DE19958506A1 - Manufacturing glass keyboard, involves joining plates so defined distance is set between them with adhesive strand forming distance piece and setting adhesive strand - Google Patents

Abstract

The method involves applying a strand of adhesive (8) to the edge of the inner surface of a bearer plate (3) and/or to the edge of the inner surface of a thin glass plate (2), positioning the plates with respect to each other, joining the plates so that a defined distance is set between them with the adhesive strand forming the distance piece and setting the adhesive strand. Independent claims are also included for the following: an arrangement for manufacturing a glass keyboard.

Description

The invention relates to a method and a device for producing a glass keyboard.

Such transparent pressure switch elements are also called touch panels known and are today often used as input media in the form of a header module used in front of flat screens or television screens. About that In addition, touch panels are also available without a combination with a flat screen screen or television screen as a control terminal instead of a classic one Keyboard inserted.

Various types of transparent touch panels are available on the market available. All designs have in common that the place of contact of the Surface of the touch panel with a finger or an auxiliary tool (pen or similar) is converted into electrical signals. Based on these signals the touch point of the surface of the touch panel is detected. By a central processing unit that receives both the signals of the touch panel and evaluates as well as controls the flat screen becomes one special enables user-friendly computer communication.

Visible to the user and partly "palpable" during operation the different touch panels have different user interfaces on. Touch panels based on capacitive operating principles demonstrate one mechanically non-compliant glass surface. The radio tion principle is based on the fact that due to the different Dielek tricity of the finger or the auxiliary tool compared to the air a capaci changes in movement around the point of contact. The disadvantage here is that too contamination around the point of contact erroneously as touch can be interpreted. Because the surface of thick glass (a few millimeters) exists, capacitive displays have a high mechanical, physical and chemical resistance. Capacitive displays are therefore, for example used in communication terminals in banks, information terminals or the like.  

Based on comparable optical or electrical principles Ultrasonic touch panels, infrared touch panels and field effect touch panels. Here too, the surface can be made of glass. Contamination is too critical here, so that such designs in similar applications aim like capacitive panels. However, their market share is significantly small larger than the capacitive panels.

Resistive touch panels, on the other hand, are based on spacing a conductively coated flat carrier, the base material of which is made of glass or plastic panes a few millimeters thick, with a thin, deformable film that is likewise conductively coated. When the film is touched, its deformation leads to local contacting of the two opposite conductive layers. In principle there are two versions of resistive touch panels:

• - The conductive layers have a very homogeneous, local constant surface resistance. By reading the electrical Voltage values can be due to the homogeneous surface resistance the place of touch are closed.
• - The conductive layers of carrier and film are structured so that dis Crete conductor tracks are created. By touching the touch panel there is a local short circuit between the discrete interconnects, whereby within the structure size of the conductor tracks on the Touch point can be closed.

The film material is mainly available on the market Touch panels used transparent plastics. These are from Ab stands to the carrier material at a distance, so that a fault circuit (touching the conductive layers) without actuation is closed. Compared to other designs of touch panels An advantage of resistive touch panels is that one, albeit one, is used for actuation low mechanical deformation force must be exerted on the film. Therefore, their sensitivity to contamination is essential lower, which is why in safety-relevant areas such as medical technology and Industrial automation uses almost exclusively resistive touch panels become.

A disadvantage of using plastics as film material is that in Compared to glass user interfaces much smaller physical and Chemical resistance. Due to mechanical scratching,  Cloudiness, UV radiation or surface damage from chemicals etc. there is a deterioration in transparency. Furthermore, the waiter area sterilizability limited. Another disadvantage when using Plastics is in the lower thermal resistance (softening, Swelling) and the strong thermal expansions compared to glass. The size of the touch Panels severely restricted. Relatively simple and therefore inexpensive Such phenomena can be controlled in smaller resistive touch panels such as those used in electronic diaries.

Novel designs of resistive touch panels are becoming a foil Use thin glass pane with a thickness of 0.15 mm to 0.4 mm has sufficient deformability. Such a surface has Advantages of chemical and physical resistance of glass at low Danger of incorrect switching.

