JP2018008554A - Control device of air belt, control method of air belt, and air belt - Google Patents

Abstract

PROBLEM TO BE SOLVED: To provide a control device of an air belt, a control method of an air belt, and an air belt, which can enhance convenience of an occupant.SOLUTION: A control device 101 of an air belt 1 having a webbing 2 and an air bag 3 provided in a portion of the webbing 2 corresponding to a neck and a head of an occupant C comprises a control unit 110 which calculates a possibility of collision of a vehicle from a situation surrounding the vehicle and a state of the vehicle to determine whether or not the possibility of collision exceeds a predetermined value, controls an air pressure of the air bag 3 to be a first air pressure in which the air bag can support at least a part of a portion of the occupant C from the neck to the head if it is determined that the possibility of collision does not exceed the predetermined value, and controls the air pressure of the air bag 3 to be a second air pressure higher than the first air pressure if it is determined that the possibility of collision exceeds the predetermined value.SELECTED DRAWING: Figure 1

Description

  The present invention relates to an air belt control device, an air belt control method, and an air belt.

2. Description of the Related Art Conventionally, there is known a seat belt of a vehicle in which an air bag is formed on a belt portion (webbing) that hits the chest of the seat belt (for example, see Patent Document 1).
The seat belt of Patent Document 1 supplies gas to the air bag when the buckle is set, and discharges the gas from the air bag when the buckle is removed. Thereby, the seat belt of patent document 1 makes it possible to make a hit with a passenger | crew soft. A seat belt provided with the above air bag is generally called an air belt.

Japanese Utility Model Publication No. 62-43858

  However, since the air belt of Patent Document 1 only supplies and discharges gas to and from the air bag according to the attachment and detachment of the buckle, an air belt control device, an air belt control method, and an air belt that are even more convenient for passengers are desired. .

  In view of the above circumstances, an object of the present invention is to provide an inflatable belt control device, an inflatable belt control method, and an inflatable belt that can improve the convenience of the occupant.

  In order to solve the above problems, an air belt control device (for example, the air belt control device 101 of the embodiment) according to the invention described in claim 1 includes a webbing (for example, the air belt webbing 2 of the embodiment) and the webbing. An air belt control device having an air bag (for example, air bag 3 of the embodiment) provided in a portion corresponding to the head from the neck of an occupant (for example, occupant C of the embodiment), When the collision possibility of the vehicle is calculated from the state of the vehicle, it is determined whether or not the collision possibility exceeds a predetermined value, and when it is determined that the collision possibility does not exceed the predetermined value Controls the air pressure of the air bag so that the air bag becomes a first air pressure capable of supporting at least a part of the portion from the neck to the head of the occupant, and the possibility of collision is When it is determined that the value exceeds the value, control means (for example, the control unit 110 of the embodiment) is provided to control the air pressure of the air bag to be a second air pressure higher than the first air pressure. It is said.

  According to a second aspect of the present invention, there is provided the air belt control apparatus, wherein the control means determines that the collision possibility exceeds the predetermined value, and then the collision possibility exceeds the predetermined value. If the possibility of collision does not exceed the predetermined value, the air bag supports at least a part of the head from the occupant's neck to the air pressure of the air bag. Control is performed such that the third atmospheric pressure is lower than the possible second atmospheric pressure.

  According to a third aspect of the present invention, there is provided the air belt control device according to the present invention, wherein the vehicle is provided with a pretensioner (for example, the pretensioner 15 of the embodiment) that winds up the slack of the webbing. The pretensioner is driven when it is determined that the possibility of collision exceeds the predetermined value.

  In addition, an air belt control device (for example, the air belt control device 201 of the embodiment) according to the invention of claim 4 includes a webbing (for example, the air belt webbing 2 of the embodiment) and an occupant (for example, the embodiment of the embodiment). In the air belt control device having an air bag (for example, the air bag 3 of the embodiment) provided in a portion corresponding to the head from the neck of the occupant C), when a vehicle collision is not detected, When the air pressure of the air bag is controlled to be a first air pressure at which the air bag can support at least a part of the portion from the neck to the head of the occupant, and the collision of the vehicle is detected, Control means for controlling the air pressure of the air bag to be a second air pressure higher than the first air pressure is provided.

  According to a fifth aspect of the present invention, there is provided a control device for an air belt, wherein the vehicle is provided with a pretensioner (for example, the pretensioner 15 of the embodiment) for winding up the slack of the webbing. The pretensioner is driven when a collision of the vehicle is detected.

  According to a sixth aspect of the present invention, there is provided a method for controlling an inflatable belt corresponding to a webbing (for example, the webbing 2 of the inflatable belt according to the embodiment) and a neck to a head of an occupant (for example, the occupant C in the exemplary embodiment). A method for controlling an air belt having an air bag (for example, the air bag 3 of the embodiment) provided in a portion, wherein the collision possibility of the vehicle is calculated from a situation around the vehicle and the state of the vehicle, It is determined whether or not the possibility of collision exceeds a predetermined value, and when it is determined that the possibility of collision does not exceed the predetermined value, the air pressure of the air bag is reduced from the occupant's neck. Control is performed so that the first atmospheric pressure capable of supporting at least a part of the portion over the head is reached, and if it is determined that the collision possibility exceeds the predetermined value, the atmospheric pressure of the air bag is set to the first atmospheric pressure. 1 atmosphere Air belt control method, characterized by controlling so that the remote high second atmospheres.

