JP5332035B2 - Seat belt retractor - Google Patents

Abstract

<P>PROBLEM TO BE SOLVED: To provide a compact retractor for seat belt in which an automatic locking mechanism can be operated and an end-lock of an emergency locking mechanism can be prevented from occurring. <P>SOLUTION: In the retractor for seat belt, a WS lever 50 serving as a webbing acceleration sensing means is controlled such that it is retained in a first inoperative position in which rotation of a steering wheel 40 in a webbing pull-out direction is not prevented by a control plate 80 when the webbing is completely taken up; and an ALR lever 60 of the automatic locking mechanism is controlled such that it is retained in a second operative position in which the automatic locking mechanism operates with the control plate 80 until, after the entirety of the webbing is pulled out, a predetermined amount of webbing is taken up. <P>COPYRIGHT: (C)2010,JPO&amp;INPIT

Description

  The present invention relates to an improvement in a seat belt retractor including an emergency lock mechanism (ELR) and an automatic lock mechanism (ALR).

Conventionally, as a seat belt retractor for safely holding an occupant or the like of a vehicle in a seat, an emergency lock mechanism that physically locks a webbing drawer by a vehicle body acceleration sensing means that reacts to sudden acceleration, collision or deceleration is provided. Therefore, an emergency lock type retractor that effectively and safely restrains an occupant is used.
Also, as a seat belt retractor for fixing child seats to vehicle seats with seat belts, it operates when all the webbing is pulled out, prevents webbing from being pulled out during winding, and deactivates when all the webbing is wound A device equipped with an automatic locking mechanism is used.

  By the way, in the seatbelt retractor provided with the emergency lock mechanism, the rotation of the spindle (winding shaft) in the webbing pull-out direction may be locked even when it is not necessary in the event of a vehicle emergency. That is, when the entire amount of webbing is suddenly taken up in accordance with the spring force of the take-up spring from the webbing pulled-out state when the vehicle is mounted, the emergency lock mechanism is activated by the impact and the rotation of the spindle in the webbing pull-out direction is locked. In this case, the webbing cannot be pulled out. In addition, since the webbing is fully wound up at this time, the spindle cannot rotate in the webbing winding direction, and the retractor falls into a so-called end-locked state.

  For example, there are the following emergency locking mechanisms. One is to detect the sudden withdrawal of the webbing and prevent the spindle from rotating in the webbing withdrawal direction (webbing acceleration sensing means: WS), and the other is to sense the sudden deceleration of the vehicle and to pull the spindle webbing. This is one that prevents rotation in the direction (vehicle body acceleration sensing means: VSI). In either case, the lock member that rotates integrally with the spindle is rocked so that the claw of the lock member meshes with the inner teeth of the frame that supports the spindle to lock the spindle (for example, Patent Document 1). And 2).

There are the following three cases where such an end lock occurs.
(1) Due to malfunction of webbing acceleration sensing means (WS).
In general, the webbing acceleration sensor means that when the belt is pulled out rapidly, the rotation of the mass side is delayed from the spindle due to the inertia of the mass, so that the lock member pops out and bites into the inner teeth of the frame Is used. However, if the webbing is stretched after the webbing is taken up suddenly, the mass is moved relative to the spindle with momentum, and the lock member is engaged with the inner teeth of the frame.
(2) Due to malfunction of vehicle body acceleration sensing means (VSI).
This is a case where when the acceleration is inputted to the vehicle body acceleration sensing means due to the rapid winding of the webbing, the ball as the inertia member moves, the lever swings, and the lever is rocked to be engaged with the latch member.
(3) Due to malfunction of the lock member itself.
This is a case where the lock member itself bites into the internal teeth of the frame with the momentum of winding the webbing.

  The seat belt retractor described in Patent Document 1 guides a cam follower provided on a rocking prevention member in a cam groove of a cam plate that is interlocked with the rotation of a spindle, and rotates a stopper portion of the rocking prevention member. And this stopper part contact | abuts to an inertial body, hold | maintains an inertial body in a non-operation position, and prevents a rocking | fluctuation of an inertial body. As a result, when the webbing winding is completed, the inertial body operates to prevent engagement with the lock gear (ratchet wheel), and end-locking when the webbing winding is completed is prevented.

