JP2006159982A - Seat belt retractor - Google Patents

Abstract

<P>PROBLEM TO BE SOLVED: To carry out shock absorbing action while preventing the influence of pretensioner structure as much as possible. <P>SOLUTION: A take-up drum 20 is rotatably supported, and a torsion bar 50 is loosely inserted in the take-up drum 20. One end portion of the torsion bar 50 is coupled to one end portion of the take-up drum 20, and the other end portion of the torsion bar 50 is coupled to a motor type second pretensioner mechanism 100 and an emergency locking action mechanism 30. After the action of the second pretensioner mechanism 100, while the emergency locking action mechanism 30 prevents rotations of the other end portion of the torsion bar 50, the torsion bar 50 is torsionally deformed and the take-up drum 20 rotates in a webbing pay-out direction, thereby shock is absorbed. <P>COPYRIGHT: (C)2006,JPO&NCIPI

Description

  The present invention relates to a seat belt retractor for removing slack of webbing in an emergency such as a vehicle collision.

  As this type of seat belt retractor, there is one disclosed in Patent Document 1.

  In the retractor disclosed in Patent Document 1, a pretensioner is provided on one end side of the winding shaft. In the pretensioner, gas is generated by ignition in an emergency, and this gas is guided into the cylinder to drive the piston. At this time, by engaging the piston with one end of the take-up shaft, the take-up shaft is rotated to remove the slack of the seat belt.

  In addition, after the seat belt is retracted, the seat belt is gradually fed out by reversing the retracting shaft to reduce the impact on the occupant (impact absorbing operation).

JP-A-10-67300

  However, in the retractor disclosed in Patent Document 1, the piston on the pretensioner side remains engaged with one end of the winding shaft even during the impact absorbing operation. In this state, when the webbing is pulled out with a force exceeding a predetermined value, the winding shaft is rotated in the webbing pulling-out direction, and the engaged piston tries to return to the initial position. At this time, a resistance for driving the mechanism of the pretensioner is generated. Further, when the piston returns to the initial position, gas remains in the cylinder and hinders the movement of the piston. Further, a gas venting means for discharging the gas is also required. For this reason, it is necessary to consider the influence of the pretensioner when designing the shock absorbing mechanism.

  Therefore, an object of the present invention is to provide a technique capable of performing an impact absorbing operation while preventing the influence of a pretensioner mechanism as much as possible.

  A first aspect of the present invention is a seat belt retractor that winds up a webbing so as to remove slack in an emergency, and further gradually unwinds the webbing so as to reduce an impact applied to an occupant. A housing having a portion, a winding drum that is rotatably supported between the pair of side portions in a state where the webbing is wound, and is biased in the winding direction of the webbing, and a lock that is activated in the event of an emergency of the vehicle An activation mechanism, a lock operation mechanism that performs a locking operation that prevents the winding drum from rotating in the webbing pull-out direction in the event of an emergency of the vehicle by the activation of the lock activation mechanism, and a drum fixing portion that is fixed to the winding drum And a rotation inhibiting end portion that is coupled to the locking mechanism so as not to rotate relative to the locking mechanism and is prevented from rotating by the locking operation of the locking mechanism, The webbing is pulled out in a state in which the rotation of the rotation suppression end is suppressed, and an impact absorption mechanism that performs an impact absorption operation, and the motor unit is driven in the event of a vehicle emergency to drive the rotation suppression end of the lock mechanism. And a pretensioner mechanism that rotates the winding drum in the webbing winding direction through a portion that is coupled to the portion so as not to be relatively rotatable.

  In this case, the shock absorbing mechanism is inserted into the take-up drum, a drum fixing portion at one end thereof is coupled to the one end portion side of the take-up drum so as not to be relatively rotatable, and rotation prevention at the other end portion. It may be a torsion bar whose end is coupled to the lock mechanism in a relatively non-rotatable manner.

  According to the seatbelt retractor of the present invention, the pretensioner mechanism is a portion that is coupled to the rotation inhibiting end portion of the lock mechanism so as not to rotate relative to the lock mechanism by driving the motor portion in the event of a vehicle emergency. The webbing is taken up by rotating the take-up drum in the webbing take-up direction. Then, after winding the webbing, the webbing is pulled out in a state where the rotation of the rotation inhibition end is inhibited, thereby performing an impact absorbing operation. For this reason, it is possible to perform the impact absorbing operation while preventing the influence of the pretensioner mechanism as much as possible.

  The shock absorbing mechanism is inserted into the winding drum, a drum fixing portion at one end thereof is coupled to the one end portion side of the winding drum so as not to be relatively rotatable, and the other end portion is connected to the lock mechanism. When the torsion bar is coupled so as not to be relatively rotatable, the torsion bar itself is torsionally deformed to absorb an impact.

<Description of overall configuration>
Hereinafter, a seat belt retractor according to an embodiment of the present invention will be described.

  FIG. 1 is an exploded perspective view showing the overall configuration of the retractor, and FIG. 2 is a cross-sectional view showing the overall configuration of the retractor. For convenience of explanation, some components are omitted in FIG.

  This retractor is applied to a seat belt device provided in a seat of a vehicle or the like, and normally accommodates a webbing as a seat belt so that it can be pulled out. In the event of an emergency such as a vehicle collision, the webbing is wound up so as to remove slack in order to effectively restrain the occupant, and then the webbing is gradually extended so as to alleviate the impact applied to the occupant. Yes.

  The retractor in the present embodiment includes a housing 10, a winding drum 20, an emergency lock operation mechanism 30, a torsion bar 50 as an impact absorbing mechanism, a first pretensioner mechanism 60 using gas pressure, and a motor. And a second pretensioner mechanism 100 utilizing the above. Here, the first pretensioner mechanism 60 is provided on one end side of the winding drum 20, and the emergency lock operation mechanism 30 and the second pretensioner mechanism 100 are provided on the other end side of the winding drum 20. Yes. Hereinafter, each component will be described.

<Description of each component>
<Description of winding drum, shock absorbing mechanism and housing>
As shown in FIG.1 and FIG.2, the winding drum 20 is comprised so that webbing can be wound. More specifically, the take-up drum 20 is made of an aluminum material or the like, and is formed so as to protrude in a radial direction at a substantially cylindrical drum main body 21 and at both axial ends of the drum main body 21. Flange portions 22a and 22b. And webbing is wound by the drum main-body part 21 between the both flange parts 22a and 22b.

