WO2010089206A1 - Capacitive touch sensor - Google Patents

Abstract

The invention relates to a control element (10), comprising: a capacitive proximity sensor (12, 13, 14) having at least one capacitor electrode (13) for generating a measurement field in an approach region facing the operator on a control surface of the control element (10) and an evaluation and control circuit (12), which is connected to the capacitor electrode (13) in a conductive manner, wherein the capacitance of the capacitor electrode (13) can be determined by means of the evaluationand control circuit (12), and wherein a control process is carried out when the capacitance changes. The control element (10) is characterized in that at least one conductive, electrically insulated layer (11, 16) is arranged in the measurement field and forms a touch surface as the control surface.

Description

 Designation: Capacitive touch sensor

The invention relates to an operating element which has a capacitive proximity sensor. The sensor comprises at least one capacitor electrode for generating a measuring field in an approach area facing the operator to a user interface of the operating element and an evaluation and control circuit which is connected to the capacitor electrode. By means of the evaluation and control circuit, the capacitance defined by the capacitor electrode can be determined.

A capacitive proximity sensor or switch is a non-contact sensor - d. H. without direct contact - on approach of a conductive or non-conductive object, but also of liquids, reacted with an electrical switching signal. It uses the thereby changing electrical capacitance of a capacitor electrode to the environment or a reference electrode. Such sensors work with an oscillator whose frequency-determining capacity is partly formed by the medium or environment to be detected.

When the measuring field of the probe capacitance is influenced by a nonconductor, the capacitance change is based on a change in the effective dielectric constant in the area of the measuring field; The achievable switching distance is up to 40 mm, depending on the size of the sensor. When the field is influenced by a conductive object, the switching distance can increase to approx. 60-80 mm. Capacitive proximity sensors and their control and evaluation unit usually provide a possibility of calibration in order to adapt the sensitivity or the switching thresholds to the conditions of use. With high sensitivity, however, the influence of disturbance variables (eg humidity, dirt) increases.

The known proximity sensors have the disadvantage that the switching distance is very much dependent on the environmental properties as well as the nature of the introduced into the measuring field object so the hand of an operator and the approach angle. For example, the switching distance is increased in the case of a moist skin surface. In addition, the response capacitive proximity switch by a hysteresis characterized. In addition, the electromagnetic field emitted in the direction of the operator can prove to be critical from an EMC point of view and its strength can not be arbitrarily increased.

If touch detection is to be performed with a proximity sensor, this can not be achieved in a reproducible manner, since the switching thresholds to be defined are subject to considerable fluctuations due to environmental conditions, such as temperature, interference fields.

Furthermore, capacitive touch sensors are known. In its simplest form, a capacitive touch sensor consists of two adjacent, electrically conductive, plate-shaped electrodes. These form a capacitor whose capacitance is directly proportional to the thickness of the plates and inversely proportional to the distance between them. As soon as a conductive object such as a finger approaches the two plates, an additional parallel capacity is added to the self-capacitance of the device. To determine the operation of such a switching element, this capacitance change must be measured. A disadvantage of the contact sensors is that the contacting of the near Berühroberflächennahen electrodes is relatively expensive, and they can be easily disturbed or destroyed by electrostatic discharge. The possibilities regarding the introduction of symbols and their fluoroscopy as well as regarding the surface design are subject to great restrictions due to the mandatory, near-surface arrangement of the electrodes and their contacting.

Against the background of the above disadvantages of the prior art, the inventors have set themselves the task of providing an operating element of the type described above, which is reliable to use and easy to manufacture. This object is achieved by an operating element according to claim 1. An equally advantageous manufacturing method is the subject of the independent claim. Advantageous embodiments are the subject of the dependent claims. It should be noted that the features listed individually in the claims can be combined with each other in any technologically meaningful way, and show further embodiments of the invention. The description, in particular in connection with the figures, additionally characterizes and specifies the invention.

The invention relates to an operating element, which has a capacitive proximity sensor with at least one capacitor electrode for generating a measuring field in an approach region facing the operator to a user interface of the operating element and an evaluation and control circuit. In the proximity sensor, the evaluation and control electrode is connected by means of an electrical conductor to the at least one capacitor electrode. The evaluation and control circuit serves to determine the capacitance defined by the capacitor electrode, for example with respect to the environment or a counterelectrode, and to carry out a switching or regulating operation when the capacitance changes. Such proximity sensors are known from the prior art and constructed comparatively space-saving.

