WO2013013963A1 - Control device for a household appliance and household appliance - Google Patents

Abstract

The invention relates to a control device (1) for a household appliance, having at least one capacitive control element (2 to 8) which has a first capacitor plate (2a to 8a) and a second capacitor plate (2b to 8b), wherein the second capacitor plate (2b to 8b) is arranged over the first capacitor plate (2a to 8a) and is malleable relative thereto, so that, dependent on the deformation, a distance change between the two capacitor plates (2a to 8a; 2b to 8b) can be generated and, dependent on the distance change, a control function coupled to the activation of the control element (2 to 8) can be triggered, wherein the capacitive control element (2 to 8) is arranged on the interior of the control device (1), wherein a touchable control panel (21) is designed which has a level outer surface having at least one contact zone (23), wherein the contact zone (23) is coupled to a longitudinally stable actuator plunger (17, 25) arranged under the control panel (21) and the actuator plunger (17, 25) is coupled on the other side to the second capacitor plate (2b to 8b) so that a deformation of the control panel (21) on the contact zone (23) caused by actuation can be transferred to the second capacitor plate (2b to 8b).

Description

 Operating device for a household appliance and household appliance

The invention relates to an operating device with a capacitive control element for a household appliance and a household appliance with an operating device. There are known control devices for household appliances, which include a capacitive control element. For this purpose, two spaced apart capacitor plates are used. When an electrical voltage is applied between these plates, an electrical capacitance is built up. If the distance between the plates is changed by the action of a force, the electrical capacitance also changes, which in turn can be evaluated as a switching trip. In a touch switch or a touch switch, a capacitor plate is formed by the metal surface, while the other capacitor plate is located on a circuit board and is formed as a conductor track structure. The circuit board is at the same time the circuit carrier for the switching function evaluation and signal conditioning. Such is known for example from EP 1 704 642 B1.

A disadvantage of this structure, however, is the fact that the metal surface must be electrically connected to the circuit board. In order to exclude possible dangerous electrical voltages on the touchable metal surface, galvanic isolation of the switching evaluation electronics from the mains supply voltage is required. This galvanic separation is complicated in conventional embodiments and can only be done by dedicated and expensive additional components.

An alternative and common solution for electrical isolation with approved electrical components is the protective insulation of the accessible metal parts. This is realized by plastic plungers, which transmit the introduction of force between the touchable isolated metal surface and the capacitor plate. In the cited prior art, a metal surface surrounding the sensor is connected to ground on the circuit board.

Due to the extremely short switching paths of a few micrometers a constructive solution is required, which ensures this, which is very complex in known designs or not feasible. Especially in one embodiment of an operating device with a plurality of closely adjacent arranged capacitive console or operating elements, such a galvanic separation is extremely complex, and occur due to often only one-sided electrical contacting different distances and thus actuation paths in the individual capacitive sensors. This leads to incorrect operation or insufficient signal detection.

Furthermore, from DE 32 40 925 A1 an operating device with an internal capacitive control element is known, wherein an upper capacitor plate via an elaborately designed and high control knob, which protrudes through an aperture in the control panel and moves relative thereto, can be actuated.

It is an object of the present invention to provide an operating device for a household appliance and such a household appliance, in which or in which a capacitive operating element is improved in terms of the operation and secure signal detection.

This object is achieved by an operating device and a household appliance according to the independent claims.

An operating device according to the invention for a domestic appliance comprises at least one capacitive operating element which has a first capacitor plate and a second capacitor plate, wherein the second capacitor plate is arranged above the first capacitor plate and is deformable relative thereto. This is done in such a way that, depending on the deformation, a change in distance between the two capacitor plates can be generated and, depending on the change in distance, an operating function coupled to the actuation of the operating element can be triggered, wherein the capacitive operating element is arranged inside in the operating device. A touchable control panel is formed, which has a flat outer surface with at least one contact zone, wherein the contact zone is coupled to a arranged under the control panel length-stable actuating plunger, and the actuating plunger on the other hand coupled to the second capacitor plate, so that caused by actuation deformation of the control panel at the contact zone on the second capacitor plate is transferable. Such a rigid and in its length not deformable actuating tappet thus allows a very direct and accurate motion transmission when the control panel is pressed by a user on the outside of the contact zone. Since in such capacitive controls the distance changes due to the relatively rigid metal plate, for example, 0.3 mm thickness move only in the micrometer range and a very accurate detection must be done by such a stiff and rigid actuating plunger and a very small deformation of the control panel directly the second capacitor plate are transmitted, so that even here the slightest deformations and associated distance changes between the capacitor plates can be reliably and reliably detected.

