AT512814B1 - Temperature sensitive electrical switch - Google Patents

Abstract

Temperature-sensitive electrical switch (1) comprising a snap element made of bimetallic strip and a spring element (6) which has a movable section (11) with a free end (12) with which a fixed contact element (10) can be contacted, an actuating element (5) as Operative connection between snap element and spring element (6) in order to transfer the free end (12) of the spring element (6) from a first (19) to a second position (20). In order to be able to change the stroke of the free end (12) between first (19) and second position (20) in a simple manner, it is provided that the actuating element (5) is provided with a guide section (28) in a guide device (8a, 8b, 8c, 8d) along a guide axis (3a, 3b, 3c, 3d) is guided and that the actuating element (5) in response to its inclusion in the guide device (8a, 8b, 8c, 8d) having at least one contact portion (13) the movable portion (11) of the spring element (6) at different contact positions (26a, 26b, 26c) contacted.

Description

asterreidiiscises pitwiarot AT512 814B1 2014-01-15

description

TEMPERATURE-SENSITIVE ELECTRICAL SWITCH FIELD OF THE INVENTION

The present invention relates to a temperature-sensitive electrical switch comprising a snap element, preferably a snap disc, made of bimetallic strip and a spring element which has a along a longitudinal, width direction and thickness direction extending movable portion having a free end with which a fixed contact element is contacted wherein the movable portion has a pressure portion having a pressure portion surface extending along the longitudinal direction, and wherein the fixed contact element is electrically conductively connected to a first terminal and the spring element is electrically connected to a second terminal, an actuating element operatively connected between the snap element and the spring element free end of the spring element to be transferred from a first to a second position, wherein the actuating element has a guide portion and an upper side and a lower side, on each of which mindes at least one contact portion is arranged, a housing and a hood.

STATE OF THE ART

Temperature-sensitive electrical switches are used for temperature-dependent switching or closure and / or interruption of an electrical circuit, for example as a shutdown in a kettle, as overload protection or in regulators for boilers. Therefore, the term thermostat is common for these switches.

The construction of these thermostats includes a snap-action element made of bimetallic strip, which is usually designed as a snap-action disc as a temperature-sensitive element. The snap disc may be circular or have other shapes, e.g. square, rectangular etc.

The snap disc has a curvature, for example in the form of a flat spherical cap, which changes abruptly at a lower and an upper snap temperature. Here, a movable portion of a spring element is moved from a first to a second position, wherein the spring element contacted with a movable portion disposed on the free end in one position a fixed contact element and not in the other position. Between these two positions, the free end performs a certain stroke. Thus, a fixed contact element is contacted by the spring element in a buckling state of the snap disk; in the other curvature state, the spring element has no contact with the fixed contact element.

As an operative connection between the snap-action disc and the spring element is a guided in a pin guide pressure pin is used, which is preferably carried out electrically insulating. The mechanical contacting of the spring element by the pressure pin takes place at a pressure point of the spring element, which is usually arranged centrally on the movable portion of the spring element and by the - usually central - arrangement of the pin guide is specified in the housing.

From the prior art known thermostats have the following structure, wherein the spring element contacted the fixed contact element in principle. First, in order to allow a satisfactory contact, a contact rivet is attached to the spring element. The spring element is subsequently riveted by means of a connecting rivet with a connector or terminal and a housing of the thermostat, wherein the housing is usually made of plastic. Another contact rivet is mounted on the fixed contact element. Then another terminal is also riveted to the fixed contact element in the housing with a connecting rivet. As a result, the pin guide is placed, which usually consists of a disc with a centrally located, sleeve-shaped opening. Then, the distance between the pressure point of the spring element and the support of the snap disk is determined. Now a pressure pin with appropriate length is installed. As the last manufacturing step, the disc is used and a hood to the housing, preferably by crimping, connected.

A serious disadvantage of the structure described is that the stroke of the free end of the spring element can be changed only consuming.

Moreover, in view of different strong currents to be switched, it is desirable to be able to easily vary the force that must be applied to close or open the contact in any case. This is practically impossible with solutions known from the prior art, apart from the costly replacement of the spring element or even the snap element.

OBJECT OF THE INVENTION

The object of the present invention is to provide a temperature-sensitive electrical switch, which avoids the disadvantages mentioned above. In particular, a simple way to create the hub of a free end of a spring element with which a fixed contact element is contacted, to change. Likewise, the force that must be applied to close or open the contact in any case, can be easily changed.

