DE3336878C2 - - Google Patents

Description

The invention relates to an electrical snap switch a linearly shiftable snap-action switching element, which can be moved into direction of the snap switch opposite one another Contact sets cooperates with a snap spring arrangement that in their end positions, the snap switch each at one of the con keeps clock rates in plant, and with one under the effect of a return spring-mounted slide valve, on the snap spring arrangement acts.

Such electrical snap switches are already known (DE-OS 25 26 165); there is a snap arrangement  Intermediate piece provided. You need two snap springs that are in must have a certain relationship to each other. The remains Contact pressure is essentially the same until the switchover time, however the adjustment of the snap springs is very delicate and not long-term stable.

The invention has for its object an electrical To form snap switches of the type mentioned at the outset, that a snap spring to achieve the ge desired switching behavior without changing the contact pressure up to Switchover point is sufficient. These Object is achieved according to the invention in that inner half of it push button across the direction of movement two Snap spring assembly biased wedge pieces are guided and that these wedge pieces against each other wedge profiles of the snap face the switch.

This is advantageous during the switching movement the snap spring arrangement by the we kung the wedge pieces until the dead center position is enough. This extra tension can help increase contact pressure used in the switching process or by stops for the snap-action switch can be compensated. In any case, this leads additional tension immediately after reaching the dead center a sudden switchover. It is only at the moment of Interruption of the contacts when switching the contact pressure raised. The contact pressure will not decrease until then.

There are also advantages if  the wedge pieces guided in a common transverse channel of the slide switch and are biased by a single compression spring. This gives you a particularly symmetrical arrangement in which the switching loads can be absorbed evenly by the construction.

It is useful if on the wedge pieces of the key the wedge surfaces have a lower inclination to the movement direction of the slide switch as the wedge surfaces on the wedge professional len of the snap switch. This way you get a constant Switching behavior, because always the cutting of the splines slide the wedge surfaces of the wedge pieces. The friction becomes low held.

An embodiment of the invention is hereinafter referred to Taking explained on the drawing in which represents

Fig. 1 shows a section through the snap switch and

Fig. 2 shows a section along the line II-II in FIG. 1.

The drawing shows an electrical snap switch, which has a snap-action switch 2 in a housing 1 , which can be moved in a straight line. The guides for the snap switch 2 and also for the other switch parts are not shown. The snap-action piece 2 is designed as a U-shaped bridge with two opposing legs, which have wedge profiles 4 facing each other at their ends.

The snap-action switch 2 carries a switch bridge 3 with contact coverings 5, 6 , which are shown schematically in the drawing. The switch bridge 3 is ge with turns on the snap switch 2 hold. The contact linings 5 and 6 are opposed to housing-fixed contact linings or contact sets 7 and 8 . The contact pads 7, 8 in the housing 1 form the stops for the snap-action switching element 2 . One can also hen on the snap-action switch 2 itself, not shown, stop lugs, which define the end positions, and form the contact sets 7 and 8 resiliently, so that the contact pressure is predetermined by the resilient support of the contact pads and is not influenced by the displacement of the snap-action switch 1 .

A push slide 9 engages with an annular wall 15, the housing 1 . Cutouts 16 of the ring wall 15 snap into stop lugs 17 , which also limit the movement of the slide switch 9 . The key slide 9 cooperates with a return spring 10 . The tactile slide 9 can be designed to be latching or non-latching. The Rastvor directions are not shown in the figures.

Transversely to the direction of actuation 11 of the slide valve, a Querka channel 12 is formed, in which two wedge pieces 13 are guided. The wedge pieces 13 are biased by a single compression spring 14 . The strikes for the wedge pieces 13 are also not shown in the drawing. The wedge pieces 13 can have a larger wedge angle than the wedge profiles 4 of the snap-action switching piece 2 . As a result, the wedge surfaces of the wedge pieces 13 have a lower inclination with respect to the direction of movement 11 than the wedge surfaces of the wedge profiles 4 .

Fig. 1 shows the one switching position of the snap switch. In this position, the push-button slide 9 bears against the stop lugs 17 , so that the compression spring 14 presses the snap-action switch 2 downward via the wedge surfaces. Consequently, the contact pads 5 of the snap contact with the contact pads 7 of the housing 1 are engaged.

The changeover is initiated by pushing the slide switch 9 in the actuating direction 11 . The Keilflä surfaces of the wedge pieces 13 slide onto the corresponding wedge surfaces of the Keilpro file 4 . Due to the displacement along the wedge surfaces, the wedge pieces 13 are pushed against each other during this switching movement and compress the compression spring 14 . As soon as the cutting edges of the wedge pieces 13 and the wedge profiles 4 are one above the other, the dead center position is reached. In this position, the compression spring 14 is maximally compressed or tensioned. The contact pressure rises until then if it is not caught by a stop for the snap-action contact. When the dead center position is exceeded, the compression spring 14 is relieved and the snap-action switching element snaps over. The compression spring 14 presses the wedge pieces 13 apart so that the cutting edges of the wedge profiles 4 slide into the switch position on the opposite wedge surfaces thereof, in which the contact pads 6 of the snap-action switch 2 are in engagement with the contact pads 8 of the housing 1 .

During the switching movement, the compression spring 14 is therefore initially tensioned. The contact force is increased until the dead center is reached. However, this increase in the contact force can also be intercepted by a stop on the snap-action switch, not shown. After the dead center is reached, there is a sudden relief of the compression spring, so that the snap-action piece 2 snaps. It is only when the snap movement is initiated that the contact pressure on the contact linings previously in engagement with one another is released.

Claims (3)

1.Electric snap switch with a linearly displaceable snap-action switch, which interacts with contact sets that protrude in the direction of movement of the snap-action switch, with a snap-spring arrangement that holds the snap-action switch in their end positions on one of the contact sets, and with one under the effect of one Return spring standing slide valve, which acts on the snap spring arrangement, characterized in that within the push slide ( 9 ) transversely to the direction of movement two wedge pieces ( 13 ) biased by the snap arrangement are guided and that these wedge pieces ( 13 ) are directed against each other wedge profiles ( 4 ) of the Face the snap contact ( 2 ). 2. Electrical snap-action switch according to claim 1, characterized in that the wedge pieces ( 13 ) in a common transverse channel ( 12 ) of the push slide bers ( 9 ) and are biased by a single compression spring ( 14 ). 3. Electrical snap switch according to claim 1 or 2, characterized in that on the wedge pieces ( 13 ) of the push button ( 9 ), the Keilflä surface has a lower inclination with respect to the direction of movement of the push button ( 9 ) than the wedge surfaces on the wedge profiles ( 4 ) the snap contact ( 2 ).