In this embodiment, it is thus provided that the second capacitor plate in the operating device is arranged lying inside and thus not directly accessible and touchable by a finger. A second capacitor plate positioned in this way is then connected only indirectly via further components that can be touched by a user to deform the second capacitor plate designed as a metal plate and thus can only be actuated indirectly.

The actuation force is given as 2N to 8N, preferably 4N +/- 1N. With this relatively low actuation force is in particular even from a touch control the speech.

Preferably, the top of the second capacitor plate is coupled to a first end of the length-stable actuating plunger, wherein the actuating plunger is coupled to a second end with a touchable control panel. The actuating plunger is thus cylindrical and extends vertically in the operating device. As a result, very linear movements can be transmitted. Just a force generated by the top of a finger force on the control panel can then be transmitted directly along the longitudinal axis of the actuating plunger in a rectilinear force path and thus also experience the second capacitor plate a corresponding deformation. It is preferably provided that a tolerance compensation element is formed between the first end and the second capacitor plate. Preferably, this tolerance compensation element is an initially deformable and viscous mass which hardens after production. Manufacturing and assembly tolerances can be optimally compensated, so that the above-mentioned distance changes in the micrometer range can be transmitted and detected very accurately.

Preferably, it is additionally and instead provided that between the second end of the actuating plunger and the control panel also a tolerance compensation element is formed.

This mass, which forms a tolerance compensation element may be, for example, epoxy resin. This mass is applied to the second capacitor plate before mounting. After assembly of the switching system with the actuating tappet hardens this mass. The formed in particular as a metal plate second capacitor plate, the actuating plunger and the control panel then sit on block, so that the switching system can transfer the extremely short switching strokes without play, without them running empty in the switching system. To increase the pressure points and additional fixation of the actuating plunger between the control panel and the second capacitor plate, the tolerance compensation mass can also be applied to both ends of the switch plunger. This has the advantage that the switching play compensation is distributed on both ends of the actuating tappet. For this purpose, embodiments of the actuating plunger are possible to the effect, for example, to attach a bulk depot on the actuating plunger.

It is preferably provided that an electrically insulated carrier element is arranged between the control panel and the second capacitor plate. This is preferably made of plastic. At the top of the control panel is then attached, in particular glued by an adhesive tape. At the bottom of the capacitive control element is then arranged. This, too, can be attached to it by an adhesive film, for example. The adhesive film is then preferably glued to the upper side of the second capacitor plate and to the underside of the carrier element. The carrier element may be formed, at least in regions, from a spectral region visible to light in humans. As a result, light from a light source, which is fastened, for example, on the printed circuit board, can be directed through the carrier element. In particular, when the control panel is also at least partially formed of a translucent material, then very location-specific and individual optical information can be displayed.

It can be provided that the control panel is formed as a metal plate having recesses through which the light is radiated through. It is particularly advantageous that translucent parts, such as glass or plastic are arranged in the recesses. In turn, a symbol can be applied to these, so that the transparent area of the control panel and the symbol attached thereto can be backlit.

It can also be provided that the recesses in the sheet represent the symbol and are flush filled for illumination with the diffuse balancing mass (plan) to the user interface.

It can also be provided that the actuation tappet is formed, at least in regions, from a material which is permeable to light in the spectral range visible to the human being. Such an actuating tappet then has a multifunctionality, since it can also pass light in addition to its specific transmission of motion between the control panel and the second capacitor plate. Again, it may be provided that light from a arranged on the circuit board light source is specifically coupled into the actuating plunger and can be routed site-specific from the circuit board to the control panel. The abovementioned possibilities with regard to the backlighting of symbol and light transmissive areas of the control panel apply here analogously.

It can also be provided that a tolerance compensation element is at least partially permeable to light in the visible to the human spectral range. This is particularly useful, especially if the actuating tappet is formed from a transparent material. The light can then be passed continuously from the printed circuit board to the control panel. Preferably, the first capacitor plate is formed on a printed circuit board and the second capacitor plate is disposed over the first capacitor plate. The second capacitor plate is deformable relative to the first capacitor plate, so that depending on the deformation, a change in distance between the two capacitor plates can be generated. Depending on the change in distance coupled with the operation of the control element operating function can be triggered. Between the second capacitor plate and the printed circuit board, an electrically conductive contact spring plate is disposed without contact to the first capacitor plate. The electrically conductive contact spring plate is also arranged in electrical contact with the circuit board and also in electrical contact with the second capacitor plate. The contact spring plate has a hole which is positioned in the region between the first capacitor plate and the second capacitor plate. The vertical distance between the two capacitor plates is therefore not covered by the contact spring plate. By means of such a design of the operating device, a particularly noteworthy electrical contacting between electrically conductive regions of the printed circuit board and the second capacitor plate can be achieved. In a particularly noteworthy manner can thus be minimized space and functionally reliable galvanic separation, so that the second capacitor plate can be operated without unwanted voltage application.

