JP6744570B2 - Occupancy detection device - Google Patents

Description

The present invention relates to a seating detection equipment.

Conventionally, there is a seating detection device that determines the seating state of an occupant with respect to the seating surface of the seat based on the on/off state of a membrane switch that is arranged inside the seat skin that constitutes the seating surface (seating surface) of the seat cushion. is there.

For example, the seating detection device described in Patent Document 1 includes a membrane switch having a plurality of pressure sensitive switch parts (cells). Specifically, the membrane switch is arranged inside the seat skin so that the pressure-sensitive switch portions are arranged apart from each other along the seating surface. Further, the membrane switch is configured to be turned on when at least two pressure-sensitive switch portions among these pressure-sensitive switch portions are simultaneously in the conductive state. Thus, for example, it is configured to avoid the occurrence of erroneous detection, such as determining a luggage or the like placed on the seating surface as an occupant.

JP, 2005-153556, A

However, such a pressure-sensitive switch unit is usually arranged in the central portion of the seating surface, which is the hip point of the occupant, in order to reliably determine the seated state of the occupant. On the other hand, many child seats have a wider area including the periphery of the occupant seating portion as the installation area on the seating surface. Further, many child seats have a contact portion (leg portion) on the seating surface at the edge portion of the lower surface thereof. In many seat cushions, the height of the occupant seating portion is lower than that of the surrounding area. Therefore, the above-described configuration of the related art has a problem that it is not possible to detect the occupant (child) of the child seat installed on the seating surface.

The present invention, when solving the above problems is to provide a seating detection equipment capable of detecting the occupant of the installed child seat on the seating surface.

The seating detection device that solves the above problems has a feeling that the seating surface has a plurality of pressure-sensitive switch portions that are arranged at positions spaced from each other along the seating surface of the seat and that is arranged inside the seat skin. A pressure switch is provided, and the pressure-sensitive switch has a first detection section that is turned on when at least two pressure-sensitive switch sections are simultaneously in a conductive state, and at least one pressure-sensitive switch section is in a conductive state. A second detection unit that is turned on when the first detection unit is in the seated state. The first detection unit is configured to be connected to the first detection unit in parallel. It is preferable that the second detection unit is arranged at a passenger seating portion located in a central portion of the surface, and the second detection unit is arranged at an edge portion of a child seat installation area including a peripheral portion of the passenger seating portion .

According to the above configuration, when the occupant (child) is seated on the child seat installed on the seating surface, the child seat pushes down the peripheral edge side of the seating surface, so that the seat is mounted on the child seat more than the first detector. The 2nd detection part arrange|positioned at the edge side will be in an ON state. And thereby, the occupant of the child seat installed on the seating surface can be detected.

According to the above Symbol configuration, when the occupant is seated in the installed child seat on the seating surface, the second detection portion is likely turned on its. And thereby, the passenger|crew of the child seat installed in the seating surface can be detected more reliably.

In the seating detection device that solves the above problems, it is preferable that the pressure-sensitive switch is a membrane switch in which the first and second detection units are integrally configured.
According to the above configuration, the membrane switch can be easily attached to the sheet.

In the seating detection device for solving the above-mentioned problems, in the pressure-sensitive switch, a plurality of the pressure-sensitive switch portions forming the first detection portion are arranged in a line and a second detection portion is provided. The pressure-sensitive switch section that constitutes the first detection section is provided next to the pressure-sensitive switch section of the terminal of the plurality of pressure-sensitive switch sections that configure the first detection section, and the plurality of pressure- sensitive switch sections that configure the first detection section. It is preferable that the pressure-sensitive switch portion and the pressure-sensitive switch portion that constitutes the second detection portion are arranged side by side at substantially equal intervals .

According to the above configuration, by displacing the pressure-sensitive switch from the central portion of the seating surface, it is possible to easily arrange each pressure-sensitive switch section that constitutes the first detection section in the occupant seating section, while The pressure-sensitive switch section that constitutes the detection section of 1 can be arranged closer to the peripheral edge of the seating surface than the pressure-sensitive switch section that constitutes the first detection section.

