EP0241906A2 - Layered keyboard - Google Patents

Abstract

The membrane keyboard has a support plate with pins (11) protruding vertically from its bottom. These pins protrude through openings (22) of a coding plate (20) and beyond the surface thereof and thus form spacers for a membrane (30). They also serve to hold and align the coding plate (20)

Description

The invention relates to a membrane keyboard according to the preamble of claim 1.

Such a membrane keyboard is known from US Pat. No. 4,365,130. It has the following structure - from bottom to top:
- A support plate made of relatively hard material
- there is a thin layer of adhesive and
- Above a coding plate made of flexible, electrically insulating material.

The upper side of the coding plate has electrical switching contact surfaces and conductor tracks, which are applied in a conventional manner, for example by means of screen printing or etching technology, made of copper, silver or other conductive material. A spacer layer made of electrically insulating material is arranged above the coding plate, this layer being opposite has recesses to the switch contact surfaces. Above this is a flexible membrane, which has electrically conductive areas opposite to the cutouts on its underside. Finally there is a cover, which in turn has cutouts opposite the switch contact surfaces.

An electrical contact is made in that the flexible membrane is pressed down, for example by finger pressure, so that an electrically conductive area protrudes through the cutouts in the spacer layer and electrically connects the associated switching contact surfaces on the coding plate.

Similar membrane keyboards are also known from the following publications:
- DE-OS 30 12 717
U.S. Patent 4,405,849
U.S. Patent 4,385,215.

The use of a separate spacer film is complex. On the one hand, an additional component must be manufactured and, on the other hand, this must be precisely aligned and fixed during assembly so that it does not shift during later operation.

It has therefore already been proposed (cf. EP-A1-0 124 862, DE-OS 26 23 229, US Pat. No. 4,391,845) to apply spacers or so-called spacers directly to the coding plate instead of a spacer film, namely in In the form of printed (e.g. screen printing) insulating layers or in the form of glued-on spacers.

However, printing or sticking on spacers has the following disadvantages:
An additional step is required, which in addition to the complex alignment of a screen printing machine also entails drying or curing times. Furthermore, it is not always possible to ensure that layers of sufficient thickness are printed on during screen printing.

The object of the invention is therefore to improve the membrane keyboard of the type mentioned in such a way that it is very reliable with a simplified structure.

The functional reliability relates to the fact that incorrect contacts are prevented and that the individual components of the membrane keyboard can no longer slide against one another. Furthermore, the membrane keyboard should be easy to manufacture and assemble.

The above object is achieved by the features specified in claim 1. Advantageous refinements and developments of the invention can be found in the subclaims.

• Fig. 1 einen Querschnitt der Membrantastatur nach der Erfindung;
• Fig. 2 einen Schnitt einer Einzelheit nach einer Weiter­bildung der Erfindung;
• Fig. 3, 4 und 5 Draufsichten der Membrantastatur bei fortge­ lassener Membran zur Darstellung der Anordnung der Stifte und
• Fig. 6 eine perspektivische Ansicht einer Variante der bei der Erfindung verwendeten Stützplatte.

In the following, the invention is explained in more detail using an exemplary embodiment in connection with the drawing. It shows:

• 1 shows a cross section of the membrane keyboard according to the invention.
• 2 shows a section of a detail according to a development of the invention;
• 3, 4 and 5 plan views of the membrane keyboard at fortge let membrane to show the arrangement of the pins and
• Fig. 6 is a perspective view of a variant of the support plate used in the invention.

1 consists of only three basic components, namely a support plate 10, a coding plate 20 and a membrane 30. The support plate 10, which for example also contains the housing of an electrotechnical function group, for example the housing of a remote control transmitter for television sets, the housing of a Calculator or the housing of a dialing keypad can be made of electrically non-conductive material, such as Plastic and has pins 11 projecting perpendicularly from its base. These pins are preferably connected in one piece to the support plate. However, they can also be made as separate parts and subsequently glued, inserted, screwed, riveted, etc. The cross section of the pins 11 can be circular, square, rectangular, triangular or of any other shape.

