JP7089150B2 - Arrangement structure of biosensor - Google Patents

Description

The present invention relates to an arrangement structure of a biosensor.

If the health condition of the driver who drives the vehicle deteriorates, it may adversely affect the driving of the vehicle. Therefore, it is desirable to detect the deterioration of the health condition in advance and take some measures. As such a measure, biological information such as blood flow and blood pressure is estimated based on the measurement results of pulse waves and the like by a non-contact blood flow sensor provided so as to be embedded in the seat surface and the back surface of the seat. A technique for grasping the health condition of a driver is known (see Patent Document 1).

Japanese Unexamined Patent Publication No. 2016-168177

By the way, in the technique described in Patent Document 1, the patellar artery of the subject is measured from the blood flow data obtained by measuring the blood flow state of the patellar artery and the thoracic aorta of the subject sitting on the seat. And the blood pressure of the thoracic aorta is calculated respectively.
However, when the person to be measured sitting on the seat is the driver of the vehicle, the portion of the back of the knee through which the patellar artery passes may be separated from the seat during driving. Further, when the person to be measured who sits on the seat is other than the driver, or when the seat is not a vehicle seat, the seating posture is difficult to stabilize, so that accurate measurement may not always be possible.

The present invention has been made in view of the above circumstances, and an object of the present invention is to provide an arrangement structure of a biological sensor capable of improving accuracy in measuring the health condition of a person sitting on a seat.

In order to solve the above problems, the invention according to claim 1 is a biosensor arrangement structure in which a plurality of biosensors for measuring the health condition of the occupant are provided on a seat supporting the occupant. And
The seat is provided with a seat body for holding the occupant and an auxiliary support portion for supporting any part of the occupant's body other than the torso and thighs, and can be deformed so as to be in a reclining state. Is configured in
The measurement by the plurality of biosensors is started when the seat is deformed to be in the reclining state and the auxiliary support portion is moved, and the seat is returned from the reclining state to the original state. It is set to stop when the auxiliary support moves.
At least one of the plurality of biosensors is characterized in that it is provided in the auxiliary support portion.

The invention according to claim 2 is based on the arrangement structure of the biosensor according to claim 1.
The auxiliary support includes an armrest that supports the occupant's arm.
The front upper end of the armrest is a place where the biosensor is installed.

The invention according to claim 3 is based on the arrangement structure of the biosensor according to claim 1 or 2.
The auxiliary support includes a headrest that supports the occupant's head.
The front side of the headrest is a place where the biosensor is installed.

The invention according to claim 4 is based on the arrangement structure of the biosensor according to any one of claims 1 to 3.
The auxiliary support includes a necklace that supports the occupant's neck.
The front side of the necklace is a place where the biosensor is installed.

The invention according to claim 5 is based on the arrangement structure of the biosensor according to any one of claims 1 to 4.
The auxiliary support includes an ottoman that supports the legs of the occupant.
The left and right sides of the ottoman are the installation locations of the biosensor.

The invention according to claim 6 is based on the arrangement structure of the biosensor according to any one of claims 1 to 5.
The auxiliary support includes a footrest that supports the occupant's foot.
The left and right sides of the footrest are the installation locations of the biosensor.

The invention according to claim 7 is based on the arrangement structure of the biosensor according to any one of claims 1 to 6.
The plurality of biological sensors are characterized by including a pulse wave sensor for estimating the blood pressure of an occupant.

The invention according to claim 8 is based on the arrangement structure of the biosensor according to claim 7.
The pulse wave sensor is characterized by being a photoelectric pulse wave sensor that measures a occupant's pulse wave by using light.

The invention according to claim 9 is based on the arrangement structure of the biosensor according to claim 8.
The photoelectric pulse wave sensor is characterized in that it is provided so as to be exposed from a skin material constituting the surface of the sheet body or the auxiliary support portion.

The invention according to claim 10 relates to the arrangement structure of the biosensor according to any one of claims 7 to 9.
The pulse wave sensor is characterized by being a piezoelectric pulse wave sensor that measures a occupant's pulse wave by measuring a pressure wave on the occupant's body surface.

The invention according to claim 11 is based on the arrangement structure of the biosensor according to any one of claims 7 to 10.
The pulse wave sensor is characterized by being an electromagnetic wave type pulse wave sensor that measures a occupant's pulse wave by using an electromagnetic wave.

The invention according to claim 12 is based on the arrangement structure of the biosensor according to any one of claims 7 to 11.
The seat is installed in a vehicle equipped with a driving control unit that switches between automatic driving and manual driving, and is configured so that it can be changed to a different form during automatic driving and manual driving.
At least one of the plurality of biosensors is a biosensor of a different type from the pulse wave sensor.