According to the present invention, the occupant of the child seat installed on the seating surface can be detected.

1 is a schematic configuration diagram of a seating detection device provided on a vehicle seat. Sectional drawing of a membrane switch. The top view of a membrane switch. Circuit diagram of membrane switch. 1 is a schematic configuration diagram of a seating detection device. The schematic block diagram of the seating detection device provided in the vehicle seat of another example. The schematic block diagram of the seating detection device provided in the vehicle seat of another example. The schematic block diagram of the seating detection device provided in the vehicle seat of another example.

An embodiment of a seating detection device provided on a vehicle seat will be described below with reference to the drawings.
As shown in FIG. 1, a vehicle seat 1 includes a seat cushion 2 and a seat back 3 provided at a rear end portion of the seat cushion 2. Specifically, the seat 1 is configured as a so-called bench seat that forms a plurality of seats 5 in the vehicle width direction. The seat 1 is mounted on a vehicle to form a left rear seat 5a, a right rear seat 5b, and a central rear seat 5c, respectively.

In addition, inside the seat surface 1s that constitutes the seating surface S (S1 to S3) of the seat cushion 2, a plurality of membrane switches 10 that are switched on and off based on the load applied to the seating surface S are provided. ing. Specifically, the seat 1 of the present embodiment includes first to third membrane switches 10a to 10c provided at positions corresponding to the seats 5 (5a to 5c). Then, in the present embodiment, by using each of these membrane switches 10 (10a to 10c) as a pressure-sensitive pressure-sensitive sensor, the seating detection device 20 that determines the seated state of the occupant on the seating surface S is formed. There is.

More specifically, as shown in FIG. 2, the membrane switch 10 according to the present embodiment includes a first film F1 and a second film F2 that are laminated (bonded) with an intermediate film F0 serving as a spacer 30 interposed therebetween. It has the configuration of. Specifically, the first film F1 and the second film F2 have a circuit having contact portions T (Ta, Tb) facing each other through a connecting portion (through hole) 31 formed in the intermediate film F0. A pattern P is formed. The circuit patterns P are formed, for example, by printing using conductive ink. Further, in the membrane switch 10 of the present embodiment, the second film F2 thereof constitutes the lower film 34 and the first film F1 thereof constitutes the upper film 35 in a state in which the membrane switch 10 is disposed inside the sheet skin 1s. Then, based on the load applied to the seating surface S of the seat cushion 2, the first film F1 is elastically deformed and bent downward, so that the first contact point Ta formed on the first film F1 and the first contact point Ta are formed. The lower contact portion Tb formed on the 2 film F2 is in contact with the lower contact portion Tb.

That is, in the membrane switch 10 of the present embodiment, the pressure-sensitive switch unit SW is configured by the upper contact portion Ta of the first film F1 and the lower contact portion Tb of the second film F2 that are arranged to face each other in the vertical direction. ing. The conductive state is switched based on the contact between the upper contact portion Ta and the lower contact portion Tb of the pressure-sensitive switch portion SW.

As shown in FIG. 3, the membrane switch 10 of the present embodiment includes a plurality of switch rows 40 in which a plurality of pressure sensitive switch units SW that are separated from each other are linearly arranged. Specifically, the membrane switch 10 of the present embodiment includes a first switch row 40a and a second switch row 40b that are provided substantially parallel to each other. Each of the switch rows 40 (40a, 40b) includes first to fifth pressure sensitive switch units SW1 to SW5.

More specifically, as shown in FIG. 4, in the membrane switch 10 of the present embodiment, each switch row 40 (40a, 40b) has first and third pressure sensitive switch units SW1 and SW3 connected in parallel. At the same time, the second and fourth pressure sensitive switch units SW2 and SW4 are connected in parallel. In addition, each switch row 40 (40a, 40b) includes a first switch pair 41 formed by the first and third pressure sensitive switch units SW1 and SW3 and a second and fourth pressure sensitive switch units SW2 and SW4. The second switch pair 42 to be formed is connected in series. Further, each switch row 40 (40a, 40b) includes a first circuit L1 including these first to fourth pressure sensitive switch units SW1 to SW4, and a second circuit L2 including a fifth pressure sensitive switch unit SW5. , Are connected in parallel. The membrane switch 10 of this embodiment has a configuration in which the first and second switch rows 40a and 40b are connected in parallel.

