JP5399283B2 - Webbing take-up device - Google Patents

Description

  The present invention relates to a webbing take-up device including a tension reducer that can reduce the urging force that urges the webbing belt in the winding direction in a state where the webbing belt that restrains the body of an occupant is attached.

  In the webbing retractor disclosed in Patent Document 1 below, a winding shaft connected to one end of a seat belt winding shaft is rotatably supported by a housing. The end portion of the mainspring spring that generates a biasing force in the direction (winding direction) in which the seat belt is retracted by the seat belt being retracted from the seat belt retracting shaft. And a ratchet wheel constituting a so-called tension reducer is rotatably supported.

  In the tension reducer applied to this webbing take-up device, the inner end in the spiral direction of the auxiliary spring spring whose outer end in the spiral direction is locked to the ratchet wheel is frictionally engaged with the above-described winding shaft via a ring or a spring clutch. Match.

  When the main spring spring rotates the winding shaft in the winding direction while the ratchet pawl of the rotation restricting mechanism restricts the rotation of the ratchet wheel in the winding direction, the inner end of the auxiliary spring spring in the spiral direction passes through the ratchet wheel. It rotates in the winding direction with respect to the outer end in the spiral direction in which rotation in the winding direction is restricted. As a result, the biasing force generated by the secondary spring is offset by the biasing force of the main spring.

Japanese Patent No. 3396027

  In the tension reducer applied to this webbing take-up device, the ratchet pawl of the rotation restricting mechanism is engaged with the ratchet wheel as described above, and when the ratchet wheel is pressed against the ratchet pawl, this pressing force supports the ratchet wheel. It is transmitted to the reel. In this way, the pressing force transmitted to the winding shaft via the ratchet wheel becomes resistance to rotation of the winding shaft.

  In consideration of the above facts, the present invention provides a webbing take-up device that can smoothly rotate a connecting member such as a winding shaft even when a tension reducer is operated and rotation of a rotating body such as a ratchet wheel is restricted. The purpose is to obtain.

In the webbing take-up device according to the first aspect of the present invention, the longitudinal base end side of the long belt-like webbing belt is locked, and the webbing belt is drawn out while winding the webbing belt from the base end side. A spool that rotates in the pull-out direction, and is directly or indirectly connected to the spool, and the spool is rotated in the pull-out direction so that the spool is wound in a winding direction opposite to the pull-out direction. The first urging means for generating the first urging means, and one end side is frictionally or directly engaged with the rotating body rotatable in the pull-out direction and the winding direction, and is rotatable together with the rotating body. A biasing force of the first biasing means, the second biasing means having the other end mechanically connectable directly or indirectly to the coupling member coupled directly or indirectly to the first biasing means; Against In the winding direction applied to the spool by the application of the urging force of the second urging means or the separation of the urging force of the second urging means added to the urging force of the first urging means. A tension reducer that reduces rotational force, a first support means that rotatably supports the rotating body, and a first support member that rotatably supports the connecting member separately from the rotating body . 2 support means.

  In the webbing retractor according to the first aspect of the present invention, when the vehicle occupant pulls out the webbing belt from the spool, the spool rotates in the pull-out direction. When the spool rotates in the pull-out direction in this way, a winding attachment biasing force is generated by the first biasing means, and the spool is biased in the winding direction opposite to the pull-out direction.

  When the tension reducer operates in such a state that the webbing belt drawn out from the spool is wound around the occupant's body, the rotation of the rotating body constituting the tension reducer in the winding direction is restricted. One end side of the second urging means is engaged with the rotating body by friction or is directly engaged, and the other end of the second urging means is connected to the spool and the first urging means. It can be mechanically directly or indirectly connected to a connecting member that is directly or indirectly connected to the means.

  As described above, when the rotation of the rotating body is restricted, the urging force of the second urging means is added to the urging force of the first urging means, or the urging force of the first urging means until then. The urging force of the second urging means added to is disconnected. Thereby, the rotational force applied to the spool in the winding direction is reduced. In this way, the rotational force applied to the spool in the winding direction is reduced, so that the pulling force of the webbing belt toward the proximal end is reduced, and the webbing belt attached to the occupant's body tightens the occupant's body. Power is reduced.

By the way, in the webbing take-up device according to the present invention, the rotating body is rotatably supported by the first supporting means, whereas the connecting member is separated by the second supporting means separately from the supporting of the rotating body in the first supporting means. It is supported independently of the rotating body . For this reason, even if some external force acts on the rotating body and attempts to displace in the rotational radius direction, this influence does not reach the connecting member supported by the second support means, or this influence Few. For this reason, a connection member can rotate smoothly also in such a state.

