DE750668C - Compressed gas switch - Google Patents

Description

Pressurized gas switch There are switches with a glazing of the arc a pressure medium! known, which cause the compression of the pressure medium itself. This is done either through the utilization or heat generated by the interruption arc or from an auxiliary arc ignited in series with the main arc , or by means of a pneumatic cylinder, which is driven by the engaging movement of the interruption device is moved under tension.

The invention aims to increase the interruption capacity wire-like switch. Its object is a switch, which when it is switched on a certain amount of mechanical energy to generate compressed air that .on the Interrupting arc directed for the purpose of blowing. is stored and the Energy of the current flowing through it. from a certain one, in the interruption arc flowing current to generate another used for blowing Amount of energy used. According to the invention, such a switch is in the manner designed that this second energy source is formed by air from a in the vicinity of the main interruption point, but in a separate location Space located auxiliary interrupting light under pressure occupied and just like the compressed air generated by the mechanical energy stored by the switch directed at the main arc.

Although it is known a switch that controls the blowing by means of a generated by a spring moved piston itself, with an auxiliary device for To provide generation of compressed air, (which acts on the piston and which in a takes advantage of the heat developed by the resistance flowing through the interruption current. This known device is less intended to increase the interruption capacity of the seer than rather a reduction in size of the compression spring to enable work to be done. However, it does not allow the Dimensions of the cylinder and the piston to reduce and also has numerous Disadvantage. In particular, the piston has an unfavorable effect: the efficiency of the Blowing out because of the friction losses caused by it and on the speed of action the blow because of the time required for the piston mass to accelerate. If you were to replace the heating resistor with an auxiliary arc, the The deficiencies outlined are still increased, since large mechanical forces are present at high pressures would act on the piston and the parts connected to it.

The design created by the invention avoids these disadvantages due to the independence of the two energy sources and the elimination of the blow piston, on which the energy of the auxiliary arc acts. It also has the advantage that it makes it possible to shift the action of the two energy sources to to achieve the highest level of efficiency, and also to increase the blowing pressure more quickly and finally the dimensions of the cylinder and its To reduce the size of the piston to a large extent. It is known per se in switch construction that the Energy of an auxiliary arc solely for generating pressure for the main arc extinguishing other pressurized fluid flow; however, this is not the case therefore, an existing extinguishing agent flow through the one caused by an auxiliary arc Increase flow.

The use of auxiliary blowing by means of an auxiliary arc is at Liquid switches and compressed air switches with flow chambers are known. The effect This auxiliary blowout is, however, in the known switches due to their different Beard style far less beneficial. With these switches the blowing agent contaminated by the auxiliary blowing, which is just avoided by the invention.

On the drawing are several execution: example @ e an arrangement shown according to the invention.

Fig. R shows a side view, partially in section, a switch with an air compressor P of known type, the piston of which is under the pressure of a front tensioned the engagement of the switch by means of a transmission, not shown Spring R stands. This spring R causes the switch to disengage and delivers the energy for blowing the arc. The fixed contact of the switch is with cl and the movable contact with c. It is from these contacts that arise the main arc, which is labeled A. The switch is also with auxiliary contacts ci and c. which, when the current to be interrupted exceeds a certain Value, an auxiliary arc, which is marked with .1., And which is marked with the main arc is in series. The contacts ci and c. ' are controlled so that the auxiliary arc, if necessary, before the Main arc arises or occurs at the same time as this. According to the invention the pilot arc is used to generate bubble energy. To this end the contacts ci and c @ 'are housed in a chamber E, which is expediently of the chamber containing the fixed main contact cl is separated. The one from the pilot arc generated gases - as well as the air of chamber E, which by the heat of the arc Bred to a high pressure will be on the main arc drives, either immediately or after they have come into contact with a flame protection device b ', that cools them down. They evoke a blister of a strength, that of strength of the current to be interrupted is proportional.

This bubble is in the embodiment in question by that Bladder coming out of the P cylinder is added. For this purpose, the compressed air flows, generated by the auxiliary arc and the pressure cylinder, in parallel Paths directed towards the main arc. In the illustrated exemplary embodiment are (reads streams concentrically.

The two compressed air flows act simultaneously and therefore add up their blowing effect. If the arcs A and A are extinguished, the one from the acts. Cylinder P coming blowing continues alone, blowing through the space that is the main contacts separates from each other and thus prevents the possibility of re-ignition.

