DE202010005412U1 - Switching device with capacitive sensor for electrical components in a piece of furniture - Google Patents

Abstract

Switching device for an electrical component located in a piece of furniture (1), in particular an electromotive furniture actuator (3), comprising a switching unit (10) and a capacitive sensor (20) with at least one electrode (22), the electrical component being approximated the sensor (20) or can be switched by touching the sensor (20), characterized in that the sensor (20) is suitable for arrangement on a piece of furniture and in which the electrode (22) of the sensor (20) has a layered design.

Description

The invention relates to a switching device for a located in a furniture electrical component, in particular an electromotive furniture actuator with a capacitive sensor.

In many furniture are integrated electrical or electronic components, such. As lamps, heating and / or cooling devices or adjusting motors that can be switched via appropriate controls in cooperation with a switching unit by the user.

Adjustment motors are often part of a furniture actuator for moving furniture parts against each other, for example, for height adjustment of tables or foot and headboards in beds or armchairs. In such Möbelstellantrieben it is necessary to switch off the adjustment motor immediately when a body part is in the range of movement of the furniture actuator and a risk of entrapment exists.

From the publication DE 93 00 438 U1 is provided as anti-trap, to use a metallic scissors of such a designed furniture actuator as a capacitive sensor, is switched off in cooperation with an evaluation and switching unit of the furniture actuator when the scissors is touched or approaching a body part of the scissors questionably. This solution, in which a part of the furniture actuator itself is used as a capacitive sensor, but can only be used in connection with moving metallic parts of a furniture actuator application.

It is therefore an object of the present invention to provide a switching device for a located in a furniture electrical component with a capacitive sensor that can be used as anti-trap for monitoring even non-metallic moving furniture parts and beyond for manual switching operations.

This object is achieved by switching device with a capacitive sensor with the features specified in the protection claim 1.

The switching device according to the invention for a located in a furniture electrical component, in particular an electromotive furniture actuator, has a switching unit and a capacitive sensor with at least one electrode, wherein the electrical component is switched by approaching the sensor or by touching the sensor. It is characterized in that the sensor is suitable for arrangement on or in a furniture part and in which the electrode of the sensor is designed in layers.

Such a sensor that can be easily mounted on a surface of a furniture part or in a furniture part, eg. As a cushion can be integrated, allows in a simple and cost-effective way, the realization of a pinch protection even with a non-metallic furniture part. Properly positioned, such a sensor in cooperation with the switching unit as well as control element for a manual switching of electrical components, eg. As lamps or the motors of the furniture actuators used. In this case, the upholstery or the upholstery cover may be part of the layered sensor. In this case, the switching unit on suitable switching means which the high currents of the consumer, such. B. lamps or turn the motors of the furniture actuators, wherein the switching unit is still associated with at least one sensor.

Preferred embodiments and advantageous developments are specified in the dependent claims.

In the following the invention will be explained in more detail by means of embodiments with the aid of figures.

The figures show:

1 a switching device with a capacitive sensor, used as anti-trap in a height-adjustable table;

2 a sectional view of a first embodiment of a capacitive sensor;

3 a sectional view of a second embodiment of a capacitive sensor; and

4 a plan view of a third embodiment of a capacitive sensor.

1 shows schematically as an example of a piece of furniture 1 a table with a table top 2 that have an electromotive furniture actuator 3 is height adjustable. The electromotive furniture actuator 3 is via a power supply unit 4 with mains connection 5 supplied with electrical power. The power supply unit 4 is with the furniture actuator 3 via a switching unit 10 connected. At the switching unit 10 is a control unit 11 connected, in the example executed as a wired remote control with multiple controls. About this control unit 11 the furniture actuator can be controlled and so the table top 2 be adjusted in height according to the wishes of the user.

To prevent when lowering the table top 2 for example, the legs of the user located under the table are pinched, is at the bottom of the table top 2 a capacitive sensor 20 , in the following also briefly sensor 20 called, arranged. When approaching the sensor 20 to a body part during a movement of the table top 2 down comes a capacitance change of the sensor 20 one by one in the switching unit 10 integrated evaluation unit 12 is detected, whereupon as anti-trap the furniture actuator 3 from the switching unit 10 switched off or briefly operated in the opposite direction and then turned off.