The invention according to claim 13 is based on the arrangement structure of the biosensor according to any one of claims 1 to 12.
The sheet is
A seat cushion that holds the occupant's buttocks and thighs,
The lower end portion has a seat back supported by the seat cushion, and has.
The seat cushion is
The seat cushion frame that becomes the skeleton and
The cushion pad provided on the seat cushion frame and
It is composed of the seat cushion frame and the skin material that covers the cushion pad.
The seat back is
The seat back frame that becomes the skeleton and
The cushion pad provided on the seat back frame and
It is composed of the seat back frame and the skin material that covers the cushion pad.
The plurality of auxiliary support portions are attached to the seat cushion and the seat back, respectively .

According to the first aspect of the present invention, since at least one of the plurality of biosensors is provided in the auxiliary support portion, the body part supported by the auxiliary support portion provided with the biosensor. , Biometric information can be acquired at multiple locations on other parts of the body. As a result, it is possible to improve the accuracy in measuring the health condition of the occupant.
Since the timing of starting or stopping the measurement of the biosensor can be made to correspond to the operation of the auxiliary support portion, it is not necessary to start or stop the measurement by the biosensor by the operation of the occupant, which is convenient and hassle-free. Excellent.

According to the second aspect of the present invention, since the biological sensor can be provided on the armrest, the biological information on the arm can be acquired. Since the biosensor can be provided at a position where the arm can be easily touched, it becomes easy to acquire biometric information on the arm.

According to the third aspect of the present invention, since the biological sensor can be provided on the headrest, the biological information on the head can be acquired. Since the biosensor can be provided at a position where the head can be easily touched, it becomes easy to acquire biometric information on the head.

According to the invention of claim 4, since the biological sensor can be provided for the necklace, the biological information in the neck can be acquired. Then, since the biosensor can be provided at a position where the neck can be easily touched, it becomes easy to acquire biometric information in the neck.

According to the fifth aspect of the present invention, since it is possible to provide a biological sensor for the ottoman, it is possible to acquire biological information on the legs. Since the biosensor can be provided at a position where the legs can be easily touched, it becomes easy to acquire biometric information on the legs.

According to the invention of claim 6, since the biological sensor can be provided on the footrest, the biological information on the foot can be acquired. Since the biosensor can be provided at a position where the foot can be easily touched, it becomes easy to acquire biometric information on the foot.

According to the invention of claim 7, since the pulse wave of the occupant can be measured at a plurality of points by a plurality of biological sensors, the accuracy in estimating the blood pressure of the occupant can be improved.

According to the invention of claim 8, since the pulse wave sensor is a photoelectric pulse wave sensor, it is suitable for measuring a pulse wave in a part of the body that can be irradiated with light.

According to the invention of claim 9, since it is possible to suppress the light from being blocked by the skin material, the accuracy of measurement by the photoelectric pulse wave sensor can be improved.

According to the invention of claim 10, since the pulse wave sensor is a piezoelectric pulse wave sensor, it is suitable for measuring a pulse wave in a part of the body where a pressure wave can be measured.

According to the invention of claim 11, since the pulse wave sensor is an electromagnetic wave type pulse wave sensor, it is possible to measure the pulse wave of the occupant even if it is not in contact with the body of the occupant.

According to the invention of claim 12, since at least one of the plurality of biosensors is a biosensor of a type different from the pulse wave sensor, other biometric information can be acquired, and as a result, the health condition of the occupant. It is possible to improve the accuracy in measuring.

Further , even when the seat is changed into a different form between the automatic operation and the manual operation, the measurement by the biosensor can be performed. In addition, since it is easy for the auxiliary support portion to support the body during automatic driving, it is easy to obtain highly accurate measurement results by a plurality of biosensors.

It is a figure explaining the position of a plurality of biosensors provided in a sheet. It is a figure explaining the positional relationship between a occupant and a plurality of biosensors when a seat is in a reclining state. It is a top view which shows the position of the plurality of biosensors provided for the seat cushion and each auxiliary support part attached thereto. It is a perspective view which shows the installation mode of the biological sensor with respect to the armrest. It is a figure which shows the installation mode of the biological sensor with respect to the sheet provided with the skin material in which a punching hole is formed. It is a figure explaining the state which the biosensor and the control part are connected. It is a figure explaining the state which the biosensor and the vibration power generation element are connected. It is a figure explaining the structure which the vibration power generation element is provided in a vehicle.

Hereinafter, embodiments of the present invention will be described with reference to the drawings. However, although the embodiments described below are provided with various technically preferable limitations for carrying out the present invention, the technical scope of the present invention is not limited to the following embodiments and illustrated examples. do not have.

In FIGS. 1 and 2, reference numeral 1 indicates a seat in which a person who is an occupant P sits and supports the seated occupant P. This seat 1 is provided in a vehicle V such as an automobile in the present embodiment, and in the present embodiment, it is particularly provided in a vehicle V capable of switching between automatic driving and manual driving. And. The seat 1 is not limited to that provided in the vehicle, and may be provided in other vehicles.

