DE2106732C3 - Electric membrane keyboard - Google Patents

Description

This invention relates to an electric membrane keyboard, particularly in a miniaturized form with a high packing density of the insertion points, with at least one on a base made of insulating material lower contact element and at least one upper contact element at a distance above it is attached to the underside of a membrane on one of the Underlay located in the area of the contact elements in each case a hole-having insulating intermediate layer rests and in the case of the membrane an actuating device acting on this is provided

Such known electric keyboards, which are provided with a membrane switching system, have except for the well-known advantages, e.g. B. that they are only one require low actuation force and a small actuation stroke or switching path, have small dimensions and only a few components and also are inexpensive to manufacture, also disadvantages. Especially when these well-known keyboards come in very small Dimensions are made so that they have a large packing density of Eintastbzw. Have switching points, there is the possibility of that when a one-touch cell is actuated, an adjacent switching point also closes briefly, so that result in undesired switching operations.

This electrical membrane keyboard according to the invention is a substantial improvement of such a keyboard Switching systems aims in that the above-mentioned malfunction can no longer occur; also will yet further miniaturization of such keyboards is achieved so that in a conventional keyboard format compared to the known designs, a multiple number of insertion points can be accommodated can.

Membrane keyboards contain pressure actuatable electrical switch assemblies. A preferred one The type of design that is commonly used as an input station in data processing systems has been implemented by the American patent 33 08 253 known The membrane switch system described there to be actuated by compressive force basically has the following, briefly Structure described: On an approximately 1.5 mm thick base made of stable insulating material is a perforated, also made of insulating material, for example 0.1 mm thick, non-deformable intermediate layer arranged through the thickness of the distance of the open contacts is determined. The elastic membrane layer rests on this intermediate layer on, which can consist of an approximately 0.10 mm thick polyester film. In the perforations or holes in the intermediate layer, the contact switching points are

len formed at these switching points each other opposite sides of the backing layer and the membrane are copper-plated and covered with a thin Gold plating, which makes contact elements result. Depending on the design of the pressure-sensitive switch, by arranging one or more Contact elements in the switching points is the gold plating directly with the printed conductor connections connected, or it can appear as a contact strip over the underside of the membrane and / or the top of the ι ο Extend the underlayer. The upper and the lower The contact element of a switching or contact point is only slightly separated from one another in its rest position by the intermediate layer. Chen switch is made by the action of a compressive force on the elastic membrane at the location above the Switching point, as a result of which it is pressed into the hole in the intermediate layer until the upper contact element touches the lower contact element

So far, the actuation of the pressure-sensitive switch was made manually by pressing pointed objects or by resiliently preloaded stempeiförmige pressure pieces, the z. B. at the stop a button are released and exert a shock pulse on the membrane through their spring force. To protect the thin membrane and the sensitive conductor tracks that serve as contact elements and which are attached to the underside of the membrane, before overstretching has been over the membrane a arranged elastomeric protective layer on which the pressure actuator acted initially. The shock pulse is somewhat cushioned in this protective layer, which is somewhat softer than the membrane, and from this to the Transfer membrane. In some applications, the protective layer also serves the purpose of a To effect reduction of the stop operating stroke to the operator z. B. at one Keystroke to convey the feeling that a switching operation has been triggered. While the way of the -to movable contact element corresponds approximately to the thickness of the separating intermediate insulating layer, approx. 0.1 mm as mentioned above, the distance of the actuator can be designed to be larger be about 0.5 to 2 mm, depending on the thickness and elastic deformability of the material above the Has membrane lying protective layer. This means that the contact elements open quickly and that a certain contact distance is maintained, even over longer periods of time is guaranteed, it is useful if the insulating intermediate layer consists of a hard, dimensionally stable material. With such switches contamination of the conductive contact surfaces by dust is largely excluded. One possibly Small amounts of contamination, which can form as a thin film over the contact surfaces, are broken through during the closing process when the contact surfaces are touched. Instead of individual switching elements in the design described above, the compact units with several switching points can be combined, bo these are preferably as complete keyboards each made with a single base layer, intermediate layer, membrane and protective layer, whereby the contact elements are designed as printed or etched conductor tracks that are very close to each other lie.