PRESENTATION OF THE INVENTION

In a temperature-sensitive electrical switch with a snap disc made of bimetallic an electrical contact between a free end of a movable portion of a spring element and a fixed contact element is closed or opened. In this case, the free end is transferred from a first position to a second position due to a temperature-dependent sudden change in curvature of the snap disk, wherein the free end experiences a certain stroke. In this case, the snap disk exerts a pressure on an actuating element. This has a guide section, with which the actuating element is received and guided in a guide device. The actuator further has an upper side and a lower side. At least one contact section is arranged both on the top side and on the bottom side. With at least one contact section, the actuating element contacts the snap disk, and with at least one contact section, the actuating element presses against the movable section of the spring element. In principle, both the closure and the opening of the electrical contact can be effected by the pressure of the actuating element on the spring element. For reasons of stability with regard to contacting, the latter variant is usually chosen, i. in this case the contact is closed in the first position and open in the second position.

As described above, the stroke of the free end results by pressing the operating member on the movable portion of the spring element. The movable portion extends along a longitudinal direction and is limited in this of the free and a fixed end. Since the actuator engages a contact portion along the longitudinal direction at a predetermined distance from the fixed end at a pressure point on the movable portion, a lever arm results between the fixed end and the pressure point. Thus, when the operating element is pressed onto the pressure point, a torque acting on the movable section results, which leads to the bending of the spring element and to the stroke of the free end.

Essence of the invention is to change said lever arm and thus the stroke of the free end in a simple manner by the actuating element in response to its inclusion in the guide device contacted with at least one contact portion, the movable portion of the spring element at different contact positions. Depending on the con-

»Position« «» pitwiaist AT512 814B1 2014-01-15 timing position results in a longer or shorter lever arm. For a given force that can be exerted by the snap disk on the actuator, this results in an adjustable torque which acts on the movable portion of the spring element.

Conversely, by the change of the lever arm but also the force that must be applied to the closure or opening of the electrical contact from the snap element at least, be set at a predetermined spring constant of the spring element.

Therefore, it is in a temperature-sensitive electrical switch comprising a snap element, preferably a snap disc of bimetallic strip and a spring element having a along a longitudinal direction, width direction and thickness direction extending movable portion having a free end with which a fixed contact element is contacted wherein the movable portion has a pressure portion having a pressure portion surface extending along the longitudinal direction, and wherein the fixed contact element is electrically conductively connected to a first terminal and the spring element is electrically connected to a second terminal, an actuator operatively connected between the snap element and the spring element free end of the spring element to be converted from a first to a second position, wherein the actuating element has a guide portion and an upper side and a lower side, on each of which at least one Kontaktabsc A housing and a hood, according to the invention provided that a guide device is provided for receiving the guide portion of the actuating element, that the actuating element is guided with the guide portion in the guide device along a guide axis and that the actuating element in response to its inclusion in the guide device contacted with at least one contact portion, the movable portion of the spring element at different contact positions.

Preferably, in this case, the different contact positions are arranged on the printing section surface and spaced apart in the longitudinal direction.

These different contact positions can be realized that, for example, both at the top and at the bottom exactly one contact portion is arranged and these contact portions are spaced apart in the longitudinal direction. Accordingly, it is provided in a preferred embodiment of the switch according to the invention that two contact portions are spaced from each other in the longitudinal direction.

Thus, by a rotated orientation of the actuating element in the guide device a longitudinally displaced contact position can be effected. If the contact section which contacts the printing section surface is arranged eccentrically with respect to the guide axis, an orientation of the actuating element rotated about the guide axis causes a changed contact position. In order to guarantee a contact position invariable during operation of the switch, only a discrete number of rotated orientations is provided, wherein the actuating element in the guide device itself can not be rotated, but can be accommodated only in differently rotated orientations in the guide device. Accordingly, in a preferred embodiment of the switch of the invention, it is provided that the actuator is orientable and guidable in a finite number of configurations in the guide apparatus, the configurations differing only by rotation of the actuator a discrete angular amount about the guide axis.

If the contact portions on the top and bottom of the actuator in the longitudinal direction spaced from each other, so different contact positions can be forced by the actuator is taken in a rotated by 180 ° orientation in the guide device, wherein the rotation about an axis normal the guide axis takes place. That Top and bottom are now reversed. Accordingly, it is provided in a preferred embodiment of the switch according to the invention that the actuating element in two configurations in the guide device can be oriented and guided, wherein the configurations only by rotation of the actuating element to 3/28

asterreidiiscists pitwiarot AT512 814B1 2014-01-15 180 ° around an axis normal to the guide axis.

