DE102008029567A1 - Illuminated capacitive proximity sensor - Google Patents

Abstract

The invention relates to a capacitive proximity sensor (1) for detecting an approach of a hand of an operator to perform a switching and / or control function in response to this approach, comprising a light source (5), an operator facing the display panel (3), at least a translucent or transparent portion (4) to be backlit by the light of the light source, and at least one conductive, capacitance-forming sensor layer (2a), and (2a) translucent or transparent and in a beam path of the light from the light source (5) the backlit portion (4) is arranged.

Description

The The invention relates to a capacitive proximity sensor for detection an approximation of one Hand of an operator to carry a switching and / or regulating function depending on this approach, wherein the sensor comprises: a light source; Operator facing display panel, the at least one translucent or transparent, to be backlit by the light of the light source Section and at least one conductive, capacitance-forming sensor layer.

capacitive proximity sensors this genus are known. It is also known, a sensor layer with a measuring signal, preferably a time-dependent measuring signal, a control and evaluation unit to generate an associated measurement capacity and the associated capacity change when approaching a foreign object, such as the hand of a person, by evaluating of the measurement signal to be detected by the control and evaluation unit. Known methods for detecting the approach use the measuring capacity, for example as the frequency-determining part of an oscillator whose frequency then as a measure of the unknown capacity the measuring capacity is used. Alternatively, the control and evaluation unit the capacity the measuring capacity determine the capacitive component of the impedance of the measuring capacitance.

Independent of the choice of the specific type of hand detecting the approach capacitive method raises the problem regarding the space-saving arrangement of the capacitance-forming sensor layer without Loss of sensitivity of the sensor. This problem occurs more frequently when the display field of the proximity sensor is backlit for easier locating the sensor. By doing Case of a backlit display panel has been a leading, Capacity building Sensor layer for a sufficient sensitivity of the sensor must be maximally possible, only outside the beam path of the light of the light source can be arranged. For example, the sensor layer is looked at by the operator, arranged beyond the light source, due to the great distance between display panel and sensor layer to a reduced sensitivity leads.

In front In the background of these disadvantages, the inventors have the task put, a capacitive proximity sensor for the Detection of an approach a hand of an operator to perform a switching and / or Control function depending this approach provide that is relatively compact and delicate and at the same time inexpensive to manufacture. This task is done by a sensor of claim 1 solved. Advantageous embodiments are the subject of the dependent claims.

The The invention relates to a capacitive proximity sensor for detection an approximation of one Hand of an operator to carry a switching and / or control function in response to this approach. The approach sensor according to the invention includes a light source, such as a light bulb or an LED. Prefers is the light source due to the low heat generation, high durability and low power consumption around one LED, in addition to that, due to the light weight of one in SMD construction. The proximity sensor according to the invention comprises an operator-facing display panel, which is at least one translucent or transparent, to be backlit by the light of the light source Section, which is configured, for example, the at least in the backlit condition a symbol, a lettering or the like for the operator easily, especially in low ambient light recognize. At least according to the invention a senior, capacity building Sensor layer provided which is translucent and in a beam path of the light from the light source through the section to be backlit is arranged. Ie. Light source, sensor layer and display field are arranged in sequence in the direction of the operator, without it to limit the invention that the sensor layer and the display panel in the above order are arranged. Therefore, in one embodiment, the sensor layer between the operator and the display panel, for example as a coating the user facing surface of the display panel provided be.

Thereby, that the sensor array according to the invention arranged in the beam path is the space requirement of the proximity sensor minimized in the plane perpendicular to the aforementioned beam path. The display field is, for example, a planar element made of plastic, for example a thermoplastic, such as acrylonitrile-butadiene-styrene polymer (ABS) or ABS / polycarbonate (ABS-PC). The transparent or translucent section exists for example, from a polycarbonate or a colored polycarbonate.

Around the comparatively sensitive sensor layer before contact the operator or by foreign objects and action of cleaning fluid to protect, the sensor layer is in a preferred embodiment between the display panel and the light source.

