JP2016049796A - Vehicle seat - Google Patents

Abstract

PROBLEM TO BE SOLVED: To streamline an attachment structure for attaching a bracket and a motor unit to a seat frame.SOLUTION: A seat includes: a side frame 11 of a seat cushion; a motor unit 6D for tilting which is attached to the side frame 11; and a bracket 14 for assembling an outer shield to the side frame 11. The seat has an insertion type fastening structure CO for attaching the motor unit 6D for the tilting to the side frame 11. The bracket 14 is inserted into the insertion type fastening structure CO to be attached to the side frame 11 with the motor unit 6D for the tilting.SELECTED DRAWING: Figure 9

Description

  The present invention relates to a vehicle seat. More specifically, the present invention relates to a vehicle seat having a seat frame, a motor unit attached to the seat frame, and a bracket for assembling seat components to the seat frame.

  2. Description of the Related Art Conventionally, in a vehicle seat, a configuration is known in which a bracket for assembling seat components and a motor unit for driving a seat mechanism are attached to a side frame of a seat cushion (Patent Document 1). Each of the brackets and the motor unit described above is attached and fixed to the side frame using a plurality of pins.

JP 2013-129280 A

  However, in the above prior art, since the bracket and the motor unit are separately attached and fixed to the side frame, there is a problem that not only the number of parts increases but also the installation space becomes bulky. . The present invention has been devised to solve the above-described problems, and a problem to be solved by the present invention is to rationalize the mounting structure of the bracket and the motor unit to the seat frame.

  In order to solve the above problems, the vehicle seat of the present invention takes the following means.

  A first invention is a vehicle seat having a seat frame, a motor unit attached to the seat frame, and a bracket for assembling seat components to the seat frame. This vehicle seat has an insertion-type fastening structure for attaching the motor unit to the seat frame. A bracket is attached to the seat frame together with the motor unit through the insertion-type fastening structure.

  According to the first aspect of the present invention, the bracket can be attached to the seat frame by the insertion type fastening structure for attaching the motor unit to the seat frame. Therefore, it is possible to rationalize the mounting structure of the bracket and the motor unit with respect to the seat frame, and it is possible to keep the entire installation space small.

  The second invention is the following configuration in the first invention described above. The plug-in type fastening structure is configured with two fasteners. The bracket is fitted to the outer periphery of the first boss portion of the motor unit through which one of the two fasteners is passed, and the other of the two fasteners is passed through the motor unit. The second boss portion is attached to the seat frame by fastening two fasteners as being pressed between the second boss portion and the seat frame in the insertion direction.

  According to the second aspect of the invention, the bracket can be attached to the seat frame in a state where the bracket is not rattled in the axial direction and the radial direction. Further, the brackets can be installed together in the seat frame in a state in which the brackets are previously fitted into the first boss portions of the motor unit and temporarily held.

  The third invention is the following configuration in the second invention described above. The bracket has a fitting region that is fitted to the outer peripheral portion of the first boss portion of the motor unit with respect to a holding region that is pressed and sandwiched between the second boss portion of the motor unit and the seat frame. It is made into the shape bent in the step shape so that it might be deeply inserted in the outer peripheral part of a part.

  According to the third aspect of the present invention, when the bracket is fitted in the first boss portion of the motor unit in advance and temporarily held, the bracket is difficult to drop off from the first boss portion. It can be stabilized.

  A fourth invention is the following configuration in the above-described second or third invention. The first boss portion is made of resin, and the outer peripheral portion is filled in the radial direction with respect to the bracket by a compressive force accompanying fastening to the seat frame.

  According to the fourth invention, even if the first boss portion is designed to interfere with the bracket, the first boss portion and the bracket are less likely to be damaged. Therefore, it is possible to easily fit the bracket to the first boss portion with little backlash.

  According to a fifth invention, in any one of the second to fourth inventions described above, the following configuration is adopted. The 1st boss | hub part is made into the outer peripheral part shape which can be fitted in the state which stopped rotation of the bracket.

  According to the fifth aspect of the invention, the bracket is temporarily held in a state in which the bracket is prevented from rotating with respect to the first boss portion. Therefore, the bracket can be more easily installed on the seat frame.

  A sixth invention is the following configuration in any one of the second to fifth inventions described above. An outer peripheral region where the bracket of the first boss portion is fitted is formed in a tapered shape, and the outer peripheral region is radially spaced from the bracket by a compression force accompanying fastening to the seat frame. It comes to be stuffed.

  According to the sixth aspect of the invention, the bracket can be fitted to the first boss portion with less backlash.

1 is a perspective view illustrating a schematic configuration of a vehicle seat of Example 1. FIG. It is the perspective view which visualized and represented the principal part of the cushion frame. It is the perspective view which expanded and represented the attachment part of the motor unit. It is a perspective view showing the state which removed the motor unit from the side frame. It is a perspective view showing the state where the bracket was fitted to the motor unit and temporarily held. It is a perspective view showing the state which installed the motor unit in the side frame. It is the VII-VII sectional view taken on the line of FIG. It is the perspective view showing the state where the motor unit was bolted and fixed to the side frame. It is the IX-IX sectional view taken on the line of FIG.