Alternatively or additionally, the guide device may comprise a plurality of actuator guides, which are spaced apart in the longitudinal direction. Depending on whether a longer or shorter lever arm is desired, the actuating element is optionally inserted into an actuating element guide with a greater or lesser distance from the fixed end or guided in such. Accordingly, it is provided in a particularly preferred embodiment of the switch according to the invention that the guide device comprises a plurality of actuator guides each having a guide axis, wherein the actuator guides are spaced apart in the longitudinal direction. In this way, the length of the lever arm can be varied and very finely adjusted by combining with different orientations of the actuating element, as described above for cases in which the actuating element has contact portions which are spaced apart in the longitudinal direction.

Since the actuating element acts as a power transmission between snap disk and spring element, the actuating element guides between the snap element must be arranged the movable portion of the spring element. Accordingly, it is provided in a preferred embodiment of the switch according to the invention that the actuating element guides are arranged between the snap element and the movable portion of the spring element.

In order to be able to set the lever arm very precisely, in principle many, very closely spaced actuator guides are desirable. On the other hand, the space available in the switch are limited, so that not as many actuator guides can be provided. As a good compromise in practice, there are 3 actuator guides, of which a first with respect to length and width direction centered in the housing - and thus essentially as known from the prior art - is arranged. A second actuator guide is located farther from the fixed end and a third actuator guide closer to the fixed end. Accordingly, it is provided in a particularly preferred embodiment of the switch according to the invention that exactly 3 actuator guides are provided.

Preferably, the second and third actuator guide are placed symmetrically about the first actuator guide. Accordingly, it is provided in a particularly preferred embodiment of the switch according to the invention that a first actuator guide has a first guide axis, which is preferably arranged centrally in the housing and which has the same distance to a second guide axis of a second actuator guide in the longitudinal direction as to a third guide axis of a third actuator leadership.

In particular, in the event that the movable portion of the spring element is not curved without mediated by the actuator pressure action, it is advisable to run all the guide axes parallel. As a result, the actuating element in each actuator guide is initially at the same angle to the movable portion. This in turn means that the differences between the possible torques that result due to the longitudinally different positions of the actuating element in the different actuator guides, depend only on the distance of the respective guide axis or the respective pressure point on the movable portion to the fixed end. This allows easy control or adjustability of the possible torques. Therefore, it is provided in a particularly preferred embodiment of the switch according to the invention that all guide axes parallel to each other.

A particularly space-saving way to arrange the actuator guides, resulting in execution of all actuator guides as a coherent large recess. Here, the recess has portions which each act as a single actuator guide and are dimensioned so that the actuator alone by movement in a plane perpendicular to a guide axis not from 4/28

It is possible to move an actuator guide out of the way. Accordingly, it is provided in a particularly preferred embodiment of the switch according to the invention that the actuator guides in a plane perpendicular to one of the guide axes form a common opening, which is surrounded by a single closed border line.

In contrast, of course, embodiments are conceivable where the actuator guides are designed sleeve-shaped and fully surrounded the actuator, creating a very stable leadership is guaranteed. Accordingly, it is provided in a particularly preferred embodiment of the switch according to the invention that at least one actuator guide is designed sleeve-shaped. That the actuator guides do not form a single common aperture here, and therefore, in this embodiment, there is no common outline of the actuator guides in a plane perpendicular to a pilot axis.

From the prior art it is known that the -. exactly one - to provide actuator guide as an opening of a small plate, which is inserted into the housing or placed on this. Since in this case the actuator guide is almost always performed in the middle of the plate and the central placement of the plate in the housing - for example, by corresponding recesses in the housing - can be easily guaranteed, the desired arrangement of the actuator guide can be ensured relative to the movable portion of the spring element. It does not matter whether the plate is rotated about the guide axis, as this does not affect the orientation of the actuator guide to the movable portion.

In contrast, in the case of a plurality of actuating element guides - and in particular also in the case of actuating elements which have contact sections at the top and bottom, which are spaced apart from one another in the longitudinal direction - this is no longer possible since the exact arrangement of the actuating element guide along the longitudinal direction now has to be guaranteed so that the actuator with at least one contact portion in each actuator guide can contact the movable portion at the desired distance from the fixed end of the movable portion. This problem is solved by the actuator guides are rigidly connected to the housing. An unintended change in the orientation of the actuator guides, as would be possible with a free plate with the actuator guides, is thus prevented. Therefore, it is provided in a particularly preferred embodiment of the switch according to the invention that the housing is rigidly connected to a plurality, preferably all actuator guides.

The alignment is particularly accurate when the actuator guides are integral with the housing. That the housing has a corresponding portion in which openings or a large, correspondingly shaped opening are provided as actuator guide. In addition, in this way the number of individual components of the switch is reduced, whereby process steps and costs in the production can be saved. Accordingly, it is provided in a particularly preferred embodiment of the switch according to the invention that the housing is designed in one piece with a plurality, preferably all actuator guides.