  In addition, the air belt control method according to the invention of claim 7 determines again whether or not the collision possibility exceeds the predetermined value after determining that the collision possibility exceeds the predetermined value. If it is determined that the possibility of the collision does not exceed the predetermined value, the air pressure of the air bag is determined so that the air bag can support at least a part of the head from the neck of the occupant. Control is performed so that the third atmospheric pressure is lower than the atmospheric pressure.

  According to an eighth aspect of the present invention, there is provided a method for controlling an air belt according to the present invention, wherein the vehicle is provided with a pretensioner (for example, the pretensioner 15 of the embodiment) that winds up the slack of the webbing, and the possibility of collision. The pretensioner is driven when it is determined that the value exceeds the predetermined value.

  A method for controlling an inflatable belt according to a ninth aspect of the present invention corresponds to a webbing (for example, the webbing 2 of the inflatable belt in the embodiment) and a neck to a head of an occupant (for example, the occupant C in the embodiment) with the webbing. A method of controlling an air belt having an air bag (for example, the air bag 3 of the embodiment) provided in a portion, and when the collision of a vehicle is not detected, the air bag controls the air pressure of the air bag. Control is performed so that at least a part of the portion from the neck of the occupant to the head can be supported, and when a vehicle collision is detected, the pressure of the air bag is set to be higher than the first pressure. It is characterized by controlling to be a high second atmospheric pressure.

  According to a tenth aspect of the present invention, there is provided the air belt control method according to the present invention, wherein the vehicle is provided with a pretensioner (for example, the pretensioner 15 of the embodiment) that winds up the slack of the webbing. The pretensioner is driven when the above is detected.

  An air belt (for example, the air belt 1 of the embodiment) according to the invention of claim 11 includes a webbing (for example, the webbing 2 of the air belt of the embodiment) and an air bag (for example, the air bag of the embodiment) provided on the webbing. 3), wherein the air bag is folded in a closed state, is expanded when gas is supplied to the inside, and is contracted when gas is discharged from the inside. The formed bag body (for example, the bag body 31 of the embodiment), the folding portion for folding the bag body at a predetermined folding position (for example, the folding portion 33 of the embodiment), and the folding direction of the bag body An elastic member (e.g., an elastic portion of the embodiment) provided to be wound around the bag body so as to extend, expands according to the expansion of the bag body, and contracts according to the contraction of the bag body Is characterized in that it comprises a 35), the.

  Further, in the air belt according to the invention of claim 12, the bag body covers the portion corresponding to the bent portion of the elastic member (for example, the portion 35a corresponding to the bent portion of the embodiment). A member (for example, the friction member 36 of the embodiment) is provided, and the friction member is formed such that a friction coefficient of the friction member with respect to the bag body is higher than a friction coefficient of the elastic member with respect to the bag body. It is characterized by being.

  In addition, the air belt according to the invention of claim 13 is provided side by side in the folding direction so as to sandwich the bent portion, and a regulating member that regulates the expansion of the bag body (for example, the regulating member 34 of the embodiment). It is characterized by being provided.

  In the air belt control apparatus according to claim 1 of the present invention and the air belt control method according to claim 6 of the present invention, when the possibility of collision of the vehicle does not exceed a predetermined value, the air pressure of the air bag is set to the air bag. Is controlled so as to be a first atmospheric pressure capable of supporting at least a part of the portion from the neck to the head of the occupant. As a result, the occupant can obtain comfort because at least a part of the portion from the neck to the head is supported by the air bag at a normal time when the possibility of a vehicle collision is low. In the air belt control device of the present invention, when the possibility of collision of the vehicle exceeds a predetermined value, the air pressure of the air bag is controlled to be a second pressure higher than the first pressure. This allows the occupant to receive at least part of the neck-to-head pressure in an emergency where there is a high possibility of a vehicle collision, so at least part of the occupant's neck-to-head part is normal. Is supported at a second atmospheric pressure higher than the first atmospheric pressure, and it is possible to know that the possibility of a vehicle collision is high. Therefore, the air belt control device of the present invention can support at least a part of the portion from the neck to the head by the air belt while maintaining the comfort of the occupant. Therefore, according to the air belt control device and the air belt control method of the present invention, it is possible to improve the convenience of the passenger.

  In the air belt control device according to claim 2 of the present invention and the air belt control method according to claim 7 of the present invention, when the possibility of collision of the vehicle decreases after exceeding a predetermined value, By controlling the atmospheric pressure to the third atmospheric pressure at which the air bag can support at least a part of the head from the occupant's neck, it is possible to provide comfort to the occupant when a vehicle collision is avoided. Therefore, according to the air belt control device and the air belt control method of the present invention, it is possible to further enhance the convenience of the passenger.

  In the air belt control device according to claim 3 of the present invention and the air belt control method according to claim 8 of the present invention, when a vehicle collision is detected, the pretensioner is driven to The slack is wound and the air bag can be brought into close contact with the passenger.

  Further, in the air belt control device according to claim 4 of the present invention and the air belt control method according to claim 9 of the present invention, the air pressure of the air bag is set to the first air pressure when no vehicle collision is detected. I tried to control it. As a result, at the normal time when no vehicle collision is detected, the occupant can obtain comfort because at least part of the portion from the neck to the head is supported by the air bag. In the air belt control device of the present invention, when a vehicle collision is detected, the air pressure of the air bag is controlled to the second pressure. Thereby, at the time of emergency where the collision of the vehicle is detected, the occupant is supported by the air bag at least part of the portion from the neck to the head. According to the air belt control device and the air belt control method of the present invention, it is possible to support at least a part of the portion from the neck to the head by the air belt while maintaining the comfort of the occupant. Therefore, the convenience of the passenger can be improved.