  Further, a shaft hole portion 22h is formed along the central axis of the winding drum 20, and one flange portion 22a side (left side in FIG. 2) of the shaft hole portion 22h is a coupling hole portion. 22 ha. A joined body 28 made of steel or the like is joined to the joining hole 22ha by press-fitting or the like so as not to rotate relative to the winding drum 20 (see FIG. 2).

  Further, a torsion bar 50 is inserted into the shaft hole portion 22h. The inner diameter of the shaft hole portion 22h is larger than the outer diameter of the torsion bar 50. Therefore, the torsion bar 50 can freely rotate in the shaft hole portion 22h except for a portion fixed to the winding drum 20. It has become.

  One end portion (drum fixing portion) of the torsion bar 50 is coupled to the coupling body 28 so as not to be relatively rotatable by spline coupling or the like. Thereby, the one end part (left end part of FIG. 2) of the torsion bar 50 and the one end part (left end part of FIG. 2) of the winding drum 20 are coupled so as not to be relatively rotatable.

  The other end portion (rotation suppression end portion) of the torsion bar 50 is connected to an emergency lock operation mechanism 30 described later. In an emergency, rotation of the other end portion of the torsion bar 50 is suppressed by the locking operation of the emergency locking mechanism 30. In this state, when the load acting on the webbing exceeds a predetermined value set in advance, the winding drum 20 rotates in the webbing drawing direction while twisting the torsion bar 50. As described above, the torsion bar 50 is twisted and deformed, and the webbing is pulled out to absorb impact energy generated in the occupant.

  In addition, as a mechanism for absorbing shocks, various configurations using various deformations, frictional forces, elastic forces, and the like can be employed in addition to those performing the shock absorbing operation by torsional deformation as described above.

  The take-up drum 20 is supported so as to be rotatable with respect to the housing 10. The housing 10 has a substantially U shape in a plan view including a pair of side plate portions 11a and 11b arranged opposite to each other and a back plate portion 14 connecting one side edge portions of the side plate portions 11a and 11b. It is configured. The winding drum 20 is rotatably supported between the side plate portions 11a and 11b.

  Specifically, the coupling body 28 connected and fixed to one end portion of the winding drum 20 passes through a through hole 11ah formed in one side plate portion 11a and is rotatably supported by the first pretensioner mechanism 60 or the like. Has been. Further, at the other end of the winding drum 20, the other end of the torsion bar 50 is coupled to the lock mechanism 31 so as not to be relatively rotatable, and the lock mechanism 31 is inserted into a through hole 11bh formed in the other side plate portion 11b. It is penetrated and supported rotatably.

  In addition, a first pretensioner mechanism 60 is attached to the outer surface side of one side plate portion 11a of the housing 10, and the take-up drum 20 is biased in the take-up direction outside the first pretensioner mechanism 60. Winding mechanism 16 is provided.

  Here, the winding mechanism 16 includes a winding attachment urging mechanism 18 including a spiral spring and a spring case 17 that accommodates the winding attachment urging mechanism 18. Then, the front end portion of the coupling body 28 that passes through the side plate portion 11b and the first pretensioner mechanism 60 and projects outward is coupled to the spiral spring in the spring case 17, and is wound by the urging force of the spiral spring. The take-up drum 20 is constantly rotated in the webbing take-up direction.

<Description of first pretensioner mechanism>
FIG. 3 is an exploded perspective view showing the first pretensioner mechanism. As shown in FIGS. 1 to 3, the first pretensioner mechanism 60 operates the gas generator in an emergency of the vehicle, and uses the pressure of the gas to take up the winding drum 20 via one end of the torsion bar 50. Is a mechanism for rotating the webbing in the webbing take-up direction. Here, the first pretensioner mechanism 60 meshes with the rack 70, the gas generator 61, the cylinder 62, the rack 70 that moves in the cylinder 62 under the gas pressure of the gas generator 61, and the rack 70. And a pinion gear body 75 that rotates in conjunction with the winding drum 20 and a cover body 78 that forms a movement guide path for the rack 70.

  The gas generation unit 61 includes explosives, and is configured to generate gas by igniting and exploding the explosives according to an ignition signal from a control unit (not shown).

  The cylinder part 62 has a configuration in which the gas generating part 61 is attached to one end (lower end) thereof, and one side part of the other end part (upper end part) is attached to the outside of one side plate part 11 a of the housing 10. Has been.

  Specifically, the cylinder part 62 is formed of a zinc alloy material or the like, and is formed in a substantially L-shaped member having a cylinder main body part 63 and a housing cylinder part 64. Then, in a state where the gas generating part 61 is accommodated in the accommodating cylinder part 64, the gas generating part 61 is accommodated in the accommodating cylinder part 64 by screwing and fastening the screw cap 64 a to the opening end side of the accommodating cylinder part 64. Will be installed inside. The internal space of the accommodating cylinder portion 64 and the internal space of the cylinder portion 62 are in communication with each other, and the gas generated in the gas generating portion 61 is configured to flow into the cylinder main body portion 63.

  Further, attachment pieces 63p having screw holes are formed on both sides of the cylinder body 63. Then, the cylinder body 63 is attached to the side plate 11a via the attachment pieces 63p so as to be along the outer surface of the one side plate 11a.

  The rack 70 has a long overall shape, and a piston portion 71 is provided on the base end side (lower end side) thereof. The piston part 71 is formed in a substantially short cylindrical shape that can be inserted into the cylinder body part 63. Then, in a state where the piston portion 71 is press-fitted in the cylinder body portion 63, the gas generated in the gas generation portion 61 flows into the cylinder body portion 63 so that the pressure of the gas presses the piston portion 71. Then, the cylinder body 63 is moved to the open end side (upper end side).

  A rack body 72 having a substantially elongated plate shape is formed at the tip of the rack 70, and rack teeth 72 a that mesh with the pinion gear portion 76 are formed on one side of the rack body 72. In a normal state until the gas generating unit 61 explodes, the rack main body 72 is retracted to the inner side of the cylinder main body 63 and is not engaged with the pinion gear 76. The rack body 72 protrudes from the open end side of the cylinder body 63 due to the pressure of the gas generated in the gas generator 61, and the rack teeth 72a mesh with the pinion gear 76, thereby moving the pinion gear body 75 in a predetermined direction. It is configured to rotate (see FIG. 5).