The operating element according to the invention is characterized in that at least one conductive, electrically insulated layer is arranged in the measuring field, which at least partially forms a contact surface as a user interface. The arrangement of the conductive layer in the measuring field has the advantage that the electromagnetic measuring field generated by the proximity sensor is reduced on the side of the layer facing away from the sensor and thus a shielding is achieved. This reduces the electromagnetic interference caused by the proximity sensor in the operating area. For example, it may also be a non-closed area, for example a grid, In general, the layer will have at least one dimension corresponding to the extent of the proximity sensor The layer can easily meet the optical requirements For example, the layer may be adapted to the appearance of the environment of the operating element in order to be visually inconspicuous or not recognizable. Since the layer can be relatively large and it does not matter where it is touched, operating errors can be avoided. The layer may have any shapes, may be flat or curved. The area defined by the layer is preferably formed parallel to the area defined by the capacitor electrode, so that the sensitivity of the operating element according to the invention is as little as possible dependent on the contact point on the insulated, conductive layer.

In addition, the arrangement of the conductive layer in the user interface causes the charge carriers induced thereon to flow off when the layer touches, and the resulting sudden capacitance change can be very well detected by the evaluation and control unit. Thus, the reliability of the switching operation can be improved. Ambient and Hystereseeinflüsse can be reduced, since at the latest when touching the conductive layer by the associated, relatively large jump change in the capacity of the switching is triggered.

Preferably, the at least one insulated, conductive layer and the control and evaluation unit are designed so that the switching operation is performed only by touching the user interface by the control circuit in order to increase the reliability of operation. This can easily be done, for example, by adjusting the sensitivity of the evaluation unit.

The control element according to the invention is not limited to one, ie single, conductive layer, but it may be provided a layer structure of a plurality of conductive, insulated layers. For example, a second, less conductive, the actual user interface forming layer may be applied to a first, more conductive layer. For example, the second layer is achieved by painting with a conductive paint. It depends on the conductivity that a detectable capacitance jump in contact with the respective outer and thus touchable layer can be determined. According to a further advantageous embodiment, the conductive, insulated layer or the layer structure is formed as a coating of a diaphragm or cap body of an operating element in order to be able to produce the layer easily and to give it sufficient stability.

The diaphragm or cap body is preferably arranged between the proximity sensor and the insulated, conductive layer or layer structure. As a result, the proximity sensor is protected from environmental influences, such as moisture.

According to a further advantageous embodiment, the proximity sensor is arranged adjacent to the diaphragm or cap body. For example, it is the cap body of a button or a knob. This is to make it clear that the control element according to the invention can act alone as a control element, but it is also possible that the controls according to the invention can be provided by combinations with other types of controls with other functionalities. For example, the insulated conductive layer is applied to a movable cap body to manually perform a switching or regulating operation by moving it.

In order to simplify the production and to increase the design freedom, the at least one insulated, conductive layer is formed by a conductive lacquer or a conductive PVD coating.

The invention further relates to a motor vehicle, which is advantageously characterized by an operating element in one of the previously described embodiments. For example, the control element according to the invention is integrated in a dashboard or a control panel.

The invention further relates to a method for producing a control element. In an assembly step of the method according to the invention, a capacitive proximity sensor with at least one capacitor electrode for generating a measuring field in an approach area facing the operator to a user interface of the operating element and an evaluation and control circuit connected to the capacitor electrode is conductively connected, mounted under a diaphragm or cap body of the control. By means of the evaluation and control circuit, the capacitance of the capacitor electrode can be determined. The evaluation and control circuit further performs a switching operation upon detection of a change in the capacitance. The method is further characterized by a coating step, for example a PVD coating, a coating or the like, in which the diaphragm or cap body is at least partially provided with at least one insulated, conductive layer which is arranged in the measuring field of the proximity sensor. By virtue of the method, the operating element according to the invention with the advantages described above can be produced comparatively easily.

The invention and the technical environment will be explained in more detail with reference to FIGS. It should be noted that Figure 2 shows a particularly preferred embodiment of the invention, but this is not limited thereto. They show schematically:

Fig. 1 is a sectional view of a non-inventive control element;

2 shows a sectional view of an operating element according to the invention.

FIG. 1 shows a sectional view of a control element not according to the invention

1, which comprises a proximity sensor 2, 3, 4. The proximity sensor 2, 3, 4 has a capacitor electrode 3, which generates a measuring field directed upward in FIG. By means of the line 4, the capacitor electrode 3 is conductively connected to an evaluation and control unit 2. The proximity sensor