  The webbing take-up device according to a second aspect of the present invention is the webbing retractor according to the first aspect of the present invention, wherein the first support means and the second support means are configured in one part.

  In the webbing take-up device according to the second aspect of the present invention, the first support means for supporting the rotating body and the second support means for supporting the connecting member are configured in one part, so that the first support Compared with a configuration in which the means and the second support means are provided completely separately, the configuration is simplified, and the setting space of the first support means and the setting space of the second support means are basically the same, thus saving space. Can be planned.

  A webbing take-up device according to a third aspect of the present invention is the webbing retractor according to the second aspect, wherein one of the rotating body and the connecting member is fitted into an inner peripheral portion. A cylindrical portion that rotatably supports one of the other and has an outer peripheral portion fitted into one of the other and rotatably supporting the other is used as the first support means and the second support means. .

  In the webbing take-up device according to the third aspect of the present invention, one of the rotating body and the connecting member is fitted into the inside of the cylindrical portion, so that one of the rotating body and the connecting member is inserted into the cylindrical portion. Is supported rotatably. On the other hand, a cylindrical portion is inserted into the other of the rotating body and the connecting member, and thereby the other of the rotating body and the connecting member is rotatably supported by the cylindrical portion (the outer peripheral portion of the cylindrical portion). Is done. Thereby, the rotating body and the connecting member can be coaxially supported while maintaining the support of the connecting member with respect to the support of the rotating body.

  A webbing take-up device according to a fourth aspect of the present invention is the webbing take-up device according to the first aspect, wherein one end side is engaged with the rotating body and the other end is the connection. When the other end rotates in the winding direction by transmitting the rotational force in the winding direction through the connecting member, it can be directly or indirectly connected to the member. The urging force is generated by restricting the urging force, and the canceling urging means that cancels the urging force of the first urging means with this urging force is used as the second urging means.

  In the webbing take-up device according to the fourth aspect of the present invention, the canceling biasing means can be arranged inside the rotating body, and the canceling biasing means can be arranged inside the rotating body in this way to form a unit. Furthermore, the rotating body can be attached (supported) to the first supporting means in a state where the canceling biasing means is disposed inside the rotating body and is in a unit shape.

  On the other hand, the first urging means can be made into a unit shape by being held by the holding body, and the first urging means is held by the holding means in this way, and the connecting member is urged by the first urging means. The connecting member can be attached (supported) to the second supporting means while being attached to the means.

  Furthermore, in the webbing take-up device according to the present invention, either one of the attachment of the unitized rotating body to the first support means and the attachment of the unitized connecting member to the second support means is performed. Either one can be attached later. Thereby, the unit on the rotating body and the offset urging means side, the first urging means and the unit on the connecting member side are assembled in a separate process in advance, and each unit is sequentially assembled into the first support means and the second support means. Assembling can be made efficient.

  As described above, the webbing take-up device according to the present invention can smoothly rotate the connecting member even when the tension reducer is operated and the rotation of the rotating body is restricted.

It is a disassembled perspective view of the principal part of the webbing winding device concerning one embodiment of the present invention. It is front sectional drawing of the principal part of the webbing winding device concerning one embodiment of the present invention. It is a side view which shows the mechanism which controls the rotation to the winding direction of the rotary body which comprises the webbing winding apparatus which concerns on one embodiment of this invention, and a rotary body. It is a side view of the rotary body seen from the opposite side to FIG. It is a figure which shows the assembly process of a tension reducer.

<Configuration of the present embodiment>
FIG. 1 is an exploded perspective view showing a configuration of a main part of a webbing take-up device 10 according to an embodiment of the present invention, and FIG. It is shown by the figure.

  As shown in FIG. 2, the webbing retractor 10 includes a frame 12. The frame 12 includes a back plate 14. A leg plate 16 extends from one end in the width direction of the back plate 14 toward one side in the thickness direction of the back plate 14, and from the other end in the width direction of the back plate 14 to the back plate 14. A leg plate (not shown) is extended toward the extending direction of the leg plate 16. A spool 18 is provided between a leg plate 16 extending from one end in the width direction of the back plate 14 and a leg plate (not shown) extending from the other end in the width direction of the back plate 14. . As shown in FIG. 1, the spool 18 has a cylindrical shape whose axial direction is along the width direction of the back plate 14.

  The spool 18 is engaged with the longitudinal base end side of the webbing belt 20 formed in a long band shape. When the spool 18 rotates in one winding direction around its axis, the webbing belt 20 is The webbing belt 20 is wound around the outer periphery from the end side. On the other hand, when the webbing belt 20 is pulled toward the tip, the webbing belt 20 wound around the spool 18 is pulled out from the spool 18 and the webbing take-up device 10 moves in a drawing direction opposite to the winding direction. Rotate.