  Further, in the air belt control device according to claim 5 of the present invention and the air belt control method according to claim 10 of the present invention, when a vehicle collision is detected, the pretensioner is driven, so that in an emergency. The slack of the webbing is taken up and the air bag can be brought into close contact with the occupant.

  Moreover, according to the air belt which concerns on Claim 11 of this invention, an air bag is extended according to expansion | swelling of a bag body, a folding part which bends a bag body in a folding position, and a bag body. And an elastic member that contracts in response to contraction. As a result, the air bag is automatically folded when the bag body is folded at the folding portion by using the contraction force of the elastic member at the time of contraction. Thereby, since the passenger | crew has the effort which folds an air bag, it can improve a passenger | crew's convenience.

  According to the air belt of claim 12 of the present invention, the friction member that covers the portion corresponding to the bent portion of the elastic member is provided on the bag body, so that the elastic member is bent by the friction member. Expansion and contraction of the corresponding part is inhibited. As a result, the air bag expands and contracts on the side facing the bent portion of the elastic member, so that it can be unfolded and converged on the side facing the folded portion when folded even if it expands and contracts from the folded state. become. Therefore, the air belt of the present invention can fold the air bag stably.

  In the air belt according to claim 13 of the present invention, the regulating member that regulates the expansion of the bag body is provided side by side in the folding direction so as to sandwich the folding portion. It is securely bent at the part. Therefore, the air belt of the present invention can fold the air bag more stably.

It is explanatory drawing of the air belt to which the control apparatus of the air belt which concerns on the 1st Embodiment of this invention is applied. It is a block diagram of the control apparatus of the air belt of 1st Embodiment. It is a flowchart which shows the control processing of the control apparatus of the air belt of 1st Embodiment. It is a block diagram of the control apparatus of the air belt which concerns on the 2nd Embodiment of this invention. It is a flowchart which shows the control processing of the control apparatus of the air belt of 2nd Embodiment. It is sectional drawing of the air bag of the air belt which concerns on the 3rd Embodiment of this invention. It is operation | movement explanatory drawing of the air bag of the air belt which concerns on 3rd Embodiment.

  Embodiments of the present invention will be described below with reference to the drawings.

(First embodiment)
FIG. 1 is an explanatory diagram of an air belt to which an air belt control device according to a first embodiment of the present invention is applied. The air belt 1 is provided in the passenger seat of the vehicle. The air belt 1 includes a webbing 2, an air bag 3, a buckle 4, and a retractor 5.

  The retractor 5 is disposed in a center pillar (not shown) provided on the side of the seat 11. The webbing 2 is wound around the retractor 5 in the initial state. The tip of the webbing 2 is drawn upward from the retractor 5 and is inserted into a through anchor 12 supported on the upper side of the center pillar. The front end of the webbing 2 is fixed to the vehicle body floor via an outer anchor 13 provided on the outer wall of the seat 11. A tongue plate 6 is provided between the through anchor 12 and the outer anchor 13 of the webbing 2 so that the webbing 2 is inserted therethrough. The buckle 4 is provided on the vehicle body floor near the inner wall of the seat 11. A tongue plate 6 is detachably fixed to the buckle 4.

  When the webbing 2 is wound around the retractor 5, the occupant C pulls out the tip of the webbing 2 by hand and fixes the tongue plate 6 to the buckle 4. Restrained.

  The air bag 3 is provided in a portion corresponding to the head from the neck of the occupant C in the webbing 2. The air bag 3 is detachably attached to the webbing 2. The air bag 3 is provided to be movable in the length direction of the webbing 2.

  The retractor 5 is provided with a pretensioner 15. When the pretensioner 15 is driven, the retractor 5 is rotated by a predetermined number of rotations in the winding direction of the webbing 2 to wind up the slack of the webbing 2.

FIG. 2 is a block diagram of the air belt control apparatus according to the first embodiment.
The control device 101 for the air belt 1 according to the first embodiment is provided in a vehicle. The control device 101 of the air belt 1 of the first embodiment includes a control unit 110 (control means), an ambient condition detection unit 120 connected to the input side of the control unit 110, a vehicle state detection unit 130, and an operation unit 140. And a pump 150 connected to the output side of the control unit 110.

  The surrounding situation detection unit 120 detects the surrounding situation of the vehicle (own vehicle) and outputs the surrounding situation detection signal 121. The ambient condition detection unit 120 includes a measurement unit that measures the distance between the vehicle and an object around the vehicle. Examples of the measuring means include a camera, a millimeter wave radar, an infrared laser radar, and an ultrasonic sonar. Examples of the object include a preceding vehicle, an oncoming vehicle, a succeeding vehicle, a bicycle, a motorcycle, a pedestrian, and an obstacle on the road.

  The vehicle state detection unit 130 detects the state of the vehicle and outputs a vehicle state detection signal 131. Examples of the vehicle state detection unit include a speed sensor that detects the traveling speed of the vehicle.

  The operation unit 140 includes a control switch for performing manual control by the occupant C. The occupant C can manually perform various operations (a supply operation, an exhaust operation, a stop operation, etc.) of the pump 150 by a control switch. Further, when various operations are performed on the control switch by the occupant C, the operation unit 140 outputs operation signals 145 corresponding to the various operations.