In the present embodiment, the vehicle V is a driving control unit V1 that switches between automatic driving and manual driving, the above-mentioned seat 1 that can be changed into a plurality of forms, and a seat that controls the operation of the seat 1 when changing the form. A control unit (not shown) is provided. By interlocking the operation control unit V1 and the seat control unit, the seat 1 can be changed into different forms during automatic operation and manual operation.
The driving control unit V1 controls switching from automatic driving to manual driving, for example, when a vehicle is moved from a highway to a general road or when a road having a complicated shape is approached.

The seat 1 is an auxiliary support portion for supporting the seat body 2 for holding the occupant P and any of the parts P3 to P7 attached to the seat body 2 and excluding the body P1 and the thigh P2 in the body of the occupant P. It is equipped with 11 to 15.
Further, the seat body 2 has a seat cushion 3 that holds the buttocks and thighs P2 of the occupant P, and a seat back 4 whose lower end is supported by the seat cushion 3.
It is assumed that the body P1 of the occupant P includes a shoulder, a chest, an abdomen, a waist, and a buttocks.

The seat cushion 3 includes a seat cushion frame (not shown) as a skeleton, a cushion pad 3a provided on the seat cushion frame, and a skin material 3b for covering the seat cushion frame and the cushion pad. There is.

The seat back 4 includes a seat back frame (not shown) as a skeleton, a cushion pad 4a provided on the seat back frame, and a skin material 4b for covering the seat back frame and the cushion pad. There is.

The plurality of auxiliary support portions 11 to 15 are attached to the seat body 2 as described above, and more specifically, are attached to each of the seat cushion 3 and the seat back 4.
That is, the plurality of auxiliary support portions 11 to 15 include an armrest 11 that supports the arm portion P3 of the occupant P, a headrest 12 that supports the head portion P4 of the occupant P, and a necklace that supports the neck portion P5 of the occupant P. 13 includes an ottoman 14 that supports the leg P6 of the occupant P, and a footrest 15 that supports the foot P7 of the occupant P.

In the present embodiment, the armrest 11, the headrest 12, and the necklace 13 are attached to the seat back 4, and the ottoman 14 and the footrest 15 are attached to the seat cushion 3.
Although the armrest 11 is attached to the seat back 4 in the present embodiment, the armrest 11 is not limited to this, and may be attached to the seat cushion 3 via a member such as a bracket.

Further, the plurality of auxiliary support portions 11 to 15 are also configured to include a frame, a cushion pad, and a skin material, similarly to the seat cushion 3 and the seat back 4.
In the example shown in FIG. 4, it is clearly shown that the armrest 11 is configured to include the skin material 11a.

A plurality of biosensors 20 to 23 for measuring the health condition of the occupant P are provided on the seat 1 as described above. Further, at least one of the plurality of biosensors 20 to 23 is provided in the auxiliary support portions 11 to 15.
In the present embodiment, as shown in FIGS. 1 and 2, 1 for each of the seat cushion 3, the seat back 4, the armrest 11, the headrest 12, the necklace 13, the ottoman 14, and the footrest 15. Up to two biosensors 20 to 23 are provided.

When the biosensors 20 to 23 are provided for the seat cushion 3, they are arranged corresponding to the central portions of the left and right ischia in the buttocks of the occupant P, as shown in FIG. 3, in order to improve the sitting comfort. In other words, the biosensors 20 to 23 are arranged in the central portion of the seat cushion 3 where the buttocks rest. In short, the position where the biosensors 20 to 23 are provided may be the buttocks.
Although one biosensor 20 to 23 in the present embodiment is provided in the center of the seat cushion 3, it is provided on both left and right sides of the seat cushion 3 corresponding to the left and right thighs P2 and P2. May be done.

When the biosensors 20 to 23 are provided for the seat back 4, they are arranged according to the position of the human heart. The thoracic aorta passes through the chest where the heart is located, and is suitable for measuring the blood flow state by the biological sensors 20 to 23.
The biosensors 20 to 23 in the present embodiment are arranged according to the position of the heart in the seat back 4, but the present invention is not limited to this and is suitable for measuring the blood flow state. Any position is acceptable.

When the biological sensors 20 to 23 are provided for the plurality of auxiliary support portions 11 to 15, each of the plurality of auxiliary support portions 11 to 15 has a suitable location for acquiring the biological information of the occupant P. Biosensors 20 to 23 are arranged with respect to the above.

In the case of the armrest 11, the upper end portion on the front side of the armrest 11 is the place where the biosensors 20 to 23 are installed. The front upper end portion of the armrest 11 is suitable because it is a portion where the arm portion P3 can easily come into contact with, for example, during driving or in a reclining state.

In the case of the headrest 12, the front side portion of the headrest 12 is the place where the biosensors 20 to 23 are installed. The front side portion of the headrest 12 is suitable because it is difficult for the head P4 to come into contact with the headrest 12 during operation, but it is easy for the head P4 to come into contact with the headrest 12 in the reclining state.

