DE3012717C2 - - Google Patents

Description

The invention relates to a keypad with a first iso layer, on which at least a first, electrically conductive layer in the form of a conductor track with a first Switch contact surface is applied, with at least one second, electrically conductive layer in the form of a ladder track with a second switching contact surface, and with a immediately above the first insulating layer or the first electrically conductive layer lying second insulation layer in the area of the first switching contact surface Has opening through which the electrical con clocks between the first and second switching contact surface is adjustable.

Such keypads are already known from DE-OS 29 03 898. According to Fig. 1 of this DE-OS both the first conductor path together with the first switching contact surface than are also accommodated the second conductor including a second switch contact surface on the constructed as a flexible film on the first insulating layer. The second insulating layer, which is designed as a relatively thick plate, is placed on this first insulating layer or on the conductor tracks, this second insulating layer having an opening in the region of the adjacent switching contact surfaces of the first and second conductor tracks. A third switching contact surface is applied to a third insulating layer designed as a flexible film, the third insulating layer being placed on the second insulating layer and the third switching contact surface being formed on that side of the third insulating layer which faces the first two switching contact surfaces. The third switching contact surface is formed only in the region of the opening of the second switching contact surface and serves as a bridging contact surface for bridging the electrical contact between the first and the second switching contact surface. In this arrangement, a pressure is exerted on the flexible film (insulating layer) in the region of the opening in order to produce the electrical contact, whereby the third switching contact surface is pressed down under deformation of the flexible film together with the third switching contact surface until the third switching contact surface with the two first switching contact surfaces comes into contact, as shown in FIGS. 2A and 2B of DE-OS 29 03 898.

It is perceived as a disadvantage that the first and the second conductor tracks in the same plane, namely are placed on top of the film so that it ent it is not at all possible that the first and cross the second traces (resulting in an undesirable th contact between first and second conductor tracks would lead), or in manufacturing-technical circumstances licher and more expensive in the case of crossing area Chen from first and second conductor tracks additional Iso layers must be produced.

In the embodiment shown in FIG. 3 from the aforementioned DE-OS, the first electrically conductive layer together with the most switching contact surface is formed on a flexible film, a second insulating layer designed as a relatively thick plate with openings in the area of the first switching contact surface is placed on it and the second electrically conductive layer with the second switching contact surface is applied to the first insulating layer facing the inside of a third insulating layer formed as a flexible film, the second switching contact surface being in the region of the opening of the insulating plate, so that the two Switch contact surfaces are arranged opposite each other in the area of this opening. To close the electrical contact, the third insulating layer is pressed down in the area of the opening until the first and second switching contact surfaces come into contact. Here, the second switching contact surfaces are strongly deformed when the contact closes, which is the case with the materials normally used, such as. B. conductive paint or thin copper lamination, easily leads to bridges or hairline cracks, which impair a perfect switching function in the long run.

In a construction known from DE-PS 21 06 732 the second electrically conductive layer with the second Switch contact surfaces on the first insulating layer facing side of the second insulating layer, so that an additional intermediate insulating layer is required here is. Otherwise, the switch contact is also here surfaces deformed when closing the contact.

From DE-PS 20 05 176 another type is known which includes the first and second electrically conductive layers corresponding switch contact surfaces in turn in a tens level, so here again the problem the crossover-free connection results.

The invention has for its object a keypad of the type mentioned so that ver is avoided that the switch contact surfaces during the Kon clock are deformed to a significant degree, whereby however, a crossover-free interconnection of the first and receive second conductor tracks or switching contact surfaces should stay.

This object is achieved in that the second insulating layer is formed as a film that the second, electrically conductive layer with the second switching Contact surface facing away from the first insulating layer  th side of the second insulating layer is applied, and that the second switch contact surface is not in the opening protrudes and at least partially surrounds the opening.

In the case of the keypad described here, the second electrically conductive layer including the switching contact surface is thus provided directly on the second insulating layer, on the side facing away from the first conductor track and not, as in the case of FIG. 1 of the DE-OS mentioned at the beginning, on the same side the first insulating layer, and also not, as in the case of FIG. 3 of the aforementioned DE-OS, on a third insulating layer, facing the first insulating layer. The second switching contact surface is arranged outside the opening and does not extend, as in the case of the aforementioned DE-OS, in the loading area of the opening.

