JP5499491B2 - Occupant detection sensor and occupant detection system - Google Patents

Description

  The present invention relates to an occupant detection sensor and an occupant detection system that detect a seated state of a seated person on a seat.

  An automobile is equipped with an airbag for passenger protection. The airbag is designed on the assumption that an adult wears a seat belt and sits on the seat. When a child sits directly on the seat or when an infant sits via a child seat, control is performed by prohibiting the deployment of the airbag or reducing the deployment pressure to protect the child or infant from the impact of the airbag. Is doing. For this reason, it is possible to accurately detect whether an adult is seated on a seat, a child is seated, an infant is seated via a child seat, or only a child seat is mounted. It is necessary to control the back development pressure. For example, in the one shown in Patent Document 1, a load or pressure detection type seat back load sensor 3 capable of detecting a load state applied to the seat back 61 is disposed on the seat back 61 of the seat 6. Four sheet body load sensors 2 a, 2 b, 2 c, and 2 d that can detect a load state applied to the sheet body 60 are arranged on the sheet body 60. The passengers on the seat are detected by comprehensively judging from the detection results of both the seat back load sensor 3 and the seat body load sensors 2a, 2b, 2c, and 2d. The child seat is judged.

JP 2005-206088 A

  However, in the prior art described above, when the occupant takes a posture that does not lean against the seat back 61 or when the vehicle is on a downhill and the occupant's body is bent forward, the seat is a load or pressure detection type. The load cannot be detected by the back sensor. Further, when the child seat is mounted on the seat, depending on the kind of the child seat, a part of the child seat may come into contact with the seat back load sensor 3 and it may be difficult to distinguish it from an adult. Furthermore, in the prior art, four expensive load sensors 2a, 2b, 2c, and 2d are used, and the system is not inexpensive.

  The present invention has been made in view of the above problems, and an object of the present invention is to provide an occupant detection sensor and an occupant detection system that can accurately discriminate between an adult and a child seat and are inexpensive.

In order to solve the above-mentioned problem, a feature of the occupant detection sensor according to claim 1 is that an occupant detection sensor that detects a load state of a seat including a seat cushion and a seat back by a plurality of sensors arranged on the seat cushion. The occupant detection sensor is disposed between the seat frame constituting the lower part of the seat cushion and the floor side at one end in the width direction of the seat cushion and in the rear portion in the front-rear direction. 1 and load sensor you output as detected voltage load acting on the arranged along the seating surface of the seat cushion, in order to detect the activated condition of the load, at a distance in the longitudinal direction comprising a plurality of contacts, the other longitudinal side of at least one of the said longitudinal direction of at least one of said contacts on one side Point is formed by at least one membrane switch is formed in an elongated planar with an operation circuit for turning on when simultaneously closed, the membrane switch, the other end portion in the width direction of the seat cushion And, it extends in the front-rear direction of the seat cushion at the rear part in the front-rear direction and is disposed along the seating surface, or extends in the width direction of the seat cushion at the rear part of the seat cushion to the seating surface. A width of the seat cushion at the front portion of the seat cushion for detecting a state in which the adult sits ahead of the normal seating state A first membrane switch extending in the direction and disposed along the seating surface, and the first membrane switch Is to include at least one of the second membrane switch disposed along parallel with said seating surface and said first membrane switch backwards interference.

The invention of the occupant detection system according to claim 2 is characterized in that an output value from the load sensor of the occupant detection sensor according to claim 1 is an on / off signal output from the first to third membrane switches. When the occupant detection system includes an ECU that determines that the occupant on the seat cushion is an adult when the threshold is larger than the threshold value set according to the vehicle, the ECU outputs from the first to third membrane switches. The threshold for determining that the occupant is an adult when the on / off signal to be turned off is stored as a normal seating threshold H, and the on / off signal output from the third membrane switch Is stored as a biased seating threshold value K that is smaller than the normal seating threshold value H, and the threshold value output from the second membrane switch is stored. When the biased seating threshold I is smaller than the biased seating threshold K stored as the threshold when the / off signal is on, and the on / off signal output from the first membrane switch is on At least one of the biased seating threshold values J smaller than the biased seating threshold value I stored as the threshold value .
The occupant detection system according to claim 3 is characterized in that, in claim 2, the ECU outputs an output value from the load sensor of the occupant detection sensor from the first to third membrane switches. When it is smaller than the threshold value set in accordance with the on / off signal, the occupant on the seat cushion determines that the child or the child seat is mounted on the seat cushion.

The occupant detection system according to claim 4 is characterized in that an occupant detection sensor that detects a load state of a seat including a seat cushion and a seat back by a plurality of sensors disposed on the seat cushion, and the occupant detection sensor includes: An occupant detection system comprising: an ECU for determining that an occupant on the seat cushion is an adult based on an output; and the occupant detection sensor includes both ends of the seat cushion in the width direction and a rearward direction The first load sensor and the second load are arranged between the seat frame constituting the lower part of the seat cushion and the floor side, each detecting a load acting on the seat cushion and outputting it as a voltage. A sensor is disposed along a seating surface of the seat cushion to detect an action state of the load , Comprising a plurality of contacts spaced in the longitudinal direction, and an operation that turns on when at least one contact on one side in the longitudinal direction and at least one contact on the other side in the longitudinal direction are simultaneously closed And at least one membrane switch formed in an elongated surface shape having a circuit, wherein the membrane switch is configured to detect the state in which an adult is seated forward of a normal seating state. A first membrane switch extending in the width direction of the seat and disposed at the front portion of the seat cushion along the seating surface, and parallel to the first membrane switch slightly behind the first membrane switch. wherein at least one of the second membrane switch the disposed along the seating surface, the ECU, the of the occupant detection sensor When the total output value from the first and second load sensors is greater than a plurality of threshold values set according to the on / off signals output from the first and second membrane switches, An occupant detection system that determines that an occupant is an adult.

A feature of the occupant detection system according to claim 5 is that, in claim 4, the ECU is configured such that the occupant is an adult when the on / off signals output from the first and second membrane switches are off. The threshold for discriminating that the normal seating is used is stored as the normal seating threshold F, and is stored as the threshold when the on / off signal output from the second membrane switch is on. A biased seating threshold P smaller than the threshold F, and a biased seat smaller than the biased seating threshold P stored as the threshold when the on / off signal output from the first membrane switch is on. That is, at least one of the use threshold values G is stored.
The occupant detection system according to claim 6 is characterized in that, in claim 4 or 5, the ECU is configured such that a total output value of the occupant detection sensor from the first and second load sensors is the first and second load sensors. By determining that the occupant on the seat cushion is a child or a child seat is mounted on the seat cushion when the threshold is smaller than the threshold value set according to the on / off signal output from the second membrane switch. is there.

According to the invention of an occupant detection sensor according to claim 1, the working condition of at least two load on the seating surface of the long planar membrane switch detects, one load sensors disposed in the sheet It can be determined that the occupant is an adult based on the detected seat load (output value). In this way, it is possible to appropriately determine whether or not the occupant on the seat cushion is an adult while significantly reducing the cost as compared with the conventional apparatus configured by four expensive load sensors.
The third membrane switch detects a state in which a load is acting on the other end side in the width direction of the seat cushion (lateral displacement seating state). Further, the first membrane switch detects a load acting in front of the seat from the load in the normal seating state (front seating state), and the second membrane switch detects the load in the normal seating state and the front seating state. A state in which a load is acting forward is detected (a front landing state). Further, the magnitude (output value) of the load acting on the rear one side of the seat is detected by one first load sensor arranged at one rear end portion in the width direction of the seat cushion. Based on the load state on the seat detected by the first to third membrane switches and the magnitude (output value) of the load detected by the first load sensor, it is seated on the seat. Determined to be an adult. Since the low-cost third membrane switch detects the lateral displacement seating state and the inexpensive first and second membrane switches can detect the front seating state and the front seating state, the load is relatively expensive. A single sensor can be used, and adults can be properly identified while significantly reducing costs.