In the case of the necklace 13, the front side of the necklace 13 is the place where the biosensors 20 to 23 are installed. The front side portion of the necklace 13 is suitable because it is difficult for the neck P5 to come into contact with the necklace 13 during operation, but it is easy for the neck P5 to come into contact with the necklace P5 during the reclining state.

In the case of the ottoman 14, in order to correspond to both legs P6 and P6, as shown in FIG. 3, the left and right side portions 14a and 14b of the ottoman 14 are the installation locations of the biosensors 20 to 23. The left and right side portions 14a and 14b of the ottoman 14 are suitable because the legs P6 and P6 do not easily come into contact with each other during operation, but the legs P6 and P6 easily come into contact with each other during the reclining state. ..
In this embodiment, the thigh P2 and the leg P6 are described separately, and the leg P6 is particularly a portion of both legs of the occupant P below the thigh P2 (than the knee). It shall point to (downward).

In the case of the footrest 15, in order to correspond to both foot portions P7 and P7, as shown in FIG. 3, the left and right side portions 15a and 15b of the footrest 15 are the installation locations of the biosensors 20 to 23. The left and right side portions 15a and 15b of the footrest 15 are suitable because the feet P7 and P7 do not easily come into contact with each other during operation, but the feet P7 and P7 easily come into contact with each other during the reclining state. ..

The plurality of auxiliary support portions 11 to 15 are configured to be able to be stored, moved, or removed when not in use. When the seat 1 is in the reclining state as shown in FIG. 2, all of the biosensors 20 to 23 provided on the seat 1 are in the used state, but for example, during operation, it may not be in a preferable state for sensing. be. In particular, the ottoman 14 and the footrest 15 may hinder driving if they remain in the state shown in FIG. Therefore, the plurality of auxiliary support portions 11 to 15 can be stored, moved, or removed when not in use.
When removing the auxiliary support portions 11 to 15, it is not preferable that the connection line such as the harness connecting the biosensors 20 to 23 and the control unit / power supply is broken. Therefore, as the harness in the present embodiment, a harness having a connector capable of separating the harness from one side and the other side and reconnecting the harness is adopted. If a connection wire such as a harness provided with such a connector is adopted, even if the auxiliary support portions 11 to 15 are temporarily removed, the auxiliary support portions 11 to 15 can be reattached to the seat 1.
In this embodiment, the armrest 11 can be moved (rotated around the axis of rotation) when not in use, the headrest 12 and the necklace 13 can be removed, and the ottoman 14 and the footrest 15 are stored. Is possible. However, the present invention is not limited to this, and each of the auxiliary support portions 11 to 15 may be capable of being stored, moved, or removed when not in use.

Further, the timing of starting or stopping the measurement of the biological sensors 20 to 23 may be set according to the storage, movement, or removal of the auxiliary support portions 11 to 15.
If such a configuration is adopted, for example, when the seat 1 is deformed to the state shown in FIG. 2 during the automatic driving of the vehicle V, the measurement by the biosensors 20 to 23 is started, and the seat 1 is returned to the manual driving. When the state returns to the state shown in FIG. 1, the measurement by the biosensors 20 to 23 can be stopped.
That is, since the timing of starting or stopping the measurement of the biological sensors 20 to 23 can correspond to the operation of the auxiliary support portions 11 to 15, the measurement by the biological sensors 20 to 23 is started or stopped by the operation of the occupant P. It is not necessary, hassle-free, and is excellent in convenience.

The plurality of biological sensors 20 to 23 provided on the seat body 2 or the plurality of auxiliary support portions 11 to 15 include pulse wave sensors 20 to 22 for estimating the blood pressure of the occupant and such pulse wave sensors 20 to 22. A different type of biosensor 23 is included.
Examples of the pulse wave sensors 20 to 22 include a photoelectric pulse wave sensor 20 that measures the pulse wave of the occupant P using light, and a pulse wave of the occupant P by measuring a pressure wave on the body surface of the occupant P. Examples thereof include a piezoelectric pulse wave sensor 21 that measures the pulse wave of the occupant P, and an electromagnetic wave type pulse wave sensor 22 that measures the pulse wave of the occupant P by using an electromagnetic wave.
Then, in this embodiment, any of these plurality of types of pulse wave sensors 20 to 22 may be adopted, or these plurality of types of pulse wave sensors 20 to 22 may be used in combination as appropriate.

As shown in FIG. 4, the photoelectric pulse wave sensor 20 includes a light emitting unit 20a and a light receiving unit 20b, irradiates the body of the occupant P with light from the light emitting unit 20a, and receives the reflected light. It is received by the part 20b and the pulse wave is measured.

Although not shown, the piezoelectric pulse wave sensor 21 is provided with a piezoelectric element, a substrate on which the piezoelectric element is mounted, a case surrounding the piezoelectric element, and the like, and measurement is performed in a state of being close to (contacting) the measurement target. Be piezo.