2, 3, 4 is arranged on a surface facing away from the operator of a diaphragm or key cap 5. The key cap 5 is provided with a paint 6 for decoration. The evaluation and control unit 2 serves to detect a change in capacitance of a capacitor formed by the capacitor electrode 3 to ground. The capacitance change is effected, for example, by the movement, for example, approach of a hand in the measuring field. By in the evaluation and control unit 2 predetermined switching thresholds, a switching operation can be performed. The proximity sensor 2, 3, 4 has the disadvantage that the predetermined by the switching thresholds switching distance depends very much on the environmental properties as well as the nature of the introduced into the measuring field object so the hand of an operator and the approach angle. For example, the switching distance is increased in the case of a moist skin surface. In addition, the response of capacitive proximity switches is characterized by a hysteresis. In addition, the electromagnetic field emitted in the direction of the operator can prove to be critical from an EMC point of view and its strength can not be arbitrarily increased. If touch detection is to be carried out with a proximity sensor, this is difficult, since the switching thresholds to be defined are subject to strong fluctuations due to environmental conditions, such as temperature, interference fields.

FIG. 2 shows a comparison of a preferred embodiment 10 of the operating element according to the invention. This likewise comprises a proximity sensor 12, 13, 14. The proximity sensor 12, 13, 14 has a capacitor electrode 3 which generates a measuring field directed upward in FIG. By means of the line 14, the capacitor electrode 13 is conductively connected to an evaluation and control unit 12. The proximity sensor 12, 13, 14 is arranged on a surface facing away from the operator surface of a diaphragm or key cap 15. The key cap 15 is provided with a conductive layer structure of a first insulated conductive layer 11 and a second insulated less conductive layer 16 applied over it. The isolated, conductive layers 11, 16 located in the measuring field cause the electromagnetic measuring field generated by the proximity sensor 12, 13, 14 to be greatly reduced on the side of the layers 11, 16 remote from the sensor 12, 13, 14, and thus a shading is reached. As shown, the layers 11, 16 have an extension that exceeds the extent of the capacitor electrode 3.

In addition, the arrangement and design of the conductive layers 11, 16 as a user interface, that upon contact of the layers 11, 16, the charge carriers induced thereon can flow off and the resulting sudden capacitance change can be detected very well by the evaluation and control unit 12. Thus, the reliability of the switching operation can be improved. Ambient and hysteresis influences can be reduced because at the latest when touching the conductive layers 11, 16 can be triggered by the concomitant, relatively large jump change in the capacity of the switching operation. Thus, the inventive design of the capacitive proximity sensor 12, 13, 14 to the touch-sensitive control element 10th

Claims

claims

A control element (10), comprising: a capacitive proximity sensor (12, 13, 14) having at least one capacitor electrode (13) for generating a measuring field in an approach region facing the operator to a user interface of the control element (10) and an evaluation and control circuit (12), which is conductively connected to the capacitor electrode (13), wherein by means of the evaluation and control circuit (12) the capacitance defined by the capacitor electrode (13) can be determined and when changing the capacitance, a switching operation is performed, wherein the operating element ( 10) is characterized in that in the measuring field at least one conductive, electrically insulated layer (11, 16) is arranged, which forms a contact surface as a user interface.

2. Control element (10) according to claim 1, characterized in that the at least one insulated, conductive layer (11, 16) and the control and evaluation unit (12) are designed so that only by touching the contact surface by the evaluation and Control circuit (12) of the switching operation is performed.

3. Operating element (10) according to any one of claims, characterized in that the operating element (10) comprises a layer structure of a plurality of conductive, insulated layers (11, 16).

4. Control element (10) according to one of the preceding claims, characterized in that the conductive, insulated layer (11) or the layer structure (11, 16) as a coating of a diaphragm or cap body (15) of the operating element (10) is formed.

5. Operating element (10) according to the preceding claim, characterized in that the diaphragm or cap body (15) between the proximity sensor (12, 13, 14) and insulated, conductive layer (11) or layer structure (11, 16) is arranged.

6. operating element (10) according to the preceding claim, characterized in that the proximity sensor (12, 13, 14) adjacent to the diaphragm or cap body (15) is arranged.

7. Operating element (10) according to one of the preceding claims, characterized in that the at least one insulated, conductive layer (11, 16) is formed by a conductive paint or a conductive PVD coating.

8. Motor vehicle characterized by an operating element (10) according to one of the preceding claims.

9. A method for producing a control element, comprising an assembly step, in which a capacitive proximity sensor with at least one capacitor electrode for generating a measuring field in an operator facing the proximity area to a user interface of the control element and an evaluation and control circuit which is connected to the capacitor electrode, be mounted under a user interface forming Aperture or cap body of the control, wherein by means of the evaluation and control circuit, the capacitance of the capacitor electrode can be determined and when changing the capacitance, a switching operation is performed; characterized by a coating step in which the diaphragm or cap body is at least partially coated with at least one insulated, conductive layer which is arranged in the measuring field of the proximity sensor to form a contact surface as a user interface.