According to the occupant detection system of the present invention, when the first, second, and third membrane switches are all off , the ECU assumes that the occupant is seated in the normal seating state, and the first load If the sensor output value is greater than the normal seating threshold H, it is determined that the person is an adult. In addition, when the third membrane switch is turned on and the load state of the lateral displacement seat is detected, the output value of the first load sensor is smaller than the normal seating threshold value H. If it is greater than the threshold value K, it is determined that the person is an adult. In addition, when the second membrane switch is turned on and the load state of the front landing seat is detected, the bias value for the front landing seat in which the output value of the first load sensor is smaller than the bias seating threshold value K. If it is greater than the sitting threshold I, it is determined that the person is an adult. Further, when the first membrane switch is turned on and the load state of the front seating is detected, the output value of the first load sensor is smaller than the biasing seating threshold value I. If it is larger than the threshold value J, it is determined that the person is an adult. Since it can be determined that an adult is on board without using complicated control in this way, a simple system configuration can be achieved, and the cost can be reduced.

According to the occupant detection system of the present invention, the load acting state on the seating surface detected by at least one long surface membrane switch and the two load sensors arranged on the seat It can be determined that the occupant is an adult based on the detected seat load (output value). In this way, it is possible to appropriately determine whether or not the occupant on the seat cushion is an adult while significantly reducing the cost as compared with the conventional apparatus configured by four expensive load sensors.
Further, a state in which a load is applied in front of the seat (a front seating state) is detected by a first membrane switch from a load in a normal seating state, and the load in the normal seating state and the front seating state are detected by the second membrane switch. A state in which a load is acting on the front side (front landing state) is detected. Further, the magnitude of the load (total output value) acting rearward and leftward and rightward on the seat is detected by the first and second load sensors arranged one by one at both ends in the width direction of the seat frame. . And on the seat based on the load state on the seat detected by at least one of the first and second membrane switches and the magnitude (total output value) of the load detected by the first and second load sensors. It is determined that an adult is seated in In this way, one or two inexpensive membrane switches can detect the front seating state or the front seating state, so that two relatively expensive load sensors can be configured. Can distinguish adults.

According to the occupant detection system of the present invention, when the first and second membrane switches are both off , the ECU assumes that the occupant is seated in the normal seating state, and the first and second loads. If the total output value of the sensor is greater than the normal seating threshold F, it is determined that the person is an adult. When the second membrane switch is turned on and the load state of the front landing seat is detected, the total output value of the first and second load sensors is smaller than the normal seating threshold F. If it is larger than the biased seating threshold value P, it is determined that the person is an adult. Further, when the first membrane switch is turned on and the load state of the front seating is detected, the total output value of the first and second load sensors is smaller than the biased seating threshold value P. If it is larger than the biased seating threshold G, it is determined that the person is an adult. Thus, since it can be determined that an adult is on board without using complicated control, a simple system configuration can be achieved, and it can be handled at low cost.

It is a perspective view which shows the vehicle seat provided with the passenger | crew detection sensor which concerns on embodiment of this invention. It is a control block diagram concerning an embodiment of the invention. It is a block diagram of the sensor element of a load sensor. It is a top view of a membrane switch. It is a top view of the vehicle seat which has arrange | positioned the passenger | crew detection sensor which concerns on the 1st thru | or 7th embodiment. It is the schematic which shows the contact of a membrane switch. It is a threshold value table for adult determination concerning the 1st thru / or a 3rd embodiment. It is the flowchart 1 of the action | operation which concerns on 1st Embodiment. It is the flowchart 2 of the action | operation which concerns on 2nd Embodiment. It is the flowchart 3 of the action | operation which concerns on 3rd Embodiment. It is the flowchart 4 of the action | operation which concerns on 4th Embodiment. It is the flowchart 5 of the action | operation which concerns on 5th Embodiment. It is a flowchart 6 of the action | operation which concerns on 6th Embodiment. It is the flowchart 7 of the action | operation which concerns on 7th Embodiment. It is a threshold value table for adult determination concerning the 4th thru / or 7th embodiment. It is a top view of the vehicle seat which showed another example of arrangement of the 3rd membrane switch.

  Hereinafter, occupant detection sensor 30 and occupant detection system 50 of vehicle seat 11 concerning a 1st embodiment of the present invention are explained based on a drawing. In the following description, the front, rear, left, right, up and down directions are as shown in FIG. 1 and correspond to the respective directions seen from the state where the seated person is seated on the vehicle seat 11.

  As shown in FIG. 1, a vehicle seat 11 includes a seat cushion 11 a on which an occupant is seated, a seat back 11 b that is connected to the seat cushion 11 a and is fixed so as to be rotatable at an arbitrary angle around a connection portion (not shown). It comprises a seat slide device 13 for fixing the seat cushion 11a to a vehicle floor (not shown) so that the position can be adjusted, and an occupant detection sensor 30 constituting the occupant detection system 50 according to the present invention disposed on the seat cushion 11a.

  The seat cushion 11a includes a frame 17 that forms the lower part of the vehicle seat 11, and a cushion that covers the frame 17. The seat slide device 13 is fixed to a floor (not shown) and extends in the front-rear direction of the vehicle as shown in FIG. And a pair of left and right upper rails 16 movably supported on the upper side of the lower rail 14.

  The occupant detection system 50 is in a state in which a buckle switch 40 that outputs an ON signal is engaged when a male part and a female part of a buckle part of an unillustrated seat belt are engaged, that is, an adult or a child gets on the seat belt. In the state where the child seat is worn or the child seat is worn by the seat belt, an adult on the seat cushion 11a is discriminated from the child seat (or a child is seated).

  As shown in the control block diagram of FIG. 2, the occupant detection system 50 includes first and second load sensors 31 and 32 and a first membrane switch 33 that constitute the occupant detection sensor 30, and a seat belt buckle (not shown). A switch 40 and an ECU (control unit) 42 are provided. The ECU 42 includes a CPU 43, a RAM 44, a ROM 45, and an interface 46. In the RAM 44, the output values of the load sensors 31 and 32 constituting the occupant detection sensor 30, the on / off signal of the first membrane switch 33, and the on / off signal of the seat belt buckle switch 40 are connected via the interface 46. The ROM 45 stores a program for operating the occupant detection system 50. The CPU 43 executes the occupant detection system 50 based on the output values of the load sensors 31 and 32 transmitted to the RAM 44 and the on / off signals of the first membrane switch 33 and the buckle switch 40. Further, an airbag device 41 is connected to the ECU 42, and the deployment of the airbag device 41 is controlled based on the detection result of the occupant detection system 50.

