DE1028662B - Fire chamber for low-liquid electrical circuit breakers - Google Patents

Description

GERMAN

Arcing chambers for low-liquid circuit-breakers equipped with a pumping device, are effective in that the arc causes a flow of extinguishing agent through channels in a more concentrated manner Form can be fed. A known pumping device is the differential piston. To his drive the pressure generated by the arc through evaporation of extinguishing liquid is used. There the differential piston can only start moving after the flow paths have been opened, the The quenching chamber absorbs the sudden surge of pressure that occurs when the contacts are separated. This pressure surge, the size of which depends primarily on the strength of the current, can be dangerous assume high values. The extinguishing chamber is therefore exposed to very high mechanical loads. As a result of the constantly increasing short-circuit performance of the networks, this problem wins more and more important.

In order to be able to better control the mechanical stress caused by the pressure surge, it has already been proposed to equip the extinguishing chamber with an air-filled pressure storage space, which absorbs the pressure surge and thereby reduces the stress on the extinguishing chamber walls. The arc gases press the extinguishing agent into the pressure storage space and the compressed one Potential energy inherent in gas cushions is used for the flow of extinguishing agent. It must be taken into account here, however, that at the moment of exposure of the flow channels through the Switching pin the passage between the pressure accumulator chamber and the arc chamber must be closed, otherwise at least part of the stored pressure is uselessly balanced in the arc chamber, its Gas pressure relaxes through the flow channel. The closure of the pressure storage space can done by check valves, which are when the stored pressure overhands compared to the Close arc gas pressure. Non-return valves, however, represent a considerable flow resistance, since they can naturally only release a partial cross-section. It should therefore be inevitable that in the extremely short time from the creation of the arc to the opening of the flow channels not all of the arc gas pressure can be transferred to the pressure storage space. Consequently will the extinguishing flow is delayed, d. H. only start after a pressure gradient has formed. It is further take into account the closing time of the valves, so that the arc duration is also undesirable extended.

The invention relates to an arcing chamber for low-liquid circuit breakers with a gas-filled one

Extinguishing chamber for low-liquid
electric circuit breakers

Applicant:
Sachsenwerk

Licht- & Kraft-Aktiengesellschaft,
Munich, Schillerstr. 41

Erich Obert, Regensburg,
has been named as the inventor

Pressure storage space for bringing about a flow of extinguishing agent through the movable switch pin Channels. It makes use of the advantages of the piston chamber and the pressure storage chamber, without their defects having to be accepted. This is achieved by removing an arc gas pressure Piston acting on one side transmits the pressure to the pressure accumulator chamber, which is also the flow channels is in free communication, and that after opening the flow channels through the switching pin the return movement of the piston under the action of a spring tensioned during the pumping stroke by z. B. means based on clamping effect until about the time of relaxation of the gas cushion is delayed.

The return movement of the piston can be brought about by a roller or spherical pressure body that is located between the cylinder wall and at the moment of the reversal of movement of the piston a pressure surface of one carried by the piston at an acute angle to this, against resistance sliding counter pressure piece stuck. The counter-pressure piece is advantageously tightly closing in one with the liquid extinguishing agent, ζ. Β. Oil, filled blind hole in the piston, expediently disc piston, out, with an outflow opening controlling the delay and / or an outflow channel is provided. The liquid displaced by the counter-pressure piece until the clamping is released a measure of the duration of the delay.

The delay device associated with the piston makes the use of check valves superfluous. The piston can therefore respond immediately when the arc gas pressure arises and the extinguishing agent is unhindered by

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to the contact pieces lying pressure storage space 9 is in the immediate vicinity of the with him in free connection standing flow channels 10 and 11 arranged. The flow channels are perpendicular to the light

5 arc axis aligned and open into the pressure-free Room 12 of the extinguishing chamber. The disc piston contains three delay devices evenly distributed around its circumference 13, the mode of operation of which is explained in more detail with reference to Figs. 2 to 4.

ο The delay device consists of the roller-shaped pressure body 14 and the counter-pressure piece 15, the pressure surface 16 of which is at an acute angle to the cylinder wall. The counter pressure piece is tightly closing in the blind hole 17

narrow valve openings and, since nothing stands in the way of ample dimensioning of the through channel,
practically smoothly in the pressure storage space
to press. There are thus the prerequisites for the
Transfer of the entire arc gas pressure to
given the pressure storage space. The volume of gas enclosed in the pressure storage space has a mitigating effect on the pressure surge. In addition, the with
the increase in volume of the arc chamber associated with the formation of pressure as a result of the piston movement, the dangerous peak is taken away from the pressure surge. The delay in the return of the
The piston causes the moving switch pin to open the flow channels immediately
the entire potential energy of the pressure accumulator 15 is performed. The spring 18 moves the counter-pressure piece in the output space as a power source for the extinguishing agent flow position of the piston only as far as is available. The extinguishing agent is thus in the position required for the unimpeded pumping movement of the KoI position, immediately the gas jacket of the arc beneath, that is, the pressure body 14 is constricted and in the current zero passage the light is loosely in the position shown in Fig. 1 between the arc to deionize and against the re-20 of the pressure surface 16 and the cylinder wall. To make this sweeping voltage puncture-proof. To make it possible, the cylinder with the turning occurs therefore in the shortest possible time the extinction of the light 19 is provided.

