JP5574524B2 - Seat belt retractor - Google Patents

Description

  The present invention relates to a seat belt retractor, and more particularly to a seat belt retractor that locks in response to tilting of a seat back of a reclining seat.

  A seat belt device mounted on a vehicle is for restraining an occupant of a vehicle seat by a seat belt pulled out from a seat belt retractor in a seat back to protect the occupant at the time of a vehicle collision or the like. When an acceleration greater than a predetermined value is applied in the horizontal direction in the event of a vehicle collision, the seat belt retractor detects this acceleration and activates the seat belt locking mechanism, thereby making it impossible to pull out the seat belt. .

  In this case, since the acceleration sensor detects the acceleration in the horizontal direction, the posture must be maintained horizontally regardless of the inclination angle of the seat back during reclining, and a mechanism for holding the acceleration sensor horizontally is proposed. Has been. Also, the mechanism for locking the retractor when the seat back and the retractor are moved from the tilted design position of the seat back to a specific forward and rearward tilt, regardless of the sensed acceleration when moved. Has also been proposed (see Patent Document 1).

JP-T-2002-528322

  By the way, in the conventional seat belt retractor, a stopper is provided as a rotation restriction of the sensor case, but in this case, even if the rotation of the sensor case stops, the retractor is locked if the seat back does not tilt until the self-supporting inertial body collapses. I can't let you. For this reason, even in a state where the seat back is excessively reclined, there is a range in which the retractor is not locked in the range of an angle of dozens of degrees after exceeding the set angle, and there is a problem that the seat belt is pulled out. there were.

  The present invention has been made in view of the above-described circumstances, and an object of the present invention is to provide a seat belt that can be forcibly locked when a reclining angle of a seat back falls to a predetermined angle with a relatively simple configuration. To provide a retractor.

The above object of the present invention is achieved by the following configurations.
(1) a retractor frame attached to a seat back of a reclining seat;
An acceleration sensor for detecting horizontal acceleration;
In a seat belt retractor comprising: a lock mechanism that locks a pull-out operation of the seat belt according to the acceleration detected by the acceleration sensor;
The acceleration sensor is
An inertial body,
It has a supporting surface for supporting the inertial body, and can swing the sensor case relative to the retractor frame,
A counter mass attached to the sensor case so as to hold the support surface of the sensor case horizontally;
An actuating part that activates the lock mechanism to the lock side by the movement of the inertial body when a predetermined horizontal acceleration is applied to the inertial body;
When the seat back is tilted rearward by a predetermined angle, the other actuating part is configured to actuate the lock mechanism to the lock side by swinging the sensor case with respect to the retractor frame without accompanying movement of the inertial body ; I have a,
The other operating part locks the locking mechanism via the operating part,
The sensor case has a case main body having the support surface, and a pair of rib portions extending laterally from the case main body,
The counter mass has a pair of extending portions that respectively engage with the pair of rib portions,
The other operating part is pushed by the rib part of the sensor case or the extending part of the counter mass that swings with respect to the retractor frame when the seat back is tilted backward by a predetermined angle, A seat belt retractor characterized in that the lock mechanism is operated to the lock side .
( 2 ) The other operating part is constituted by a protrusion provided on the sensor case,
The projection is characterized in that when the seat back is tilted backward by a predetermined angle, the lock mechanism is actuated to the lock side via the actuating part by swinging of the sensor case with respect to the retractor frame. The seat belt retractor as described in 1).
( 3 ) a retractor frame attached to the seat back of the reclining seat;
An acceleration sensor for detecting horizontal acceleration;
In a seat belt retractor comprising: a lock mechanism that locks a pull-out operation of the seat belt according to the acceleration detected by the acceleration sensor;
The acceleration sensor is
An inertial body,
The case body having a support surface for supporting the inertial body, and has a pair of ribs extending laterally from the case body, and can swing the sensor case relative to the retractor frame,
A counter mass that has a pair of extending portions that respectively engage with the pair of rib portions, and is attached to the sensor case so as to hold the support surface horizontally;
An actuating part that activates the lock mechanism to the lock side by the movement of the inertial body when a predetermined horizontal acceleration is applied to the inertial body;
When the seat back is tilted backward by a predetermined angle, the lock mechanism is pushed to the lock side by being pushed by the rib portion of the sensor case or the extension portion of the counter mass without the movement of the inertial body . With other operating parts to be activated,
A seat belt retractor and having a.

