DE102008036442A1 - Operating plate for household appliance e.g. washing machine, has electrode that is connected to ground and another electrode that is connected to electrically conducting operating plate - Google Patents

Abstract

The operating plate (100) has operating element (20) that is arranged on the electrically conductive plate. An electrode of operating element is connected to ground through a capacitance element. Another electrode is connected to the electric conductive plate. The operating element is connected to a receiving device (10). An independent claim is included for receiving device.

Description

The The invention relates to an operating unit for operating household appliances, in particular to operate a hob.

such Operating units are in a variety of ways and manner known in the art. In particular, too Control units for the operation of herds or hobs known.

So are about in the field of hob control rotary switch for operation a hob known which is arranged at the front of the cooker are. The rotary switches are connected to an electronic, which the setting of individual hobs according to the position of Rotary switch performs. Next is also known such rotary switch directly on the surface to arrange the hob, especially in hot plates, which have no have own front panel. The disadvantage here, however, that the rotary switch a certain Take the space of the stove, which then for cooking, so the actual Determination of the stove plate is no longer available. The disadvantage is Also, the rotary switches are subject to wear and so wear material represent.

Further is known from the prior art, on the stove surface or directly under the stove surface touch-sensitive Provide controls, wherein by touching the controls a appropriate adjustment of the respective hobs made can be. The touch-sensitive Controls are also connected here with electronics, which which made on the control Setting for takes the hob. Although this form of controls has the Advantage that they are almost no wear under, but has the Disadvantage on that these controls have a certain amount of space the stove surface take, which then for the cooking is no longer available stands.

Further is known to position controls off the stove plate. This will indeed be available standing space of the stove plate for cooking does not shrink, this Controls need but expensive be wired to the control unit of the stove.

Known are also controls, which by radio the switch positions or transfer settings of the controls to the control unit of the cooker. This has the disadvantage that for the Controls must provide its own power supply. One Another disadvantage is also that the stove with the control can be operated even when the control is not near of the stove is located. For example, the stove can be from another room be turned off, which is particularly disadvantageous if switching on the cooker is done unintentionally.

task The invention is therefore an operating unit for the operation of Household appliances, in particular to provide for the operation of a hob, which from The prior art known disadvantages at least partially avoids. The Task is through the objects solved according to the claims.

Further Details and features of the invention will become apparent from the following Descriptions in connection with the drawing. It shows:

1 an operating unit according to the invention for use with a stove;

2 an operating unit according to the invention for use with a stove in the view from above;

3 a possible embodiment of a control panel; and

4 a possible circuit diagram with a server circuit and a client circuit, wherein the server circuit is arranged on the device to be controlled (stove) and wherein the client circuit (or multiple client circuits) are arranged on or in a control panel, server circuit and client circuit together form the control unit according to the invention ,

1 shows an embodiment of a possible arrangement of a erfindungemäßen control unit for use with a stove or a stove top 120 ,

The operating unit essentially comprises a control panel 100 , at the multiple controls 20 are arranged. The number of provided controls 20 depends essentially on the setting options of the cooker. The control panel 100 is at least partially formed of an electrically conductive material. In the following, conductive material or conductive plate is always understood to mean electrically conductive material or an electrically conductive plate. For example, a conductive plate may be surrounded by an acrylic housing or other plastic housing so that the conductive plate is not visible. The control panel can thus be designed dishwasher safe. However, the control panel should 100 have at least at the points a conductive material to which the individual NEN controls are arranged.

In one embodiment, as in FIG 1 visible, the controls on the surface of the control panel 100 be arranged, the arrangement of the controls 20 preferably takes place where the control panel has a conductive plate. The controls 20 can also be arranged displaceable and / or removable, so that the controls 20 easily cleanable and stowable.

In another embodiment, the controls 20 Part of the control panel 100 be, ie the controls 20 can in the control panel 100 be integrated, and here it is preferable to make sure that the controls 20 so in the control panel 100 be arranged so that they are located in the region of the conductive plate. This can be a control panel 100 be provided, which is easy to clean us in particular child safe can be stowed.

In particular, the control panel 100 be positioned and moved freely beside, in front of or behind the stove. It is also possible the control panel 100 Set up vertically or diagonally behind the stove, which is especially possible when the controls 20 Part of the control panel 100 are. As a result, a large degree of freedom in terms of the arrangement of the control panel 100 or the operating elements 20 reached.

