JP2012116206A - Operating part structure of vehicle seat - Google Patents

Abstract

PROBLEM TO BE SOLVED: To improve the assembling workability of a torsion spring that rotates and activates a lever with respect to a base.SOLUTION: An operating part structure of a vehicle seat includes a rotational operation type lever 3 connected to a base 2 that is fixed to a frame of a seat back so as to axially rotate the lever by a rotation shaft. A torsion spring 6 that rotates and activates the lever 3 in one direction is hooked between the lever 3 and the base 2 with one end of the spring hooked on the lever 3 and the other end 6B hooked on the base 2. The lever 3 includes a hooking part to hook one end of the torsion spring 6 and a temporary hooking part 3E where the other end 6B of the torsion spring 6 can be hooked in a torsion state. The torsion spring 6 is configured in such a manner that the torsion spring with both ends hooked on the lever 3 is assembled together with the lever 3 into the base 2, and then the other end 6B is switched to be hooked on the base 2.

Description

  The present invention relates to a structure for operating a vehicle seat. More specifically, the present invention relates to a vehicle seat operation unit structure in which a rotary operation lever is connected to a base fixed to a seat frame so as to be axially rotatable by a rotation shaft.

  As this kind of operation part structure, what was indicated by the following patent documents 1 is known. This operation part structure is provided in the shoulder opening of the seat back of the vehicle seat, and is configured to release the fixed state of the backrest angle of the seat back by raising the lever. The lever is inserted into the base fixed to the frame of the seat back from the upper side and set, and is connected to a state in which the shaft can rotate by a rotating shaft that penetrates both sides from the side. Has been. Further, a torsion spring that urges the lever to rotate in one direction with respect to the base is hooked between the lever and the base.

JP 2005-80740 A

  In the above prior art, when the lever is assembled to the base, one end of the torsion spring is previously attached to the lever, and the other end is twisted and assembled to the base together with the lever. ing. The present invention was devised as a solution to the above problem, and the problem to be solved by the present invention is to improve the workability of the torsion spring that urges the lever to rotate relative to the base. is there.

In order to solve the above problems, the vehicle seat operating portion structure of the present invention takes the following means.
1st invention is the operation part structure of the seat for vehicles by which the lever of a rotation operation type was connected with the base fixed to a seat frame in the state where axis rotation is possible with a rotating shaft. Between the lever and the base, a torsion spring is hooked, with one end hooked to the lever and the other end hooked to the base, which urges the lever to rotate in one direction. The lever is formed with a hook portion on which one end of the torsion spring is hooked, and a temporary hook portion that can be hooked with the other end of the torsion spring being twisted. The torsion spring is switched so that the other end is hooked to the base after being assembled to the base together with the lever in a state where both ends are hooked on the lever.

  According to the first aspect of the present invention, the torsion spring is hooked on the lever in a state where the other end is also twisted in addition to being hooked at one end thereof, so that both ends of the torsion spring are engaged with the lever. In the state of being hung and held, after being assembled to the base together with the lever, it is possible to switch the hooking of the other end to the base. In this way, by allowing both ends of the torsion spring to be hung on the lever, it is possible to keep the torsion spring in the lever without applying external force, and the lever is assembled to the base, and then In addition, the torsion spring can be easily assembled in a state of being twisted between the lever and the base by a simple operation of transferring the hook of the other end to the base.

  According to a second invention, in the first invention described above, the other end of the torsion spring is configured to be hooked in a state of being bent in the axial direction with respect to the temporary hooking portion of the lever. After removing the hook from the other end of the temporary hook, the other end is urged toward the main hook of the base formed in the axial direction with the temporary hook by the restoring force. It is designed to be hooked on the main hook.

  According to the second aspect of the invention, the other end of the torsion spring is hooked in a state of being bent in the axial direction with respect to the temporary hooking portion of the lever. By being configured to be hooked to the main hook while being biased toward the main hook of the base arranged in the axial direction, the work of moving the hook at the other end to the base can be performed more easily. .

FIG. 3 is a perspective view illustrating a schematic configuration of a vehicle seat operating unit structure according to the first embodiment. It is a disassembled perspective view of the operation part structure of a vehicle seat. It is a perspective view of the assembly state of the operation part structure of a vehicle seat. It is the perspective view which looked at the lever simple substance from another angle. It is the perspective view which looked at the lever simple substance from another angle. It is the VI-VI sectional view taken on the line of FIG. It is the perspective view which looked at the lid cover simple substance from another angle. It is the perspective view which looked at the cap from another angle. It is a lock state figure of a locking device. It is the state figure which carried out release operation of the locking device. It is a state diagram after the unlocking operation of the locking device. It is a top view of the assembly | attachment state of the operation part structure of a vehicle seat. It is the XIII-XIII sectional view taken on the line of FIG. It is the XIV-XIV sectional view taken on the line of FIG. It is the XV-XV sectional view taken on the line of FIG. It is the XVI-XVI sectional view taken on the line of FIG. It is an enlarged view which shows the latching state of the torsion spring exposed in a slit. FIG. 6 is an enlarged view of a main part of an operation unit structure for a vehicle seat according to a second embodiment. It is the XIX-XIX sectional view taken on the line of FIG. FIG. 6 is an enlarged view of a main part of a vehicle seat operating unit structure according to a third embodiment. It is the schematic diagram which looked at a mode that the hooking of the torsion spring was transferred, and showed it.

