The invention relates to an electrical snap-action switch, comprising a contact bridge which can be actuated by a switching plunger and a bistable spring arrangement and which is connectable in a first switch position to at least one first contact pair and in a second switch position to at least one second contact pair, wherein the spring arrangement has at least one spring arm on both sides of the switching plunger, by means of which, in addition, the contact bridge is movable transversely with respect to the movement direction of the switching plunger up to a movement end position in the event of breakage of one of the spring arms.
Numerous electrical snap-action switches are known in the state of the art, in which contact pairs separated from each other are each connectable to each other in one of two switch positions by a contact bridge. The position of the contact bridge is influenced by an actuating unit which, in most cases, comprises a switching plunger disposed and movable transversely to the contact bridge as well as a spring arrangement which can be operated by this switching plunger. Further, the spring arrangement is directly connected to the contact bridge. In this case, different spring assemblies have already been implemented, wherein specifically a bistable spring arrangement with two spring arms has proved to be particularly suitable. A suitable design and arrangement of the spring arms of these bistable spring assemblies allows a temporary switching from a first to a second switch position if a certain switchover point is exceeded, wherein a first contact pair is connected to each other by the contact bridge in the first switch position and a second contact pair in the second switch position.
As the contact bridge and the contacts of the contact pairs of such snap-action switches may be subjected to an undesired bonding due to a thermal overload of the contact areas, lever elements for a forced opening are furthermore provided in some cases of application. These lever elements can mostly be pivoted by the switching plunger, and one end thereof can be placed against the contact bridge. If sufficient force is applied to the switching plunger the contact bridge is pressed away from the contacts, thus resulting in a forced opening of the switch position. For realizing one of the switch positions as a rest position an additional spring element can be integrated in the snap-action switch such that the position of the contact bridge is stabilized in this rest position by the action of the force of this spring member.
However, the above-mentioned electrical snap-action switches have the disadvantage that, if one spring arm breaks, connected contact pairs cannot be spaced apart from each other safely so as to avoid the respective switch positions. Hence, snap-action switches are known in practice, where a specific end position of the contact bridge is to be obtained in the event of a spring fracture, in which neither the contact pairs of the first nor those of the second switch position are connected to each other.
An electrical snap-action switch is disclosed in DE 296 14 028 U1, wherein, if a spring arm breaks, a contact bridge is transferred into an end position avoiding the first and/or second switch position in such a way that the contact bridge is displaced transversely to the direction of movement of the switching plunger and is tilted upon subsequently abutting against a stop edge due to the momentum acting on the contact bridge. In this end position neither the first nor the second switch position is active. Thus, if one spring arm breaks, it is possible to avoid the current flow in the first and/or second switch position and achieve a great opening safety.
However, it is a drawback of the solution shown in DE 296 14 028 U1 that the momentum applied to the contact bridge when a spring arm breaks is relatively small. If there are additional forces acting externally on the snap-action switch, and accelerating the snap-action switch, the momentum for opening the switch position permanently is not sufficient. Especially if dynamic movements occur it may happen that an undesired displacement and/or rotation of the contact bridge takes place and results therewith in a switch position that was not intended.
Therefore, it is the object of the present invention to configure an electrical snap-action switch in such a way that a forced opening avoiding a first and/or a second switch position is ensured, even if the snap-action switch is subjected to dynamic movements.
This object is solved by providing a sliding ramp in the movement path of the contact bridge, which sliding ramp spaces apart at least one contact of the contact bridge in the movement end position from the associated contact of the respective contact pair in the event of breakage of one spring arm.
Thus, it is possible that directly after the breakage of one spring arm and the displacement of the contact bridge resulting therefrom both the first and the second switch positions of the snap-action switch are avoided. Upon sliding on the sliding ramp arranged in the movement path of the contact bridge the contact bridge is spaced apart from the contact pair of the first and/or second switch positions. Furthermore, the undamaged spring arm acts on the contact bridge to ensure a forced opening of the snap-action switch, even in the event of forces acting externally on the snap-action switch, in particular dynamic forces.
Advantageous embodiments are claimed in the dependent claims and will be explained below.
It is a further advantage that the sliding ramps on the contact bridge are arranged on both sides of the switching plunger. The arrangement of the sliding ramps on the contact bridge permits a simple configuration of the sliding ramps. Moreover, a distribution of the sliding ramps on both sides of the switching plunger ensures that the contact bridge is spaced apart from the respective contact pairs, regardless of the direction of movement of the contact bridge which is directed transversely to the switching plunger.