  The pump 150 is connected to the air bag 3 of the air belt 1 through a pipe. The pump 150 is configured to supply gas (intake) and discharge (exhaust) gas to the air bag 3.

The pretensioner 15 described above is connected to the output side of the control unit 110.
An inflator 160 is connected to the output side of the control unit 110. An airbag 170 is connected to the inflator 160. The airbag 170 is provided inside the dashboard.

  When the operation signal 145 for the air supply operation is output from the operation unit 140, the control unit 110 outputs the control signal 115 for the air supply operation to the pump 150. The pump supplies air based on this control signal 115. When an operation signal 145 for exhaust operation is output from the operation unit 140, the control unit 110 outputs a control signal 115 for exhaust operation to the pump 150. The pump 150 exhausts based on the control signal 115. When the operation signal 145 for the stop operation is output from the operation unit 140 while the pump 150 is supplying or exhausting air, the control unit 110 outputs the control signal 115 for stop based on the operation signal 145. The pump 150 stops supply or exhaust based on the control signal 115.

Based on the ambient condition detection signal 121 output from the ambient condition detection unit 120 and the vehicle condition detection signal 131 output from the vehicle condition detection unit 130, the control unit 110 operates the operation unit 140, the pump 150, and the pretensioner 15. The driving of the inflator 160 is controlled.
Further, as described later, when the control unit 110 determines that the vehicle collision possibility (%) calculated based on the surrounding state detection signal 121 and the vehicle state detection signal 131 exceeds a predetermined value, A manual control inhibition signal 141 is output. The operation unit 140 is prohibited from manual control by the occupant C by outputting a manual control prohibition signal 141.

FIG. 3 is a flowchart showing the control process of the control unit.
Hereinafter, the control processing of the control unit 110 will be described with reference to the flowchart of FIG. In addition, the code | symbol in the following description should refer FIG. 1 and FIG.
This control process is performed while the vehicle is running and stopped.

(Step SA1)
The control unit 110 determines whether or not the ambient condition detection signal 121 is output from the ambient condition detection unit 120. If the control unit 110 determines that the ambient condition detection signal 121 is output (the determination result of step SA1 is YES), the control unit 110 proceeds to step SA2.

(Step SA2)
Control unit 110 determines whether or not vehicle state detection signal 131 is output from vehicle state detection unit 130. If controller 110 determines that vehicle state detection signal 131 is output (YES at step SA2), control proceeds to step SA3. Note that the control unit 110 may first perform the process of step SA2 and then perform the process of step SA1.

(Step SA3)
The control unit 110 calculates the collision probability (%) of the vehicle based on the surrounding state detection signal 121 and the vehicle state detection signal 131, and proceeds to step SA4. The possibility of a vehicle collision is the possibility that the vehicle will collide with an object. The possibility of collision of the vehicle is calculated from, for example, the distance between the vehicle and the object obtained from the ambient condition detection signal 121, the traveling speed of the vehicle obtained from the vehicle state detection signal 131, and the like.

(Step SA4)
Control unit 110 determines whether or not the possibility of collision of the vehicle exceeds a predetermined value. The predetermined value is stored in the control unit 110 in advance by mapping or the like. If control unit 110 determines that the possibility of vehicle collision does not exceed a predetermined value (NO at step SA4), control unit 110 proceeds to step SA5. If control unit 110 determines that the possibility of vehicle collision exceeds a predetermined value (YES in step SA4), control unit 110 proceeds to step SA6.

(Step SA5)
When the controller 110 determines that the possibility of collision of the vehicle does not exceed a predetermined value, the controller 110 outputs a first atmospheric pressure control signal 111 to the pump 150.
The first atmospheric pressure control signal 111 is a control signal for controlling the atmospheric pressure of the air bladder 3 to an atmospheric pressure (first atmospheric pressure) that can support at least a part of the portion from the neck of the occupant C to the head. When the first atmospheric pressure control signal 111 is output from the control unit 110, the pump 150 supplies gas to the air bladder 3 so that the air pressure of the air bladder 3 becomes the first atmospheric pressure. After outputting the first atmospheric pressure control signal 111 to the pump 150, the controller 110 returns to the process of step SA1.

(Step SA6)
When it is determined that the possibility of a vehicle collision exceeds a predetermined value, the control unit 110 outputs a manual control prohibition signal 141 to the operation unit 140. As a result, the passenger C is prohibited from manually performing various operations of the pump 150 (such as an air supply operation, an exhaust operation, and a stop operation).

(Step SA7)
Next, the control unit 110 outputs the second atmospheric pressure control signal 112 to the pump 150 and proceeds to step SA8.
The second atmospheric pressure control signal 112 is a control signal for controlling the atmospheric pressure of the air bag to an atmospheric pressure (second atmospheric pressure) higher than the first atmospheric pressure. When the second atmospheric pressure control signal 112 is output from the control unit 110, the pump 150 supplies gas to the air bladder 3 so that the air pressure of the air bladder 3 becomes the second atmospheric pressure.

(Step SA8)
Subsequently, the control unit 110 outputs the pretensioner drive signal 116 to the pretensioner 15, and proceeds to step SA9. When the pretensioner drive signal 116 is output from the control unit 110, the pretensioner 15 rotates the retractor 5 in the winding direction of the webbing 2 by a predetermined number of rotations to wind up the slack of the webbing 2.