For keyboards that are used, for example, to enter characters in one of the Asian languages, a large number of touch-in points required. If a key is assigned a character, For a keyboard with Japanese characters, around 2500 to 6000 individual keys would be required Keyboard are manufactured in the usual, known manner, so this would be impractical occupy a large area. The avenging of a keyboard is ultimately determined by the reach of the arms of the keyboard Operator limited In order to accommodate this large number of keys in a given area, one is forced to reduce the size of the Make the size of the individual push-in or switching points and the distances between them reduce to a minimum. Since the signs also look very similar to one another, it is with the large number expedient that the individual input positions each can be identified by the symbol assigned to them on their surface. However, this must Marking can also be kept small, so you choose a compromise between legibility characters identifying these keys and the distance between the keys.

With a keyboard for 3600 characters, an area of 6x6 mm is provided for one key pad, the pure area of a push-button or switching point is 4.2 χ 4.2 mm and the distance between two such input points is thus limited to only 1.8 mm in such a miniaturized keyboard the individual insertion points are either opened with a hand-held push pin or with a the fingers on the short actuating pin struck. Such miniaturized keyboards, the one Have a high packing density at input points, are expediently as membrane keyboards produced with the electrical pressure switches briefly described at the beginning Except their simple Construction, which allows a compact design, these keyboards still have the advantage that they with Stop only need a small actuation force. However, with a miniaturized keyboard, in which the individual push-in or switching points are arranged in a high packing density in the manner of the construction mentioned at the beginning, the disadvantage the so-called "crosstalk" "crosstalk" or a mutual influencing of neighboring switching points Or explained in other words: If a push-in point is pressed by a pressure or actuating pin, then there is only very little Distances of the switching points from each other the possibility that one or more of the directly close neighboring switching points in an undesirable manner, which results in incorrect switching. the The cause of the undesired incorrect switching is to be found in the fact that from the key-in point to the damping point Protective layer also compressive forces as tension waves on the membrane to the neighboring switching points be transmitted. In the case of the known membrane keyboards, therefore, none of the switching points just open this limited force achieved, but a diffuse force distribution.

It is therefore an object of the invention to provide an improved membrane keyboard with a Actuating mechanism through which the guarantee is given that when a key point is hit, none of the closes neighboring switching points and thus avoids the risk of undesired crosstalk is. This new operating mechanism should be designed so that it can be used in both

voltages that have only a few switching points, as well as keyboards with a very high packing density of the Insertion points is applicable. Further requirements are that the actuating force introduced can reliably close one or more mutually isolated contact points of a switching point without whose contact elements are overstressed and damaged in long-term operation.

This object is achieved according to the invention in that the actuating device for each insertion point contains an elastic plunger which is assigned above the switching point and the membrane and which is located in the opening a guide plate arranged above the membrane is freely movable in the vertical direction that its the lower surface opposite the membrane is smaller than the associated hole in the intermediate layer and that an elastic member is provided which resets the plunger into its rest position.

The membrane keyboard according to the invention can be used particularly expediently and advantageously in such electric keyboards which have a large packing density of key-in points. Such an improved keyboard has the following structure in principle: On an electrically insulating carrier plate there is a pattern of electrical conductor tracks which have areas that serve as stationary lower contact elements. At least one contact element of this type is assigned to each insertion point. There is an insulating intermediate layer on the carrier plate and the line pattern, which should expediently consist of a dimensionally stable, non-compressible material. At the intended switching points, the intermediate plate is provided with holes that are aligned with the lower contact elements. Above the intermediate plate, the membrane is arranged, which also has a pattern of conductor tracks on its underside, which contains the upper contact elements of the switching points. The intermediate layer separates the lower and upper contact points from one another and their holes lie one above the other. A guide plate is arranged above the membrane and has openings which are located above the holes in the intermediate plate. In each of the openings of the guide plate a plunger is inserted, which consists of an upper thick part, freely movable in the guide opening, and a lower, thinner part, this delimiting the switching points and lying on the membrane above the upper contact elements in particular, the lower part consists of an elastic material. A sheet-shaped marking plate made of elastic material lies on the guide plate and over the plungers. This identification plate serves firstly as a protective layer to prevent dust or dirt from penetrating the openings in the guide plate, and secondly as nomenclature, ie it is provided with the symbols identifying the switching points below at the points above the tappets. Expediently, there is also a perforated, stable cover plate on the marking plate, which has openings at the touch-in points which lie above the switching points. In these openings, which limit the actuation area of a key-in point and which serve to guide the actuation pin, the pressure or actuation pin is inserted during the so-called keystroke and a slight pressure is exerted so that the shock and the membrane move downwards, whereby the Establish a contact connection between the upper contact elements and the lower contact elements of this switching point.