In another embodiment it is an advantage that the contact bridge comprises two contact carriers which run substantially parallel towards each other and which are spaced apart and connected by at least two electrically insulating spacers, wherein the spacers are arranged on both sides of the switching plunger and the sliding ramps are formed by ends of the spacers protruding over the contact carriers. The configuration of the sliding ramps in such a way further reduces the production expenditure for the sliding ramps. Furthermore, each contact of the contact pairs can be spaced apart from the contact bridge by a separate sliding ramp.
It is positive if the sliding ramps are made of an electrically insulating material, as an undesired current transition between the contact pairs of the different switch positions is thus avoided.
If the sliding ramps are substantially wedge-shaped the distance between the contact bridge and the respective contact pair changes constantly as the movement path increases when the contact bridge is displaced transversely to the direction of movement of the switching plunger. Thus, jerky movements of the contact bridge during the displacement can be avoided and a uniform guidance of the contact bridge into the movement end position is ensured.
Advantageously, the contacts of the contact pairs can be realized with a slope which faces the respective sliding ramp. Accordingly, the risk that the contact bridge or the sliding ramp associated with this contact bridge gets wedged with the respective contact of the contact pair is minimized.
If the slopes have a continued curvature, the slope can easily be realized by machining the respective contact to obtain a bend.
In an advantageous embodiment it is conceivable that the contacts of the contact pairs are each realized with two contact flanks running towards each other substantially v-shaped, wherein the contact flanks are each joined by a horizontal supporting surface on which the corresponding sliding ramp lies face to face in a movement end position. This face-to-face support can prevent the contact bridge from tilting under dynamic use conditions of the snap-action switch.
The invention will be explained by means of an embodiment below, with the aid of figures in a drawing. In the drawing:
The figures are merely of a schematic nature and only serve the understanding of the invention. Like elements are designated with like reference numerals.
The electrical snap-action switch 1 as illustrated in
Approximately in the center of the switching plunger 2 two opposite notches are provided on the switching plunger 2. Each of these notches serves to receive one of the ends of two catch springs 7 which are arranged on both sides of the switching plunger 2. The two catch springs 7 are configured as two substantially omega-shaped spring arms and are arranged substantially symmetrically relative to the direction of movement of the switching plunger 2.
The other ends of the catch springs 7 are, in turn, each supported in a notch of a spacer 8. The two spacers 8, which are also arranged on both sides of the switching plunger 2, form together with two contact carriers 9 a contact bridge 10. Apart from connecting the contact bridge 10 to the catch springs 7 the spacers 8 serve to receive the two contact carriers 9 which run substantially parallel towards each other. The respective ends of the spacers 8 protruding over the contact carriers 8 are each formed as sliding ramps 11. The sliding ramps 11 have a flank running substantially wedge-shaped and a supporting area running substantially horizontally.
In the rest position of the snap-action switch 1 shown in
In addition, displacement limit stops 17 opposing the end faces of the contact carriers 9 are provided on the casing 3, which limit the movement path of the contact bridge 10 that runs transversely to the direction of movement of the switching plunger 2.
In terms of function the spring arrangement comprising the catch springs 7 is oriented such that when the switching plunger 2 is displaced transversely to the contact bridge 10 the contact bridge 10 snaps over when a snap-over point is exceeded. For switching the second switch position the switching plunger 2 is moved by an actuating force opposite to the spring force of the spring member 6, while the position of the catch springs 7 changes at the same time. Once the snap-over point is reached, which is predefined by the construction of the catch springs 7, the contact bridge 10 snaps over into a second switch position. In this second switch position a second contact pair 13 is connected by a contact carrier 9 and the other contact carrier 9 is spaced apart from the first contact pair 12. If the actuating force externally applied to the switching plunger 2 is interrupted subsequently the switching plunger 2 is again pushed upwardly due to the action of the force of the catch springs 7, so that finally the contact bridge 10 snaps over back into the first switch position.
The detailed view of
Number | Date | Country | Kind |
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10 2011 014 294.0 | Mar 2011 | DE | national |
Filing Document | Filing Date | Country | Kind | 371c Date |
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PCT/EP12/00381 | 1/27/2012 | WO | 00 | 9/17/2013 |