  EMBODIMENT OF THE INVENTION Below, the form for implementing this invention is demonstrated using drawing.

  First, the operation part structure 1 (hereinafter referred to as the operation part structure 1) of the vehicle seat of the first embodiment will be described with reference to FIGS. As shown in FIG. 1, the operation unit structure 1 of the present embodiment is provided at the shoulder opening on the vehicle body wall W side (the left side in the drawing) of the seat back SB of the vehicle seat, and pushes the lever 3 forward. Thus, the fixed state of the backrest angle of the seat back SB is released. Here, the seat back SB is normally locked to the striker ST provided on the side of the vehicle body wall W by the locking device 10 provided on the side of the vehicle body wall W (left side in the figure). The backrest angle with respect to the wall W is held in a fixed state.

  The fixed state of the backrest angle of the seat back SB is released when the lock state of the lock device 10 with respect to the striker ST is released by operating the lever 3. Hereinafter, a specific configuration of the operation unit structure 1 will be described in detail. As shown in FIGS. 2 to 3, the operation unit structure 1 includes a base 2 that is fixed to a frame SF (see FIGS. 13 to 15) of the seatback SB, and a rotary shaft 3 </ b> F with respect to the base 2. A lever 3 that is connected in a rotatable state, a lid cover 4 that is mounted on the top of the base 2 and covers the base 2 with respect to the outside, and a lever 3 that is attached to the base 2 in a direction that rotates forward. And a torsion spring 6 to be biased. The base 2, the lever 3 and the lid cover 4 are each formed of a resin member, and the rotating shaft 3F and the torsion spring 6 are each formed of an iron member.

  The base 2 is formed in a rectangular container shape having an opening 2A in the center, and covers the entire surface of the seat back SB to be put on the frame SF of the seat back SB as shown in FIGS. The cushion pad SP is provided by being fitted into a recess SP1 formed in the shoulder opening. Specifically, as shown in FIGS. 2 and 12, the base 2 includes the opening 2A, and a vertically long slit 2A1 that penetrates a part of the opening 2A from the side surface side of the base 2 to the outside. A square frame-shaped inner frame portion 2B formed so as to surround the outer periphery of the opening 2A, and a square frame-shaped outer frame formed so as to surround the outer periphery of the inner frame portion 2B. 2C, a rectangular annular housing portion 2D formed by a space between the outer frame portion 2C and the inner frame portion 2B, and two outer peripheral portions opposed to the outer frame portion 2C. A pair of mounting plate portions 2E to be taken out, a bottom plate portion 2F forming the bottom surface of the opening 2A, and a cushion rubber 2G (see FIG. 12) attached to the bottom plate portion 2F are provided.

  As shown in FIG. 14, the base 2 has two attachment plate portions 2 </ b> E (only one side is shown in FIG. 14) protruding toward the outside. Is fastened to the frame SF by being fastened by the screw BS1. Here, as shown in FIGS. 2 and 12, the base 2 is further provided with a main hook 2 </ b> A <b> 2 for hooking the other end 6 </ b> B of a torsion spring 6 to be described later and a lid cover 4 to be described later. Engaging claws 2B1 are formed. The main hook 2A2 protrudes from the wall surface of the inner frame 2B of the base 2 adjacent to the slit 2A1 so as to be bent in an L shape toward the inner side of the frame. Specifically, the main hook 2A2 is formed in a shape that is bent in an L shape toward the side opposite to the opening direction of the slit 2A1. The engaging claws 2B1 are formed on several wall portions that form the inner frame portion 2B, and are respectively provided with elasticity that can be bent and deformed inward and outward of the frame with respect to the inner frame portion 2B. . The functions of these engaging claws 2B1 will be described later.

  As shown in FIGS. 2 to 5, the lever 3 is formed in a fan-shaped cylindrical shape as viewed from the side, and is assembled in the opening 2 </ b> A of the base 2 and can be rotated about the base 2 by the rotation shaft 3 </ b> F. (See also FIG. 12). Specifically, the lever 3 is formed in a side-view cylindrical fan-shaped gripping part 3A that is gripped and rotated by an operator, and is formed at one end in the axial direction of the gripping part 3A and has a larger fan shape than the gripping part 3A. A projecting side portion 3B, a central shaft portion 3C having a through hole formed in a corner portion on the center side of the fan shape and capable of being inserted through the rotation shaft 3F in the axial direction, and an outer surface of the side portion 3B ( 5) and a temporary hooking portion 3E that is formed so as to be bent in an L-shape from the outer surface of the side portion 3B.

  As shown in FIG. 4, the grip portion 3 </ b> A is formed with a plurality of ridges extending in a streak shape in the axial direction on a fan-shaped side surface portion on which the operator's finger is put. Jagged irregularities are formed as stops. As shown in FIG. 3, the side portion 3B is assembled into the slit 2A1 of the base 2 by assembling the grip portion 3A into the opening 2A. As shown in FIGS. By rotating the lever 3, the protruding fan shape is exposed in the opening 2A (see FIGS. 10 to 11) or hidden in the slit 2A1 (see FIG. 9). Here, as shown in FIGS. 2 and 4, a red display portion 3 </ b> B <b> 1 is formed by applying red coating to the portion of the side portion 3 </ b> B on the front end side that protrudes in a fan shape. As shown in FIGS. 10 to 11, the red display portion 3 </ b> B <b> 1 exposes the red display to the outside that the lock device 10 described above is unlocked by the rotation operation of the lever 3. In the state before the lever 3 is rotated, it is hidden in the slit 2A1 (see FIG. 9), and the opening is opened by the lever 3 rotating operation. It is exposed in 2A.