  As shown in FIG. 1, the first and second load sensors 31, 32 are provided on the lower surface of the frame 17 (seat-side fixing member) constituting the lower part of the seat cushion 11 a at two locations on the rear side and on the pair of upper rails 16. It is interposed and fixed between the mounting surface 18 formed on the upper surface. The lower surface of the front side of the frame 17 is directly fixed to a mounting surface 18 formed on the upper surfaces of the pair of upper rails 16.

  As a result, the first and second load sensors 31 and 32 measure the magnitude of the load applied to the rear and left and right of the load applied to the vehicle seat 11 by the occupant seated on the vehicle seat 11. In other words, a large output value is output when the seated adult occupant is seated deeply behind the seat cushion 11a, and when the seat is closer to the front of the seat cushion 11a than when seated normally, that is, when sitting forward. The output value becomes small. Even when the vehicle is going downhill, the occupant's body bends forward and the output value decreases. In the present invention, in order to accurately discriminate between an adult and a child seat even in various situations as described above, each situation is detected by an occupant detection sensor 30 and prepared according to each detected state, which will be described later. Discrimination between adults and child seats is performed based on each threshold value. The first and second load sensors 31 and 32 may be any one that can output a voltage value corresponding to the magnitude of the load applied to the seat 11, and in this embodiment Apply load sensors with strain gauges.

  FIG. 3 is a block diagram showing the electrical connection of the first and second load sensors 31 and 32. The first and second load sensors 31 and 32 include a sensor unit 2, an amplifier circuit 3, and a digital circuit 4. The sensor unit 2 is composed of a Wheatstone bridge circuit composed of four strain gauges 2a. The load of the occupant seated on the seat cushion 11a is transmitted to the sensor unit 2 via the seat seating surface skin, and the strain generated in the sensor unit 2 is converted into an electrical resistance by the strain gauge 2a. It is converted into a voltage by a Wheatstone bridge circuit. The amplifier circuit 3 amplifies the voltage output from the sensor unit 2, and the digital circuit 4 converts the output voltage of the amplifier circuit 3 into a digital value and transmits the digital value to the ECU 42.

  As shown in FIG. 4, the first membrane switch 33 is formed in a long surface shape, and has four contacts S1 to S8 in total, four on each of the left and right sides with the central portion in the longitudinal direction as a boundary. doing. It also has an operation circuit that turns on when at least one contact on the right side on one side and at least one contact on the left side on the other side are simultaneously closed, and a load is applied to two or more specific contacts. It is configured to detect the load by turning on when conducting simultaneously.

  As shown in FIG. 5A, the first membrane switch 33 is embedded in the seat back surface of the seat cushion 11a, which is the seat surface of the vehicle seat 11, so that the longitudinal direction is parallel to the left-right direction. 11 in the left-right direction of the seat surface, the substantially central portion of the first membrane switch 33 in the longitudinal direction is disposed at the substantially central portion of the vehicle seat 11, and is disposed closer to the front in the front-rear direction. The first membrane switch 33 is configured such that a load acting downward by a seated person is transmitted through the seat seating surface skin. In other words, when the occupant is seated in the vehicle seat 11 in a forward seated state or in a forward-bent state, a load greater than a predetermined amount generated by the seating is transmitted to the first membrane switch 33 and specified. It is turned on when two or more of the contact points are conducted, and it is detected that the occupant is in the forward sitting state or the forward bending state. That is, the first membrane switch 33 is for detecting the applied state of the load acting on the seating surface of the seat 11 (front seating state, forward bending, etc.), and other membrane switches described later have similar purposes. have.

  As shown in FIG. 6, the first membrane switch 33 has a three-layer structure of a lower film 25, a spacer 26, and an upper film 27. The lower film 25 includes a counter electrode 28 on which a resistor is printed, and the upper film 27 includes a pair of comb electrodes 60 and 61. The comb electrodes 60 and 61 are spaced apart. A hole 26a is formed in the spacer 26, and the opposing electrode 28 and the pair of comb electrodes 60 and 61 face each other through the hole 26a. The lower film 25 and the upper film 27 are formed of, for example, a PEN film having a thickness of about 100 μm.

  The contact points S1 to S8 of the first membrane switch 33 are formed such that the lower electrode 25 and the upper film 27 are deformed by a load greater than or equal to a certain value applied from above, so that the comb electrodes 60 and 61 are connected to the counter electrode 28. Touched. When the comb electrodes 60 and 61 come into contact with the counter electrode 28, the pair of comb electrodes 60 and 61 are electrically connected via the counter electrode 28. The opposing side electrode 28 and the pair of comb electrodes 60 and 61 constitute each contact (S1 to S8) of the first membrane switch 33. The lower film 25 and the upper film 27 are set to have such strength that the comb electrodes 60 and 61 do not come into contact with the counter electrode 28 when the weight of a small child is small.

  Next, operation | movement of the passenger | crew detection system 50 which concerns on this invention is demonstrated based on FIG. In the occupant detection system 50, in the configuration described above, first, the output of the first membrane switch 33 that detects forward seating is input to the ECU 42 via the I / F 46 and confirmed. If the signal of the first membrane switch 33 is OFF, an adult seated person is seated deeply behind the seat cushion 11a (regular seated state), a light weight child is seated, or a child seat The case where is installed. The total output value of the first and second load sensors 31 and 32 is input to the ECU 42 via the I / F 46. If an adult seated person is seated deeply in the seat cushion 11a, a sufficient load is applied to the first and second load sensors 31 and 32. Therefore, as shown in FIG. As the threshold value for comparison with the total output value from the load sensors 31 and 32, the normal seating threshold value F stored in the ECU 42 as the normal seating value that is evaluated and determined in the initial stage is selected. Then, the total output value from the first and second load sensors 31, 32 is confirmed. If the total output value is larger than the normal seating threshold F, the ECU 42 determines that an adult is seated on the seat cushion 11a. The If the output values from the first and second load sensors 31, 32 are smaller than the normal seating threshold F, it is determined that the child is seated or the child seat is worn.

  Next, the case where the output of the 1st membrane switch 33 which detects a passenger | crew's front seating state is ON is demonstrated. If the first membrane switch 33 is on, an adult occupant may be seated forward (or bent forward), or a part of the child seat may be in contact with the first membrane switch 33. When an adult occupant is seated forward, the seat is not necessarily seated deeply behind the seat cushion 11a, and the total output value from the first and second load sensors 31, 32 decreases by a predetermined amount A. . Therefore, as shown in FIG. 7, a biased seating threshold value G obtained by lowering the threshold value for the adult and child seat with respect to the total output value from the first and second load sensors 31 and 32 by a predetermined amount A from the normal seating threshold value F is used. The determination is made based on the threshold value stored in the ECU 42. If the total output value from the first and second load sensors 31 and 32 is larger than the biased seating threshold G, it is determined that an adult is seated. If it is equal to or less than the biased seating threshold G, the ECU 42 determines that the child seat is attached to the vehicle seat 11. When it is determined that an adult is seated, the operation of the air bag device 41 is permitted, and the air bag device 41 is operated in a collision or the like so that the occupant can be protected. On the other hand, in the other state, that is, when it is determined that at least a child seat is worn or a small child is seated, the operation of the airbag device 41 is not permitted. Thereby, it is possible to prevent the airbag device 41 from operating even at the time of a collision and the like, so that an impact caused by the operation of the airbag device 41 is not given to an infant or a small child.