In order to ensure optimum transmission of force by the actuating element on the movable portion of the spring element, it is provided that the actuating element or the corresponding guide axis is normal to the corresponding surface of the movable portion immediately before or after the movement of the actuating element. Therefore, in a particularly preferred embodiment of the switch according to the invention, it is provided that in the first or second position of the free end of the spring element, a guide axis is perpendicular to the printing section surface in at least one point of the printing section surface.

In order to facilitate the movement of the actuating element, its mass can be reduced

piiesSasnt AT512 814B1 2014-01-15 be made hollow by the actuator is hollow or has recesses. Accordingly, it is provided in a particularly preferred embodiment of the switch according to the invention, that the actuating element is at least partially hollow or at least has a recess.

In order to ensure that the actuating element can not be rotated about a guide axis when it is received in the guide device, it is advisable not to perform the cross section of the corresponding actuator guide and the corresponding cross section of the guide portion of the actuating element non-circular.

Accordingly, it is provided in a particularly preferred embodiment of the switch according to the invention that the projection of the guide portion of the actuating element in the direction parallel to a guide axis on a plane which is perpendicular to this guide axis, an envelope which deviates from the circular shape.

BRIEF DESCRIPTION OF THE FIGURES

The invention will now be explained in more detail with reference to embodiments. The drawings are exemplary and are intended to illustrate the inventive idea, but in no way restrict it or even reproduce it.

FIG. 1 shows an axonometric view of a temperature-sensitive electrical one. FIG

2 shows a plan view of a temperature-sensitive electrical switch FIG. 3 shows a sectional view of a temperature-sensitive electrical switch corresponding to the section line BB in FIG. 2 with a spring element in a first position and an actuating element in a first actuating element guide. [0038] FIG. 4 shows a sectional view of a temperature-sensitive electrical switch corresponding to the section line BB in FIG. 2 with a spring element in a first position and an actuating element in a second actuating element guide FIG. 5 shows a sectional view of a temperature-sensitive electrical switch corresponding to the section line BB in Fig. 2 with a spring element in a first position and an actuating element in a third actuator guide Fig. 6 is an exploded view of a temperature-sensitive electrical scarf age without showing a snap-action disc and a Ha 7 shows an axonometric view of a housing with 3 integrated actuation element guides FIG. 8 shows a plan view of the housing of FIG. 7 [0044] FIG. 9 shows the sectional view of FIG. 3, but with the spring element in FIG a second

FIG. 10 shows the sectional view of FIG. 4, but with the spring element in a second position. FIG. 11 shows the sectional view of FIG. 5, but with the spring element in a second position

Position Figure 12 is a sectional view of a temperature-sensitive electrical switch corresponding to the section line B-B in Fig. 2 with a spring element in a first position and an actuating element in a first configuration 6/28

Fig. 13 is a sectional view of a temperature-sensitive electrical switch corresponding to the section line BB in Fig. 2 with a spring element in a first position and an actuating element in a second configuration. Fig. 14 Fig. 16 Fig. 16 Fig. 18 Fig. 19 Fig. 20 Fig. 20 Fig. 21 Fig. 22 A sectional view a temperature-sensitive electrical switch corresponding to the section line BB in Fig. 2 with a spring element in a first position and an actuator in a third configuration an exploded view of a temperature-sensitive electrical switch without showing a snap disc and a hood an axonometric view of a housing with an oriented Actuate element guide a plan view of the housing of FIG. 16 is the sectional view of FIG. 12, but with the spring element in a second Po However, with the spring element in a second position, the sectional view of FIG. 14, but with the spring element in a second position, an axonometric view of an actuating element, a side view of the actuating element from FIG. 21

WAYS FOR CARRYING OUT THE INVENTION

In Fig. 1 an axonometric view of a temperature-sensitive electrical switch 1 according to the invention is shown, which is also referred to as a thermostat. This has a preferably made of plastic housing 4, which is closed on one side by means of a hood 7. In this case, the hood 7 is preferably made of a metal, for example aluminum, and connected by crimping with the housing 4. Furthermore, in Fig. 1, a first 22 and a second terminal 23 can be seen, which serve for electrical connection from the outside.

Fig. 2 shows a plan view of the switch 1 of Fig. 1 with an indicated section line B-B and arrows indicating the corresponding viewing direction. Figures 3, 4 and 5 each show the corresponding sectional view.