  The pinion gear body 75 is formed of a steel material or the like, and includes a pinion gear portion 76 that meshes with the rack teeth 72a.

  The pinion gear body 75 is held so as to be able to rotate in conjunction with the winding drum 20.

  Specifically, the pinion gear body 75 can rotate in conjunction with the take-up drum 20 by a clutch mechanism including a clutch support base 80, a plurality of clutch rollers 81, and a clutch ring portion 77. The clutch mechanism connects the pinion gear body 75 and the take-up drum 20 so as to be capable of interlocking rotation when the first pretensioner mechanism 60 is operated, and at other times, the take-up drum is connected to the pinion gear body 75. It has a function to make 20 freely rotatable. Here, the clutch mechanism has a one-way clutch function.

  That is, the clutch support base 80 is formed of resin or the like, and is attached to the outer surface side of the side plate portion 11a. The clutch support base 80 holds a pinion gear body 75 so as to be positioned on the axial extension of the winding drum 20. Further, a coupling body 28 coupled to one end of the torsion bar 50 so as not to rotate relative to the torsion bar 50 is disposed so as to pass through the center portion of the pinion gear body 75 from the clutch support base 80 (see FIG. 2).

Each clutch roller 81 is formed of a steel material or the like into a substantially cylindrical member. A plurality of clutch rollers 81 are held on the clutch support base 80 on the radially outer side of the combined body 28. FIG. 4 is a diagram illustrating a positional relationship among the clutch ring portion, the engagement cylinder portion, and each clutch roller. That is, a clutch ring portion 77 is formed on one side portion of the pinion gear body 75. The inner peripheral surface of the clutch ring portion 77 is formed on a cam surface 77a whose distance from the center changes sequentially.

  In the initial state, each clutch roller 81 is held by the clutch support base 80 at a portion of the cam surface 77 a that is far from the central axis, and each clutch roller 81 is separated from the outer peripheral surface of the combined body 28. It is in a state. Therefore, when the webbing is pulled out and wound in the normal state (non-emergency state), the combined body 28 is relatively rotatable inside each clutch roller 81. Thereby, interference with the pinion gear body 75 and the winding drum 20 in a normal state is prevented.

  On the other hand, when the gas generator 61 is activated in an emergency, the rack 70 is moved, and the pinion gear body 75 is rotated in the direction of the arrow A, each clutch roller 81 is pushed radially inward by the cam surface 77a. Is operated. Thereafter, the clutch rollers 81 are engaged between the cam surface 77a and the outer peripheral surface of the coupling body 28, and the pinion gear body 75 and the coupling body 28 are configured to rotate integrally.

  As shown in FIGS. 1 to 3, the cover body 78 is disposed on the extension of the other end portion (upper end portion) of the cylinder portion 62, and guides movement of the rack 70 that protrudes from the other end portion of the cylinder portion 62. Forming a road.

  Specifically, the cover body 78 is formed of a steel material or the like, and includes a rack cover portion 78 a that covers the moving path of the rack 70 that protrudes from the other end of the cylinder portion 62, and a pinion gear cover portion that covers the pinion gear body 75. 78b.

  The pinion gear cover portion 78 b is configured to cover the outer peripheral side of the pinion gear body 75 held by the clutch support base 80. The rack cover portion 78a is connected to the tip end portion of the pinion gear cover portion 78b, and forms a movement guide path for the rack body portion 72 so as to extend on the other end side extension of the cylinder portion 62.

  In the inner space of the cover body 78, the rack body 72 moves on the movement guide path in the rack cover 78a while the rack teeth 72a of the rack body 72 are engaged with the pinion gear 76 of the pinion gear body 75. It has become.

  The cover body 78 is attached to the outer surface side of the side plate portion 11a together with the clutch support base 80 and the cylinder portion 62 by screws or the like.

  In the first pretensioner mechanism 60, the rack teeth 72a of the rack 70 and the pinion gear body 75 are in a non-engagement state during normal winding / drawing operation (when the first pretensioner mechanism 60 is not operated), and The take-up drum 20 is rotatable with respect to the pinion gear body 75.

  In an emergency such as a vehicle collision, the gas generation unit 61 is ignited by an ignition signal from a control unit (not shown), and the high-temperature and high-pressure gas generated by the explosive of the explosive inside the cylinder unit 62 instantaneously. To charge. With this gas pressure, the rack 70 is pressed in the direction of the arrow Q as shown in FIG. As the rack 70 moves in the arrow Q direction, the rack teeth 72a mesh with the pinion gear portion 76, and the pinion gear portion 76 is rotationally driven in the arrow P direction. Along with this, the pinion gear body 75 rotates, and with this rotation, the coupling body 28 rotates in conjunction with each other through the clutch rollers 81, and the winding drum 20 rotates in the winding direction to remove the slack of the webbing.

  Then, as shown in FIG. 6, the rack teeth 72 a move in a direction protruding from the one end side opening of the cylinder portion 62 while meshing the rack teeth 72 a with the pinion gear portion 76. Eventually, the rack 70 moves to a position where the end teeth of the rack teeth 72a of the rack 70 mesh with the pinion gear body 75, rotate the pinion gear body 75, rotate the winding drum 20 in the webbing winding direction, and loosen. Remove.

<Description of second pretensioner mechanism>
FIG. 7 is an exploded perspective view showing a second pretensioner mechanism, FIG. 8 is an exploded perspective view showing a clutch wheel in the second pretensioner mechanism, and FIG. 9 is an explanatory view showing an internal configuration of the clutch wheel. .

  As shown in FIGS. 1, 2, and 7 to 9, the second pretensioner mechanism 100 is provided on the other end side of the winding drum 20. Here, the 2nd pretensioner mechanism 100 is attached to the inner surface side of the side plate part 11b of the other side so that it may be located in the other end side of the winding drum 20. The second pretensioner mechanism 100 drives the motor 110 in an emergency of the vehicle to rotate the winding drum 20 in the webbing winding direction via the other end portion (rotation suppression end portion) of the torsion bar 50. Here, the second pretensioner mechanism 100 includes a motor 110 and a clutch wheel 120.

  The motor 110 is an electric motor, and is driven to rotate at a predetermined timing under the control of a control unit (not shown). For example, when the vehicle collision is predicted based on the operation state of the acceleration sensor or the brake, the control unit drives the motor 110 to rotate.