The fact that here the first traces including the first Schaltkon tact areas are arranged in a different plane than the second conductor tracks including second switching contact surfaces, and that between the two conductor tracks or switching contact surface an insulating layer, namely the second iso layer, is more advantageous show the possibility of a crossover-free switching of the given first and second conductor tracks. To close the electrical contact between the first and second Switching contact surfaces becomes a third switching contact surface, which in any way perpendicular to the plane of the Keypad can be arranged movably on the Opening areas pressed so that they on the one hand with the second switching contact surface on the edge of the opening and on on the other hand with the first switching contact surface within the Opening comes into contact. Due to the training of the second insulating layer as a film is in the manufacture of the Contact only a very slight deformation of the third Switch contact area required. The first are subject and second switch contact surfaces or assigned to them neten conductor tracks when switching no significant Deformation, so that the mechani  the first and second switching contacts areas during the switching process is reduced to a minimum.

Another advantage is that here  an isolating one Spacer film is saved.

In the following three embodiments of the Invention with reference to the drawings  explained. It shows

Figure 1 is a partially cut and partially broken view of a first embodiment of the keypad of the.

Fig. 2 is a section along the line II-II of Fig. 1;

Fig. 3 is a plan view similar to Figure 1 of a second exemplary embodiment of the keypad.

Fig. 4 is a section along the line IV-IV of Fig. 3;

Figure 5 is a plan view of a third embodiment of the keypad with more than two to be connected electrically conductive layers. and

Fig. 6 shows a section along the line IV-IV of Fig. 5.

Corresponding parts of the individual figures are included provided with the same reference numerals.

On an electrically insulating base plate 1 , for example made of hard paper, a first electrically conductive layer in the form of a conductor track 2 , which opens into a switch contact surface 3 , is applied. Of course, several conductor tracks with switch contact surfaces in the form of the generally known "printed circuits" can be applied. The first electrically conductive layer can in a generally known manner, such as. B. by means of etching, screen printing, spraying, etc., are applied to the base plate. Above the base plate 1 with the electrically conductive layer is an insulating film 4 made of electrically non-conductive material. On the side of the insulating film 4 facing away from the base plate 1 , a second electrically conductive layer in the form of a conductor track 5 , which opens into a second switching contact surface 6 , is applied. Of course, here too there can be several conductor tracks with switch contact surfaces. The second electrically conductive layer is applied to the insulating film 4 by means of the above-known, generally known techniques.

The insulating film 4 has an opening 7 on each of the switching contact surfaces 3 of the first electrically conductive layer. The switching contact surface 6 of the second electrically conductive layer is brought up to this opening 7 and at least partially surrounds it.

In the embodiment of FIGS. 1 and 2, the opening 7 is circular. The switching contact surface 3 is also circular and approximately the same size as the opening 7 . A slight overlap, ie that the opening 7 is somewhat smaller than the switching contact surface 3 underneath, is advantageous since certain tolerances can be used to compensate for this. The switching contact surface 6 is annular in the embodiment of FIGS. 1 and 2 and borders directly on the edge of the opening 7 .

In the embodiment of FIGS. 3 and 4, the opening 7 is semicircular. The switch contact surface 3 of the electrically conductive layer located on the base plate 1 is also below the opening 7 and is also semicircular. The switching contact surface 6 applied to the insulating film 4 is also semicircular and is mirror-symmetrical to the switching contact surface 3 .

In the embodiment of FIGS. 5 and 6, the opening 7 of the insulating film 4 is again circular. On the base plate 1 are two separate conductor tracks 2 ' and 2'' before, the switching contact surfaces 3' and 3 '' are formed from a semicircle and are at a certain distance from each other. However, the essential parts of the switching contact surfaces 3 ' and 3'' are also below the opening 7 . On the insulating film 4 two leading to the opening 7 conductor tracks 5 ' and 5''are also provided, which open into ring-shaped switching contact surfaces 6' and 6 '' , which are also mirror image symmetry to the opening.

A switching plunger 9 can be seen from FIG. 6, which carries a third electrically conductive button 8 on its lower side. The button 8 and the plunger 9 are flexible to a certain extent. If the switching plunger 9 is now depressed, the button 8 touches the switching contact surfaces 3 ', 3'',6' and 6 '' , so that these or the correspondingly assigned conductor tracks 2 ', 2'',5' and 5 '' be electrically connected to each other.