In particular, when this second capacitor plate represents the outer control surface of the operating device, which can be touched by a user, for example, with a finger directly, such a configuration is advantageous, in particular, a galvanic isolation is formed to the mains voltage or minimum distances with respect to air and Creepage distances are provided.

It is preferably provided that the contact spring plate at the edge of the hole has at least one tab, which is in electrical contact with the circuit board and the second capacitor plate. At particularly specific and desired location thus the electrical contact is made. The tab is a particularly flexible element which, even with a relative mobility between the two capacitor plates, in particular due to the deformation of the second Capacitor plate always remains in contact with the electrically conductive region of the circuit board and the second capacitor plate during actuation.

It is preferably provided that a contact area provided for contacting the contact spring plate electrical contact area is formed directly on the circuit board, in particular the first capacitor plate is electrically isolated from this insulated. On an upper side of the printed circuit board, an electrically conductive coating is thus applied in a fixed and permanent manner, wherein on the one hand, this represents, on the one hand, the first capacitor plate and forms, electrically insulated from it, the electrical contact region. The first capacitor plate can be designed in many ways with regard to their shape. Preferably, a circular configuration is provided. However, it may also be an oval or angular configuration.

In a particularly noteworthy manner, it is provided that the at least one tab is arranged obliquely or rotated relative to the plane of the contact spring plate, so that a spacer element is formed by the tab, through which a larger distance between the first and the second capacitor plate results. By such a rotation or tilting of the tab, the above-mentioned flexibility with regard to the deformation and Bewegungsmitführung in the deformation of the second capacitor plate can be achieved. The width of the tab viewed in the direction of rotation of the hole is thus so large that when a rotation or inclination of the tab a level is reached, which is greater than the thickness of the contact spring plate. Preferably, it can be provided that the height distance between the plane of the contact spring plate and one of them, viewed at a maximum in the vertical direction remote point of a rotated tab between 0.2 mm and 0.4 mm, in particular between 0.25 mm and 0.35 mm , The thickness of the contact spring plate is preferably between 0.02 mm and 0, 1 mm, in particular 0.05 mm. Preferably, this is due to the rotation of the tab and its planar configuration on both opposite sides of the plane of the contact spring plate dimensioned accordingly. If the thickness of the contact spring plate is still added, the result is a total maximum height between the two maximum spaced points of the rotated tab between 0.50 mm and 0.80 mm, preferably between 0.60 mm and 0.70 mm.

It is advantageously provided that the width of a tab viewed in the direction of rotation of the hole is between 2.5 mm and 3.5 mm, in particular 3 mm. Advantageously, the tab in the radial direction of the hole has a length between 2.5 mm and 3.5, in particular 3 mm.

The design of the contact spring plate is particularly chosen so that by the thickness of the material (spring hardness), by the length and width of the at least one tab and its setting a permanently elastic el. Contacting between the second capacitor plate and the contact area is guaranteed. In particular, this is also due to the thickness of transfer adhesive tapes (strapless adhesive films) which have a thickness of preferably 125 μm (0.125 mm). For two adhesive films with corresponding thicknesses and, for example, 0.05 mm thick contact spring plate results in 0.3 mm. The height of the turned tab is preferably 0.6 mm, so that the individual tab is bent back by 0.3 mm after the bonding. This is in the permanently elastic range of the contact spring plate and ensures the contact between the circuit board and the upper second capacitor plate over the life of the operating device. The hole in the contact spring plate preferably has a diameter between 10 mm and 22 mm. Preferably between 10 mm and 16 mm, preferably 13 mm. Preferably, it is provided that the tab is radially inwardly from the edge of the hole and a front end of the tab terminates in front of the outer edge of the first capacitor plate. The hole is at the inner end of the tabs and is formed by the springs. Since the springs simultaneously take on a Faraday function, the gaps between the tabs are not seen as an interruption of the electrical connection (Faraday effect). In particular, they form the outer radial boundary of the capacitor. In the radial direction, this tab is so short dimensioned that in the assembled state of the operating device and its rotated position does not come into electrical contact with the first capacitor plate.

