JP2018065546A - Seat slide device - Google Patents

Abstract

PROBLEM TO BE SOLVED: To provide a seat slide device which can change slide resistance caused when a seat is slid according to a situation.SOLUTION: A seat slide device 100 includes: a lower rail 1 fixed to a floor of a vehicle; and an upper rail 2 fixed to a seat ST of the vehicle and supported in a state where the upper rail 2 can move relative to the lower rail 1. The upper rail 2 is provided with a slide member 15 which contacts with a slid surface 3S of the lower rail 1 from above. The seat slide device 100 is configured so that slide resistance received by the slide member 15 when the upper rail 2 is moved is changed by a vertical load received by the seat ST.SELECTED DRAWING: Figure 1

Description

  The present invention relates to a seat slide device provided in a vehicle.

  The seat slide device is a device that enables a seat (seat) provided in a vehicle to move in the front-rear direction. The seat slide device has a lower rail that is fixed to the floor of the vehicle and an upper rail that is fixed to the bottom of the seat, and the upper rail is supported in a movable state with respect to the lower rail.

  In a normal state, the movement of the upper rail relative to the lower rail is restricted, that is, a locked state. Only when the occupant operates the lever and the locked state is released, the seat can be moved in the front-rear direction together with the upper rail.

  In the seat slide device described in Patent Document 1 below, when the seat is moved in the front-rear direction in the unlocked state, the sliding resistance when moving forward is more than the sliding resistance when moving backward. It is configured to be large. For this reason, even in a state where the lower rail is slightly inclined downward toward the front side, it is possible to prevent a phenomenon in which the seat slides due to its own weight due to the inclination. . That is, the stability of the slide movement in the unlocked state can be improved.

International Publication No. 2016/009495

  By the way, the operation of moving the unlocked seat back and forth may be performed while the occupant is seated on the seat or may be performed without being seated. In the former case, the passenger may feel uneasy if the moving speed of the seat becomes too high. For this reason, it is preferable that the sliding resistance during movement is increased to some extent so that the moving speed of the sheet is moderately suppressed. On the other hand, in the latter case, it is preferable that the sliding resistance during movement is low so that the occupant can move the seat with a light force.

  Also, even when the seat is moved back and forth while the occupant is seated, when the occupant is a child, the sliding resistance during movement is such that even a weak child can easily move the seat. A lower value is preferred. Thus, the preferable magnitude of the sliding resistance during the movement of the sheet varies depending on the situation.

  The present invention has been made in view of such problems, and an object of the present invention is to provide a seat slide device that can change the sliding resistance when the seat is slid according to the situation.

  In order to solve the above-described problems, a seat slide device according to the present invention is a seat slide device provided in a vehicle, which is fixed to a vehicle floor and fixed to the vehicle seat and moves relative to the lower rail. An upper rail supported in a possible state. The upper rail is provided with a sliding member that comes into contact with the sliding surface of the lower rail from above. It is configured to change.

  In the seat slide device having such a configuration, a sliding member is provided on the upper rail as a member for generating a sliding resistance when the seat is moved. The sliding member is in contact with the sliding surface of the lower rail from above. The sliding resistance when the seat is moved is generated as a sliding resistance that the sliding member receives when the upper rail is moved, that is, a frictional force. The sliding resistance varies depending on the vertical load that the sheet receives.

  For this reason, for example, when the occupant moves the seat without being seated on the seat, the vertical load received by the seat is reduced, and the sliding resistance received by the sliding member is also reduced. Similarly, when a light weight child is seated, the vertical load received by the seat is also reduced, and the sliding resistance received by the sliding member is also reduced. On the other hand, when an adult with a heavy weight is seated, the load in the vertical direction that the seat receives increases, and the sliding resistance that the sliding member receives also increases.

  Thus, in the seat slide device having the above configuration, the sliding resistance when the seat is slid can be appropriately changed according to the situation.

  ADVANTAGE OF THE INVENTION According to this invention, the seat slide apparatus which can change the sliding resistance at the time of sliding a sheet | seat according to a condition is provided.