  As shown in FIG. 5, the temporary hooking portion 3E is bent in an L shape from the outer surface of the side portion 3B toward the radially outward side of the lever 3 (the direction away from the central shaft portion 3C). Protrusively formed. Further, as shown in FIG. 12, the rotating shaft 3F for connecting the lever 3 to the base 2 so as to be axially rotatable is one in which the lever 3 is attached to the base 2 from the state in which the lever 3 is assembled in the opening 2A. By inserting the E-ring 3F1 from the outer wall surface on the side through the central shaft portion 3C of the lever 3 and penetrating to the outer wall surface on the other side, And the E-ring 3F1 are attached in a state of being prevented from being detached from the base 2.

  As shown in FIGS. 2 to 3 and 7, the lid cover 4 is formed in a plate shape having a square opening 4 </ b> A in the center, and is attached to the upper part of the base 2 to open the opening. In a state where the opening 2A of the base 2 is opened to the outside by the portion 4A, the inner frame portion 2B and the outer frame portion 2C of the base 2 are covered to the outside by the covering portion 4B around the opening 4A. It can be assembled. Specifically, as shown in FIG. 2, the lid cover 4 includes a central opening 4A, a rectangular frame-shaped covering portion 4B that surrounds the outer periphery of the opening 4A, and a frame surface on the vehicle outer side of the covering portion 4B. A belt guide portion 4C formed to protrude in a mountain shape, a cap 5 detachably formed so as to constitute a part of the belt guide portion 4C, and a base portion 4D serving as a mounting portion of the cap 5; It has composition which has.

  As shown in FIGS. 13 to 15, a square frame-like mounting frame portion 4 </ b> B <b> 1 extending so as to hang downward is provided on the back surface of the cover portion 4 </ b> B of the lid cover 4. The mounting frame portion 4B1 is formed with engagement holes 4B2 penetrating at a plurality of locations. By setting the mounting frame portion 4B1 so as to fit into the outer periphery of the inner frame portion 2B of the base 2, Each engagement hole 4B2 of the mounting frame portion 4B1 is engaged with each engagement claw 2B1 of the inner frame portion 2B, and the lid cover 4 is set in a state of being covered on the upper portion of the base 2. . Further, as shown in FIG. 6, the lid cover 4 includes a base portion 4D which is applied to the frame SF of the seat back SB by the attachment in addition to the attachment of the mounting frame portion 4B1 to the base 2. By being fastened and fixed directly to the SF with the screw BS2, the frame SF is also fixed and fixed directly to the frame SF. Here, as shown in FIG. 2 and FIGS. 6 to 7, the base portion 4 </ b> D is positioned immediately below the place where the cap 5 is mounted on the lid cover 4, and has a stepped shape so that the cap 5 can be received in the upper portion thereof. It is formed in a flat shape that is depressed. As shown in FIGS. 2 to 3, the base portion 4 </ b> D has an overall shape including the screw hole 4 </ b> D <b> 1 serving as a fastening portion of the screw BS <b> 2 (see FIG. 6) as described above by mounting the cap 5. It is covered and functions as a support portion for supporting the mounted cap 5 from below.

  As shown in FIGS. 2 to 3, the cap 5 constitutes a part of the belt guide portion 4 </ b> C formed on the lid cover 4, and is continuous with the belt guide portion 4 </ b> C of the portion formed on the lid cover 4. The belt guide portion 5A has a mountain-like protruding shape. The cap 5 is a part formed on the lid cover 4 by a belt guide portion 5A that covers the base portion 4D with respect to the exterior and protrudes in a mountain shape by being assembled to the upper portion of the base portion 4D. A belt-like protruding shape that is continuous with the belt guide portion 4C is formed. The belt guide portion 5A formed on the cap 5 has a shape in which the protruding height of the mountain gradually decreases from the front end side toward the rear end side. As shown in FIG. 8, a plate-like insertion projecting from the rear end of the cap 5 where the protruding height of the crest of the cap 5 is lowered and projecting downward in a stepped manner toward the rear side. A claw 5B is formed, and an engaging claw 5C having a claw shape protruding forward is formed on the standing surface portion on the front end side where the protruding height of the mountain is high. The engaging claws 5C are formed with elasticity that can be bent and deformed in the front-rear direction with respect to the standing surface portion.

  As shown in FIG. 16, the cap 5 is attached to the base portion 4D as follows. First, the cap 5 is tilted so as to be rearwardly lowered, and the insertion claw 5B formed at the rear end portion of the cap 5 is inserted into the rear end portion of the base portion 4D. It is inserted into the hole 4D2 (the phantom line state in the figure). Next, using the inserted rear end (insertion claw 5B) as a fulcrum, the cap 5 is turned down so that the engagement claw 5C formed at the front end is connected to the front end of the base 4D. It pushes into engagement hole 4D3 formed in the part. As a result, the engaging claw 5C hits the vertical wall surface of the belt guide portion 4C of the lid cover 4 and is once squeezed, then expands in the engaging hole 4D3 and elastically engages with the engaging hole 4D3. It becomes a state (solid line state in the figure). As a result, the cap 5 is hooked on the base portion 4D so as to be prevented from coming off.