Further details about the structure, the structural features and details of the membrane keyboard according to the invention are described in detail below in an exemplary embodiment with reference to four figures. The figures show on a greatly enlarged scale:
F i g. 1 is a plan view of the operating side of part of the membrane keyboard according to the invention,

F i g. Fig. 2 is a partial sectional view taken along line 2-2 in Fig. 1;

3 is a plan view of a section through the keyboard along the line 3-3 in F i g. 2 and

4 shows a detail of a vertical sectional view a push-in point and switching point that is actuated by a push pin.

In Fig. Fig. 1 is an enlarged plan view of part of the operation side of a miniaturized keyboard shown, the dimensions of which have in fact been chosen so that they are suitable for the characters of languages such as Japanese or Chinese, which require a keyboard with 2500 to 6000 character keys, is suitable. As was already mentioned at the beginning, with such a keyboard for a key field is approximately an area of 6x6 mm provided, the pure area dimension a push-in or switching point 4.8 4.8 mm and the distance between two adjacent ones Insertion points is limited to 1.8 mm

In the in F i g. The sectional view shown in FIG. 2 through the keyboard, the lower part in FIG. 2 is essentially formed by a known membrane switch, as already disclosed in American patent 33 08 253 and briefly described in its structure at the beginning; In this embodiment, however, the elastomeric protective layer usually lying over the membrane is missing. Such a membrane switch consists of a carrier plate 10, on one surface side of which a pattern of electrical conductor tracks is arranged, which also contains the lower contact elements 12 and 12A. Due to the lower contact elements 12, 12Λ lying next to one another at a small distance , it is possible to create several, in this case 2 separate contact points at one switching point of a push-in point. These two contact points can belong to different circuits of a circuit arrangement, but can also be combined again into a single contact switching point, depending on how the circumstances require. 3, which shows a plan view of the line pattern of the membrane switch, shows the routing of the individual conductor tracks and the arrangement of the contact elements. On the carrier plate 10 lies an intermediate layer 14 of preferably non-compressible insulating material, which has holes at the switching points provided. On this intermediate layer 14 lies a membrane 18, the underside of which also has a pattern of electrical conductor tracks

wi is provided which contains the upper contact elements 20 and 20Λ, which are placed so that they are able to produce electrical contact connections with the lower contact elements 12 and 12Λ. There are thus two pairs of contact elements at the switching point.

6th planned. The membrane switch structure described so far is known and the most essential one The difference between the known and the conventional version lies in the actuation mechanism.

nism for the membrane keyboard. While an elastomeric damping protective layer extending over all touch or switching points is arranged over the membrane in the known design, an elastic plunger is used instead in the design according to the invention for each touch point. The carrier plate 10 can be a copper-clad glass or a paper-filled epoxy laminate and have a thickness of about 1.5 mm. The line pattern arranged on this carrier plate 10 can consist of a thin deposited copper layer from which the desired line pattern has been etched out. The insulating intermediate plate 14 can consist of a 0.03 to 0.15 mm thick polyester film, depending on the present requirements. Such insulating polyester films are known, for example, under the trade name Mylar. (Mylar is a trademark of Dupont.) The membrane 18 can also consist of a polyester film which is approximately 0.05 to 0.15 mm thick and which is provided on its underside with a thin deposited copper layer, from which the conductor pattern passes a photochemical process or by etching. The contact elements 12 A, 12 V, 20 and 20Λ in the switching points are expediently formed from a thin gold layer in order to get good, reliable contact transition connections.

The plungers 22 arranged above the diaphragm 18 at each input point can have a cylindrical shape and consist of an upper, thicker part 22A and a lower, thinner part 22S . The dimensions are chosen so that the upper part 22/4 has a diameter D and an equally large or slightly smaller height and the lower part 223 has a diameter somewhat equal to V2 D.

