JP2005177227A - Headrest of car seat - Google Patents

Abstract

<P>PROBLEM TO BE SOLVED: To provide a headrest which solves the problem that a full effect of preventing whiplash injury by actuation after sensing a rear-end collision cannot be expected as a subtle back and forth adjustment is difficult. <P>SOLUTION: A headrest 3 is formed in an upper part of a backrest seat 2 of a car seat 1 so that it can move back and forth freely against a pillar 8 attached to a support member 9 of the backrest seat 2 with a parallel link mechanism L, the parallel link mechanism L is so structured that it can easily adjust a lengthwise position by the operation of a position adjustment link A with a motor 16, a forecasting system S which anticipates rear impact by a radar or the like provided at a desired position is installed in the car body provided with the car seat 1, an impact forecasting signal from the forecasting system S turns on electricity to the motor 16, an impact forecasting actuation link B is operated prior to the position adjustment link A and the headrest 3 is moved to the forefront position. <P>COPYRIGHT: (C)2005,JPO&NCIPI

Description

  The present invention relates to a headrest for a vehicle seat, and particularly provides a headrest for preventing whiplash.

2. Description of the Related Art Conventionally, a headrest provided on an upper portion of a backrest seat has a pillar of the headrest attached to a support member of the backrest seat.
A parallel link mechanism is provided between the headrest frame of the headrest and the pillar, and the headrest is configured to be movable back and forth with respect to the back seat by the parallel link mechanism. The parallel link mechanism is provided with a latch and a ratchet, and it is possible to move the headrest to the front side one step at a time, but it is possible to move the headrest to the front side. I try to support it.
When the headrest is advanced to the forefront position by the front / rear position adjustment operation, the ratchet is released and temporarily returned to the rearmost position.
On the other hand, a headrest of a vehicle seat in which a sensor unit for detecting a rear collision is provided in the headrest and the headrest is forcibly moved to the foremost position when the sensor unit detects the rear collision is known (Patent Document 1). reference).
JP 2000-342379 A

In the known example, there is a problem that it is difficult to make a fine back-and-forth adjustment because of the “step” adjustment by the latch and the ratchet.
Further, in the movement of the headrest after detecting the rear collision of the sensor unit, the head has already started to move backward, and a sufficient effect for preventing whiplash cannot be expected.
In the present application, while adjusting the position of the stepless headrest, the stepless position adjustment mechanism is devised so as to move the headrest to the support position in accordance with an expected rear collision.

In the present invention, a headrest 3 is provided on the upper portion of a backrest 2 of a vehicle seat 1 so as to be movable back and forth by a parallel link mechanism L with respect to a pillar 8 attached to a support member 9 of the backrest 2. The mechanism L is configured such that the position adjustment link A is actuated by the motor 16 so that the front and rear positions can be adjusted, and the vehicle body provided with the vehicle seat 1 predicts a collision from the rear in advance by a radar or the like provided at a desired position. A prediction system S is mounted, the motor 16 is energized by a collision prediction signal from the prediction system S, the collision adjustment operation link B is operated in preference to the position adjustment link A, and the headrest 3 is brought to the foremost position. The vehicle seat headrest is configured to move.
In the present invention, the position adjusting link A includes a position adjusting arm 19 provided at one end of the output rotation shaft 18 of the motor 16 and a rear link arm 12a of the parallel link mechanism L attached to the position adjusting arm 19. And an adjustment rod 20 having a long hole 22 that engages with the pin 23, and the collision prediction operation link B includes a one-way clutch 27 provided at the other end of the output rotation shaft 18 of the motor 16. A rear-projection operating arm 35 that is rotated by the one-way clutch 27; a lock link 45 having an upper hook portion 48 that is connected to and disengaged from the shaft 37 of the rear-projection operating arm 35; and a lower engaging portion 46 of the lock link 45 A drive link 39 having a front engagement hook 43 that engages with the drive link 39, and the drive link 39 includes a lower portion of the lock link 45. When the motor 16 is energized by the collision prediction signal from the prediction system S, the lock is released from the engagement with the shaft 37 of the rear-projection operating arm 35. The lower engagement portion 46 of the link 45 is disengaged from the front engagement hook 43 of the drive link 39, and the rear engagement hook portion 42 of the drive link 39 is engaged with the pin 23 of the rear link arm 12a, so that the long hole 22 is engaged. The vehicle seat headrest is configured to move inside.
In the present invention, the parallel link mechanism L is always urged by the spring 24 to move the headrest 3 backward, and the drive link 39 moves the pin 23 forward when the front engagement hook 43 is disengaged from the lower engagement portion 46. The spring 50 is always urged by a spring 50, and the spring 50 is a headrest of a vehicle seat that is more elastic than the spring 24.