  Further, the seat belt retractor described in Patent Document 2 has a cam member that is rotated by a planetary gear mechanism, and the lock wheel provided with a pair of lock plates as a lock means is fully wound with the spindle. End lock prevention means for preventing relative rotation is provided. Further, the seat belt retractor constitutes an automatic lock mechanism by rotating another cam member via a gear of the planetary gear mechanism and another gear.

JP-A-9-58410 Japanese Patent Laid-Open No. 10-129417

  By the way, in the seatbelt retractor described in Patent Document 1, end locking due to malfunction of the webbing acceleration sensing means is prevented by preventing the swinging of the inertial body, but the automatic locking mechanism is not described. . Further, in the retractor for seat belt described in Patent Document 2, it is described that an end locking due to a malfunction of the lock member itself is provided while an automatic lock mechanism is provided. There is a problem that the number of parts increases and the size of the entire retractor increases.

  The present invention has been made in view of the above-described circumstances, and an object thereof is to provide a compact seat belt retractor capable of preventing the occurrence of an end lock of an emergency lock mechanism along with the operation of an automatic lock mechanism. There is.

In order to achieve the above-mentioned object, the seatbelt retractor according to the present invention is characterized by the following (1) to (7).
(1) a spindle that is rotatably supported by a frame and on which a webbing is wound;
A locking member that locks rotation of the spindle in the webbing pull-out direction by engaging with the frame;
A steering wheel that is rotatably supported by the spindle and that operates the lock member by causing a rotation delay with respect to the spindle;
First locking means pivotally supported on the steering wheel is provided, and when the webbing is pulled out at a predetermined speed or more, the first locking means is displaced to the first operating position. Webbing acceleration sensing means for preventing rotation of the steering wheel in the webbing pull-out direction;
A second locking means pivotally supported by the steering wheel, wherein the second webbing is retracted from the first predetermined amount until the second predetermined amount is wound. An automatic locking mechanism that displaces the locking means to the second operating position and prevents rotation of the steering wheel in the webbing pull-out direction;
A control plate that rotates at a different speed from the spindle according to the rotation of the spindle;
With
The first locking means is controlled by the control plate so as to be held at a first non-operating position where rotation of the steering wheel in the webbing pull-out direction is not blocked when the winding of the webbing is completed,
The second locking means is held by the control plate at the second operating position from when the webbing is pulled out by the first predetermined amount until it is wound up by the second predetermined amount. A retractor for a seat belt, which is controlled.
(2) The seat belt retractor according to (1), wherein the lock member is controlled by the control plate so that the lock member cannot be engaged with the frame when the winding of the webbing is completed. .
(3) An inner peripheral surface of the cover member attached to the frame is engaged with the first locking means at the first operating position and the second locking means at the second operating position. The seatbelt retractor according to (1) or (2), wherein possible internal teeth are formed.
(4) A drive gear that rotates integrally with the spindle, a driven gear that rotates integrally with the control plate and has fewer teeth than the drive gear, and an idle gear that meshes with both the drive and the driven gear. A gear speed increasing mechanism;
The seat belt retractor according to any one of (1) to (3), wherein the control plate rotates at a speed higher than the rotation of the spindle by the gear speed increasing mechanism.
(5) The webbing acceleration sensing means is supported at one end by the steering wheel and at the other end by the first locking means, and the first locking means is at the first inoperative position. Further comprising a biasing means for WS biasing toward the
The first locking means has a WS protrusion extending in the axial direction toward the control plate,
The control plate has a WS cam for controlling the first locking means to be held in the first inoperative position by contacting the WS protrusion when the webbing is completely wound. The retractor for a seat belt according to any one of (1) to (4), wherein
(6) The automatic lock mechanism further includes an ALR biasing unit having one end supported by the steering wheel and the other end supported by the second locking unit,
The second locking means has an ALR projection extending in the axial direction toward the control plate,
The control plate abuts against the ALR projection when the webbing is pulled out by a first predetermined amount, and causes the second locking means to exceed the dead point of the ALR biasing means. When the webbing is wound up by a second predetermined amount, the second locking means is moved beyond the dead point of the ALR biasing means when the webbing is wound up by the second predetermined amount. The retractor for a seat belt according to any one of (1) to (5), further comprising an ALR cam that snaps to a second non-operating position where rotation of the steering wheel in the webbing pull-out direction is not blocked.
(7) The lock member is provided with a pin portion that penetrates a cam hole formed in the steering wheel,
A cancel member having a projection for a lock member extending in the axial direction toward the control plate is positioned and fixed to the pin portion penetrating the cam hole,
The control plate includes a lock member cam that controls the lock member so that the lock member cannot be engaged with the frame by contacting the lock member protrusion when the webbing is completely wound. The retractor for a seat belt according to any one of (2) to (6).