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

  First, the configuration of the seat 1 (vehicle seat) according to the first embodiment will be described with reference to FIGS. As shown in FIG. 1, the seat 1 according to the present embodiment is configured as a driver's seat of an automobile, and includes a seat back 2 that serves as a backrest for a seated occupant and a seat cushion 3 that serves as a seating portion. It has become. The seat 1 has a so-called “power seat” configuration in which the backrest angle of the seat back 2 and the seating position of the seat cushion 3 can be adjusted by an electric operation by operating a switch, respectively. It has become.

  Specifically, the seat back 2 has a configuration in which the lower end portions of the left and right sides thereof are respectively connected to the rear end portions of the left and right sides of the seat cushion 3 via electric recliners (not shown). . As a result, the seat back 2 is normally held in a state in which the backrest angle is fixed by each of the above-mentioned recliners, and the backrest angle can be changed back and forth by electrically operating each recliner by operating a switch (not shown). The direction is adjusted. The seat cushion 3 is connected to a vehicle floor via a pair of left and right electric slide rails 4. As a result, the seat cushion 3 is normally held in a state where the seating position in the front-rear direction is fixed by each slide rail 4 described above, and by electrically operating each slide rail 4 by operating a switch (not shown), The seating position in the front-rear direction is adjusted.

  The seat cushion 3 has a configuration in which an electric seat lifter 5 is interposed between the pair of left and right slide rails 4 described above. As a result, the seat cushion 3 is normally held in a state in which its height position is fixed by the seat lifter 5 described above, and its height position is adjusted by electrically operating the seat lifter 5 by operating a switch (not shown). It has come to be. Further, the seat cushion 3 has a configuration in which an electric tilt mechanism 6 is provided at the front thereof. Thus, the seat cushion 3 is normally held in a state in which the support angle (support height) of the front part supporting the thigh of the seated occupant is fixed by the tilt mechanism 6 described above, and the operation of a switch (not shown) is performed. By operating the tilt mechanism 6 electrically, the support angle of the front portion is adjusted in the height direction.

  As described above, the seat 1 is configured to adjust the backrest angle of the seat back 2 (front and rear two directions), adjust the seating position of the seat cushion 3 (front and rear two directions and upper and lower two directions), and adjust the front of the seat cushion 3. It is configured to be able to adjust the support angle (up and down 2 directions) and perform an adjustment operation in 8 directions called “8 ways”. These adjustment operations are performed by an electric operation by operating a switch (not shown) provided at a predetermined location such as a side of the seat cushion 3 on the vehicle outer side (left side in the drawing).

  As will be described in detail later, the seat lifter 5 described above is interposed between each side frame 11 of the seat cushion 3 and each slide rail 4 on the floor. It has a configuration having a link 5A and a rear link 5B. The seat lifter 5 described above is configured as a pair of left and right four-bar linkage mechanisms that change the height position of the seat cushion 3 with respect to the floor by the link motion of the pair of left and right front links 5A and rear links 5B described above. Yes.

  Of the pair of left and right front links 5A and rear links 5B described above, the front link 5A and the rear link 5B disposed on the vehicle outer side on the left side in the drawing are the seat outer side (vehicle outer side) of the side frame 11 on the same side. It is provided in the position. Further, the front link 5A and the rear link 5B disposed on the vehicle inner side which is on the right side in the drawing are provided on the seat inner side (vehicle outer side) of the side frame 11 on the same side. The reason is that the arrangement position of the seat 1 in the seat width direction with respect to the floor is offset from the arrangement of the pair of left and right slide rails 4 so as to be closer to the vehicle inner side. The front link 5A and the rear link 5B on each side are individually connected to the side frame 11 on each side so as to be individually rotatable by bushes 5G and 5H made of circular steel pipes. Yes. Further, the front link 5A and the rear link 5B on each side are respectively rotatably connected to the upper part of the slide rail 4 on each side by rotating shafts 5J and 5K. .

  Each bush 5G that connects the upper end portion of each front link 5A to the side frame 11 on each side penetrates the upper end portion of each front link 5A and each side frame 11, and is outside in the axial direction (seat width direction). Are connected to each other and can be rotated. Each bush 5G is welded to a front pipe 5C inserted so as to be bridged between them, and is integrally coupled. As a result, each bush 5G has a flange portion 5G1 formed at the outer end portion in the axial direction (seat width direction), and the end portion outside the seat is the upper end portion of the front link 5A outside the vehicle or the vehicle. The upper end portions of the front links 5A are rotatably connected to the side frames 11 on each side so as not to come off from the inner side frames 11.