The concentric arrangement of the two compressed air flows can also be achieved thereby be achieved that one uses a hollow, solid main contact, the interior of which with the cylinder P is in connection, as Fig. a shows, or with that Space in which the auxiliary arc occurs, as shown in FIG. 3. In this embodiment is the apparatus through the line S, with the cylinder P and through the line S, connected to your space of the auxiliary arc, and the main contact is to one Spark pulling contact is provided, which protrudes into the air flow coming from the line S. and whose cross-section is smaller: ils that of the opening of the insulating mouthpiece. Man can also have a certain simultaneity of the effects of the two compressed air flows can be achieved by moving them in the opposite direction. on the arc can act, as shown in FIG. 4, in such a way that the two traps of the main arc be deionized. In this case too, the auxiliary arc is created in the chamber E only if the current to be interrupted exceeds a predetermined value. The gases generated by the auxiliary arc are on .die trap of the Main arc directed, which is located in chamber E, during the off The compressed air flow coming from the cylinder P to the other trapping point of the arc is directed.

The bubble energies generated from the auxiliary arc and from the cylinder P can be delivered one after the other. In this case begins the blowing from the auxiliary arc, which is always the predominant one, and works for the time being alone. The blowing caused by the cylinder P then takes effect and complements the first; it sweeps through the space that separates and surrounds the contacts, completes the breaking of the arc and thus avoids any subsequent re-ignition.

In Figs. 5 to 1a Aus: guide examples for .der such Implementation of the subject matter of the invention shown.

The arrangement shown in Fig. 5 is similar to that of Fig. i. The pilot arc develops only when the strength of the interrupted Current goes beyond a predetermined value. The current then sets the relays de :, switch, which contacts causing the formation of the Hilds arc control, by a transmission in action, which corresponds to that shown in Fig. .r. The blow out from the cylinder P comes to that from the auxiliary arc Blowing added, but with a certain time lag, as explained above.

Two variants of this embodiment are in .den Fig. 6 and. 7 shown. In the first case, according to FIG. 6, the blow resulting from the auxiliary arc is in a chimney E generated. The compressed air and the compressed gases escape through a pipe T, which carries the fixed main contact cl. This tube is provided with an opening or the like provided through which the air flow originating from the cylinder P enters. The two Blow currents are directed parallel to the main arc, which is at the end of the tube 7 'developed.

In the embodiment shown in Fig. 7: occurs through d he auxiliary interruption point in the chamber E generated air and gas flow through a Opening o1 in the contact-bearing tube T1, while the one coming from the cylinder P1 Compressed air flows into the pipe through a second opening o2.

In both of the embodiments just explained, the one with the cylinder P associated inlet opening of the raw rice .with -a non-return valve provided which the outflow of coming from the auxiliary interruption chamber Prevents air and gas masses from entering the cylinder.

Fig. 8 shows an embodiment for the application of such Arrangement in a device according to FIG. 5. The valve k remains closed. As long as the pressure prevailing in the chamber of the auxiliary arc is high and prevents thereby the flow of the generated gases into the pressure cylinder <°. As soon as the pressure in chamber E is lower than the pressure generated in the pressure cylinder, Ida's valve k opens, and the bubble coming from the cylinder P joins it to that resulting from the auxiliary arc.

The air and gas masses resulting from the auxiliary interruption can also be prevented from pushing back the compressor piston by blocking the calving at the moment when the auxiliary interruption takes place. Such an embodiment is shown in Fig. G. The locking of the piston in cylinder P2 is effected by a cam disc Ca , the position of which is made dependent on the position of the auxiliary contacts of the switch.

You can also use a combination of divisions to create the sequence (-) of the simultaneity of the one hand from the chamber. of the auxiliary arc and on the other hand to cause blow currents originating from the compressor cylinder. Such an embodiment is shown in Fig. 10.

Here the chamber of the auxiliary lightb:) gene is designed in a ring shape and is connected to the valve k1 on the piston of the air compressor Cylinder U in connection, which in turn has the fixed main contact at its end supporting pipe T2 is in communication. If the auxiliary arc A2 ignites, so if the pressure in the ring-shaped chamber increases, valve k1 opens and allows the gases to escape through the pipe T2 leading to the main break point leads and causes the blister there. Because when small currents are interrupted, pressure is generated does not occur in the annular chamber, the displacement of the piston calls in a pressure reduction in this chamber. So that this harmful effect is avoided will, a second valve k2 is arranged on the rear wall of the cylinder, the the back of the The piston in contact with the open air, if the pressure in the annular chamber is not high enough to open the valve hl.

In the apparatus shown in Fig.5 and c), concentric Outlet channels are used for the blow streams, as shown in FIG is. The air nozzle consists of two concentric mouthpieces b1 and b2, whose first-mentioned b1 slides along the pipe section t1 carrying it, as long as the pressure generated by the pilot arc is higher than that of the self-blowing system generated pressure; the mouthpiece b1 recedes during self-blowing alone and exposes the end of the spark drawing contact, which is then in the most favorable position opposite the nozzle throat.