  According to the seat belt retractor of the present invention, the operation of the automatic locking mechanism and the operation of preventing the end lock due to the malfunction of the webbing acceleration sensing means can be performed by a single control plate. A retractor having a function can be reduced in size.

It is a disassembled perspective view of the seatbelt retractor of one Embodiment of this invention. It is sectional drawing of the assembly state of the retractor for seatbelts of FIG. It is a front view of a steering wheel. (A) is a perspective view of a bearing cover, (b) is a front view of a bearing cover. (A) is the cam side perspective view of a control plate, (b) is the front view. It is a figure for demonstrating the control state by each cam of a control plate, (a) shows a total amount storing state, (b) shows a webbing mounting state, (c) shows the state just before pulling out all the amounts. It is a figure for demonstrating switching of an automatic locking mechanism, (a) shows the state just before pulling out all the webbing, (b) shows the state which an automatic locking mechanism act | operates by pulling out all, (c) Shows a state in which the webbing is wound and the second ALR cam is in contact with the cam pin of the ALR lever. (D) shows that the webbing is further wound and the second ALR cam pushes the cam pin. The state which rotates an ALR lever is shown, (e) shows the state by which the action | operation of the automatic lock mechanism was cancelled | released. It is a figure for demonstrating operation | movement of WS lever of a webbing acceleration sensing means, (a) is a state when the phase difference between the inertial body 70 and the steering wheel 40 is 0 degree, (b) is this phase difference (C) shows a state when the phase difference is 5 °. It is a figure for demonstrating the action | operation of a lock dock, (a) is a state at the time of WS lever engagement, (b) is a tooth dock engagement start state of a lock dock, (c) is complete of a lock dock. Indicates the binding state.

  Hereinafter, a preferred embodiment of the seatbelt retractor of the present invention will be described in detail with reference to FIGS.

  The seatbelt retractor of this embodiment has both an emergency locking mechanism having a webbing acceleration sensing means and a vehicle body acceleration sensing means, and an automatic locking mechanism. As shown in FIGS. 1 and 2, this seat belt retractor is made of a metal (for example, aluminum alloy) spindle 1 around which a webbing (not shown) is wound, and the spindle 1 is rotated in the winding direction. A spring-type winding device 2 that urges, a metal U-shaped frame 10 that rotatably supports the spindle 1, a metal (for example, iron) lock dock 20 as a lock member, and a resin A steering wheel 40, a metal (for example, zinc alloy) inertial body (inert mass) 70 that imparts mass to the steering wheel 40, and a resin ratchet wheel 30 as a latch member attached to the inertia mass 70; Resin WS lever 50 as the first locking means of the webbing acceleration sensing means, and resin as the second locking means of the automatic locking mechanism ALR lever 60, a cancel cap 90 made of resin, which is a cancel member attached to the lock dock 20, a control plate 80 made of resin, a vehicle body acceleration sensing means 110 for sensing the acceleration of the vehicle body, the lock dock 20, the ratchet A resin bearing cover 100 is mainly provided as a cover member that covers main components of the emergency lock mechanism such as the wheel 30, the steering wheel 40, the WS lever 50, the inertial body 70, and the vehicle body acceleration sensing means 110. The inertia mass 70 may be made of resin.

  As shown in FIG. 2, the frame 10 has left and right side plates 10A and 10B that are opposed to each other with a central portion of the spindle 1 in the axial direction, and an emergency lock mechanism and an automatic lock mechanism are disposed outside one side plate 10A. The winding device 2 is disposed outside the other side plate 10B. The shaft 5 on one end side of the spindle 1 passes through the center holes 45, 75, 85 of the steering wheel 40, inertia mass 70, and control plate 80, and the drive gear 6 is fitted to the tip of the shaft 5 so as to rotate integrally. ing.