Preferably, the conductive, capacitance is formed de and transparent sensor layer formed as a metallic coating of a transparent or translucent substrate in order to produce the sensor inexpensive. In one embodiment, the substrate is the display panel, wherein its surface facing the light source is metallically coated. The substrate is preferably a flexible film, for example a plastic film of polyethylene terephthalate (PET) or triacetyl cellulose (TAC). It is an alternative embodiment with one of its surfaces, preferably with the uncoated surface, disposed adjacent to the display panel. As a result of the arrangement of the sensor layer close to the display field, a metallic reflecting effect on the side of the operator when the illumination of the light source is switched off is achieved even under strong ambient light. As a result, the section to be backlit is not recognizable even under high ambient light and, when viewed by the operator, can result in an optical "merging" with the surrounding display field, provided that the area of the display area surrounding the section to be backlit is correspondingly colored or painted. This avoids misinformation for the operator who might otherwise have the impression, due to the intense ambient light, that the section to be backlit is backlit.

In a preferred embodiment the substrate is colored and / or surface-treated. For example, a surface roughened the substrate so that the substrate acts as a diffuser and for one uniform illumination the backlit portion of the display provides.

Preferably, the conductive, capacitance-forming sensor layer comprises a material selected from the group consisting of mixed oxide of indium (III) oxide (In ₂ O ₃ ) and tin (IV) oxide (SnO ₂ ), a fluorine-doped tin (IV ) oxide, aluminum doped zinc oxide, antimony doped tin (IV) oxide. It is preferably a mixed oxide (ITO) of a high proportion (for example about 90% by weight) of indium (III) oxide (In ₂ O ₃ ) and a minor proportion (for example about 10% by weight) of tin (IV). -oxide. The coating is applied for example by means of a method selected from the group consisting of sputtering, high vacuum evaporation, sol-gel coating on the substrate.

In a further advantageous embodiment is an elastic shielding element, For example, essentially made of silicone, which provides a breakthrough for one Light channel between the light source and the backlit Section forms. This reduces stray light and the intensity of backlighting increased. The shielding element can in a further embodiment serve the fixing positioning of the substrate.

In a further advantageous embodiment, the flexible film as a one-piece substrate trained conductive extension as a contacting element for electrical Contacting the conductive, capacitance-forming sensor layer over the Trace on. For example, the conductivity of the extension is through achieved the same metallic coating as that of the sensor layer. This so created flexible trace can with trace through a plug contact or by soldering to be connected. Especially through the soldering the number of components is reduced and manufacturing costs saved.

According to one Another advantageous embodiment is a conductor track, for example on a printed circuit board, and a conductive, elastic, to the conductive, capacity building Sensor layer and / or the conductor pressed on contacting element, For example, essentially of silicone, for electrical contact the leading, capacity building Sensor layer over provided the conductor track. This makes comparatively easy and reliable achieved a secure contact of the sensor layer. Prefers is the composition of the material of the contacting element and its dimension from the point of contact to the track to the touch point chosen to the sensor layer, that the associated one Resistance is less than 30 Ω. to Reducing the contact resistance to the conductor track whose surface is, for example electrolytically coated with nickel and / or gold. The contact resistance of the two contact surfaces to the track or to the sensor surface and the resistance of the Contacting element, measured between the two contact surfaces is preferably less than 1 kΩ.

According to one Another advantageous embodiment is the contacting element in the area of at least one of its contact surfaces to the track and the conductive, capacity building Sensor layer concave configured. This will work together with the elasticity the material of the contacting a secure contact with achieved low contact resistance.

In In one embodiment, the contacting element is in the region of Inner circumference of the opening of the shielding arranged, wherein for example, as coaxial with the breakthrough of the shielding arranged hollow element is formed.

Prefers the contacting element and the shielding element are integrally formed. Thereby the assembly is simplified and additionally the production costs reduced.

It is according to one another embodiment of the invention an electrical control and evaluation unit for acting on the Sensor layer with a measuring capacity and for detecting the change the measuring capacity when approaching a hand of a person provided for switching or control purposes.

The The invention further relates to an arrangement of a plurality of proximity sensors in one of the previously described embodiments, wherein the plurality conductive, capacity building Sensor layers as a plurality of electrically insulated coating areas a film are formed as a substrate. Such an arrangement let yourself so comparatively easy and inexpensive manufacture.

Prefers are the associated ones a plurality of contacting elements and / or shielding mat-shaped, thereby simplifying the production and thus the production costs be lowered.

The The invention further relates to a motor vehicle with a proximity sensor or an arrangement of several proximity sensors in one of previously described embodiments, the or these in a control panel, for example in the dashboard, the vehicle are arranged so that the respectively the display fields are facing the driver (operator).