  According to the seatbelt retractor of the present invention, the acceleration sensor has a support surface that supports the inertial body, the sensor case that can swing with respect to the retractor frame, and the support surface of the sensor case are held horizontally. A counter mass attached to the sensor case, an operating part for operating the lock mechanism to the lock side by the movement of the inertial body when a horizontal acceleration of a predetermined level or more is applied to the inertial body, and a seat back at a predetermined angle backward And the other operating part that operates the lock mechanism to the lock side by swinging the sensor case with respect to the retractor frame when tilted, so that when the reclining angle of the seat back is tilted to a predetermined angle by the other operating part It can be locked forcibly.

  Further, the other operating part is constituted by a protrusion provided on the sensor case, and the protrusion is locked via the operating part by the swinging of the sensor case with respect to the retractor frame when the seat back is tilted backward by a predetermined angle. Since the mechanism is operated to the lock side, it is possible to forcibly lock the seat back when the reclining angle of the seat back falls down to a predetermined angle by simply changing the structure of the sensor case.

  Further, according to the seat belt retractor of the present invention, the acceleration sensor has a case main body having a support surface for supporting the inertial body, and a pair of rib portions extending laterally from the case main body. A counter case that can swing relative to the sensor case, a pair of extending portions that respectively engage with the pair of rib portions, a counter mass that is attached to the sensor case so as to hold the support surface horizontally, and a predetermined inertial body. When the above horizontal acceleration is applied, when the inertial body moves the lock mechanism to the lock side and the seat back tilts backward by a predetermined angle, the sensor case rib or countermass And other actuating parts that are pushed by the extending part and actuate the lock mechanism to the lock side, so that the rib part of the sensor case or the extending part of the counter mass extends. Therefore, it is possible to reclining angle of the seat back is locked forcibly when fallen to a predetermined angle.

It is a disassembled perspective view of the seatbelt retractor of 1st Embodiment of this invention. (A) is a perspective view which shows a partial structure of the acceleration sensor utilized for the seatbelt retractor, (b) is a front view of (a). (A) is the III-III arrow sectional drawing of FIG. 1, (b) is the III'-III 'arrow sectional drawing of FIG. It is a fragmentary sectional view which shows the state of the acceleration sensor at the time of tilting a seat back by 40 degrees. It is a fragmentary sectional view showing the state of the acceleration sensor when the seat back is tilted by 45 °. It is a fragmentary sectional view which shows the state of the acceleration sensor at the time of tilting a seat back by 50 degrees. In the seatbelt retractor of 2nd Embodiment of this invention, it is a fragmentary sectional view which shows the state of the acceleration sensor at the time of tilting a seat back by 40 degrees. It is a fragmentary sectional view showing the state of the acceleration sensor when the seat back is tilted by 45 °. It is a fragmentary sectional view which shows the state of the acceleration sensor at the time of tilting a seat back by 50 degrees. In the seatbelt retractor of 3rd Embodiment of this invention, it is a fragmentary sectional view which shows the state of the acceleration sensor at the time of tilting a seat back by 40 degrees. It is a fragmentary sectional view showing the state of the acceleration sensor when the seat back is tilted by 45 °. It is a fragmentary sectional view which shows the state of the acceleration sensor at the time of tilting a seat back by 50 degrees.

  Hereinafter, a seat belt retractor according to each embodiment of the present invention will be described in detail with reference to the drawings.

(First embodiment)
As shown in FIG. 1, a seat belt retractor 10 of the first embodiment includes a retractor frame 11 attached to a seat back (not shown) of a reclining seat, and the retractor frame 11 includes a seat belt (see FIG. 1). A spindle 12 (not shown) is rotatably supported.

  A retractor spring 13 for urging the spindle 12 in the seat belt winding direction is connected to one end side of the spindle 12 in the axial direction, and the retractor spring 13 is attached to the retractor frame 11 while being accommodated in the cover 14. It has been.