  An idle gear 7 is pivotally supported on the bearing cover 100 attached to one side plate 10 </ b> A of the frame 10, and meshes with both the drive gear 6 and a driven gear 81 formed on one side of the control plate 80. ing. Accordingly, the rotation of the spindle 1 is transmitted from the drive gear 6 to the driven gear 81 via the idle gear 7, and the control plate 80 having the driven gear 81 rotates at an increased speed in conjunction with the spindle 1. . The speed increasing ratio of the gear speed increasing mechanism comprising the drive gear 6, the idle gear 7, and the driven gear 81 is such that the rotation of the spindle 1 when the webbing is fully pulled out to the fully wound state is controlled by the control plate 80. It is set to a numerical value that can be converted into one rotation. In the present embodiment, the number of teeth of the drive gear 6 is 22, the number of teeth of the idle gear 7 is 13, and the number of teeth of the driven gear 81 is 21. The drive, idle, and driven gears 6, 7, and 81 are made of resin.

  A large number of internal teeth 11 into which the claws 22 of the lock dock 20 are fitted are formed on the inner periphery of the circular opening of the side plate 10 </ b> A of the frame 10. The lock dock 20 is slidably accommodated in a space secured between one end face of the spindle 1 and a metal (for example, iron) cover plate 29 fixed to the end face. In addition, a spring accommodation hole 3 that supports and accommodates one end of the coil spring 28 is formed on one end face of the spindle 1. Then, by supporting the other end of the coil spring 28 on a spring support (not shown) formed on the back surface of the steering wheel 40, the coil spring 28 rotates the steering wheel 40 counterclockwise with respect to the spindle 1 (unlock direction). ) To allow the spindle 1 and the steering wheel 40 to rotate integrally. The lock dock 20 is held in the unlocking direction in which the claw 22 is separated from the internal teeth 11 by inserting the cam pin 21 into the cam hole 41 formed in the steering wheel 40. Further, when necessary, the steering wheel 40 is rotated relative to the spindle 1 in the clockwise direction (actually, the spindle 1 is rotated), and the movement of the cam pin 21 resists the force of the coil spring 28. Then, the nail 22 jumps out. Then, the claw 22 jumping out is engaged with the inner teeth 11 of the frame 10 to lock the spindle 1 to the inner teeth 11 of the frame 10 and mechanically lock the rotation in the webbing pull-out direction.

  The steering wheel 40 is supported by the spindle 1 so as to be relatively rotatable. As shown in FIG. 3, the steering wheel 40 is fitted into the cam hole 41 with which the cam pin 21 of the lock dock 20 is engaged and the shaft hole 51 of the WS lever 50. A convex shaft 42 that swingably supports the lever 50, a convex shaft 43 that swingably supports the ALR lever 60 by fitting in the shaft hole 61 of the ALR lever 60, and a convex that protrudes toward the spindle side of the ALR lever 60. And another cam hole 44 that accommodates the portion 64.

The cam hole 41 pushes the claw 22 of the lock dock 20 outward through the cam pin 21 when the steering wheel 40 rotates relative to the spindle 1. For example, when the steering wheel 40 is delayed in rotation with respect to the spindle 1 when the webbing is pulled out, the lock dock 20 is operated to the lock side by the relative rotation of the spindle 1 and the steering wheel 40.
A cancel cap 90 having a lock member projection 91 extending in the axial direction toward the control plate 80 on the side surface of the cam pin 21 penetrating the cam hole 41 is not rotatable relative to the cam pin 21. Positioning is fixed.

  The WS lever 50 includes a claw 52 that can be engaged with an inner tooth 108 (FIG. 4) of the bearing cover 100 described later and a WS protrusion 53 that extends in the axial direction toward the control plate 80. The WS lever 50 is rotationally biased in a direction in which the claw 52 is retracted inward by a WS spring 58 that is a biasing means for WS, and is held in a first inoperative position that does not engage with the internal teeth 108 in a normal state. The The WS spring 58 is supported at one end by the steering wheel 40 and at the other end by the WS lever 50.

