DE202020002026U1 - Seat occupancy sensor for detecting the occupancy of a seat - Google Patents

Abstract

Seat occupancy sensor (1) for detecting seat occupancy in a seat, wherein the seat occupancy sensor (1) has an optical sensor arrangement (5) and a housing (2) for receiving the optical sensor arrangement (5) and wherein the optical sensor arrangement (5) has a light source ( 6) and a photodetector (7) and wherein the light source (6) is designed to emit a light signal and the photodetector (7) is designed to receive the light signal reflected on a reflective surface, with an unloaded state of the seat in a loaded state of the seat, the reflective surface is displaced along a beam path of the light signal relative to the optical sensor arrangement (5), characterized in that the photodetector (7) is designed to detect an amount of light and / or a radiation density of the light signal reflected on the reflective surface.

Description

The invention relates to a seat occupancy sensor for detecting seat occupancy in a seat, wherein the seat occupancy sensor has an optical sensor arrangement and a housing for receiving the optical sensor arrangement and wherein the optical sensor arrangement has a light source and a photodetector and the light source is designed to emit a light signal and the photodetector is designed to receive the light signal reflected on a reflection surface, the reflection surface being displaced along a beam path of the light signal with respect to the optical sensor arrangement in relation to an unloaded state of the seat in a loaded state of the seat.

The detection of seat occupancy at a seat is necessary in many areas. For example, there is a need to detect seat occupancy on motor vehicle seats. Motor vehicles have numerous safety and comfort systems. The need arises more and more to operate these systems depending on the seat occupancy of the motor vehicle. In the case of airbag systems, for example, it is important not to trigger the airbags on the front passenger seat in the event of an accident if the seat is occupied by a baby seat. Furthermore, the output of a warning signal is desirable when a seat of the motor vehicle is occupied by a person but this person has not put on the seat belt. The knowledge of the seat occupancy in a motor vehicle can also be used for an optimized air flow guidance in the interior ventilation. All of this makes it necessary to recognize the occupancy of motor vehicle seats.

Numerous seat occupancy sensors for detecting seat occupancy in a seat are known from the prior art. In particular is off U.S. 5,988,676 A a seat occupancy sensor with an optical sensor arrangement is known, this seat occupancy sensor being arranged between an underside of a seat foam of the seat occupancy sensor and a substructure carrying the seat foam. The optical sensor arrangement is surrounded by a housing of the seat occupancy sensor, a housing cover of the housing facing the seat foam being designed to be flexible. The optical sensor arrangement consists of a light source, a lens system and a photodetector. A light signal emitted by the light source is guided via the lens system to an inside of the housing cover facing away from the seat foam, where it is reflected and reaches the photodetector. In the unloaded state of the seat, the light signal reaches a reference position on the photodetector. When the seat is occupied, the seat foam is moved in the direction of the housing cover of the seat occupancy sensor and the housing cover is deformed as a result. As a result of the deformation of the housing cover, the light signal is reflected to a different position on the photodetector that deviates from the reference position. The greater the load on the seat, the further the light signal shifts in relation to the reference position, so that the load acting on the seat surface of the seat can be determined by evaluating the position shift. Basically, this solution has proven itself. However, it is disadvantageous that the overall structure is complex, in particular due to the need for the lens system. In addition, precise adjustment of the lens system is necessary for the correct functioning of the seat occupancy sensor, which, however, makes it susceptible to external influences (eg vibrations). Furthermore, the entire structure is characterized by relatively large dimensions due to the lens system.

The object of the invention is therefore to propose a seat occupancy sensor with an optical sensor arrangement which is characterized by a simpler and less error-prone structure.

