DE607795C - Switch capsule - Google Patents

Description

Moving devices are used in switches with contacts arranged in liquid used with harmonica-like, easily movable walls, which move under the influence of the heat of a liquid filling and which also contain liquid evaporates. Through the movements caused by the evaporating liquid circuits were also made. With such a switch, which can be used to operate regulating circuits, but is the evaporating one Liquid not suitable for extinguishing arcs. To be actuated at such a liquid by evaporating Switches to use the steam for arc quenching, the contacts must in a certain way in the liquid or at the exit point of the vapor from the Liquid space are attached and sufficiently large spaces be provided in which the vapor in the arc extinguishing flows and condenses.

According to the invention, in such a switching capsule, a liquid space is connected to a vapor space provided with movable walls and the contacts are arranged in such a way that when switching off the vapor generated in the liquid space is forced through between the contacts into the vapor space enclosed by the moving shell. The vapor pressure is used to move the accordion-like walls so that a chamber is formed above the liquid space and that the vapor through the vapor pressure between the at the point of passage, z. B. a through pipe, seated contacts is pressed through. With such an arrangement, large currents can be interrupted, since the steam with its full force in the passage opening has a quenching effect on the arc. If the passage opening is now specially shaped, as shown in the figures, and the chamber is made sufficiently large for the steam, the steam will take on high speed as it passes and will certainly extinguish it. He will do this all the more if it is not just the force of the steam that causes the movement of the accordion walls. Holding devices are used which inhibit the separating movement of the contacts until the vapor pressure inside the capsule has reached a certain level, and. the disconnection movement is then assisted by a spring, so ^r w ill the chamber into which the steam enters, quickly increased, and the inflowing higher pressure steam is then accept high speed. To a certain extent, you can put this spring force in the capsule walls themselves by making the wave-shaped or harmonica-like walls of the capsule resilient and bending them in the switched-on position so that they bend in one

are in an unstable state of equilibrium, which is overcome by the internal pressure and then makes the resilient force active. The force generated by the evaporating liquid can also be supported electromagnetically or both effects or all three forces can be made effective together.
Another force that could be used is the

ίο bring the power of bimetal, if one the capsule or parts of the same made of bimetal, which when heated also in the Sense of steam acts, z. B. bimetal strips or the like. As resistors. Since the bimetal effect is not suddenly, but comes more gradually, one will then make the arrangement expediently so that the initially occurring bimetal force does not lead to movement, but rather to movement is only initiated when the bimetallic force and steam force work together. Do you want To achieve special powerful effects, then one could use bimetal, steam, electromagnetic and let spring force work together. When different forces are supposed to work together or when you first get the Steam wants to bring it to a higher pressure before the movement is initiated, so you can attach locks that are only overcome with a certain pressure. That could be done by the outside or inside snap springs o. The like. Are attached below a certain Hold the pressure and only release the movement when this pressure is exceeded. the Moving wall in the capsule can also be piston-like in a capsule with solid walls be performed so that a seal is already given by the piston guide. It can also the steam generated inside the capsule for actuating another switching device to serve.

The interruption inside the capsule could also be caused by the special arc easily extinguishing steam, e.g. B. carbon tetrachloride o. The like., So that also relatively high voltages can be interrupted with switch capsules that are not too large can. In addition to steam, an electromagnetic one can act on the interruption point inside Blow field work.

Depending on the evaporation point, d. H. the liquid to be evaporated, selects, one can initiate the movement at different levels of current heat and thus current strengths. So you could z. B., if you include alcohol in such a capsule, the evaporation even at low temperatures and thus achieve the switching movement quickly.

The capsule itself can be particularly thermally insulated so that it can be externally Temperatures is independent. With the appropriate content of the capsule (amount of liquid, Type of liquid), due to the arrangement of the heating devices and the like, the capsule can have a certain heat capacity are given so that they are also the objects to be protected (line protection, motor protection and the like) can be adapted. Such capsules can optionally be used also in certain places, e.g. B. in engines o. The like., Install, so that they are even higher Dimensions depend on the temperature of the object to be protected.

Radiators (resistors) can be used to cause evaporation that are surrounded by only a little liquid, so that the evaporation is rapid he follows. Bimetal strips can also serve as resistance. The resistors can also be used instead of by direct current indirectly heated by a current induced inside the capsule. Instead of the Evaporation through resistances can also be caused by direct current transfer occur through the liquid, preventing direct contact with the contacts or walls by spacers will.