According to the first aspect of the invention, the operability is improved by adjusting the position of the headrest 3 steplessly by the motor 16 and the headrest 3 can be moved to the support position in response to the rear collision expected by the motor 16. In addition, the effect of preventing whiplash is sufficiently high, and the mechanism portion including the motor 16 is provided in the headrest 3, so that the correspondence on the vehicle seat 1 side can be minimized.
In addition, all operations (operations) can be performed by one motor 16, and the cost can be reduced.
According to the second aspect of the present invention, since the position adjusting link A and the collision predicting operation link B are used, the mechanism including the motor 16 can be reduced in size and provided in the headrest 3 with a simple configuration.

An embodiment of the present invention will be described with reference to the drawings. Reference numeral 1 denotes a vehicle seat, 2 denotes a backrest seat of the vehicle seat 1, and 3 denotes a headrest provided on an upper portion of the backrest seat 2.
The headrest 3 is configured by providing a cushion material 5 on a headrest frame 4. The headrest 3 of the embodiment covers the periphery of the cushion material 5 with the skin member 6, but the skin member 6 is not a requirement.
Reference numeral 8 denotes a pillar for mounting the headrest 3 to the support portion 9 of the dorsal seat 2, and in the embodiment, a pair of left and right leg portions 10 are provided at a predetermined interval, but may be formed in a flat plate shape.
Further, the support member 9 of the dorsal seat 2 is provided with an engagement body that engages with an engagement portion provided on a leg portion 10 of a known configuration, so that the pillar 8 is held at a predetermined position in the vertical direction. If the height of the headrest 3 can be adjusted, the position of the headrest 3 can be adjusted to the physique of the seated person, which is preferable.

Thus, the headrest frame 4 is attached to the pillar 8 by the parallel link mechanism L so as to be movable back and forth. A fixing member 11 is provided on the pillar 8, and a lower portion of a pair of front and rear link arms 12 is attached to the fixing member 11 so as to be rotatable by a shaft 13. The upper part of each link arm 12 is rotatably attached to the interlocking member 14 (headrest frame 4) by a shaft 15.
A motor 16 is attached to the fixing member 11, a base of a position adjusting arm 19 is attached to one end of an output rotating shaft 18 of the motor 16, and one end of an adjusting rod 20 is attached to the position adjusting arm 19 by a shaft 21. . A long hole 22 is formed at the other end of the adjusting rod 20, and the pin 23 of the rear link arm 12 a is engaged with the long hole 22.
The motor 16 rotates the position adjusting arm 19 in either the forward or reverse direction, and pushes and pulls the pin 23 engaged with the distal end side of the long hole 22 of the position adjusting arm 19, and the rear rear link. The pin 23 of the arm 12a is rotated back and forth about the shaft 13, and the headrest frame 4 is moved back and forth with respect to the pillar 8 by rotating the pin 23 back and forth.
Therefore, the position adjusting link A is constituted by the position adjusting arm 19 and the adjusting rod 20.

Reference numeral 24 denotes a spring that urges the link arm 12 to always rotate backward, and one end is locked to the link arm 12, and the other end is locked to the fixing member 11 although not shown.
A rotor 26 is attached to the other end of the output rotating shaft 18 of the motor 16 via a one-way clutch 27 so as to rotate in either the forward or reverse direction. Protrusions 30 and 31 are provided on the outer periphery of the rotor 26, and a switch 32 is provided on the movement path of the protrusions 30 and 31.
The other end of the output rotating shaft 18 is attached with a base portion of a rear impact operating arm 35 via a one-way clutch 27 (for the sake of easy understanding, the rear impact operating arm 35 is connected to the position adjusting arm 19 in a side view). It is listed together.) One end of a rear-projection operating rod 36 is attached to the tip of the rear-projection operating arm 35 by a shaft 37. A long hole 38 is formed at the other end of the rear impact operating rod 36, and a pin 40 provided at one end of the drive link 39 is engaged with the long hole 38. The drive link 39 is pivotally attached to the fixed member 11 by a shaft 13 at the front and rear intermediate portions. The drive link 39 is provided with a rear engagement hook portion 42 at the rear end. The rear engagement hook portion 42 is disposed so as to contact the pin 23 when the drive link 39 rotates about the shaft 13.