As shown in FIG. 1, the electromagnetic wave type pulse wave sensor 22 is a non-contact type sensor that irradiates the body of the occupant P with an electromagnetic wave and detects biological information from the reflected wave from the body of the occupant P. Therefore, it is possible to measure the unexposed part of the body of the occupant P.
Here, the electromagnetic wave means an electromagnetic wave in a broad sense including radio waves and microwaves of about 100 MHz, infrared light, visible light, ultraviolet light, X-rays, etc., and is suitable as long as it does not adversely affect the human body. Electromagnetic waves are used. Such electromagnetic waves are characterized in that they do not easily pass through various metals such as iron, copper, and aluminum.

The data related to the blood flow state measured by the pulse wave sensors 20 to 22 is a blood pressure estimation configured by the above-mentioned operation control unit V1 or other control unit (may be another external device such as a computer). It is calculated appropriately by the unit. Then, the blood pressure (arterial pressure) of the occupant P can be obtained by calculating by the blood pressure estimation unit.
It should be noted that the blood pressure estimation unit can calculate and derive the blood pressure of the occupant P in cooperation with a calculation program stored in a storage unit (not shown).

More specifically, the distance between the two points where the biosensors 20 to 23 are installed (pointing to the installation locations corresponding to the two parts of the body of the occupant P) and the biosensors 20 to 23 are installed. The blood pressure can be estimated by using a known blood pressure estimation method based on the pulse wave propagation time, which estimates the blood pressure based on the time lag of the pulse wave sensing at two points. The above-mentioned arithmetic program is created based on the blood pressure estimation method, and is executed by the above-mentioned operation control unit V1 or other control unit (see FIG. 6).
In other words, when the plurality of biosensors 20 to 23 are arranged so as to be spaced apart from each other at at least two places in the seat 1 as shown in FIGS. 1 and 2, at least two of the bodies of the occupant P are arranged. It is possible to detect pulse wave data from a location. As a result, the accuracy of estimating the blood pressure from the detected pulse wave data and calculating the health condition of the occupant P can be improved as compared with the case of using only one biological sensor 20 (21 to 23). ..
As shown in FIG. 6, the biosensors 20 to 23 are connected to the above-mentioned operation control unit V1 or other control unit via a communication / connection line 25 such as a harness, and the communication / connection line 25 is connected. Is wired so as to pass through the inside of the seat body 2 and the plurality of auxiliary support portions 11 to 15 (armrest 11 in FIG. 6).

Examples of the biological sensor 23 different from the pulse wave sensors 20 to 22 include a blood flow sensor, a heart rate sensor, a brain wave sensor, an electromyographic sensor, a non-invasive blood glucose level sensor, a drowsiness sensor, and the like. , Any of them may be adopted.
However, biosensors that cannot be incorporated into the seat body 2 or a plurality of auxiliary support portions 11 to 15 are excluded.

The plurality of biosensors 20 to 23 as described above are required to be provided at positions in the seat 1 where the health condition of the occupant P can be measured as accurately as possible. Therefore, the plurality of biosensors 20 to 23 are provided in the seat 1 at a position close to the exposed portion of the body of the occupant P or at a position where the measurement is not obstructed by a predetermined obstructing factor.

As described above, the photoelectric pulse wave sensor 20 receives the reflected light of the light radiated to the body of the occupant P by the light receiving unit 20b. It is suitable for measuring easily exposed parts such as the neck P5. Therefore, the photoelectric pulse wave sensor 20 is provided on the sheet 1 so as to be exposed from the skin materials 3b, 4b, 11a constituting the surface of the sheet body 2 or the auxiliary support portions 11 to 15.

The piezoelectric pulse wave sensor 21 detects a pressure wave on the body surface of the occupant P by a piezoelectric element, and is exposed such as an arm P3, a head P4, a neck P5, etc. in the body of the occupant P. It is suitable for measuring easy-to-use parts. Therefore, when the piezoelectric pulse wave sensor 21 is provided on the seat 1, it is installed in a state of being exposed from the skin material in the seat main body 2 or the plurality of auxiliary support portions 11 to 15.

As described above, the electromagnetic wave type pulse wave sensor 22 is characterized in that it does not easily pass through various metals such as iron, copper, and aluminum. Although not shown, the sheet 1 has a built-in heater wire for heating the sheet 1 as a member that obstructs the passage of electromagnetic waves. Therefore, the electromagnetic wave type pulse wave sensor 22 is arranged at a position avoiding a member that obstructs the passage of the electromagnetic wave.