EP 0 546 003 B1 describes a pressure formed from a glass laminate switching element known that from a flexible thin glass pane and min least a carrier material disk is formed, which towards each other facing surfaces each have an electrically conductive layer. Which Opposing electrically conductive layers are created using a Spacers kept at a distance. As a spacer there is a thin one Foil or a double-sided adhesive tape between the thin glass pane and arranged the carrier material disc. The electrically conductive layers be move under pressure when the flexible thin glass layer on the im essential point pressure point.

This invention has for its object a method and a front direction to make a resistive glass keyboard. The production the glass keyboard should be particularly inexpensive, with a few simple Process steps and with a high manufacturing speed consistently high quality of the glass keyboard to be feasible. The The method and the device are intended for extensive automation suitable for manufacturing. The resulting glass keyboard should go over it in addition, especially in the edge area, an increased breaking strength in particular the thin glass pane. Furthermore, the resulting glass key effective edge protection, especially on the thin glass pane point.  

This object is achieved with a method according to claim 1. The method for producing a glass keyboard ( 1 ) with at least one keyboard surface ( 4 ) formed from a flexible thin glass pane ( 2 ) and at least one carrier material pane ( 3 ), each of which has at least one electrically conductive layer on the mutually facing surfaces opposite electrically conductive layers are kept at a distance with the aid of a spacer ( 7 ) and the electrically conductive layers touch when the flexible thin glass pane ( 2 ) is subjected to pressure at the essentially point-specific pressure load point, the following steps include:

• - Applying a circumferential bead of adhesive ( 8 ) to the edge region ( 3 a) of the inner surface of the carrier material pane ( 3 ) and / or to the edge region ( 2 a) of the inner surface of the thin glass pane ( 2 ),
• Positioning the carrier material disc ( 3 ) and the thin glass disc ( 2 ) relatively one above the other,
• - Joining thin glass pane ( 2 ) and carrier material disc ( 3 ) so that a predetermined distance between the thin glass pane ( 2 ) and the carrier material disc ( 3 ) is set and the adhesive bead ( 8 ) forms the spacer ( 7 ) in wesent union, and
• - Hardening of the adhesive bead ( 8 ).

With regard to the device, the object is achieved according to claim 14. In the apparatus for producing a glass keyboard (1) with at least a keyboard surface formed from a flexible thin glass pane (2) (4) and least one carrier material pane (3) which each have, on the mutually facing surfaces at least one electrically conductive layer, the min The opposing electrically conductive layers are kept at a distance with the aid of a spacer ( 7 ) and the electrically conductive layers touch each other when the flexible thin glass pane ( 2 ) is subjected to pressure at the essentially point-specific pressure load point:

• - a first holder ( 9 ) for holding and positioning the carrier material disc ( 3 ),
• - a second holder ( 10 ) for holding and positioning the thin glass pane ( 2 ),
• - Means for applying a circumferential bead of adhesive ( 8 ) to the edge area ( 3 a) of the inner surface of the carrier material pane ( 3 ) and / or to the edge area ( 2 a) of the inner surface of the thin glass pane ( 2 ),
• - Means for positioning the carrier material disc ( 3 ) and thin glass disc ( 2 ) relatively one above the other,
• - Means for joining thin glass pane ( 2 ) and carrier material pane ( 3 ) so that a predetermined distance between the thin glass pane ( 2 ) and the carrier material pane ( 3 ) is adjustable and the bead of adhesive ( 8 ) essentially forms the spacer ( 7 ), and
• - Means for curing the adhesive bead ( 8 ).

With the method according to the invention and the front according to the invention direction, it is advantageously possible to make a glass keyboard particularly cost-effective and to manufacture in large numbers. With just a few simple process steps glass keyboards can be manufactured largely fully automatically. The Glass keyboards are of consistently high quality. especially the Gluing or connecting and spacing thin glass and carrier material disc can now be extremely accurate, with a small distance tolerances.

Further advantageous refinements of the method and the device according to the invention are the subject of the dependent claims and are explained below.

The flexible thin glass pane ( 2 ) is preferably mechanically pretensioned at least during the joining and curing of the adhesive bead ( 8 ), so that the resulting keyboard surface ( 4 ) has a convex curvature. The flexible thin glass pane ( 2 ) can be mechanically pretensioned by means of the second holder ( 10 ), the convex curvature of the keyboard surface ( 4 ) preferably being provided essentially by the shape of the second holder ( 10 ). Preference is given here have large glass Keyboards (1) a more curved keyboard surface (4) and small glass Keyboards (1) a rather flat keyboard surface (4).