It is a figure which shows the whole shape of the seat slide apparatus which concerns on 1st Embodiment of this invention. It is a figure which shows the internal structure of the seat slide apparatus shown by FIG. It is sectional drawing for demonstrating the function of the locking member of the seat slide apparatus shown by FIG. It is sectional drawing for demonstrating the function of a movable member. It is sectional drawing for demonstrating the function of a movable member. It is a perspective view which shows the shape of a movable member and a slider. It is a figure for demonstrating the sliding resistance at the time of sliding a sheet | seat. It is a figure which shows the whole shape of the seat slide apparatus which concerns on 2nd Embodiment of this invention. It is a figure for demonstrating the sliding resistance at the time of sliding a sheet | seat. It is a figure which shows the internal structure of the seat slide apparatus which concerns on 3rd Embodiment of this invention. It is a figure which shows the internal structure of the seat slide apparatus which concerns on 3rd Embodiment of this invention. It is a figure which shows the internal structure of the seat slide apparatus which concerns on 3rd Embodiment of this invention. It is a figure which shows the shape of the part except a lower rail among the seat slide apparatuses which concern on 4th Embodiment of this invention. It is a figure which shows the shape of the part except a lower rail among the seat slide apparatuses which concern on 4th Embodiment of this invention. It is a figure which shows the shape of the part except a lower rail among the seat slide apparatuses which concern on 4th Embodiment of this invention. It is a figure which shows the structure of the plate member and sliding member of the seat slide apparatus which concerns on 4th Embodiment of this invention.

  Hereinafter, embodiments of the present invention will be described with reference to the accompanying drawings. In order to facilitate the understanding of the description, the same constituent elements in the drawings will be denoted by the same reference numerals as much as possible, and redundant description will be omitted.

  The configuration of the seat slide device 100 according to the first embodiment of the present invention will be described with reference mainly to FIG. The seat slide device 100 is a device that is provided between a vehicle floor and a seat (both not shown) and supports the seat in a state in which the seat can move (slide) in the front-rear direction. The seat slide device 100 includes a lower rail 1 and an upper rail 2. Two combinations of the lower rail 1 and the upper rail 2 are provided for one seat.

  The lower rail 1 is a member fixed to the floor of the vehicle. The two lower rails 1 provided on the lower side of one seat are provided so as to be lined up in the left-right direction with their respective longitudinal directions aligned with the longitudinal direction of the vehicle.

  In FIG. 1, the x-axis is set with the direction from the rear side to the front side of the vehicle as the x direction. The y-axis is set with the direction from the right side to the left side of the vehicle as the y direction. Furthermore, the z-axis is set with the direction from the lower side to the upper side of the vehicle as the z direction. In the subsequent drawings, the x axis, the y axis, and the z axis are similarly set.

  The upper rail 2 is a member fixed to the vehicle seat. The upper rail 2 is fixed to the bottom surface of the seat. The two upper rails 2 fixed to one seat are provided so as to be lined up in the left-right direction with their respective longitudinal directions aligned with the vehicle front-rear direction. The upper rail 2 is supported so as to be movable along the x-axis with respect to the lower rail 1 provided on the lower side thereof.

  The configuration of the lower rail 1 will be described. As shown in FIGS. 3A and 3B, the lower rail 1 is entirely formed of a metal plate. The lower rail 1 has a bottom plate portion 3, a side plate portion 4, an upper plate portion 5, and a mouth plate portion 6.

  The bottom plate portion 3 is a portion on the most −z direction side of the lower rail 1 and is a portion that is directly fixed to the floor. The bottom plate part 3 has a generally horizontal flat plate shape as a whole. The side plate portion 4 is a portion formed so as to extend in the z direction from each of the y direction side end portion and the −y direction side end portion of the bottom plate portion 3. FIG. 1A shows a state in which a part of the side plate portion 4 is cut out so that the arm plate portion 14 and the like disposed inside the lower rail 1 can be seen.

  The upper plate part 5 is a part formed so as to extend from the z direction side end of each side plate part 4 toward the center side in the y direction. The upper plate portion 5 is provided along a horizontal plane and faces the bottom plate portion 3. A surface on the −z direction side of the upper plate portion 5, that is, a lower surface is a contacted surface 5 a with which a movable member 29 described later contacts. FIG. 1B shows a state in which a part of the upper plate portion 5 is cut away so that an arm plate portion 14 and the like (described later) arranged inside the lower rail 1 can be seen.

  The mouth plate portion 6 is a portion formed so as to extend in the −z direction from the end portion of the upper plate portion 5 on the side opposite to the side plate portion 4. The respective mouth plate parts 6 are separated from each other, and each face the side plate part 4. A gap is formed between the end portion on the −z direction side of the mouth plate portion 6 and the bottom plate portion 3.

  A plurality of rectangular openings 10 are formed on the side of the pair of mouth plate portions 6 arranged on the y direction side. As shown in FIG. 1A, the openings 10 are formed in a line along the x direction. The opening 10 is a hole through which a claw portion 18a of a lock member 18 described later is inserted.

  Among the spaces formed inside the lower rail 1, a space surrounded by the bottom plate portion 3, the side plate portion 4, the upper plate portion 5 and the mouth plate portion 6 is a space 9 in FIGS. 3 (a) and 3 (b). It is shown. A space sandwiched between the bottom plate portion 3 and the pair of mouth plate portions 6 is shown as a space 7 in FIGS. Further, an opening sandwiched between the pair of upper plate portions 5, that is, an opening formed on the upper end side of the space 7 is shown as an opening 8 in FIGS.