A front engagement hook 43 is provided at the front end of the drive link 39. The front engagement hook 43 is connected to and detached from the lower engagement portion 46 of the lock link 45. The upper and lower intermediate portions of the lock link 45 are attached to the fixing member 11 by a shaft 47, and an upper hook portion 48 is formed on the upper portion of the lock link 45, and the upper hook portion 48 is configured to engage with the shaft 37.
In this case, the lower engagement portion 46 of the lock link 45 and the front engagement hook 43 of the drive link 39 are respectively formed with a guide surface 46a and a guide surface 43a, and the front engagement hook 43 of the drive link 39 is lower. It is guided to engage with the engaging portion 46.
Further, the lock link 45 is provided with a spring 49 that urges the lock link 45 so as to always rotate in a direction in which the lock link 45 is engaged with the front engagement hook 43 of the drive link 39. One end of the spring 49 engages with the lock link 45, and the other end engages with the fixing member 11 although not shown.

In addition, a stopper 50 is provided on the rotation path of the lock link 45 for waiting at a predetermined position when the front engagement hook 43 of the drive link 39 is released.
Reference numeral 51 denotes a spring that biases the rear engagement hook portion 42 of the drive link 39 so as to contact the pin 23 of the rear link arm 12a. The elasticity of the spring 51 is set to be stronger than the elasticity of the spring 24. 51 moves the headrest 3 forward through the parallel link mechanism L against the elasticity of the spring 24.
As described above, the collision prediction operation link B is configured by the rear collision operation arm 35, the drive link 39, and the lock link 45.

Accordingly, a prediction system S that predicts a collision from behind by a radar or the like in advance is provided at a desired body position, and the motor 16 is energized by a collision prediction signal from the prediction system S.
In the embodiment, the connection terminal 56 provided at the other end of the connection cord 55 having one end connected to the motor 16 is provided in the pillar 8 of the headrest 3, and the connection terminal 56 is connected to the support portion 9 of the backrest seat 2. 57, and the connection cord 58 is connected to the connection terminal 57, and the motor 16 is energized from the connection cord 58 via the connection terminal 56 and the connection terminal 57. 59 and the collision prediction signal from the prediction system S.
Further, when the prediction system S is activated and the headrest 3 is moved forward by the rear collision prediction operation, the energization is once turned off, and the timer 60 is configured to energize automatically after a predetermined time has elapsed.

Next, the operation of the embodiment will be described.
(Front / back adjustment mode)
In FIG. 3, the headrest 3 is located at the rearmost position, and the rear link arm 12 a is located at the rear end of the long hole 22 of the adjustment rod 20.
When the motor 16 is energized in this state, the output rotating shaft 18 rotates in FIG. 3, and the position adjusting arm 19 fixed to one end of the output rotating shaft 18 rotates in the clockwise direction (the output rotating shaft 18 The rotor 26 on the other end side is not transmitted clockwise in the drawing by the one-way clutch 27, and the rear impact arm 35 is stopped while the position adjusting arm 19 is rotating while the position adjusting arm 19 is rotating. .

When the position adjustment arm 19 rotates, the adjustment rod 20 is pulled, and the inner periphery of the rear end of the long hole 22 of the adjustment rod 20 pulls the pin 23 to rotate the rear link arm 12a forward about the shaft 13 ( 4), the headrest 3 is moved to the front side.
Further, when the position adjusting arm 19 is rotated by the motor 16, the headrest 3 is positioned at the foremost position. At this time, the position adjusting arm 19 is positioned at the maximum traction position where the adjustment rod 20 is pulled to the maximum ( FIG. 5).
When the position adjusting arm 19 is further rotated by the motor 16 from this state, the position adjusting arm 19 passes through the maximum pulling position of the adjusting rod 20 and acts to return the adjusting rod 20.