In addition, the operating unit comprises one or more server electrodes 250 , which preferably on one or more sides of the stove 120 are arranged. The arrangement of server electrodes 250 This can be done so that they are essentially not visible from the outside and so do not affect the aesthetics of the stove. The server electrodes 250 are with a server or a server circuit 10 connected.

The following will be related to 1 explains the basic principle of the operation of the control unit according to the invention. A detailed description of how it works is given below 4 ,

The server 10 is designed so that it can generate an alternating electric field, which at the server electrode 250 is radiant or is emitted. This alternating electric field is at the arranged next to the stove control panel 100 coupled (or on the conductive plate of the control panel 100 ). The only prerequisite for the functioning of the operating unit is that it lies in the area of the radiated alternating field so that the alternating field is coupled into the operating panel 100 is possible.

The controls 20 essentially have two electrodes 251 . 252 and a modulation device, wherein the modulation device is coupled to the two electrodes. Are the controls 20 on the control panel 100 arranged, so exists between a lower electrode 251 the controls 20 and the conductive plate of the control panel 100 a capacitive coupling. The finger of an operator of the upper electrode approaches 252 At or touch this, creates a capacitive coupling between the upper electrode and earth.

The on the control panel 100 ( 250a ) coupled electrical alternating field is first to the lower electrode 251 of the operating element 20 coupled. That in the control 20 Coupled alternating electric field can be rectified and so for the power supply of the controls 20 be used. The controls 20 so do not need their own power supply, as they relate the required energy from the alternating electric field.

The between the electrodes 251 and 252 arranged modulation device is designed so that these approaching a finger 60 a load of the server is modulated on the upper electrode or on contact of the upper electrode, preferably amplitude modulated. This change in the load on the server can be detected by an evaluation device of the server. The server or the controls 20 are designed so that the operation of various controls 20 are distinguishable from the evaluation device. The evaluation device can thus the operation of various controls 20 recognize and according to the operated control element 20 a setting of the stove or the stove 120 make. The result of the evaluation of the evaluation device can also be sent to a control unit 151 be forwarded, which then makes the appropriate setting.

An advantage of the operating unit according to the invention is that the control panel 100 without its own energy supply. In addition, no galvanic connection must be provided to the control panel 100 to connect with the stove electronics, as the transmission of operating information from the controls 20 to the server electronics or to the server 10 Capacitive is done by the controls 20 are designed to modulate the load of the server, this modulation being detectable by the server.

2 shows the in 1 shown cooking plate 120 and the control panel 100 from above. In this embodiment, on the right and on the left side of the cooking plate 120 one each over gan ze edge length of the cooking plate extending server electrodes 250 arranged. Both server electrodes are connected to the server circuit or the server 10 coupled so that the one server 10 both the power supply of the controls 20 as well as the evaluation of the operation of the controls 20 regardless of which side of the hob 120 the control panel 100 is parked or stored.

In this example, the entire control panel 100 designed conductive. The controls 20 can therefore be arbitrary on the control panel 100 (integrated on the control panel or in the control panel).

It can controls 20 be provided of various kinds. An example is simple controls 20 , which are intended only for "tapping", such as an on / off switch.

Another example would be a rotary switch 20a , For a rotary switch with different switching states can be realized, it is necessary to provide a specially provided for this requirement area on the control panel 100 provided. One possibility is to provide a rotary switch with a rotor electrode and a stator electrode, wherein the stator electrode part of the control panel 100 but not with the conductive plate of the control panel 100 connected is. The control panel 100 can be designed here so that on the control panel 100 from the server electrode 250 coupled alternating electric field in the stator of the rotary switch can be coupled. Different rotational positions of the rotor electrode compared to. the stator electrode then affect the modulation of the load of the server.

Another example would be a slider 20b , This slider can consist of several side-by-side controls 20 be formed. Another embodiment is for a slider similar to the rotary switch to provide a rotor electrode and a stator, wherein when changing the position of the rotor electrode against. the stator electrode changes the load of the server accordingly. Again, the stator electrode must not touch the conductive plate of the control panel 100 be connected.

Other forms of controls 20 are possible. Depending on the requirements, appropriate electrodes can be provided, as with the rotary switch or slide switch, or it can be the evaluation unit of the server 10 be adjusted accordingly. For example, a long hold of a finger on a control element 20 effect a quick start of the temperature setting.