  A small gear 113 is fixed to the motor shaft 112 of the motor 110. The motor 110 is accommodated in the motor cover 118 with the small gear 113 protruding outside.

  The clutch wheel 120 is configured to establish or separate a power transmission path between the motor 110 and the winding drum 20 at a predetermined timing. That is, the clutch wheel 120 establishes a power transmission path between the motor 110 and the winding drum 20 when the motor 110 rotates in the first direction (the direction in which the winding drum 20 is rotated in the winding direction). . On the other hand, when the motor 110 rotates in the second direction opposite to the first direction, the power transmission path between the motor 110 and the winding drum 20 is disconnected.

  More specifically, the clutch wheel 120 has a substantially disk-like overall shape, and gear teeth 124a are formed on the outer periphery thereof. The clutch wheel 120 is housed rotatably in the clutch cover 102. The motor 110 is attached to the outer surface of the clutch cover 102 so that the small gear 113 is disposed in the clutch cover 102. A relay gear 106 is rotatably disposed in the clutch cover 102 so as to be interposed between the small gear 113 and the clutch wheel 120. The rotational driving force of the motor 110 is transmitted from the small gear 113 to the clutch wheel 120 via the relay gear 106, and in conjunction with the rotation of the motor 110 in the forward or reverse direction, The wheel 120 is configured to rotate in the forward or reverse direction.

  As shown in FIGS. 1, 8, and 9, the clutch wheel 120 includes a base member 122, a gear member 124, a ratchet gear portion 126, and a pawl member 128.

  The gear member 124 is formed in a substantially annular member, and gear teeth 124a are formed on the outer periphery thereof. In addition, a plurality of rotation suppression convex portions 124b are continuously formed on the inner peripheral portion of the gear member 124 along the circumferential direction.

  The base member 122 is formed in a substantially circular plate shape, and a substantially annular surrounding wall portion 123 projects from an outer peripheral side portion of one surface thereof. The gear member 124 is disposed on the outer peripheral side of the surrounding wall portion 123 with a gap. A plurality of spring fixing portions 123 a are formed on the outer periphery of the surrounding wall portion 123. Each spring piece 125 is fixed to the spring fixing portion 123a in a state in which one end portion of each spring piece 125 is engaged with the rotation restraining convex portion 124b while being spring-biased. Thereby, the base member 122 and the gear member 124 are coupled via the spring piece 125 so as to be integrally rotatable. Further, when a large relative rotational force is applied so that each spring piece 125 elastically deforms and can sequentially get over each rotation restraining convex portion 124b, the base member 122 and the gear member 124 rotate relative to each other. Thereby, for example, when an excessive force is applied to the webbing while the webbing is being wound by the rotation of the motor 110, the power transmission path between the motor 110 and the winding drum 20 is cut off.

  In addition, a ratchet gear portion 126 is rotatably disposed at the center portion of the base member 122. The pawl member 128 is detachably provided on the ratchet gear portion 126. Here, a ratchet gear portion 126 is disposed on the one side of the base member 122 and in the central portion surrounded by the surrounding wall portion 123. In addition, a pair of pawl members 128 are swingably disposed at the position where the ratchet gear portion 126 is interposed via a support shaft portion.

  In addition, the opening part of the surrounding wall part 123 is covered with the cover plate 122b on a substantially disc.

  An outer fitting shaft portion 32c, which will be described later, is inserted and coupled to the ratchet gear portion 126 so as not to be relatively rotatable. The ratchet gear portion 126 rotates integrally with the winding drum 20 via the outer fitting shaft portion 32c and the torsion bar 50. It is configured as follows. Further, ratchet teeth 126 a are formed on the outer periphery of the ratchet gear portion 126.

  Each pawl member 128 is swingably supported by the base member 122 and rotates around its rotation axis together with the base member 122. Each pawl member 128 is supported so as to be swingable between a posture capable of engaging with the ratchet gear portion 126 and a posture capable of releasing the engagement. Here, the pawl member 128 has a pawl claw 128a that can be engaged with and disengaged from the ratchet teeth 126a. The pawl claw 128a reciprocates along the radial direction of the base member 122 to the inner and outer peripheries. It is supported freely. Then, by moving the pawl claw 128a to the inner peripheral side, the pawl claw 128a engages with the ratchet teeth 126a, and the base member 122 and the ratchet gear portion 126 rotate integrally. On the other hand, by moving the pawl claw 128 a to the outer peripheral side, the engagement between the pawl claw 128 a and the ratchet teeth 126 a is released, and the ratchet gear portion 126 is freely rotated with respect to the base member 122.

  A bearing member 138 is interposed between the base member 122 and the ratchet gear portion 126. Thereby, the ratchet gear part 126 rotates more smoothly with respect to the base member 122.

  Each pawl member 128 is constantly urged in a direction to release the engagement with the ratchet gear portion 126 by a torsion coil spring 129 which is a release direction urging means. Thus, the engagement is more reliably released when the motor 110 described later is not rotating.

  The posture of each of the pawl members 128 is changed by a pawl guide 130 which is a pawl posture changing means.

  The pawl guide 130 is formed in a substantially disc shape, and a sliding contact tube portion 131 into which the outer fitting shaft portion 32c can be loosely inserted is formed at the center portion, and the posture of the pawl member 128 is changed at the outer peripheral portion. For this purpose, a pushing piece 132 is formed.

  The push piece 132 is disposed in the front and rear positions of each pawl member 128 within the surrounding wall portion 123. Then, when the base member 122 and the pawl guide 130 rotate relative to each other, the push piece 132 comes into contact with the pawl member 128 and swings it. In FIG. 9, the base member 122 and the pawl member 128 are rotated in the direction of the arrow R with respect to the pushing piece 132, so that the pushing piece 132 contacts the pawl member 128 and the pawl claw 128a is moved to the ratchet teeth 126a. Move to the side. As a result, the pawl member 128 and the ratchet gear portion 126 are engaged with each other. On the other hand, by rotating the base member 122 and the pawl member 128 in the arrow S direction with respect to the push piece 132, the push piece 132 comes into contact with the pawl member 128 from the opposite side to the pawl claw 128a. Is moved away from the ratchet teeth 126a. Thereby, the meshing between the pawl member 128 and the ratchet gear portion 126 is released.