  The ALR lever 60 includes a cam pin 62 that is an ALR protrusion extending in the axial direction toward the control plate 80, a claw 63 that can be engaged with the internal teeth 108 (FIG. 4) of the bearing cover 100, And a convex portion 64. The ALR lever 60 supports the other end portion of an ALR spring 69 which is an ALR biasing means whose one end portion is supported by the steering wheel 40. The ALR lever 60 is guided by the ALR spring 69 in the second cam position where the convex portion 64 is guided in the other cam hole 44 of the steering wheel 40 and is not engaged with the internal tooth 108. Snap action is performed across the dead point of the ALR spring 69 between the two inoperative positions.

  The inertia body 70 is attached to the steering wheel 40 with the WS lever 50, the ALR lever 60, and the like assembled to the steering wheel 40, and the center hole 75 is fitted to the shaft 5 of the spindle 1 so as to be relatively rotatable. Yes. Further, the inertia body 70 is assembled so as to be slightly rotatable relative to the steering wheel 40 by a plurality of claw members 46 provided around the center hole 45 of the steering wheel 40. A convex portion 71 is provided on a side surface of the inertial body 70, and the convex portion 71 is located in the vicinity of the base portion of the WS protrusion portion 53 of the WS lever 50. When relative rotation occurs between the inertial body 70 and the steering wheel 40, the convex portion 71 of the inertial body 70 presses the WS lever 50 supported by the steering wheel 40, and the claw of the WS lever 50 52 is displaced to the first operating position protruding outward and meshed with the internal teeth 108 of the bearing cover 100. As a result, the webbing sensing means prevents the steering wheel 40 from rotating in the webbing pull-out direction. The inertia body 70 includes notches 72 and 73 through which the protrusion 53 of the WS lever 50 and the lock member protrusion 91 of the cancel cap 90 penetrate toward the control plate 80, and the cam pin 62 of the ALR lever 60. A through-hole 74 is formed through which can be swung freely toward the control plate 80 side.

  As shown also in FIG. 4, a cylindrical wall 107 protrudes from the inner surface side of the face plate 101 of the bearing cover 100, and the above-described WS lever 50 and ALR lever 60 can be engaged with the inner periphery of the cylindrical wall 107. Teeth 108 are provided. Further, the bearing cover 100 is provided with a base portion 110A constituting the vehicle body acceleration sensing means 110, and a ball cover 127 for holding a ball (not shown) is attached thereto. Then, when a ball (not shown) moves in accordance with the vehicle body acceleration, the VS sensor lever 120 as the operating member swings and the claw 121 is lifted, and engages with the external teeth 31 provided on the outer periphery of the ratchet wheel 30. Then, the ratchet wheel 30 is locked.

  The control plate 80 is provided with a center hole 85 that is rotatably fitted to the bearing cover 100 at the center, and the above-described driven gear 81 is provided on one side. Further, on the side opposite to the side where the driven gear 81 is provided, as shown in FIG. 5, a first cam 86 that is a WS cam, a second cam 87 that constitutes an ALR cam, 88, a fourth cam 89 which is a cam for the lock member protrudes in the axial direction and is formed in a rib shape.

  The first cam 86 is formed in a circular arc shape concentric with the outer peripheral surface of the control plate 80, and when the webbing winding is completed, the first cam 86 contacts the projection 53 of the WS lever 50 in the first non-operating position. It is formed so as to include a contact position. The second cam 87 extends substantially in the radial direction of the control plate 80 and is formed in an arc shape. When the webbing is pulled out from just before the full amount is pulled out to the full amount that is the first predetermined amount, the cam pin 62 of the ALR lever 60 is drawn. It is formed in the position which contacts. The third cam 88 has a circular arc portion concentric with the outer peripheral surface of the control plate 80 and a guide portion extending toward the inner periphery from one end of the circular arc portion, and the total amount of webbing being the first predetermined amount. When the second predetermined amount is wound from the drawer, it is formed at a position where it comes into contact with the cam pin 62 of the ALR lever 60 in the second operating position. The fourth cam 89 is formed in an arc shape concentric with the outer peripheral surface of the control plate 80, and is attached to the lock dock 20 at a position where it does not engage with the internal teeth 11 of the frame 10 when the webbing winding is completed. The lock member projection 91 of the cancel cap 90 is formed so as to include a position in contact with the inner peripheral surface.