A glass pane is used as the carrier material pane ( 3 ) to produce the glass keyboard ( 1 ) before.

The first holder ( 9 ) and / or the second holder ( 10 ) is, for example, an adhesive holder (e.g. double-sided adhesive tape or adhesive film), the respective pane ( 2 , 3 ) being fixed but detachable essentially on its respective outer one Surface is held and positioned. At least one holder ( 9 , 10 ) is advantageously a vacuum holder (vacuum clamping plate).

Furthermore, an adhesive, in particular an essentially organic adhesive or plastic, for example a thermally curing adhesive or a UV-curing adhesive, and / or an essentially inorganic adhesive, for example a glass solder, is preferably used as the bead of adhesive ( 8 ). Correspondingly, in a device according to the invention, means for applying the bead of adhesive ( 8 ) are provided, which allow the application of an adhesive, in particular an essentially organic adhesive, for example a thermally curable adhesive or a UV-curable adhesive, and / or an essentially inorganic adhesive, for example a glass solder.

In one embodiment of the device, the means for applying the adhesive bead ( 8 ) are screen printing devices. In this case, for example, a peripheral bead of adhesive (8) on the edge region (3 a) of the inner surface of the carrier material pane (3) and / or the inner surface of the thin glass pane applied to the edge region (2 a) (2) by means of screen printing. The adhesive bead ( 8 ) can consist of a two-component screen printing ink. In addition to the gluing or connection and spacing of the two panes ( 2 , 3 ), the screen printing ink can also be used for decorative purposes or as a boundary to the pressure-sensitive area of the glass keyboard ( 1 ).

In a further embodiment of the device, the means for applying the adhesive bead ( 8 ) contain at least one dispenser. Here, for example, a circumferential bead of adhesive ( 8 ) on the edge region ( 3 a) of the inner surface of the carrier material disc ( 3 ) is brought up by means of the dispenser.

For example, during the manufacture of the glass keyboard ( 1 ) on the edge area of the inner surface of a pane ( 2 , 3 ) by means of screen printing, a first bead of adhesive ( 8 ), e.g. B. a screen printing ink, which essentially forms the spacer ( 7 ). The application thickness of the screen printing ink essentially specifies the resulting distance between the two disks ( 2 , 3 ). On the opposite disc ( 2 , 3 ) on the edge area of the inner surface is also screen printed a second adhesive bead ( 8 ), z. B. a hot glue applied. The two panes ( 2 , 3 ) are positioned one above the other in such a way that the first and second adhesive beads ( 8 ), i.e. screen printing ink and hot glue, overlap during the joining process, so that a predetermined distance between the thin glass pane ( 2 ) and the carrier material pane ( 3 ) is set and the first and second adhesive beads ( 8 ) essentially form the spacer ( 7 ). After the adhesive bead ( 8 ) has hardened, in particular the hot glue, the two disks ( 2 , 3 ) are fixed and firmly connected to one another.

In order to set a often preferred residual flexibility and elasticity of the spacer ( 7 ), the bead of adhesive ( 8 ) is only incompletely cured, or an adhesive bead ( 8 ) is used which remains elastic after curing. Accordingly, the means for curing the adhesive bead ( 8 ) allow incomplete curing of the adhesive bead ( 8 ).

In a further preferred embodiment of the device, at least one holder ( 9 , 10 ) is at least partially made of a glass plate in order to harden the adhesive by means of UV radiation.

Particularly when using UV-curable adhesives, it is advantageous if at least one holder ( 9 , 10 ) is at least partially transparent to UV radiation; can thus be cured in the device. The curing then takes place by UV irradiation of the adhesive, the UV radiation being generated by means of UV lamps, which are preferably integrated in at least one holder ( 9 , 10 ).

If, for example, heat-curing adhesives are used, the device according to the invention and particularly preferably at least one of the holders ( 9 , 10 ) additionally has means for hot gluing, it being generally advantageous if the means for hot gluing (ie means for applying the hot glue and after the joining means for cooling the hot adhesive) are integrated in at least one holder ( 9 , 10 ).