At this time, the rear link arm 12a is urged so as to always rotate backward by the spring 24, and the pin 23 is pressed against the rear end of the long hole 22 of the adjusting rod 20, so that the position adjusting arm 19 is adjusted. When the rod 20 is moved rearward and the elongated hole 22 of the adjusting rod 20 moves rearward, the pin 23 at the rear end of the elongated hole 22 is allowed to move backward and moves backward together with the adjusting rod 20, and the rear link. The arm 12a rotates rearward, and the headrest 3 moves rearward.
In this way, the position adjusting arm 19 for the back and forth adjustment always rotates clockwise, the adjustment rod 20 reciprocates back and forth, and the pin 23 remains in contact with the inner periphery of the rear end of the long hole 22 of the adjustment rod 20. The headrest 3 is moved forward and backward by the rotational force of the motor 16 and moved rearward by the elasticity of the spring 24. As a result, the headrest 3 is reciprocated back and forth to energize the motor 16 when it is at a desired position in the middle. When is turned off, the front / rear position adjustment operation ends.

  In this front / rear adjustment mode, the output rotary shaft 18 rotates in the clockwise direction, and at this time, the one-way clutch 27 is disengaged and the rotor 26 and the rear collision operating arm 35 are not rotated.

(Rear collision prediction operation mode)
A collision prediction signal from a prediction system that predicts a collision from the rear in advance by a radar or the like provided at a desired position of the vehicle body is sent to the motor 16, and the motor 16 rotates the output rotary shaft 18 counterclockwise in FIG.
The rotation of the output rotating shaft 18 is transmitted to the rear impact operating arm 35 via the one-way clutch 27, the rear impact operating arm 35 rotates counterclockwise, and the shaft 37 of the rear impact operating arm 35 rotates counterclockwise. The shaft 37 rotates the lock link 45 about the shaft 47 in the clockwise direction so that the engagement with the upper hook portion 48 of the lock link 45 is released.

When the lock link 45 rotates about the shaft 47 in the clockwise direction, the lower engagement portion 46 of the lock link 45 is separated from the front engagement hook 43 of the drive link 39, and the front engagement hook 43 of the drive link 39 is locked. When the drive link 39 is disengaged from the lower engagement portion 46 of 45, the drive link 39 suddenly rotates clockwise around the shaft 13 due to the elasticity of the spring 51 (FIG. 7), and the rear engagement hook portion 42 of the drive link 39 moves to the rear. The rear link arm 12a is rotated forward by hitting the pin 23 of the side link arm 12a (FIG. 8).
Therefore, the headrest 3 is moved forward by the forward rotation of the rear link arm 12a.
In this case, since the pin 23 moves forward in the long hole 22 of the adjusting rod 20, the rear link arm 12a instantaneously rotates forward.
On the other hand, the rotation of the output rotating shaft 18 is transmitted to the rotor 26 via the one-way clutch 27, and the protrusion 30 of the rotor 26 that is in contact with the switch 32 is separated, so that the drive link 39 is disengaged from the lower engaging portion 46 of the lock link 45. When the front engagement hook 43 is released and the drive link 39 rotates the rear link arm 12a forward, 31 contacts the switch 32 and stops the motor 16.

(Return operation mode)
In the rear impact prediction operation mode, when the motor 16 is operated and the headrest 3 is moved to the front side of the emergency, the protrusion 31 of the rotor 26 contacts the switch 32 and the motor 16 is deenergized. The motor 16 is automatically energized, and the rotor 26 and the rear impact arm 35 rotate counterclockwise.
The rear-projection operating arm 35 rotates the shaft 37 counterclockwise, and the shaft 37 pulls the rear-projection operating rod 36 upward and engages with the long hole 38 of the rear-projection operating rod 36. Pull 40 upward.

As a result, the drive link 39 rotates clockwise around the shaft 13, and the guide surface 43 a of the front side engagement hook 43 of the drive link 39 abuts on the guide surface 46 a of the lower engagement portion 46 of the lock link 45, causing the lock link 45 to move. When the guide surface 43 a of the front engagement hook 43 passes through the guide surface 46 a of the lower engagement portion 46 of the lock link 45, the front engagement hook 43 moves to the lower engagement portion 46 of the lock link 45. Engage.
When the front engagement hook 43 of the drive link 39 is engaged with the lower engagement portion 46 of the lock link 45, the rear engagement hook portion 42 of the drive link 39 is retracted from the pin 23 of the rear link arm 12a, As it is, the adjustment rod 20 returns to the original position by the counterclockwise rotation of the position adjusting arm 19, and the pin 23 of the rear link arm 12 a is also moved to the rear side of the long hole 22.
Then, when the position adjusting arm 19 and the adjusting rod 20 return to the initial positions, the shaft 37 of the rear impact operating arm 35 contacts the upper hook portion 48 of the lock link 45.
In this state, the protrusion 30 of the rotor 26 contacts the switch 32 and the motor 16 is deenergized.