  Next, the operation of the occupant detection system 50 will be described with reference to the flowchart 1 of FIG. The occupant detection system 50 is executed at regular time intervals, and in step S100, it is determined whether or not the first membrane switch 33 is in an on state. When the adult is seated deeply behind the seat cushion 11a, that is, in a normal seated state, the first membrane switch 33 is turned off and the determination result in Step S100 is NO, and the process proceeds to Step S101. .

  In step S101, the total output value of the first and second load sensors 31, 32 and the selected normal seating threshold F are compared, and if the total output value is larger, the process proceeds to step S104 and the adult occupant Is determined to be seated. If the total output value is smaller than the normal seating threshold value F, the process proceeds to step S102, and it is determined that a child seat is installed on the seat cushion 11a (or a child is on the seat cushion 11a). Is done.

  In step S100, when an adult is seated in the front portion of the seat cushion 11a, that is, when seated forward, the first membrane switch 33 is turned on, and the determination result in step S100 is yes. The process proceeds to S103.

  In step S103, the total output value of the first and second load sensors 31 and 32 is compared with the biased seating threshold G obtained by subtracting a predetermined amount A from the normal seating threshold F, and the total output value is biased seating. When it is larger than the use threshold G, the process proceeds to step S104 and it is determined that an adult occupant is seated. If the total output value is smaller than the biased seating threshold G, the process proceeds to step S102, where it is determined that a child seat, not an adult occupant, is mounted on the seat cushion 11a.

  The above is the basic operation of the occupant detection system 50 according to the present invention. However, since the riding postures of the occupants in the actual vehicle are diverse, it is verified by experiment whether the operation of the occupant detection system 50 can be normally judged between an adult and a child seat, assuming four possible riding postures. . As a result, since all were able to be discriminated well, the reasoning that can be judged is described below.

  The four patterns assumed are: (1) a regular seating state in which the user sits deeply on the vehicle seat 11; (2) when the passenger sits forward on the vehicle seat 11; And (4) when the occupant leans against either the left or right door or armrest on the vehicle seat 11 (hereinafter referred to as one side leaning). is there.

  In (1) to (4) described above, (1) the normal seating state and (2) the front seating state have been described in detail in the operation of the occupant detection system 50, and thus the description thereof is omitted.

  When the adult occupant of (3) is seated on the vehicle seat 11 in a laterally displaced state, first, the output of the first membrane switch 33 is confirmed in the same manner as in the (1) regular seating state and (2) the front seating state. Is done. When sitting deeply behind the seat cushion 11a and seated in a laterally shifted state, the output of the first membrane switch 33 for detecting forward seating is turned off. And even if a seated person sits in a state of lateral deviation, the first and second load sensors 31 and 32 increase the load on one side and decrease the other side, and the total output value does not change so much. Therefore, there is no need to change the normal seating threshold value F. The total output value from the first and second load sensors 31 and 32 is confirmed, and if the total output value is larger than the normal seating threshold value F, the seat cushion 11a Can determine that an adult is sitting.

  Next, a description will be given of a case where the user sits on the seat cushion 11a while sitting in a laterally shifted state. In this case, the first membrane switch 33 for detecting forward seating extends in the left-right direction and includes a plurality of contacts, so that the output is turned on under the load of an adult seated person. And since (2) is seated forward, the total output value from the first and second load sensors 31, 32 decreases by a predetermined amount A. Therefore, as shown in FIG. 7, an adult is seated by a biased seating threshold G obtained by lowering the normal seating threshold F for adult determination with respect to the total output value from the first and second load sensors 31 and 32 by a decrease amount A. Judge that you are doing. If the total output value from the load sensors 31, 32 is greater than the biased seating threshold G, it can be determined that an adult is on board.

  Next, the determination of the seating in the state of leaning on one side (4) will be described. In the leaning state on one side, an adult occupant sits forward or sits deeply behind the seat cushion 11a and is seated slightly shifted in either direction in the left-right direction (width direction) of the seat cushion 11a. Assume a state of leaning against the door or armrest on the opposite side.

  First, a description will be given of the leaning on one side while sitting deeply behind the seat cushion 11a. In this case, the output of the first membrane switch 33 for detecting forward seating is turned off. The total output value from the first and second load sensors 31 and 32 is reduced by the amount of the leaning load. However, as a result of the evaluation, it was found that the amount of decrease was small and it was not necessary to consider it, except for the extreme leaning posture. Accordingly, an adult and a child seat may be determined based on the normal seating threshold F selected in the normal seating state shown in FIG.

  Next, a description will be given of a case where the user sits forward and sits slightly off the center in the left-right direction (width direction) of the seat cushion 11a and leans against a door or an armrest. In this case, the output of the first membrane switch 33 for detecting forward seating is turned on. And the total output value from the 1st, 2nd load sensors 31 and 32 falls because of forward seating. Further, the total output value from the first and second load sensors 31 and 32 further decreases by the amount of the load on which the seated person leans left and right. However, as described above, it was found that the amount of decrease was not so large that it was not necessary to consider it. Thus, it has been found that it is possible to determine that an adult is seated based on the biased seating threshold G selected when the occupant shown in FIG. 7 is seated forward.

  As is apparent from the above description, in the first embodiment, when the first membrane switch 33 is off, the occupant detection system 50 assumes that the occupant is seated in the normal seating state. When the total output value of the load sensors 31 and 32 is larger than the normal seating threshold F, it is determined that the person is an adult. Further, when the first membrane switch 33 is turned on and the load state of the forward seating is detected, the forward output in which the total output value of the first and second load sensors 31 and 32 is smaller than the normal seating threshold F. If it is larger than the biased sitting threshold G for sitting, it is determined to be an adult. As described above, the front seating state can be detected by one inexpensive first membrane switch 33, so that two relatively expensive load sensors can be configured, and it is possible to appropriately discriminate adults while reducing costs. Can do. Further, since it is possible to discriminate adults without using complicated control, a simple system configuration can be achieved, and it can be handled at a lower cost.

  Next, a second embodiment of the occupant detection system according to the present invention will be described. The second embodiment differs from the first embodiment in that an occupant detection system 51 is configured by a second membrane switch 34 instead of the first membrane switch 33 that configures the occupant detection sensor 30. Therefore, the occupant detection sensor 63 constituting the occupant detection system 51 includes the first and second load sensors 31 and 32 and the second membrane switch 34. In the second embodiment, only the changing unit will be described, and the description of other parts will be omitted. The configuration and operation of the first membrane switch 33 and the second membrane switch 34 are exactly the same.

  As shown in FIG. 5 (b), the second membrane switch 34 is embedded in the seat back surface of the seat cushion 11a, which is the seat surface of the seat 11, so that the longitudinal direction is parallel to the left-right direction, and the seat cushion 11a. The central part of the second membrane switch 34 in the longitudinal direction is disposed at the substantially central part of the seat cushion 11a in the left-right direction of the seating surface, and is also disposed at the substantially central part in the front-rear direction. That is, the first membrane switch 33 arranged in the first embodiment is arranged slightly behind the position where the first membrane switch 33 is arranged and in parallel with the first membrane switch 33.

  The second membrane switch 34 is for detecting the front seating state in which the load is acting slightly forward between the load in the normal seating state and the front seating state on the seat cushion 11a. It is. When the signal of the second membrane switch 34 is OFF, there is a possibility that the occupant is seated in the normal seating state. Therefore, the total output value of the first and second load sensors 31 and 32 is confirmed and compared with the normal seating threshold value F stored in the ECU 42 shown in FIG. Judge that there is.

