DE9012407U1 - Pressure switch element - Google Patents

Description

The invention relates to a pressure switch element made of at least two carrier material layers arranged at a distance from one another, which are coated with an electrically conductive coating on at least one side and have an elastic spacer between the electrically conductive layers facing one another, wherein the electrically conductive layers touch one another in a contact area when the upper flexible carrier material layer is subjected to pressure.

Such pressure switch elements are known as touch panels in display screens. The touch panels consist

15 usually made of transparent plastic films, the inner surfaces of which are coated with an electrically conductive coating. To support these films, spacers are glued into the air gap, with a spacer running around the outside of the contact area providing airtight

20 is welded to the plastic foils to stabilize the internal air pressure and thereby

Telephone: (02 21) 131041 Telex: 888 2307 dopa d Fax: (02 21)134297 (0221)134881 Telegram: Dompatent Köln

Accounts:

3al. Oppenheim jr, & Cie., Cologne (bank code 370 302 00) Account no. 10 [Deutsche Bank AG, Cologne (bank code 370 700 60) Account no. 1165 Postgiro Cologne (bank code 37010050) Account no. 654-500

supports the upper foil. Elastic spacers are also arranged within the contact area to ensure that the foils return to their original position. The known pressure switch element has the disadvantage of requiring a hermetically sealed air space that does not allow pressure equalization. In the case of significant deviations from normal atmospheric pressure, e.g. when used in underwater vehicles or in aerospace, and at high temperatures, the changes in air pressure cause hairline cracks in the vapor-deposited electrically conductive contact layer, which leads to a malfunction. At high altitudes, the spacer in the contact area expands. This changes the switching path of the contact foil and the specified electronic and mechanical parameters, such as the pressure point, are not maintained. Other disadvantages of the known touch panels are that the plastic foils have only limited mechanical and chemical resistance and are not antistatic. In the event of large temperature fluctuations, there is also a risk of cracks forming in the electrically conductive layer due to significantly different expansion coefficients between the conductive layer and the plastic carrier.

The invention is based on the object of creating a pressure switching element whose functionality is reliably guaranteed even in the event of high pressure and temperature fluctuations.

To solve this problem, the invention provides

that the carrier material is made of glass,
that one carrier material layer consists of a thin cover plate and the other carrier material layer

consists of a thick carrier disc and
that the spacer consists of an intermediate layer made of elastic plastic.

The use of an elastic intermediate layer between a carrier plate made of relatively thick glass and a cover plate made of relatively thin glass advantageously makes it possible to create a pressure switch element made of glass that can be actuated without breaking the glass.

Due to the natural recovery behavior of the cover plate made of relatively thin glass, no spacer is required. The elastic spacer in the area surrounding the contact area can be reduced in size so that a film is sufficient as an intermediate layer. The use of glass as a carrier material also has the advantage of creating a scratch-resistant pressure switch element that has a high chemical resistance and is antistatic. The temperature expansion coefficients and the deformation behavior under pressure of glass and electrically conductive layer show a smaller difference compared to plastic films, so that the risk of cracks forming in the electrically conductive layer is significantly reduced.

Preferably, the ratio of the carrier disk thickness to the cover disk thickness is approximately 8 to 16, preferably 12. With this ratio, sufficient elasticity can be achieved for the cover disk and sufficient rigidity for the carrier disk.

In a preferred embodiment, the cover plate has a thickness of approximately 0.3 mm to 0.7 mm, preferably 0.5 mm. Such a cover plate thickness is suitable for creating a shatter-proof pressure switch element for manual actuation.

The elastic intermediate layer can be kept open on at least one side to equalize pressure. In this way, the actuation of the pressure switching element is independent of the atmospheric pressure conditions. The reset of the pressure switching element occurs solely due to the elasticity of the glass carrier material, if necessary with the support of the elastic spacer.

The carrier and/or cover plate can be thermally or chemically hardened. This increases the pressure stability of the glass pressure switch element.

In a further development of the invention, it is provided that the edge area of the carrier and cover plate is sealed with an edge cover.

Preferably, the edge cover is provided with ventilation openings that allow pressure equalization with the environment.

A filter material can be arranged between the carrier or cover plate and the edge cover. This filter material, which is incorporated into the back of the edge cover, protects the pressure switch element from contamination.

In addition, a dehumidifying agent, e.g. silica gel, can be placed between the carrier or cover plate and the edge cover. This dehumidifier protects against corrosion of the electrically conductive layers.