That is, in the membrane switch 10 of the present embodiment, at least one of the first and third pressure-sensitive switch units SW1 and SW3 in the first circuit L1 in each switch row 40 (40a, 40b) is in a conductive state, and When at least one of the second and fourth pressure sensitive switch units SW2 and SW4 is in a conducting state, it is in an ON state. That is, when at least two of the first to fourth pressure-sensitive switch units SW1 to SW4 are simultaneously turned on, they are turned on. The membrane switch 10 is a fifth pressure-sensitive switch that constitutes the second circuit L2 in each switch row 40 (40a, 40b) regardless of the first to fourth pressure-sensitive switch units SW1 to SW4. It is turned on when the section SW5 is turned on. Then, as a result, the membrane switch 10 of the present embodiment includes the first circuit L1 including the first to fourth pressure sensitive switch sections SW1 to SW4 and the second circuit L2 including the fifth pressure sensitive switch section SW5. And are respectively configured to form an independent first detection unit α and second detection unit β.

More specifically, as shown in FIG. 3, the membrane switch 10 according to the present embodiment has first to fourth pressure-sensitive switches that form the first detection unit α in each switch row 40 (40a, 40b). The parts SW1 to SW4 have a configuration in which they are arranged at substantially equal intervals. Further, the fifth pressure-sensitive switch section SW5 forming the second detection section β is arranged in the terminal so as to be aligned with the first to fourth pressure-sensitive switch sections SW1 to SW4 at substantially equal intervals. It is provided at a position adjacent to the fourth pressure sensitive switch unit SW4. Then, in the membrane switch 10 of this embodiment, the first detection unit α and the second detection unit β are integrally configured.

As shown in FIG. 1, in each of the seats 5 (5a to 5c) formed by the seat 1 of the present embodiment, the occupant seating portion X( X1 to X3). Further, in each of these seats 5 (5a to 5c), the height of the passenger seating portion X (X1 to X3) is lower than that of the surrounding area in order to accommodate the buttocks of the passenger. When a child seat (not shown) is installed on the seating surface S (S1 to S3) of each of the seats 5 (5a to 5c), the seat 1 of the present embodiment has the occupant seating portions X (X1 to X3). A wider range including the peripheral portion of the child seat is configured to be the child seat installation area Y (Y1 to Y3).

Further, each of the membrane switches 10 (10a to 10c) of the present embodiment constitutes a seating surface S (S1 to S3) at a position corresponding to each seat 5 (5a to 5c) formed by the seat 1. It is arranged inside the seat skin 1s. Further, in each of these membrane switches 10 (10a to 10c), the first to fourth pressure-sensitive switch units SW1 to SW4 constituting the first detection unit α are respectively seats 5 (5a to 5c). Of the passenger seating portion X (X1 to X3). The fifth pressure-sensitive switch section SW5 forming the second detection section β is closer to the peripheral side of the seating surface S than the first detection section α, specifically, the child seat installation area Y (Y1 to Y3). It is supposed to be placed at the edge of.

Specifically, the first membrane switch 10a has a seating surface S1 of the left rear seat 5a in a state in which the respective switch rows 40a, 40b are substantially parallel to the seat width direction (the horizontal direction in FIG. 1). Is arranged at a position closer to the left side (left side in the figure). And the 1st-4th pressure sensitive switch parts SW1-SW4 are arrange|positioned at the passenger|occupant seating part X1 of the left back seat 5a, respectively, and the 5th pressure sensitive switch part located in the terminal of each switch row 40a, 40b. The SW 5 is configured to be arranged at the left edge of the child seat installation area Y1.