  If the signal of the second membrane switch 34 is on, there is a possibility that the occupant is seated in the front landing state. Then, the total output value of the first and second load sensors 31 and 32 is confirmed by the ECU 42. At this time, as shown in FIG. 7, the first and second load sensors 31, 32 have a smaller load than when seated normally and a larger load than when seated forward. The biased seating threshold value P stored in the ECU 42, which is smaller by the predetermined amount B and larger by the predetermined amount (AB) than the biased seating threshold value G employed in the first embodiment, is selected and used for determination. The If the total output value from the first and second load sensors 31, 32 is greater than the biased seating threshold value P, it is determined that an adult is seated on the seat cushion 11a. Here, the predetermined amount B is the magnitude of the total output value that is reduced by the front landing seat with respect to the total output value detected from the first and second load sensors 31 and 32 in the normal seating state. is there.

  Next, the operation of the occupant detection system 51 of the second embodiment will be described based on the flowchart 2 of FIG.

  First, in step S200, it is determined whether or not the second membrane switch 34 is in an on state. If it is off, the process proceeds to step S201, and if it is on, the process proceeds to step S203.

  In step S201, the total output value of the first and second load sensors 31, 32 and the normal seating threshold value F are compared. If the total output value is larger than the normal seating threshold value F, the process proceeds to step S204. Is determined to be seated.

  As described above, if the second membrane switch 34 is in the on state in step S200, it is assumed that the adult is sitting on the seat cushion 11a in the front seating state, and the process proceeds to step S203. In step S203, the total output value of the first and second load sensors 31 and 32 is compared with the biased seating threshold P that is lower than the normal seating threshold F by a predetermined amount B. If the total output value is larger, In step S204, it is determined that an adult is seated. If the total output value is smaller than the biased seating threshold P, the determination result in step S203 is NO, and the process proceeds to step S202, where a child, not an adult, is seated on the seat cushion 11a, or a child seat is mounted. It is determined that

  As is apparent from the above description, in the second embodiment, the occupant detection system 51 assumes that the occupant is seated in the normal seating state when the second membrane switch 34 is off, and the first and second When the total output value of the load sensors 31 and 32 is larger than the normal seating threshold F, it is determined that the person is an adult. When the second membrane switch 34 is turned on and the load state of the front landing seat is detected, the total output value of the first and second load sensors 31 and 32 is a predetermined amount B from the normal seating threshold F. When it is smaller and larger than the biased seating threshold value P stored in the ECU 42, which is larger than the biased seating threshold value G at the time of forward seating by a predetermined amount (AB), it is determined to be an adult. As described above, since the front seating state can be detected by one inexpensive second membrane switch 34, the load sensor which is relatively expensive can be configured with two pieces, and the cost of the adult can be appropriately reduced. Can be distinguished. Further, since it is possible to discriminate adults without using complicated control, a simple system configuration can be achieved, and it can be handled at a lower cost.

  Next, a third embodiment of the occupant detection system according to the present invention will be described. The third embodiment is different from the first embodiment in that an occupant detection system 52 is configured by adding the second membrane switch 34. Therefore, the occupant detection sensor 64 constituting the occupant detection system 52 includes the first and second load sensors 31 and 32, the first membrane switch 33, and the second membrane switch 34. In the third embodiment, only the changing unit will be described, and the description of other parts will be omitted. In addition, as shown in FIG.5 (c), the 1st membrane switch 33 and the 2nd membrane switch 34 are the 1st membrane arrange | positioned on the seat cushion 11a in 1st Embodiment and 2nd Embodiment. The switch 33 and the second membrane switch 34 are disposed at positions similar to the positions, and the objects detected by the load sensors 31 and 32 and the membrane switches 33 and 34 are the same as those in the first embodiment and the second embodiment. The contents are the same as described.

  In the third embodiment, the operation of the occupant detection system 52 will be described based on the flowchart 3 of FIG.

  First, in step S300, it is determined whether or not the first membrane switch 33 indicating that the occupant is in the forward sitting state is in the on state. If it is in the off state, the process proceeds to step S301, and if it is in the on state indicating forward seating, the process proceeds to step S305 described later.

  In step S301, it is determined whether or not the second membrane switch 34 is on. If it is off, the process proceeds to step S302, and if it is on, the process proceeds to step S304 described later.

  In step S302, the total output value from the first and second load sensors 31, 32 is compared with the normal seating threshold value F stored in the ECU 42 for determining the normal seating, and the total of the load sensors 31, 32 is calculated. If the output value is larger, the process proceeds to step S306 and it is determined that an adult is on board. If the total output value from the first and second load sensors 31, 32 is smaller than the normal seating threshold F, the process proceeds to step S303 and it is determined that the child seat is attached.

  In step S304, if the second membrane switch 34 is on from step S301, the movement is YES, and the total output value from the first and second load sensors 31, 32 is a predetermined amount B more than the normal seating threshold F. It is compared with the biased seating threshold value P stored in the lower ECU 42, and if the total output value is larger, the process proceeds to step S306 and it is determined that an adult is on board. If the total output value from the first and second load sensors 31, 32 is smaller than the biased seating threshold value P, the process proceeds to step S303 and it is determined that the child seat is attached. Here, the predetermined amount B is as described in the second embodiment.

  In step S305, as described above, when the first membrane switch 33 that detects forward seating in step S300 is in the ON state, the movement is YES, the total output value from the first and second load sensors 31, 32, The biased seating threshold G stored in the ECU 42 is smaller than the normal seating threshold F by a predetermined amount A and smaller than the biased seating threshold P by a predetermined amount (A−B), and the total output value is greater. If it is larger, the process proceeds to step S306 and it is determined that an adult is on board. If the total output value from the first and second load sensors 31 and 32 is smaller than the biased seating threshold G, the process proceeds to step S303 and it is determined that the child seat is attached.

  As is apparent from the above description, in the third embodiment, the occupant detection system 52 assumes that the occupant is seated in the normal seating state when both the first and second membrane switches 33 and 34 are off. If the total output value of the first and second load sensors 31, 32 is larger than the normal seating threshold F, it is determined that the person is an adult. When the second membrane switch 34 is turned on and the load state of the front landing seat is detected, the total output value of the first and second load sensors 31 and 32 is smaller than the normal seating threshold F. If it is larger than the biased sitting threshold P for the front landing, it is determined that the person is an adult. Further, when the first membrane switch 33 is turned on and the load state of the front seating is detected, the total output value of the first and second load sensors 31 and 32 is smaller than the biased seating threshold value P. If it is larger than the biased seating threshold G for forward seating, it is determined that the person is an adult. As described above, the front seating state and the front seating state can be detected by the two inexpensive first and second membrane switches 33 and 34, so that two relatively expensive load sensors can be configured, thereby reducing the cost. It is possible to discriminate adults properly while trying. Further, since it is possible to discriminate adults without using complicated control, a simple system configuration can be achieved, and it can be handled at a lower cost.

