EP0438793A2 - Switch device - Google Patents

Abstract

(Electrical) switch devices are known, having a base part 2 on whose one side there is arranged a switching element having at least one moving switching element part (moving contact 7) and on whose other side there is arranged a thermal trip device, whose trip movement can be transmitted by means of a transmission pin 10, guided in the base part 2, to the moving switching element part. <??>In order to create a reproducible switching behaviour, in this case the length of the longitudinally displaceable transmission pin 10 must be matched to the characteristics of the switch device (tolerances of the base part consisting of insulating material, characteristics and design of the tripping elements, for example spring plates and the like). <??>In order to overcome such tolerance problems, to reduce the assembly cost and to increase the assembly cycle rates, in the case of the new switch device, the transmission pin 10 consists of two parts 11, 12 and is in this way constructed such that its length is variable, in that the one part 11 can be pressed into the other part 12 by exerting axial pressure. Such transmission pins can be preinstalled with an excess length and inserted into premounted switch bases, a mutually opposingly directed pressure being exerted on the elements which act on the pin ends in order deliberately to shorten the transmission pin. <IMAGE>

Description

The invention relates to a switching device, in particular an electrical switching device, with the features of the preamble of claim 1.

From German patent 28 26 205, for example, a thermal fuse for electrical devices with a base part made of insulating material emerges, on one side of which a fixed contact and a movement contact attached to the free end of a contact spring are arranged, and on the other side a thermal release is provided, the release movement of which can be transferred to the contact spring by means of a transmission pin guided in the base part. The thermal trigger is, for example, a fuse insert in the case of temperature protection, the triggering movement of which is that the surface of the initially rigid fuse material insert lowers when the superheating temperature is exceeded and thus when the melt material is liquefied, as a result of which the illustrated transfer pin dodges under the pressure of the contact spring can. As a result, the release movement of the melt material insert is transferred to the contact spring.

In addition, transmission pins of this type are also used in electrical switching devices with other thermal triggers, for example in switching devices, that are switched via bimetallic spring washers, capillary tube pressure sockets or other activators. The prerequisite for the invention is that a transmission pin is provided in a base of some kind, which transmits a movement of a triggering device to a switching element.

With such switching devices, there is now a need to adapt the length of the longitudinally displaceable transmission pin as exactly as possible to the conditions of the switching device, in particular to the tolerances of the base part made of insulating material, for example ceramic, as well as to the conditions and the design of the triggering elements, for example, to create reproducible switching conditions Spring washers and the like.In addition, when assembling such a switch there are additional tolerances which have to be taken into account by deliberately and individually cutting the transmission pin to length, otherwise it may happen that the contact conditions do not comply with the regulations, for example contact pressures are too high or too low or For example, the opening path of a switch is not sufficient.

In the prior art, the procedure is generally that a number of transmission pins of different lengths are available, the conditions within the preassembled switch are measured using a gauge during the assembly process, and then a pin of suitable length is added. This necessitates having a large number of sorted pins of different lengths available, which are then separated out during the assembly process and inserted into the preassembled switch Need to become. The stocking or selection of such pens of different lengths is complicated and expensive.

In addition to this described way, attempts have also been made to press housing parts such as holding plates and the like in order to create defined switching conditions in the sense of a positive or negative “change in length”. However, such effects on the housing are difficult to verify and difficult to reproduce.

Furthermore, attempts have already been made to vary the distance between the movement contact end and the fixed contact. By pressing the fixed contact more or less against the movable contact clamped away from it, a certain tolerance compensation can also be achieved, however the deliberate bending of contact springs has a negative effect on the suspension properties.

Finally, there are already so-called length-adjustable pins made of glass in the prior art, the length of which can be adapted to the housing conditions by heating and axial compression pressure.

Furthermore, it is also known to grind pins on their longitudinal ends during the machining process in order to achieve an exact adaptation of the pin length to the conditions of the base or the further switch components.

All of these methods are disadvantageous in that they are labor intensive or require a high level of warehousing require and in particular do not allow high cycle times during the assembly process.

The invention has for its object to develop a switching device, in particular an electrical switching device with the features of the preamble of claim 1 such that the assembly effort is reduced and in particular the assembly cycle times can be increased.

This object is achieved in that the transmission pin consists of two parts and is designed to be variable in length in that one part can be pressed into the other part by the application of axial pressure. With such transmission pins made of two parts, it is possible to pre-assemble the transmission pins with excess length, to insert them into the likewise preassembled switch bases and then to exert a counter-pressure on the elements acting on the longitudinal ends of the pin, such as a bimetallic snap disk on the one hand and the contact spring on the other leads to a targeted shortening of the transmission pin without complicated measures having to be taken. The pressure can be exerted, for example, when applying heat transfer plates, holding elements or the like, so that the additional effort for reducing the length is minimized, as it were.