Similarly, the second membrane switch 10b is also provided at a position corresponding to the seating surface S2 of the right rear seat 5b with the respective switch rows 40a, 40b being substantially parallel to the seat width direction. .. The second membrane switch 10b is arranged on the seating surface S2 on the right side (right side in FIG. 1). And the 1st-4th pressure sensitive switch parts SW1-SW4 are arrange|positioned at the passenger|crew seating part X2 of the right back seat 5b, respectively, and the 5th pressure sensitive switch part located in the terminal of each switch row 40a, 40b. The SW 5 is configured to be arranged at the right edge of the child seat installation area Y2.

Further, the third membrane switch 10c is also arranged at a position on the left side of the seating surface S3 of the central rear seat 5c with the respective switch rows 40a, 40b being substantially parallel to the seat width direction. And the 1st-4th pressure sensitive switch parts SW1-SW4 are arrange|positioned at the occupant seating part X3 of the center back seat 5c, and the 5th pressure sensitive switch part SW5 located in the terminal of each switch row 40a and 40b. Is arranged at the left edge of the child seat installation area Y3.

Further, as shown in FIG. 5, in the seating detection device 20 of the present embodiment, the output signal of each of the membrane switches 10 (10a to 10c) indicates the on/off state of each of the membrane switches 10 (10a to 10c). The seating detection signals Sd (Sd1 to Sd3) shown are input to the ECU 50. Then, the ECU 50 determines the seating state of the occupant on the seating surfaces S (S1 to S3) of the seats 5 (5a to 5c) formed by the seat 1 based on the seating detection signal Sd (Sd1 to Sd3). It is configured to run.

That is, each of the membrane switches 10 of the present embodiment has at least two pressure-sensitive switches arranged at positions spaced apart from each other along the seating surface S in the occupant seating portion X located at the center of the seating surface S. When the section SW is turned on, the first detection section α including these pressure-sensitive switch sections SW is turned on. Then, the seating detection device 20 of the present embodiment can detect the occupant seated on the seating surface S of the seat 1 with high accuracy.

Further, the height of the seating surface S of each seat 5 is higher in the peripheral portion than in the passenger seating portion X located in the central portion. Therefore, when a child seat having an abutting portion with the seating surface S is installed in a wider area than the passenger seating portion X, even if the passenger (child) is seated on the child seat, each membrane switch is installed. In No. 10, the first detection unit α arranged in the passenger seating portion X remains in the off state. However, in each of the membrane switches 10 of the present embodiment, at this time, the second detection unit β arranged at the edge portion of the child seat installation area Y including the peripheral portion of the occupant seating portion X is turned on. Then, the seating detection device 20 of the present embodiment can thereby detect the occupant of the child seat installed on the seating surface S of the seat 1.

Specifically, in each of the membrane switches 10 of the present embodiment, when the occupant is not seated on the child seat installed on the seating surface S, the second detector β remains in the off state. It is configured. However, when the occupant is seated on the child seat, the child seat pushes down the child seat installation area Y formed on the seating surface S thereof. Then, as a result, the seat load for turning on the second detection unit β installed in the child seat installation area Y is applied to the membrane switch 10.

As described above, according to this embodiment, the following effects can be obtained.
(1) The seating detection device 20 has a plurality of pressure-sensitive switch portions SW arranged at positions separated from each other along the seating surface S of the seat 1, and is arranged inside the seat skin 1s that constitutes the seating surface S. Equipped membrane switch 10. In the membrane switch 10, the first detection unit α that is turned on when at least two pressure-sensitive switch units SW are simultaneously in the conducting state and the at least one pressure-sensitive switch unit SW is in the conducting state. In this case, the second detection unit β is turned on. Further, the membrane switch 10 has a configuration in which the first and second detection units α and β are connected in parallel. In the membrane switch 10, the first detecting portion α is arranged in the occupant seating portion X located at the center of the seating surface S, and the second detecting portion β is seated on the seating surface more than the first detecting portion α. It is arranged on the peripheral side of S.

According to the above configuration, when the occupant (child) is seated on the child seat installed on the seating surface S, the membrane switch 10 pushes down the peripheral edge of the seating surface S, so that the first detecting unit α. The second detection unit β arranged closer to the peripheral side than that is turned on. Accordingly, the occupant of the child seat installed on the seating surface S can be detected.