In the attached figures are three preferred embodiments of the capacitive proximity sensor according to the invention 1 . 1' respectively 1'' illustrated, without limiting the invention thereto, show:

1 : A sectional view of the capacitive proximity sensor 1 in a first embodiment;

2 : Another sectional view in another cutting direction of the capacitive proximity sensor 1 ;

3 FIG. 2: another sectional view in a further cutting direction of the capacitive proximity sensor 1 ;

4 FIG. 2: another sectional view in a further cutting direction of the capacitive proximity sensor 1 ;

5 FIG. 3: a perspective sectional view of the capacitive proximity sensor. FIG 1' in a second embodiment; and

6 FIG. 3: a perspective sectional view of the capacitive proximity sensor. FIG 1'' in a third embodiment.

The 1 . 2 . 3 and 4 show the approach sensor according to the invention 1 a first embodiment in section in different cutting directions. The proximity sensor 1 includes a light source 5 , In this light source 5 it is an LED in SMD design on a printed circuit board 9 is soldered. The light source 5 is used to backlight a transparent or translucent section 4 (for example: the letter sequence "CD") of a display field 3 that with its surface 3a an operator, not shown faces. In the beam path of the light from the light source 5 to the backlit section 4 of the display field 3 there is a transparent or translucent substrate 2 , which is adjacent to the user facing away from the surface of the display panel 3 is arranged (see 1 ). The substrate 2 is with a conductive, metallic coating 2a for example, an ITO coating, ie, a mixed oxide with a high proportion (for example about 90% by weight) of indium (III) oxide (In ₂ O ₃ ) and a small proportion (for example about 10% by weight) of tin (IV). oxide on its the light source 5 facing surface provided. To form a light channel 8th is a shielding element 6 made of an elastic, opaque silicone material with a breakthrough 8th provided in which the light source 5 is arranged centrally. The shielding element 6 prevents the leakage of stray light from the light channel 8th and ensures along with the positioning pins 10 for a fixing positioning of the substrate 2 , That in the shielding element 6 arranged, almost cylindrical contacting 7 made of a conductive, elastic silicone material with conductive pigmentation is used for contacting the conductive sensor layer 2a via a conductor track, in addition to the electrical wires to supply the light source 5 on the circuit board 9 is provided, see 3 , The contacting element 7 thus provides the electrically conductive connection via its respective contact surfaces to the sensor surface 2 and to the trace on the circuit board 9 ago. For producing a secure contacting and fixing of the sensor layer 2a is the elastic contact element 7 elastically pre-tensioned by placing it between the circuit board 9 and the display panel 3 passing through with the circuit board 9 bolted (see screws 12 in 2 ) Spacer 11 be held at a fixed distance, be squeezed together. The contacting element 7 can in the area of the contact surface to the circuit board 9 or to the conductor track and in the region of the contact surface to the conductive sensor layer 2a have a concave configuration for reducing the respective contact resistance. To reduce the contact resistance further, the conductor track is at least in the region of the contact surface with the contacting element 7 elec trolytically coated with nickel and gold.