  When the cap 5 is assembled as described above, as shown in FIG. 1, the edge of the lid cover 4 on the vehicle body wall W side (the left side in the figure) protrudes from the rear end side toward the front end side. A belt guide portion 4C having a shape in which the height increases smoothly is formed. The protruding shape of the belt guide portion 4C is formed such that the width and height of the protrusion protruding in a mountain shape increase from the rear end side toward the front end side. By this protrusion, the belt guide portion 4C causes the seat belt WB to be pulled out from the outer rear part of the seat back SB toward the front side to the slope on the inner side of the protrusion, so that the seat belt WB is moved to the front surface of the seat back SB. It can be held in the state pulled out to the side.

  Accordingly, by hooking and holding the seat belt WB on the belt guide portion 4C, the seat back SB can be tilted forward while the seat belt WB is pulled out to the front side of the seat back SB. When raising the seat back SB that has been tilted, the edge of the back side of the seat back SB does not normally hit the tongue of the seat belt WB that is hung on the vehicle body wall W side. You can wake up smoothly.

  As shown in FIG. 2, the torsion spring 6 is set in a state of being twisted between the lever 3 and the base 2, so that the operator is applied to the lever 3 by the spring biasing force that is twisted. A spring biasing force is applied in the direction of gripping and rotating operation (counterclockwise direction in the drawing) to assist the rotation operation of the lever 3. The torsion spring 6 is twisted between the lever 3 and the lever 3 in advance as follows in order to make it easy to set the torsion spring 6 between the lever 3 and the base 2. After the lever 3 is assembled to the base 2, the other end 6B is detached from the temporary engagement portion 3E of the lever 3 as shown in FIG. Thus, the hooks can be hooked by a step-by-step operation of hooking on the main hook 2A2 of the base 2.

  Specifically, as shown in FIG. 5, the torsion spring 6 has a center at which a coiled portion 6 </ b> C wound around the lever 3 in a coil shape at the center projects from the side 3 </ b> B of the lever 3. One end 6 </ b> A that is passed through the shaft portion 3 </ b> C and bent into a hook shape is hooked and hooked into a concave hooking portion 3 </ b> D formed on the side portion 3 </ b> B of the lever 3. Thereby, the torsion spring 6 is temporarily held in a state in which one end 6 </ b> A and the winding portion 6 </ b> C are engaged with the lever 3. Next, the other end 6B that is the free end of the torsion spring 6 (the other end 6B in the phantom line state in the figure) is twisted with the one end 6A as a base point, and the other end 6A is moved to the one end 6A. Set in a state of being bent in the axial direction so as to be closer to the axial direction toward the axial direction, and hooked so as to be inserted into an L-shaped space of the temporary hooking portion 3E formed on the side portion 3B of the lever 3 To do. As a result, the torsion spring 6 is in a state where one end 6A and the other end 6B thereof are twisted into a state where the torsion spring 6 is hooked on the lever 3 (solid line state in the figure).

  Next, as shown in FIG. 12, the lever 3 with the torsion spring 6 hooked is set in the opening 2A of the base 2, and the lever 3 and the base 2 are inserted through the rotary shaft 3F described above. Are connected to each other. As a result, the lever 3 is in a state in which only the shaft 2 can rotate with respect to the base 2, and is in a state in which the lever 3 is prevented from coming off from the base 2. However, in this state, since the both ends of the torsion spring 6 are hooked on the lever 3, the spring biasing force is not exerted. With the above assembly, as shown in FIG. 17, the temporary hooking portion 3E formed on the side portion 3B of the lever 3 and the other end 6B of the torsion spring 6 hooked on the temporary hooking portion 3E (the phantom line state of FIG. ) Is set in a state of being exposed in a vertically long slit 2A1 penetrating the side surface of the base 2 (a state exposed to the outside). Further, in the slit 2A1, the main hook 2A2 formed on the base 2 described above forms the inner wall of the slit 2A1 so that the main hook 2A2 is also aligned with the temporary hook 3E in the axial direction. It protrudes from the wall surface. The temporary hooking portion 3E and the main hooking portion 2A2 are arranged apart from each other in the axial direction, and even if the temporary hooking portion 3E rotates integrally with the lever 3 by the rotation operation of the lever 3, The relationship does not interfere with each other.

  Next, a finger or an operation tool is inserted into the slit 2A1, and the other end 6B of the torsion spring 6 hooked on the temporary hook 3E is pushed into the back side (the back side of the paper). Remove from the temporary hook 3E. Then, the other end 6B of the torsion spring 6 is moved to the position on the right side in the figure where the main hook 2A2 of the base 2 is located, and the hand is released from the pushed operation at the moved position. As a result, as shown by the solid line state in FIG. 17, the other end 6B of the torsion spring 6 is hooked with its tip being inserted into the L-shaped space of the hook 2A2 by the spring biasing force. Becomes (becomes hooked). Specifically, the other end 6B of the torsion spring 6 is temporarily hooked in the axially bent state with respect to the temporary hook portion 3E of the lever 3 described above. As a result, the restoring force for returning to the free state moves in the axial direction (right side in the figure) where the main hook 2A2 of the base 2 is located. Therefore, the operation of removing the other end 6B of the torsion spring 6 from the temporary hooking portion 3E of the lever 3 and transferring the hooking to the main hooking portion 2A2 of the base 2 can be easily performed by an operation using the restoring force of the torsion spring 6. It can be carried out. Thus, the torsion spring 6 is in a state of being hooked between the lever 3 and the base 2, and is in a state in which a rotational urging force is applied in a direction (forward direction) in which the lever 3 is always rotated.