  On the other hand, the bushes 5H that connect the upper ends of the rear links 5B to the side frames 11 on the respective sides penetrate through the side frames 11 and the upper ends of the rear links 5B in the axial direction (seat width direction). However, it is welded integrally with the upper end of each rear link 5B and is connected to the side frame 11 on each side so as to be rotatable. Each bush 5H is also welded integrally with a rear pipe 5D inserted so as to be bridged therebetween. As a result, each bush 5H has a flange portion 5H1 formed at the outer end portion in the axial direction (seat width direction), and the end portion outside the seat is the upper end portion of the rear link 5B outside the vehicle or the vehicle. The upper ends of the rear links 5B are rotatably connected to the side frames 11 on each side so as not to come off from the inner side frames 11. Further, both the rear links 5B can rotate integrally with each other via the above-described rear pipe 5D. As a result, the rear links 5B have a high support rigidity that is rotated and stopped in an integrated manner by receiving a rotational driving force and a braking force output from a later-described lifter motor unit 5F. It has a configuration that can be demonstrated.

  Hereinafter, a specific configuration of each part of the seat cushion 3 described above will be described in detail. As shown in FIG. 1, the seat cushion 3 has a structure in which a metal cushion frame 10 constituting the skeleton is assembled in a square frame shape along the outer peripheral shape of the seat cushion 3. Specifically, the cushion frame 10 includes a pair of left and right side frames 11 and a front panel 12 that is bridged between the front end portions of the side frames 11 and supports the thighs of the seated occupant from below. A structure in which the front pipe 5C and the rear pipe 5D made of steel pipes are assembled in a state of being bridged between the front part and the rear part of each side frame 11 so that the whole is assembled in a square frame shape in a plan view. Has been.

  In addition, on the upper part of the cushion frame 10 described above, there is a cushion pad made of urethane foam (not shown) that can soften and receive the load received from the seated occupant, and a cushion cover made of cloth (not shown) that covers the entire surface of the seat cushion 3. Although attached, description of these specific configurations will be omitted. In addition, a resin shield SH that covers these from the outer peripheral side is attached to the front side portion and the left and right side portions of the seat cushion 3 described above.

  The shield SH includes a front shield (not shown) that covers the front side portion of the seat cushion 3, an inner shield (not shown) that covers the vehicle inner side portion of the seat cushion 3, and an outer shield 20 that covers the vehicle outer side portion of the seat cushion 3. And these are assembled into one. Among these, as shown in FIGS. 2 to 4 and 8, the outer shield 20 has its front portion (fitting portion 21) hooked on a bracket 14 attached to the front portion of the side frame 11 outside the vehicle. In addition, the rear portion is provided in a state of being fastened and fixed to the rear portion of the side frame 11 by a fastener such as a screw. The bracket 14 for latching the front portion (fitting portion 21) of the outer shield 20 is a plug-type fastening in which the tilt motor unit 6D for driving the tilt mechanism 6 is attached to the side frame 11. The structure CO is reasonably attached to the side frame 11 together with the tilt motor unit 6D. The above configuration will be described in detail later. Here, the tilting motor unit 6D corresponds to the “motor unit” of the present invention.

  By the way, each of the side frames 11 described above is formed by a single pressed steel plate material, and is cut into a plate shape that is long in the front-rear direction, and the inner side surfaces of the side frames 11 face in the sheet width direction. It is in a state of being arranged in a combined form. Each of the side frames 11 has a configuration in which the upper edge portion and the lower edge portion thereof are bent to the outside of the seat to increase the structural strength against bending and twisting.

  The front panel 12 is formed of a single pressed steel plate material in the same manner as each of the side frames 11 described above, and is cut into a long plate shape in the sheet width direction, and has a surface on the upper side of the sheet. It is set as the state arrange | positioned. The front panel 12 has its front edge and left and right edges bent to the lower side of the seat to increase the structural strength against bending and twisting, and the upper side and outer periphery of the seat on which the occupant sits. The edge is not formed to stand on the side.

  In addition, a recess 12D for incorporating an air bag unit (not shown) that prevents a seated occupant from entering when a frontal collision of the vehicle occurs is recessed in the seat width direction at the center of the upper surface of the front panel 12. It is formed into a shape. The front panel 12 has side edges on both the left and right sides of the front frame 12 at the middle in the front-rear direction of each side frame 11 by a rotating shaft 12B (pin) via an elongated tilt arm 12A extending rearward of the seat. The shafts are coupled so that they can rotate in the vertical direction.

  Each of the tilt arms 12A described above is formed of a pressed steel sheet material, and is cut into a plate shape that is long in the front-rear direction so that the surface overlaps the inner side surface of each side frame 11. It is in the state where it was stood and arranged. Each tilt arm 12A has a structure in which the upper edge portion thereof is bent to the outer side of the seat to increase the structural strength against bending and twisting. Each tilt arm 12A has the bent top plate surface portions positioned directly above the upper edge portions of the side frames 11 that are bent to the outside of the seat, and the left and right edges of the front panel 12. They are applied to the bottom of the part from the lower side and are integrally fastened by rivets.