The switching capsule can serve to not only supply the current inside the capsule interrupt, but also to separate contacts attached outside the capsule as they move. The Arrange so that the first interruption takes place inside the capsule and the moving force of the switch capsule is still used to switch another switch (Main switch or voltage switch) so that even after the Reignition is impossible.

Some embodiments are shown in the figures. In Fig. 1 is a Arrangement shown in which in the i ° 5 Capsule 5 a contact 3 is seated, the current through resistors 4 to the contact point transfers against which the contact pin 1 lies. The contact pin 1 is in connection with the outer contact 2. no An insulating piece 9 separates the point of contact of the contacts of the foot of the contact 3 sitting in the capsule. The capsule consists made of insulating material, e.g. B. ceramic insulating material. On the capsule 5 there is a "5 Harmonica-like sleeve 6, which carries the contact 2 on an insulating plate. Between the Sheath 6 and the capsule 5 is the passage opening 8 through which the Contact pin 1 is passed through, in such a way that a narrow annular space between Pin ι and the capsule 5 remains. The capsule S

is filled with liquid /. The harmonica walls are in the switched-on position shown compressed so that the contact ι is firmly against the contact 3. If a current of lesser strength now flows through the arrangement, the current transition occurs take place from the contact 2 through the contact pin ι on the contact head piece 3 and via the resistors 4 after the foot contact 3 in the capsule. Here is ever according to the choice of resistors 4, the liquid can be heated but not evaporated. Te after the pressure with which the contact pin 1 is held on the contact piece 3.

the switch capsule can remain switched on. Does the pressure outweigh the Steam, the steam will flow up through the ring opening 8 and the Move contact pin 1 upwards. The steam also expands under the action of the between r and 3 resulting arc in the space of the envelope 6. the harmonica is here moves more and more upwards and so the expansion space increases, so that the steam at high speed in the expanding expansion space of the shell 6 can occur. Here flows through the steam the space in which the arc burns between 1 and_3 and extinguishes the arc. After the switching process has ended, the steam will condense in space 6 and the liquid return through the opening 8 back down into the switching capsule. By a corresponding slope ail the upper edges of the switch capsule 5 on the This backflow can be achieved with ease in the vicinity of the opening 8. Intended to If the switch capsule is switched on again, the pressure on the upper part the sleeve 6, e.g. on contact 2. the sleeve compressed until between 1 and 3 Contact is established. Switching on can be done with a trip-free so that at If the current is too high, it is switched off again directly without the contacts are recorded.

In the arrangement according to Fig. 2, the contact piece ι makes contact on a pin slidable so that bet the evaporation of the liquid in the insulating capsule 5, the first interruption has already occurred can, in that the steam acts against the movable contact piece 1, only then after the first sudden sub-

break, the harmonica cover 6 expands and the contact 2 with the contact piece 1 together upwards even further than when the contact 3 was first separated. Here the steam enters the Audi, quenching it

Space between τ and 3, while the light is formed. and deletes iiiesi-n.

The arrangement of the movable contact 1 and the mating contact 3 can be different Way.

In Fig. 3 it is also shown how, for. B. the contact 3. at which the interruption takes place, the movable contact piece 1 surrounds ring-shaped and so the blowing effect on the Interruption point becomes even cheaper. The suspension of the harmonica cover 6, which is shown in the Fig 3 is not drawn, can be set as desired.

A similar arrangement is shown in Fig. 4, but here the capsule wall is 5 expanded upward like a nozzle in an insulating sleeve 11, so that after the interruption of the Steam held together, guided, and with the greatest force and pressure between the contacts are driven to delete.

Fig. 5 shows an arrangement in which the contact piece 1, which is conically shaped is, against a contact ring 3 on a resilient sheath ir lays. The resilient one Covers, which can be made resilient as desired through spring slots 10, hold that Contact piece 1 firmly in the switched-on position. It can then besides the spring force the harmonica cover 6 still has a special spring 12 attached, which is in the on position 1 presses against 3 and, afterwards, by evaporation of the liquid the Contact 1 is torn out upwards, supports the effect of the steam and the Contact r moved up even faster. The balancing of the pressures and spring forces can be easily achieved here, in that the spring force of the shell 11 is only overcome when the steam pressure is increased and the contact is separated. The quenching steam enters here, led through the »o Contact ring 3, between 3 and 1 through, here extinguishing the arc and into the Expansion space, which is formed by the harmonica cover 6, entering. Here must of course, the condensed steam is fed back through openings in the switching capsule 5 will.