  Here, when the lever 3 is rotated by receiving the spring biasing force of the torsion spring 6, the movement in the forward rotation direction is such that the lever 3 hits the rubber 2G installed on the bottom plate portion 2F of the base 2 as shown in FIG. It has come to be accepted gently. As shown in FIG. 9, the lever 3 is connected to a lock device 10 provided on the seat back SB by a connecting rod 15, and the lock device 10 is locked to the striker ST provided on the vehicle body wall W described above. When in the activated state, the red display portion 3B1 is held in the rotational position state concealed in the slit 2A1 as being pushed up from the lower side by the connecting rod 15 against the spring biasing force of the torsion spring 6. ing. In this state, the lever 3 is in a state of receiving a rotational urging force by the torsion spring 6 in a direction opposite to the direction pushed upward from the lower side by the connecting rod 15, and there is no backlash due to the action of this urging force. In this state, the initial position is maintained.

  Then, by rotating the lever 3 from this state, the connecting rod 15 is pushed downward, and the lock device 10 is operated so as to release the locked state with the striker ST (see FIG. 10). And by this rotation operation, the red display part 3B1 of the lever 3 mentioned above will be in the state exposed outside from the opening part 2A, and it will be in the state displayed to the user that the locking device 10 is a release state. Even if the lever 3 is released after the release operation, the lever 3 is rotated (the red display portion 3B1 is an opening portion) due to the operation structure (see FIG. 11) in which the lock device 10 is held in the release state. 2A is exposed to the outside). The lever 3 is pushed up by the connecting rod 15 again as shown in FIG. 9 by pushing the seat back SB rearward and pushing the lock device 10 into the striker ST to lock it. Then, it is rotated to return to the initial position state before the rotation operation in which the red display portion 3B1 is hidden in the slit 2A1. As a result, the red display portion 3B1 is hidden in the slit 2A1, and the user can recognize that the lock device 10 is in the locked state.

  Next, the configuration of the locking device 10 will be described. As shown in FIGS. 9 to 11, the lock device 10 includes a base plate 11, a latch 12, a pole 13, and a tension spring 14. The base plate 11 is provided so as to be integrally fixed to the frame SF of the seat back SB, and has a recess 11A that can receive the striker ST at the rear edge thereof. The latch 12 is connected to the base plate 11 by a support shaft 12E so that the shaft can rotate. The latch 12 includes an upper jaw 12A, a lower jaw 12B, a hanging portion 12C, and a corner portion 12D. As shown in FIGS. 10 to 11, the upper jaw 12 </ b> A is held in a state of protruding into the recess 11 </ b> A of the base plate 11 described above when the lock device 10 is released, and the striker ST enters the recess 11 </ b> A. Accordingly, the latch 12 is pushed and rotated by this movement to rotate the latch 12 in the lock operating direction (clockwise direction in the drawing).

  As shown in FIG. 9, the lower jaw 12B is retracted to a position disengaged from the recess 11A of the base plate 11 when the lock device 10 is released, and the striker ST enters the recess 11A and the latch 12 rotates. In addition, the concave portion 11A is covered and locked behind the striker ST so as to prevent the striker ST from coming out of the concave portion 11A. One end of the tension spring 14 is hung on the hanging portion 12C. The corner portion 12D is formed in a stepped shape on the outer peripheral portion of the latch 12, and the striker ST enters the recess portion 11A as shown in FIG. 9 from the unlocked state of the locking device 10 as shown in FIG. When the latch 12 is rotated, a corner 13A of a pole 13 (described later) is dropped below the step, thereby restricting the return rotation of the latch 12.

  The pole 13 is arranged in the radial direction with the latch 12 described above, and is connected to the base plate 11 by a support shaft 13C so as to be axially rotatable. The pole 13 has a corner portion 13A and a hook portion 13B. As shown in FIG. 11, the corner portion 13 </ b> A is formed so as to protrude in a step shape on the side surface portion of the pole 13 formed in an arm shape, and when the lock device 10 is in the released state, the spring force of the tension spring 14 is used. These are held in a state of being pressed against the outer peripheral surface of the pole 13 described above. As shown in FIG. 9, when the striker ST enters the recess 11A and the latch 12 rotates, the corner 13A is rotated by the rotation of the tension spring 14 that receives the spring biasing force of the latch 12D. It is dropped below the step to restrict the return rotation of the latch 12, and the striker ST is held between the lower jaw 12B of the latch 12 and the recess 11A of the base plate 11 (locked state). The other end of the tension spring 14 is hooked on the hook portion 13B.