  Each tilt arm 12A has a rear end portion rotatably connected to an intermediate portion of each side frame 11 by a rotation shaft 12B (pin). These rotary shafts 12B are in a state of being provided side by side at positions on the same axis. As a result, the front panel 12 is provided in a state where it can rotate in the height direction about the rotation shafts 12 </ b> B with respect to the side frames 11. With the above configuration, the tilt mechanism 6 is configured that can adjust the support angle for supporting the thigh of the seated occupant by changing the support angle of the front panel 12 in the height direction. The tilt-up and tilt-down operations for rotating the front panel 12 in the height direction described above are performed by a tilting motor attached to the inner side of the side frame 11 outside the vehicle shown on the left side in FIG. This is performed by driving the unit 6D.

  Specifically, as shown in FIG. 2, the tilt motor unit 6D described above is connected to the gear link 6A integrally coupled with the bush 5G coupled to the vehicle outer end of the front pipe 5C. Are connected in a state where power can be transmitted. The gear link 6A described above is rotated with respect to the side frame 11 on the same side integrally with the bush 5G by receiving power transmission from the motor unit 6D for tilt described above. By this rotation, the gear link 6A pushes up and down the tilt link 6C linked between the gear link 6A and the bottom portion of the front panel 12 to raise the support angle of the front panel 12 in the height direction. It is supposed to change.

  In addition, the gear link 6A described above is rotated integrally with the bush 5G connected to the vehicle inner end of the front pipe 5C by rotating the front pipe 5C integrally connected to the bush 5G described above. The follower link 6B that is coupled to each other is also rotated integrally. Like the gear link 6A, the driven link 6B is linked to a tilt link 6C with the front panel 12, and the front panel 12 is also raised and lowered from the inside of the vehicle along with the rotation. ing. The front panel 12 is moved up and down by stopping the driving of the tilting motor unit 6D, and by the braking force, the movement of the gear link 6A and the driven link 6B moving integrally therewith is stopped. It has come to be stopped.

  As shown in FIGS. 2 to 4, the tilting motor unit 6 </ b> D has columnar bosses 6 </ b> D <b> 1 formed so as to extend from the three outer peripheral regions of the resin housing toward the outside of the seat. -6D3 are respectively aligned with the three fastening holes 11A1 to 11A3 formed through the side frame 11, and the three fastening bolts B1 to B3 constituting the insertion type fastening structure CO are respectively inserted. By being fastened, the side frame 11 is attached to the inner side.

  Of the three bosses 6D1 to 6D3 described above, the front two bosses 6D1 and 6D2 are formed at relatively close positions in the front edge side region of the housing of the tilting motor unit 6D. Has been. The remaining one boss 6D3 on the rear side is formed in a rear edge region of the housing of the tilting motor unit 6D, and is formed at a position separated from the front two bosses 6D1 and 6D2 in the front-rear direction. Has been. The two front bosses 6D1 and 6D2 described above are fastened to the fastening holes 11A1 and 11A2 formed in the upper and lower portions near the front end of the side frame 11, and the rear one boss 6D3 is connected to the side frame 11. The bush 5G is fastened to a fastening hole 11A3 opened at a position obliquely below the front of the bush 5G, close to the place where the bush 5G is connected.

  The three boss portions 6D1 to 6D3 described above are each formed in a substantially cylindrical shape having round hole-like through holes 6D1a to 6D3a penetrating in the sheet width direction. And as shown in FIG. 4, the said 3 boss | hub parts 6D1-6D3 are in the state aligned with each fastening hole 11A1-11A3 of the side frame 11 mentioned above, and fastening bolt B1 from those edge parts inside a sheet | seat. ˜B3 are inserted and the fastening bolts B1 to B3 are fastened to the fastening holes 11A1 to 11A3 to be integrally fixed to the inner side portion of the side frame 11.

  2 to 4, among the three boss portions 6D1 to 6D3, the two boss portions 6D1 and 6D2 on the front side are provided with the outer frame described above between the side frame 11 serving as the attachment destination. The bracket 14 for latching the front part (fitting part 21) of the shield 20 is interposed and attached. Specifically, as shown in FIGS. 4 to 5, the bracket 14 has two front side bosses 6 </ b> D <b> 1 and 6 </ b> D <b> 2 aligned with the fastening holes 11 </ b> A <b> 1 and 11 </ b> A <b> 2 of the side frame 11. After being inserted into one of the bosses 6D1 and 6D2 (upper boss 6D1) and temporarily held, it is aligned with the fastening holes 11A1 and 11A2 of the side frame 11 together with the two front bosses 6D1 and 6D2. It is set to the state that was made.

  As shown in FIGS. 6 to 7, the bracket 14 described above has the two front bosses 6D1 and 6D2 aligned with the fastening holes 11A1 and 11A2 of the side frame 11, and the fastening bolts B1 and B2. Are fastened integrally to the side frame 11 together with the two front bosses 6D1 and 6D2. Here, the above-described front upper boss portion 6D1 corresponds to a “first boss portion” of the present invention, and the front lower boss portion 6D2 corresponds to a “second boss portion” of the present invention. 11 corresponds to the “seat frame” of the present invention, and the fastening bolts B1 and B2 correspond to the “fastener” of the present invention.