(2) The second detection unit β is arranged at the edge portion of the child seat installation area Y including the peripheral portion of the passenger seating portion X. As a result, when the occupant sits on the child seat installed on the seating surface S, the second detector β is likely to be turned on. As a result, the occupant of the child seat installed on the seating surface S can be detected more reliably.

(3) The membrane switch 10 is integrally configured with the first detection unit α and the second detection unit β.
According to the above configuration, the membrane switch 10 can be easily attached to the seat cushion 2.

(4) The membrane switch 10 has a configuration in which the first to fourth pressure sensitive switch units SW1 to SW4 forming the first detection unit α are linearly arranged at positions separated from each other. In the membrane switch 10, the fifth pressure-sensitive switch unit SW5 that constitutes the second detection unit β is connected to the terminals of the respective pressure-sensitive switch units SW (SW1 to SW4) that constitute the first detection unit α. The configuration is provided adjacent to the fourth pressure-sensitive switch unit SW4 located.

According to the above configuration, by shifting the arrangement of the membrane switch 10 from the central portion of the seating surface S, the first to fourth pressure sensitive switch units SW1 to SW4 forming the first detection unit α can be easily arranged. The fifth pressure-sensitive switch unit SW5 that constitutes the second detection unit β can be arranged at the edge of the child seat installation region Y while being arranged in the occupant seating unit X. Moreover, the manufacture of the membrane switch 10 is facilitated. Furthermore, when forming the membrane switch 10, the amount of the film (F0 to F2) used as the material thereof can be reduced. And thereby, the manufacturing cost of the membrane switch 10 can be reduced.

(5) The first detection unit α has a configuration in which a plurality of switch pairs (41, 42) formed by connecting a pair of pressure sensitive switch units SW (SW1, SW3, SW2, SW4) in parallel are connected in series. Have. Accordingly, with a simple configuration, it is possible to form the first detection unit α that is turned on when at least two pressure-sensitive switch units SW are simultaneously turned on.

The above embodiment may be modified as follows.
In the above-described embodiment, the membrane switch 10 is used as the pressure-sensitive switch, but if it has independent first and second detection units α and β, for example, a pressure-sensitive switch unit other than the contact type is provided. The configuration of the pressure sensitive switch, such as a thing, may be arbitrarily changed.

In the above-described embodiment, in the membrane switch 10, the fifth pressure-sensitive switch section SW5 forming the second detection section β is arranged at the edge of the child seat installation area Y (Y1 to Y3). However, the present invention is not limited to this, and when the occupant is seated on the child seat installed on the seating surface S, if the child seat is in a position where it is turned on by pushing down the peripheral side of the seating surface S, the second detection unit The position where β is arranged may be closer to the center of the seating surface S than the edge of the child seat installation area Y.

In the above embodiment, the membrane switch 10 is configured to be provided with five pressure sensitive switch units SW1 to SW5, but the number of pressure sensitive switch units SW may be arbitrarily changed.
For example, the first detection unit α may be composed of two or three pressure sensitive switch units SW, or may be composed of five or more pressure sensitive switch units SW. If the first detection unit α is turned on when at least two pressure-sensitive switch units SW arranged at positions separated from each other are turned on, the first detection unit α is set to the ON state. The arrangement of the respective pressure-sensitive switch sections SW and the circuit configuration thereof may be arbitrarily changed.

The second detection unit β may be composed of two or more pressure sensitive switch units SW. For example, the second detection unit β may include a pair of switch rows 40 including a pair of pressure-sensitive switch units SW connected in parallel. That is, the second detection unit β is turned on when at least one pressure-sensitive switch unit SW provided independently of each pressure-sensitive switch unit SW forming the first detection unit α is in the conductive state. It should be in a state. The arrangement of the pressure-sensitive switch sections SW forming the second detection section β and the circuit configuration thereof may also be arbitrarily changed.

In the above-described embodiment, each membrane switch 10 is arranged such that each switch row 40 (40a, 40b) is substantially parallel to the seat width direction. The orientation may be changed arbitrarily.