  One end and the other end of the tension spring 14 are hooked on the hook portion 12C of the latch 12 and the hook portion 13B of the pole 13, and the spring biasing force causes the latch 12 to rotate in the counterclockwise direction shown in the figure. The pole 13 is urged to rotate in the clockwise direction in the figure. As shown in FIG. 11, the rotation of the latch 12 with the counterclockwise biasing shown in the figure is locked at a position where the outer peripheral portion contacts the stopper portion 11 </ b> B of the base plate 11. . The position where the rotation of the latch 12 is locked is the position where the upper jaw 12A is held in a state of protruding into the recess 11A. Further, the rotation of the pole 13 accompanied by the clockwise urging shown in the figure is locked at a position where the corner portion 13A hits the outer peripheral surface of the latch 12, as shown in FIG.

  The connecting rod 15 is formed of a hard member that is difficult to bend and deform. The upper end of the connecting rod 15 is connected to the side of the lever 3 and the lower end of the connecting rod 15 is connected to the hook 13B of the pole 13 of the lock device 10. Yes. As shown in FIG. 9, the connecting rod 15 is rotated downward from the state where the locking device 10 is locked to the striker ST and is pushed downward (see FIG. 10). Is pushed in a direction against the urging force of the tension spring 14 (counterclockwise direction in the drawing), and the corner 13A of the pole 13 is dropped under the step of the corner 12D of the latch 12 and pulled out from the engaged position. As a result, the state in which the return rotation of the latch 12 is restricted by the corner portion 13A of the pole 13 (locked state) is released, and the latch 12 is rotated counterclockwise in the figure by the urging force of the tension spring 14, The striker ST is removed from the recess 11A.

  Here, in the rotation operation of the lever 3 for releasing the locked state of the locking device 10, as shown in FIG. 10, the side surface of the pole 13 pushed by the connecting rod 15 comes into contact with the stopper portion 11 </ b> C of the base plate 11. It can be done to the position. Then, after releasing the locked state of the locking device 10 by the rotation operation of the lever 3, the lever 3 is connected to the connecting rod 15 as shown in FIG. The corner portion 13A of the pole 13 is not locked under the step of the corner portion 12D of the latch 12, but hits the outer peripheral portion of the latch 12, and the return rotation is restricted, and the red display portion 3B1 is held as it is exposed to the outside from the opening 2A.

  Then, the lever 3 after the release operation pushes the seat back SB rearward in order to fix the backrest angle of the seat back SB, and the striker ST enters the recess 11A of the base plate 11 of the lock device 10. (See FIG. 9), and by turning the latch 12 and the pole 13 by this movement, they are pushed upward via the connecting rod 15, and the lock device 10 is locked to the striker ST. It is returned to the initial position before rotating.

  By the way, the seat back SB described above is configured such that the surface of the cushion pad SP is further covered with a cloth skin material SC as shown in FIGS. 1 and 13 to 14. Each edge SC1 of the skin material SC facing the recess SP1 is drawn into the operation portion structure 1 as it is fitted into the recess SP1 formed in the shoulder opening of the cushion pad SP. It is configured to be held in a hooked state. Hereinafter, a configuration in which each edge portion SC1 of the skin material SC is drawn into the operating portion structure 1 and held in a state of being engaged will be described.

  As shown in FIGS. 13 to 14, each edge portion SC <b> 1 of the skin material SC has an outer frame portion 2 </ b> C formed on the base 2 before the lid cover 4 is attached to the operation portion structure 1. By being pulled into the accommodating portion 2D between the inner frame portion 2B and mounting the lid cover 4 in this state, the height is increased between the outer frame portion 2C of the base 2 and the covering portion 4B of the lid cover 4. It is held in a retracted state in a state of being sandwiched in the vertical direction. Specifically, an L-shaped resin plate SC2 extending along the shape of each edge SC1 is integrally coupled to each edge SC1 of the skin material SC. Each of the resin plates SC2 is provided in a state of being bonded to the back surface of the skin material SC, and has a first surface portion SC2a extending in the pull-in direction TS of the skin material SC (in-plane direction of the skin material SC), and a first surface portion SC2a. It is formed in a hook shape (L-shaped in a cross-sectional view) having a second surface portion SC2b extending downward (standing downward in the figure) from the surface portion SC2a. Each of the resin plates SC2 is provided such that the first surface portion SC2a and the second surface portion SC2b are integrally bonded to each other so that the surfaces are overlapped with the back surface of the skin material SC.

  Each of the edge portions SC1 of the skin material SC to which the resin plate SC2 is coupled pulls each edge portion SC1, and the second surface portion SC2b that is bent to the lower side of each resin plate SC2 is connected to the outer frame portion 2C of the base 2. Even if each edge portion SC1 is pulled back in the in-plane direction by the tension applied to the skin material SC by setting it so as to drop into the accommodating portion 2D between the frame portion 2B, the second surface portion SC2b is not attached to the outer frame. It will not come off by being caught by the part 2C. Here, each resin plate SC2 has a hard structure that is difficult to bend and deform even when subjected to the tension applied to the skin material SC in a state where the second surface portion SC2b is hooked on the outer frame portion 2C. Further, when the second surface portions SC2b of the resin plates SC2 are hooked in the housing portion 2D of the base 2, the first surface portions SC2a ride on the upper portion of the outer frame portion 2C of the base 2. It can be assembled in a hanging state.