  The pawl guide 130 is rotatably supported with respect to the clutch cover 102 in a state where the rotation is suppressed by a predetermined frictional force. That is, the sliding contact cylinder portion 131 of the pawl guide 130 is externally fitted to the support cylinder portion 102 a protruding from the inner peripheral side of the clutch cover 102. In addition, a substantially annular spring material 133 is fitted on the outer periphery of the sliding contact cylinder portion 131. The elastic force of the spring member 133 urges the sliding contact tube portion 131 so that the diameter of the sliding contact tube portion 131 is reduced, and the inner peripheral portion of the sliding contact tube portion 131 contacts the outer peripheral portion of the support tube portion 102a with a predetermined friction force. is doing.

  And in the normal rotation state of the winding drum 20, the pawl guide 130 has stopped rotating. When the clutch wheel 120 is rotated by the rotation of the motor 110, the base member 122 initially rotates relative to the pawl guide 130 (see arrow R in FIG. 9). By the relative rotation of the clutch wheel 120 with respect to the pawl guide 130, the pawl guide 130 changes the posture of each pawl member 128 and engages the ratchet gear portion 126. Thereafter, when the rotational drive of the motor 110 continues, the pawl guide 130 rotates together with the ratchet gear portion 126 and the base member 122 while bringing the sliding contact tube portion 131 into frictional contact with the support tube portion 102a.

  From this state, when the motor 110 rotates in the reverse direction, the base member 122 rotates relative to the pawl guide 130 in the reverse direction while stopping the rotation of the pawl guide 130 (see arrow S in FIG. 9). Then, the reverse rotation of the base member 122 and the pawl member 128 with respect to the pawl guide 130 causes the pawl guide 130 to change the posture of the pawl member 128 and release the engagement with the ratchet gear portion 126. Thereafter, the rotation of the motor 110 stops.

  In the second pretensioner mechanism 100, the ratchet gear portion 126 and the pawl member 128 are in a disengaged state during normal winding / drawing operation (when the second pretensioner mechanism 100 is not operated). The take-up drum 20 is rotatable relative to the base member 122 and the like.

  When a vehicle collision is predicted, the motor 110 is rotationally driven in a predetermined forward rotation direction under the control of a control unit (not shown). The rotational driving force of the motor 110 is transmitted to the clutch wheel 120 so that the clutch wheel 120 rotates.

  When the clutch wheel 120 rotates relative to the pawl guide 130, the pawl guide 130 swings the pawl member 128. As a result, the pawl member 128 engages with the ratchet gear portion 126, and the base member 122 and the ratchet gear portion 126 rotate together. The rotational driving force of the motor 110 is transmitted to the winding drum 20 via the clutch wheel 120, and the winding drum 20 rotates in the winding direction in response to the driving force of the motor 110.

  The pawl member 128 is engaged with the ratchet gear portion 126 in one rotational direction. For this reason, in a state where the pawl member 128 and the ratchet gear portion 126 are engaged, the ratchet gear portion 126 is rotatable relative to the pawl member 128 in the arrow R direction (see FIG. 9). Thus, even when the pawl member 128 and the ratchet gear portion 126 are engaged after the operation of the second pretensioner mechanism 100, the winding operation by the first pretensioner mechanism 60 is continuously performed.

  When the motor 110 is rotated in the reverse rotation direction opposite to the predetermined forward rotation direction after completion of the predetermined winding operation, the clutch wheel 120 rotates in the reverse direction. Then, when the clutch wheel 120 rotates in the reverse relative to the pawl guide 130, the pawl guide 130 swings the pawl member 128. Thereby, the engagement between the pawl member 128 and the ratchet gear portion 126 is released, and the ratchet gear portion 126 rotates freely with respect to the base member 122.

  Such a second pretensioner mechanism 100 is characterized in that the webbing take-up operation can be repeated by the rotation control of the motor 110. That is, in the first pretensioner mechanism 60, once the gas generation unit 61 is ignited, it cannot be operated again, whereas in the second pretensioner mechanism 100, the motor 110 is appropriately controlled to rotate. Therefore, there is a feature that the operation can be performed again.

  Therefore, generally, the first pretensioner mechanism 60 operates when it is determined that the vehicle collision is more reliable based on the detection output of the impact detection sensor or the like, and the second pretensioner mechanism 100 is It operates when a vehicle collision is predicted based on detection outputs from an acceleration sensor, a brake sensor, a speed sensor, and the like.

<Description of emergency locking mechanism>
The emergency lock operation mechanism 30 is configured to perform a lock operation that prevents the winding drum 20 from rotating in the webbing pull-out direction in the event of a vehicle emergency.

  Here, the emergency lock operation mechanism 30 includes a lock mechanism 31, a first lock activation mechanism 40, and a second lock activation mechanism 45. The emergency lock operation mechanism 30 is accommodated in a cover body 85 attached to the outer surface of the side plate portion 11b.

  FIG. 10 is an exploded perspective view showing the lock mechanism, and FIG. 11 is a view showing an outer end face of the lock mechanism.

  As shown in FIGS. 1, 2, 10, and 11, the lock mechanism 31 is a mechanism that prevents the winding drum 20 from rotating. Here, the lock mechanism 31 is connected to the other end of the torsion bar 50 so as not to be relatively rotatable. A lock base 32 and a pawl 35 are provided.

  The lock base 32 includes a lock base main body 32a formed of an aluminum material and the like, and a resin holding plate 32b attached to one side of the lock base main body 32a. The lock base 32 holds a pawl 35 made of a steel material or the like so that the pawl 35 can protrude and retract from the outer peripheral surface of the lock base 32.

  Further, an external fitting shaft portion 32c projects from one side surface of the lock base main body 32a. The external fitting shaft portion 32c passes through the pinion gear body 75 and the cover body 78 and the second pretensioner mechanism 100, and is loosely inserted into the other end side of the shaft hole portion 22h of the winding drum 20. And this external fitting shaft part 32c is externally fitted to the other end part of the torsion bar 50 so that relative rotation is impossible. In the state where the outer fitting shaft portion 32c is inserted inside the other end side of the shaft hole portion 22h, the circumferential engagement groove 32d formed on the outer peripheral surface of the outer fitting shaft portion 32c is inserted into the winding drum 20. The attached retaining stopper 90 is locked, and the outer fitting shaft portion 32c is retained.