  The configuration of the upper rail 2 will be described. As shown in FIGS. 3A and 3B, the upper rail 2 is formed by combining two metal plates 11. The upper rail 2 has a side plate portion 13 and an arm plate portion 14 in the −z direction side portion.

  The side plate portion 13 is a portion of the metal plate 11 that is inserted from the opening 8 into the space 7. The side plate portion 13 is provided so that most of the side plate portion 13 is parallel to the mouth plate portion 6 and faces the mouth plate portion 6. A plurality of rectangular openings 13a are formed on the side plate 13 that is disposed on the y-direction side. The openings 13a are formed in a line along the x direction. The shape and arrangement interval of each opening 13a are substantially equal to the shape and arrangement interval of the opening 10. Similar to the opening 10, the opening 13 a is a hole through which the claw portion 18 a of the lock member 18 is inserted. In addition, the space pinched | interposed between a pair of side-plate parts 13 is shown as the space 12 in Fig.3 (a) (b).

  The vicinity of the end portion on the −z direction side of the side plate portion 13 is bent so as to spread outward along the y axis. The arm plate portion 14 is a portion formed so as to extend from the bent portion through the space 9 toward the z direction side. The arm plate portion 14 is parallel to the mouth plate portion 6 and is provided to face the mouth plate portion 6 in the space 9. A plurality of rectangular openings 14 a are formed in the pair of arm plate portions 14 arranged on the y direction side. The openings 14a are formed in a line along the x direction. The shape and arrangement interval of each opening 14 a are equal to the shape and arrangement interval of the opening 10. Further, the x coordinate of the position where each opening 14 a is formed is equal to the x coordinate of the position where the opening 13 a is formed in the side plate portion 13. The opening 14a is a hole through which the claw portion 18a of the lock member 18 is inserted, like the opening 10 and the opening 13a.

  A sliding member 15 is fixed to the surface of the arm plate portion 14 that faces the side plate portion 4. The sliding member 15 is a plate-like member made of resin, and the shape when viewed from the y direction is a trapezoid. The lower surface 15S of the sliding member 15 is a flat surface and is a portion that becomes the base of the trapezoid. The lower surface 15 </ b> S protrudes further downward than the lower end of the arm plate portion 14. The entire lower surface 15S is in contact with the upper surface of the bottom plate portion 3.

  A shaft SH that is a columnar member is fixed to the side plate portion 4. The shaft SH is provided so as to protrude outward from the side plate portion 4 with its central axis being along the y-axis. Each sliding member 15 is formed with a circular through hole, and a shaft SH is inserted through the through hole. That is, each sliding member 15 is fixed to the side plate portion 4 of the upper rail 2 by being fitted to the shaft SH from the side.

  The entire sliding member 15 may be formed of resin, but only the portion that contacts the upper surface of the bottom plate portion 3 (sliding surface 3S described later) is formed of resin, and the other portions. May be formed of another material.

  As shown in FIG. 1B, two sliding members 15 are arranged along the x direction on the arm plate portion 14 on the y direction side. On the other hand, in the arm plate portion 14 on the −y direction side, one sliding member 15 is disposed at a position that is the center in the x direction. The upper rail 2 is supported from below by these three sliding members 15. Thus, a plurality of sliding members 15 are provided along the moving direction (x direction) of the upper rail 2.

  In the following description, the portion of the upper surface of the bottom plate portion 3 that is in contact with the lower surface 15S of the sliding member 15 is referred to as a “sliding surface 3S”. Of the three sliding members 15, the one arranged closest to the x direction is also referred to as “sliding member 151”, and the one arranged in the center is also referred to as “sliding member 152”. What is arranged on the −x direction side is also referred to as “sliding member 153”.

  Each sliding member 15 is in contact with the sliding surface 3S of the lower rail 1 from above. When the sheet moves in the front-rear direction, each sliding member 15 moves along the x-axis while sliding on the sliding surface 3S. At this time, since a frictional force is generated between the lower surface 15S and the sliding surface 3S, the upper rail 2 moves while receiving a sliding resistance due to the frictional force. The effect of providing such a sliding member 15 will be described later.

  The lock member 18 will be described. The lock member 18 is a member that performs an operation of switching between a locked state in which the movement of the upper rail 2 is restricted and an unlocked state in which the movement of the upper rail 2 is allowed. FIG. 3 (a) shows the locked state, and FIG. 3 (b) shows the unlocked state. As shown in both drawings, the lock member 18 is formed of a bent metal plate. The lock member 18 is attached to the one disposed on the y-direction side of the pair of metal plates 11 via the bracket 17. The bracket 17 supports the lock member 18 in a rotatable state by a rotation shaft 19 parallel to the x-axis.