(Step SA9 to Step SA12)
In step SA9 to step SA11, control unit 110 performs the same processing as step SA1 to step SA3. Description is omitted.
Next, when the controller 110 determines in step SA12 that the possibility of collision of the vehicle does not exceed the predetermined value (the determination result in step SA12 is NO), the control unit 110 proceeds to step SA13. If control unit 110 determines that the possibility of a vehicle collision exceeds a predetermined value (YES at step SA12), control unit 110 proceeds to step SA15.

(Step SA13)
When the controller 110 determines that the possibility of a vehicle collision does not exceed a predetermined value, the controller 110 cancels the output of the manual control prohibition signal 141. Thus, the occupant C can perform various operations of the pump 150 (a supply operation, an exhaust operation, a stop operation, etc.). After canceling the output of the manual control prohibition signal 141, the control unit 110 proceeds to step SA14.

(Step SA14)
Next, the control unit 110 outputs the third atmospheric pressure control signal 113 to the pump 150 after canceling the output of the manual control prohibition signal 141.
The third air pressure control signal 113 controls the air pressure of the air bag 3 to a pressure (third air pressure) lower than the second air pressure at which the air bag 3 can support at least a part of the head from the neck of the occupant C. Control signal. When the third atmospheric pressure control signal 113 is output from the control unit 110, the pump 150 discharges the gas from the air bladder 3 so that the air pressure of the air bladder 3 becomes the third atmospheric pressure. After outputting the 3rd atmospheric pressure control signal 113 to pump 150, control part 110 returns to Step SA1.

(Step SA15)
When determining that the possibility of collision of the vehicle exceeds a predetermined value, the control unit 110 determines whether or not the vehicle is colliding with an object based on the surrounding state detection signal 121 and the vehicle state detection signal 131. Judging. If control unit 110 determines that the vehicle is colliding with an object (the determination result in step SA15 is YES), control unit 110 proceeds to step SA16. When control unit 110 determines that the vehicle has not collided with the object (the determination result of step SA15 is NO), control unit 110 returns to step SA9.

(Step SA16)
When it is determined that the vehicle is colliding with an object, the control unit 110 outputs an inflator drive signal 117 to the inflator 160. When the inflator drive signal 117 is output from the control unit 110, the inflator 160 generates gas and inflates the airbag 170. Thus, the control process of the control unit 110 ends.

The effect of the control apparatus 101 of the air belt 1 of 1st Embodiment is demonstrated.
In the control device 101 of the air belt 1 and the control method of the air belt 1 according to the first embodiment, when the possibility of collision of the vehicle does not exceed a predetermined value, the air bag 3 reduces the air pressure of the air bag 3 to the neck of the occupant C. At least a part of the portion from the head to the head is controlled to a first pressure that can be supported. As a result, the occupant C can obtain comfort because at least a part of the portion from the neck to the head is supported by the air bag 3 at normal times when the possibility of collision of the vehicle is low.
Further, in the control device 101 of the air belt 1 and the control method of the air belt 1 according to the first embodiment, when the possibility of collision of the vehicle exceeds a predetermined value, the air pressure of the air bag 3 is higher than the first air pressure. The second atmospheric pressure was controlled. As a result, the occupant C has at least a part of the portion from the neck to the head in an emergency where the possibility of a vehicle collision is high, so that at least a part of the portion from the neck to the head of the occupant C is at least. While supporting a part at the second atmospheric pressure higher than the first atmospheric pressure, it becomes possible to know that the possibility of collision of the vehicle is high. Therefore, the control device 101 of the air belt 1 according to the first embodiment can support at least a part of the portion from the neck to the head by the air belt 1 while maintaining the comfort of the occupant C. Therefore, according to the control device 101 of the air belt 1 and the control method of the air belt 1 of the first embodiment, the convenience of the passenger C can be improved.

  Further, in the control device 101 of the air belt 1 and the control method of the air belt 1 according to the first embodiment, when the possibility of collision of the vehicle decreases after exceeding a predetermined value, the air bag 3 reduces the air pressure of the air bag 3. By controlling the third pressure so that at least a part of the head can be supported from the neck of the occupant C, it is possible to give comfort to the occupant C when a vehicle collision is avoided. Therefore, according to the control device 101 of the air belt 1 and the control method of the air belt 1 of the first embodiment, the convenience of the passenger C can be further improved.

  Further, in the control device 101 of the air belt 1 and the control method of the air belt 1 according to the first embodiment, the slack of the webbing 2 is wound by driving the pretensioner 15 when a vehicle collision is detected. Thus, the air bag 3 can be brought into close contact with the occupant C.

  In the control device 101 and the control method for the air belt 1 according to the first embodiment, if the vehicle collides when the air pressure of the air bag 3 is controlled to the second air pressure, the air bag 3 is It can function as an auxiliary device for the side airbag.

(Second Embodiment)
FIG. 4 is a block diagram of an air belt control apparatus according to the second embodiment of the present invention.
In the control device 201 of the air belt 1 of the second embodiment, the same reference numerals are given to the same parts as those of the control device 101 of the air belt 1 of the first embodiment. The control device 201 for the air belt 1 according to the second embodiment will be described with a focus on differences from the control device 101 for the air belt 1 according to the first embodiment. In addition, the code | symbol in the following description should refer FIG. 1 and FIG.

The control device 201 for the air belt 1 according to the second embodiment is provided in a vehicle. The control device 201 of the air belt 1 according to the second embodiment is connected to the control unit 210, the collision detection unit 220 connected to the input side of the control unit 210, the operation unit 140, and the output side of the control unit 210. A pump 150. The pump 150 is connected to the air bag 3 of the air belt 1. The pretensioner 15 and the inflator 160 are connected to the output side of the control unit 210. The inflator 160 is connected to the air bag 3 and the air bag 170 of the air belt 1.
The collision detection unit 220 detects a vehicle collision and outputs a collision detection signal 221. Examples of the collision detection unit 220 include an acceleration sensor.