Will the control panel 100 far enough away from the hob, so that no coupling between the server electrode 250 and the control panel 100 can take place, the control panel 100 not be inadvertently used to operate the hob. An efficient parental control is possible.

3 branches a special design of a control panel 100 , The control panel 100 consists of two (electrically conductive) segments 101 and 102 , wherein these segments are not conductively connected to each other, 103 , The segment 101 has a certain coupling with earth.

On this control panel 100 become the controls 20 arranged with respect to their electrodes in a certain way. As shown above, the controls 20 two electrodes 251 and 252 on. The electrode 252 will be here on the segment 101 arranged, which is coupled to earth. The second electrode 251 will be on the other segment 102 the control panel 100 arranged. Due to the capacitive coupling to earth of the segment 101 this too is through the electrodes 251 and 252 coupled to earth.

This creates an always existing basic coupling of the controls 20 against earth as soon as the control panel 100 is located in the region of the radiated from the server electrode electric field. This existing slight ground-to-ground coupling causes any modulation device 270 the controls 20 the load of the server is constantly modulated with a certain (low) amplitude. The server can detect that the necessary controls 20 located in the server field. Furthermore, the server can detect if individual controls 20 fail because they then cause no load change on the server more. In addition, this low basic coupling can also be used to detect when the control panel 20 removed from the server field. The stove or the stove electronics or the server can then automatically switch off the stove after a certain time.

Furthermore, the control panel 100 also be designed so that between the controls 20 and the conductive plate an insulator 255 (see. 4 ) is provided. This can increase the sensitivity of the controls 20 or the server circuit 10 increase.

4 shows an embodiment (as equivalent circuit diagram) of a control unit. The control panel 20 or the controls 20 are hereinafter referred to as a client or client circuit.

The server circuit 10 consists essentially from a generator 240 and one of an inductance 241 and a capacity 242 formed LC resonant circuit. The LC resonant circuit may be formed as a series resonant circuit or as a parallel resonant circuit. Parallel to the LC resonant circuit is a server electrode 250 as well as an evaluation device 245 ,

The generator 240 the server circuit initially generates an alternating voltage, which is the LC resonant circuit 241 . 242 is supplied to subsequently generate an electric field with a sufficiently large Reichweise. The generated electric field f _c is at the server electrode 250 delivered and at the electrode 250a (which corresponds to the electrically conductive plate) of the client circuit 20 coupled.

The client circuit 20 consists essentially of an electrode device with two electrodes 251 and 252 , a modulation device 270 , where the electrodes 251 . 252 each with the modulation device 270 are coupled. The electrodes 251 form the above-mentioned and described lower electrode of the control element 20 ,

With the coupling of the electric field to the conductive plate 250a At the same time, the client circuit is also supplied with energy.

The arrangement of the server electrode 250 opposite the conductive plate 250a is to be chosen so that the radiated from the server electrode electric field on the conductive plate 250a can be coupled.

That from the server circuit 10 generated and at the server electrode 250 discharged electric field f _c is applied to the conductive plate 250a the client circuit coupled and further by means of capacitive coupling to the electrode 251 coupled. About the coupled electric field f _c is from the modulation device 270 the load of the server circuit is amplitude modulated. This modulation is detectable by the server circuit.

The from the modulation device 270 the client circuit modulation of the load is performed by the evaluation 245 evaluated.

Approaches, as in 4 shown a hand or a finger 60 the second electrode 252 (the upper electrode of the control) of the client circuit 20 , this causes the coupling capacitance C3 to change so that the level at which the load is modulated changes resulting in a changed amplitude of the load.

According to the in 1 and 2 In the embodiment shown, the operating unit can have a plurality of operating elements 20 have multiple client circuits ( 251 . 270 . 252 and 251 ' . 270 ' . 252 ), which are operated with the electric field of the server circuit (ie with a single server circuit). The evaluation device 245 is therefore to be designed such that the amplitude modulations of the load are distinguishable by the two client circuits.

The individual client circuits are designed so that the Evaluation unit of the server circuit from the client circuits separate amplitude modulated load and according to the individual Can associate client circuits. This can be done on the client circuits page different measures be provided.

For example can the individual client circuits provide a free-running oscillator, which each operated with a different oscillator frequency so that at the server circuit (with multiple client circuits) a frequency mixture with different amplitudes is applied, which z. B. separated using a Fourier transform accordingly can be.