  On the other hand, a case 24 constituting a tension reducer 22 is provided outside the leg plate 16 along the width direction of the back plate 14. The case 24 includes a plate-like base portion 26 whose thickness direction is along the thickness direction of the leg plate 16. The base portion 26 is fixed to the leg plate 16 by a fastening fixing means such as a screw or a fitting fixing means such as a gusset pin. Is done. A hole having a predetermined shape is formed in the base portion 26, and an annular peripheral wall 28 along the edge of the hole is formed toward the side opposite to the leg plate 16 of the base portion 26. An intermediate wall 30 is formed continuously from the peripheral wall 28 at the end of the peripheral wall 28 opposite to the base 26. The middle wall 30 is formed in a plate shape whose thickness direction is along the thickness direction of the base portion 26, and a space surrounded by the peripheral wall 28 on the side of the base portion 26 with respect to the middle wall 30 is a winding spring unit housing portion 32 (see FIG. 1).

  A winding spring unit 40 is disposed inside the winding spring unit housing portion 32. The winding spring unit 40 includes a spring cover 42 as a holding body. The spring cover 42 has a flat bottom wall 44. A peripheral wall 46 is erected from the outer peripheral portion of the bottom wall 44 toward the leg plate 16, and the spring cover 42 has a box shape that is open toward the leg plate 16 as a whole. The outer peripheral shape of the spring cover 42 is slightly smaller than the inner peripheral shape of the take-up spring unit accommodating portion 32 (that is, the inner peripheral shape of the peripheral wall 28), and the spring cover 42 is a case inside the take-up spring unit accommodating portion 32. 24 is fitted in a state where it is locked against rotation.

  A winding spring 50 as a first urging means is provided inside the spring cover 42. The winding spring 50 is constituted by a mainspring spring in which the direction from the outer side in the spiral direction to the inner side in the spiral direction is the drawing direction. In the vicinity of the end of the winding spring 50 on the outer side in the spiral direction, the winding spring 50 is folded back in the opposite direction to form a locking portion 52, and the locking spring erected from the bottom wall 44 toward the leg plate 16 side. Locked to the wall 54. On the other hand, the end of the winding spring 50 on the inner side in the spiral direction is locked to the outer peripheral portion of the adapter 56 constituting the rotation transmitting means as a connecting member.

  The adapter 56 is formed in a cylindrical shape that is substantially coaxial with the spool 18, and the end of the adapter 56 that faces the end on the axial leg plate 16 side of the spool 18 is coaxial with the spool 18. A fitting hole 60 into which the connecting shaft portion 58 that protrudes from the spool 18 is fitted is formed, and the adapter shaft 56 cannot be rotated relative to the spool 18 by fitting the connecting shaft portion 58 into the fitting hole 60. In this state, the spool 18 and the adapter 56 are connected.

  For this reason, when the webbing belt 20 is pulled to the tip end side and the spool 18 is rotated in the pull-out direction, the end portion on the inner side in the spiral direction of the winding spring 50 rotates relative to the end portion on the outer side in the spiral direction in the pull-out direction. When the winding spring 50 is tightened in this manner, the spool 18 is urged in the winding direction, and the relative rotation amount of the winding direction inner end portion with respect to the spiral direction outer end portion of the winding spring 50 in the pulling direction. The greater the number, the above-mentioned urging force increases.

  A seat 62 is provided on the opening side of the spring cover 42 in which the take-up spring 50 is accommodated. The sheet 62 has a plate shape whose thickness direction is along the thickness direction of the leg plate 16. The sheet 62 has a through hole 64 through which the adapter 56 passes. A fitting piece 66 extends from a part of the outer periphery of the sheet 62. A fitting portion 70 having a fitting hole 68 is formed in the back plate 14 corresponding to the fitting piece 66, and the fitting piece 66 is fitted into the fitting hole 68 of the fitting portion 70. Thus, the seat 62 is integrally attached to the back plate 14, and the opening side of the winding spring unit housing portion 32 and the opening side of the spring cover 42 on the back plate 14 are closed.

  On the other hand, a hole 82 having a predetermined shape is formed in the inner wall 30 of the back plate 14. Further, a peripheral wall 84 is formed along the edge of the hole 82 from the surface of the intermediate wall 30 opposite to the leg plate 16. The end of the peripheral wall 84 opposite to the inner wall 30 is closed by a bottom wall 86, and the inner side of the peripheral wall 84 closer to the inner wall 30 than the bottom wall 86 is a reduction spring unit housing portion 88. A reduction spring unit 90 is accommodated in the spring unit accommodating portion 88. The reduction spring unit 90 includes a ratchet gear 92 as a rotating body.