You can use all of the switches described above in a known manner place a resistor that serves to speed up the recovery to delay the tension; this resistance is either mechanical or by Air pressure switched on, expediently in connection with the auxiliary arc and, if necessary, to the main arc. Such an arrangement is shown in FIG. As long as the strength of the short-circuit current to be interrupted is low, complete the interruption without the involvement of a resistor under the sole use of the Blowing out of the cylinder P. If this current strength becomes significant, the auxiliary arc is generated a blower and switches on the resistor r. The current, .den the main contacts now have to interrupt, is only a diminished by this resistance Current.

You can also use the!, Last-described type of switches Resistance is switched on in a known manner by a mechanical or air pressure Replace capacitance, which is expedient in the hub connection to the auxiliary arc and if necessary to the main arc.

The compressed air flow generated by the compressor cylinder can not only at the same time as that from the auxiliary arc chamber Electricity act. but only after the breakaway arc has been extinguished. He cleans then in a very effective manner the environment of the switch contacts and thereby prevents every reignition of the arc. This process takes place with most of them of the devices described above by themselves, if one of the main and auxiliary contacts a suitably regulated displacement speed granted and the self-blowing Sv_ stone matching dianensionier t. The devices described have the advantage the breaking capacity of the usual switches that are used to blow the breakaway arcs self-pressurizing required air to increase .the strength of the blow to be related to the strength of the current to be interrupted and just as well to interrupt the weak as well as the strong arcs.

Claims (1)

PATENT CLAIMS: i. Electrical switch, in which, during the switch-on process, mechanical energy for generating compressed air, which is directed onto the interruption arc for the purpose of blowing, is stored and the energy of the current flowing through the arc is used from a certain current strength to generate a further amount of energy used for blowing, characterized in that this second energy source is formed by air which is pressurized by an auxiliary interrupting arc located in the vicinity of the main interruption point, but in a space separate from it, and likewise the compressed air produced by the mechanical energy accumulated by the switch directed at the main arc. a. Switch according to claim i, in which the two bubble energies do not take effect at the same time, characterized in that the energy produced by the auxiliary arc first comes into effect and produces a predominant blow, while the blow produced by the mechanical energy source only takes place a while after the first blow begins to take action. 3. Switch according to claim i, in which the two amounts of energy contribute simultaneously to the generation of the blow and the amount of mechanical energy that is stored in the switch during its engagement is generated with the aid of a cylinder whose calving is influenced by a spring which is controlled by the Closing movement of the switch is tensioned, characterized in that the two compressed air flows are guided in parallel and rectified paths against the main arc. a. Switch according to Claim 3, characterized in that the two supply channels for the compressed air flows are concentric to one another. 5. Switch according to claim q., Characterized in that?) The two pressure air streams are directed through two concentric nozzles on the arc. 6. Switch according to claim 4, characterized in that the one compressed air flow through the hollow Kox1-ta1 #: t passes and or another through a nozzle surrounding this hollow contact. 7. Switch 'according to claim 3, characterized in that the supply of the two compressed air streams takes place in opposite directions to the arc. B. Switch according to claim 7 with a hollow, fixed contact, which lies outside and opposite a blow nozzle, in the interior of which ider.mobile contact withdraws, characterized in that -the one compressed air stream from the nozzle and the other from the cavity of the fixed Contact emerges. G. Switch according to Claim 2, in which the mechanical energy stored upon switch-on is generated by means of a cylinder, the piston of which is provided with a spring, this spring being pinned by the switch-on movement of the switch, characterized in that the two compressed air flows into one and the same Lead into the line that directs it to the breakaway arc. ok Counter. according to claim 9 with a blowing nozzle, characterized in that the two compressed air streams flow into the nozzle. i i. Switch according to Claim 9 with a hollow, fixed contact, characterized in that the two compressed air flows flow into the cavity of the fixed contact. 12. Switch according to claim 9 to ii, characterized in that the connection: the spaces in which the two blowing streams are pressurized is prevented by a shut-off device, as long as -the pressure of the air pressurized by the piston action is less than that Pressure of the air pressurized by the auxiliary arc. 13. Switch according to claim 9 to 12, characterized in that the pressure cylinder for the blown air is designed so that the air pressurized by it flows between the contacts and around them even after the arc has been extinguished. To distinguish the subject of the application from the state of the art, the following publications were taken into account in the granting procedure: German patents .... No. 561 329, 368 348, 6or 563, 6o3 239, 661 9i2; Swiss Patent No. 155 896; French patents. . - 723 167, 749 949; USA.-patent document. . . . . - 730704-