For example, as shown in FIG. 6, each switch row 40 (40a, 40b) may be provided with the membrane switch 10 so as to extend in the seat front-rear direction. Then, for example, as shown in FIG. 7, the membrane switch 10B may be arranged so that the switch row 40 is inclined with respect to the seat front-back direction (or the seat width direction).

In the above embodiment, each membrane switch 10 includes the pair of switch rows 40 (40a, 40b), but the number of switch rows 40 may be changed arbitrarily. For example, it may be configured by one switch row 40 like the membrane switch 10B shown in FIG. 7. The configuration may include three or more switch rows 40.

In the above embodiment, the membrane switch 10 is configured such that the switch rows 40 (40a, 40b) are arranged in parallel with each other, but the arrangement of the switch rows 40 (40a, 40b) may be changed arbitrarily. Good.

For example, like the membrane switch 10C shown in FIG. 8, the first switch row 40a is arranged so as to extend from the center of the seating surface S to the right side, and the second switch row 40b extends from the center of the seating surface S to the left side. You may arrange so.

In the above embodiment, the membrane switch 10 is arranged in the rear seat, but it may be arranged in other seats such as the passenger seat.
In the above embodiment, the membrane switches 10 (10a to 10c) are arranged in the left rear seat 5a, the right rear seat 5b, and the central rear seat 5c, respectively, but the number and arrangement of the membrane switches 10 are arbitrarily changed. You may. For example, the membrane switch 10 may be arranged only in the left rear seat 5a and the right rear seat 5b.

-The membrane switch 10 should just be arrange|positioned inside the seat skin 1s which comprises the seating surface S of the seat 1. For example, it may be provided between the seat surface 1s that constitutes the seating surface S and the cushion pad, or between the cushion pad and a support member of the cushion pad (for example, a cushion pan or a so-called S spring). ..

Next, technical ideas that can be understood from the above-described embodiment will be described together with effects.
(A) The membrane switch has a plurality of switch rows provided with a plurality of pressure sensitive switch sections that constitute the first and second detection sections.

According to the above configuration, the occupant detection area can be expanded by using a plurality of switch rows. And thereby, the detection accuracy of the seating detection determination can be improved.
(B) The first detection unit has a configuration in which a plurality of switch pairs formed by connecting a pair of pressure sensitive switch units in parallel are connected in series. Accordingly, it is possible to form the first detection unit that is turned on when at least two pressure-sensitive switch units are simultaneously turned on with a simple configuration.

1... Seat, 1s... Seat skin, 10, 10B, 10C... Membrane switch (pressure sensitive switch), 20... Seating detection device, 50... ECU, S... Seating surface, SW (SW1 to SW5)... Pressure sensing switch part ( First to fifth pressure sensitive switch portions), X... Occupant seating portion, Y... Child seat installation area, α... First detecting portion, β... Second detecting portion.

Claims (3)

A pressure sensitive switch disposed inside the seat skin that constitutes the seating surface having a plurality of pressure sensitive switch portions arranged at positions separated from each other along the seating surface of the seat,
The pressure sensitive switch is
A first detection unit that is turned on when at least two pressure-sensitive switch units are simultaneously turned on;
A second detection unit that is turned on when at least one of the pressure sensitive switch units is in a conductive state,
While having a configuration in which the first and second detection units are connected in parallel,
The first detection unit is arranged in the occupant seating portion located in the central portion of the seating surface,
A seating detection device in which the second detection unit is arranged at an edge portion of a child seat installation area including a peripheral portion of the passenger seating portion . The pressure sensitive switch is
The seating detection device according to claim 1, wherein the seating detection device is a membrane switch in which the first and second detection units are integrally configured. The pressure sensitive switch is
While the plurality of pressure-sensitive switch units that form the first detection unit are arranged linearly,
The pressure-sensitive switch section forming the second detection section is provided next to the pressure-sensitive switch section of the terminal of the plurality of pressure-sensitive switch sections forming the first detection section, and The seating detection device according to claim 1 or 2 , wherein the plurality of pressure-sensitive switch portions that form a detection portion and the pressure-sensitive switch portions that form the second detection portion are arranged at substantially equal intervals .

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