  The ratchet gear 92 includes a plate-like bottom wall portion 94 whose thickness direction is along the thickness direction of the bottom wall 86. A boss 96 is formed at the center of the bottom wall portion 94. The boss 96 is formed in a bottomed cylindrical shape that opens toward the bottom wall 86, and one side (opening side of the boss 96) is located toward the bottom wall 86 side of the bottom wall portion 94 from the axially intermediate portion. The other side (the bottom 98 side of the boss 96) of the boss 96 is protruded toward the leg plate 16 side of the bottom wall 94.

  The inner peripheral shape of the boss 96 is formed in a circular shape coaxial with the outer peripheral shape which is circular. Further, a through hole 100 coaxial with the inner peripheral shape of the boss 96 is formed in the bottom 98. The through hole 100 has a truncated cone shape that not only penetrates the bottom portion 98 but also gradually decreases toward the opening end on the leg 98 side surface of the bottom portion 98.

  As shown in FIGS. 1 and 2, a bearing portion 102 constituting both the first support means and the second support means is formed on the bottom wall 86 of the case 24 corresponding to the boss 96 as a cylindrical portion. Yes. The bearing portion 102 is formed in a cylindrical shape that is coaxial with the spool 18 with the case 24 attached to the leg plate 16. However, the tip end side of the bearing portion 102 has a truncated cone shape that gradually decreases in outer diameter toward the tip corresponding to the through hole 100 formed in the bottom 98 of the boss 96. A boss 96 enters the inside of the bearing portion 102 in a state where the ratchet gear 92 is disposed in the reduce spring unit housing portion 88, and the ratchet gear 92 is rotatably supported by the boss 96. Further, inside the boss 96, a bearing portion 102 formed integrally with the adapter 56 in a cylindrical shape coaxially with the spool 18 enters, and the bearing portion 102 (that is, the adapter 56) is rotatably supported. .

  A ratchet portion 106 is formed on the outer peripheral portion of the bottom wall portion 94, and the ratchet gear 92 is generally formed in a tray shape (a bottomed cylindrical shape having a relatively short axial dimension) that opens toward the leg plate 16 side. ing. A solenoid 110 is provided on the radially outer side of the ratchet portion 106 (below the ratchet portion 106 in the present embodiment). The solenoid 110 is electrically connected to a battery mounted on the vehicle via an ECU as control means. Further, the ECU is electrically connected to a buckle switch provided in the buckle device constituting the seat belt device together with the webbing take-up device 10, and the tongue plate provided in the webbing belt 20 is connected to the buckle device. When the buckle switch detects that it is attached, the ECU energizes the solenoid 110. Thus, when the solenoid 110 is energized, the solenoid 110 generates a magnetic field.

  The solenoid 110 is provided with a plunger 112. The plunger 112 is formed in a rod shape by a magnetic body, and the longitudinal base end side enters the solenoid 110. When the solenoid 110 is energized as described above, the plunger 112 is further pulled inside the solenoid 110 by the magnetic field formed by the solenoid 110. A pawl 114 is provided on the distal end side of the plunger 112. The pawl 114 has a cylindrical portion 116. The cylindrical portion 116 has the same axial direction as the axial direction of the spool 18. A shaft portion 118 (see FIG. 2) having at least one end held by at least one of the sheet 62 and the case 24 passes through the cylindrical portion 116, and the pawl 114 is rotatably supported around the shaft portion 118. Yes. A rotation restricting piece 120 extends from a part of the outer periphery of the cylindrical portion 116.

  As shown in FIG. 3, when the pawl 114 rotates in one engagement direction around the shaft portion 118, the tip of the rotation restricting piece 120 approaches the outer peripheral portion of the ratchet portion 106 and the ratchet teeth of the ratchet portion 106. Engage with. In this manner, when the tip of the rotation restricting piece 120 is engaged with the ratchet teeth of the ratchet portion 106, the rotation of the ratchet gear 92 in the winding direction is restricted. A connecting piece 122 extends from a part of the outer periphery of the cylindrical portion 116. The pawl 114 is connected to the plunger 112 by the connecting piece 122. When the plunger 112 is pulled into the solenoid 110, the connecting piece 122 is pulled by the plunger 112, and the pawl 114 moves around the shaft portion 118 in the engaging direction. Rotate. Further, one end of a return spring 124 is locked to the pawl 114, and the pawl 114 is urged in a direction opposite to the engaging direction. If the solenoid 110 is not energized, the leading end side of the rotation restricting piece 120 is the ratchet portion. It maintains in the state spaced apart from the outer peripheral part of 106.