  Here, as shown in FIGS. 3 to 5, the bracket 14 described above is a part that is attached to the side frame 11 described above when a single steel plate material is half-cut or bent in the plate thickness direction. A stepped plate portion 14A having a level difference, and a latch plate portion 14B that is bent from the stepped plate portion 14A to the outside of the seat so as to be hooked on the fitting portion 21 of the outer shield 20. It is formed to have a shape.

  As shown in FIGS. 4 to 5, the stepped plate portion 14 </ b> A described above has a fitting region 14 </ b> Aa having an oval fitting hole 14 </ b> A <b> 1 in the center and a perfect circular through hole 14 </ b> A <b> 2 in the center. The sandwiching region 14Ab has a shape formed at a position offset in a step shape in the sheet width direction (plate thickness direction). In the bracket 14 described above, the oval fitting hole 14A1 formed in the fitting region 14Aa of the stepped plate portion 14A described above has the upper boss portion 6D1 of the two front boss portions 6D1 and 6D2 described above. It is temporarily held in a state in which it is fitted to the outer peripheral portion and prevented from rotating. Specifically, the outer peripheral portion of the upper boss portion 6D1 into which the fitting hole 14A1 is fitted has a length in which the distal end side region 6D1b into which the fitting hole 14A1 is fitted partially matches the fitting hole 14A1. The shape has a circular outer peripheral surface shape. In addition, the distal end side region 6D1b into which the fitting hole 14A1 in the outer peripheral portion of the upper boss portion 6D1 is fitted is formed in a shape in which the cross section is tapered toward the distal end side. The fitting hole 14A1 of the bracket 14 is formed so as to be loosely fitted at a place.

  Since the bracket 14 has a tapered shape as described above, when the fitting hole 14A1 is fitted into the outer peripheral portion of the upper boss portion 6D1, the fitting hole 14A1 of the bracket 14 is shaped more than that. The upper boss 6D1 can be inserted smoothly without being held by the tip of the lower boss 6D1. When the fitting hole 14A1 is fitted into the upper boss portion 6D1, the bracket 14 is prevented from rotating with respect to the upper boss portion 6D1, and is formed in the lower clamping region 14Ab. The through-hole 14A2 is positioned so as to be overlapped and matched with the through-hole 6D2a of the lower boss portion 6D2 in the axial direction.

  Here, as shown in FIG. 4, the through hole 14A2 is formed in a round hole shape that is slightly smaller than the outer peripheral portion of the lower boss portion 6D2. Therefore, the bracket 14 is in a state where the through hole 14A2 is aligned with the through hole 6D2a of the lower boss portion 6D2 in the axial direction, so that the clamping region 14Ab is formed on the distal end surface of the lower boss portion 6D2. It is in a state of abutting in the axial direction. In addition, the bracket 14 has a fitting hole 14A1 that gently engages with the outer peripheral portion of the upper boss portion 6D1 at a position where the clamping region 14Ab contacts the tip of the lower boss portion 6D2. It is configured to be held in a state (temporary holding state) that has received a resilient force.

  Further, the lower boss portion 6D2 has a length position that extends in the axial direction (sheet outer side) is shorter than the upper boss portion 6D1, and as shown in FIGS. When the bracket 14 is assembled, the clamping region 14Ab of the bracket 14 is in a surface contact state in the axial direction, so that the length position obtained by adding the plate thickness of the clamping region 14Ab of the bracket 14 in contact with the surface is the upper side. The boss 6D1 is aligned with the length position extending in the axial direction. Therefore, in the temporary holding state described above, by installing the front two boss portions 6D1 and 6D2 so as to be aligned with the fastening holes 11A1 and 11A2 of the side frame 11, the holding region 14Ab of the bracket 14 can be It will be in the state assembled | attached in the state pinched | interposed between the boss | hub part 6D2 and the side frame 11. FIG. In this state, the bracket 14 is inserted by inserting the fastening bolts B1 and B2 into the two front bosses 6D1 and 6D2 and fastening the fastening bolts B1 and B2 to the fastening holes 11A1 and 11A2 of the side frame 11, respectively. The two front bosses 6D1 and 6D2 and the side frame 11 are fixed in an integrated state with no backlash both in the axial direction (sheet width direction) and in the rotational direction.

  Here, as shown in FIG. 4, each of the fastening bolts B1 to B3 described above includes flanged flanged heads B1a to B3a, and shaft legs extending in a columnar shape in the axial direction from the heads B1a to B3a. It has the structure which has part B1b-B3b and screw part B1c-B3c which protrudes small in an axial direction from the center part of the front-end | tip of axial leg part B1b-B3b. The fastening bolts B1 to B3 are inserted into the through holes 6D1a to 6D3a of the boss portions 6D1 to 6D3 from the inside of the seat, and the screw portions B1c to B3c are inserted into the side frames. The boss portions 6D1 to 6D3 are integrally coupled to the side frame 11 by being screwed into and fastened to the fastening holes 11A1 to 11A3 that are formed in the through holes 11. Specifically, when the fastening bolts B1 to B3 are fastened as described above, the flanged flanged heads B1a to B3a are attached to the end faces in the axial direction of the boss portions 6D1 to 6D3. The bosses 6D1 to 6D3 are pressed and held in a state of being tightened in the axial direction between the heads B1a to B3a and the side frames 11.