Herein each recognizable is a spring element 6, which is electrically conductively connected to the second terminal 23 and a fixed contact element 10 contacted, which in turn is electrically conductively connected to the first terminal 22. In detail, the spring element 6 has a fixed end 25, with which it is spatially fixed relative to the second terminal 23, followed by a movable portion 11 having a free end 12. The movable portion 11 is made substantially flat and extends along one Longitudinal direction 14, a width direction 15 and a thickness direction 16th

In order to optimize the electrical contact between the spring element 6 and the fixed contact element 10, in each case a contact profile 24 is attached to the free end 12 and the fixed contact element 10. In a first position 19 of the spring element 6 or its free end 12, which is shown in Figures 3, 4, and 5, the two contact profiles 24 contact each other flatly.

In order to transfer the spring element 6 or its free end 12 into a second position 20 (cf., Fig. 9) in which the two contact profiles 24 do not contact each other, a snap-action disc 2 is provided, which jumps as a function of the temperature her vault changes. In this case, the snap disk 2 exerts a force 7/28 on an actuating element 5

äsfei «id> iscije AT512 814B1 2014-01-15.

In this case, the snap disc 2 presses on a contact portion 13 of the actuating element 5, which is arranged on an upper side 29 of the actuating element 5. Since the actuating element 5 is located in a first actuating element guide 8a or is guided with a guide section 28 in the first actuating element guide 8a, the actuating element 5 can only move along a first guide axis 3a which runs parallel to the longitudinal axis 18 of the actuating element 5.

As a result, the actuating element 5 presses with a contact portion 13, which is arranged on a bottom 30 of the actuating element 5, in the region of a pressure section 9 of the movable portion 11 of the spring element 6 against the movable portion 11. This results in a deflection the movable portion 11, the free end 12 undergoes a stroke, and the electrical contact between the fixed contact element 10 and the spring element 6 is interrupted. The spring element 6 or its free end 12 is now in the second position 20, cf. Fig. 9.

In FIG. 3 and FIG. 9, the actuating element 5 is located in the first actuating element guide 8a, which is arranged centrally in the housing 4 with respect to the longitudinal direction 14 and the width direction 15. Accordingly, a mean distance between the longitudinal axis 18 of the actuating element 5 and a first contact position 26a of the contact portion 13 on the underside 30 of the actuating element 5 and the fixed end 25 results parallel to the longitudinal direction 14. This distance corresponds to a lever arm, due to the length of the free End 12 between the first 19 and second position 20 undergoes a medium stroke. Accordingly, a torque which results from the lever arm and the force transmitted by the actuating element 5, of medium size.

Conversely, a mean minimum force generated by the snap disc 2 is basically sufficient to transfer the spring element 6 or its free end 12 from the first 19 to the second position 20 (see FIG. Corresponding to the middle stroke of the free end 12, the longitudinal direction 14 and the thickness direction 16 rotate between the first 19 and second position 20.

4, the actuating element 5 is located in a second actuating element guide 8b with a second guide axis 3b. Here, the distance measured parallel to the longitudinal direction 14 between the longitudinal axis 18 of the actuating element 5 and a second contact position 26b of the contact portion 13 on the underside 30 of the actuating element 5 and the fixed end 25 is greater than in the case shown in FIG. The corresponding lever arm is therefore larger. Consequently, the free end 12 experiences a smaller stroke between the first 19 and second position 20 of the spring element 6, cf. Fig. 10. With the same applied force, which is transmitted by the actuator 5 to the movable portion 11, the resulting torque correspondingly larger than in the case shown in Fig. 3. Conversely, with the same spring constant of the spring element 6, in principle, a smaller minimum force to be applied by the snap-action disc 2 is sufficient to transfer the spring element 6 or its free end 12 from the first 19 to the second position 20 (see FIG. Corresponding to the lesser stroke of the free end 12, the longitudinal direction 14 and the thickness direction 16 rotate between the first 19 and second positions 20.

In Fig. 5, the actuator 5 is in a third actuator guide 8c with a third guide axis 3c. In this case, the distance measured parallel to the longitudinal direction 14 between the longitudinal axis 18 of the actuating element 5 and a third contact position 26c of the contact section 13 on the underside 30 of the actuating element 5 and the fixed end 25 is smaller than in the case shown in FIG. The corresponding lever arm is therefore smaller. Consequently, the free end 12 experiences a larger stroke between the first 19 and second position 20 of the spring element 6, cf. Fig. 11. At the same applied force, which is transmitted by the actuator 5 to the movable portion 11, the resulting torque correspondingly smaller than in the case shown in Fig. 3. Conversely, at the same spring constant of the spring element 6 is basically a size 8/28

Austrian päteü camouflaged minimal force required by the snap-action disc 2 in order to transfer the spring element 6 or its free end 12 from the first 19 to the second position 20 (see FIG. Corresponding to the larger stroke of the free end 12, the longitudinal direction 14 and the thickness direction 16 rotate between the first. 19 and second position 20.

