to the movable contact piece are, characterized in that the nozzle (22) at least on its inside a ι ο Has part (50) made of electrically conductive material, which is arranged isolated from the movable contact piece (26) and with the stationary Contact piece (36) is electrically conductively connected at least during the extinguishing phase. 2. Compressed gas switch according to claim 1, characterized in that the electrically conductive part (50) the nozzle (22) consists of a material with a high line resistance. 3. Compressed gas switch according to claim 2, characterized in: o characterized in that the electrically conductive part (50) of the blow nozzle (22) consists of graphite. 4. Gas-blast switch according to claim 1, characterized in that an electric resistance in the connection means between the electrically ^r 2> conductive member is inserted (50) of the blast nozzle (22) and the fixed contact piece (36). 5. Compressed gas switch according to claim 4, characterized in that the blowing nozzle (22) in the Locking position? of the contact pieces (26,36) from a) < > Coaxial tubular sleeve (40, 58) made of electrically conductive material is surrounded with the fixed KontaK'Uück (36) in electrical conductive connection and i., it the electrically conductive part (50) of the blow nozzle (22) at least r> is electrically connected during the deletion phase. 6. Gas-blast switch according to claim 5, characterized in that the electrically conductive connection between the electrically conductive portion (50) of the w blast nozzle (22) and the sleeve (40,58) is manufactured attached to the tuyere current collector (46) via at least . 7. Compressed gas switch according to claim 5 or 6 with main contacts which open in front of the contact pieces arranged inside the -r, blowing nozzle, characterized in that the main contact pieces (44, 54) outside of the blowing nozzle (22) and the sleeve (58) are coaxial are arranged in relation to these and that the blowing nozzle (22) and the tubular coaxial sleeve v> (58) form a screen which prevents the gases ionized by the arc from entering the zone of the main contact pieces. 8. Compressed gas switch according to claim 7, characterized in that the sleeve (58) consists of a ίΐ Material with high electrical power resistance is made. 9. Compressed gas switch according to claim 7, characterized in that the sleeve (58) has a wound Contains resistance, l "