arc a. The arc gas pressure can force the piston

Experience has shown that with venous inhibition, press down. If the piston tries, be a forced flow is proportional to the spring tensioned during its pumping stroke, Moderately small amount of extinguishing agent, especially if it is due to overpressure in the pressure accumulator In the case of oil, chamber for arc quenching, return, then the is required. In a further embodiment of the pressure body between the cylinder wall and the counter-finding If this knowledge is used, the pressure piece is jammed and thus inhibits the power. After a predetermined stroke, the piston returns. The counter pressure piece can Piston, e.g. B. by means of approaches acting as a slide, give in to the pressure on it to the extent that Chamber from the pumping chamber into the pressure-free chamber of the extinguishing agent like liquid through the discharge opening 20 leading exhaust ports free. The piston is pushing, so that finally the pressure hull thus only a small one, but is released again for deletion. By appropriately dimensioning the sufficient amount of extinguishing agent in the pressure accumulator 35 cross section of the outflow opening and length of the to convey space, so that it accelerates very quickly the pressure surface and, if necessary, the degree of its inclination can be. If at the time of opening the stop, you have the option to determine the time span of the return ducts or any excess arc gas pressure running delay of the piston, In Fig. 2, the length of the pressure surface is through the channels relax. As a result, the piston is limited to only 40 stop 21.

still to a small extent, if at all, over the As the return delay of the piston is only

Driven predetermined stroke addition. The controlled over the short, up to the opening of the pressure chamber The first pressure relief therefore still has the further period of time required by the switch pin, i.e. The advantage that the degree of compression of the gas does not extend over more than several half-waves or air cushion in the pressure storage space is to limit 45, it is desirable that the delay stops, is lifted nicely. The piston can then immediately return to the drawing, so that the switch is in the shortest possible time schematically illustrated embodiments, which is ready to switch again. This requirement will be additional Contain features of the invention, which is met according to the invention in that, according to Fig. 3, the further explained. It shows 50 blind hole 17 serving as an outflow channel Fig. 1 shows the longitudinal section of a groove 22 according to the invention. This is designed in such a way that it follows

a short, the desired duration of the delay corresponding displacement path of the counter-pressure piece an increasing outlet cross-section

Fig. 5 shows the longitudinal section of a further embodiment. In Fig. 4, which shows the section AB , is the shape of the extinguishing chamber and shows that the outflow channel 22 in the different

Fig. 6 and 7 the sections CD and EF through this direction of movement of the counter-pressure piece has a widening cross-section.

For the sake of clarity, they are the same in the arcing chamber according to Fig. 1

If parts of the drawing are separated with the same reference 60 contact pieces, the arc symbol Mistake. gas pressure initially only affect the piston. Since the extinguishing chamber according to Fig. 1, a significant flow resistance is not described first. The extinguishing chamber housing is marked with 1, which stands, the piston can immediately re-fix the pressure surge Switching contact with 2 and the movable switching give and pump extinguishing agent into the pressure accumulator pen labeled 3. The fixed switch contact 65 space. This elastic design of the arcing chamber The sheltering housing 4 is located in the arc chamber 5, making it largely insensitive to the through to which the cylinder space 6 adjoins. In which the sudden pressure surge occurring mechanical The disc piston 7 slides into the cylinder space, causing its stress. As soon as the flow channels 10 and Return to the starting position, the spring 8 11 are exposed by the switch pin, this can serves. The ring-shaped and concentrically 70 compressed gas cushion in the pressure storage space

Extinguishing chamber,

Figs. 2, 3 and 4 show details of the delay device on an enlarged scale,

relax by feeding the extinguishing agent upstream of it into the flow channels. As a result of With a short return delay of the piston, the entire accumulated pressure for the extinguishing agent flow comes into play to the effect. The risk of gas or gas as a result of the rapid movement of the extinguishing agent. Air escaping from the pressure storage space can be reduced by increasing the level of the extinguishing agent in the pressure storage space prevent. You can do so much through a hole in a wall of the pressure storage chamber Let air out until the desired level is reached. The hole is then closed again. the The use of a pump piston has the advantage over the pistonless pressure storage chamber, that the hot arc gases are separated from the oil intended for extinguishing. If necessary, im A bore with a small cross-section in relation to the piston area is provided for the piston crown, in order to suck extinguishing agent out of the pressure storage chamber when the piston returns Avoid gas losses leading extent.