This object is achieved with a seat occupancy sensor having the features of claim 1. The seat occupancy sensor for detecting seat occupancy in a seat has an optical sensor arrangement and a housing for receiving the optical sensor arrangement. The optical sensor arrangement contains a light source for emitting a light signal. Furthermore, the optical sensor arrangement contains a photodetector for receiving the light signal, the photodetector being designed such that it detects an amount of light and / or a radiation density of the light signal impinging on the photodetector. The light source and the photodetector are arranged with respect to one another in such a way that the light signal emitted by the light source is guided onto a reflection surface and is reflected from there onto the photodetector. The light source and the photodetector of the optical sensor arrangement can either be combined in one component or they can each be designed as a separate component. Compared to an unloaded state of the seat, in a loaded state of the seat, the reflective surface is displaced along a beam path of the light signal with respect to the optical sensor arrangement. By shifting the reflection surface with respect to the optical sensor arrangement, the distance between them is changed. A change in the distance causes a variation in the amount of light and / or radiation density of the light signal reflected onto the photodetector. At a greater distance, the amount of light and / or the radiation density of the light signal reflected onto the photodetector is lower. A decrease in the amount of light is caused, for example, by an increased absorption of the light signal in the extended beam path between the reflection surface and the optical sensor arrangement. A reduction in the radiation density of the light signal on the photodetector is caused, for example, by the fact that the light signal is more widely scattered when the beam path is lengthened. The variation in the amount of light and / or the radiation density of the light signal reflected onto the photodetector is thus coupled with the distance between the reflection surface and the optical sensor arrangement. Since the distance between the reflective surface and the optical sensor arrangement is changed depending on the load on the seat, load on the seat can be recognized by detecting the amount of light and / or the radiation density of the light signal reflected on the photodetector. If, for example, a limit value for the amount of light and / or the radiation density is reached, it can be concluded that a seat is occupied. In addition, the seat occupancy sensor according to the invention can also be used to quantify the weight acting on the seat. The stronger the weight acting on the seat, the more the distance between the reflective surface and the optical sensor arrangement is changed and the more the amount of light and / or the radiation density of the light signal reflected onto the photodetector is varied. From the variation of the amount of light and / or the radiation density, conclusions can be drawn about the acting weight.

Light as a form of electromagnetic radiation can be understood in the narrower sense as that part of the entire electromagnetic spectrum that is visible to the human eye. In a broader sense, electromagnetic waves of shorter wavelength (ultraviolet) and longer wavelength (infrared) are also counted as light. For the purposes of the application, the broader understanding is assumed, so that the term light includes the portion of the electromagnetic spectrum that is visible to the human eye and also ultraviolet and infrared radiation.

An advantageous embodiment provides that the housing has an actuating element, this actuating element being displaceable relative to the housing along the beam path of the light signal. In one embodiment, the optical sensor arrangement is fixed on the housing and an inside of the actuating element facing the sensor arrangement forms the reflection surface. In an alternative embodiment, the optical sensor arrangement is fixed to an inside of the actuating element facing the interior of the housing, and an inside of the housing facing the actuating element forms the reflective surface.

In an advantageous embodiment, the actuating element can be displaced relative to the housing against a spring force of a spring element of the seat occupancy sensor.

It is proposed that the spring element is a compression spring or a wave washer. A compression spring or a wave washer are particularly suitable when the actuating force is to be detected continuously along the movement of the actuating element. The compression spring or the corrugated spring washer can also be designed in such a way that it only provides a restoring force necessary to return the actuating element.

Furthermore, a device for detecting seat occupancy on a seat with such a seat occupancy sensor is proposed, the seat having a seat cushion and a substructure and the seat cushion with a seat cushion underside resting at least partially on the substructure. The substructure can for example be a wire frame or a spring base or a part of the body. In one embodiment, the housing of the seat occupancy sensor is fixed to the substructure and the actuating element points in the direction of the underside of the seat cushion. When the seat is occupied, the seat cushion underside of the seat cushion is moved in the direction of the actuating element, as a result of which the actuating element is displaced relative to the housing and this displacement is detected by the optical sensor arrangement. If the seat occupancy is dissolved again, the underside of the seat cushion moves away from the housing again. If the housing contains a spring element, as described above, the actuating element, which was previously displaced against the spring force of the spring element when the seat was occupied, is moved back to its original position by the spring force and the original state is restored. This (back) displacement of the actuating element can also be evaluated by the optical sensor arrangement. However, the spring element is not absolutely necessary for resetting the actuating element. Resetting can also be achieved in that the actuating element is connected to the underside of the seat cushion and the housing is connected to the substructure. When a seat is occupied, the underside of the seat cushion is shifted in the area of the housing in the direction of the substructure, so that the actuating element is shifted relative to the housing. When the seat occupancy is resolved, the underside of the seat cushion is moved away from the substructure again in the area of the housing and carries the actuating element connected to it with it, so that it is returned to its starting position.

Another embodiment provides that the housing is fixed on the underside of the seat cushion and the actuating element in the direction of the substructure is directed. In a further alternative embodiment, the housing is fixed to a seat cushion frame surrounded by the seat cushion and the actuating element points in the direction of the seat cushion underside.

In an advantageous embodiment, the seat occupancy sensor is at least partially embedded in the seat cushion on the underside of the seat cushion.

Another embodiment of the seat occupancy sensor provides that the housing has a housing opening and that the light signal emitted by the light source can be guided through this housing opening. A reflection surface located outside the seat occupancy sensor can thus be used. This reflection surface can be, for example, the underside of the seat cushion of the seat or also a section of the substructure of the seat.