Although the electrically conductive layers are in different planes, the mechanical stress during the switching process lies exclusively in the switching element, ie in the third switching contact surface 8 , and not in the conductor structure. If the third switching element, which is slightly deformed during each switching operation, is damaged due to permanent stress (breaks, hairline cracks), then the conductor structure itself is not affected by this, rather the third switching elements (switching plunger or the like) must be replaced will.

Instead of the switching plunger 9 , for example, a flexible layer in the form of a film or a rubber mat can be provided, which is provided with an electrically conductive layer at least in the region of the switching contact surfaces to be bonded to one another.

The described keypad also allows in the simplest way Arrangement of more than two conductor structures one above the other, the switching if necessary by several right levels, each in different levels NEN, can be done. Here are examples wise three conductor structures arranged one above the other, d. H. So three layers of insulation, one each on their top applied conductor structures, because of the The fact that the conductor structures are always on the same Side of the associated insulating film, and further hin due to the fact that the insulating layers as Films, that is very thin, are formed, for example a contact between the top and bottom ladder track, between the top and middle conductor track or between the middle and the bottom ladder web are manufactured. Likewise, one is without further ado Contacting the top and middle and the bottom most conductor track possible at the same time.

It is clear that the opening 7 can take any convenient shape. So elongated shapes are also conceivable if several switch contact surfaces to be bonded to one another lie in one plane.

Claims (16)

1. Keypad with a first insulating layer, on which at least a first, electrically conductive layer in the form of a conductor track with a first switch contact surface is applied, with at least a second, electrically conductive layer in the form of a conductor track with a second switch contact surface, and with a direct Over the first insulating layer or the first, electrically conductive layer lying second insulating layer, which has an opening in the area of the first switching contact, through which the electrical contact between the first and second switching contact surface can be produced, characterized in that the second insulation Layer ( 4 ) is designed as a film that the second, electrically conductive layer ( 5 ) with the second switching contact surface ( 6 ) on the side of the second insulating layer ( 4 ) facing away from the first insulating layer ( 1 ), and that second switching contact surface ( 6 ) does not protrude into the opening ( 7 ) u nd at least partially surrounds the opening ( 7 ). 2. Keypad according to claim 1, characterized in that the second electrically conductive layer ( 5 ) is printed on the second insulating layer ( 4 ), sprayed onto it or applied by an etching process. 3. Keypad according to claim 1 or 2, characterized in that the second insulating layer ( 4 ) on the first insulating layer ( 1 ) is attached. 4. Keypad according to claim 3, characterized in that the second insulating layer ( 4 ) is fixed by means of contact pins to the first insulating layer ( 1 ) formed as a plate. 5. Keypad according to claim 4, characterized in that the contact pins connect selected conductor tracks of the first and second electrically conductive layer ( 5 ) with one another. 6. Keypad according to one of claims 1-5, characterized in that the switching contact surface ( 3 ) of the first electrically conductive layer ( 2 ) is congruent to the opening ( 7 ). 7. Keypad according to one of claims 1 to 5, characterized in that the opening ( 7 ) is circular. 8. Keypad according to one of claims 1 to 5, characterized in that the opening ( 7 ) is semicircular. 9. Keypad according to claim 7, characterized in that the switching contact surface ( 6 ) of the second electrically conductive layer ( 5 ) surrounds the opening ( 7 ) in a ring shape. 10. Keypad according to one of claims 1 to 9, characterized in that the opening ( 7 ) more ( 3 ', 3'',6', 6 '' ) are assigned as two switching con tact surfaces, which in the form of circular segments or Ring segments are attached to the first insulating layer ( 1 ) or the second insulating layer ( 4 ). 11. Keypad according to one of claims 1 to 10, characterized in that above the second electrically conductive layer ( 5 ) a movable, electrically conductive button ( 8 ) is provided, which in its contact position the mutually assigned first and second switching contact surfaces ( 3, 6 ) touched. 12. Keypad according to claim 11, characterized in that the button ( 8 ) of the opening ( 7 ) associated switching contact surfaces ( 3, 3 ', 3'', 6, 6', 6 '' ) covers. 13. Keypad according to claim 12, characterized in that the button ( 8 ) is applied to a flexible layer. 14. Keypad according to claim 13, characterized in that the fle xible layer is a rubber mat. 15. Keypad according to claim 13, characterized in that the button ( 8 ) is provided on a movable switching plunger ( 9 ) made of flexible material. 16. Keypad according to claim 13, characterized in that the fle xible layer of a film with conductive areas.