In the exemplary embodiment in FIG. 1, the support plate 10 has side walls 15, the upper end face of which lies in one plane with the upper end face of the pins 11. Furthermore, these side walls 15 have a widening 17 at their upper end, which in turn has a bevel 16 which faces inwards, ie. H. points to the opposite side wall.

Furthermore, the membrane keyboard has a coding plate 20, the switching contact surfaces 21 and conductor tracks, not shown. The switch contact surfaces are designed in a conventional manner, for example accordingly the switching contact surfaces of US Pat. No. 4,365,130 or US Pat. No. 4,391,845. Coding plate 20 itself is made of electrically insulating material. It can also consist of a thin, flexible film. The switch contact surfaces and the conductor tracks are produced in a conventional manner, for example by etching or printing, from an electrically conductive material. The coding plate 20 has a plurality of openings 22 which are arranged such that one of the pins 11 projects through one of the openings. The coding plate 20 is inserted into the support plate 10 so that its underside rests on the bottom of the support plate. The pins 11 prevent it from slipping sideways. Furthermore, it is centered relative to the support plate.

The third assembly is the membrane 30, which consists of elastic material and is electrically conductive at least opposite to the switch contact surfaces 21 on its underside. In the exemplary embodiment of the innovation, the membrane 30 is electrically conductive on its entire underside, for example by a coating of conductive lacquer. The membrane 30 lies on the upper end face of the pins 11 and on the edges of the side walls 15. The length of the pins 11 is selected so that the pins protrude from the coding plate 20 to such an extent that they hold the membrane at such a distance above the switching contact surfaces that, on the one hand, undesired contact between the membrane and the switching contact surfaces 21 in the event of mechanical shocks are avoided, and on the other hand the membrane 30 touches the switching contact surfaces 21 of the selected switching contact by finger pressure at selected “switching points” in the direction of the arrows 32 and thus connects them electrically.

The widening 17 of the side walls 15 acts together with the bevels 16 as a snap lock, which secures the coding plate 20 against falling out.

As a further safeguard, the coding plate 20 can be glued to the support plate 10 and in particular in the area of the pins 11. In other words, an adhesive can be present between the inside diameter of the openings 22 and the outside diameter of the pins 11.

According to the development of the invention shown in FIG. 2, the pins 11 can be given a thickened head 12 by hot upsetting or ultrasonic welding, as a result of which the coding plate 20 is positively secured against falling out even in the area of the pins. Here, when manufacturing the support plate, care must be taken that the length of the pins 11 is selected such that the shortening that occurs during hot upsetting still leaves a sufficient distance between the underside 31 of the membrane 30 and the switch contact surfaces 21.

3, 4 and 5 show different variants for the arrangement of the pins 11 (and the openings 22) with respect to the switch contact surfaces 21. The switch contact surfaces are only shown as circles in these figures. However, it should be noted that any known forms of switch pads can be used here.

3 and 4, a "four-point support" is provided, ie the membrane is supported with respect to each switching contact surface 21 by four pins. Since in FIGS. 3 and 4 the switching contact surfaces 21 are arranged in rows and columns in a uniform division are, in both embodiments, the pins 11 can be arranged rotationally symmetrically with respect to the center of the switch contact surface, ie they lie on a circle, the center of which is also the center of the switch contact surface.

In the exemplary embodiment in FIG. 3, the pins 11 lie at intersections of diagonals 23 which connect the center points of diagonally adjacent switching contact surfaces 21 to one another. In relation to the row and column arrangement of the switching contact surfaces 21, the pins 11 arranged around a switching contact surface thus form a square.

The embodiment of FIG. 4 is also a "four-point support". However, the individual pins 11 lie on straight lines 24, which connect the center points of the switching contact surfaces 21 in rows and columns. Furthermore, the pins 11 lie on these lines in such a way that they lie exactly in the middle between two adjacent switching contact surfaces. The pins surrounding a switch contact surface thus also span a square, which, however, is rotated by 45 ° with respect to the squares of FIG. 3.