FIG. 5 is a flowchart showing the control process of the control unit.
Hereinafter, the control process of the control unit 210 will be described with reference to the flowchart of FIG. This control process is performed while the vehicle is running and stopped.

(Step SB1)
The controller 210 determines whether or not the collision detection signal 221 is output from the collision detector 220. When the control unit 210 determines that the collision detection signal 221 is not output (the determination result of step SB1 is NO), the control unit 210 proceeds to step SB2. If control unit 210 determines that collision detection signal 221 has been output (the determination result in step SB1 is YES), control unit 210 proceeds to step SB3.

(Step SB2)
When the controller 210 determines that the collision detection signal 221 is not output from the collision detector 220, the controller 210 outputs the first atmospheric pressure control signal 111 to the pump 150. When the first atmospheric pressure control signal 111 is output from the controller 210, the pump 150 supplies gas to the air bladder 3 so that the air pressure of the air bladder 3 becomes the first atmospheric pressure. After outputting the first atmospheric pressure control signal 111 to the pump 150, the controller 210 returns to step SB1.

(Step SB3)
When the controller 210 determines that the collision detection signal 221 is output from the collision detector 220, the controller 210 outputs the pretensioner drive signal 116 to the pretensioner 15 and proceeds to step SB5. When the pretensioner drive signal 116 is output from the controller 210, the pretensioner 15 rotates the retractor 5 in the winding direction of the webbing 2 by a predetermined number of rotations to wind up the slack of the webbing 2.

(Step SB4)
Subsequently, the controller 210 outputs an inflator drive signal 117 to the inflator 160. When the inflator drive signal 117 is output from the control unit 210, the inflator 160 generates gas and inflates the air bag 3 and the air bag 170 of the air belt 1. Thereby, the air pressure of the air bag 3 becomes a second air pressure higher than the first air pressure, and restrains at least a part of the portion from the neck of the occupant C to the head. Thus, the control process of the control unit 210 ends. Thereafter, the air pressure of the air bag 3 becomes a third atmospheric pressure lower than the second atmospheric pressure by releasing gas from a vent hole (not shown).

The effect of the control apparatus 201 of the air belt 1 of 2nd Embodiment is demonstrated.
In the control device 201 of the air belt 1 and the control method of the air belt 1 according to the second embodiment, the air pressure of the air bag 3 is controlled to the first air pressure when a vehicle collision is not detected. As a result, the occupant can obtain comfort because at least a part of the portion from the neck to the head is supported by the air bag 3 in a normal time when no vehicle collision is detected. Moreover, in the control apparatus 201 of the air belt 1 according to the second embodiment, when a vehicle collision is detected, the air pressure of the air bag 3 is controlled to the second air pressure. As a result, the occupant C is supported by the air bag 3 at least in a part from the neck to the head in an emergency in which a vehicle collision is detected. According to the control device 201 and the control method for the air belt 1 according to the second embodiment, the air belt 1 supports at least a part of the portion from the neck to the head while maintaining the comfort of the occupant C. It becomes possible. Therefore, the convenience of the passenger C can be improved.

  Further, in the control device 201 of the air belt 1 and the control method of the air belt 1 according to the second embodiment, the webbing 2 is loosened in an emergency by driving the pretensioner 15 when a vehicle collision is detected. The air bag 3 can be tightly attached to the occupant C by being wound up.

  In the control device 201 of the air belt 1 and the control method of the air belt 1 according to the second embodiment, the air bag 3 can function as a side air bag when a vehicle collision is detected.

(Third embodiment)
6 is a cross-sectional view of an air bag of an air belt according to the third embodiment of the present invention, and is a cross-sectional view taken along line AA of FIG. In the air belt 1 of 3rd Embodiment, the same code | symbol is attached | subjected to the part similar to 1st Embodiment.

  As shown in FIG. 6, the air bladder 3 is provided on the webbing 2. The air bag 3 is folded when contracted (when not in use). The air bag 3 includes a bag body 31, a storage bag 32, a bent portion 33, a regulating member 34, an elastic member 35, and a friction member 36.

  The bag body 31 is formed in a bag shape whose periphery is closed by a synthetic resin such as a rubber material. A pump 150 (see FIG. 2) is connected to the bag body 31 via a pipe (not shown). The bag body 31 expands when gas is supplied into the bag body 31 by the pump 150. Further, the bag body 31 contracts when gas is discharged from the inside of the bag body 31 by the pump 150.

  The bent portion 33 is provided at the folding position 31a. The folding position 31a of the bag body 31 is a folded portion when the bag body 31 is folded up and down (for example, an intermediate portion in the vertical direction of the bag body 31). The bent portion 33 is, for example, a stretchable belt-like or string-like rubber material, and is wound around the folding position 31 a via the storage bag 32. Thereby, the bending part 33 bends the bag body 31 in the folding position 31a.

  The regulating member 34 is formed in a plate shape. The regulating member 34 is provided in the vicinity of the bent portion 33 in the bag body 31. Specifically, the regulating member 34 is arranged in the vertical direction across the bent portion 33, and the opposing surface 31 e of the upper portion 31 b formed on the upper side of the bent portion 33 in the bag body 31, It is provided on the facing surface 31f of the lower portion 31c formed on the lower side of the bent portion 33, respectively. As a result, the regulating member 34 regulates the expansion of the bag body 31.