  On the other hand, on the inner side of the ratchet gear 92 (that is, the inner side of the ratchet portion 106 on the leg plate 16 side of the bottom wall portion 94), a reduction balance spring 130 is disposed as a counter biasing means constituting the reduction spring unit 90. . The reduction balance spring 130 has a biasing force that is weaker than that of the winding spring 50, and is constituted by a mainspring spring whose direction from the outside in the spiral direction to the inside in the spiral direction is the winding direction.

  As shown in FIGS. 3 and 4, the reduction balance spring 130 is bent inward in the radial direction and inward in the spiral direction in the vicinity of the end portion outside the spiral direction. A reduction slide spring 140 is disposed between the outermost layer portion (the outermost portion of the spiral) of the reduction balance spring 130 and the second portion from the outermost layer (the second portion from the outer side of the spiral). ing. The reduction slide spring 140 is formed in a narrow plate shape whose longitudinal direction is along the circumferential direction of the reduction balance spring 130 and whose width direction is along the axial direction of the spool 18. The reduction balance spring 130 is curved around an axis with the inner end side in the spiral direction as the center of curvature and the width direction as the axial direction.

  Further, as shown in FIG. 2 to FIG. 4, a clutch 150 that constitutes a rotation transmission means as a rotation transmission member further inside the spiral innermost layer portion (the innermost portion of the spiral) of the reduction balance spring 130. Is provided. The clutch 150 includes a spring case 152. The spring case 152 is formed in a bottomed cylindrical shape that opens toward the leg plate 16 side. Of the boss 96 formed on the bottom wall portion 94 of the ratchet gear 92, the portion positioned closer to the leg plate 16 than the bottom wall portion 94 is supported coaxially and relatively rotatably with respect to the ratchet gear 92.

  The shaft portion 104 of the adapter 56 passes through the bottom wall of the spring case 152 and is supported by the shaft portion 104 so as to be relatively rotatable coaxially with the shaft portion 104, as shown in FIGS. 3 and 4. As shown in the drawing, the end of the reduction balance spring 130 on the inner side in the spiral direction is locked to the spring case 152.

  As shown in FIG. 1, the clutch 150 includes a clutch wheel 154. The clutch wheel 154 includes a cylindrical clutch wall 156. The clutch wall 156 enters the inside of the spring case 152 in a state of being coaxial with the bearing portion 102. In this state, the clutch wheel 154 is assembled to the spring case 152. attached. Further, the clutch wheel 154 passes through a non-circular detent 158 interposed between the main body portion of the adapter 56 and the bearing portion 102, and relative rotation of the clutch wheel 154 with respect to the adapter 56 is restricted.

  A clutch spring 160 is disposed inside the spring case 152 and outside the clutch wall 156. The clutch spring 160 is formed in a coil shape whose axial direction is the same as the axial direction of the spool 18, and one end of the clutch spring 160 is locked to the spring case 152. When the clutch spring 160 is regarded as a cylindrical shape, the inner diameter dimension thereof is substantially equal to the outer diameter dimension of the clutch wall 156, and the clutch spring 160 is in sliding contact with the outer peripheral portion of the clutch wall 156. Further, the winding direction of the coil is set so that the clutch spring 160 is wound when the other end side is displaced in the winding direction with respect to the one end side.

<Operation and effect of the present embodiment>
Next, the operation and effect of the present embodiment will be described.

(Operation of tension reducer 22)
In the webbing retractor 10, when an occupant seated on a vehicle seat pulls the webbing belt 20 from the spool 18 and pulls the webbing belt 20 from the spool 18 in order to attach the webbing belt 20 to the body, the spool 18 is pulled out. Rotate in the direction. When the spool 18 rotates in the pull-out direction, the adapter 56 rotates in the pull-out direction and rotates the inner end in the spiral direction of the winding spring 50 in the pull-out direction with respect to the outer end in the spiral direction. As a result, the take-up spring 50 is tightened, and the urging force for urging the spool 18 in the take-up direction via the adapter 56 gradually increases.

  Further, the clutch wheel 154 rotates in the pulling direction by the adapter 56 rotating in the pulling direction in this way. Since the clutch spring 160 is in sliding contact with the outer peripheral portion of the clutch wall 156 of the clutch wheel 154, when the clutch spring 160 rotates together with the clutch wall 156 in the pull-out direction due to friction between the outer peripheral portion of the clutch wall 156 and the clutch spring 160, The spring case 152 with one end of the clutch spring 160 locked rotates in the pull-out direction.