In particular, therefore, furthermore, the vertical space between the first capacitor plate and the second capacitor plate in the area of the first capacitor plate is free of these tabs, so that only a free air space is formed therein.

Preferably, a plurality of tabs, in particular equidistant in the circumferential direction of the edge, formed at the edge of the hole. Preferably, the number of tabs is> 4, in particular> 6.

The contact spring plate is preferably formed in one piece and made for example of beryllium copper or spring-hard stainless steel and has the necessary flexibility and deformability.

Preferably, it is thus provided that a spring plate is arranged by the spring plate, which allows a direct almost annular electrical contact with the second capacitor plate. Just when the operating device has a plurality of capacitive controls, is given by such an arrangement of a spring plate, the advantage that for each switch or each capacitive control element so that an identical electrical path length between the upper and the lower capacitor plate is formed. This greatly simplifies the electrical evaluation of the switch operation. In addition, the introduction of such a separate contact spring plate allows a saving of contact with the printed circuit board by means of welded contact wheel. The missing tabs are connected in particular in the rotated or inclined position over the shortest possible path between the second capacitor plate and the electrical contact region of the circuit board.

Preferably, the second capacitor plate is formed as a metal plate. This second capacitor plate may be provided for contact by a user outer component of the operating device. In such a configuration is then provided that by directly placing a finger actuation takes place, in particular, a galvanic isolation of the mains voltage is formed.

It is preferably provided that between the printed circuit board and the contact spring plate, a first electrically insulating element, in particular an adhesive film, is arranged with a recess in the region of the hole of the contact spring plate. This allows a very space-saving, yet reliable and durable connection between the circuit board and the contact spring plate can be formed.

Additionally or instead, it may be provided that between the contact spring plate and the second capacitor plate, a second electrically insulating element, in particular an adhesive film, is arranged with a recess in the region of the hole of the contact spring plate. Here too, a very compact, yet permanently stable connection between the contact spring plate and the second capacitor plate can thus advantageously be achieved.

The adhesive film on the one hand, the connection between said components can be achieved and on the other hand, the electrical insulation can be created, so that here also a multi-functional part is provided. It is preferably provided that at least two capacitive operating elements are formed and the contact spring plate is located in both operating elements between the circuit board and the second capacitor plates.

The contact spring plate is designed in particular in one piece, so that here too a component reduction of the device is created. Especially in such an embodiment with a plurality of capacitive controls, the particular advantage of the contact spring plate comes into play, as already explained above.

The carrier element may in particular be formed of a diffusely transparent plastic for light scattering. The carrier element may in particular have continuous channels in which the actuating tappets are arranged accurately. A fit gap length determines the air and creepage distance between the upper and thus second capacitor plate and the control panel. The control panel, which is preferably formed as a continuous metal plate, preferably has a thickness between 0.25 mm and 0.8 mm, preferably between 0.3 mm and 0.7 mm. Due to the additional use of a contact spring plate, which is electrically connected electrically to the second capacitor plate and a first capacitor plate electrically insulated contact area, in particular on the circuit board, this metal surface of the second capacitor plate, in particular if they the outside control panel by a user is touched, represents, be designed as a continuous stainless steel or aluminum sheet. Non-wearing materials such as plastics or natural materials such as wood are also possible because the touchable surface no longer has to be electrically conductive.

Another advantage consists in the tolerance compensation elements formed by the curing tolerance compensation mass, through which a possible compliance with prescribed clearances and creepage distances is achieved, which ultimately represents a cost advantage and due to the compact dimensions extended design and design options in the field of control and display module allows.

Furthermore, the invention relates to a household appliance with an operating device according to the invention or an advantageous embodiment thereof.

A household appliance is a device that is used for household management. For example, household appliances here are understood devices that are designed for preparing food. Such a household appliance is for example an oven, a hob, a microwave cooking appliance, a steam cooker or a fryer. Likewise, however, a coffee machine or the like can also be understood here. In addition, a household appliance may also be designed for the care of items of laundry and be, for example, a washing machine or a tumble dryer. Furthermore, the household appliance may be a dishwasher for cleaning dishes. Particularly advantageous may also be a household appliance for preserving and storing food, such as a fridge or a freezer. In particular, when the outside of the door of such a household appliance is formed, for example, partially made of metal and in this area, the operating device is formed, an embodiment with, for example, continuous metal surface and integrated capacitive controls can be created.

Further features of the invention will become apparent from the claims the figures and the description of the figures. The features and feature combinations mentioned above in the description, as well as the features and combinations of features mentioned below in the description of the figures and / or shown alone in the figures, can be used not only in the respectively specified combination but also in other combinations or in isolation, without the frame to leave the invention.