In order to always guarantee optimal force transmission by the actuating element 5, in the first position 19, the guide shafts 3a, 3b and 3c are normal to a printing section surface 21 of the printing section 9. The printing section surface 21 is in axono-metric view of the in FIG 6 very well recognizable. From Fig. 6 is also an integral embodiment of the housing 4 with the actuator guides 8a, 8b and 8c show, which form a guide device.

The axonometric view of the housing 4 in Fig. 7 shows this even more clearly. In the exemplary embodiment shown, the actuating element guides 8a, 8b, 8c are not sleeve-shaped, ie not so that each actuating element guide 8a, 8b, 8c comprises the actuating element 5 in its entirety, but designed as a large opening. The opening forms three sections which each act as a single actuating element guide 8a, 8b, 8c and are dimensioned so that the actuating element 5 can be moved by movement in a plane perpendicular to a guide axis 3a, 3b, 3c (cf., for example, FIG. can not be moved out of an actuator guide 8a, 8b, 8c out.

Fig. 8 shows a plan view of the housing 4, in which is particularly clear that the three actuator guides 8a, 8b, 8c in a plane which is normal to the guide shafts 3a, 3b, 3c and which in the case of Fig. 8 is the drawing plane, are surrounded by a single closed border line 17.

21 shows an axonometric view of an actuating element 5 of a further embodiment variant. FIG. 22 shows the corresponding side view. The guide section 28 of the actuating element 5 has, normal to the longitudinal axis 18, a cross section which deviates greatly from the circular shape. As a result, a defined orientation of the actuating element 5 in a guide device with an oriented fastener guide 8d, which has an opening cross-section normal to its guide axis 3d, which corresponds to said guide section cross-section of the fastener 5, is possible.

Fig. 16 shows an axonometric view of a housing 4, which has a corresponding oriented actuator guide 8d, the opening cross section in the top view of FIG. 17 is particularly well recognizable.

It can be seen in FIGS. 21 and 22 that a contact section 13 is arranged centrally on the upper side 29 of the actuating element 5. At the bottom 30 is also a contact portion 13, but this is not centered, but arranged laterally. Thus, the two contact portions 13 seen in the longitudinal direction 14 are spaced apart from each other when the actuator 5 is received in an oriented fastener guide 8 d.

The fastening element 5 can thus be introduced in the embodiment shown in a total of four configurations in the oriented actuator guide 8d along the guide axis 3d, as illustrated in the exploded view of FIG. 15. Two of the configurations differ in that the actuating element 5 is rotated by 180 ° about the longitudinal axis 18 and the guide axis 3d. Two further configurations differ in that the actuating element 5 is rotated by 180 ° about an axis that is normal to the longitudinal axis 18 and the guide axis 3d.

FIG. 12, FIG. 13 and FIG. 14 illustrate, on the basis of a sectional view along the section line BB in FIG. 2, the arrows in FIG. 2 indicating the viewing direction, three different configurations of the actuating element 5, wherein the spring element 6 or whose free end 12 is in the first position 19. FIG. 18, FIG. 19 and FIG. 20 again illustrate the three different configurations of the actuating element 5, with the spring element 6 or its free end 12 being in the second position 20.

In FIG. 12 and FIG. 18, the actuating element 5 is in a first configuration, wherein, in the illustration of FIG. 12, it is also clearly recognizable, FIG. that the actuating element 5 has a recess 27 for the purpose of weight optimization.

In the first configuration, the actuating element 5 of FIGS. 21 and 22 is arranged in the oriented actuating element guide 8d such that the upper side 29 faces the spring element 6. The contact section 13 on the upper side 29 contacts the spring element 6 or the pressure section surface 21 in a first contact position 26, the spring element 6 or its free end 12 being shown in the first position 19 in FIG.

Correspondingly, a mean distance between the first contact position 26a and the fixed end 25 measured parallel to the longitudinal direction 14 results. This distance corresponds to a Flebelarm, due to the length of which the free end 12 between the first 19 and second position 20 experiences a medium stroke , Accordingly, a torque which results from the lever arm and the force transmitted by the actuating element 5, of medium size.

Conversely, a minimum force generated by the snap-action disc 2 basically suffices to transfer the spring element 6 or its free end 12 from the first 19 to the second position 20 (see FIG. Corresponding to the middle stroke of the free end 12, the longitudinal direction 14 and the thickness direction 16 rotate between the first 19 and second position 20.