  The lock mechanism 31 is disposed in a through hole 11bh formed in the side plate portion 11b. Here, the through-hole 11bh is formed with a lock tooth 11ba on which the pawl 35 is detachably engaged over the entire circumference in the circumferential direction. The pawl 35 and the lock teeth 11ba are configured to mesh with each other so as to prevent rotation in the winding drum 20 webbing pull-out direction and allow rotation in the winding direction. The pawl 35 protrudes from the outer peripheral surface of the lock base 32 in response to the activation operation of the first lock activation mechanism 40 or the second lock activation mechanism 45 described below. Accordingly, the pawl 35 and the lock teeth 11ba are engaged with each other, and the rotation of the winding drum 20 in the webbing pull-out direction is prevented.

  Further, a disk-shaped lock clutch body 36 is supported on the outer surface side of the lock base 32 so as to be relatively rotatable. As shown in FIGS. 12 and 13, a cylindrical ratchet wheel portion 37 having a ratchet 37 a formed on the outer peripheral surface is integrally formed on the outer peripheral portion of the lock clutch body 36.

  Further, a spring receiving portion 38 projects from one side surface of the lock clutch body 36, and the spring receiving portion 38 is free to move relative to a recessed groove-shaped spring accommodating portion 32f formed in the lock base body 32a. It is fitted (see FIG. 11). At this time, the spring receiving portion 38 is elastically biased in a predetermined direction by the return spring 34 made of a coil spring housed and held in the spring housing portion 32f, and the lock clutch body 36 is pulled out of the webbing relative to the lock base 32. It is configured to rotate synchronously with the lock base 32 in a state where it is biased to.

  Further, the lock clutch body 36 is formed with a protruding guide groove 36d in which an interlocking pin 35a protruding from the pawl 35 is slidably guided. Then, the lock base 32 and the lock clutch body 36 rotate relative to the urging force of the return spring 34, whereby the interlocking pin 35a is slidably guided along the protruding guide groove 36d. By this sliding guide, the pawl 35 protrudes from the outer peripheral surface of the lock base 32 so as to protrude and retract.

  Here, in a state where the rotation of the lock clutch body 36 is stopped by the first lock activation mechanism 40 or the second lock activation mechanism 45, the lock base 32 and the lock clutch are rotated by rotating the lock base 32 by the pulling output of the webbing. The body 36 rotates relative to the body 36. Then, the pawl 35 protrudes by this relative rotation and performs a predetermined locking operation.

  The first lock activation mechanism 40 and the second lock activation mechanism 45 are mechanisms for operating the lock mechanism 31 at a predetermined timing. The first lock activation mechanism 40 is a mechanism that performs an activation operation in response to a rapid change in acceleration of the vehicle, and the second lock activation mechanism 45 is a mechanism that performs an activation operation in response to a rapid pull-out of the webbing. is there.

  FIG. 14 is an exploded perspective view showing the first lock starting mechanism and its built-in portion, and FIG. 15 is a partial cross-sectional view showing the first lock starting mechanism and its built-in portion.

  The first lock starting mechanism 40 is a holder 41 made of a box-shaped resin molded body having a conical concave portion with a gradually open smaller diameter on the bottom surface with the upper surface open, and the first lock starting mechanism 40 placed on the concave portion of the holder 41. A spherical sensor weight 42 made of steel as an inertial mass body that swings in response to acceleration exceeding a predetermined value, and a resin molded body that is rotatably supported at one end by a holder 41 The sensor lever 43 which consists of is provided. The first lock activation mechanism 40 is held at a position below the outer periphery of the lock clutch body 36 in the cover body 85.

  In a state where no acceleration exceeding a predetermined value is generated, the sensor weight 42 maintains the repose posture arranged on the concave portion of the holder 41, and the lock claw 43a protruding from the tip of the sensor lever 43 is provided. And the ratchet 37a are kept separated from each other.

  In this case, the rotation of the lock clutch body 36 is not restricted at all, and therefore the webbing is maintained in a drawable state.

  On the other hand, when a sudden acceleration change in an emergency such as a vehicle collision or sudden braking occurs, the sensor weight 42 swings and moves from the concave portion in response to the acceleration change. As the weight 42 moves, the sensor lever 43 is pushed upward, and the lock claw 43a of the sensor lever 43 moves upward. Then, the lock claw 43a is engaged with the ratchet 37a of the ratchet wheel portion 37, and the rotation of the lock clutch body 36 is stopped. In this state, if a load acts on the webbing in the pull-out direction, the lock base main body 32a rotates integrally with the take-up drum 20 against the biasing force of the return spring 34 in the webbing pull-out direction.

  With the rotation of the lock base body 32a, the interlocking pin 35a of the pawl 35 held by the lock base body 32a slides and moves within the protruding guide groove 36d. Along with this sliding movement, the pawl 35 is projected and moved radially outward from the lock base body 32a, meshes with the lock teeth 11ba formed on the side plate portion 11b, and the subsequent rotation of the lock base body 32a is prevented. The webbing pull-out is stopped, and the lock mechanism 31 is operated here.

  When the sudden acceleration change is released, the sensor weight 42 is returned to the concave portion that is the original rest position of the holder 41 by the gravitational action, and the sensor lever 43 moves downward accordingly. To return to the initial position.

  On the other hand, since the load in the pull-out direction acting on the webbing is also released, the lock base main body 32a is rotated relative to the lock clutch body 36 by the urging force of the return spring 34, and the interlocking pin of the protruding guide groove 36d is thereby rotated 35a is returned to the initial position, where the pawl 35 is returned to the buried state, and the engagement between the pawl 35 and the lock teeth 11ba is released. Then, the webbing is returned to the initial state where the webbing can be pulled out and wound.

  In the emergency lock operation mechanism 30, the lock mechanism 31 is rotated in synchronization with the take-up drum 20, while the start operation can be performed while the first lock start mechanism 40 is disposed at a fixed position. Therefore, the starting operation of the first lock starting mechanism 40 can be stabilized.

  The second lock activation mechanism 45 includes a lock arm 46 that is swingably supported by the lock clutch body 36 at its eccentric position, and a cylindrical engagement inner peripheral wall 86 that is integrally projected on the inner surface side of the cover body 85. It has.

  Inner teeth 86a are formed on the inner peripheral portion of the engagement inner peripheral wall 86 so that the distal end locking portion 46a of the lock arm 46 is detachably engaged.