The sensor 20 is flat, in particular strip-shaped. It has a width of a few centimeters to a few decimetres, with which it moves in the direction of the depth of the table top 2 extends. In its length, the sensor covers 20 prefers almost the entire length of the table top 2 from.

The sensor 20 is multi-layered, with one of the tabletop 2 pioneering conductive layer as an electrode 22 and one to the table top 2 facing upholstery layer 23 , As an electrode 22 can a thin continuous metal foil, for. As an aluminum or copper foil can be used. Alternatively, the use of a metallic wire mesh or a number of wire lines or stranded wires as an electrode 22 possible. Also non-metallic but electrically conductive materials, eg. As graphite or a polymerized conductive plastic can as materials for the electrode 22 Find use. Furthermore, the sensor 20 be configured as a flexible circuit board. As a cushion layer 23 For example, a foam layer with a thickness of a few millimeters can be provided. The cushion layer 23 serves on the one hand the electrical insulation of the electrode 22 of possibly conductive areas of the tabletop 2 , On the other hand, the reduced by the cushion layer 23 reached distance of the electrode 22 from the table top 2 a (parasitic) capacitive coupling between the table top 2 and the electrode 22 , This increases the sensitivity and the stability of the arrangement as a proximity switch or as a proximity sensor for anti-trap protection. In the case of pinching objects or body parts, eg. For example, if the presented here electronic anti-trap (not), the compressible cushion layer provides 23 an additional mechanical anti-trap protection.

In the embodiment, wherein the electrode 22 is designed as a wire line or stranded wire, an electrical insulating layer is provided which surrounds the wire or the line at least in sections. According to this embodiment of an electrode 22 This could also be considered a very narrow electrode 22 be designated, which with a strip-shaped sensor 20 is trained. For this purpose, the formed as a wire or as a lead electrode forms 22 together with the at least partially surrounding insulating layer a layered sensor 20 wherein a longitudinally extending portion of the insulating layer may be provided with or be in communication with an adhesive layer. According to this last-mentioned embodiment of a layered sensor 20 stands the adhesive layer 26 with a movable or a fixed component of a piece of furniture 1 , for example with a table top 2 adhesive, wherein as further layer an insulating layer of the electrode 22 , which is designed as a wire or as a line, is provided. The subsequent layer is formed by the electrode and as a further or as a final layer is the insulating layer of the electrode 22 , which is designed as a wire or as a line provided. According to this embodiment of a sensor 20 this can advantageously very easily and simply along a designed as a link fitting furniture component, which is designed for example in the form of an armchair fitting or a function fitting for armchairs or beds.

When approaching the electrode 22 to a body part, z. B. to the legs of a user of the furniture 1 , the capacity of the electrode changes 22 opposite to the acting as a reference electrode surrounding ground or ground potential. This capacitance change of the electrode 22 is from the evaluation unit 12 recorded and evaluated.

The flat design of the sensor 20 offers the advantage that even large-scale moving furniture parts, as in the example shown, the table top 2 , can be hedged. The sensor 20 can be made to order for certain furniture parts or manufactured by the meter. Meterware can then be cut to the required size, which also includes retrofitting furniture 1 makes it possible in a simple way. Also conceivable is the sensor 20 produce strip-shaped with predetermined width and any length as a roll material or endless strip. The application of the sensor 10 on a surface of the furniture 1 happens advantageous via an adhesive connection. For this purpose, preferably in the 1 not shown adhesive layer on the cushion layer 23 be applied so that the sensor 20 is self-adhesive. As an alternative to a sensor 20 , which is prefabricated at least with respect to its layer structure is still conceivable, the individual layers of the sensor 20 to apply manually one after the other to the surface of the furniture.

2 shows in a schematic sectional view of another embodiment of a sensor 20 , The same reference numerals designate the same or the same elements in all figures. As in the first embodiment, this sensor 20 an electrode formed by a conductive layer 22 and a padded layer associated therewith 23 on. Regarding the usable materials and the dimensioning of these layers is related to 1 referenced embodiment described.