  Since the inner end of the reduction balance spring 130 in the spiral direction is locked to the spring case 152, when the spring case 152 rotates in the pull-out direction, the inner end in the spiral direction of the reduce balance spring 130 rotates in the pull-out direction. Since the outermost layer of the reduction balance spring 130 is in pressure contact with the ratchet portion 106 of the ratchet gear 92 by the elasticity of the reduction balance spring 130 and the elasticity of the reduction slide spring 140, the inner end in the spiral direction of the reduction balance spring 130 is in the pull-out direction. When rotated, the outermost layer of the reduction balance spring 130 rotates in the pull-out direction, and the ratchet gear 92 rotates in the pull-out direction due to friction between the outermost layer of the reduce balance spring 130 and the inner peripheral portion of the ratchet portion 106. That is, in this state, even if the rotational force in the pull-out direction of the spool 18 is transmitted to the ratchet gear 92, the ratchet gear 92 only rotates in the pull-out direction, and no particular change occurs in the reduction balance spring 130.

  Next, when the webbing belt 20 is sufficiently pulled out and hung around the occupant's body, and further, the tongue provided on the webbing belt 20 is attached to the buckle device, an electric signal from a buckle switch provided on the buckle device. Based on the above, the ECU sets the solenoid 110 in the energized state. When the plunger 112 is pulled into the solenoid 110 by a magnetic field formed by energizing the solenoid 110, the pawl 114 having the connecting piece 122 engaged with the distal end side of the plunger 112 resists the urging force of the return spring 124. Turn in the engagement direction. Thereby, when the rotation restricting piece 120 of the pawl 114 is engaged with the ratchet teeth formed on the outer peripheral portion of the ratchet portion 106, the rotation of the ratchet gear 92 in the winding direction is restricted.

  In this state, when the pulling force applied to the webbing belt 20 by the occupant to pull out the webbing belt 20 is eliminated (when the occupant stops pulling the webbing belt 20), the winding spring 50 is urged by the biasing force. The spool 18 is rotated in the winding direction via the adapter 56 to eliminate the slack of the webbing belt 20. When the adapter 56 is rotated in the winding direction, when the clutch wheel 154 is rotated in the winding direction, the other end of the clutch spring 160 is rotated in the winding direction due to friction with the clutch wall 156, whereby the clutch spring 160 is tightened.

  When the friction between the clutch spring 160 and the clutch wall 156 increases due to the tightening of the clutch spring 160, the entire clutch spring 160 rotates in the winding direction together with the clutch wall 156 (that is, the clutch wheel 154). When the spring spring 152 rotates in the winding direction by rotating the clutch spring 160 in the winding direction, the inner end portion in the spiral direction of the reduction balance spring 130 locked to the spring case 152 rotates in the winding direction.

  The outermost layer of the reduction balance spring 130 is in pressure contact with the ratchet portion 106 of the reduction spring unit 90 due to the elasticity of the reduction balance spring 130 and the elasticity of the reduction slide spring 140, and the winding direction of the ratchet gear 92 as described above. Therefore, even if the inner end of the reduction balance spring 130 in the spiral direction rotates in the winding direction in this state, the outermost layer of the reduction balance spring 130 is in contact with the inner peripheral portion of the ratchet portion 106. It does not rotate due to friction, or the amount of rotation is less than the inner end of the spiral direction. The direction of the reduction balance spring 130 from the outer side in the spiral direction to the inner side in the spiral direction is the winding direction. For this reason, when the inner end portion in the spiral direction rotates in the winding direction relative to the outer end portion in the spiral direction, the reduction balance spring 130 is tightened so that the inner end portion in the spiral direction is pulled out. The urging force to rotate is increased.

  The urging force of the reduction balance spring 130 generated (increased) in this way is a force that attempts to rotate the spring case 152 in which the spiral balance inner end of the reduction balance spring 130 is locked in the winding direction, that is, This resists the urging force of the winding spring 50.

  Further, when the reduction balance spring 130 is tightly wound until it comes into full contact with the outer peripheral portion of the spring case 152, the reduction balance spring is rotated by the rotational force in the winding direction transmitted to the reduction balance spring 130 via the spring case 152 after this state. The outermost layer 130 and the reducing slide spring 140 rotate together.

  In this way, a part or all of the urging force of the take-up spring 50 is offset by the urging force of the reduction balance spring 130, so that the force to rotate the spool 18 in the take-up direction is reduced, and the occupant's The force pulling the webbing belt 20 attached to the body toward the proximal end is reduced. Thereby, the fastening (static fastening force) which the webbing belt 20 gives to the occupant is reduced.

  When the body of the passenger wearing the webbing belt 20 moves, the webbing belt 20 is pulled out. When the webbing belt 20 is pulled out and the spool 18 rotates in the pulling-out direction, the winding spring 50 is wound up, and the force that urges the spool 18 in the winding-up direction, and thus pulls the webbing belt 20 to tighten the occupant's body. Power increases. However, in the webbing take-up device 10, the urging force of the reduction balance spring 130 cancels the urging force of the take-up spring 50, so that the webbing belt 20 is tightened when the occupant's body moves and pulls the webbing belt 20. An increase in the force (dynamic tightening force) can be suppressed.