  On the other end side of the spindle 12 in the axial direction, a lock mechanism 15 that locks the seat belt withdrawing operation, an acceleration sensor 20 that detects acceleration acting on the vehicle and activates the lock mechanism 15 according to the acceleration, An automatic lock mechanism 40 that operates by performing a webbing pull-out operation and prevents rotation of the spindle 12 in the webbing pull-out direction under normal conditions is provided. The lock mechanism 15 is disposed in the bearing plate 16 and is disposed in the sensor cover 17 together with the acceleration sensor 20 and the automatic lock mechanism 40.

  The automatic lock mechanism 40 includes a drive gear 41 to which the rotation of the spindle 12 is transmitted, an ALR lever 42 that is swingably supported by the bearing plate 16, and two ALRs that are rotatably supported by the ALR lever 42. An automatic locking mechanism assembly 45 including gears 43 and 44 and a pawl 46 that engages and disengages with the ratchet wheel 15a of the locking mechanism 15 in response to the swing of the ALR lever 42.

  A fan-shaped first ALR protrusion 41 a is provided on the side surface of the drive gear 41, and a second ALR gear 43, 44 has a second contactable surface with the first ALR protrusion 41 a. The ALR projection 43a and the third ALR projection 44a are provided. When a predetermined webbing pull-out operation is performed, the first ALR projection 41a and the second ALR projection 43a come into contact with each other, so that the ALR lever 42 swings and the pawl 46 is moved to the ratchet wheel 15a. To be locked. On the other hand, when a predetermined webbing take-up operation is performed, the first ALR projection 41a and the third ALR projection 44a come into contact with each other, whereby the ALR lever 42 swings and the pawl 46 moves to the ratchet wheel. Detach from 15a and unlock.

  Here, on the side surface of the bearing plate 16, a first gear 47 that meshes with the drive gear 41, a second gear 48 that meshes with the first gear 47, and a cam plate 49 that meshes with the second gear 48. The rotation of the spindle 12 is transmitted to the cam plate 49 via the first and second gears 47 and 48. As a result, in the range where the seat back is tilted forward (the occupant is not wearing the seat belt), the cam plate 49 is rotated according to the amount of winding in this range, and the cam plate 49 is predetermined. The ratchet lever 24 described later is pressed against the acceleration sensor at the phase position. Thereby, the claw 24a of the ratchet lever 24 is not engaged with the outer peripheral teeth of the ratchet wheel 15a, and the acceleration sensor 20 is inactivated.

  The acceleration sensor 20 is fixed to the sensor case 21, the self-supporting inertial body 22 stored in the case 21, the acceleration sensor lever 23 and the ratchet lever 24 as operating parts, and the retractor frame 11, and can tilt the sensor case 21. And a counter mass 26 attached to the sensor case 21.

  The sensor case 21 is attached to a holder 25 so as to be tiltable about a horizontal axis parallel to the axial direction of the spindle 12 (X direction in FIG. 1). As shown in FIG. 2, the sensor case 21 has a case main body 21a and a pair of rib portions 21b extending on both sides in the Y direction, and elastic pieces 21c are formed on the respective rib portions 21b. The counter mass 26 includes a pair of concave extending portions having a weight portion 26b extending from the flat plate portion 26a so as to surround a lower portion of the case main body portion 21a, and an engagement hole 26c extending from the flat plate portion 26a in the same direction as the weight portion 26b. 26d. The counter mass 26 is attached to the sensor case 21 by inserting the flange portion 21b of the sensor case 21 into the concave extending portion 26d and elastically returning the elastic piece 21c within the engagement hole 26c. As a result, the support surface 31 (see FIG. 3) formed on the bottom of the case main body 21a of the sensor case 21 is always kept in a horizontal state regardless of the reclining adjustment angle of the seat back.

  The self-supporting inertia body 22 has a substantially cylindrical shape including a small-diameter portion 52 having a bottom surface 51 and a large-diameter portion 54 having a guide surface 53 on the upper portion. The self-supporting inertia body 22 is stored in the sensor case 21 in a self-supporting state by placing the bottom surface 51 on the support surface 31 of the sensor case 21. Then, when a horizontal acceleration of a predetermined level or more is applied, it can fall within an allowable range with the outer diameter position in the acceleration direction of the area where the support surface 31 and the bottom surface 51 are in surface contact as a fulcrum. It has become.