  Further, the outer diameter of the engagement inner peripheral wall 86 is formed to be slightly smaller than the inner diameter of the ratchet wheel portion 37, and as shown in FIGS. The peripheral wall 86 is configured to be loosely fitted.

  The lock clutch body 36 is provided with a swing stopper 39a for restricting the swing range of the lock arm 46, and a release biasing spring 39b made of a coil spring or the like is provided between the lock clutch body 36 and the base of the lock arm 46. The lock arm 46 is elastically biased in the disengagement direction.

  Normally, when the torsion bar 50 and the lock base 32 rotate with the rotation of the winding drum 20 by pulling out the webbing, the lock clutch body 36 is synchronously rotated under the resilient force of the return spring 34.

  Further, at the time of winding the webbing, when the lock base 32 rotates, the lock clutch body 36 is synchronously rotated by the pushing of the return spring 34.

  On the other hand, when the webbing is suddenly pulled out, the rotation of the lock arm 46 does not follow during the synchronous rotation of the lock clutch body 36, and the inertia in the rearward direction of the rotation against the urging force of the release urging spring 39b. A delay occurs, the lock arm 46 is swung in the engagement direction, and the distal end locking portion 46a protrudes radially outward and engages with the internal teeth 86a of the engagement inner peripheral wall 86, where the lock clutch body 36 Synchronous rotation is prevented.

  When the lock clutch body 36 stops, the interlocking pin 35a slides in the protruding guide groove 36d as the lock base 32 rotates. Along with this sliding movement, the pawl 35 is projected and moved radially outward from the lock base body 32a, meshes with the lock teeth 11ba of the side plate portion 11b, and the rotation of the lock base body 32a thereafter is prevented, and the webbing The drawer is stopped, and the lock mechanism 31 is activated here.

  When the webbing is suddenly released, the lock arm 46 returns to the initial release position by the urging force of the release urging spring 39b, and the engagement state between the tip engagement portion 46a and the internal teeth 86a is released. Is done. Further, the lock clutch body 36 is rotated relative to the lock base 32 by the urging force of the return spring 34, and this rotation returns the interlocking pin 35a in the protruding guide groove 36d to the initial position. And the engagement between the pawl 35 and the lock teeth 11ba is released. Then, the webbing is returned to the initial state where the webbing can be pulled out and wound.

  Further, the radially outer peripheral portion of the engaging inner peripheral wall 86 in the cover body 85 is configured as an inner peripheral wall support portion 87 formed so as to protrude toward the side plate portion 11b to which the cover body 85 is attached over the entire circumference. Yes.

<Operation>
In the seat belt retractor configured as described above, in an emergency in which a vehicle collision is predicted, first, the motor 110 of the second pretensioner mechanism 100 is rotationally driven, and this driving force is transmitted via the clutch wheel 120. It is transmitted to the winding drum 20. Thereby, the winding drum 20 rotates in the winding direction, and the webbing is wound up.

  Thereafter, when a vehicle collision does not actually occur, the motor 110 is driven to rotate in the reverse direction, the power transmission path in the clutch wheel 120 is cut off, and the winding drum 20 is in a state in which it can freely rotate. Return to seat belt wearing condition.

  On the other hand, when a vehicle collision actually occurs, after the operation of the second pretensioner mechanism 100 or depending on the collision mode, the operation of the second pretensioner mechanism 100 is omitted, and the first pretensioner mechanism 60 is Performs winding operation. That is, the gas generator 61 of the first pretensioner mechanism 60 is ignited, the rack 70 moves, and the pinion gear body 75 is rotated. Along with this rotation, the combined body 28 is rotated in an interlocked manner via each clutch roller 81, the winding drum 20 is rotated in the winding direction to remove the slack of the webbing, and the webbing is further wound.

  Then, before or after the operation of the second pretensioner mechanism 100 or the first pretensioner mechanism 60, the emergency lock operation mechanism 30 performs the lock operation by the activation operation of the first lock activation mechanism 40 or the second lock activation mechanism 45. . Thereby, the external fitting shaft portion 32c and the other end portion of the torsion bar 50 are in a state in which the rotation of the webbing in the winding direction is suppressed.

  After the operation of the first and second pretensioner mechanisms 60, 100, a force for pulling out the webbing is applied by the inertial force that pushes the passenger forward with respect to the vehicle. Then, the winding drum 20 rotates in the drawing direction of the webbing while torsionally deforming the torsion bar 50 in a state where the rotation of the other end portion of the torsion bar 50 is suppressed by the emergency lock operation mechanism 30. Thus, the impact energy generated in the occupant is absorbed by pulling out the webbing while torsionally deforming the torsion bar 50.

  According to the seat belt retractor configured as described above, the second pretensioner mechanism 100 rotates the take-up drum 20 in the webbing take-up direction via the other end of the torsion bar 50 in an emergency of the vehicle. . Then, after winding the webbing, in a state where the rotation of the other end of the torsion bar 50 is stopped, the torsion bar 50 is torsionally deformed and the webbing is pulled out to perform an impact absorbing operation. For this reason, the winding drum 20 rotates and performs an impact absorbing operation regardless of being disconnected from the operation of the second pretensioner mechanism 100. Therefore, the impact absorbing operation can be performed while preventing the influence of the second pretensioner mechanism 100.

{Modification}
In the above embodiment, the first pretensioner mechanism 60 that winds the webbing using the gas pressure may be omitted.

  In addition, the first pretensioner mechanism 60 is disposed on the other end side of the take-up drum 20, and, like the second pretensioner mechanism 100, the take-up takes place via the other end portion (rotation suppression end portion) of the torsion bar 50. The drum 20 may be rotated in the webbing take-up direction. Thereby, when performing an impact absorbing operation, the influence of both the first and second pretensioner mechanisms 60 and 100 can be prevented.

  Further, the second pretensioner mechanism 100 may be disposed outside the emergency lock operation mechanism 30.

  Further, the first pretensioner mechanism 60 is omitted and the second pretensioner mechanism 100 is disposed on the other end side of the winding drum 20, or both the first and second pretensioner mechanisms 60 are disposed on the other end side of the winding drum 20. In the form in which the tensioner mechanisms 60 and 100 are disposed, the left and right balances are unbalanced on both ends of the winding drum 20. Therefore, an emergency lock operation mechanism 230 as shown in FIGS. 16 and 17 may be applied.