In the first configuration of the actuating element 5, the underside 30 faces the snap disc 2. The contact portion 13 on the bottom 30 is spaced from the contact portion 13 on the top 29 seen in the longitudinal direction 14. Seen in the longitudinal direction 14, the contact section 13 on the underside 30 in the first configuration of FIGS. 12 and 18 is arranged behind the contact section 13 on the upper side 29. That the distance measured in the longitudinal direction 14 between the contact section 13 on the upper side 29 and the fixed end 25 is less than the distance measured in the longitudinal direction 14 between the contact section 13 on the underside 30 and the fixed end 25.

In Fig. 13 and Fig. 19, the actuator 5 is in a second configuration. Compared with the first configuration of FIGS. 12 and 18, the actuating element 5 is rotated about an axis normal to the guide axis 3d or normal to the longitudinal axis 18 by 180 °. Accordingly, the upper side 29 now faces the snap-action disk 2 and the underside 30 faces the spring element 6. This has the consequence that the contact section 13 now contacts the spring element 6 or the pressure-section surface 21 on the underside 30 in a second contact position 26b, wherein the spring element 6 and whose free end 12 is shown in Fig. 13 in the first position 19. Here, the distance measured parallel to the longitudinal direction 14 between the second contact position 26b and the fixed end 25 is greater than in the case shown in FIG. 12. The corresponding lever arm is therefore larger. Consequently, the free end 12 experiences a smaller stroke between the first 19 and second position 20 of the spring element 6, cf. Fig. 19. With the same applied force, which is transmitted by the actuating element 5 on the movable portion 11, the resulting torque correspondingly larger than in the case shown in Fig. 12. Conversely, with the same spring constant of the spring element 6, a smaller minimum force to be applied by the snap-action disk 2 is basically sufficient to transfer the spring element 6 or its free end 12 from the first 19 to the second position 20 (see FIG. Corresponding to the lesser stroke of the free end 12, the longitudinal direction 14 and the thickness direction 16 rotate between the first 19 and second positions 20.

In Fig. 14 and Fig. 20, the actuator 5 is in a third configuration. Compared to the second configuration of FIGS. 13 and 19, the actuating element 5 is rotated about the guide axis 3d or about its longitudinal axis 18 by 180 °. That the underside 30 again faces the spring element 6, and the spring element 6 or the pressure section surface 21 is contacted by the contact section 13 on the underside 30 in a third contact position 26c, the spring element 6 or its free end 12 in FIG. 28

Merreöiise-ts piiesSasnt AT512 814B1 2014-01-15 14 is shown in the first position 19. However, the distance measured in the longitudinal direction 14 between the contact element 13 contacting the spring element 6 and the fixed end 25 of the spring element 6 has now changed. This is shorter than in the first and second configurations, or the distance measured in the longitudinal direction 14 between the third contact position 26c and the fixed end 25 is shorter. The corresponding lever arm is therefore smaller. Consequently, the free end 12 experiences a larger stroke between the first 19 and second position 20 of the spring element 6, cf. Fig. 20. At the same applied force, which is transmitted by the actuator 5 to the movable portion 11, the resulting torque correspondingly smaller than in the case shown in Fig. 12. Conversely, with the same spring constant of the spring element 6, a larger minimum force to be applied by the snap disk 2 is basically necessary to transfer the spring element 6 or its free end 12 from the first 19 to the second position 20 (see FIG.

Corresponding to the larger stroke of the free end 12, the longitudinal direction 14 and the thickness direction 16 rotate between the first 19 and second position 20th

Finally, it should be noted that, of course, embodiments with a guide device consisting of several oriented actuator guides 8d and corresponding actuators 5 are conceivable to cover a particularly large range of torques particularly fine.

REFERENCE LIST 1 switch 2 snap-action disk 3a first guide axis 3b second guide axis 3c third guide axis 3d guide axis of an oriented actuator guide 4 housing 5 actuator 6 spring element 7 hood 8a first actuator guide 8b second actuator guide 8c third actuator guide 8d oriented actuator guide 9 pressure section of spring element 10 fixed contact element 11 movable section of the spring element 12 free end of the spring element 13 contact portion of the actuating element 14 longitudinal direction 15 width direction 11/28

Thickness direction 17 Border line 18 Longitudinal axis of the actuating element 19 First position of the free end of the spring element 20 Second position of the free end of the spring element 21 Pressure section surface 22 First terminal 23 Second terminal 24 Contact profile 25 Fixed end of spring element 26a First contact position 26b Second contact position 26c Third contact position 27 Recess 28 Guide section 29 Top of the actuating element 30 Bottom of the actuating element 12/28

Claims (17)