  Next, fourth to seventh embodiments will be described. The fourth to seventh embodiments are different from the first to third embodiments in that one of the first and second load sensors 31, 32 is eliminated, and the third membrane switch 35 is added to constitute occupant detection sensors 66-68. In the present embodiment, as shown in FIGS. 5D to 5G, the third membrane switch 35 is embedded in the back surface of the seat cushion 11a extending in the width direction behind the seating surface. Yes. The seat is configured to be turned on when a load state of so-called lateral displacement seating is detected in which the seated person is seated with a slight shift in the width direction from the center on the seat cushion 11a, and when the occupant is seated in a regular seating state. Turns off. The third membrane switch 35 may have any structure as long as it can detect ON / OFF, but a sensor having higher sensitivity than the first and second membrane switches 33 and 34 is preferable. Therefore, even if the structure and operation are the same as those of the first and second membrane switches 33 and 34, each contact can be contacted with a lower load. In the fourth to seventh embodiments, since the load sensor 31 is composed of one piece, the output value from the load sensor 31 is the first to third elements that are composed of the two load sensors 31, 32. Compared to the case of the embodiment, it becomes approximately half.

  In the fifth to seventh embodiments, the first load sensor 31 and the third membrane switch 35 are basically configured as described above, and the first is similar to the first to third embodiments. The membrane switch 33 and the second membrane switch 34 are combined. The first to third embodiments and the fourth to sixth embodiments have a correspondence relationship in the combination of the first membrane switch 33 and the second membrane switch 34, and the first, fourth, Each of the second and fifth, third, and sixth embodiments has the same combination, and only the seventh embodiment has no corresponding relationship.

  First, a fourth embodiment will be described. As described above, the fourth embodiment differs from the first embodiment only in that the second load sensor 32 is eliminated and a third membrane switch 35 is added. Therefore, as shown in FIG. 5D, the occupant detection sensor 65 constituting the occupant detection system 53 includes the first load sensor 31, the third membrane switch 35, and the first membrane switch 33. In the fourth embodiment, only the changing unit will be described, and the description of other parts will be omitted.

  The operation of the occupant detection system 53 of the fourth embodiment will be described based on the flowchart 4 of FIG.

  First, in step S400, it is determined whether or not the first membrane switch 33 is in an on state. When the adult is normally seated on the seat cushion 11a, the first membrane switch 33 is turned off, and the determination result of step S400 is NO, and the process proceeds to step S401. If it is on, the process proceeds to step S405 described later.

  In step S401, it is determined whether the third membrane switch 35 is on. If it is off, the process proceeds to step S402. If it is on, the process proceeds to step S404. At this time, the fact that the third membrane switch 35 is on may be seated while being laterally displaced in the width direction of the seat cushion 11a.

  In step S402, the output value of the first load sensor 31 is compared with the normal seating threshold value H stored in the ECU 42 shown in FIG. 15. If the output value is larger than the normal seating threshold value H, the process proceeds to step S406. Advancing is determined as an adult. When the output value of the load sensor 31 is smaller than the normal seating threshold value H, the process proceeds to step S403 and it is determined that the child seat is attached.

  In step S404, the output value of the first load sensor 31 is compared with the biased seating threshold value K stored in the ECU 42 that is lower by the predetermined amount N than the normal seating threshold value H shown in FIG. 15, and the output value is larger. Advances to step S406 and it is determined that an adult is seated. Here, the predetermined amount N is the magnitude of the output value that decreases due to the lateral displacement seating with respect to the output value detected from the first load sensor 31 in the normal seating state.

  As described above, if the first membrane switch 33 is on in step S400, there is a possibility that an adult is sitting forward, and the process proceeds to step S405.

  In step S405, the output value of the first load sensor 31 is compared with the biased seating threshold value J (<biased seating threshold value K) stored in the ECU 42 that is lower than the normal seating threshold value H shown in FIG. If the output value is larger, the process proceeds to step S406 and it is determined that an adult occupant is seated. If the output value is smaller than the biased seating threshold value J, the determination result in step S405 is NO, the process proceeds to step S403, and a child, not an adult occupant, is seated on the seat cushion 11a, or a child seat is seated. It is determined that it is attached. Here, the predetermined amount D is the magnitude of the output value that is reduced by forward seating with respect to the output value detected from the first load sensor 31 in the normal seating state.

  As is apparent from the above description, in the fourth embodiment, the occupant detection system 53 assumes that the occupant is seated in the normal seating state when the first and third membrane switches 33 and 35 are all off. When the output value of the first load sensor is larger than the normal seating threshold H, it is determined that the person is an adult. Further, when the third membrane switch 35 is turned on to detect the load state of the lateral displacement seating, the lateral displacement seating deviation in which the output value of the first load sensor 31 is smaller than the normal seating threshold value H. If it is larger than the sitting threshold K, it is determined that the person is an adult. Further, when the first membrane switch 33 is turned on and the load state of the forward seating is detected, the biased seat for forward seating in which the output value of the first load sensor 31 is smaller than the biased seating threshold value K. If it is larger than the threshold J, it is determined that the person is an adult. As described above, since the two low-cost first and third membrane switches 33 and 35 can detect the laterally displaced seating state and the front seating state, a relatively expensive load sensor can be constituted by one, and the cost can be reduced. It is possible to discriminate adults properly while trying. Further, since it is possible to discriminate adults without using complicated control, a simple system configuration can be achieved, and it can be handled at a lower cost.

  Next, a fifth embodiment of an occupant detection system according to the present invention will be described. The fifth embodiment differs from the second embodiment only in that the second load sensor 32 is eliminated and a third membrane switch 35 is added. Therefore, as shown in FIG. 5 (e), the occupant detection sensor 66 that constitutes the occupant detection system 54 includes the first load sensor 31, the third membrane switch 35, and the second membrane switch 34. In the fifth embodiment, only the changing unit will be described, and the description of other parts will be omitted.

  The occupant detection system 54 of the fifth embodiment will be described based on the flowchart 5 of FIG.

  First, in step S500, it is determined whether or not the second membrane switch 34 is on. If it is off, the process proceeds to step S501. If it is on, the process proceeds to step S505.

  In step S501, it is determined whether the third membrane switch 35 is on. If it is off, the process proceeds to step S502. If it is on, the process proceeds to step S504. At this time, the fact that the third membrane switch 35 is on may be seated while being laterally displaced in the width direction of the seat cushion 11a.

  In step S502, the output value of the first load sensor 31 and the normal seating threshold value H stored in the ECU 42 are compared. If the output value is larger than the normal seating threshold value H, the process proceeds to step S506 and the adult is an adult. It is determined. If the output value is smaller than the normal seating threshold H, the process proceeds to step S503, where it is determined that the child seat is used.

  In step S504, the output value of the first load sensor 31 is compared with the biased seating threshold value K stored in the ECU 42 that is a predetermined amount N lower than the normal seating threshold value H shown in FIG. 15, and the output value is larger. Advances to step S506 and it is determined that an adult occupant is seated.

  If the second membrane switch 34 is on in step S500, there is a possibility that an adult is sitting on the seat cushion 11a in the front seating state, the determination result is YES, and the flow proceeds to step S505.

  In step S505, the output value of the first load sensor 31 is compared with the biased seating threshold value I (<biased seating threshold value K) stored in the ECU 42 that is lower than the normal seating threshold value H shown in FIG. If the output value is larger, the process proceeds to step S506 and it is determined that an adult occupant is seated. If the output value is smaller than the biased seating threshold I, the determination result in step S505 is NO, and the process proceeds to step S503, where a child, not an adult occupant, is seated on the seat cushion 11a, or the child seat is It is determined that it is attached. Here, the predetermined amount C is the magnitude of the output value that is reduced by forward seating with respect to the output value detected from the first load sensor 31 in the normal seating state.