5 shows a “three-point support”, ie the membrane is supported by only three pins 11 per switching contact surface 21. These therefore span a triangle with respect to the respective switching contact surface 21. If the distance between the switch contact surfaces 21 in the row and column direction is the same, equilateral triangles are formed with the center of the area of the center of the switch contact surfaces.

If, on the other hand, as shown in FIG. 5, the distance in the row and column direction is different, isosceles triangles are formed, as indicated by lines 25, 26 and 27. Furthermore, the pins 11 lie on lines 26, which line by line runs exactly in the middle between adjacent lines of switching contact surfaces.

6 shows a further development of the support plate 10. This has webs 13 and 14 projecting perpendicularly from their base for the purpose of stiffening, a pin 11 each projecting upwards at the crossings of the webs 13 and 14. The coding plate is then only on the upper end of the webs. Here, too, the side walls 15 are raised, similarly to FIG. 1, so that their end faces lie in one plane with the end faces of the pins 11. The membrane is then also here on the pins 11 and the end faces of the side walls 15.

Claims (13)

1. Membrane keyboard with a support plate, a coding plate arranged thereon, which has electrical switching contact surfaces and with a flexible membrane, which is arranged at a distance opposite the coding plate and has electrically conductive areas at least opposite to the switching contact surfaces,
characterized by
that the coding plate (20) has openings (22) laterally next to the switching contact surfaces (21), through which pins (11) of electrically non-conductive material protrude, and that the pins (11) extend from the support plate (10) to the membrane (30 ) he stretch, protruding beyond the surface of the coding plate. 2. Membrane keyboard according to claim 1, characterized in that the pins (11) are integrally connected to the support plate (10). 3. Membrane keyboard according to claim 1 or 2, characterized in that the pins (11) have a thickened head (12) which laterally overlaps the associated opening (22). 4. Membrane keyboard according to claim 1 or 2, characterized in that an adhesive is present between the inner diameter of the openings (22) and the outer diameter of the pins (11). 5. Membrane keyboard according to one of claims 1 to 4, characterized in that the opening (22) and the pins (11) in the top view are arranged rotationally symmetrically to the centers of the switching contact surfaces (21). 6. Membrane keyboard according to claim 5, characterized in that the opening (22) and pins (11) are arranged in a uniform grid and in such a way that they lie on the intersection of diagonals (23) which are the centers of adjacent switching contact surfaces (21st ) connect. 7. Membrane keyboard according to claim 5, characterized in that the openings (22) and pins (11) are arranged in a uniform grid and in such a way that they lie on straight lines (24) which are the means Connect the points of the switch contact surfaces (21) in rows and columns, and the openings (22) and pins (11) also have the same distance from the centers of the immediately adjacent switch contact surfaces. 8. Membrane keyboard according to one of claims 1 to 4, characterized in that the openings (22) and the pins (11) are arranged around the respective switching contact surfaces (21) so that connecting lines (25, 26, 27) form a triangle , in which the center of the assigned switch contact surfaces (21) lies. 9. Membrane keyboard according to one of claims 1 to 8, characterized in that the support plate (10) from the bottom of vertically projecting webs (13, 14), with a pin (11) projecting above the upper edge of the webs at intersections of the webs . 10. Membrane keyboard according to claim 9, characterized in that side walls (15) of the support plate (10) lie in one plane with the upper end face of the pins (11). 11. Membrane keyboard according to claim 10, characterized in that the side walls (15) of the support plate (10) have a thickened head (17) which has a bevel (16) which inwards, ie. H. is inclined towards the opposite side wall. 12. Membrane keyboard according to one of claims 1 to 11, characterized in that the membrane (30) is electrically conductive on its entire underside. 13. Membrane keyboard according to claim 12, characterized in that the membrane (30) consists of a homogeneous, electrically conductive material.

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