Advantageous developments of the invention result from the subclaims. For example, the two parts of the transmission pin can be arranged telescopically one inside the other. For example, "telescope-like" to understand that the first part is a pin and the second part is a sleeve part or a quasi-sleeve part. Advantageously, one part will be an insulating pin and the other part will be a metallic sleeve which encompasses one end of the insulating pin. This selection of materials ensures, on the one hand, electrical and thermal insulation, and on the other hand, the metallic sleeve ensures that, despite a relatively tight fit of the sleeve around the end of the insulating pin, a telescopic displacement of the two parts into one another takes place without the risk of destroying one of the parts can.

Under certain circumstances, it is advantageous to form the metallic sleeve directly by means of a soldering iron insert. But it is also possible to embed a separate sleeve in a soldering iron insert, so that the displacement between the pin and the sleeve takes place and only when the melting soldering insert, ie. H. if the fuse temperature value is exceeded, the sleeve and the pin continue to sink into the fusible link insert when the fusible link is displaced and the securing function is thus fulfilled.

In order to avoid that the fusible link insert is damaged or at least squashed when the pin-fusible link combination is shortened, a cavity is provided in the axial extension area of the pin, the diameter of which is slightly smaller than the diameter of the pin.

If the end of the pin arranged in the sleeve is conical, spherical or rounded, then it is ensures that the pin can be pressed into the sleeve without damage and that there is a uniform radial deformation of the sleeve material.

The sleeve can be pot-shaped or can be provided with a taper in the direction of the end of the sleeve facing away from the pin. Overall, it is important that the sleeve is made of deformable material, since the pin can then be made sufficiently rigid. Alternatively, however, the sleeve can be made of non-deformable but elastic material and can be provided, for example, with a spring recess in the form of a suspension slot, so that the slotted sleeve resiliently encompasses the end of the pin.

In order to ensure a relatively firm hold between the pin and the sleeve in the long term, the inner surface of the sleeve can be provided with projections or a toothing or the like. Alternatively, it is of course possible to provide the outer surface of the pin with appropriate elements.

If the end of the sleeve facing away from the pin is provided with a radial projection, then the sleeve for inserting the pin-sleeve combination can be better gripped by an automatic machine, which considerably simplifies the handling of the transmission pin.

For the preassembly of the insulating pin and sleeve, it may be advantageous to expand the leading end of the sleeve facing the insulating pin in a trumpet-like manner.

If the pin is arranged in a first bore of the base part and the sleeve is arranged in a second bore aligned with the first bore, the diameter of which is somewhat expanded compared to the first bore, then it is ensured that the transmission pin as a whole is securely guided axially in the base part.

Claim 19 relates to a method for producing a switching device, with the features of the preamble of claim 19. The manufacturing method steps a) - f) according to the invention substantially simplify the assembly of such a switch.

Fig. 1

einen Mittelängsschnitt durch eine elektrische Schalteinrichtung mit längenveränderbarem Übertragungsstift und Schmelzloteinsatz;

Fig. 2

ein gegenüber Fig. 1 abgewandeltes Ausführungsbeispiel einer Schalteinrichtung;

Fig. 3

eine Detailansicht eines Übertragungsstiftes in vormontiertem Zustand;

Fig. 4

eine Detailansicht eines Übertragungsstiftes in abgelängtem Zustand;

Fig. 5

ein weiteres Ausführungsbeispiel eines Übertragungsstiftes und

Fig. 6

ein weiteres, gegenüber Fig. 5 abgewandeltes Ausführungsbeispiel.

The invention is explained in more detail using exemplary embodiments in the drawing figures. These show:

Fig. 1

a central longitudinal section through an electrical switching device with variable-length transmission pin and fusible link insert;

Fig. 2

an embodiment of a switching device modified compared to FIG. 1;

Fig. 3

a detailed view of a transmission pin in the preassembled state;

Fig. 4

a detailed view of a transmission pin in the cut state;

Fig. 5

another embodiment of a transmission pin and

Fig. 6

a further, modified from FIG. 5 embodiment.

1, the switching device 1 according to the invention consists of a base part, i. H. an insulating base 2, on one side 3 of which a fixed contact 4 and a moving contact 7 fastened to the free end 5 of a contact spring 6 are arranged, and on the other side 8 of which a thermal release in the form of a fusible link insert 9 is arranged, the triggering movement of which is carried out by means of a base 2 in the insulating base Transfer pin 10 is transferable to the contact spring 6.

The transmission pin 10 consists of the parts 11 and 9 and is designed to be variable in length in that the part 11 can be pressed into the fusible link insert forming a sleeve by exerting axial pressure in the direction of the arrows 13.

