DE3414009C2 - - Google Patents

Description

The invention relates to a push button switch according to the preamble of the saying 1.

In a known push button switch of this type (US-PS 41 31 992) is a for the foot switch provided by two elastic Membra NEN built on their facing each other, at a distance from each other arranged and mutually parallel sides contact surfaces exhibit. These contact surfaces extend practically over the entire Size of pages. On one of the contact areas there are several, in comparison small rubber spacers applied to the size of the contact surfaces. This prevents the upper mat from sagging through it Dead weight a mutual contacting of the opposing Contact surfaces occurs. The introduction of individual spacers is labor-intensive and when using thin membranes, for example as 0.1 mm thick can be difficult to carry out.

The invention is based, with a push button switch according to the task Preamble of claim 1 the distance holder between the contact surfaces without additional single train parts. This task will according to the invention in the characterizing part of Claim specified means solved.

As a result, part of the membrane is advantageously as  Spacers effective.

The following is an embodiment of the invention based on the drawing explained in more detail.

A first membrane 2 , which consists of a relatively thin, elastic plastic film, lies on a relatively rigid support plate 1 . At a distance above this first membrane 2 is a further parallel membrane 3 , which also consists of elastic, deflectable Ma material. On their mutually facing sides, both membranes 2, 3 each have a contact surface 4 or 5 , which form a switching path. Several switching paths of this type can be provided next to one another in the course of the surface expansion of the membranes 2, 3 . Spacers 6 and 7 protrude in the space between the contact surfaces 4, 5 . In the present case, the spacers 6, 7 are formed from the lower membrane 2 in the region of zones in which no contact material is provided within the contact surface 4 . Since the membrane 2 is made of an electrically insulating material, contact is not possible in this area when the upper membrane 3 is depressed. The unwanted deflection of the upper membrane 3 which occurs during material fatigue, heating or due to its own weight can thus lead to no electrical connection between the contact surfaces 4 and 5 due to the action of the spacers. Of course, the upper membrane 3 can be equipped with appropriate spacers. If the spacers in the two membranes 2, 3 are laterally offset from one another, then only half of all the necessary spacers need to be molded into each film. The spacers can be shaped by thermal action on the membrane 2 and / or 3 . The individual membrane then only needs to be thermally stretched at a correspondingly reduced number of locations. However, the spacers can also face each other in the two membranes and then only need to be formed from the respective membrane 2 or 3 by half the required height. This also results in a reduced stress on the membranes 2, 3 . Are spacers 6 dome-shaped formed from the membrane 2 , then they are elastically depressible, so that when the Schaltbe actuating force is exerted in the region of a spacer 6 , this is at least partially depressed and reliable contact between the adjacent zones of the contact surfaces 4 and 5 occurs. The spacers 6 are shaped so that they stand up again automatically. However, a tab punched free on three sides can also be provided in the membrane 2 or 3 , which is bent obliquely towards the opposite membrane, as shown by the spacer 7 . In addition, the free end of the tab is bent back to the level of the membrane 2 , so that the supporting force of the spacer 7 is increased compared to a simply bent tab. This spacer also straightens up automatically and can be pushed completely back into the plane of the membrane 2 . If no areas free of contact material are provided within the contact areas 4 or 5 , then layers 9 made of electrically insulating hardening material, for example made of lacquer, can also be applied in the area of the spacers 6, 7 . This layer can be applied to the formations 6, 7 or also to flat sections of the contact surfaces 4, 5 . This results in a permissive design of contact fields, in which there is otherwise the risk that unwanted deflections of at least one membrane lead to incorrect switching. The necessary switching force can also be influenced in the desired manner by the design, in particular the height and the distance of the spacers. Since, in addition, the spacers can be part of the diaphragms, there is a particularly favorable manufacture, and when the spacers are formed, outer boundary edges 8 can also be formed for the individual switching areas. The edges 8 also formed from the membranes determine the distance between the membranes 2, 3 in the region of the contact surfaces 4, 5 . Spacer films between the membranes 2, 3 can thus be omitted and a direct connection can be made by gluing or welding.

Claims (8)

1. Pushbutton switch with spaced apart, mutually facing and parallel contact surfaces, of which at least one is provided on an elastically deflectable membrane and with at least one electrically insulating spacer in the space between opposing contact surfaces, the spacer being fixed in the region of a contact surface is arranged, characterized in that the membrane within at least one contact surface ( 4, 5 ) has a surface free of contact material, which is formed towards the opposite contact surface ( 5, 4 ). 2. Key switch according to claim 1, characterized in that both contact surfaces ( 4, 5 ) on elastic membranes ( 2, 3 ) are arranged. 3. Key switch according to claim 2, characterized in that both diaphragms NEN ( 2, 3 ) of contact material have free, shaped surfaces. 4. Key switch according to claim 2 or 2, characterized in that the shaped surfaces on the two membranes ( 2, 3 ) are laterally offset from one another. 5. Key switch according to one of claims 1 to 4, characterized in that the surfaces free of contact material as spacers ( 6 are dome-shaped. 6. Push button switch according to one of claims 1 to 4, characterized in that the surface free of contact material is punched as a free on three sides, to the opposite contact surface ( 5, 4 ) is formed obliquely bent tab. 7. Key switch according to claim 6, characterized in that the free end of the tab back to the level of the associated contact surface ( 4, 5 ) is bent out GE. 8. Key switch according to one of claims 1 to 7, characterized records that the shaped surface by a layer of electrical insulating, curing material is formed.