In the embodiment shown is an adhesive layer 26 on the cushion layer 23 applied and the electrode 22 is with an insulating layer 21 covered. The insulating layer 21 used in addition to the electrical insulation as a protective layer, eg. B. against the absorption of moisture. In addition, the insulating layer 21 be provided with decorative elements. An adhesive method can also be used to join the layers together. Depending on the nature of the layer, a vapor deposition or Aufsprühverfahren is conceivable, for. B. in the case of a graphite layer as an electrode 22 ,

For contacting the electrode 22 is in the embodiment of 2 a hollow rivet 31 provided by the entire layer structure of the sensor 20 is guided. In another embodiment, however, not shown is the rivet 31 only with the electrode 2 connected. The rivet 31 includes a washer with a contact element, for. As a Lötfahne or a cable lug, in the example shown on the side of the adhesive layer 26 is positioned. About the contact element is the connection to the connection 30 made, the electrode 22 over the rivet 31 will be contacted. Alternatively, it is possible with the electrode exposed 22 the connection 30 mechanically and electrically via a soldering or bonding with the electrode 22 connect to. In addition, a capacitive coupling of the connection 30 to the electrode 22 possible. For this purpose, the connection 30 on the side of the sensor 20 in turn be enlarged to a small-area electrode, the z. B. on the insulating layer 21 is glued on. The connection 30 then capacitively couples with the electrode 22 ,

3 shows in the same way as 2 another embodiment of a capacitive sensor 20 , In contrast to the embodiments shown above, the sensor 20 of the 3 another electrode 24 on top of that from the electrode 22 through the padding layer 23 spaced apart. The further electrode 24 is also connected to the evaluation unit 12 connected and serves as a reference electrode. A detectable capacitance change results on the one hand, as before, by approaching the first electrode 22 , On the other hand, a change in capacitance occurs when the distance between the two electrodes 22 . 24 at least at one point to each other in deformation of the compressible cushion layer 23 changes. This can also objects in Einklemmbereich be detected, which is a sensor 20 with only one electrode 22 not possible.

In addition, another insulating layer 25 provided, which is analogous to the padding layer 23 in the embodiments of the 1 and 2 the insulation and spacing of the electrode, here the other electrode 24 , to the surface of the furniture 1 serves. Another difference to the embodiments shown above concerns the cushion layer 23 , which is executed here broken, z. B. to influence the compressibility. In addition to the layer structures shown in the exemplary embodiments, further combinations of the various layers are conceivable, depending on the intended use. In the simplest case, the capacitive sensor, for example, by a combination of a metal foil as an electrode 22 and an adhesive layer 26 be formed. A single-core cable encased in an insulating layer on the furniture surface also provides a strip-shaped capacitive sensor in this sense 20 represents.

4 shows a further embodiment of a capacitive sensor 20 in a supervision. In this embodiment, the insulating layer is 21 made larger in size than the electrode in their lateral dimensions 22 and as further, underlying the electrode and not visible in this figure layers. The insulating layer 21 is advantageously carried out as a self-adhesive film, so that on the supernatant on the one hand, the entire sensor 20 can be attached to the furniture surface and on the other hand, a hermetic seal of the layer structure of the sensor 20 he follows. In this way, in particular the cushion layer 23 protected from water absorption, which adversely affects the electrical properties of the sensor 20 can affect. This is especially true for sensors with two electrodes, such as in 3 shown in cross section.

Furthermore, in the embodiment of the 4 the evaluation unit 12 integrated on the sensor 20 arranged and not, as in the example of 1 shown in the switching unit 10 integrated. As output of the evaluation circuit 12 For example, a digital signal indicative of its level, whether touching or approaching the sensor, can be delivered 20 or according to the 3 a deformation of the sensor 20 present or not. The transmission of a digital signal in the connection 30 is far less susceptible to interference than the transmission of an analog signal between the sensor 20 and the evaluation circuit 12 about the connection 30 , To power the evaluation unit 12 are appropriate power supply lines in the connection 30 integrated. As another Alternative may be provided, the evaluation unit 12 externally from the switching unit 10 and externally from the sensor 20 to arrange in a separate housing. Advantageously, this housing is then positioned close to the sensor.