  Each of the fastening holes 11A1 to 11A3 formed in the side frame 11 shown in FIG. 4 described above, as shown in FIG. 7 (parts of the fastening holes 11A1 and 11A2), By forming the rising portions 11B1 to 11B3 projecting in a cylindrical shape toward the surface, they are formed as through-holes formed in the inside. A female to which the threaded portions B1c to B3c (male screws) of the fastening bolts B1 to B3 described above can be screwed onto the inner peripheral surface of the holes of the rising portions 11B1 to 11B3 forming the fastening holes 11A1 to 11A3. Screws (not shown) are cut.

  As shown in FIGS. 6 to 7, the through hole 14A2 aligned with the through hole 6D2a of the lower boss portion 6D2 of the bracket 14 described above is passed through the through hole 6D2a of the lower boss portion 6D2. A round hole shape having an inner diameter substantially the same (slightly larger) as the outer diameter of the shaft foot B2b. The through hole 14A2 is inserted into the shaft foot B2b of the fastening bolt B2 passed through the through hole 6D2a of the lower boss portion 6D2, and is gently fitted into the shaft foot B2b. It is supposed to be in a state. Thereby, the bracket 14 is in a state of being strongly supported by the shaft foot B2b of the fastening bolt B2 passed through the through hole 14A2 so as not to be loose in the radial direction (FIGS. 8 to 9). reference). With the above-described fastening structure, the bracket 14 is passed through the insertion type fastening structure CO for attaching the tilt motor unit 6D to the side frame 11, and is firmly integrated with the side frame 11 together with the tilt motor unit 6D. It is supposed to be attached to the.

  Next, returning to FIGS. 1 to 2, the configuration of the sheet lifter 5 will be described. As described above, the seat lifter 5 includes a pair of left and right front links 5A and a pair of left and right rear links 5B interposed between the side frames 11 of the seat cushion 3 and the slide rails 4 on the floor. Furthermore, it has the bush 5G made from a circular steel pipe which connects the upper end part of each front link 5A to each side frame 11 so that rotation is possible. Furthermore, it has the bush 5H made from a circular steel pipe which connects the upper end part of each rear link 5B to each side frame 11 so that rotation is possible. Furthermore, it has the rotating shaft 5J which connects the lower end part of each front link 5A to the upper part of each slide rail 4 so that rotation is possible. Furthermore, it has the rotating shaft 5K which connects the lower end part of each rear link 5B to the upper part of each slide rail 4 so that rotation is possible.

  Furthermore, it has the front pipe 5C made from a circular steel pipe which connects each bush 5G which connects the upper end part of each front link 5A mentioned above to each side frame 11 in the mutually integral state. Furthermore, it has the rear pipe 5D made from a circular steel pipe which connects each bush 5H which connects the upper end part of each rear link 5B mentioned above to each side frame 11 in the mutually integral state. Furthermore, a gear link 5E that transmits a rotational driving force and a braking force to the rear link 5B outside the vehicle via the bush 5H is provided.

  The gear link 5E is integrally coupled to the bush 5H, and receives power transmitted from the lifter motor unit 5F attached to the outer portion of the side frame 11 outside the vehicle, thereby being integrated with the bush 5H. And rotates with respect to the side frame 11 on the same side. By this rotation, the gear link 5E integrally drives and rotates the vehicle outer rear link 5B integrally coupled with the above-described bush 5H, and the rear pipe 5D integrally coupled with the bush 5H is also integrated. Thus, the vehicle inner rear link 5B integrally coupled to the bush 5H coupled to the vehicle inner end of the rear pipe 5D is also integrally driven to rotate.

  By the above operation, both the rear links 5B and the front links 5A constituting these four-links are linked together to raise and lower the seating height of the seat 1. The movement of raising and lowering the seating height of the seat 1 is caused by the movement of the gear link 5E and each rear link 5B that moves integrally with the brake force by stopping the drive of the lifter motor unit 5F. Is stopped and stopped.

  Each of the slide rails 4 is disposed outside the vehicle, whereas the slide rail 4 disposed inside the vehicle is disposed at a position almost directly below the side frame 11 on the same side. In addition, the slide rail 4 is disposed at a position projecting outward (seat outer side) from the side frame 11 on the same side, and has a wide installation space in the seat width direction. However, even if the installation interval between the slide rails 4 is wider than that between the side frames 11 as described above, the front link 5A and the rear link 5B disposed outside the vehicle as described above. However, it is located on the outer side (seat outer side) from the side frame 11 on the same side, and is connected to the location where the bushes 5G and 5H extending from the side frame 11 on the same side extend to the seat outer side. Therefore, there is a dimensional difference in the seat width direction without adding another part such as a bracket for compensating for the dimensional difference in the seat width direction between the side frame 11 and the slide rail 4 on the same side. Each front link 5A and each rear link 5B can be easily assembled between each side frame 11 and each slide rail 4.