For a seat occupancy sensor designed in this way, a device for detecting seat occupancy in a seat is also proposed, the seat also having a seat cushion and a substructure and the seat cushion with a seat cushion underside resting at least partially on the substructure. In one embodiment, the housing is fixed to the substructure and the housing opening points in the direction of the underside of the seat cushion. In this embodiment, the reflection surface is formed by a section of the seat cushion underside located in the beam path. An alternative embodiment provides that the housing is fixed on the underside of the seat cushion and the housing opening points in the direction of the substructure. In this case, the reflective surface is then formed by a section of the substructure located in the beam path, the reflective surface.

In a further embodiment of the seat occupancy sensor, the housing has a housing section that is permeable to the light signal, the light signal emitted by the light source being guided through this housing section. The housing of the seat occupancy sensor can be fixed to a substructure section of the substructure. The light signal emerging from the transparent housing section is guided to the underside of the seat cushion, reflected from there and passed through the transparent housing section to the photodetector of the seat occupancy sensor. When the seat is occupied, the underside of the seat cushion is moved in the direction of the substructure section, so that the path of the light signal between the light source and the photodetector is then shortened, the shortening of the light path being recognizable as a change in the intensity and / or radiation density of the light signal on the photodetector. In an alternative embodiment, the housing of the seat occupancy sensor is fixed to an underside section of the underside of the seat cushion. The light signal emerging from the transparent housing section is guided to a section of the substructure located in the beam path, where it is reflected and passed through the transparent housing section to the photodetector. Here, when the seat is occupied, the underside section of the seat cushion underside is moved in the direction of the substructure section and thus the path of the light signal between the light source and the photodetector is shortened, the shortening of the light path being recognizable as a change in the intensity and / or radiation density of the light signal on the photodetector.

In an advantageous embodiment, the seat occupancy sensor with the housing section that is permeable to the light signal has a resetting element. The resetting element is designed so that after a seat was occupied, the distance between the section of the seat cushion underside in the beam path and the base section or the distance between the section of the base in the beam path and the underside section is restored.

It is proposed that the housing section that is permeable to the light signal is designed to be flexible and thus at the same time forms the restoring element. In the event that the housing of the seat occupancy sensor is fixed to the substructure section of the substructure, the flexible housing section, which is permeable to the light signal, rests against the underside of the seat cushion when the seat is unoccupied. When the seat is occupied, the underside of the seat cushion is moved against the substructure section, as a result of which the flexible housing section is compressed. In the event of compression, a restoring force is formed which acts between the seat occupancy sensor and the underside of the seat cushion. When the seat is transferred from its occupied to its unoccupied state, the section of the seat cushion underside located in the beam path moves away from the substructure section again, this being supported by the restoring force emanating from the flexible housing section and thus ensuring that in the unoccupied state the original distance between the portion of the seat cushion underside and the base portion is restored. In the event that the housing is fixed on the underside of the seat cushion, the flexible housing section, which is permeable to the light signal, rests against the substructure section when the seat is unoccupied. When a seat is occupied, the flexible housing section is also compressed here and a restoring force is formed in an analogous manner.

It is suggested that the light source is a laser diode or an IR LED. The use of an IR LED has the advantage that the influence of ambient light is reduced.

• 1 Eine räumliche Darstellung einer Ausführung eines erfindungsgemäßen Sitzbelegungssensors
• 2 Eine räumliche Darstellung des Sitzbelegungssensor gemäß 1 mit geöffnetem Gehäuse
• 3 Eine Schnittdarstellung des Sitzbelegungssensors gemäß 1

An exemplary embodiment of the invention is explained below with reference to the drawings. Show it:

• 1 A three-dimensional representation of an embodiment of a seat occupancy sensor according to the invention
• 2 A spatial representation of the seat occupancy sensor according to 1 with the housing open
• 3 A sectional view of the seat occupancy sensor according to 1

1 shows a three-dimensional representation of an embodiment of a seat occupancy sensor according to the invention 1 . The seat occupancy sensor 1 has a housing 2 and an actuator 3 on. On the housing 2 is a slot 4th intended to accommodate a plug for connection to a cable for electrical contacting. However, the plug and the cable are not shown.

2 shows a three-dimensional representation of the seat occupancy sensor 1 according to 1 , wherein the actuator 3 is not shown and thus the view into the interior of the housing 2 free is. Inside the case 2 is an optical sensor arrangement 5 arranged. This optical sensor arrangement 5 has a light source 6th and a photodetector 7th on. The light source 6th is used to emit a light signal. The photodetector 7th is designed to receive a light signal and to detect an amount of light and / or a radiation density of this light signal. The light source 6th and the photodetector 7th are combined in one component, the invention not being limited to this, and the light source 6th and the photodetector 7th can also be designed as separate components. Furthermore is in the housing 2 a spring element designed as a helical spring 8th arranged.