In one embodiment, it is provided that the intermediate space is hermetically sealed via the intermediate layer in the contact area. In this case, passages to the intermediate space can be arranged in the carrier disk, which enable pressure equalization. Such a pressure switching element is suitable for use in aggressive environments, e.g. in high humidity.

In a further embodiment, it is provided that the electrically conductive layers have an insulating interruption in the edge area when there is central contact. The interruptions serve to prevent corrosion of the electrically conductive layers at the adhesive edge of the elastic intermediate layer due to water vapor diffusion, which can lead to the destruction of the switching matrix. The circumferential insulating interruption preferably has a width of approximately 150 to 500 μιλ.

The carrier disk can be concavely curved in relation to the cover disk in the contact area. Such a design of the carrier disk is advantageous for a hermetically sealed pressure switch element, whereby the curvature is in a certain ratio to the air volume

3Q of the system.

In a further development, it is provided that the carrier disc is positioned below the contact area on the

■" 6 ■■

Cover plate has illuminated blind holes on the side opposite. The blind holes can be illuminated with a lateral or vertical light source, whereby an illuminated switch marking is created due to the refraction of light on the inner walls of the blind hole.

In the following, embodiments of the invention are explained in more detail with reference to the drawings. 10

a cross-section through the pressure switch element,

Fig. 2 a cross section through the pressure switch element

according to Fig. 1 when pressure is applied to the cover plate,

a second embodiment with concave
curved carrier disc,

Fig. 4 an embodiment with ventilation openings provided in the edge seal,
the application of pressure switch elements in a display panel,
a cross section through a carrier disc

with two pressure switches and

another embodiment.

The pressure switch element 1 consists of a lower, relatively thick carrier disk 12 and a cover disk 14 made of glass running parallel to it and at a distance from the carrier disk 12, between which an intermediate layer 10 preferably made of a polyvinyl butyral film as

It show Fig . 1 Fig . 2 Fig . 3 Fig . 4 Fig . 5 Fig . 6 Fig . 7

Spacer 6 is arranged. A double-sided adhesive, preferably transparent tape can also be used as the intermediate layer 10. The intermediate layer 10 leaves a contact area 22 free between the carrier disk 12 and the cover disk 14, which in plan view can preferably be circular but can also be designed differently, e.g. rectangular or square.

The carrier disk 12 and the cover disk 14 are provided with electrically conductive layers 2, 3 on the inner surfaces facing each other, which enable a switching process when they come into contact. To this end, as can be seen from Fig. 2, the relatively thin cover disk 14 can be pressed in by applying pressure in the contact area 22 until the electrically conductive layers 2, 3 come into contact. With a cover disk 14 with a thickness of approx. 0.5 mm and a carrier disk 12 with a thickness of approx. 6 mm, the thickness of the intermediate layer 10 is 0.3 to 0.5 mm, preferably approx. 0.38 mm.

It is essential that the intermediate layer 10 forming the spacer 6 is elastic and thus reduces the risk of glass breakage in the thin cover pane 14.

The intermediate layer 10 has a passage 30 to the outside, so that when the pressure switch element 1 is actuated, a pressure equalization can take place in the space of the contact area 2Q.

For additional pressure stability of the pressure switching element 1, the carrier and cover plates 12,14 can be thermally or chemically hardened.

If the intermediate layer 10 hermetically seals the gap 4 in the contact area, the carrier disk 12 is preferably concavely curved relative to the cover disk 14, as can be seen from Fig. 3.

In the embodiment of Fig. 4, an edge cover 16 is shown for the pressure switch element 1, which can consist of an edge cover strip, for example. The edge cover strip has ventilation openings 18, which in conjunction with one or more passages 30 enable pressure equalization in the intermediate space 4 in the contact area 22.

Between the edge cover strip, which encompasses both the carrier and cover disk 12,14, and the pressure switch element 1, a strip-shaped filter material 20 can additionally be introduced, which covers the ventilation openings 18 and the gap between the carrier and cover disk 12,14.

Instead of the filter material 20 or in addition to the filter material, a dehumidifying agent can also be provided between the cover strip and the pressure switch element 1, which protects the electrically conductive layers from corrosion.

The pressure switch element 1 is preferably used in glass surfaces in front of display devices, eg screens, where it can be used eg for a freely _programmable menu selection.

As a larger-area pressure switch element in digital design, one or more pressure positions

—» Q —

within the contact area using an X-Y matrix in the electrically conductive layer.

The pressure switch element 1 can also be colored by tinting the carrier and/or cover plate 12, 14 or the contact area 22.