Next, the operation of the seat belt retractor of the present embodiment will be described.
As shown in FIG. 6A, in the state in which the entire amount of webbing is stored, the protrusion 53 of the WS lever 50 is in contact with the outer peripheral surface of the first cam 86, and the WS lever 50 is pulled out of the webbing of the steering wheel 40. The first non-actuated position where rotation in the direction is not prevented, that is, the position where the claw 52 that does not engage with the internal teeth 108 of the bearing cover 100 is retracted is held unrotatable.

  Similarly, the protrusion 91 of the cancel cap 90 is in contact with the inner peripheral surface of the fourth cam 89, and the lock dock 20 cannot be rotated at a position where it cannot engage with the inner teeth 11 of the frame 10. Retained. The outer peripheral surface of the third cam 88 is opposed to the ALR lever 60 in the vicinity thereof, and the ALR lever 60 that is biased by the ALR spring 69 and is in the second non-operating position is snapped by the second operation. Prevents movement to the operating position.

  When the webbing is pulled out from the full storage state shown in FIG. 6A, the control plate 80 rotates relative to the spindle 1 in the arrow A direction. Therefore, the control plate 80 rotates relative to the lock dock 20 supported by the spindle 1 and the WS lever 50 and ALR lever 60 supported by the steering wheel 40 rotating together with the spindle 1 in the direction of arrow A.

  Accordingly, the contact between the protrusion 53 of the WS lever 50 and the first cam 86 is released, and the contact between the protrusion 91 of the cancel cap 90 and the fourth cam 89 is released. For this reason, the WS lever 50 held in the first non-operating position by the WS spring 58 can swing and rotate to the first operating position that prevents the steering wheel 40 from rotating in the webbing pull-out direction. Further, the lock dock 20 held at a position where it cannot be engaged with the inner teeth 11 of the frame 10 by the coil spring 28 can jump outward to a position where it engages with the inner teeth 11. Therefore, as shown in FIG. 6B, in the webbing wearing state in which the tongue is attached to the buckle, the webbing can be freely pulled out and taken up at normal times when the deceleration exceeding the predetermined value does not act on the vehicle. Further, in a webbing wearing state, the webbing acceleration sensing means and the vehicle body acceleration sensing means can be operated in an emergency in which a deceleration greater than a predetermined value acts on the vehicle.

  Then, as shown in FIGS. 6C and 7A, in the vicinity of the full amount drawer where the webbing is further pulled out, the cam pin 62 of the ALR lever 60 abuts on the second cam 87 and is further pulled out, It moves radially inward along the arc of the second cam 87. For this reason, the ALR lever 60 snaps to the second operating position beyond the dead point of the ALR spring 69. As a result, as shown in FIG. 7B, the claw 63 of the ALR lever 60 engages with the internal teeth 108 of the bearing cover 100, so that the automatic locking mechanism is activated, and the spindle 1 rotates in the pull-out direction. Is regulated.

  In this state, the spindle 1 can rotate while flipping the ALR lever 60 inward by the internal teeth 108 together with the steering wheel 40, so that the webbing can be taken up. For this reason, when the child seat or the like is attached, the child seat can be securely fixed to the vehicle seat by setting the automatic locking mechanism in an activated state and winding the surplus webbing with the winding device 2.

  Then, as shown in FIG. 7 (c), when the webbing is wound up by the second predetermined amount from the vicinity of the entire amount, the cam pin 62 of the ALR lever 60 comes into contact with the third cam 88, and FIG. As shown, it moves radially outward along the other cam hole 44 and snaps to the second non-operating position beyond the dead point of the ALR spring 69 (see FIG. 7E). Thereby, the operation state of the automatic lock mechanism is switched to the state in which the emergency lock mechanism can be operated.

  Further, after the occupant releases the fastening between the tongue and the buckle, the webbing is wound up by the spring force of the winding device 2. The protrusion 53 of the WS lever 50 comes into contact with the first cam 86 from the time before the winding is completed to the time of completion, and the WS lever 50 is held in the first inoperative position, and the protrusion of the cancel cap 90 The portion 91 comes into contact with the fourth cam 89 and the lock dock 20 is held at a position where it cannot be engaged with the internal teeth 11 of the frame 10. As a result, it is possible to prevent end lock due to malfunction of the webbing acceleration sensing means and to prevent end lock of the lock dock 20 itself.