In a practical example, for example, the total height L of the plunger 22 (the sum of the heights of the upper part 22Λ and the lower part 22ß) is approximately equal to D, where D is approximately 4 mm. In a tappet 22 , the two parts 22A and 22ß can form a whole with one another and are made of an elastomeric material, such as, for. B. neoprene, exist and be relatively hard (hardness value 60 - 80 Shore according to the Α scale). However, the upper portion 22A need not be made of elastomeric material. The plungers 22 are freely guided in the openings of a guide plate 24 and can move freely in the vertical direction therein. The guide plate 24 is expediently made of a solid, stable plastic casting with good dimensional accuracy, for. B. made of polycarbonate resins. On the underside of the guide plate 24 , a retaining disk 26 is attached to hold the plunger 22 , which is also made of a plastic, for. B. Mylar, in a thickness of about 0.13 to 0.25 can now exist. This retaining disk 26 is glued to the guide plate 24 and, in addition to serving as a support for the plunger 22, it also serves as a guide part when the keyboard is being assembled and disassembled.

Corresponding to the number of insertion points provided, the guide plate 24 and the holding disk 26 are provided with the same number of openings, but of different sizes. The larger openings in the guide plate 24 accommodate the upper, thicker parts 22A of the tappets 22, and the lower thinner parts 22S of the tappets 22 penetrate the smaller openings in the retaining disk 26. The rigidity of the membrane 18 is selected so that it supports the tappets 22 can mechanically fully bear. The weight of a plunger 22 is approximately 0.1 g, while the weight required to actuate a switching point is approximately 20 to 30 g.

On the guide plate 24 there is an elastic label plate 28 which is provided with a corresponding symbol assigned to the switching point at each of the key-in points. These characters can be embossed or printed. The designation plate 28, which is made of an elastomeric material, e.g. B. polyurethane, has a layer thickness of about 0.4 to 0.5 mm. This designation plate 28 serves as a protective cover for the actuating device formed from the plungers 22, guide plate 24 and retaining disk 26, in order to prevent the ingress of dust or dirt; it also acts as a further elastic element when actuated the keyboard. A labile cover plate 30 is arranged on the designation plate 28, which also has openings at the touch-in points, the size of which is selected so that the characters on the designation plate 28 underneath can be easily recognized. The cover plate 30, which can consist, for example, of an approximately 0.4 mm thick sheet metal, holds the designation panel 28 firmly in its position and also prevents unintentional, accidental actuation of the keyboard if, for example, the operator inadvertently leans on the keyboard or if a Object is placed on the surface of the keyboard. In the idle state there is normally an air gap of approximately 0.10 to 0.25 mm between the identification plate 28 and the top of the plunger 22.

The F i g. 3 is a sectional view taken along line 3-3 of FIG. 2. This shows the arrangement of the lower contact elements 12 and 12/4 on the carrier plate 10 and the upper contact elements 20 and 20A on the underside of the membrane 18. Width of the two contact elements 20 and 20Λ is chosen so that it is equal to or greater than the diameter of the lower part 22S of the plunger 22 , ie a projection of the lower plunger part 22ß covers at least part of the width of both contact elements. From FIG. 3 also shows the symmetrical arrangement of the two pairs of contact elements in relation to the central axis of the plunger. 3 also shows the arrangement and relative size of the openings in the intermediate layer 14. These openings are preferably chosen so large that the intermediate layer 14 rests on the contact elements 12 and 12/4. The openings can be of any convenient shape, but preferably they will be circular.

From FIG. 4 shows the states when a key is pressed. A rigid actuating pin 32 is passed through an opening in the cover plate 30 and presses the elastic labeling plate 28 downwards somewhat, which deforms at this point, bridges the air gap and forces the plunger 22 downward in the vertical direction in the opening of the guide plate 24 freely movable plunger 22 moves downwards and its lower plunger part 220 deflects the membrane 18 through the hole in the intermediate plate 14 so far down that the contact elements 20 and 20Λ arranged on their underside on the stationary counter-contact elements 12 and 12A rest and establish the contact connection of this actuated switching point. When the lower tappet part 223 is pressed down against the diaphragm 18, it is deformed by its elastic property and widens outward in its lower part. In

809645/102

In this operating state, the ratio of the diameter of the lower tappet part 223 under pressure to the diameter in the rest position is more than 1.