A carrier material pane (3) is preferably used, whose area is greater, so that the edge region of the carrier material pane (3) projects beyond than the area of the thin glass pane (2) in the resultier glass keyboard (1) the edge region of the thin glass pane (2) circumferentially.

In order to significantly increase the breaking strength of the thin glass pane ( 2 ) and ultimately the glass keyboard ( 1 ), the method is carried out in such a way that when the thin glass pane ( 2 ) and the carrier material pane ( 3 ) are joined, the outer, lateral and inner edge region of the thin glass pane ( 2 ) or at least the inner and lateral edge area of the thin glass pane ( 2 ) is completely surrounded by the adhesive bead ( 8 ), so that part of the resulting spacer ( 7 ) projects beyond the lateral and outer edge area of the thin glass pane ( 2 ). Due to this special arrangement of the adhesive bead during joining, the adhesive bead ( 8 ) forms effective edge protection after curing. Correspondingly, means for joining the thin glass pane ( 2 ) and the carrier material pane ( 3 ) are provided in the device, which allow the outer, lateral and inner edge region of the thin glass pane ( 2 ) to be completely covered by the adhesive bead ( 8 ).

In addition to the effective edge protection, the arrangement of the adhesive bead ( 8 ) gives another advantage:
So glass keyboards in the edge area against mechanical stress, such. B. finger pressure, very sensitive. Such loads can cause incorrect operation or broken glass. For this reason, glass keyboards are usually additionally installed in fixed installation frames or front panels protecting behind the edge area in order to reduce or avoid these loads.

However, the pressure-sensitive surface of the glass keyboard may be used during installation and not mechanically when used later be charged.

Characterized in that the adhesive bead ( 8 ) and thus the resulting spacer ( 7 ) protrudes at least beyond the outer edge area and thus the keyboard surface ( 4 ) of the thin glass pane ( 2 ), the spacer ( 7 ) forms a possible contact surface to a mounting frame or to a front panel ( 12 ). This effectively prevents the frangible edge area from being directly loaded by the frame or the plate. Accordingly, the method is preferably carried out in such a way that the glass keyboard ( 1 ) is held by an outer frame or that the glass keyboard ( 1 ) is mounted behind a front plate ( 12 ).

The profile of the contact surface can be adjusted depending on the application: On flat profile can be used as a mechanical stop, a round one Profile can serve as a seal.

The distance between the front plate ( 12 ) and thin glass pane ( 2 ) can be varied depending on the application. Typical values for the distance are between 0.1 mm and 1 mm. The contact surface serves as a seal to the front plate. This enables fastening and simultaneous sealing by mechanical screwing. Additional sealing / gluing in a frame is no longer required for sealing in a housing.

The contact surface also serves as a mechanical stop and is simplified thereby the automation of the frame assembly. The contact surface protects especially the thin glass pane from direct contact with loads the front panel.

At least when joining the thin glass pane ( 2 ) and the carrier material pane ( 3 ), the thin glass pane ( 2 ) and the carrier material pane ( 3 ) are exactly aligned with one another in all three spatial directions. Accordingly, the device according to the invention is designed in such a way that the means for joining the thin glass pane ( 2 ) and the carrier material pane ( 3 ) precisely align the thin glass pane ( 2 ) and the carrier material pane ( 3 ) in all three spatial directions (six degrees of freedom; x, y, z, ϕ _x , ϕ _y , ϕ _z ) allow each other.

The brackets ( 9 , 10 ) preferably have means for precisely positioning the respective disks ( 2 , 3 ), in particular stops.

In order to position the carrier material disc ( 3 ) and the thin glass disc ( 2 ) exactly one above the other, the means for positioning the two discs ( 2 , 3 ) preferably have guides and / or spacers ( 11 ), the guides and / or spacers ( 11 ) are particularly preferably attached to the first holder ( 9 ) and / or the second holder ( 10 ).