  6B, when the webbing is pulled out at a predetermined speed or more due to a vehicle collision or the like and a sudden webbing pulling force is applied to the spindle 1, the state shown in FIG. Relative rotation occurs between the inertial body 70 and the steering wheel 40 from the state where the phase difference between the inertial body 70 and the steering wheel 40 is 0 °. For this reason, as shown in FIG. 8B, the convex portion 71 of the inertial body 70 that is in contact with the WS lever 50 presses the WS lever 50 and rotates the WS lever 50. When the predetermined angle is reached, the claw 52 of the WS lever 50 engages with the internal teeth 108 of the bearing cover 100 (see FIG. 8C).

  Then, as shown in FIG. 9A, when the webbing is further pulled out in a state where the steering wheel 40 is fixed by engaging the claw 52 of the WS lever 50 with the internal teeth 108 of the bearing cover 100, the steering wheel 9 causes a rotation delay with respect to the spindle 1, and the lock dock 20 in which the cam pin 21 is accommodated in the cam hole 41 of the steering wheel 40 moves outward as shown in FIG. 22 jumps out and engages with the internal teeth 11 of the frame 10. FIG. 9C shows a state in which the webbing is further pulled out and the claw 22 of the lock dock 20 is completely fastened to the inner teeth 11 of the frame 10. As a result, the spindle 1 is locked and rotation of the webbing in the pulling direction is prevented.

  Further, when the vehicle body acceleration sensing means 110 is activated, the ratchet wheel 30 is locked by the claws 121 of the VS sensor lever 120 engaging the external teeth 31 of the ratchet wheel 30. When the ratchet wheel 30 is locked, relative rotation occurs between the inertial body 70 to which the ratchet wheel 30 is fixed and the steering wheel 40, so that the spindle is acted by the action of the WS lever 50 and the lock dock 20 in the same manner as described above. 1 is locked.

  As described above, according to the seat belt retractor of the present embodiment, the WS lever 50 and the ALR lever 60 are controlled by the single control plate 80, so that the function of the automatic locking mechanism and the webbing acceleration sensing means can be improved. A function of preventing end lock due to malfunction can be performed, and a retractor having these two functions can be reduced in size.

  Specifically, the function of preventing end lock due to malfunction of the webbing acceleration sensing means can be performed by the WS protrusion 53 of the WS lever 50 and the first cam 86 of the control plate 80. The automatic locking mechanism can be operated and released by the ALR spring 69, the cam pin 62 of the ALR lever 60, and the second and third cams 87 and 88 of the control plate 80.

Moreover, the function which prevents the end lock | rock by malfunctioning of the lock dock 20 itself can also be controlled by the single control plate 80, and a compact structure can be maintained.
Specifically, the function of preventing the end lock due to the malfunction of the lock dock 20 itself is performed by the cam pin 21 of the lock dock 20, the cancel cap 90 having the lock member projection 91, and the fourth cam 89 of the control plate 80. be able to.

  Further, since the WS lever 50 and the ALR lever 60 are respectively engaged with the internal teeth 108 of the bearing cover 100, the positions where the two levers 50 and 60 are engaged are shared, the number of parts is reduced, and the retractor is mounted. It can be downsized.

  The control plate 80 is rotated at a speed higher than the rotation of the spindle 1 by the gear speed increasing mechanism having the drive gear 6, the driven gear 81, and the idle gear 7, so that the webbing is wound up and pulled out. Further, the swing control of the WS lever 50 and the ALR lever 60 and the movement control of the cancel cap 90 can be easily performed. Specifically, since the speed of the control plate 80 is increased so as to rotate by one tooth with respect to one rotation of the spindle 1, the WS lever 50 and the ALR lever 60 can be swung in A schedule for moving the cancel cap 90 can be created.

  In addition, this invention is not limited to embodiment mentioned above, A deformation | transformation, improvement, etc. are possible suitably.

  The control plate of the present invention may be rotated at a different number of rotations according to the rotation of the spindle, may be a speed-increasing rotation as in the present embodiment, or a rib-shaped cam of the control plate is appropriately designed. By doing so, it may be decelerated.

  In addition, the control plate of the present invention controls the swing of the WS lever and the ALR lever and the movement control of the cancel cap by the rib. However, these controls are performed by forming a cam groove in the control plate. Also good.

  Furthermore, each cam of the control plate of the present invention can exhibit the function of each cam described above, and can have the shape of this embodiment as long as it does not unnecessarily interfere with the swinging and movement of each protrusion. It is not limited.