  The acceleration sensor lever 23 is tilted around the axis in the X direction integrally with the sensor case 21 and supported so as to be tiltable around the axis in the direction (Y direction) perpendicular to the axis direction of the spindle 12 with respect to the sensor case 21. Has been. Further, the ratchet lever 24 is supported by the holder 25 so as to be tiltable about an axis in the X direction.

  Thereby, the contact position of the guide surface 53 of the self-supporting inertial body 22 and the spherical protrusion 23a is changed by the movement of the first lever 23 when the self-supporting inertial body 22 falls in either direction. Tilt. Then, the tilted acceleration sensor lever 23 moves the claw 24a of the ratchet lever 24 upward so as to be engaged with the teeth of the ratchet wheel 15a of the lock mechanism 15 so as to lock the lock mechanism 15 (lock ON). It has become.

  Further, as shown in FIGS. 3 and 4, a first lock lever 27 and a second lock lever 28 as other operating parts are swingably attached to the holder 25. The first lock lever 27 is supported by the holder 25 so as to tilt about the axis in the X direction, and the front end portion 27a is in the holder state with the lower surface thereof facing the outer surface of the concave extending portion 26d of the counter mass 26. 25 is held by the upper edge surface. Further, the second lock lever 28 is supported above the first lock lever 27 so as to be tilted around the axis line in the X direction by the holder 25, and is in contact with the upper surface of the first lock lever 27. The arm 28a and the claw 24a of the ratchet lever 24 and the second arm 28b that comes into contact with the action portion 24b extending on the opposite side with respect to the swing fulcrum are provided at a predetermined angle.

  In the seat belt retractor 10 configured as described above, the support surface 31 of the sensor case 21 is always maintained until a predetermined angle at which the seat back tilts with respect to the vertical direction, that is, the tilt angle of the seat back reaches 50 °. The first and second lock levers 27 and 28 and the ratchet lever 24 are held by the counter mass 26 attached to the sensor case 21 that is kept horizontal and is attached to the sensor case 21 that is kept horizontal. Then, the lock mechanism 15 is operated to lock the acceleration sensor 20.

  Specifically, as shown in FIG. 4, when the tilt angle of the seat back is 40 °, the lower surface of the first lock lever 27 is separated from the outer surface of the concave extending portion 26d of the counter mass 26, and the tip portion 27 a is held by the upper edge surface of the holder 25. In this state, the claw 24a of the ratchet lever 24 is not engaged with the teeth of the ratchet wheel 15a. As shown in FIG. 5, when the tilt angle of the seat back is 45 °, the lower surface of the first lock lever 27 is in contact with the outer surface of the concave extending portion 26d of the counter mass 26, and the distal end portion 27a is the holder. 25, the first arm 28a of the second lock lever 28 is pushed away from the upper edge surface. As a result, the second lock lever 28 swings and the ratchet lever 28 is gradually rotated by the second arm 28b pushing the action portion 24b of the ratchet lever 24. As shown in FIG. 6, when the tilt angle of the seat back reaches 50 °, the claw 24a of the ratchet lever 28 is engaged with the teeth of the ratchet wheel 15a, and the lock mechanism 15 is operated.

  As described above, according to the seat belt retractor 10 of the present embodiment, the acceleration sensor 20 includes the case main body 21a having the support surface 31 that supports the self-supporting inertial body 22, and the case main body 21a extending laterally. A sensor case 21 that can swing with respect to the retractor frame 11 and a pair of extending portions 26d that respectively engage with the pair of rib portions 21b. A counter mass 26 that is attached to the sensor case 21 so as to be held in place, and an acceleration sensor lever 23 and a ratchet that actuate the lock mechanism 15 to the lock side by a movement when a horizontal acceleration of a predetermined level or more is applied to the self-supporting inertia body 22 The lever 24 comes into contact with the extending portion 26d of the counter mass 26, and the swing angle between the sensor case 21 and the retractor frame 11 is set. Since the first and second lock levers 27 and 28 for locking the lock mechanism 15 are provided, the reclining angle of the seat back is up to 50 ° depending on the extension length of the extension portion 26d of the counter mass 26. It can be locked forcibly when it falls. That is, by determining the extension length of the extension portion 26d of the counter mass 26, the reclining angle of the seat back when locking the retractor can be appropriately set. Until then, the support surface 31 of the sensor case 21 can be held horizontally, and the acceleration sensor 20 has high sensor performance.