  The elastic member 35 is formed in a band shape or a string shape that can be expanded and contracted by, for example, a rubber material. The elastic member 35 is wound around the bag body 31 so as to be along the folding direction (vertical direction) of the bag body 31. The elastic member 35 is formed so as to expand according to the expansion of the bag body 31 and to contract according to the contraction of the bag body 31.

  The friction member 36 is formed in a band shape by, for example, a cloth material. The friction member 36 is provided on the bag body 31 so as to cover a portion 35 a corresponding to the bent portion 33 of the elastic member 35. Specifically, the friction member 36 covers a portion 35 a corresponding to the bent portion 33 excluding a portion 35 b facing the bent portion 33 in the elastic member 35. The friction member 36 is formed of a cloth material having a rougher surface than the elastic member 35. Accordingly, the friction coefficient of the friction member 36 with respect to the bag body 31 is formed to be higher than the friction coefficient of the elastic member 35 with respect to the bag body 31.

  FIG. 7 is an operation explanatory view of the air bag of the air belt. Hereinafter, the operation of the air bladder 3 will be described with reference to FIG.

When gas is supplied into the bag body 31 from the folded state shown in FIG. 7A, the bag body 31 expands as shown in FIG. 7B. The elastic member 35 extends in the winding direction. When the supply of gas to the bag body 31 is completed, the bent portion 33 expands and the bag body 31 expands to the limit as shown in FIG.
The expanded bag body 31 contracts as the internal gas is discharged. As a result, the bent portion 33 contracts as shown in FIG. As the bent portion 33 contracts, the bag body 31 is bent with the bent portion 33 as a base point. In the elastic member 35, the portion 35 a corresponding to the bent portion 33 is inhibited from contracting by the friction member 36, so that the facing portion 35 b facing the bent portion 33 contracts to become a bellows shape. Thereafter, the elastic member 35 moves in the friction member 36 and becomes in a state without the slack shown in FIG. Thereby, the bag body 31 returns to the original folded state shown in FIG.

Next, the effect of the air belt 1 of 3rd Embodiment is demonstrated.
According to the air belt 1 according to the third embodiment, the air bag 3 extends in accordance with the expansion of the bag body 31, the folding portion 33 that bends the bag body 31 at the folding position, and the expansion of the bag body 31. And an elastic member 35 that contracts in accordance with the contraction of the bag body 31. As a result, the air bag 3 is automatically folded when the bag body 31 is folded at the folding portion 33 by using the contraction force of the elastic member 35 at the time of contraction. Thereby, since the passenger | crew C does not have the effort to fold the air bag 3, the convenience of the passenger | crew C can be improved.

  Further, according to the air belt 1 according to the third embodiment, the elastic member 35 is provided with the friction member 36 that covers the portion 35 a corresponding to the bent portion 33 of the elastic member 35 on the bag body 31. The friction member 36 inhibits the expansion and contraction of the portion 35 a corresponding to the bent portion 33. As a result, the air bag 3 expands and converges on the side facing the folded portion 33 when folded even if the side facing the folded portion 33 of the elastic member 35 expands and contracts to expand and contract from the folded state. It becomes possible to do. Therefore, according to the air belt 1 which concerns on 3rd Embodiment, the air bag 3 can be folded stably.

  Moreover, according to the air belt 1 which concerns on 3rd Embodiment, since the regulation member 34 which regulates the expansion | swelling of the bag body 31 is provided along with the folding direction so that the bending part 33 may be pinched | interposed, the air bag 3 is provided. The bent portion 33 is securely bent. Therefore, according to the air belt 1 which concerns on 3rd Embodiment, the air bag 3 can be folded more stably.

  The present invention is not limited to the above-described embodiment, and includes various modifications made to the above-described embodiment without departing from the spirit of the present invention.

  In the control device 101 for the air belt 1 of the first embodiment, the air belt 1 is provided in the passenger seat, but it may be installed in the driver seat or the rear seat.

  In the control method of the air belt 1 according to the first embodiment, when it is determined that the possibility of collision of the vehicle does not exceed a predetermined value, the output of the manual control prohibition signal 141 is canceled (step SA13), and then the pump The third atmospheric pressure control signal 113 is output to 150 (step SA14). On the other hand, when it is determined that the possibility of collision of the vehicle does not exceed the predetermined value, the output of the manual control inhibition signal 141 may be canceled after the third atmospheric pressure control signal 113 is output.

  In the control device 101 of the air belt 1 and the control method of the air belt 1 according to the first embodiment, the air pressure of the air bag 3 is controlled to the third pressure when the possibility of collision of the vehicle decreases after exceeding a predetermined value. However, it may be controlled to the first atmospheric pressure. In other words, the third atmospheric pressure may be the same value as the first atmospheric pressure. The same applies to the control device 201 of the air belt 1 and the control method of the air belt 1 of the second embodiment.

  In the control device 101 of the air belt 1 and the control method of the air belt 1 of the first embodiment, after the air pressure of the air bag 3 is controlled to the third air pressure, when the possibility of collision of the vehicle does not exceed a predetermined value, Although the air pressure of the air bag 3 is controlled to be the first pressure, the controlled state may be maintained to be the third pressure. In other words, the first atmospheric pressure may be the same value as the third atmospheric pressure. The same applies to the control device 201 of the air belt 1 and the control method of the air belt 1 of the second embodiment.