The carrier material disc ( 3 ) and / or the flexible thin glass disc ( 2 ) preferably have at least one opening, in particular a continuous bore. Ventilation between the glued panes ( 2 , 3 ) is possible through the opening, so that, particularly when the flexible thin glass pane ( 2 ) is subjected to pressure, it can deform without creating a pressure cushion. Furthermore, the bore ensures pressure equalization between the internal pressure of the glass keyboard ( 1 ) and the external pressure in the case of atmospheric pressure fluctuations or changes in temperature. The same effect can be achieved by interrupting the bead of adhesive ( 8 ) at at least one point and thereby enabling pressure equalization. For this purpose, means for interrupting the adhesive bead ( 8 ) are provided at at least one point in the device according to the invention. The ventilation hole can preferably be provided with a filter material so that contamination is excluded.

For design reasons, to compensate for manufacturing tolerances as well as to protect the edges or to further increase the breaking strength of the panes ( 9 , 10 ), the edges of the thin glass pane ( 3 ) and / or the edges of the carrier material pane ( 3 ) after joining and curing of the adhesive bead ( 8 ) at least partially reworked, in particular ground or faceted, and / or the thin glass pane ( 3 ) and / or the carrier material pane ( 3 ) are at least partially trimmed after the adhesive bead ( 8 ) has been joined and hardened. Corresponding to the device are means for at least partial reworking, in particular for grinding or faceting the edges of the thin glass pane ( 3 ) and / or the edges of the carrier material pane ( 3 ) or means for at least partially trimming the thin glass pane ( 3 ) and / or the carrier material pane ( 3 ) provided.

In addition, there is a further advantage that metering inaccuracies of the adhesive bead ( 8 ) can be compensated for later, so that an optically perfect edge is created.

The first holder ( 9 ) is preferably fixed and the second holder ( 10 ) is movably arranged.

During the joining and curing of the adhesive bead ( 8 ), the second holder ( 10 ) lies at least partially on the first holder ( 9 ), the holders ( 9 , 10 ) being designed so that a predetermined distance between the thin glass pane ( 2 ) and the carrier material disc ( 3 ) is adjustable. Spacers ( 11 ) can also be arranged between the brackets, which allow a precise, predetermined distance to be maintained between the thin glass pane ( 2 ) and the carrier material pane ( 3 ).

Furthermore, manufacturing-related tolerances, for example of the thin glass pane ( 2 ) or the carrier material pane ( 3 ), are compensated for by the adhesive bead ( 8 ) which is still liquid in the process. Since the distance between the thin glass pane ( 2 ) and the carrier material pane ( 3 ) is precisely specified by the brackets ( 9 , 10 ) or by the spacers ( 11 ) and the liquid adhesive bead ( 8 ) adapts to the gap, glass keyboards ( 1 ) can also be used very small distance tolerances can be produced.

The invention is not limited to the manufacture of glass keyboards. Rather, the invention can be used advantageously wherever at least two disks are connected to each other at exactly the same distance should.

The following example and the drawing illustrate the invention.

Fig. 1 essential process steps and parts of the device for the manufacture of a glass keyboard.

Figure 2 is cross-sectional and detailed view of a glass keyboard. Produced by the inventive method and using the inventive device, and

Fig. 3 cross section and detailed view of another glass keyboard.

In Fig. 1, the essential process steps and essential features of the apparatus are shown for producing a glass keyboard (1).

During the first method step 1.1 , a relatively thick glass carrier material ( 3 ) is placed on a first holder ( 9 ). The first bracket ( 9 ) is a flat glass plate. With the help of lateral stops attached to the first holder ( 9 ), the carrier material disc ( 3 ) is positioned exactly within the plane of the first holder ( 9 ).

On the edge region (3 a) of the inner surface of the carrier material pane (3) is applied (8), for example by means of a Kleberdispensers, a peripheral bead of adhesive (8) consists of a UV-curable adhesive. For later pressure equalization of the glass keyboard ( 1 ) with the environment, the adhesive bead ( 8 ) is completely interrupted at one point.