In 3 is a cross-sectional view of the seat occupancy sensor 1 according to 1 shown. You can see the housing 2 with the actuator 3 , the optical sensor array 5 and the spring element 8th . The optical sensor arrangement 5 is on the housing 2 fixed, with both the light source 6th , as well as the photodetector 7th in the direction of the actuator 3 point. The actuator 3 is opposite the case 2 relocatable. The seat occupancy sensor is shown in the illustration 1 in an inoperative state. A light signal coming from the light source 6th the optical sensor arrangement 5 is emitted, is at one of the optical sensor arrangement 5 facing inside 9 (Reflective surface) of the actuating element 3 reflected and onto the photodetector 7th directed. The one from the photodetector 7th The detected amount of light and / or radiation density of this light signal serves as a reference value characterizing the non-actuated state.

For actuation of the seat occupancy sensor 1 acts on the actuating element 3 a force in the direction of the optical sensor arrangement 5 . The actuating element is thereby 3 against the spring force of the spring element 8th opposite the housing 2 in the direction of the optical sensor arrangement 5 emotional. This results in a shortening of the beam path of the light signal, so that the photodetector 7th detected amount of light and / or radiation density of the light signal changes compared to the reference value of the inactivated state.

The seat occupancy sensor 1 is part of a device for detecting seat occupancy on a seat, wherein the seat has a seat cushion and a substructure and the seat cushion with a seat cushion underside rests at least partially on the substructure. The seat cushion and the substructure are not shown. The seat occupancy sensor 1 according to 1 until 3 can for example be used so that the housing 2 of the seat occupancy sensor 1 is fixed to the substructure and the actuating element 3 points in the direction of the underside of the seat cushion. In an alternative (not shown) embodiment, the housing 2 fixed to the underside of the seat cushion and the actuating element 3 points in the direction of the substructure. In a further embodiment (also not shown), the housing is 2 fixed to a seat cushion frame surrounded by the seat cushion and the actuating element 3 points in the direction of the underside of the seat cushion.

In a further (not shown) embodiment of the seat occupancy sensor 1 is the optical sensor arrangement 5 in contrast to the embodiment shown, on an inside of the actuating element facing the interior of the housing 3 fixed. The optical sensor arrangement 5 is oriented so that one of the actuating element 3 facing inside of the housing 2 forms the reflection surface.

In an alternative (not shown) embodiment of the seat occupancy sensor 1 is the case 2 designed so that it has a housing opening and the light signal emitted by the light source can be guided through this housing opening.

Such a seat occupancy sensor 1 is part of a further device (not shown) for detecting seat occupancy on a seat. In this device, the housing is 2 fixed to the substructure and the housing opening points in the direction of the seat cushion underside, so that a section of the seat cushion underside located in the beam path forms the reflection surface.

In a further device (also not shown) for detecting seat occupancy the housing is on one seat 2 of the seat occupancy sensor 1 fixed to the underside of the seat cushion and the housing opening directed towards the substructure, so that a section of the substructure located in the beam path forms the reflection surface.

In a further (not shown) embodiment of the seat occupancy sensor 1 , is its case 2 formed with a housing section permeable to the light signal. Furthermore, this housing section is also designed to be flexible, so that it can also act as a restoring element. For this purpose, the housing section can be, for example, a cap made of silicone. The case 2 of the seat occupancy sensor 1 is fixed to a substructure section of the substructure and the flexible housing section that is permeable to the light signal rests against a section of the seat cushion underside. In the occupied state of the seat, the flexible housing section still rests against the underside of the seat cushion, but the flexible housing section is compressed compared to the unoccupied state, so that a restoring force is formed by this compression. That from the light source 6th emitted light signal is through the permeable housing section out of the housing 2 guided out, reflected on the section of the seat cushion underside and guided through the flexible housing section back into the housing to the photodetector.

List of reference symbols

1

Seat occupancy sensor

2

casing

3rd

Actuator

4th

slot

5

optical sensor arrangement

6th

Light source

7th

Photodetector

8th

Spring element

9

inside

QUOTES INCLUDED IN THE DESCRIPTION

This list of the documents listed by the applicant was 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.