  Further, according to the seat belt retractor 10 of the present embodiment, the acceleration sensor 20 has the support surface 31 that supports the self-supporting inertial body 22, and the sensor case 21 that can swing with respect to the retractor frame 11, and the sensor case The lock mechanism 15 is moved by the movement of the self-supporting inertial body 22 when a predetermined horizontal acceleration is applied to the countermass 26 attached to the sensor case 21 so as to hold the support surface 31 of the 21 horizontally and the self-supporting inertial body 22. When the seat back is tilted backward by a predetermined angle, the lock mechanism 15 is moved to the lock side by swinging the sensor case 21 with respect to the retractor frame 11 when the seat back is tilted backward by a predetermined angle. 1 and second lock levers 27 and 28, so that the first and second lock levers 2 , It is possible to force locks when fallen back until 50 ° reclining angle of the seat back is set angle by 28.

  Further, since the first and second lock levers 27 and 28 lock the lock mechanism 15 via the ratchet lever 24, the first and second lock levers 27 and 28 are additionally added. With a simple structure, when the reclining angle of the seat back falls down to a predetermined angle, it can be forcibly locked.

(Second Embodiment)
Next, a seat belt retractor according to a second embodiment of the present invention will be described with reference to FIGS.

  In this embodiment, instead of providing the first and second lock levers 27 and 28 of the first embodiment, a single lock lever 60 is provided as another operating portion. The lock lever 60 is swingably supported by the holder 25, and is engaged with the first arm 60a pressed by the outer surface of the concave extension portion 26d of the counter mass 26 and the teeth of the ratchet wheel 15a. Two arms 60b are provided at a predetermined angle.

  Accordingly, as shown in FIG. 7, when the tilt angle of the seat back is 40 °, the lock lever 60 is separated from the outer surface of the concave extension portion 26 d of the counter mass 26, and the lever holding portion 25 a provided in the holder 25. Is held by. In this state, the lock lever 60 is not engaged with the teeth of the ratchet wheel 15a. As shown in FIG. 8, when the tilt angle of the seat back is 45 °, the first arm 60a of the lock lever 60 comes into contact with the outer surface of the concave extending portion 26d of the counter mass 26 and rotates. Then, as shown in FIG. 9, when the tilt angle of the seat back reaches 50 °, the claw of the second arm 60b of the lock lever 60 engages with the teeth of the ratchet wheel 15a to operate the lock mechanism 15. Let

Therefore, as in the second embodiment, the first embodiment may be configured such that the lock mechanism 15 is operated by directly engaging the ratchet wheel 15a without using the ratchet lever 24 by the single lock lever 60. The same effect can be achieved.
Other configurations and operations are the same as those in the first embodiment.

(Third embodiment)
Next, a seat belt retractor according to a third embodiment of the present invention will be described with reference to FIGS.

  In this embodiment, instead of providing the first and second lock levers 27 and 28 of the first embodiment and the single lock lever 60 of the second embodiment, the case main body of the sensor case 21 is provided as another operating part. A protrusion 21d is provided on 21a. The protrusion 21d is opposed to the claw 24a of the ratchet lever 24 and the action portion 24b extending to the opposite side with respect to the swing fulcrum.

  As a result, as shown in FIG. 10, the protrusion 21 d of the sensor case 21 is held away from the action portion 24 b of the ratchet lever 24 when the tilt angle of the seat back is 40 °. In this state, the ratchet lever 24 is not engaged with the teeth of the ratchet wheel 15a. As shown in FIG. 11, when the tilt angle of the seat back is 45 °, the projection 21 d of the sensor case 21 comes into contact with the action portion 24 b of the ratchet lever 24 and rotates the ratchet lever 24. Then, as shown in FIG. 12, when the tilt angle of the seat back reaches 50 °, the claw 24a of the ratchet lever 24 is engaged with the teeth of the ratchet wheel 15a, and the lock mechanism 15 is operated.