To give a more specific example, when at least one biosensor 20 (21-23) out of a plurality of biosensors 20-23 is provided on the armrest 11, the arm rest P3 of the occupant P may be contacted. It is desirable that the biosensor is provided at a position close to the arm P3.
Therefore, in the present embodiment, the upper end portion on the front side of the armrest 11 is the installation location of the biosensors 20 to 23. In the example shown in FIG. 4, a storage portion 16 for accommodating the photoelectric pulse wave sensor 20 is provided at the front upper end portion of the armrest 11. More specifically, the opening 11b is formed in the skin material 11a at the upper end of the front side of the armrest 11, and the space on the inner side of the armrest 11 including the opening 11b is the storage portion 16. The photoelectric pulse wave sensor 20 is housed in the storage unit 16. The storage portion 16 (opening portion 11b) can be opened and closed by a single-opening type cover portion 17. The tip of the cover 17 is in a removable state by the hook-and-loop fasteners 18a and 18b provided on both the tip of the cover 17 and the skin material 11a of the armrest 11. It is assumed that the surface of the cover portion 17 is made of the same material as the skin material 11a.
By adopting the configuration as shown in FIG. 4, the photoelectric pulse wave sensor 20 can be normally hidden, and the photoelectric pulse wave sensor 20 can be easily exposed at the time of measurement. The piezoelectric pulse wave sensor 21 may be provided instead of the photoelectric pulse wave sensor 20.

Further, in the example shown in FIG. 5, punching holes 5 are formed in the skin material constituting the surface of the sheet body 2 or the auxiliary support portions 11 to 15. Then, the photoelectric pulse wave sensor 20 can irradiate the occupant P with light through the punching hole 5.
A ventilation path 6 is formed in the cushion pads 3a and 4a of the seat body 2 so that air sent from a blower (not shown) can pass therethrough. The skin materials 3b and 4b are provided so as to cover the cushion pads 3a and 4a in which the ventilation passage 6 is formed so that the air passing through the ventilation passage 6 can pass therethrough. The photoelectric pulse wave sensor 20 can measure the pulse wave of the occupant P by using the punching hole 5 for such ventilation.
That is, strictly speaking, most of the photoelectric pulse wave sensor 20 is shielded, and a part (light emitting portion 20a and light receiving portion 20b) is exposed from the punching hole 5, so that sensing is possible. It has become.

Further, in the examples of FIGS. 6 and 7, the biosensors 20 to 23 are provided on the armrest 11 in a completely exposed state. That is, in the examples of FIGS. 4 and 5, the biological sensors 20 to 23 are clearly shown to be easily exposed or exposed to a level that can be sensed, but the present invention is not limited to this. , The biosensors 20 to 23 may be provided in a state of being exposed on the surface of the sheet 1.

The power supply to the plurality of biosensors 20 to 23 as described above may be performed from the battery of the vehicle V via a communication / connection line such as a harness, or as shown in FIGS. 7 and 8. It may be performed by using the vibration power generation element 26 which can generate power by vibration.
Such a vibration power generation element 26 can be provided at an arbitrary position on the sheet 1. In the example shown in FIG. 7, the biosensor 20 (21 to 23) and the vibration power generation element 26 are connected via a communication / connection line 27 such as a harness, and are compactly integrated (unitized state). ) Is built in the armrest 11.
In the example shown in FIG. 7, the vibration power generation element 26 is built in the armrest 11 and is provided, but the present invention is not limited to this, and the vibration power generation element 26 may be provided in the seat body 2 or other auxiliary. It may be provided in the support portions 12 to 15. However, when the biosensors 20 to 23 and the vibration power generation element 26 are unitized, the biosensor 20 (21 to 23) is used by the occupant P so as not to interfere with the sensing by the biosensor 20 (21 to 23). It is arranged on the side close to the body, that is, on the surface side of the sheet 1.

Further, the vibration power generation element 26 may be provided at an arbitrary position on the vehicle V as shown in FIG. 8 instead of the seat 1. The seat 1 and the vehicle V may be configured to reduce vibration in order to make the ride comfortable, but for example, the engine part, the chassis part such as the suspension, etc. are relatively relatively. Vibration is likely to occur. Therefore, when the vibration power generation element 26 is provided in the vehicle V, it is preferable to provide the vibration power generation element 26 in such a portion of the vehicle V where vibration is relatively likely to occur. Even when the vibration power generation element 26 is provided in the vehicle V, the biosensor 20 (21 to 23) and the vibration power generation element 26 are connected via a communication / connection line 27 such as a harness.

When measuring the health condition of the occupant P by the biological sensors 20 to 23 arranged on the seat body 2 or the plurality of auxiliary support portions 11 to 15 as described above, the reclining state as shown in FIG. 2 is the reclining state of the whole body. It is optimal because it is a measurable location. On the other hand, even in the driving posture shown in FIG. 1, there is no problem because a wide range of the body can be measured depending on the type of the pulse wave sensor to be adopted. That is, the biological information can be acquired at a plurality of parts of the body of the occupant P.
For example, when the health condition of the occupant P who is the driver is measured in the driving posture as shown in FIG. 1 during driving and the deterioration of the health condition of the occupant P is detected, the operation control unit V1 manually adjusts the seat 1. The operation mode may be switched to the automatic operation mode to obtain the state as shown in FIG. 2, and more precise measurement may be performed in this state. In this case, if a biological sensor 23 of a type different from the pulse wave sensors 20 to 22 is used, other biological information different from the pulse wave data can be acquired, which is suitable for performing precise measurement.