Embodiments of the invention are explained in more detail below with reference to schematic drawings. Show it:

Fig. 1 is an exploded view of subcomponents of an embodiment of an operating device according to the invention;

Fig. 2 is a plan view of an embodiment of a contact spring plate of the operating device of FIG. 1;

Fig. 3 is a sectional view of the contact spring plate of FIG. 2;

4 is a sectional view through a further embodiment of an operating device according to the invention;

Fig. 5 is a sectional view through a variant of the embodiment of FIG.

 4;

6 is a sectional view through a further embodiment of an operating device according to the invention; 7 is a sectional view through a further embodiment of an operating device according to the invention; and

8 is a plan view of the operating device according to FIG. 7.

In the figures, identical or functionally identical elements are provided with the same reference numerals.

In Fig. 1, an embodiment of an operating device 1 is shown in subcomponents in a perspective exploded view. The operating device 1 comprises a plurality of capacitive operating elements 2, 3, 4, 5, 6, 7 and 8.

Each of the capacitive operating elements 2 to 8 comprises a first capacitor plate 2a, 3a, 4a, 5a, 6a, 7a and 8a. These first capacitor plates 2a to 8a are formed on an upper surface of a printed circuit board 9. In the exemplary embodiment, the circuit board is designed as a rectangular, strip-shaped plate. The first capacitor plates 2a to 8a are applied from an electrically conductive material as a coating or printing on the upper side of the printed circuit board 9.

In the exemplary embodiment, the first capacitor plates 2a to 8a have a circular area. However, it can also be provided a different geometric shape design. Each capacitive control element 2 to 8 also has a second capacitor plate 2b, 3b, 4b, 5b, 6b, 7b and 8b. The second capacitor plates 2b to 8b are integrally formed in a likewise formed as a rectangular plate cover of the operating device 1, wherein this cover is formed as a one-piece metal plate 10. Preferably, this metal plate 10 is formed as a continuous, uninterrupted plate. The capacitor plates 2b to 8b are then not explicitly incorporated as corresponding circular area-shaped zones in the metal plate 10, but represent fictitious such surfaces.

It can be provided that on a top 1 1 of this metal plate 10 touch zones 2c, 3c, 4c, 5c, 6c, 7c and 8c are optically marked for a user to touch the capacitive controls 2 to 8 at the appropriate appropriate places and to be able to press. This is particularly advantageous if the metal plate 10 represents the topmost cover of the operating device 1, so that the contact zones 2c to 8c can be touched directly by a user with a finger. It can also be provided that corresponding symbols are also arranged on these touch zones 2c to 8c, which can be made visually recognizable in particular, which indicate to the user the respective functionality assigned to the specific operating element 2 to 8. In particular, it is provided that the dimensions of the metal plate 10 correspond to the dimensions of the printed circuit board 9.

As can be seen from the illustration in FIG. 1, on the upper side of the printed circuit board 9, on which the first capacitor plates 2a to 8a are formed, they are separated from one another by annular zones 2d, 3d, 4d, 5d, 6d, 7d and 8d electrical contact area 12 electrically isolated. This electrical contact region 12 is likewise formed as a printing or coating on the upper side of the printed circuit board 9.

Between the metal plate 10 and the circuit board 9, a contact spring plate 13 is formed, which is formed of an electrically conductive material. The contact spring plate 13 is also rectangular in shape and has substantially the dimensions of the metal plate 10 and the circuit board 9.

The contact spring plate 13 has holes 13a, 13b, 13c, 13d, 13e, 13f and 13g. These are so formed in the x-direction and in the z-direction that in the assembled state of the operating device 1 between the respective capacitor plates 2a to 8a and in the vertical direction (y-direction) directly above the second capacitor plates 2b to 8b, a free space or Visual space or air space is formed, which is not covered by the material of the contact spring plate 13.

The holes 13a to 13g are designed to be the same in terms of their shape and design, so that in the following representative of the hole 13a is discussed in more detail. This has at a peripheral edge 31 a plurality of tabs 131 a to 131 h. These extend in the radial direction and represent rectangular strips or plates. They are arranged in the direction of rotation about the edge 131 equidistant from one another.

In addition, it is envisaged that they do not extend completely in the x-z plane but are rotated or tilted about their longitudinal axes extending in the radial direction of the hole 13a, so that they are arranged quasi obliquely relative to the x-z plane. A longitudinal axis of a tab 131 a to 131 h extends in the radial direction. In addition, it is provided that a maximum radial length of a tab 131 a to 131 h so dimensioned that they do not extend to the first capacitor plate 2 a.