In Fig. 6, the contact pieces 1 are held against a spring force 12 and 3 against each other by overlapping n ° pieces 13, which are on the edge of the pipe section ir, in which the liquid and the contacts are located. These pieces 13 ensure the necessary contact pressure and ensure that the contact is only separated can after the vapor pressure has reached a certain level. With this arrangement it is also shown how the liquid 7 goes beyond the contact point 1/3 and so with the separation of 1 and 3 still additional liquid due to the arc is evaporated, so dall also hk-rdinvh

Claims (24)

the separation and deletion is accelerated. At the same time, the steam then extinguishes the arc "between ι un ^ l 3. In Fig. 7 is a similar design as shown in Fig. 6. Just surrounds here again the contact piece 3 the contact 1, so that the steam here between an annular cross-section between the contacts 1 and 3 passes through during deletion. The retainers 13 are in openings in the contact ring 3 held. If steam forms, it acts both against the cover piece of the harmonica cover 6 and against the retaining pieces 13. The vapor pressure can rise quite high due to these holdings before it releases the contact 1 of 3 and drifts upwards. Before it is triggered, it acts both on the closure of the cover6 (support piece for contact 2 and 1) as well as against the restraints 13. The vapors entering the expansion space 6 are there condenses and can then as a liquid through the openings in which the retaining devices 13 have sat, flow back to the insulating capsule 5. The flowing back but can also be done through deeper openings of the shell 5, the next the contact ring 3 sit. In Fig. 8, the lock is in place in the sense of the 3 »holding piece 13 directly against contact 1. which is pressed against the ring contact 3 by a spring. If there is overpressure, that too the end of the lever 13 acts, it is moved outward. This will make that Retainer 18 moved away from contact 1, and the deactivation is initiated. For example, steam penetrating outside through the opening collects and condenses in the adjacent space of the switching capsule and can then be used as a liquid flow back into the switch capsule. Instead of the restraints, as shown in Fig. 7, special ones could also be carried out Openings may be provided for the backflow of the liquid and the triggering of the Holdings 13 take place in the manner shown in Figs. 9 to 13. So takes hold z. B. in Fig. 9 the holding piece 13 with a protruding nose 16 in an opening, do completed with movable walls is. A plate 15 sits on these movable walls. If the pressure rises above a certain level Measure, he presses against the plate 15 and moves it so that the holding piece 13 is triggered and the switch-off can take place. In Fig. 10 is the abutment of the holding piece 13 appropriate for itself. A plate 15 presses against a feeler lever 17 on the holding piece 13 and releases the latch at ιό. In Fig. 11 the pressure is acting on you Piston 18 and loosens the holder with a pin. but a movable wall 15 (membrane "), which increases when the pressure increases is bent outwards and triggers. In Fig. 13 there is a piston 26 made of insulating material at the end of the contact 2. Against the Contact 2, with springs 13, place contacts 3 in recesses in contact 2. If the pressure increases against the upper shell on which the contact 2 is seated, so that the If springs can no longer hold, contact 2 is thrown upwards and it takes place the interruption. In order to be able to regulate the pressure from outside, contact 2 a screw with a ring attached through which the bends on the contact 1. into which the contacts 3 engage, can be changed. The sheath 25 is piston-like in the Capsule shell 5 guided so that no liquid or vapor against the urinary ionic tube 6 can kick. The expansion space is switched by the fact that the shell 25 with the harmonica tube 6 moves upwards and so space for the upwards moving Steam creates. In Fig. 14 an arrangement is drawn in which an electromagnetic blow is exerted by a coil 36 on the interruption point for arc extinction. When contact 1 tk: n leaves contact 3, the coil blows at the point of interruption and thereby also contributes to the quick and safe extinguishing of the arc. Parts of the sheath 5 can be made of iron in order to increase the blowing effect. With this arrangement, the steam again passes through an annular cross section through the opening between contacts 3 and 1, so that the greatest extinguishing effect is achieved. In Fig. 15, the contact 3, separated by the insulating piece 27, sits on a piece of iron 28, which is generated by the coil 36 at a certain current strength against the spring force 12 is torn down while the steam reaches the point of interruption between the Contacts 1 and 3 flows. The point of interruption becomes electromagnetic at the same time blow. The liquid 7 flowing through the resistors 4. to evaporate is brought, is located in the cavity of the movable iron piece 28. Patent examination cn ε: i. Switching capsule with easily movable walls and with liquid, in which the Kontakttreninuig as a function of λόιι the temperature of the liquid the resulting movement of the movable capsule walls takes place, characterized in that a liquid space is connected to a vapor space provided with movable walls is and that the contacts are arranged such that when switching off the steam causing the switch-off process so between the contacts in the under the to the action of the steam expanding steam space is driven that he causes the switching arc that occurs between the contacts to be extinguished. 