The side view of a back seat and a headrest. The perspective view of the link mechanism in a headrest. The same side view. The side view of the link mechanism of the state which moved the headrest to the front-back intermediate position. The side view of the link mechanism of the state which moved the headrest to the foremost position. The side view of the link mechanism in the state which energized the motor by the rear collision prediction signal. The side view of the drive link rotation start state. The side view of the link mechanism of the state which moved the headrest by the drive link to the foremost position. The side view of the return start state based on the drive link. The side view of the return state of the drive link. The side view of the reset state of a lock link and a drive link. Block Diagram.

Explanation of symbols

  DESCRIPTION OF SYMBOLS 1 ... Vehicle seat, 2 ... Backrest seat, 3 ... Headrest, 4 ... Headrest frame, 5 ... Cushion material, 6 ... Skin member, 8 ... Pillar, 9 ... Support member, 11 ... Fixing member, 12 ... Link arm, 12a ... rear side link arm, 13 ... shaft, 14 ... interlocking member, 15 ... shaft, 16 ... motor, 18 ... output rotating shaft, 19 ... position adjusting arm, 20 ... adjusting rod, 21 ... shaft, 22 ... long hole , 23 ... pin, 24 ... spring, 26 ... rotor, 27 ... one-way clutch, 30 ... protrusion, 31 ... protrusion, 32 ... switch, 35 ... rear operation arm, 36 ... rear operation rod, 37 ... shaft, 38 ... Long hole, 39 ... Drive link, 40 ... Pin, 42 ... Rear side engagement hook part, 43 ... Front side engagement hook, 45 ... Lock link, 46 ... Lower engagement part, 47 ... Shaft, 48 ... Upper hook part, 49 ... Spring, 50 ... Stopper, 51 ... spring, 55 ... connection cord, 56 ... connection terminal, 57 ... connection terminal, 58 ... connection cord, 59 ... longitudinal adjustment switch, 60 ... timer.

Claims (3)

A headrest 3 is provided on the upper part of the backrest 2 of the vehicle seat 1 so as to be movable back and forth by a parallel link mechanism L with respect to a pillar 8 attached to the support member 9 of the backrest 2. The parallel link mechanism L is a motor. 16 is configured so that the position adjustment link A is actuated to adjust the front-rear position, and the vehicle body provided with the vehicle seat 1 is provided with a prediction system S that predicts a collision from the rear in advance by a radar or the like provided at a desired position. It is mounted, and the motor 16 is energized by the collision prediction signal from the prediction system S, and the headrest 3 is moved to the foremost position by operating the collision prediction operation link B in preference to the position adjustment link A. Constructed vehicle seat headrest. 2. The position adjustment link A according to claim 1, wherein the position adjustment link A includes a position adjustment arm 19 provided at one end of the output rotation shaft 18 of the motor 16, and a rear link arm of the parallel link mechanism L attached to the position adjustment arm 19. And an adjustment rod 20 having a long hole 22 that engages with a pin 23 of 12a, and the collision-predicting operation link B is a one-way clutch 27 provided at the other end of the output rotating shaft 18 of the motor 16. A rear-projection operating arm 35 that is rotated by the one-way clutch 27, a lock link 45 having an upper hook portion 48 that is connected to and disengaged from the shaft 37 of the rear-projection operating arm 35, and a lower engaging portion of the lock link 45 46 and a drive link 39 having a front engagement hook 43 that engages with the drive link 39, and the drive link 39 is connected to the lock link 4. When the motor 16 is energized by the collision prediction signal from the prediction system S, the engagement with the shaft 37 of the rear collision operating arm 35 is engaged. The lower engaging portion 46 of the disengaged lock link 45 is disengaged from the front engaging hook 43 of the drive link 39, and the rear engaging hook portion 42 of the drive link 39 is engaged with the pin 23 of the rear link arm 12a. A vehicle seat headrest configured to move in the long hole 22. In claim 2, the parallel link mechanism L is always urged by the spring 24 to move the headrest 3 backward, and the drive link 39 moves the pin 23 forward when the front engagement hook 43 is disengaged from the lower engagement portion 46. A vehicle seat headrest that is always urged by a spring 50 so as to be moved, and the spring 50 is more elastic than the spring 24.

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