FIG. 2 shows a further exemplary embodiment of an electrical switching device with a length-adjustable transmission pin 10, this switching device essentially having the same components as the exemplary embodiment according to FIG. Fig. 1, but now instead of a fusible link insert 9 (as in Fig. 1) a bimetallic spring washer 20 is provided, which is arranged below the part 12 of the transmission pin 10 and cooperates with this part 12.

As can now be seen better in the drawing figures 3 and 4, the two parts 11 and 12 of the transmission pin 10 arranged telescopically one inside the other, part 11 is an insulating pin, part 12 is a metallic sleeve which engages around the lower end 14 of the insulating pin (part 11).

The length of the sleeve formed by the part 12 is about 20 to 50% of the insulating pin length, the inner diameter of the sleeve 12 relative to the diameter of the insulating pin 11 is dimensioned such that it can only be pressed into the sleeve 12 when the sleeve material is radially deformed. The end 14 of the insulating pin is conical, spherical or rounded and thus has sliding inclined surfaces which can press the sleeve material apart somewhat when pressure is applied to the transfer pin 10 in the direction of the arrow 13.

The sleeve 12 can be made of deformable material, it will then expand and deform somewhat radially when the insulating material pin 11 is pressed in, but it is also possible to make the sleeve from elastic material, for example spring steel, and to provide it with a suspension recess that is drawn is not shown in detail. It is important that the part 11 is held in the part 12 with a press fit which is dimensioned sufficiently strong that the transmission pin 10 can fully fulfill its transmission function within the insulating base 2.

It is also possible to provide projections or teeth or the like in the area of the clamping seat surfaces, for example on the inner surface of the sleeve or on the outer surface of the insulating material pin, in order to reduce the friction between to increase these two parts if necessary.

In drawing fig. 3 and 4 it can be seen that either the end of the sleeve 12 facing away or facing the insulating pin 11 can be provided with a radial projection 16 which simplifies the handling of the pin / sleeve unit during the assembly process in the insulating base. 3 and 4 that the insertion end 17 of the sleeve 12 facing the part 11 widens like a trumpet.

3 and 4 also shows that the part 12 in its area facing the lower end 14 of the part 11 can have a radially inward deformation 21, for example in the manner of an inner bead on the inner circumference of the part 12 As a result, when the part 11 is inserted into the interior of the part 12 by means of the lower end 14 of the part 11, the bead 21 is quasi pushed in front of the part 11 during the pressing-in process, in such a way that ultimately this inner bead 21 extends to the lower region of the sleeve-shaped part 12 has been displaced, provided that the part 12 is made of a deformable material. This leads to an improved support in the final state of the press-in, which is important insofar as the stability states within the transmission pin 10 after the press-in process and thus also after the installation of the transmission pin 10 in the actual switching device 1 (see FIG. 1 or 2). are no longer verifiable. The bead 21 and the bead support achieved by this are also important because in thermal Switches, for example, temperature ranges up to approx. 400 and 500 ° C are controlled and switched, thus temperature ranges in which the different expansion coefficients of the materials used play a major role. If, for example, a metallic sleeve (part 12) expands more than an insulating bolt, loosening can occur, which can have fatal consequences and must therefore be avoided from the outset.

With reference to Fig. 1 it can still be seen that the insulating pin, namely the part 11, in a first bore 18 of the insulating base 2 and the fusible link insert 9, which virtually forms the sleeve of the pin, is arranged in a second bore 19, the Diameter is larger than that of the first hole.

In the embodiments for a transmission pin 10 according to FIGS. 5 and 6 it is provided that the part 12 is essentially pot-shaped and is provided in the region of its upper opening with a flanged edge 23, while the part 12 in its lower region has a curved or has curved bottom 22. This configuration results in defined length ratios.

The other part 11 of the transmission pin 10 is in turn pressed into the cup-shaped part 12 by the application of axial pressure in the direction of the arrow 13, whereby the length of the transmission pin 10 can be changed. The exemplary embodiments according to FIGS. 5 and 6 are each a transmission pin 10 without a soldering iron insert. The design of the pot-like sleeve part In contrast to the embodiment according to FIG. 5, 12 according to FIG. 6 has a lower floor 22 that is curved outward or practically round.