(Function of the bearing portion 102 of the case 24)
By the way, when the rotation restricting piece 120 of the pawl 114 is engaged with the ratchet teeth of the ratchet portion 106 as described above to restrict the rotation of the ratchet gear 92 in the winding direction, the ratchet gear 92 is pushed from the rotation restricting piece 120. Under the pressure, the ratchet gear 92 tends to be displaced in the radial direction as a whole. However, the ratchet gear 92 is supported by the bearing portion 102 when the bearing portion 102 formed in the case 24 enters the inside of the boss 96 (that is, the ratchet gear 92 is supported by the outer peripheral portion of the bearing portion 102. ). In contrast, the shaft portion 104 of the adapter 56 is supported by the bearing portion 102 by entering the inside of the bearing portion 102 (that is, the shaft portion 104 of the adapter 56 is supported by the inner peripheral portion of the bearing portion 102. )

  That is, the boss 96 of the ratchet gear 92 and the shaft portion 104 of the adapter 56 are supported by the bearing portion 102 in an independent state. For this reason, even if the rotation restricting piece 120 of the pawl 114 is engaged with the ratchet teeth of the ratchet portion 106, the adapter 56 is not affected (resistance) even if the ratchet gear 92 tries to be displaced in the radial direction as a whole. Alternatively, the ratchet gear 92 is less affected as a whole in its radial direction.

  Therefore, even when the rotation restricting piece 120 is engaged and the rotation of the ratchet gear 92 in the winding direction is restricted, the adapter 56 can rotate smoothly.

(Function of clutch 150)
On the other hand, for example, when the passenger removes the tongue plate from the buckle device by operating the buckle device when removing the webbing belt 20 worn on the body, the ECU cuts off the power to the solenoid 110 by the electrical signal from the buckle switch. To do. When the magnetic field formed by the solenoid 110 is eliminated by shutting off the energization of the solenoid 110, the pawl 114 is rotated in the direction opposite to the engagement direction by the urging force of the return spring 124, and the rotation restricting piece 120 is rotated. And the ratchet teeth of the ratchet portion 106 are released.

  As described above, in the state where the rotation of the ratchet gear 92 in the winding direction is restricted, the inner end portion in the spiral direction of the reduction balance spring 130 is relatively rotated in the winding direction with respect to the outer end portion in the spiral direction. The biasing force is increasing. For this reason, when the rotation restriction of the ratchet gear 92 is eliminated, the outermost layer of the reduce balance spring 130 pressed against the inner peripheral portion of the ratchet portion 106 by the urging force of the reduce balance spring 130 winds the ratchet gear 92 in the winding direction. Rotate to In this way, the urging force of the reduction balance spring 130 is released, and when the ratchet gear 92 is rotated in the winding direction and the spring case 152 is further rotated in the winding direction, it is wound around the outer periphery of the clutch wall 156 until then. The loosened clutch spring 160 is loosened.

  Accordingly, the clutch spring 160 to which the rotational force of the ratchet gear 92 is transmitted via the spring cases 152 and 130 rotates in the winding direction so as to slide with respect to the clutch wall 156. For this reason, it does not act on the inner end portion in the spiral direction of the reduction balance spring 130 of the rotation balance spring 130 in the winding direction of the ratchet gear 92 and its vicinity. Therefore, a support member for preventing buckling of the inner end portion in the spiral direction of the reduce balance spring 130 and its vicinity due to such rotational force (for example, as disclosed in JP-A-2003-19946). Support member) becomes unnecessary.

  By eliminating the need for such a support member, the urging force of the reduction balance spring 130 can be directly transmitted to the spring case 152, and the transmission efficiency of the urging force is improved. Moreover, since it is not necessary to provide a support member inside the ratchet gear 92, the space efficiency inside the ratchet gear 92 can be improved. For example, the ratchet gear 92 can be reduced in size or the ratchet gear 92 can be increased in size. A relatively large reduction balance spring 130 can be used.

(Operation and effect of the present embodiment as seen from the assembly side)
Next, the operation and effect of this embodiment viewed from the assembly surface of the tension reducer 22 will be described through the description of the assembly process of the tension reducer 22.

  In assembling the tension reducer 22 in the webbing take-up device 10, first, the take-up spring unit 40, the reduce spring unit 90, and the clutch 150 are each assembled.