  As is apparent from the above description, in the fifth embodiment, the occupant detection system 54 assumes that the occupant is seated in the normal seating state when the second and third membrane switches 34 and 35 are all off. When the output value of the first load sensor 31 is larger than the normal seating threshold H, it is determined that the person is an adult. Further, when the third membrane switch 35 is turned on to detect the load state of the lateral displacement seating, the lateral displacement seating deviation in which the output value of the first load sensor 31 is smaller than the normal seating threshold value H. If it is larger than the sitting threshold K, it is determined that the person is an adult. When the second membrane switch 34 is turned on and the load state of the front landing seat is detected, the output value of the first load sensor 31 is smaller than the biased seating threshold value K. If it is larger than the biased seating threshold I, it is determined that the person is an adult. As described above, since the two low-cost second and third membrane switches 34 and 35 can detect the lateral displacement seating state and the front landing seating state, the load sensor which is relatively expensive can be configured by one, and the cost can be reduced. While trying to reduce, adults can be properly identified. Further, since it is possible to discriminate adults without using complicated control, a simple system configuration can be achieved, and it can be handled at a lower cost.

  Next, a sixth embodiment of the occupant detection system according to the present invention will be described. The sixth embodiment differs from the third embodiment only in that the second load sensor 32 is eliminated and a third membrane switch 35 is added. Therefore, as shown in FIG. 5 (f), the occupant detection sensor 67 constituting the occupant detection system 55 includes the first load sensor 31, the third membrane switch 35, the first membrane switch 33, and the second membrane. Switch 34. In the sixth embodiment, only the changing unit will be described, and the description of other parts will be omitted.

  In the sixth embodiment, the operation of the occupant detection system 55 will be described based on the flowchart 6 of FIG.

  First, in step S600, it is determined whether or not the first membrane switch 33 that detects that the occupant is in the forward sitting state is in the on state. If it is in the off state, the process proceeds to step S601, and if it is in the on state indicating forward seating, the process proceeds to step S607 described later.

  In step S601, it is determined whether or not the second membrane switch 34 is on. If it is off, the process proceeds to step S602, and if it is on, the process proceeds to step S606 described later.

  In step S602, it is determined whether the third membrane switch 35 is on. If it is off, the process proceeds to step S603, and if it is on, the process proceeds to step S605. At this time, the fact that the third membrane switch 35 is on may be seated while being laterally displaced in the width direction of the seat cushion 11a.

  In step S603, the output value of the first load sensor 31 is compared with the normal seating threshold value H stored in the ECU 42. If the output value is greater than the normal seating threshold value H, the process proceeds to step S608 and the adult is seated. It is determined that they are doing. If the output value is smaller than the normal seating threshold H, the process proceeds to step S604, where it is determined that the child seat is attached.

  In step S605, which proceeds when the third membrane switch 35 is in the ON state in step S602, the ECU 42 lowers the output value of the first load sensor 31 and the normal seating threshold H shown in FIG. The stored biased seating threshold value K is compared, and if the output value is larger, the process proceeds to step S608, where it is determined that an adult occupant is seated. If the output value from the first load sensor 31 is smaller than the biased seating threshold value K, the process proceeds to step S604, where it is determined that the child seat is attached.

  If the second membrane switch 34 is on in step S601, the process proceeds to step S606, where the biased seat stored in the ECU 42 is lower than the output value of the first load sensor 31 and the normal seating threshold H by a predetermined amount C. Is compared with the threshold value I (<biased bias threshold value K), and if the output value is larger, the process proceeds to step S608 and it is determined that an adult occupant is seated. If the output value is smaller than the biased seating threshold I, the determination result in step S606 is NO and the process proceeds to step S604, where a child is seated on the seat cushion 11a or a child seat is mounted. Determined.

  In step S607, when the first membrane switch 33 that detects forward seating in step S600 is in the ON state, the movement is YES, and a predetermined amount is obtained from the output value from the first load sensor 31 and the normal seating threshold value H. The biased seating threshold value J is compared with the biased seating threshold value J which is lower by D and lower than the biased seating threshold value I by a predetermined amount (DC). The If the output value from the first load sensor 31 is smaller than the biased seating threshold value J, the process proceeds to step S604, where it is determined that the child seat is attached.

  As is clear from the above description, in the sixth embodiment, the occupant detection system 55 is configured so that the occupant is in a normal seating state when the first, second, and third membrane switches 33, 34, and 35 are all off. If it is assumed that the user is seated and the output value of the first load sensor is larger than the normal seating threshold H, it is determined that the person is an adult. Further, when the third membrane switch 35 is turned on to detect the load state of the lateral displacement seating, the lateral displacement seating deviation in which the output value of the first load sensor 31 is smaller than the normal seating threshold value H. If it is larger than the sitting threshold K, it is determined that the person is an adult. Further, when the second membrane switch 34 is turned on and the load state of the front landing seat is detected, the output value of the first load sensor 31 is smaller than the biased seating threshold value K. If it is larger than the biased seating threshold I, it is determined that the person is an adult. Further, when the first membrane switch 33 is turned on and the load state of the forward seating is detected, the forward seating bias in which the output value of the first load sensor 31 is smaller than the biased seating threshold I. If it is larger than the sitting threshold J, it is determined that the person is an adult. In this way, the low-cost third membrane switch 35 can detect the lateral displacement seating state, and the inexpensive first and second membrane switches 33 and 34 can detect the front seating state and the front seating state. The load sensor can be composed of a single piece, and adults can be properly identified while reducing costs. Further, since it is possible to discriminate adults without using complicated control, a simple system configuration can be achieved, and it can be handled at a lower cost.

  Next, a seventh embodiment of the occupant detection system according to the present invention will be described. In the seventh embodiment, the occupant detection sensor 68 constituting the occupant detection system 56 includes only the first load sensor 31 and the third membrane switch 35 as shown in FIG. In the seventh embodiment, only the changing unit will be described, and the description of other parts will be omitted.

  In the seventh embodiment, the operation of the occupant detection system 56 will be described based on the flowchart 7 of FIG.

  In step S700, it is determined whether the third membrane switch 35 is in an on state. If it is in the off state, it is determined that it is not in the lateral displacement seated state, and the process proceeds to step S701. If it is in the on state, it is determined that the seat is in the lateral displacement seated state, and the process proceeds to step S703.

  In step S701, the output value of the first load sensor 31 and the normal seating threshold value H stored in the ECU 42 are compared. If the output value is larger than the normal seating threshold value H, the process proceeds to step S704 and the adult is seated. It is determined that they are doing. If the output value is smaller than the normal seating threshold H, the process proceeds to step S702 and it is determined that the child seat is attached.

  In step S703, which proceeds when the third membrane switch 35 is in the on state in step S700, the ECU 42 lowers the output value of the first load sensor 31 and the normal seating threshold H shown in FIG. The stored biased seating threshold value K is compared, and if the output value is larger, the process proceeds to step S704, where it is determined that an adult occupant is seated. If the output value from the first load sensor 31 is smaller than the biased seating threshold value K, the process proceeds to step S702 and it is determined that the child seat is attached.