Especially with capacitive sensors 20 that only one electrode 22 have a switching point adjustment, also called zero point adjustment, in the evaluation circuit 12 necessary. In order to be able to compensate for environmental influences and / or changing material properties over time, the zero point adjustment is preferably carried out by the evaluation unit 12 automatically made. For example, it can be performed automatically each time the switching unit 10 or the evaluation unit 12 is energized again after restarting the system. Alternatively or additionally, it is possible to balance with each operation of a furniture actuator 3 progress increase. Such adjustment takes only fractions of seconds and delays the start of the furniture actuator 3 so that only insignificant. Furthermore, such a calibration can also be designed in the manner of an automatic calibration, wherein the calibration process after a predetermined period of time during operation of the furniture actuator 3 is initiated and completed within another predetermined period of time. Furthermore, the automatic calibration process can be performed at each start-up or after a fixed and / or random number of start-ups of the furniture actuator 3 be started, with the calibration by the switching unit 10 , through the evaluation unit 12 or through the control unit 11 can be set in motion.

In addition to use as anti-trap, the switching device according to the application with capacitive sensor can also be used as a manually operated hand switch or as a seat cushion switch to switch integrated into a furniture electrical appliances such as lamps or seat heaters. When used as a seat cushion switch, a sensor 20 according to the 3 be incorporated into the mattress of a bed or communicate with it, whereby the presence of a person resting in the furniture person can be monitored. If a person resting in the furniture is no longer recognized, certain electrical adjustment movements of the furniture can be blocked or an alarm function can be issued.

QUOTES INCLUDE IN THE DESCRIPTION

This list of the documents listed by the applicant has been generated automatically and is included solely for the better information of the reader. The list is not part of the German patent or utility model application. The DPMA assumes no liability for any errors or omissions.

Cited patent literature

• DE 9300438 U1 [0004]

Claims (16)

Switching device for yourself in a piece of furniture ( 1 ) located electrical component, in particular an electromotive furniture actuator ( 3 ), comprising a switching unit ( 10 ) and a capacitive sensor ( 20 ) with at least one electrode ( 22 ), wherein the electrical component is approached by the sensor ( 20 ) or by touching the sensor ( 20 ), characterized in that the sensor ( 20 ) suitable for arrangement on a furniture part and in which the electrode ( 22 ) of the sensor ( 20 ) is layered. Switching device according to Claim 1, in which the sensor ( 20 ) is strip-shaped. Switching device according to Claim 2, in which the electrode ( 22 ) is a metal foil, a conductive plastic film or a wire mesh. Switching device according to one of Claims 1 to 3, in which the sensor has a multilayer structure and is next to the electrode ( 22 ) has at least one of the following additional layers: a cover layer ( 21 ) on the furniture ( 1 ) facing away from the sensor ( 20 ); - a cushion layer ( 23 ), adjacent to the furniture ( 1 ) facing side of the electrode ( 22 ); An insulating layer ( 25 ); An adhesive layer ( 26 ) for applying the sensor ( 20 ) on a surface of the furniture ( 1 ). Switching device according to Claim 4, in which the sensor ( 20 ) another electrode ( 24 ), which is likewise designed in layer form and from the electrode ( 22 ) through the cushion layer ( 23 ) is disconnected. Switching device according to Claim 4 or 5, in which the cover layer ( 21 ) laterally across the electrode ( 22 ) and optionally over further layers of the sensor ( 20 protrudes, wherein at least the protruding portion of the cover layer ( 21 ) is provided with an adhesive layer. Switching device according to one of claims 1 to 6, comprising an evaluation unit ( 12 ) for evaluating a signal of the sensor ( 20 ) and for providing a switching signal for controlling the switching unit ( 10 ). Switching device according to Claim 7, in which the switching signal of the evaluation unit ( 12 ) is a digital signal. Switching device according to Claim 7 or 8, in which the evaluation unit ( 12 ) in the switching unit ( 10 ) is integrated. Switching device according to Claim 7 or 8, in which the evaluation unit ( 12 ) in the sensor ( 20 ) is integrated. Switching device according to one of claims 1 to 10, wherein the evaluation unit ( 12 ) makes a comparison with an automatically determined reference value for providing the switching signal. Switching device according to claim 12, which is adapted to determine the reference value at each start-up. Switching device according to one of claims 1 to 12, comprising an operating unit for manual actuation of the switching device. Switching device according to claim 11 and 13, which is adapted to determine the reference value in each manual operation of the switching device. Switching device according to one or more of the preceding claims, in which the electrode ( 22 ) of the sensor ( 20 ) consists of a metal foil, wire or stranded wires or a non-metallic, but electrically conductive material. Switching device according to one or more of the preceding claims, in which the sensor ( 20 ) is designed as a flexible printed circuit board.

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