Therefore, unlike the third embodiment, the lock mechanism 27 is operated by engaging the ratchet lever 24 with the ratchet wheel 15a by the projection 21d of the sensor case 21 without providing the lock levers 27, 28, 60. Even if it exists, there can exist an effect similar to 1st and 2nd embodiment.
Other configurations and operations are the same as those in the first and second embodiments.

In addition, this invention is not limited to embodiment mentioned above, A deformation | transformation, improvement, etc. are possible suitably.
For example, in the above embodiment, the inertial body is a self-supporting inertial body, but may be a ball.
In the above embodiment, the concave extending portion 26d of the counter mass 26 is configured to contact the lock levers 27 and 60. However, the rib portion 21b of the sensor case 21 is configured to contact the lock levers 27 and 60. Also good.

DESCRIPTION OF SYMBOLS 10 Seatbelt retractor 15 Lock mechanism 20 Acceleration sensor 21 Sensor case 21b Rib part 21d Protrusion (other action | operation part)
22 Independent inertial body (inertial body)
23 Acceleration sensor lever (operation part)
24 Ratchet lever (actuating part)
26 counter mass 26d concave extension 27 first lock lever (other actuating part)
28 Second lock lever (other actuating part)
31 Support surface 60 Lock lever (other operating parts)

Claims (3)

A retractor frame attached to the seat back of the reclining seat;
An acceleration sensor for detecting horizontal acceleration;
In a seat belt retractor comprising: a lock mechanism that locks a pull-out operation of the seat belt according to the acceleration detected by the acceleration sensor;
The acceleration sensor is
An inertial body,
It has a supporting surface for supporting the inertial body, and can swing the sensor case relative to the retractor frame,
A counter mass attached to the sensor case so as to hold the support surface of the sensor case horizontally;
An actuating part that activates the lock mechanism to the lock side by the movement of the inertial body when a predetermined horizontal acceleration is applied to the inertial body;
When the seat back is tilted rearward by a predetermined angle, the other actuating part is configured to actuate the lock mechanism to the lock side by swinging the sensor case with respect to the retractor frame without accompanying movement of the inertial body ; I have a,
The other operating part locks the locking mechanism via the operating part,
The sensor case has a case main body having the support surface, and a pair of rib portions extending laterally from the case main body,
The counter mass has a pair of extending portions that respectively engage with the pair of rib portions,
The other operating part is pushed by the rib part of the sensor case or the extending part of the counter mass that swings with respect to the retractor frame when the seat back is tilted backward by a predetermined angle, A seat belt retractor characterized in that the lock mechanism is operated to the lock side . The other operating part is constituted by a protrusion provided on the sensor case,
The protrusion is configured to actuate the lock mechanism to the lock side via the actuating part by swinging of the sensor case with respect to the retractor frame when the seat back tilts backward by a predetermined angle. The seat belt retractor according to Item 1. A retractor frame attached to the seat back of the reclining seat;
An acceleration sensor for detecting horizontal acceleration;
In a seat belt retractor comprising: a lock mechanism that locks a pull-out operation of the seat belt according to the acceleration detected by the acceleration sensor;
The acceleration sensor is
An inertial body,
The case body having a support surface for supporting the inertial body, and has a pair of ribs extending laterally from the case body, and can swing the sensor case relative to the retractor frame,
A counter mass that has a pair of extending portions that respectively engage with the pair of rib portions, and is attached to the sensor case so as to hold the support surface horizontally;
An actuating part that activates the lock mechanism to the lock side by the movement of the inertial body when a predetermined horizontal acceleration is applied to the inertial body;
When the seat back is tilted backward by a predetermined angle, the lock mechanism is pushed to the lock side by being pushed by the rib portion of the sensor case or the extension portion of the counter mass without the movement of the inertial body . With other operating parts to be activated,
A seat belt retractor comprising:

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