1. Temperature-sensitive electrical switch (1) comprising a snap element, preferably a snap disc (2) made of bimetallic strip and a spring element (6) which extends along a movable section (11) extending in a longitudinal direction (14), width direction (15) and thickness direction (16) and having a free end (12), with which a fixed contact element (10) can be contacted, the movable section (11) having a pressure section (11) 9) having a printing section surface (21) extending along the longitudinal direction (14), and wherein the fixed contact element (10) with a first terminal (22) and the spring element (6) with a second terminal (23) electrically connected is, an actuating element (5) as an operative connection between the snap element and the spring element (6) to the free end (12) of the spring element (6) from a first (19) to a second position (20) wherein the actuating element (5) has a guide section (28) and an upper side (29) and a lower side (30), on each of which at least one contact section (13) is arranged, a housing (4) and a hood (7) , characterized in that a guide device (8a, 8b, 8c, 8d) for receiving the guide portion (28) of the actuating element (5) is provided, that the actuating element (5) with the guide portion (28) in the guide device (8a, 8b , 8c, 8d) along a guide axis (3a, 3b, 3c, 3d) is guided and that the actuating element (5) in response to its inclusion in the guide device (8a, 8b, 8c, 8d) with at least one contact portion (13) movable portion (11) of the spring element (6) at different contact positions (26a, 26b, 26c) contacted. 2. Switch (1) according to claim 1, characterized in that the different contact positions (26 a, 26 b, 26 c) arranged on the Druckabschnittsoberfläche (21) and in the longitudinal direction (14) are spaced from each other. 3. Switch (1) according to one of claims 1 to 2, characterized in that two contact portions (13) in the longitudinal direction (14) are spaced from each other. 4. Switch (1) according to one of claims 1 to 3, characterized in that the actuating element (5) in a finite number of configurations in the guide device (8 a, 8 b, 8 c, 8 d) orientable and feasible, wherein the configurations only by rotation of the actuating element (5) by a discrete angular amount about the guide axis (3d) from each other. 5. switch (1) according to one of claims 1 to 4, characterized in that the actuating element (5) in two configurations in the guide device (8a, 8b, 8c, 8d) orientable and feasible, wherein the configurations only by rotation of the actuating element (5) by 180 ° about an axis which is normal to the guide axis (3a, 3b, 3c, 3d), from each other. 6. Switch (1) according to one of claims 1 to 5, characterized in that the guide device (8a, 8b, 8c, 8d) comprises a plurality of actuating element guides (8a, 8b, 8c) each having a guide axis (3a, 3b, 3c) wherein the actuator guides (8a, 8b, 8c) are spaced apart longitudinally (14). 7. switch (1) according to claim 6, characterized in that the actuating element guides (8a, 8b, 8c) between the snap element and the movable portion (11) of the spring element (6) are arranged. 8. Switch (1) according to one of claims 6 to 7, characterized in that exactly 3 actuating element guides (8a, 8b, 8c) are provided. 9. Switch (1) according to claim 8, characterized in that a first actuating element guide (8a) has a first guide axis (3a), which is preferably arranged centrally in the housing (4) and which in the longitudinal direction (14) the same distance to a second Guide axis (3b) of a second actuator guide (8b) as to a third guide axis (3c) of a third actuator guide (8c). 13/28 Merrec &ise-e;; piiesSasnt AT512 814B1 2014-01-15 10. Switch (1) according to one of claims 6 to 9, characterized in that all the guide axes (3a, 3b, 3c) parallel to each other. 11. Switch (1) according to one of claims 6 to 10, characterized in that the actuating element guides (8a, 8b, 8c) in a plane perpendicular to one of the guide shafts (3a, 3b, 3c) form a common opening, which from a single enclosed border line (17) is bordered. 12. Switch (1) according to one of claims 6 to 10, characterized in that at least one actuating element guide (8a, 8b, 8c) is sleeve-shaped. 13. Switch (1) according to one of claims 6 to 12, characterized in that the housing (4) is rigidly connected to a plurality, preferably all actuator guides (8a, 8b, 8c). 14. Switch (1) according to one of claims 6 to 13, characterized in that the housing (4) is integral with a plurality, preferably all actuator guides (8a, 8b, 8c) is executed. 15. Switch (1) according to one of claims 1 to 14, characterized in that in the first (19) or second position (20) of the free end (12) of the spring element (6) has a guide axis (3a, 3b, 3c, 3d) is normal to the printing section surface (21) in at least one point of the printing section surface (21). 16. Switch (1) according to one of claims 1 to 15, characterized in that the actuating element (5) is at least partially hollow or at least one recess (27). 17. Switch (1) according to one of claims 1 to 16, characterized in that the projection of the guide portion (28) of the actuating element (5) in the direction parallel to a guide axis (3d) on a plane which perpendicular to this guide axis (3d ), has an envelope which deviates from the circular shape. 14 sheets of drawings 14/28