When considering the mode of operation of this device according to the invention it can be seen that the same force distribution function is exercised by the plunger 22 as by the protective or cover layer lying on the membrane in the known membrane switch according to the American patent 33 08 253 mentioned at the beginning In the case of the elastic plungers 22, a selective force application to only a limited switching point takes place. The identification plate 28 works together with the plunger 22 as a shock absorber against overload when a key is pressed by pressing the operating handle 32 with excessive force. One impact! 22, the load is distributed over a relatively large area of the contact elements 12,12 / 4 and 20, 2OA, when the external load increases, so does the area of contact between the membrane 18 and support plate 10 moves to and thereby reduces the contact resistance of the contact points. The relatively thick elastic plunger 22 hardly deforms due to the shape of the fixed actuating pin 32, so that no localized stress which could damage the diaphragm 18 is generated. The restoring force resulting from the deformation of the membrane 18 when a key is struck must overcome the small series that exists between the freely guided plunger 22 and the guide plate 24. To reduce this friction, the plunger 22 can be provided with a lubricant, or its lower part 22B can consist of a silicone-filled neoprene material. In order to maintain their free mobility in the guide openings, the plungers 22 should consist of an elastomeric material that does not absorb water or moisture or swells due to such effects.

From the above description it can be seen that with the membrane keyboard according to the invention a reliable one thanks to the new actuation device

ίο switching point is generated at each insertion point, whereby the switching point can consist of several individual, separate contact points and that despite the very close insertion points there is no mutual influence of the adjacent switching points. The active surface of the membrane of a switching part is relatively large compared to the distance between the individual insertion points, and the deflection movement of a plunger 22 is completely isolated from the adjacent insertion point and therefore does not affect it. The plunger 22 concentrates the actuating force exerted at the stop on the contact elements of this selected switching point only, resulting in a strictly localized deflection of the membrane 18 on the associated contact area, as can be seen from FIG. 3 can be seen. With this membrane keyboard according to the invention, the problem of undesired incorrect switching is solved, as is possible when using the known membrane switches, where adjacent contacts are caused by stress waves in the elastomeric cover layer

keys that are not pressed can close.

For this purpose 2 sheets of drawings

Claims (9)

Patent claims: 1. Electric membrane keyboard, especially in a miniaturized version with high packing density of the keypad, in which s made of insulating material at least one lower contact element and at least one upper contact element at a distance Contact element is attached to the underside of a membrane, which is on a pad located, in the area of the contact elements each having a hole, the insulating intermediate layer rests and in the case of the above the membrane an actuating device acting on this is provided, characterized in that that the actuation device for each insertion point one above the switching point and the membrane (18) arranged elastic plunger (22), which in the opening of a arranged above the membrane Guide plate (24) is movable in the vertical direction, its lower, the membrane opposite Area is smaller than the associated hole in the Intermediate layer and that an elastic one, the plunger resetting member is provided in its rest position 2. Membrane keyboard according to claim 1, characterized in that the plunger (22) in the The rest position resetting member is the membrane (18), on the upper side of which the lower end surfaces of the Ram resting. 3. Membrane keyboard according to one of claims 1 or 2, characterized in that the plunger (22) have a cylindrical shape and are formed from an upper thicker part (22A) and a lower thinner part (22B) and that at least the lower one Part consists of an elastomeric material 4. membrane keyboard according to one of claims 1 to 3, characterized in that on the Guide plate (24) an elastic label plate (28) is located on the over the openings of the Guide plate lying places is labeled with the characters assigned to this keying point that on the identification plate a rigid cover layer (30) is arranged, which has an opening at each of the snap-in points, the so is large that the label is recognizable and that a small air gap in the rest position exists between the underside of the identification plate and the top of the plunger (22). 5. Membrane keyboard according to one of claims 1 to 3, characterized in that the guide plate (24) is provided on its underside with a holding plate (26) which enables the passage of the lower parts (22B) of the plunger (22) Has holes. ss 6. Membrane keyboard according to claim 1, characterized in that a switching point is formed from two superimposed pairs of contact elements (12 and 20,12Λ and 20A) that the contact elements of at least one level are separated from one another by a small distance that they consist of flat conductor tracks that the width of the upper contact elements (20 and 20A) and the thickness and arrangement of the lower plunger part (22B) is chosen so that the projection h5 of the plunger pressure surface is symmetrical to the contact elements and at least partially covers them. 7. membrane keyboard according to one of the preceding claims, characterized in that the The plunger (22) is made of neoprene and has a hardness of 60 - 80 Shore. 8. membrane key pad according to one of claims 1 or 2, characterized in that the membrane (18) consists of a polyester film 9. membrane keyboard according to one of the preceding claims, characterized in that the selected ratio between the weight of the plunger (22) and the required actuation weight in Range 1: 200 to 300 Hegt