According to the present embodiment, the seat 1 supporting the occupant P is provided with a plurality of biological sensors 20 to 23 for measuring the health condition of the occupant P, and the seat 1 holds the occupant P. A plurality of biological sensors 20 to 23 are provided with a seat body 2 and auxiliary support portions 11 to 15 for supporting any of the parts P3 to P7 excluding the torso P1 and the thigh P2 in the body of the occupant P. Since at least one of them is provided in the auxiliary support portions 11 to 15, the body part P3 (P4 to P7) supported by the auxiliary support portions 11 (12 to 15) provided with the biological sensors 20 to 23 is provided. ) And other body parts P1 to P7, biometric information can be acquired at multiple locations. As a result, it is possible to improve the accuracy in measuring the health condition of the occupant P.

Further, since the auxiliary support portions 11 to 15 include an armrest 11 that supports the arm portion P3 of the occupant P, the biosensors 20 to 23 can be provided on the armrest 11 so that the arm portion P3 may be provided. Biometric information can be acquired. Since the upper end of the front side of the armrest 11 is the place where the biosensors 20 to 23 are installed, the biosensors 20 to 23 can be provided at a position where the arm P3 can be easily touched, and the biometric information on the arm P3 is acquired. It will be easier to do.

Further, since the auxiliary support portions 11 to 15 include a headrest 12 that supports the head P4 of the occupant P, it is possible to provide the biosensors 20 to 23 for the headrest 12 and the head P4. Biological information can be acquired. Since the front side of the headrest 12 is the place where the biosensors 20 to 23 are installed, the biosensors 20 to 23 can be provided at a position where the head P4 can easily touch, and the biometric information on the head P4 can be acquired. It will be easier.

Further, since the auxiliary support portions 11 to 15 include the necklace 13 that supports the neck P5 of the occupant P, the biosensors 20 to 23 can be provided for the necklace 13 and the neck P5. You can get the biometric information in. Since the front side of the necklace 13 is the place where the biosensors 20 to 23 are installed, the biosensors 20 to 23 can be provided at a position where the neck P5 can be easily touched, and the biometric information in the neck P5 is acquired. It will be easier to do.

Further, since the auxiliary support portions 11 to 15 include the ottoman 14 that supports the leg portion P6 of the occupant P, it is possible to provide the biosensors 20 to 23 for the ottoman 14 and to provide the leg portion P6. Biometric information can be acquired. Since the left and right side portions 14a and 14b of the ottoman 14 are the installation locations of the biosensors 20 to 23, the biosensors 20 to 23 can be provided at a position where the leg P6 can be easily touched, and the living body in the leg P6 can be provided. It will be easier to get information.

Further, since the auxiliary support portions 11 to 15 include a footrest 15 that supports the foot portion P7 of the occupant P, the biosensors 20 to 23 can be provided for the footrest 15, and the foot portion P7 can be provided with the biosensors 20 to 23. Biometric information can be acquired. Since the left and right side portions 15a and 15b of the footrest 15 are the installation locations of the biosensors 20 to 23, the biosensors 20 to 23 can be provided at positions where the foot P7 can easily touch, and the living body in the foot P7 can be provided. It will be easier to get information.

Further, since the plurality of biosensors 20 to 23 include pulse wave sensors 20 to 22 for estimating the blood pressure of the occupant P, the plurality of biosensors 20 to 22, which are pulse wave sensors, are used by the occupant P. The pulse wave can be measured at a plurality of points, and the accuracy can be improved in estimating the blood pressure of the occupant P.

Further, since the pulse wave sensor is a photoelectric pulse wave sensor 20 that measures the pulse wave of the occupant using light, it is suitable for measuring the pulse wave in the body parts P1 to P7 that can be irradiated with light. be.

Further, since the photoelectric pulse wave sensor 20 is provided so as to be exposed from the skin materials 3b, 4b, 11a constituting the surface of the seat body 2 or the auxiliary support portions 11 to 15, light is emitted from the skin material 3b, Obstruction by 4b and 11a can be suppressed, and the accuracy of measurement by the photoelectric pulse wave sensor 20 can be improved.

Further, since the pulse wave sensor is a piezoelectric pulse wave sensor 21 that measures the pulse wave of the occupant P by measuring the pressure wave on the body surface of the occupant P, the pressure wave can be measured in the body parts P1 to P7. It is suitable for measuring pulse waves.

Further, since the pulse wave sensor is an electromagnetic wave type pulse wave sensor 22 that measures the pulse wave of the occupant P using electromagnetic waves, the pulse wave of the occupant P is measured even if the occupant P is not in contact with the body. be able to.

Further, since at least one of the plurality of biosensors 20 to 23 is a biosensor 23 of a type different from that of the pulse wave sensors 20 to 22, other biometric information can be acquired, and as a result, the health condition of the occupant P can be determined. It is possible to improve the accuracy in measurement.