By tilting or tilting of the tabs 131 a to 131 h from the xz-plane in which the contact spring plate 13 otherwise extends, is achieved in the assembled state of the operating device 1 that the tabs 131 a to 131 h both the bottom of the Metal plate 10 outside of the second capacitor plate 2b electrically contact as well as the electrical contact region 12 contact. By this contact spring plate 13 and in particular the very specific configuration with the hole 13 a and the tabs 131 a to 131 h and their orientation, the metal plate 10 can be placed on a to the capacitor plates 2 a to 8 a separate electrical potential. In a very compact and highly functional manner, a highly functional electrical safety system can thus be created.

It is preferably provided that between the metal plate 10 and the contact spring plate 13, an electrically insulating element, in particular a double-sided adhesive tape is formed, so that a mechanically stable and electrical insulating connection between the metal plate 10 and the contact spring plate 13 outside of the tabs 131 a to 131 h is reached. It is likewise provided that a further electrically insulating element in the form of a double-sided adhesive tape likewise not shown in FIG. 1 is arranged between the contact spring plate 13 and the printed circuit board 9.

The two adhesive tapes between the components metal plate 10, contact spring plate 13 and circuit board 9 are designed so that they are also configured with correspondingly sized holes at the locations of the first capacitor plates 2a to 8a and the second capacitor plates 2b to 8b, so that even through these tapes the surface area, as given by the dimensions of the capacitor plates 2a to 8a and 2b to 8b, is not covered in the y-direction.

As already mentioned, the operating device 1 formed in this way can be arranged directly on an outer side of a domestic appliance and the upper side 11 of the metal plate 10 can be provided for direct contact with a finger. However, it can also be provided that this embodiment, as is realized in FIG. 1 with the subcomponent shown, is arranged inside in an operating device with further components and the contact zones 2c to 8c can be actuated only indirectly via further components of the operating device. The operation of the operating device 1 according to FIG. 1 takes place in that one of the contact zones 2 c to 8 c is touched and corresponding pressure is exerted in the y direction. By the metal plate 10 in particular at the contact zones 2c to 8c deformable at least in the micrometer range, the distance to the stationary arranged printed circuit board 9 and thus the first capacitor plates 2a to 8a can be changed. Depending on this change in distance can then be detected due to the capacitive operating principle of the controls 2 to 8 an operation and the associated functionality can be controlled by a control unit, not shown.

In Fig. 2 is a plan view of the contact spring plate 13 is shown. Here, exemplary dimensions are given in mm. The longitudinal axis A of the contact spring element 131 c is shown. As can be seen, the contact spring plate 13 has a thickness (extension in the y-direction) of preferably 0.05 mm. As can be seen by way of example from the illustration in FIG. 3, in this sectional view the tab 131c turned out of the plane of the contact spring plate 13 is shown by way of example. The rotation or tilting is chosen so that in the y-direction, the height between the two opposite radial edges of the tab 131 c is 0.57 mm. Less than the thickness of about 0.05 mm of the contact spring plate 13 thus has each of the two edges of the tab 131 c at a distance in the y direction of 0.26 mm to the respective facing side of the contact spring plate 13.

The following Figs. 4 to 7 show embodiments that show instead of galvanic isolation, the protective structure of the control unit in terms of protection against electrical voltages according to standard I EC 60355 "Safety of electrical appliances for household use and similar purposes" protection class II. The galvanic isolation 4 is a sectional view through a further embodiment of an operating device 1. In this embodiment, the component arrangement, as shown in Fig. 1, is not arranged directly on a top of a household appliance and the Thus, this component arrangement is located on the inside and therefore not directly accessible from outside. As can be seen from the representation in FIG. 4, the metal plate 10, an underlying K living film 14, which in turn disposed thereunder contact spring plate 13, an underlying further adhesive film 15 and the circuit board 9 is arranged under a support member 16 which is formed of plastic. In addition, the support element 16 may be formed, at least in some areas, from a material that is transparent to the visible wavelength range of the material. It can have a diffusely scattering effect on the light.