2. Switching capsule according to claim 1, characterized in that the moving Contact through the partition wall separating the liquid space from the vapor space separates, through and into the hard so monika-like cover (6) is moved into it (Fig. I. 2 and 12). 3. Switching capsule according to claim 2, characterized in that the moving Contact is passed through the partition in such a way that it corresponds to the liquid space generated steam the outlet after the harmonica cover during the switching movement · suddenly releases. 4. switch capsule according to claim 1, da-] o characterized in that the contacts (i, 3) at the narrowest point of a nozzle-shaped, arranged after the harmonica-like shell to be widened opening (11) are (Fig. 4). is 5. switch capsule according to claim 4, characterized in that the fixed con tact ^{= is} conical. 6. Switching capsule according to claim 1, characterized in that the fixed contact (3) the movable contact (1) surrounds it in a ring and the steam passes through it flows through the ring-shaped fixed contact (Fig. 3). 7. Switching capsule according to claim 1, characterized in that the separation of the contacts takes place in the liquid and the moving contact (1) when switching off is moved out of the liquid (Fig. 6). 8. Switching capsule according to claim 1, characterized in that -the movable wall (25) with a concertina-like folded seal (Ci) is sealed to the outside (Fig. 13). 9. Switching capsule according to claim 1, characterized in that the switching capsule is designed as a closed chamber (5) with fixed dignities and that a piston (28) which slides within the closed chamber (AbI) serves as a movable wall. 15). 10. switch capsule according to claim 1 to 9, characterized in that an electromagnetic blown field also acts on the interruption point inside. 11. switch capsule according to claim 1 to 10, characterized in that the windings for heating inside the capsule provided resistors are used. 12. Switching capsule according to claim 1 to 11, characterized in that a retaining device inhibits the separating movement of the contacts until the vapor pressure has reached a certain level inside the capsule. 13. Switching capsule according to claim 1 to 12, characterized by the arrangement of a spring, which the switch-off movement with causes great rapidity. 14. Switching capsule according to claim 13, characterized characterized in that the spring is triggered by the vapor pressure within the capsule. 15. Switching capsule according to claim 1 to 14, characterized by electromagnetic • support for the switch-off movement. ιό. Switching capsule according to Claim 15, characterized characterized in that the capsule is arranged and designed in such a way. dal.! they are the core of an electromagnet forms. 17. Switching capsule according to claim 1 to 10, characterized in that the capsule walls order wholly or partially made of bimetal, such that they are heated when heated support the switch-off movement, 18. Switching capsule according to claim 17, characterized characterized in that the resistances to evaporate the liquid are formed from bimetallic strips and arranged such that they are the switch-off movement support. 19. Switching capsule according to claim 1 bis.iS, characterized in that the Ausaltbcwegung by the force of Vapor pressure, the bimetal, by spring force and magnetic force in any Combination is effected. 20. Switching capsule according to claim 1 to 19, characterized in that the movement force of the switch capsule serves to after the interruption in the interior of the switch capsule another switch, in particular a main or voltage switch to trigger. 21. Switching capsule according to claim 1 to 20, characterized in that the steam generated inside the capsule is also used to actuate another switching device. 22. Switching capsule according to claim ι to 21, characterized in that the capsule is used as a power switch. 23. Switching capsule according to claim 1 to 22, characterized by the use of liquids, especially carbon tetrachloride, which make the arc easily form extinguishing steam. 24. Switching capsule with the features of claim 1 to 23, but for one evaporating mass in place of the liquid. For this purpose ι sheet of drawings