The extinguishing chamber according to Fig. 5 differs from the first described in that it is with the Piston-controlled outlet channels opening into the pressure-free space of the extinguishing chamber are provided. The arcing chamber housing is again with 1, the fixed switching contact with its housing with 2 and the Shift pin labeled 3. The pressure storage space 9 has such a position that its gas volume above the extinguishing agent level is. The delay device of the piston 7 is indicated by 13. At On its upper side, the piston has two lugs 23, which open the openings of the two into the unpressurized Cover space 12 leading outlet channels 24. Since the approaches protrude freely into the arc space, they are acted upon on all sides by the arc gas pressure, so that they are subject to mechanical stress are not exposed.

Fig. 6 illustrates the section CD and Fig. 7 the section EF. Fig. 6 shows the course of the extinguishing agent flow. The extinguishing agent, which was initially pumped through the openings 25 into the pressure storage space, after the flow channels 10 and 11 have been exposed, flows across the arc path into the pressure-free space 12, as indicated by the arrows drawn.

Fig. 7 shows that the lugs 23 are guided in a recess of the ring 26, the same time serves as a stop for the piston 7. This guidance of the approaches causes a rotation of the piston prevented. The two ring cylinders 27 and 28 are combined into one structure by narrow webs 29. The piston is again equipped with three delay devices 13.

The gas volume of the pressure storage space (Fig. 5) and the displacement of the piston in the length the extension pieces 23 given limitation are coordinated so that in the pressure storage space a certain pressure is not exceeded or only marginally exceeded. Is the piston under the action of the arc gas pressure strives to continue the pumping stroke, the lugs 23 open the outlet channels 24, so that the gas bubble can flow out into the pressure-free space. Even with the most severe shutdowns In this way, a dangerously high pressure increase and the stroke movement of the piston are prevented automatically limited. Has already increased the volume of the arc space according to the requirements of the piston stroke results in a subcooling of the gas bubble that promotes deionization, then this becomes Effect increased by the opening of the outlet channels.

It is of course also possible to use the lugs on the underside of the piston and the outlet channels 24 to be provided accordingly below the piston. However, this would result in an extension the flow paths. The arrangement of the pressure storage chamber above the extinguishing mirror has the Advantage that gas losses cannot occur, while the flow paths are shorter in the position shown in Fig. 1.

Claims (11)

Claims 1. Arcing chamber for low-liquid electrical circuit breakers with a gas-filled pressure storage space for bringing about a flow of extinguishing agent through channels controlled by the movable switching pin, characterized in that a piston acted on on one side by the arc gas pressure exerts the pressure on the pressure storage space transmits, which is in free communication with the flow channels, and that after Opening of the flow channels through the switch pin the return movement of the piston under the Effect of a spring tensioned during the pump stroke by z. B. means based on clamping action until about the time the gas cushion is released. 2. extinguishing chamber according to claim 1, characterized in that that the return movement of the piston up to about the time of the opening of the pressure chamber is delayed by the switch pin. 3. arcing chamber according to claim 1 and 2, characterized in that the delay by a roller or spherical pressure body is brought about, which is caused by the return movement of the piston between the cylinder wall and a pressure surface at an acute angle to it a counter-pressure piece, which is carried by the piston and can be displaced against resistance, jams. 4. extinguishing chamber according to claim 3, characterized in that the counter-pressure piece is tight closing in a blind hole in the piston filled with the liquid extinguishing agent, which is expedient is designed as a disc piston, is guided, which is an outflow opening that controls the delay and / or has an outflow channel. 5. extinguishing chamber according to claim 4, characterized in that as an outflow channel a groove in the blind hole or in the counter pressure piece. 6. extinguishing chamber according to claim 4 and 5, characterized by such a design of the Ausströmkanals that after a predetermined displacement of the counter-pressure piece an expanding Outlet cross-section is released. 7. extinguishing chamber according to claim 3 to 6, characterized in that the cylinder of the pump piston has a recess which in the initial position of the piston, the return of the Allowed counter pressure piece under the action of a spring tensioned during displacement. 8. extinguishing chamber according to claim 1 or one of the subsequent claims, characterized in that that after a predetermined stroke of the piston from the pump chamber into the pressure-free space the quenching chamber releases leading outlet channels. 9. extinguishing chamber according to claim 1 or one of the subsequent claims, characterized in that that at the upper or lower piston side mounted, sliding on the cylinder wall and approaches acting as sliders control the correspondingly arranged outlet channels. 10. extinguishing chamber according to claim 1 or one of the subsequent claims, characterized in that that the ring-shaped pressure storage space lying concentrically to the contact pieces is arranged below the extinguishing agent level, preferably in the vicinity of the flow channels. 11. extinguishing chamber according to claim 1 or one of the subsequent claims, characterized by such a position of the pressure storage space that its gas volume is above the extinguishing agent level. Considered publications:
German Patent Nos. 637 074, 495 195, 505, 866 689. For this purpose 2 sheets of drawings