DESCRIPTION OF SYMBOLS 1 Spindle 2 Spring type winding device 6 Drive gear 7 Idle gear 10 Frame 20 Lock dock (lock member)
30 Ratchet wheel (latch member)
40 Steering wheel 50 WS lever (first locking means)
53 WS protrusion 60 ALR lever (second locking means)
62 Cam pin (projection for ALR)
70 Inertial body 80 Control plate 81 Driven gear 86 First cam (WS cam)
87 Second cam (cam for ALR)
88 3rd cam (cam for ALR)
89 Fourth cam (cam for locking member)
90 Cancel cap (cancellation member)
91 Locking member projection 110 Car body acceleration sensing means 120 VS sensor lever

Claims (7)

A spindle that is rotatably supported by the frame and on which the webbing is wound,
A locking member that locks rotation of the spindle in the webbing pull-out direction by engaging with the frame;
A steering wheel that is rotatably supported by the spindle and that operates the lock member by causing a rotation delay with respect to the spindle;
First locking means pivotally supported on the steering wheel is provided, and when the webbing is pulled out at a predetermined speed or more, the first locking means is displaced to the first operating position. Webbing acceleration sensing means for preventing rotation of the steering wheel in the webbing pull-out direction;
A second locking means pivotally supported by the steering wheel, wherein the second webbing is retracted from the first predetermined amount until the second predetermined amount is wound. An automatic locking mechanism that displaces the locking means to the second operating position and prevents rotation of the steering wheel in the webbing pull-out direction;
A control plate that rotates at a different speed from the spindle according to the rotation of the spindle;
With
The first locking means is controlled by the control plate so as to be held at a first non-operating position where rotation of the steering wheel in the webbing pull-out direction is not blocked when the winding of the webbing is completed,
The second locking means is held by the control plate at the second operating position from when the webbing is pulled out by the first predetermined amount until it is wound up by the second predetermined amount. A retractor for a seat belt, which is controlled.   The retractor for a seat belt according to claim 1, wherein the lock member is controlled by the control plate so as not to be engaged with the frame when the winding of the webbing is completed.   An inner peripheral surface of the cover member attached to the frame has an inner surface engageable with the first locking means in the first operating position and the second locking means in the second operating position. The retractor for a seat belt according to claim 1 or 2, wherein teeth are formed. A gear speedup having a drive gear that rotates integrally with the spindle, a driven gear that rotates integrally with the control plate and has fewer teeth than the drive gear, and an idle gear that meshes with both the drive and the driven gear. Further comprising a mechanism,
The seatbelt retractor according to any one of claims 1 to 3, wherein the control plate rotates at a speed higher than the rotation of the spindle by the gear speed increasing mechanism. The webbing acceleration sensing means is supported at one end by the steering wheel and at the other end by the first locking means, with the first locking means facing the first inoperative position. Further comprising a biasing means for WS
The first locking means has a WS protrusion extending in the axial direction toward the control plate,
The control plate has a WS cam for controlling the first locking means to be held in the first inoperative position by contacting the WS protrusion when the webbing is completely wound. The retractor for seatbelts according to any one of claims 1 to 4. The automatic locking mechanism further includes ALR biasing means having one end supported by the steering wheel and the other end supported by the second locking means,
The second locking means has an ALR projection extending in the axial direction toward the control plate,
The control plate abuts against the ALR projection when the webbing is pulled out by a first predetermined amount, and causes the second locking means to exceed the dead point of the ALR biasing means. When the webbing is wound up by a second predetermined amount, the second locking means is moved beyond the dead point of the ALR biasing means when the webbing is wound up by the second predetermined amount. The seatbelt retractor according to any one of claims 1 to 5, further comprising an ALR cam that snaps to a second non-actuated position where rotation of the steering wheel in the webbing pull-out direction is not prevented. The lock member is provided with a pin portion that penetrates a cam hole formed in the steering wheel,
A cancel member having a projection for a lock member extending in the axial direction toward the control plate is positioned and fixed to the pin portion penetrating the cam hole,
The control plate includes a lock member cam that controls the lock member so that the lock member cannot be engaged with the frame by contacting the lock member protrusion when the webbing is completely wound. The retractor for seatbelts in any one of Claim 2 to 6.

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