Instead of a free-running oscillator may also be present in the client circuits a frequency divider may be provided which determines the frequency of the the server circuit shares radiated electric field. Preferably is the division ratio in the individual client circuits different, so that the individual Client circuits each operate at different frequencies and the load of the server circuit with different frequency amplitude-modulated. Again, at the server circuit (at multiple client circuits) a frequency mix with different ones Amplitudes detected, which z. B. using a Fourier transform accordingly can be separated.

The server circuit or the evaluation unit 245 can with a control unit or device control 151 be coupled.

Claims (15)

Control panel for operating a domestic appliance, comprising an electrically conductive plate ( 100 ) with at least one control element arranged on or in the plate ( 20 ), whereby the operating element ( 20 ) at least one electrode ( 251 ) and at least one electrode ( 252 ), wherein the at least one electrode ( 252 ) forms a coupling capacitance (C3) with ground, wherein the at least one electrode ( 251 ) Capacitive with the electrically conductive plate ( 100 ) can be coupled wherein an operation of the operating element ( 20 ) capacitively to a receiving device ( 10 ), and wherein a load of the receiving device of the coupling capacitor (C3) of the at least one electrode ( 252 ) corresponds to earth. A control panel according to claim 1, wherein the control element ( 20 ) at least one modulation device ( 270 ), wherein the at least one electrode ( 251 ) together with the at least one electrode ( 252 ) and the modulation device ( 270 ) an electrode device ( 20 ). Control panel according to one of the preceding claims, wherein the operating element ( 20 ) is configured such that changing the coupling capacity of the electrode ( 252 ) with earth a change in the load of the receiving device ( 10 ) causes. A control panel according to any one of the preceding claims, wherein one on the conductive plate ( 100 ) coupled electrical alternating field at least partially the electrode ( 251 ) of the electrode device ( 20 ) and the modulation device ( 270 ) for modulating an electrical quantity of the electrode device ( 20 ) as a function of the change in the coupling capacity of the electrode ( 252 ) is configured with earth. A control panel according to claim 4, wherein the modulation comprises an amplitude modulation. A control panel according to any one of claims 2 to 5, wherein the modulation means one of resonant circuit and frequency divider comprises. A control panel according to any one of the preceding claims, wherein each of the electrode means ( 20 ) is configured to cause an indicative of the respective electrode means frequency modulation of the electrical variable. A control panel according to any one of the preceding claims, wherein an electric field radiated from the receiving means is applied to the electrically conductive plate (10). 100 ) and wherein a modulation of the electrical size of the electrode device ( 20 ) a change in the load at the receiving device ( 10 ) causes. A control panel according to any one of the preceding claims, wherein the electrically conductive plate ( 100 ) two segments ( 101 . 102 ), which are separated by an insulator, wherein the at least one electrode ( 251 ) of the operating element ( 20 ) on a first segment ( 101 ), wherein the at least one electrode ( 252 ) of the operating element ( 20 ) on a second segment ( 101 ), and wherein one of the two segments is coupled to ground. Control panel according to one of the preceding claims, wherein between the electrically conductive plate ( 100 ) and the at least one control element ( 20 ) An insulator is arranged. Receiving device, which is designed to cooperate with a control panel according to one of the preceding claims, wherein the receiving device comprises: a circle ( 240 . 241 . 242 . 250 ) for generating an electric field (fc), which in the electrically conductive plate ( 100 ) of the control panel can be coupled, and means ( 245 ) for evaluating an electrical quantity. Receiving device according to claim 11, wherein the evaluation comprises a detection of a load change in the circuit ( 240 . 241 . 242 . 250 ). Receiving device according to claim 12, wherein the Last change comprising at least one frequency modulated component and wherein the Evaluation a separation of the frequency-modulated components of the load change includes. Receiving device according to one of claims 11 to 13, wherein the circuit comprises: - an LC resonant circuit ( 241 . 242 ) with a signal generator circuit ( 240 ), preferably a high-quality LC oscillation circuit, for generating the electric field; and - an electrode device connected in parallel with the LC resonant circuit ( 250 ), wherein the capacitance of the second electrode means forms part of the resonant circuit capacitance and wherein the electric field (fc) generated by the LC resonant circuit can be emitted at the electrode device. Receiving device according to one of claims 11 to 14, comprising means ( 151 ) for setting a device to be operated in accordance with operation of the at least one operating element ( 20 ).