  Further, a metal support is provided between the front pipe 5C and the rear pipe 5D described above so that a cushion pad (not shown) assembled to the upper part of the cushion frame 10 of the seat cushion 3 can be widely and elastically received from below. Four springs 13 (S springs) are provided side by side in the seat width direction so as to be bridged in the front-rear direction. Each of the support springs 13 is formed in a wave-like shape in the seat width direction, and the front and rear ends thereof are pulled from the upper side to the front pipe 5C and the rear pipe 5D via the resin cap 13A. It is supposed to be hung and mounted. Thereby, even if each support spring 13 rotates the front pipe 5C and the rear pipe 5D by the operations of the seat lifter 5 and the tilt mechanism 6 described above, the support springs 13 do not follow these axial rotation movements and escape these movements. The front pipe 5C and the rear pipe 5D are always held in a fixed posture.

  In summary, the seat 1 (vehicle seat) of the present embodiment has the following configuration. That is, the seat 1 has an insertion-type fastening structure CO for attaching the tilting motor unit 6D (motor unit) to the side frame 11 (seat frame) of the seat cushion 3. A bracket 14 is attached to the side frame 11 together with the motor unit 6D for tilting through the insertion type fastening structure CO. With this configuration, the bracket 14 can be attached to the side frame 11 by the insertion type fastening structure CO for attaching the tilting motor unit 6D to the side frame 11. Accordingly, it is possible to rationalize the mounting structure of the bracket 14 and the tilting motor unit 6D with respect to the side frame 11, and it is possible to reduce the overall installation space.

  The plug-in type fastening structure CO includes two fastening bolts B1 and B2 (fasteners). The bracket 14 is fitted in the outer peripheral portion with respect to the boss portion 6D1 (first boss portion) of the tilting motor unit 6D through which one of the two fastening bolts B1 and B2 (fastening bolt B1) is passed. And between the side frame 11 with respect to the boss portion 6D2 (second boss portion) of the motor unit 6D for tilt through which the other (the fastening bolt B2) of the two fastening bolts B1 and B2 is passed. Are attached to the side frame 11 by fastening two fastening bolts B1 and B2. With such a configuration, the bracket 14 can be attached to the side frame 11 in a state in which the bracket 14 is not rattled in the axial direction and the radial direction. Further, the bracket 14 can be installed on the side frames 11 as a whole in a state in which the bracket 14 is previously fitted in the boss portion 6D1 of the tilt motor unit 6D and temporarily held.

  Further, the bracket 14 is fitted into the outer peripheral portion of the boss portion 6D1 of the tilt motor unit 6D with respect to the clamping region 14Ab pressed between the boss portion 6D2 of the tilt motor unit 6D and the side frame 11. The fitting region 14Aa is bent in a step shape so as to be deeply fitted into the outer peripheral portion of the boss portion 6D1. With such a configuration, when the bracket 14 is fitted in the boss 6D1 of the tilting motor unit 6D in advance and temporarily held, the bracket 14 is unlikely to fall off from the boss 6D1. The temporary holding of 14 can be stabilized.

  Further, the boss portion 6D1 is made of resin, and the outer peripheral portion is filled in the radial direction with respect to the bracket 14 by the compressive force accompanying the fastening to the side frame 11. With such a configuration, even if the boss portion 6D1 is designed to interfere with the bracket 14, the boss portion 6D1 and the bracket 14 are less likely to be damaged. Therefore, the bracket 14 can be easily fitted to the boss portion 6D1 in a state with little backlash.

  Further, the boss portion 6D1 has an outer peripheral shape (oval outer peripheral surface shape) that can be fitted in a state in which the bracket 14 is prevented from rotating. With such a configuration, the bracket 14 is temporarily held in a state in which the bracket 14 is prevented from rotating with respect to the boss portion 6D1. Therefore, the bracket 14 can be installed on the side frame 11 more easily.

  Further, an outer peripheral region in which the bracket 14 of the boss portion 6D1 is fitted is formed in a tapered shape, and the outer peripheral region has a diameter with respect to the bracket 14 due to a compression force accompanying fastening to the side frame 11. The gap is filled in the direction. With such a configuration, the bracket 14 can be fitted to the boss portion 6D1 in a state with less backlash.

  As mentioned above, although the embodiment of the present invention has been described using one example, the present invention can be implemented in various forms in addition to the above example. For example, the “vehicle seat” of the present invention can be applied to seats other than the driver's seat of an automobile, and is used for vehicles other than automobiles such as railways, and other vehicles such as airplanes and ships. It can be widely applied to sheets.

  In addition, the “seat frame” to which the motor unit and the bracket of the present invention are attached is not limited to the side frame outside the vehicle of the seat cushion, and may be any frame configured as a frame constituting the seat. Specifically, various frames and brackets that constitute a seat back and a seat cushion are included. The “motor unit” attached to the seat frame together with the bracket is not limited to a tilt motor unit, but includes various motor units such as a lifter motor unit and a slide motor unit for operating a slide rail. It can be applied. The “bracket” attached to the seat frame together with the motor unit is not limited to the one that attaches the outer shield to the side frame, but the front shield and inner shield can be attached to the seat frame, and the wire harness, various electrical components, etc. These various seat components can be used for assembling to the seat frame.