5 shows a second embodiment of the approach sensor according to the invention 1' in a perspective sectional view. The proximity sensor 1' includes a light source 5 ' , In this light source 5 ' It is also an LED in SMD design on a printed circuit board 9 ' is soldered. The light source 5 ' is used to backlight a transparent or translucent section 4 ' (here: the letter sequence "CD") of a display field 3 ' that with its surface 3a ' an operator, not shown faces. In the beam path of the light from the light source 5 ' to the backlit section 4 ' of the display field 3 ' There is a transparent or translucent film substrate 2 ' , which is adjacent to the user facing away from the surface of the display panel 3 ' is arranged. The substrate 2 ' is with a conductive, metallic coating 2a ' for example, an ITO coating, ie, a mixed oxide with a high proportion (for example about 90% by weight) of indium (III) oxide (In ₂ O ₃ ) and a small proportion (for example about 10% by weight) of tin (IV) oxide, on its the light source 5 ' facing surface provided. To form a light channel 8th' is a shielding element 6 ' made of an elastic, opaque silicone material with an opening in which the light source 5 ' is arranged centrally. The shielding element 6 ' prevents the leakage of stray light from the light channel 8th' and provides together with the contact element described below 7 ' for a fixing positioning of the substrate 2 ' , The on the inner circumference of the opening of the shielding 6 arranged, almost tubular contacting 7 ' From a conductive, elastic silicone material is used to contact the conductive sensor layer 2a ' via a conductor track, in addition to the electrical wires to supply the light source 5 ' on the circuit board 9 ' is provided. The contacting element 7 ' thus provides the electrically conductive connection via its respective contact surfaces to the sensor surface 2 ' and to the conductor track and can, as described above in the first embodiment, with concave-shaped For producing a secure contact and fixation of the sensor layer 2a ' are the elastic contact element 7 ' and shielding element 6 ' resiliently biased by placing between the circuit board 9 ' and the display panel 3 ' passing through with the circuit board 9 ' screwed spacer 11 ' be held at a fixed distance, be squeezed together. As described above, the contacting element 7 ' in the area of the contact surface to the printed circuit board 9 ' or to the conductor track and in the region of the contact surface to the conductive sensor layer 2a ' have a concave configuration for reducing the respective contact resistance. In order to reduce the contact resistance, the relevant printed conductor is also at least in the area of the contact surface with the contacting element 7 ' electrolytically coated with nickel and gold.

6 shows the proximity sensor according to the invention 1'' in a third embodiment in a perspective sectional view. The proximity sensor 1'' includes a light source 5 '' , In this light source 5 '' It is also an LED in SMD design on a printed circuit board 9 '' is soldered. The light source 5 '' is used to backlight a transparent or translucent section 4 '' a display field 3 '' that with its surface 3a '' an operator, not shown faces. In the beam path of the light from the light source 5 '' to the backlit section 4 '' of the display field 3 '' is a transparent or translucent, flexible film as a substrate 2 '' , which is adjacent to the user facing away from the surface of the display panel 3 '' is arranged. The substrate 2 '' is with a conductive, metallic coating 2a ' for example, an ITO coating, ie, a mixed oxide with a high proportion (for example about 90% by weight) of indium (III) oxide (In ₂ O ₃ ) and a small proportion (for example about 10% by weight) of tin (IV) oxide, on its the light source 5 '' facing surface provided. To form a light channel 8th'' is a shielding element 6 '' made of an elastic, opaque silicone material with a breakthrough 8th'' provided in which the light source 5 '' is arranged centrally. The shielding element 6 '' prevents the leakage of stray light from the light channel 8th'' and ensures along with the positioning pins 10 '' for a fixing positioning of the substrate 2 '' , The flexible film as a substrate 2 '' has an integrally formed therewith extension 2 B'' on, as a contact element 7 '' for contacting the conductive sensor layer 2a ' with a conductor track serving in addition to the electrical leads for supplying the light source 5 '' on the circuit board 9 '' is provided. This is the extension 2 B'' as a contacting element 7 '' by means of the pressure element 13 '' pressed on the associated trace. The contacting element 7 '' thus provides the electrically conductive connection via the contact surfaces to the conductor on the circuit board 9 '' ago. For producing a secure contacting and fixing of the sensor layer 2a ' be the circuit board 9 '' and the display field 3 '' by means of one on the display panel 3 '' trained spacer 11 '' and the screw 12 '' kept fixed at a distance. To reduce the contact resistance further, the conductor track is at least in the region of the contact surface with the contacting element 7 '' electrolytically coated with nickel and gold.

Claims (17)