  As apparent from the above description, in the seventh embodiment, when the third membrane switch 35 is off, the occupant detection system 56 assumes that the occupant is seated in the normal seating state, and the first load sensor Is greater than the normal seating threshold H, it is determined that the person is an adult. Further, when the third membrane switch 35 is turned on to detect the load state of the lateral displacement seating, the lateral displacement seating deviation in which the output value of the first load sensor 31 is smaller than the normal seating threshold value H. If it is larger than the sitting threshold K, it is determined that the person is an adult. As described above, since the laterally displaced seating state can be detected by the inexpensive third membrane switch 35, a relatively expensive load sensor can be configured by one, and an adult can be discriminated while reducing the cost. Further, since it is possible to discriminate adults without using complicated control, a simple system configuration can be achieved, and it can be handled at a lower cost.

  In the fourth to seventh embodiments, the third membrane switch 35 extends in the width direction at the cushion rear position of the seat cushion 11a and is disposed along the seating surface. However, not limited to this, as shown in FIG. 16A, the third membrane switch 35a extends in the front-rear direction of the seat cushion 11a at the rear end of the other end in the width direction of the seat cushion 11a and is disposed along the seating surface. May be. Also by this, it is possible to detect the lateral displacement seating of the occupant, and the same effect as in the fourth to seventh embodiments can be expected. A plurality of third membrane switches 35a may be disposed on the seat cushion 11a in parallel with the third membrane switch 35a. As a result, the ability to detect lateral displacement seating is improved, and further effects can be expected.

  In the fourth to seventh embodiments, as shown in FIG. 16B, the third membrane switch 35b formed in a shape widened in the width direction of the seat cushion 11a is replaced with the width direction of the seat cushion 11a. The other end may be disposed so as to extend in the front-rear direction. At this time, a plurality of contacts are provided in the width direction, and this also improves the detection capability of the lateral displacement seating, and further effects can be expected.

  In the fourth to seventh embodiments, the second load sensor 32 is abolished and the first load sensor 31 is adopted as compared with the first to third embodiments. The second load sensor 32 may be adopted and the first load sensor 31 may be omitted, and the same effect can be obtained.

  In the second to seventh embodiments, as in the first embodiment, the above-described four patterns of riding postures (1) to (4) were verified by performing an adult and child seat determination experiment. A good discrimination was made.

  Furthermore, in the present embodiment, the airbag device is described as an example of the safety device. However, the present invention is not limited to this example. For example, the occupant detection systems 50 to 56 may sandwich vehicle windows or sunroofs as safety devices. The present invention can also be applied to a detection device or the like.

DESCRIPTION OF SYMBOLS 2 ... Sensor part, 11 ... Vehicle seat, 11a ... Seat cushion, 13 ... Seat slide apparatus, 14 ... Lower rail, 16 ... Upper rail, 17 ... Frame, 18 ... Mounting surface, 30 ... Passenger detection sensor, 31, 32 ... Load sensor 33, 34, 35 ... membrane switch, 42 ... ECU, 50-56 ... occupant detection system, 63-68 ... occupant detection sensor.

Claims (6)

An occupant detection sensor that detects a load state of a seat including a seat cushion and a seat back by a plurality of sensors arranged on the seat cushion,
The occupant detection sensor is disposed between a seat frame constituting a lower portion of the seat cushion and a floor side at one end portion in the width direction of the seat cushion and a rear portion in the front-rear direction, and acts on the seat cushion. 1 and load sensor you output as detected voltage,
A plurality of contacts arranged in the longitudinal direction and spaced apart in order to detect an action state of the load, and arranged along a seating surface of the seat cushion; and at least one of the contacts on one side in the longitudinal direction ; And at least two membrane switches formed in a long surface shape having an operation circuit that is turned on when at least one contact on the other side in the longitudinal direction is simultaneously closed ,
The membrane switch is disposed along the seating surface extending in the front-rear direction of the seat cushion at the other end in the width direction of the seat cushion and the rear part in the front-rear direction, or at the rear part of the seat cushion A third membrane switch for detecting the state of laterally offset seating extending along the seat cushion and extending along the seating surface;
A first membrane switch that extends in the width direction of the seat cushion at the front portion of the seat cushion and is disposed along the seating surface in order to detect a state in which an adult is seated forward of a normal seating state And at least one of a second membrane switch disposed along the seating surface in parallel with the first membrane switch slightly behind the first membrane switch. Sensor. The output value from the previous yn heavy sensor of the occupant detection sensor according to claim 1 is greater than a plurality of threshold values set according to the first to third output on / off signals from the membrane switch In addition, in an occupant detection system equipped with an ECU that determines that the occupant on the seat cushion is an adult,
The ECU stores the threshold value for determining that the occupant is an adult when the on / off signals output from the first to third membrane switches are off as a normal seating threshold value H, The threshold value when the on / off signal output from the third membrane switch is on is stored as a biased seating threshold value K smaller than the normal seating threshold value H, and is output from the second membrane switch. The biased seating threshold I smaller than the biased seating threshold K, which is stored as the threshold when the on / off signal is on, and the on / off signal output from the first membrane switch are Storing at least one of biased seating threshold values J smaller than the biased seating threshold value I, which is stored as the threshold value in the case of being on. Occupant detection system. 3. The ECU according to claim 2, wherein an output value of the occupant detection sensor from the load sensor is smaller than a threshold set in accordance with on / off signals output from the first to third membrane switches. In addition, the occupant detection system is characterized in that the occupant on the seat cushion determines that a child or a child seat is mounted on the seat cushion. An occupant detection sensor that detects a load state of a seat including a seat cushion and a seat back by a plurality of sensors disposed on the seat cushion, and an occupant on the seat cushion is an adult based on an output of the occupant detection sensor An occupant detection system comprising :
The occupant detection sensor, at both end portions and the rear portions of the front and rear direction in the width direction of the seat cushion, on the seat cushion is arranged one by one each between the seat frame and the floor side which constitutes the lower portion of the seat cushion A first load sensor and a second load sensor that detect acting loads and output them as voltages;
A plurality of contacts arranged in the longitudinal direction and spaced apart in order to detect an action state of the load, and arranged along a seating surface of the seat cushion; and at least one of the contacts on one side in the longitudinal direction ; And at least one membrane switch formed in a long surface shape having an operation circuit that is turned on when at least one contact on the other side in the longitudinal direction is simultaneously closed ,
The membrane switch extends in the width direction of the seat cushion and is disposed at the front portion of the seat cushion along the seating surface in order to detect a state in which an adult is seated forward of a normal seating state. And at least one of a first membrane switch and a second membrane switch disposed along the seating surface in parallel with the first membrane switch slightly behind the first membrane switch,
In the ECU, a total output value from the first and second load sensors of the occupant detection sensor is set in accordance with ON / OFF signals output from the first and second membrane switches. An occupant detection system that determines that an occupant on the seat cushion is an adult when larger than a threshold value . According to claim 4, before Symbol ECU, the occupant for normal sitting the threshold for determining that the adult when ON / OFF signal output from the first and second membrane switch is off A biased seating threshold value P that is stored as a threshold value F, and is stored as the threshold value when the on / off signal output from the second membrane switch is on, and is smaller than the normal seating threshold value F; and At least one of biased seating threshold values G smaller than the biased seating threshold value P stored as the threshold value when the on / off signal output from the first membrane switch is on is stored. An occupant detection system characterized by that. 6. The ECU according to claim 4, wherein the ECU outputs a total output value of the occupant detection sensor from the first and second load sensors to an on / off signal output from the first and second membrane switches. An occupant detection system according to claim 1, wherein the occupant on the seat cushion discriminates that a child or a child seat is mounted on the seat cushion when the threshold value is smaller than the threshold value.

Images