Patent literature cited

• US 5988676 A [0003]

Claims (15)

Seat occupancy sensor (1) for detecting seat occupancy in a seat, wherein the seat occupancy sensor (1) has an optical sensor arrangement (5) and a housing (2) for receiving the optical sensor arrangement (5) and wherein the optical sensor arrangement (5) has a light source ( 6) and a photodetector (7) and wherein the light source (6) is designed to emit a light signal and the photodetector (7) is designed to receive the light signal reflected on a reflective surface, with an unloaded state of the seat in a loaded state of the seat, the reflective surface is displaced along a beam path of the light signal relative to the optical sensor arrangement (5), characterized in that the photodetector (7) is designed to detect an amount of light and / or a radiation density of the light signal reflected on the reflective surface. Seat occupancy sensor (1) Claim 1 , characterized in that the seat occupancy sensor (1) has an actuating element (3) and this actuating element (3) can be displaced relative to the housing (2) along the beam path of the light signal and that either the optical sensor arrangement (5) is fixed on the housing (2) and an inner side (9) of the actuating element (3) facing the optical sensor arrangement (5) forms the reflective surface or that the optical sensor arrangement (5) is fixed to an inner side of the actuating element (3) facing the interior of the housing and one is attached to the actuating element (3) facing inside of the housing (2) forms the reflection surface. Seat occupancy sensor (1) Claim 2 , characterized in that the actuating element (3) can be displaced relative to the housing (2) against a spring force of a spring element (8) of the seat occupancy sensor (1). Seat occupancy sensor (1) Claim 3 , characterized in that the spring element (8) is a compression spring or a corrugated spring washer. Seat occupancy sensor (1) Claim 1 , characterized in that the housing (2) has a housing opening and the light signal emitted by the light source can be guided through this housing opening. Seat occupancy sensor (1) Claim 1 , characterized in that the housing (2) has a housing section which is permeable to the light signal and the light signal emitted by the light source can be guided through this housing section. Seat occupancy sensor (1) Claim 6 , characterized in that the seat occupancy sensor has a reset element. Seat occupancy sensor (1) Claim 7 , characterized in that the housing section permeable to the light signal is designed to be flexible and forms the restoring element. Seat occupancy sensor (1) according to one of the preceding claims, characterized in that the light source (6) is a laser diode or an IR LED. Device for detecting seat occupancy in a seat with a seat occupancy sensor (1) according to one of the Claims 2 until 4th , wherein the seat has a seat cushion and a substructure and the seat cushion with a seat cushion underside rests at least partially on the substructure, characterized in that the housing (2) of the seat occupancy sensor (1) is fixed to the substructure and the actuating element (3) in the direction Seat cushion underside or that the housing (2) is fixed on the seat cushion underside and the actuating element (3) is directed towards the substructure or that the housing (2) is fixed to a seat cushion frame surrounded by the seat cushion and the actuating element (3) points towards the seat cushion underside . Device for detecting seat occupancy on a seat according to Claim 10 , characterized in that the seat occupancy sensor (1) is at least partially embedded in the seat cushion on the underside of the seat cushion. Device for detecting seat occupancy on a seat with a seat occupancy sensor (1) according to Claim 5 , wherein the seat has a seat cushion and a substructure and the seat cushion with a seat cushion underside rests at least partially on the substructure, characterized in that the housing (2) is fixed to a substructure section of the substructure and the housing opening points in the direction of the seat cushion underside and one in the beam path Located section of the seat cushion underside forms the reflective surface or that the housing (2) is fixed to an underside section of the seat cushion underside and the housing opening points in the direction of the substructure and a section of the substructure located in the beam path forms the reflective surface. Device for detecting seat occupancy on a seat with a seat occupancy sensor (1) according to Claim 6 or 7th or 8th , wherein the seat has a seat cushion and a substructure and the seat cushion with a seat cushion underside rests at least partially on the substructure, characterized in that the housing (2) is fixed to a substructure section of the substructure and the Light signal-permeable housing section points in the direction of the seat cushion underside and a section of the seat cushion underside located in the beam path forms the reflection surface or that the housing (2) is fixed to an underside section of the seat cushion underside and the housing section, which is transparent for the light signal, points towards the substructure and a section of the The substructure forms the reflective surface. Device for detecting seat occupancy on a seat according to Claim 13 with a seat occupancy sensor (1) according to Claim 7 or 8th , characterized in that the restoring element is designed so that after a seat occupancy, a distance between the section of the seat cushion underside located in the beam path and the substructure section or a distance between the section of the substructure located in the beam path and the underside section is restored. Device for detecting seat occupancy on a seat according to Claim 14 with a seat occupancy sensor (1) according to Claim 8 , characterized in that in the unoccupied state and in the occupied state of the seat, the return element rests on the underside of the seat cushion or on the substructure and the return element is compressed in the occupied state.

Images