In addition, it is provided that this operating device 1 in the vertical direction and thus y-direction directly above the second capacitor plate 2b and thus also the contact zone 2c has an actuating tappet 17. This is designed to be stable in length in the direction of its longitudinal axis B and arranged in a channel 18 of the support member 16 relative fit, but minimally displaceable in the y direction. How to 1, a lower end 17a is located on the contact zone 2c. At the opposite upper end 17b, a tolerance compensation element 19 is arranged, which rests against an underside 20 of the control device 1 upwards and thus outwardly closing control panel 21. With the tolerance compensation element 19 a occurring due to manufacturing and assembly tolerances distance between the actuating plunger 17 and the control panel 21 is compensated. Since the capacitive operation and thus the effect of the change in distance between the two capacitor plates 2a and 2b in the micrometer range, also such small ways must be defined and safely transferred to the second capacitor plate 2b, so just exactly such assembly and manufacturing tolerances between the components must be avoided.

The tolerance compensation element 19 is preferably a flexible mass, which is introduced during manufacture and assembly and which hardens in the following and thus is also dimensionally stable.

In this embodiment, it is provided that, when with a finger 22, such as is placed on a touch zone 23 on the control panel 21, and in the y direction, a pressure is generated down, the control panel 21, which for example made of metal can be formed, a downward deformation, this is due to the length stability and deformation stability of a local tolerance compensation element 24 and a plunger 25 transferred directly to the second capacitor plate 3b, so that this also deformed downwards, so that the distance to the first capacitor plate 3a is changed and the operation of the capacitive control element 3 is detected.

The further operating tappets and elements shown in FIG. 4 are analogous to the embodiments explained in FIG. 4, so that they are not explained in more detail and provided with reference numerals. In all, a corresponding contact zone 23 and corresponding tolerance compensation elements 19, 25 at the upper end of the plunger 17 and 25 are provided.

The lower end of the plunger 17, 25 with the tolerance compensation element 19 and 24 is arranged in recesses 26 and 27 of the support member 16. The positive, complete and full-surface contact of the control panel 21 on the top of the support member 16 in a completely flat shape is thus guaranteed as well as the sufficient introduction of a tolerance compensation element 19 and 24 and the flat full-surface contact of the control panel 21 on this tolerance compensation elements 19 and 24 is ensured.

In Fig. 5, an alternative embodiment in Fig. 4 is shown. It is provided here that between the control panel 21 and the support member 16, a double-sided adhesive film 28 is introduced. In addition, a double-sided adhesive film 29 between the support member 16 and the metal plate 10 is formed. In Fig. 6, a further embodiment of an operating device is shown, which in contrast to the illustration of FIG. 4 also at the metal plate 10 facing ends of the actuating plunger 17 and 25 has a tolerance compensation element 30 and 31 respectively.

Another embodiment of an operating device 1 with an internal component arrangement, as shown and explained in FIG. 1, is shown in FIG. In contrast to the illustrations in FIGS. 4 to 6, it is provided here that the actuation tappets 17, 25 not only serve as stable mechanical actuation transmitters, but moreover also at least partially, in particular completely, of a material permeable to light in the spectral range visible to humans , in particular plastic, are formed.

As can be seen from the illustration in FIG. 7, light sources 33, in particular light-emitting diodes, are arranged on a lower side 32 of the printed circuit board 9 and send light upward through apertures 34 of the printed circuit board 9. This light is conducted according to the embodiment in Fig. 7 by translucent tolerance compensation elements 30 and 19 upwards and can illuminate an at least partially transparent area or a zone of the control panel 21, as shown in Fig. 8. Even if the control panel 21 is formed of metal, it is precisely in these zones of contact, as shown by way of example by the contact zone 23 for the capacitive control element 3 in FIG. 8, that light-permeable areas can be integrated. These may be, for example, glass inserts or plastic inserts, on which then symbols, as shown in Fig. 8, for example, are printed. Again, the other capacitive controls shown in Fig. 7 are analog to those, as explained with reference to the two left, so that they are not further explained and not further provided with reference numerals.

Likewise, it can be provided that an optically diffuse filling material is designed as a tolerance compensation element, which is arranged with a flush and thus planar conclusion to the surface.

Also in the embodiment in Fig. 7, the actuating plunger 17 and 25 are dimensionally stable and in particular length-stable and displaceable in the carrier element 16 in the respective channels in the vertical direction and thus y-direction to the carrier element 16.