In the second method step 1.2 the flexible thin glass pane (2) is added such that the adhesive bead (8) (2 a) comprising the top, side and bottom edge portion of the thin glass pane complete and a predetermined distance between the thin glass pane (2) and the carrier material pane ( 3 ) is set. For this purpose, the thin glass pane ( 2 ) is held by a second holder ( 10 ) by means of negative pressure. With the help of stops attached to the second holder ( 10 ), the thin glass pane ( 2 ) is positioned exactly within the plane of the second holder ( 10 ). The thin glass pane ( 2 ) is mechanically prestressed so that the resulting keyboard surface ( 4 ) has a convex curvature. For this purpose, the side of the second holder ( 10 ) with which the thin glass pane ( 2 ) is held is provided with a concave curvature. During the holding, the flexible thin glass pane ( 2 ) is adapted to the curvature of the second holding ( 10 ).

The first bracket ( 9 ) is positioned in a precisely defined, predetermined position above the second bracket ( 10 ) and then lowered vertically. The thin glass pane ( 2 ) is essentially held on its surface ( 4 ), the outer edge area of the thin glass pane ( 2 ) to be provided with the spacer ( 7 ) projecting somewhat beyond the second holder ( 10 ).

To maintain the predetermined distance, corresponding spacers ( 11 ) are integrated in the second holder ( 10 ) and / or the first holder ( 9 ). However, separate spacers ( 11 ) can also be arranged between the brackets ( 9 , 10 ).

The still liquid adhesive (8) fills the gap between the thin glass pane (2) and the carrier material pane (3) and at the same time covers the top, sides and lower edge region (2 a) of the thin glass pane (2).

The second holder ( 10 ) is arranged by means of guides, for example guide pins, exactly above the first holder ( 9 ). Thin glass pane ( 2 ) and carrier material pane ( 3 ) can be positioned in relation to each other in all three spatial directions (six degrees of freedom).

The adhesive ( 8 ) is cured in a third method step 1.3 by means of irradiation with UV rays. For this purpose, a UV lamp is arranged below the first holder ( 9 ). Because the first holder ( 9 ) is at least partially transparent to UV rays, the UV rays can penetrate to the adhesive ( 8 ).

In a fourth method step 1.4 , the first holder ( 9 ) is lifted vertically upwards and the glass keyboard ( 1 ) is removed from the device according to the invention.

In a further process step, the glass keyboard can be mounted behind a front plate ( 12 ) according to FIG. 2, the front plate ( 12 ) being placed directly on the resulting holder ( 7 ).

Alternatively, the second method step 1.2 can also be carried out in such a way that the bead of adhesive ( 8 ) only comprises the lateral and lower edge region of the thin glass pane ( 2 ) (according to FIG. 3), with at least the part of the keyboard surface ( 4 ) projecting beyond the edge region resulting bracket ( 7 ) serves as a support or contact surface for a mounting frame or a front plate ( 12 ).

Reference list

1

Glass keyboard

2nd

flexible thin glass pane

3rd

Carrier disc

4th

Keyboard surface

7

Spacer

8th

Glue bead

9

first bracket

10th

second bracket

11

outer spacer

12th

Front panel

Claims (40)

1. Method for producing a glass keyboard ( 1 ) with at least one keyboard surface ( 4 ) formed from a flexible thin glass pane ( 2 ) and at least one carrier material pane ( 3 ), each of which has at least one electrically conductive layer on the inner surfaces facing one another, wherein the opposing electrically conductive layers are kept at a distance with the aid of a spacer ( 7 ) and the electrically conductive layers touch when the flexible thin glass pane ( 2 ) is subjected to pressure at the essentially point-specific pressure load point,
characterized by the steps:

• - Applying a circumferential bead of adhesive ( 8 ) to the edge region ( 3 a) of the inner surface of the carrier material pane ( 3 ) and / or to the edge region ( 2 a) of the inner surface of the thin glass pane ( 2 ),
• - positioning of the carrier material pane ( 3 ) and thin glass pane ( 2 ) relative to one another,
• - joining of thin glass pane ( 2 ) and carrier material pane ( 3 ), so that a predetermined distance between the thin glass pane ( 2 ) and the carrier material pane ( 3 ) is set and the bead of adhesive ( 8 ) essentially forms the spacer ( 7 ), and
• - Hardening of the adhesive bead ( 8 ).