Capacitive proximity sensor ( 1 . 1' . 1'' ) for the detection of an approach of a hand of a Be to perform a switching and / or regulating function as a function of this approach, comprising a light source ( 5 . 5 ' . 5 '' ), a display panel facing the operator ( 3 . 3 ' . 3 '' ), the at least one translucent or transparent portion to be backlit by the light of the light source ( 4 . 4 ' . 4 '' ), and at least one conductive, capacitance-forming sensor layer ( 2a . 2a ' . 2a ' ), characterized in that the sensor layer ( 2a . 2a ' . 2a ' ) is translucent and in a beam path of the light from the light source ( 5 . 5 ' . 5 '' ) through the section to be backlit ( 4 . 4 ' . 4 '' ) is arranged. Capacitive proximity sensor ( 1 . 1' . 1'' ) according to claim 1, characterized in that the conductive, capacitance-forming sensor layer ( 2a . 2a ' . 2a ' ) between the display field ( 3 . 3 ' . 3 '' ) and the light source ( 5 . 5 ' . 5 '' ) is arranged. Capacitive proximity sensor ( 1 . 1' . 1'' ) according to one of the preceding claims, characterized in that the conductive, capacitance-forming sensor layer ( 2a . 2a ' . 2a ' ) as a metallic coating of a transparent or translucent substrate ( 2 . 2 ' . 2 '' ) is trained. Capacitive proximity sensor ( 1 . 1' . 1'' ) according to the preceding claim, characterized in that the substrate ( 2 . 2 ' . 2 '' ) is a flexible film. Capacitive proximity sensor ( 1 . 1' . 1'' ) according to claim 3 or 4, characterized in that the substrate is the display panel or the substrate ( 2 . 2 ' . 2 '' ), with one of its surfaces, preferably with the uncoated surface, adjacent to the display ( 3 . 3 ' . 3 '' ) is arranged. Capacitive proximity sensor ( 1 . 1' . 1'' ) according to one of the preceding claims 3 to 5, characterized in that the substrate ( 2 . 2 ' . 2 '' ) is colored or surface-treated. Capacitive proximity sensor ( 1 . 1' . 1'' ) according to one of the preceding claims, characterized in that the conductive, capacitance-forming sensor layer ( 2a . 2a ' . 2a ' ) a material selected from the group consisting of a mixed oxide of indium (III) oxide (In ₂ O ₃ ) and tin (IV) oxide (SnO ₂ ), a fluorine-doped tin (IV) oxide, with Aluminum-doped zinc oxide, antimony-doped tin (IV) oxide. Capacitive proximity sensor ( 1 . 1' . 1'' ) according to one of the preceding claims, characterized in that the conductive, capacitance-forming sensor layer ( 2a . 2a ' . 2a ' ) is applied to the substrate by a method selected from the group consisting of sputtering, high vacuum evaporation, sol-gel coating. Capacitive proximity sensor ( 1 . 1' . 1'' ) according to one of the preceding claims, characterized in that an elastic shielding element ( 6 . 6 ' . 6 '' ), for example essentially made of silicone, which has a breakthrough ( 8th . 8th' . 8th'' ) for a light channel between the light source ( 5 . 5 ' . 5 '' ) and the section to be backlit ( 4 . 4 ' . 4 '' ). Capacitive proximity sensor ( 1 . 1' ) according to one of the preceding claims, characterized in that a conductor track and a conductive, preferably elastic, to the conductive, capacitance-forming sensor layer ( 2a . 2a ' ) and / or the conductor pressed on contacting element ( 7 . 7 ' ), for example substantially of silicone, for electrical contacting of the conductive, capacitance-forming sensor layer ( 2a . 2a ' ) is provided over the conductor track. Capacitive proximity sensor ( 1'' ) according to claim 4, characterized in that the flexible film ( 2 '' ) an integrally formed conductive extension ( 2 B'' ) as a contacting element ( 7 '' ) for electrically contacting the conductive, capacitance-forming sensor layer ( 2a ' ) over the track. Capacitive proximity sensor ( 1 . 1' . 1'' ) according to one of the preceding claims, characterized in that the contacting element ( 7 . 7 ' . 7 '' ) in the region of at least one of its contact surfaces to the conductor track and to the conductive, capacitance-forming sensor layer ( 2a . 2a ' . 2a ' ) is concave. Capacitive proximity sensor according to one of the preceding claims 10 to 12, characterized in that the contacting element and the shielding in one piece are formed. Capacitive proximity sensor ( 1 . 1' . 1'' ) according to one of the preceding claims, characterized in that an electrical control and evaluation unit for acting on the sensor layer ( 2a . 2a ' . 2a ' ) is provided with a measuring capacity and for detecting the change of the measuring capacity when approaching a hand of a person for switching or control purposes, Arrangement of several proximity sensors according to a of the preceding claims, characterized characterized in that the plurality of conductive, capacitance-forming Sensor layers as a plurality of electrically insulated coating areas of a Foil are formed as a substrate. Arrangement according to the preceding Claim, characterized in that the associated plurality of contacting elements and / or shielding are designed mat-shaped. Motor vehicle, characterized by at least one capacitive proximity sensor or the arrangement according to a of the preceding claims.