  In the assembling process of the take-up spring unit 40, the take-up spring 50 is disposed inside the spring cover 42, and the engaging portion 52 is engaged with the engaging wall 54 to be unitized. On the other hand, in the assembly process of the reduce spring unit 90, the reduce balance spring 130 and the reduce slide spring 140 are arranged inside the ratchet gear 92, whereby the ratchet gear 92, the reduce balance spring 130, and the reduce slide spring are arranged. 140 is unitized. Further, in the assembly process of the clutch 150, the clutch wall 156 of the clutch wheel 154 is inserted inside the coil portion of the clutch spring 160. In this state, one end of the clutch spring 160 is locked to the spring case 152, whereby the clutch 150 is assembled.

  Next, the reduced spring unit 90 assembled as described above is first disposed in the reduced spring unit accommodating portion 88 in the case 24 as shown in FIG. 5A, and the ratchet gear 92 is attached to the bearing portion 102. Supported. Next, as shown in FIG. 5B, the clutch 150 is disposed inside the reduction balance spring 130, and the spiral case inner end of the reduction balance spring 130 is locked to the spring case 152. Here, in this state, since the clutch 150 and the reduction balance spring 130 can be easily visually recognized from the opening side of the case 24, the other end of the reduction balance spring 130 can be easily locked to the spring case 152.

  Next, as shown in FIG. 5C, the spring cover 42 of the winding spring unit 40 is fitted into the winding spring unit housing portion 32 of the case 24. Here, since the spring case 152 of the clutch 150 is rotatably supported by the boss 96, the clutch 150 is positioned at the center of the ratchet gear 92. Thus, even if the spring cover 42 is attached to the take-up spring unit housing portion 32 of the case 24, the clutch wall 156 can pass through the through hole of the bottom wall 44 (spring cover 42) through which the bearing portion 102 and the rotation stopper 158 pass. A hole into which the rotation preventing portion 158 is fitted is visible.

  As shown in FIG. 5D, an adapter 56 is disposed inside the winding spring 50 with the winding spring unit 40 mounted on the case 24, and the clutch 150 and the ratchet gear 92 are prevented from rotating around the adapter 56. As described above, the bottom wall 44 (spring cover) through which the bearing portion 102 and the anti-rotation portion 158 pass even if the spring cover 42 is attached to the take-up spring unit housing portion 32. 42), a hole into which the rotation preventing portion 158 fits in the clutch wall 156 can be visually observed. Therefore, the rotation preventing portion 158 can be easily fitted to the clutch wheel 154, and the shaft portion 104 is further connected to the bearing portion 102. Can be easily fitted.

DESCRIPTION OF SYMBOLS 10 Webbing winding device 18 Spool 20 Webbing belt 22 Tension reducer 40 Winding spring unit 50 Winding spring (1st biasing means)
56 Adapter (connection member)
90 Reduce Spring Unit 92 Ratchet Gear (Rotating Body)
102 Bearing part (cylindrical part, first support means, second support means)
130 Reduce balance spring (offset biasing means)

Claims (4)

A spool that is locked on the longitudinal base end side of the long belt-shaped webbing belt, winds the webbing belt from the base end side, and rotates in the pull-out direction when the webbing belt is pulled out;
A first urging means connected directly or indirectly to the spool and generating a winding attachment urging force in a winding direction opposite to the pulling direction by rotating the spool in the pulling direction;
One end side is frictionally or directly engaged with the rotating body rotatable in the pull-out direction and the winding direction and can rotate with the rotating body, and directly or on the spool and the first biasing means. The second urging means has a second urging means whose other end can be mechanically directly or indirectly connected to the indirectly connected linking member, and the second urging means is urged against the urging force of the first urging means. A tension reducer that reduces the rotational force in the winding direction applied to the spool by the addition of a force or the separation of the biasing force of the second biasing unit added to the biasing force of the first biasing unit; ,
First support means for rotatably supporting the rotating body;
Apart from the support of the rotating body, second support means for rotatably supporting the connecting member independently of the rotating body ;
A webbing take-up device comprising:   The webbing take-up device according to claim 1, wherein the first support means and the second support means are configured in one part.   Either one of the rotating body or the connecting member is inserted into the inner peripheral part to rotatably support one of the above, and the outer peripheral part is inserted into one of the other ones. The webbing take-up device according to claim 2, wherein a cylindrical portion that rotatably supports the other of the first and second support means is the first support means and the second support means.   One end side engages with the rotating body, and the other end can be directly or indirectly connected to the connecting member, and the other end is taken up by transmitting the rotational force in the winding direction through the connecting member. When the rotation is rotated in the direction, an energizing force is generated by restricting the follow-up rotation on one end side with respect to the other end, and the canceling energizing unit that cancels the energizing force of the first energizing unit by the energizing force The webbing take-up device according to any one of claims 1 to 3, wherein the webbing take-up device is an urging means.

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