2. The method according to claim 1, characterized in that the thin glass pane ( 2 ) is mechanically biased so that the resulting keyboard surface ( 4 ) has a convex curvature. 3. The method according to claim 1 or 2, characterized in that a glass pane is used as the carrier material disc ( 3 ). 4. The method according to at least one of the preceding claims, characterized in that the adhesive bead ( 8 ) is an adhesive, in particular an essentially organic adhesive, for example a thermally curing adhesive or a UV-curing adhesive, and / or an essentially inorganic adhesive, for example a glass solder is used. 5. The method according to at least one of the preceding claims, characterized in that the adhesive bead ( 8 ) is applied by means of screen printing. 6. The method according to at least one of claims 1 to 4, characterized in that the adhesive bead ( 8 ) is applied by means of a dispenser. 7. The method according to at least one of the preceding claims, characterized in that the adhesive bead ( 8 ) is not fully cured, or that an adhesive is used as the adhesive bead ( 8 ) which remains elastic after curing. 8. The method according to at least one of the preceding claims, characterized in that a carrier material disc ( 3 ) is used, the area of which is larger than the surface of the thin glass panel ( 2 ), so that in the resulting glass keyboard ( 1 ) the edge region of the carrier material disc ( 3rd ) extends beyond the edge area of the thin glass pane ( 2 ). 9. The method according to at least one of the preceding claims, characterized in that when joining thin glass pane ( 2 ) and carrier material pane ( 3 ) the outer, lateral and inner edge region of the thin glass pane ( 2 ) is completely covered by the adhesive bead ( 8 ), so that the resulting spacer ( 7 ) protrudes beyond the lateral and outer edge area of the thin glass pane ( 2 ). 10. The method according to at least one of claims 1 to 8, characterized in that when joining thin glass pane ( 2 ) and carrier material pane ( 3 ) the lateral and inner edge region of the thin glass pane is covered by the adhesive caterpillar ( 8 ) such that the resulting spacer ( 7 ) protrudes beyond the lateral and outer edge area of the thin glass pane ( 2 ). 11. The method according to at least one of the preceding claims, characterized in that when joining thin glass pane ( 2 ) and carrier material pane ( 3 ), the thin glass pane ( 2 ) and the carrier material pane ( 3 ) are exactly aligned with one another in all three spatial directions. 12. The method according to at least one of the preceding claims, characterized in that a carrier material disc ( 3 ) and / or a thin glass pane ( 2 ) is used which has at least one through opening, in particular a through hole. 13. The method according to at least one of the preceding claims, characterized in that the bead of adhesive ( 8 ) is permanently interrupted at at least one point. 14. The method according to at least one of the preceding claims, characterized in that the edges of the thin glass pane ( 3 ) and / or the edges of the carrier material pane ( 3 ) after the joining and curing of the adhesive bead ( 8 ) at least partially reworked, in particular ground or be faceted. 15. The method according to at least one of the preceding claims, characterized in that the thin glass pane ( 3 ) and / or the carrier material pane ( 3 ) after the joining and curing of the bead of adhesive ( 8 ) are at least partially trimmed. 16. The method according to at least one of the preceding claims, characterized in that the glass keyboard ( 1 ) is mounted in an outer frame. 17. The method according to at least one of the preceding claims, characterized in that the glass keyboard ( 1 ) is mounted behind a front plate ( 12 ). 18. Device for producing a glass keyboard ( 1 ) by a method according to at least one of claims 1 to 17, characterized by

• - - A first bracket ( 9 ) for holding and positioning the carrier material disc ( 3 ),
• - a second holder ( 10 ) for holding and positioning the thin glass pane ( 2 ),
• - Means for applying a circumferential bead of adhesive ( 8 ) to the edge region ( 3 a) of the inner surface of the carrier material disc ( 3 ) and / or to the edge region ( 2 a) of the inner surface of the thin glass disc ( 2 ),
• - Means for positioning the carrier material disc ( 3 ) and thin glass disc ( 2 ) relatively one above the other,
• - Means for joining thin glass pane ( 2 ) and carrier material pane ( 3 ) so that a predetermined distance between the thin glass pane ( 2 ) and the carrier material pane ( 3 ) is adjustable and the bead of adhesive ( 8 ) essentially forms the spacer ( 7 ), and
• - Means for curing the adhesive bead ( 8 ).