In order to avoid double reflection of the preferably transparent pressure switch element 1 in front of a glass surface of the display surface, the outer surfaces of the carrier and cover plate 12, 14 are preferably additionally anti-reflective with vapor-deposited layers or etched surfaces.

As can be seen from Fig. 6, the carrier disk 12 can have blind holes 24 on the side opposite the cover disk 14, which are illuminated by a light source 26 arranged laterally and/or under the carrier disk 12. The refraction of light on the inner walls of the blind holes 24 creates an illuminated pressure point marking in the contact area 22 in the transparent glass surface of the pressure switch element 1.

For use in aggressive environments, e.g. in high humidity, the elastic intermediate layer 10 is made airtight. The required pressure equalization in the pressure switch element 1 is achieved by at least two openings 32 in the rear carrier disk 12. These openings 32 can also consist of elongated holes and are also used to carry out the

Contact connections on the electrically conductive surfaces 2,3. Ventilation can be carried out through a filter material 2 0 in a similar way to the passage 3 0.

To avoid corrosion of the electrically conductive layers 2,3 at the adhesive edge of the elastic intermediate layer 10 due to water vapor diffusion at the critical point 34, which leads to the destruction of the switching matrix, the conductive layer 2,3 is protected in the edge area by an insulating interruption 35 with a width of approximately 150 to 500 μm when the electrically conductive layers 2,3 are contacted in the middle.

Claims (18)

Expectations 1. Pressure switch element made of at least two carrier material layers arranged at a distance from one another, which are coated with electrical conductivity on at least one side and have an elastic spacer between the electrically conductive layers facing one another, the electrically conductive layers touching one another in a contact area when the upper flexible carrier material layer is subjected to pressure, characterized , that the carrier material layers (8) consist of glass, that one carrier material layer (8) consists of a thin cover plate (14) and the other carrier material layer (8) consists of a thick carrier plate (12) and that the spacer (6) consists of an intermediate layer (10) made of elastic plastic. 2. Pressure switch element according to claim 1, characterized in that the ratio of the carrier disk thickness to the cover disk thickness is approximately 8 to 16, preferably 12. 3. Pressure switch element according to claim 1 or 2, characterized in that the cover plate (14) has a thickness of approximately 0.2 to 0.7 mm, preferably 0.5 mm. 4. Pressure switch element according to one of claims 1 to 3, characterized in that the elastic intermediate layer (10) has a passage (30) on at least one side for pressure compensation. 5. Pressure switch element according to one of claims 1 to 3, characterized in that the intermediate space (4) in the contact area (22) is hermetically sealed. 6. Pressure switch element according to claim 5, characterized in that in the carrier disk (12) at least two passages (32) to the intermediate space (4) are arranged. 7. Pressure switch element according to one of claims 1 to 6, characterized in that the carrier and/or the cover plate (12, 14) are thermally or chemically hardened. 8. Pressure switch element according to one of claims 1 to 7, characterized in that the edge region of the carrier and cover plate (12, 14) is sealed with an edge cover (16). 9. Pressure switch element according to claim 8, characterized in that the edge cover (16) is provided with ventilation openings (18). 10. Pressure switch element according to claim 8 or 9, characterized in that a filter material (2 0) is arranged between the carrier or cover plate (12, 14) and the edge cover (16). 11. Pressure switch element according to claim 8 to 10, characterized in that a dehumidifying agent, e.g. silica gel, is arranged between the carrier or cover plate (12, 14) and the edge cover (16). 12. Pressure switch element according to claims 1 to 11, characterized in that the carrier and cover disks (12, 14) are transparent. 13. Pressure switch element according to claims 1 to 12, characterized in that the elastic intermediate layer (10) consists of a polyvinyl butyral film. 14. Pressure switch element according to claims 1 to 13, characterized in that the carrier disk (12) is concavely curved relative to the cover disk (14) in the contact region (22). 15. Pressure switch element according to claims 1 to 14, characterized in that the carrier material layers (8) are anti-reflective. 16. Pressure switch element according to one of claims 1 to 14, characterized in that the carrier disk (12) has illuminated blind holes (24) below the contact area on the side opposite the cover disk (14). 17. Pressure switch element according to one of claims 1 to 16, characterized in that the electrically conductive layers (2, 3) have an insulating interruption (35) in the edge region when there is a central contact. 18. Pressure switch element according to claim 17, characterized in that the channel-shaped interruption (35) has a width of approximately 150 to 500 μm.