In the air belt 1 of the third embodiment, a band-like or string-like member that can be expanded and contracted is used for the bent portion 33, but a bent portion may be formed at the folding position of the bag body 31 with a seam or the like. .
In the air belt 1 of the third embodiment, the regulating member 34 is provided in the bag body 31, but may be provided in the storage bag 32 or in both the bag body 31 and the storage bag 32.

  In addition, it is possible to appropriately replace the components in the above-described embodiments with known components without departing from the spirit of the present invention.

DESCRIPTION OF SYMBOLS 1 Air belt 2 Webbing 3 Air bag 15 Pretensioner 31 Bag body 31a Folding position 33 Bending part 34 Restriction member 35 Elastic member 35a The part 36 corresponding to the bending part of an elastic member Friction member 101, 201 Air belt control apparatus 110, 210 Control unit (control means)
C Crew

Claims (13)

A control device for an air belt having a webbing and an air bag provided in a portion corresponding to the head from the neck of an occupant by the webbing,
The possibility of collision of the vehicle is calculated from the situation around the vehicle and the state of the vehicle, it is determined whether or not the possibility of collision exceeds a predetermined value, and the possibility of collision exceeds the predetermined value. If not, the air pressure of the air bag is controlled so that the air bag becomes a first air pressure that can support at least part of the portion from the neck to the head of the occupant. And a control means for controlling the air pressure of the air bag to be a second air pressure higher than the first air pressure when it is determined that the air pressure exceeds the predetermined value. . In the air belt control device according to claim 1,
After determining that the possibility of collision exceeds the predetermined value, the control means determines again whether or not the possibility of collision exceeds the predetermined value, and the possibility of collision exceeds the predetermined value. When it is determined that the air pressure does not exceed, the air pressure of the air bag is controlled to be a third air pressure lower than the second air pressure at which the air bag can support at least a part of the head from the neck of the occupant. A control device for an air belt. In the air belt control device according to claim 1 or 2,
The vehicle is provided with a pretensioner for winding up the slack of the webbing,
The air belt control apparatus, wherein the control means drives the pretensioner when it is determined that the collision possibility exceeds the predetermined value. A control device for an air belt having a webbing and an air bag provided in a portion corresponding to the head from the neck of an occupant by the webbing,
If no vehicle collision is detected, the air pressure of the air bag is controlled so that the air bag becomes a first air pressure capable of supporting at least a part of the portion from the neck to the head of the occupant, An air belt control device comprising: control means for controlling the air pressure of the air bag to be a second air pressure higher than the first air pressure when a collision of the vehicle is detected. In the control apparatus of the air belt of Claim 4,
The vehicle is provided with a pretensioner for winding up the slack of the webbing,
The air belt control apparatus, wherein the control means drives the pretensioner when a collision of the vehicle is detected. A method for controlling an air belt, comprising: a webbing; and an air bag provided in a portion corresponding to a head from a neck of an occupant by the webbing,
The possibility of collision of the vehicle is calculated from the situation around the vehicle and the state of the vehicle, it is determined whether or not the possibility of collision exceeds a predetermined value, and the possibility of collision exceeds the predetermined value. If not, the air pressure of the air bag is controlled so that the air bag becomes a first air pressure that can support at least part of the portion from the neck to the head of the occupant. Is determined to exceed the predetermined value, the air pressure of the air bag is controlled to be a second air pressure higher than the first air pressure. The method of controlling an air belt according to claim 6,
After determining that the collision possibility exceeds the predetermined value, it is determined again whether the collision possibility exceeds the predetermined value, and it is determined that the collision possibility does not exceed the predetermined value. In this case, the air pressure of the air bag is controlled to be a third air pressure lower than the second air pressure capable of supporting at least a part of the head of the air bag from the neck of the occupant. To control the air belt. In the control method of the air belt according to claim 6 or 7,
The vehicle is provided with a pretensioner for winding up the slack of the webbing,
A method for controlling an air belt, comprising: driving the pretensioner when it is determined that the collision possibility exceeds the predetermined value. A method for controlling an air belt, comprising: a webbing; and an air bag provided in a portion corresponding to a head from a neck of an occupant by the webbing,
If no vehicle collision is detected, the air pressure of the air bag is controlled so that the air bag becomes a first air pressure capable of supporting at least a part of the portion from the neck to the head of the occupant, An airbelt control method, comprising: controlling a pressure of the air bag to be a second pressure higher than the first pressure when a vehicle collision is detected. The method of controlling an air belt according to claim 9,
The vehicle is provided with a pretensioner for winding up the slack of the webbing,
A method of controlling an air belt, comprising: driving the pretensioner when a collision of the vehicle is detected. An air belt comprising a webbing and an air bag provided on the webbing,
The air bag is
A bag body that is folded in a state where the periphery is closed, is expanded by being supplied with gas, and is contracted by being discharged from the inside;
A folding part for folding the bag body at a predetermined folding position;
An elastic member provided to be wound around the bag body along the folding direction of the bag body, extended according to the expansion of the bag body, and contracted according to the contraction of the bag body; ,
An air belt comprising: The air belt according to claim 11,
The bag body is provided with a friction member that covers a portion corresponding to the bent portion of the elastic member,
The air belt, wherein the friction member is formed so that a friction coefficient of the friction member with respect to the bag body is higher than a friction coefficient of the elastic member with respect to the bag body. The air belt according to claim 11 or 12,
An air belt, characterized in that a regulating member is provided side by side in the folding direction so as to sandwich the bent portion, and a regulating member for regulating expansion of the bag body is provided.

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