  Thereby, the lid cover 4 is attached to the upper part of the base 2 in the set state, so that each edge SC1 of the skin material SC becomes the outer frame portion 2C of the base 2 and the covering portion 4B of the lid cover 4. Is sandwiched in the height direction. Specifically, each edge portion SC1 of the skin material SC, together with the first surface portion SC2a of each resin plate SC2 that rides on the upper portion of the outer frame portion 2C of the base 2, and the outer frame portion 2C of the base 2 and the lid cover. 4 between the four covering portions 4B in the height direction. As described above, each edge portion SC1 of the skin material SC is strong in the gap between the outer frame portion 2C of the base 2 and the covering portion 4B of the lid cover 4 by the sandwiching structure in which the hard resin plate SC2 is interposed. It can be held in a state of being sandwiched by force.

  Thus, according to the operation part structure 1 of the present embodiment, the torsion spring 6 is hooked on the lever 3 in a state where the other end 6B is also twisted in addition to the hooking of the one end 6A. As a result, the two ends 6A and 6B are hung on and held by the lever 3, and are assembled to the base 2 together with the lever 3, and then the other end 6B is switched to be moved to the base 2. It is like that. In this way, the both ends 6A and 6B of the torsion spring 6 can be hung on the lever 3, so that it is possible to keep the torsion spring 6 in the lever 3 without continuously applying external force. Assembling the torsion spring 6 between the lever 3 and the base 2 in a simple manner by assembling the lever 3 to the base 2 and then moving the hook of the other end 6B to the base 2 Can do.

  Further, the other end 6B of the torsion spring 6 is hooked in a state of being bent in the axial direction with respect to the temporary hooking portion 3E of the lever 3, and by releasing the hook, the restoring force causes the temporary hooking portion 3E and the axial direction. The structure of being hooked to the main hook 2A2 while being urged toward the main hook 2A2 of the base 2 aligned with the base 2 makes it easier to transfer the hook of the other end 6B to the base 2. be able to.

  Next, the operation part structure 1 (hereinafter referred to as the operation part structure 1) of the vehicle seat according to the second embodiment will be described with reference to FIGS. As shown in FIG. 18, in the operation portion structure 1 of the present embodiment, the main hook portion 2A2 formed on the base 2 is axially disposed with respect to the temporary hook portion 3E formed on the side portion 3B of the lever 3. It is formed in a shape protruding to the position on the inner side (lower side in the figure) in the radial direction of the temporary hook 3E so as to be overlapped. Specifically, when the lever 3 is assembled to the base 2, the main hook 2 </ b> A <b> 2 is located on the back side of the paper with respect to the temporary hook 3 </ b> E (the other end 6 </ b> B of the torsion spring 6 in the rotation direction of the lever 3). Is disposed in the direction opposite to the direction of application of the spring biasing force (the front side direction in the figure), and the front surface portion of the paper facing the temporary hook portion 3E is hung on the temporary hook portion 3E. A tapered surface 2A2a is formed that moves and guides the other end 6B of the torsion spring 6 in a direction (left direction in the drawing) in which the lever 3 is further bent in the axial direction by rotating the lever 3 to the back side in the drawing (see FIG. 19). ).

  By forming the tapered surface 2A2a, as shown in FIG. 19, after the lever 3 is assembled to the base 2, the temporary hooking portion 3E is rotated by rotating the lever 3 to the back side (the direction in which the lever 3 is rotated). The other end 6B of the torsion spring 6 hung on is moved while being further bent in the axial direction on the taper surface 2A2a of the main hook 2A2, and moved to a position over the taper surface 2A2a, thereby moving the main hook 2A2. The state is reversed. This reverse rotation restores the deformation amount of the other end 6B of the torsion spring 6 which is deflected in the axial direction by the taper surface 2A2a, so that the rear surface of the main hook portion 2A2 (the back surface in FIG. 18, the paper surface in FIG. 19). It is in a state of being hung on the upper surface).

  Therefore, after the above operation, the lever 3 is now rotated back in the direction opposite to the rotation direction, so that the other end 6B of the torsion spring 6 is connected to the back surface of the main hook 2A2 as shown in FIG. And the temporary hook portion 3E is removed from the hook by the contact with the hook, and along with the release of this hook, the restoring force moves on the back surface of the main hook portion 2A2 in the axial direction (right direction in the drawing). When it has moved from the temporary hooking portion 3E to a position disengaged in the axial direction, it falls onto the stepped surface 2A2b formed in the concave shape of the main hooking portion 2A2 and is in a state where a spring biasing force is applied to the main hooking portion 2A2. It becomes wearing state.

  In this hooked state, the other end 6 </ b> B of the torsion spring 6 is disposed in an axially spaced relationship with the temporary hook 3 </ b> E, and the temporary hook 3 </ b> E is integrated with the lever 3 by the rotation operation of the lever 3. Even if it becomes and becomes a relationship, it does not interfere with each other. In this way, the main hook 2A2 is shaped to project to the radially inner position of the temporary hook 3E, and the taper surface 2A2a is provided on the main hook 2A2, so that the lever 3 is assembled to the base 2. The operation of moving the hook of the other end 6B of the torsion spring 6 can be performed simply by performing the operation of rotating the lever 3 from the left side.