  Further, the “insertion type fastening structure (fastener)” for attaching the motor unit to the seat frame may be composed of other insertion type fastening structures (fasteners) such as rivets in addition to fastening bolts. Good. Further, the “bracket” is fitted to the outer peripheral portion of the first boss portion of the motor unit through which one of the two fasteners is passed and is prevented from rotating, and is also applied in the axial direction. As a state, the first boss portion may be assembled in a state of being sandwiched between the side frame and the side frame.

  In addition, the “bracket” includes a clamping region that is pressed between the second boss portion and the side frame, and a fitting region that is fitted to the outer peripheral portion of the first boss portion. It may be in the shape of a shape. Further, by changing the thicknesses of the sandwiching area and the fitting area, the fitting area may have a stepped shape that is deeply fitted into the outer peripheral part of the first boss part.

  Moreover, the 1st boss | hub part and 2nd boss | hub part of a motor unit may be formed with materials other than resin, such as a metal. Moreover, the outer peripheral part shape of the 1st boss | hub part made to fit in the state which stopped the bracket rotation was made into polygonal shapes, such as a triangle and a quadrangle other than an ellipse, and has unevenness in a part of shape. Any shape other than a perfect circle, such as a shape, may be used. In addition, the “first boss portion” may be assembled so that the bracket is fitted into the outer peripheral portion without stopping or temporarily holding the bracket. Further, a structure may be set in which a bracket is fitted to the outer peripheral portion and temporarily held between both the first boss and the second boss, or is pressed between the side frames.

  In addition, the structure in which the first boss portion is diametrically narrowed with respect to the bracket by fastening with an insertion-type fastening structure is accompanied by fastening in addition to tapering the distal end side region of the first boss portion. A structure utilizing a configuration in which the outer peripheral portion expands and deforms outward in the radial direction or the protrusion is press-fitted in the axial direction by a compressive force and the gap is filled in the radial direction may be used.

1 seat (vehicle seat)
2 Seat back 3 Seat cushion 4 Slide rail 5 Seat lifter 5A Front link 5B Rear link 5C Front pipe 5D Rear pipe 5E Gear link 5F Lifter motor unit 5G Bush 5G1 Flange 5H Bush 5H1 Flange 5J Rotating shaft 5K Rotating shaft 6A Tilting mechanism 6 Gear link 6B Follower link 6C Tilt link 6D Motor unit for tilting (motor unit)
6D1 boss (first boss)
6D2 boss (second boss)
6D3 Boss part 6D1a-6D3a Through-hole 6D1b Tip side area CO Insertion type fastening structure B1, B2 Fastening bolt (fastener)
B3 Fastening bolt B1a to B3a Head B1b to B3b Shaft foot part B1c to B3c Screw part 10 Cushion frame 11 Side frame (seat frame)
11A1 to 11A3 Fastening hole 11B1 to 11B3 Standing portion 12 Front panel 12A Tilt arm 12B Rotating shaft 12D Recess 13 Support spring 13A Resin cap 14 Bracket 14A Stepped plate portion 14A1 Fitting hole 14Aa Fitting region 14A2 Through hole 14Ab Holding region 14B Stop plate part 20 Outer shield 21 Fitting part SH Shield

Claims (6)

A vehicle seat having a seat frame, a motor unit attached to the seat frame, and a bracket for assembling seat components to the seat frame,
An insertion type fastening structure for attaching the motor unit to the seat frame;
A vehicle seat in which the bracket is attached to the seat frame together with the motor unit through the insertion-type fastening structure. The vehicle seat according to claim 1,
The plug-in type fastening structure comprises two fasteners;
The bracket is fitted on the outer peripheral portion with respect to the first boss portion of the motor unit through which one of the two fasteners is passed, and the other of the two fasteners is passed. The vehicle seat attached to the seat frame by fastening the two fasteners in a state of being sandwiched between the second boss portion of the motor unit and the seat frame in the insertion direction. . The vehicle seat according to claim 2,
The bracket is a fitting region that is fitted into an outer peripheral portion of the first boss portion of the motor unit with respect to a clamping region that is pressed and sandwiched between the second boss portion of the motor unit and the seat frame. However, the vehicle seat has a shape bent in a step shape so as to be deeply fitted into the outer peripheral portion of the first boss portion. The vehicle seat according to claim 2 or 3, wherein
The vehicle seat, wherein the first boss portion is made of a resin, and an outer peripheral portion thereof is radially filled with respect to the bracket by a compressive force accompanying fastening to the seat frame. The vehicle seat according to any one of claims 2 to 4,
A vehicle seat having an outer peripheral shape that allows the first boss to be fitted in a state in which the bracket is not rotated. The vehicle seat according to any one of claims 2 to 5,
An outer peripheral region in which the bracket of the first boss portion is fitted is formed in a tapered shape, and the outer peripheral region is set against the bracket by a compressive force accompanying fastening to the seat frame. A vehicle seat that is designed to be filled in the radial direction.

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