LIST OF REFERENCE NUMBERS

1 operating device

 2 to 8 operating elements

 2a to 8a first capacitor plates

 2b to 8b second capacitor plates

2c to 8c touch zones

 2d to 8d annular zones

 9 circuit board

 10 metal plate

 1 1 top

 12 contact area

 13 contact spring plate

 13a to 13g holes

 14 adhesive film

 15 adhesive film

 16 carrier element

 17 actuating tappet

 18 channel

 19 tolerance compensation element

20 bottom

 21 control panel

 22 fingers

 23 touch zone

 24 Tolerance compensation element

25 actuating tappets

 26, 27 recesses

 28, 29 adhesive films

 30, 31 Tolerance compensation elements

32 bottom

 33 light source

 34 opening

 131 edge

 131 a to 131 h straps

Claims

claims

Operating device (1) for a domestic appliance, having at least one capacitive control element (2 to 8), which has a first capacitor plate (2a to 8a) and a second capacitor plate (2b to 8b), wherein the second capacitor plate (2b to 8b) on the is arranged and relatively deformable relative to the first capacitor plate (2a to 8a), so that depending on the deformation a distance change between the two capacitor plates (2a to 8a, 2b to 8b) can be generated, and depending on the change in distance with the operation of the operating element ( 2 to 8), wherein the capacitive operating element (2 to 8) is arranged inside in the operating device (1), characterized in that a touchable control panel (21) is formed, which has a flat outer surface with at least one contact zone ( 23), wherein the contact zone (23) with a arranged under the control panel (21) length-stable Betätigungsstöß El (17, 25) is coupled, and the actuating plunger (17, 25) on the other hand with the second capacitor plate (2b to 8b) is coupled, so that an actuated deformation of the control panel (21) at the contact zone (23) on the second capacitor plate (2b to 8b) is transferable.

Operating device (1) according to Claim 1, characterized in that the upper side of the second capacitor plate (2b to 8b) is coupled to a first end (17a) of the length-stable actuating tappet (17, 25) which is connected to the second end (17b) touchable control panel (21) is coupled.

Operating device (1) according to claim 2, characterized in that between the first end (17a) and the second capacitor plate (2b to 8b) a tolerance compensation element (30, 31) is formed and / or between the second end (17b) and the control panel (21) a tolerance compensation element (19, 24) is formed.

4. Operating device (1) according to claim 3, characterized in that a tolerance compensation element (19, 24, 30, 31) is at least partially transparent to light in the visible to human spectral range.

5. Control device (1) according to one of the preceding claims, characterized in that between the control panel (21) and the second capacitor plate (2b to 8b) an electrically insulating support member (16) is arranged.

6. Operating device (1) according to claim 5, characterized in that the carrier element (16) is at least partially transparent to light in the visible to the human spectral range.

7. Operating device (1) according to one of the preceding claims, characterized in that the actuating plunger (17, 25) is at least partially transparent to light in the visible to the human spectral range.

8. Operating device (1) according to claim 7, characterized in that on a printed circuit board (9), in particular on a lower side (32), a light source (33) is arranged, the emitted light in the actuating plunger (17, 25) can be coupled ,

9. Operating device (1) according to one of the preceding claims, characterized in that between the second capacitor plate (2b to 8b) and a printed circuit board (9), at the top of which the first capacitor plate (2a to 8a) is formed, an electrically conductive contact spring plate (13) is arranged without contact with the first capacitor plate (2a to 8a) and in electrical contact with the printed circuit board (9) and the second capacitor plate (2b to 8b), the contact spring plate (13) having a hole (13a) in the region between the first capacitor plate (2a to 8a) and the second capacitor plate (2b to 8b) is positioned.

10. Operating device (1) according to claim 9, characterized in that the contact spring plate (13) at the edge (131) of the hole (13 a) at least one tab (131 a to 131 h), which is in electrical contact with the printed circuit board (9) and the second capacitor plate (2b to 8b).

1 1. Operating device (1) according to claim 10, characterized in that a for contacting by the contact spring plate (13) provided for electrical contact area (12) on the circuit board (9) is formed directly, in particular the first capacitor plate (2a to 8a) electrically surrounded by this isolated.

12. Operating device (1) according to claim 10 or 1 1, characterized in that the tab (131 a to 131 h) relative to the plane of the contact spring plate (13) is arranged obliquely, so that through the tab (131 a to 131 h ), a spacer element is formed, through which a greater distance compared to the untwisted position between the first (2a to 8a) and the second capacitor plate (2b to 8b) results.

13. Operating device (1) according to any one of claims 10 to 12, characterized in that the tab (131 a to 131 h) from the edge (131) of the hole (13 a) is radially inwardly and a front free end of the tab (131 a to 131 h) before the outer edge of the first capacitor plate (2a to 8a) ends.

14. Control device (1) according to one of the preceding claims, characterized in that the second capacitor plate (2b to 8b) is integrated in a metal plate (10) and / or the control panel (21) is a metal plate.

15. Household appliance with an operating device (1) according to one of the preceding claims.