19. The apparatus according to claim 18, characterized in that the first holder ( 9 ) and / or the second holder ( 10 ) is an adhesion holder, the respective disc ( 2 , 3 ) being held firmly but releasably essentially on its respective outer surface and is positioned. 20. The apparatus according to claim 18 or 19, characterized in that at least one holder ( 9 , 10 ) is a vacuum holder. 21. The device according to at least one of claims 18 to 20, characterized in that the thin glass pane ( 2 ) by means of the second holder ( 10 ) can be mechanically pretensioned, so that a convex curvature of the keyboard surface ( 4 ) results. 22. The apparatus according to claim 21, characterized in that the convex curvature of the keyboard surface ( 4 ) is essentially determined by the shape of the second holder ( 10 ). 23. The device according to at least one of claims 18 to 22, characterized in that the means for applying the bead of adhesive ( 8 ), the application of an adhesive, in particular an essentially organic adhesive, for example, a thermally curable adhesive or a UV-out allow curable adhesive, and / or an essentially inorganic adhesive, for example a glass solder. 24. The device according to at least one of claims 18 to 23, characterized in that the means for applying the bead of adhesive ( 8 ) are screen printing devices. 25. The device according to at least one of claims 18 to 24, characterized in that the means for curing the adhesive bead cure an incomplete From (8) of the adhesive bead allow (8). 26. The device according to at least one of claims 18 to 25, characterized in that the means for joining thin glass pane ( 2 ) and carrier material pane ( 3 ) a complete embracing of the outer, lateral and inner edge region of the thin glass pane ( 2 ) by the adhesive bead ( 8 ) allow so that the resulting spacer ( 7 ) protrudes beyond the lateral and outer edge region of the thin glass pane ( 2 ). 27. The device according to at least one of claims 18 to 25, characterized in that the means for joining thin glass pane ( 2 ) and carrier material pane ( 3 ) a complete embracing the lateral and inner edge region of the thin glass pane ( 2 ) by the adhesive bead ( 8 ) allow, the resulting spacer ( 7 ) protruding beyond the lateral and outer edge region of the thin glass pane ( 2 ). 28. Device, according to at least one of claims 18 to 27, that the central disc of joining thin glass pane (2) and carrier material (3) a precise alignment of the thin glass pane (2) and carrier material pane (3) in all three spatial directions to each other allow. 29. The device according to at least one of claims 18 to 28, characterized by means for at least partial reworking, in particular for grinding or faceting the edges of the thin glass pane ( 3 ) and / or the edges of the carrier material pane ( 3 ). 30. The device according to at least one of claims 18 to 29, characterized by means for at least partially trimming the thin glass pane ( 3 ) and / or the carrier material pane ( 3 ). 31. The device according to at least one of claims 18 to 30, characterized in that at least one holder ( 9 , 10 ) is at least partially made of a glass plate. 32. Device according to at least one of claims 18 to 31, characterized in that at least one holder ( 9 , 10 ) is at least partially transparent to UV radiation. 33. Device according to at least one of claims 18 to 32, characterized in that the means for curing the adhesive bead ( 8 ) are integrated in at least one holder ( 9 , 10 ). 34. Device according to at least one of claims 18 to 33, characterized in that the means for curing the adhesive bead ( 8 ) are UV lamps. 35. Device according to at least one of claims 18 to 34, characterized in that the brackets ( 9 , 10 ) have means for precisely positioning the respective discs ( 2 , 3 ), in particular stops,. 36. Device according to at least one of claims 18 to 35, characterized in that the means for positioning the carrier material disc ( 3 ) and thin glass disc ( 2 ) have guides and / or spacers ( 11 ) relatively one above the other. 37. Apparatus according to claim 36, characterized in that the guides and / or spacers ( 11 ) on the first bracket ( 9 ) and / or the second bracket ( 10 ) are attached. 38. Device according to at least one of claims 18 to 37, characterized by means for permanently interrupting the bead of adhesive ( 8 ) at at least one point. 39. Device according to at least one of claims 18 to 38, characterized by means for mounting the glass keyboard ( 1 ) in an outer frame. 40. Device according to at least one of claims 18 to 39, characterized by means for mounting the glass keyboard ( 1 ) behind a front panel ( 12 ).