  In the emergency lock operation mechanism 230, a first large gear 236 is provided in place of the lock clutch body 36, and the first large gear 236 can be engaged with the outer peripheral side of the lock base 232 corresponding to the lock base 32. A second large gear 250 is provided. The second large gear 250 is provided with a lock arm 246 corresponding to the lock arm 46, and an outer peripheral cover portion of the second large gear 250 is engaged with the engagement inner peripheral wall 86. A peripheral wall portion 286 is provided. That is, the second lock starting mechanism 45 is incorporated on the second large gear 250 side.

  The first lock starting mechanism 40 may be incorporated on either side of the first and second large gears.

  In this modified example, the first lock activation mechanism 240 is disposed on the outer peripheral side of the rotation center of the winding drum 20 with respect to the lock mechanism 231 including the lock base 232, so that the emergency lock operation mechanism 230 can be thinned. . Thereby, the right and left balance can be relatively improved on both sides of the winding drum 20.

  In FIG. 16, the first and second pretensioner mechanisms 60 and 100 are omitted, but these may be provided either inside or outside the emergency lock operation mechanism 230.

  Further, in the above embodiment, as shown in FIG. 8, a mechanism that allows relative rotation between the base member 122 and the gear member 124 when a force equal to or greater than a predetermined value is applied to the base member 122 is incorporated. Although the power transmission path with the winding drum 20 is cut off, the mechanism may be omitted as in the modification shown in FIG.

  That is, in this modification, in the base member 122B, the base member 122B corresponding to the base member 122 and the gear member 124B corresponding to the gear member 124 are integrated. Moreover, it is set as the structure which abbreviate | omitted the surrounding wall part 123 in each said embodiment, each spring piece 125, and each rotation suppression convex part 124b.

  The configuration according to this modification performs the same operation as that of the above-described embodiment except that the base member 122B and the gear member 124B always rotate integrally without relative rotation.

  This modification has the following advantages. That is, as a conventional technique, a torque limiter that can cut off the power transmission path from the pretensioner mechanism during the shock absorbing operation is incorporated in order to perform the shock absorbing operation while preventing the influence of the pretensioner mechanism as much as possible. There are some (for example, Unexamined-Japanese-Patent No. 2004-42788). However, in this prior art, it is necessary to incorporate a torque limiter of a precise and complicated mechanism so that the power transmission path from the pretensioner mechanism can be cut off at the time of shock absorption operation. However, in the above-described embodiment, when attention is paid to the impact absorbing operation, the impact absorbing operation can be performed while preventing the influence of the second pretensioner mechanism 100. Therefore, basically, the motor 110 and the winding drum 20 are not affected. There is no problem even if a mechanism such as a torque limiter that cuts off the power transmission path at a predetermined timing is omitted. For this reason, the structure which integrated the base member 122B and the gear member 124B like this modification is employable.

  And by acting the structure which concerns on this modification, the number of parts reduction, the simplification of a structure, the assembly | attachment ease, and cost reduction can be achieved.

It is a disassembled perspective view which shows the whole structure of a retractor. It is sectional drawing which shows the whole structure of a retractor. It is a disassembled perspective view which shows a 1st pretensioner mechanism. It is a figure which shows the positional relationship of a clutch ring part, an engagement cylinder part, and each clutch roller. It is operation | movement explanatory drawing of a pretensioner mechanism. It is operation | movement explanatory drawing of a pretensioner mechanism. It is a disassembled perspective view which shows a 2nd pretensioner mechanism. It is a disassembled perspective view which shows the clutch wheel in a 2nd pretensioner mechanism. It is explanatory drawing which shows the internal structure of a clutch wheel same as the above. It is a disassembled perspective view which shows a locking mechanism. It is a figure which shows the outer side end surface of a locking mechanism. It is a figure which shows the outer side end surface of a lock clutch body. It is a front view which shows a lock clutch body. It is a disassembled perspective view which shows a 1st lock starting mechanism and its incorporating part. It is a fragmentary sectional view showing the 1st lock starting mechanism and its incorporation part. It is a partial cross section explanatory view showing an emergency lock operation mechanism concerning a modification. It is a partially broken explanatory view which shows the emergency lock operation | movement mechanism same as the above. It is a disassembled perspective view which shows the modification of a base member.

Explanation of symbols

DESCRIPTION OF SYMBOLS 10 Housing 11a, 11b Side plate part 11ba Lock tooth 20 Winding drum 28 Combined body 30 Emergency lock operation mechanism 31 Lock mechanism 35 Pawl 37 Ratchet wheel part 40 First lock starting mechanism 45 Second lock starting mechanism 50 Torsion bar 100 Second pre Tensioner mechanism 110 Motor 120 Clutch wheel 126 Ratchet gear portion 128 Pawl member 130 Pawl guide

Claims (2)

A retractor for a seat belt that winds up the webbing so as to remove slack in an emergency, and further gradually draws out the webbing so as to reduce the impact applied to the occupant,
A housing having a pair of side portions;
A winding drum that is rotatably supported between the pair of side portions in a state where the webbing is wound and is biased in the winding direction of the webbing;
A lock activation mechanism that is activated in the event of a vehicle emergency;
A lock operation mechanism that performs a lock operation to prevent the winding drum from rotating in the webbing pull-out direction in the event of an emergency of the vehicle by the activation of the lock activation mechanism;
A drum fixing portion fixed to the winding drum; and a rotation suppression end portion that is coupled to the lock mechanism so as not to rotate relative to the lock mechanism and is prevented from rotating by the locking operation of the lock mechanism. An impact absorbing mechanism that performs an impact absorbing operation by pulling out the webbing in a state where rotation of the end portion is suppressed;
A pretensioner mechanism that drives a motor unit in an emergency of a vehicle and rotates the winding drum in a webbing winding direction through a portion of the lock mechanism that is coupled to the rotation suppression end portion so as not to rotate relative to the rotation mechanism;
Seatbelt retractor equipped with. The retractor for a seat belt according to claim 1,
The shock absorbing mechanism is
Inserted into the take-up drum, a drum fixing portion at one end thereof is coupled to the one end portion side of the take-up drum so as not to be relatively rotatable, and a rotation suppression end portion at the other end is relatively unrotatable to the lock mechanism. Seatbelt retractor, which is a torsion bar coupled to

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