Further, the seat 1 is installed in a vehicle V provided with an operation control unit V1 for switching between automatic driving and manual driving, and is configured to be able to be changed to a different form during automatic driving and manual driving. Therefore, even when the seat 1 is changed to a different form between the automatic operation and the manual operation, the measurement can be performed by the biosensors 20 to 23. Further, since it is easy to support the body by the auxiliary support portions 11 to 15 during the automatic operation, it is easy to obtain highly accurate measurement results by the plurality of biosensors 20 to 23.

V Vehicle V1 Operation control unit P Crew P1 Torso P2 Thigh P3 Arm P4 Head P5 Neck P6 Leg P7 Foot 1 Seat 2 Seat body 3 Seat cushion 3a Cushion pad 3b Skin material 4 Seat back 4a Cushion pad 4b Skin material 5 Punching hole 6 Ventilation path 11 Armrest 11a Skin material 11b Opening 16 Storage part 17 Cover part 18a Face fastener 18b Face fastener 12 Headrest 13 Necklace 14 Ottoman 15 Footrest 20 Photoelectric pulse wave sensor 20a Light emitting part 20b Light receiving part 21 Piezoelectric pulse wave sensor 22 Electromagnetic pulse wave sensor 23 Different types of biological sensors 24 Blood pressure estimation unit 25 Communication / connection line 26 Vibration power generation element 27 Communication / connection line

Claims (13)

The seat that supports the occupant is equipped with multiple biosensors to measure the health condition of the occupant.
The seat is provided with a seat body for holding the occupant and an auxiliary support portion for supporting any part of the occupant's body other than the torso and thighs, and can be deformed so as to be in a reclining state. Is configured in
The measurement by the plurality of biosensors is started when the seat is deformed to be in the reclining state and the auxiliary support portion is moved, and the seat is returned from the reclining state to the original state. It is set to stop when the auxiliary support moves.
At least one of the plurality of biosensors is provided in the auxiliary support portion, and the arrangement structure of the biosensors is characterized. The auxiliary support includes an armrest that supports the occupant's arm.
The arrangement structure of the biosensor according to claim 1, wherein the front upper end portion of the armrest serves as an installation location of the biosensor. The auxiliary support includes a headrest that supports the occupant's head.
The arrangement structure of the biosensor according to claim 1 or 2, wherein the front side portion of the headrest serves as an installation location of the biosensor. The auxiliary support includes a necklace that supports the occupant's neck.
The arrangement structure of the biosensor according to any one of claims 1 to 3, wherein the front side portion of the necklace serves as an installation location of the biosensor. The auxiliary support includes an ottoman that supports the legs of the occupant.
The arrangement structure of the biosensor according to any one of claims 1 to 4, wherein the left and right sides of the ottoman are installation locations of the biosensor. The auxiliary support includes a footrest that supports the occupant's foot.
The arrangement structure of the biosensor according to any one of claims 1 to 5, wherein the left and right sides of the footrest are installation locations of the biosensor. The arrangement structure of the biosensor according to any one of claims 1 to 6, wherein the plurality of biosensors include a pulse wave sensor for estimating the blood pressure of an occupant. The arrangement structure of the biological sensor according to claim 7, wherein the pulse wave sensor is a photoelectric pulse wave sensor that measures a pulse wave of an occupant by using light. The arrangement structure of the biological sensor according to claim 8, wherein the photoelectric pulse wave sensor is provided so as to be exposed from a skin material constituting the surface of the sheet body or the auxiliary support portion. The invention according to any one of claims 7 to 9, wherein the pulse wave sensor is a piezoelectric pulse wave sensor that measures a occupant's pulse wave by measuring a pressure wave on the occupant's body surface. Arrangement structure of biosensor. The arrangement structure of the biological sensor according to any one of claims 7 to 10, wherein the pulse wave sensor is an electromagnetic wave type pulse wave sensor that measures a occupant's pulse wave by using an electromagnetic wave. The seat is installed in a vehicle equipped with a driving control unit that switches between automatic driving and manual driving, and is configured so that it can be changed to a different form during automatic driving and manual driving.
The arrangement structure of the biosensor according to any one of claims 7 to 11, wherein at least one of the plurality of biosensors is a biosensor of a type different from that of the pulse wave sensor. The sheet is
A seat cushion that holds the occupant's buttocks and thighs,
The lower end portion has a seat back supported by the seat cushion, and has.
The seat cushion is
The seat cushion frame that becomes the skeleton and
The cushion pad provided on the seat cushion frame and
It is composed of the seat cushion frame and the skin material that covers the cushion pad.
The seat back is
The seat back frame that becomes the skeleton and
The cushion pad provided on the seat back frame and
It is composed of the seat back frame and the skin material that covers the cushion pad.
The structure for arranging the sensing member on the seat according to any one of claims 1 to 12, wherein the plurality of auxiliary support portions are attached to the seat cushion and the seat back, respectively. ..

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