In the foregoing, it has been said that the transmission pin 10 consists of two parts 11 and 12, one part 11 being able to be pressed into the other part 12 by the application of axial pressure. In particular, the part 12 has been defined as a sleeve part or a quasi-sleeve part, and this wording is intended to express that the part 12 need not be an element which is basically a priori basically hollow and relatively thin-walled, but rather It could also be a part 12 made of flowable solid material with a quasi-sleeve-like function, into which, for example, a plastic pin or another solid pin (part 11) can be pressed, whereby only the precondition applies that the flowable solid material of the part 12 is to be held in any suitable manner so that it can perform its desired flow movement, which then ultimately leads to shortening of the pin and change in length. This is to make it clear that it is not necessary for the part 12 to be in the form of a hollow sleeve from the outset, and that it is also not necessary for the outside diameter of this part 12 to always have the same value. It is therefore also entirely conceivable that the part 12 is initially spherical, for example, and then is formed into a quasi-sleeve-shaped element in the course of the pressing-in process, provided that it is only possible to achieve a change in length of the transmission pin in the sense of the present invention. Of course the connection of the two parts 11 and 12 of the transmission pin 10 must always be guaranteed. It follows from this that the part 12 can initially be in different configurations, for example it can initially be open or closed or be in the form of a solid body, but it can also be an open spring element or a closed element that is slotted at its upper region be. It is only important that, as already described above, two parts 11 and 12 forming a transmission pin 10 can be pressed into one another in a switching device in order to overcome tolerance problems which can occur in switching devices, in particular electrical switching devices, of the generic type.

REFERENCE SIGN LIST

1

 Switching device

2nd

 Insulated base

3rd

 Page of 2

4th

 Fixed contact

5

 Freeers

6

 Contact spring

7

 Movement contact

8th

 Page of 2

9

 Soldering iron insert

10th

 Transfer pin

11

 part

12

 "

13

 Arrows for applying pressure

14

 The End

16

 Radial projection

17th

 Introductory end

18th

 1st hole

19th

 2nd hole

20th

 Bimetal spring washer

21

 radial deformation

22

 lower floor

23

 beaded edge

Claims (10)

Switching device, in particular electrical switching device, with - a base part (2), - On one side a switching element with at least one movable switching element part (movement contact 7) is arranged and - On the other side, a thermal trigger is arranged, the trigger movement by means of a transmission pin (10) guided in the base part (2) the movable part of the switching element is transferable,

characterized, - That the transmission pin (10) consists of two parts (11, 12) and - Is designed to be permanently fixable with regard to its effective lengths in that one part (11) can be pressed into the other part (12) by exerting axial pressure. Switching device according to claim 1,

characterized,

that the two parts (11, 12) of the transmission pin (10) are arranged telescopically one inside the other. Switching device according to claim 1 or 2,

characterized,

that one part is an insulating pin and the other part is a sleeve part or quasi-sleeve part, in particular a metallic sleeve, which engages around one end of the insulating pin (part 11). Switching device according to claim 3,

characterized,

that the metallic sleeve (part 12) is formed directly by a fusible link insert. Switching device according to one of the preceding claims,

characterized,

that the inner diameter of the sleeve is dimensioned relative to the pin diameter so that the insulating pin (part 11) can only be pressed into the sleeve (part 12) when the sleeve material is radially deformed. Switching device according to one of the preceding claims,

characterized,

that the arranged in the sleeve end (14) of the pin (part 11) is conical, spherical or rounded. Switching device according to one of the preceding claims,

characterized,

that the sleeve (part 12) is pot-shaped. Switching device according to one of the preceding claims,

characterized,

that the sleeve is made of elastic material and with a suspension recess (suspension slot). Switching device according to one of the preceding claims,

characterized,

that the pin (part 11) facing insertion end (17) of the sleeve (part 12) widens like a trumpet. Method for producing a switching device, in particular an electrical switching device, which has a base part, on one side of which a switching element with at least one movable switching element part (movement contact 7) is arranged and on the other side of which a thermal release is arranged, the triggering movement of which is carried out by means of a transmission pin guided in the base part is transferable to the movable part of the switching element,

marked by
following manufacturing process steps: a) Manufacture of the individual parts of the base part (e.g. insulating base), switching element, movable switching element part (movement contact), connecting elements, thermal release and two parts, namely an insulating pin and a sleeve part or quasi-sleeve part, which together form the transmission pin; b) pre-assembly of the individual parts of the base part, switching element, movable switching element (movement contact), connecting elements; c) separate pre-assembly of the transmission pin in that the end of the insulating pin is inserted into the sleeve part or quasi-sleeve part in such a way that a transmission pin is formed whose length is greater than the length required in the base; d) inserting the prefabricated pin into an upsetting device e) Inserting a sensor into the preassembled base to determine the inside dimension (distance between switching point and base plate, transfer of the measured result to the upsetting device, carrying out the upsetting process in such a way that the pin is pushed into one another by pushing the sleeve part or quasi-sleeve part and the insulating material pin to its length adapted to the conditions in the switching device; f) inserting the finished transmission pin into the base, final assembly of the remaining base parts.

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