  Next, the operation part structure 1 (hereinafter referred to as the operation part structure 1) of the vehicle seat according to the third embodiment will be described with reference to FIGS. As shown in FIG. 20, in the operation portion structure 1 of the present embodiment, the main hook portion 2A2 formed on the base 2 is in the axial direction with respect to the temporary hook portion 3E formed on the side portion 3B of the lever 3. It is formed in a shape protruding to the position on the inner side (lower side in the figure) in the radial direction of the temporary hook 3E so as to be overlapped. Specifically, when the lever 3 is assembled to the base 2, the main hook 2 </ b> A <b> 2 is located on the front side of the paper with respect to the temporary hook 3 </ b> E (the other end 6 </ b> B of the torsion spring 6 in the rotation direction of the lever 3). (Position on the side of the acting direction (front side direction in the figure) side) of the spring urging force applied to.

  With the configuration of the main hook 2A2, as shown in FIG. 21, after the lever 3 is assembled to the base 2, the lever 3 is rotated to the front side of the paper (opposite to the direction in which the lever 3 is rotated). The other end 6B of the torsion spring 6 hung on the temporary hook portion 3E is hooked to the temporary hook portion 3E by being caught by the back surface of the main hook portion 2A2 (the surface on the upper side in FIG. 21). When the hook is detached, the restoring force causes the back surface of the main hook portion 2A2 to move in the axial direction (right direction in the figure) and move from the temporary hook portion 3E to the position disengaged in the axial direction. Thus, the hook portion 2A2 is in a hooked state in which a spring biasing force is applied.

  In this hooked state, the other end 6 </ b> B of the torsion spring 6 is disposed in an axially spaced relationship with the temporary hook 3 </ b> E, and the temporary hook 3 </ b> E is integrated with the lever 3 by the rotation operation of the lever 3. Even if it becomes and becomes a relationship, it does not interfere with each other. As described above, the main hook 2A2 is formed so as to protrude to the radially inner position of the temporary hook 3E, so that only the operation of rotating the lever 3 after the lever 3 is assembled to the base 2 is performed. The operation of moving the hook of the other end 6B of the torsion spring 6 can be easily performed.

  As mentioned above, although embodiment of this invention was described using the three Examples, this invention can be implemented with various forms other than the said Example. For example, in each of the above-described embodiments, when the other end 6B of the torsion spring 6 is temporarily attached in a state of being twisted into the lever 3, it is applied by being bent in the axial direction. An example has been illustrated in which when the destination is moved to the base 2, it is possible to simply use the restoring force of the torsion spring 6. However, the other end of the torsion spring is not twisted in the axial direction in advance. When the hook is moved to, the operator's finger or instrument is used (Example 1) The taper surface of the main hook is used (Examples 2 and 3), and the other end of the torsion spring is moved in the axial direction. You may make it bend. In each of the above-described embodiments, the torsion spring 6 is hooked so as to urge the lever 3 in the direction in which the lever 3 is rotated with respect to the base 2, but is opposite to the direction in which the lever 3 is rotated. It may be hooked so as to be biased in the direction.

DESCRIPTION OF SYMBOLS 1 Operation part structure of vehicle seat 2 Base 2A Opening part 2A1 Slit 2A2 Main hook part 2A2a Tapered surface 2A2b Step surface 2B Inner frame part 2B1 Engagement claw 2C Outer frame part 2D Storage part 2E Mounting plate part 2F Bottom plate part 2G Rubber 3 Lever 3A Gripping part 3B Side part 3B1 Red display part 3C Central shaft part 3D Hanging part 3E Temporary hanging part 3F Rotating shaft 3F1 E-ring 4 Lid cover 4A Opening part 4B Cover part 4B1 Mounting frame part 4B2 Engagement hole 4C Belt guide part 4D base part 4D1 screw hole 4D2 insertion hole 4D3 engagement hole 5 cap 5A belt guide part 5B insertion claw 5C engagement claw 6 torsion spring 6A one end 6B other end 6C winding part 10 lock device 11 base plate 11A recess 11B stopper Part 11C Stopper part 12 Latch 12A Upper jaw 12B Lower jaw 12C Hanging part 12D Corner part 2E support shaft 13 pole 13A corner portion 13B hanging portion 13C support shaft 14 tension spring 15 connecting rod SB seat back SF frame SP cushion pad SP1 recess SC skin material SC1 edge SC2 resin plate SC2a first surface portion SC2b second surface portion WB seat belt W Body wall BS1, BS2 Screw TS Pull-in direction ST striker

Claims (2)

An operation unit structure for a vehicle seat in which a rotary operation type lever is connected to a base fixed to a seat frame so as to be axially rotatable by a rotation shaft,
Between the lever and the base, one end is hooked on the lever, the other end is hooked on the base, and a torsion spring that biases the lever in one direction is hooked.
The lever is formed with a hooking portion on which the one end of the torsion spring is hooked, and a temporary hooking portion that can be hooked with the other end of the torsion spring being screwed in, The torsion spring is configured to be switched so that the other end is hooked to the base after being assembled to the base together with the lever in a state where the both ends are hooked to the lever. The operation part structure of the vehicle seat. The vehicle seat operating portion structure according to claim 1,
The other end of the torsion spring is configured to be hooked in an axially bent state with respect to the temporary hooking portion of the lever, and the other end after the torsion spring is assembled to the base together with the lever. The main hook portion is urged toward the main hook portion of the base formed in parallel with the temporary hook portion by the restoring force by removing the hook of the temporary hook portion from the temporary hook portion. An operation portion structure for a vehicle seat, wherein the operation portion structure is adapted to be attached to a vehicle.

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