  The lock member 18 has a claw portion 18a and an operation portion 18b. A plurality of claw portions 18 a are formed at the end of the lock member 18. Each claw portion 18a has a strip shape and is arranged in a line along the x-axis. Moreover, the width | variety (dimension in x direction) of each nail | claw part 18a is slightly smaller than each width | variety of the opening 13a, the opening 10, and the opening 14a. Furthermore, the arrangement interval of the claw portions 18a is equal to the arrangement interval of the openings 10 and the like. As shown in FIG. 3A, in the locked state, the claw portion 18a penetrates all of the opening 13a, the opening 10, and the opening 14a. Thereby, the movement of the upper rail 2 with respect to the lower rail 1 is controlled.

  The operation portion 18b is a portion of the lock member 18 that is formed at the end opposite to the claw portion 18a across the rotation shaft 19. A handle 20 that is a part operated by the occupant is connected to the operation unit 18b. When the occupant operates the handle 20 from the locked state of FIG. 3A, the lock member 18 rotates around the rotation shaft 19, and the claw portion 18a is extracted from the opening 13a, the opening 10, and the opening 14a. That is, the unlocked state is established (FIG. 3B). Thereby, the movement restriction | limiting of the upper rail 2 with respect to the lower rail 1 is cancelled | released, and the upper rail 2 will be in the state which can move along an x-axis.

  As shown in FIGS. 1A and 1B, one end of a coil spring 21 is connected to the lock member 18 in the vicinity of the operation portion 18b. The other end of the coil spring 21 is connected to the vicinity of the end of the upper rail 2 on the z direction side. The operating portion 18b is biased toward the z direction by the coil spring 21. Therefore, when the occupant is not operating the handle 20, the state in which the claw portion 18a is inserted through the opening 13a or the like, that is, the locked state in FIG.

  Next, an internal configuration of the seat slide apparatus 100 will be described with reference mainly to FIG. 2A and 2B, a part of the pair of metal plates 11 arranged on the y direction side, and the y direction side of the lower rail 1 (side plate portion 4, upper plate portion). 5, a state in which part of the mouth plate 6) is cut out is shown. FIG. 2A shows the locked state, and FIG. 2B shows the unlocked state.

  A pair of levers 22 are provided at positions on both sides of the lock member 18 along the x-axis. Each lever 22 is a substantially flat member, and is attached to the metal plate 11 via the rotating shaft 23 in a state where the normal direction thereof is along the y-axis. The rotating shaft 23 is an axis along the y axis. The lever 22 is attached around the rotation shaft 23 in a rotatable state. As shown in FIG. 3, the lever 22 is accommodated in a gap formed between the pair of metal plates 11. As shown in FIG. 2, the shapes of the respective levers 22 are symmetrical to each other.

  The lever 22 has an upper arm portion 24, a transmission portion 24 a, and a lower arm portion 25. The upper arm portion 24 is a portion that protrudes further toward the z-direction side at the z-direction end portion of the lever 22. One end of a coil spring 28 is connected to the upper arm portion 24 of each lever 22. By the coil spring 28, each upper arm part 24 receives force in a direction approaching each other.

  The transmission part 24 a is a part that protrudes toward the lock member 18 at a position lower than the upper arm part 24. In the locked state of FIG. 2A, the transmission portion 24a and the lock member are separated from each other. The upper arm portions 24 are in a state of approaching each other by the force of the coil spring 28.

  The lower arm portion 25 is a portion that protrudes further toward the −z direction side at the −z direction side end portion of the lever 22. One end of a slider 26 is connected to each lower arm 25 in a rotatable state. The slider 26 is a rod-like member that is arranged with its longitudinal direction along the x-axis. A movable member 29 is provided at the end of the slider 26 opposite to the lower arm 25. Specific configurations of the slider 26 and the movable member 29 will be described later.

  As shown in FIG. 2B, when the operation portion 18 b of the lock member 18 is lifted in the z direction and becomes unlocked, the lock member 18 comes into contact with the transmission portion 24 a, and the transmission portion 24 a is lifted together with the lock member 18. It is done. Thereby, each upper arm part 24 moves in the direction away from each other while resisting the force of the coil spring 28. Moreover, since the lever 22 rotates, each lower arm part 25 moves to the direction which mutually approaches. As a result, each slider 26 and movable member 29 move toward the lock member 18 side. Further, when returning from the unlocked state to the locked state, each slider 26 and the movable member 29 move in a direction away from the lock member 18.

  The configuration of the slider 26 and the movable member 29 will be described with reference to FIGS. The actual shapes of the slider 26 and the movable member 29 are the shapes shown in the perspective view of FIG. 6B, but these shapes are schematically shown in FIGS. FIG. 6A shows an exploded view of a state in which a part of the movable member 29 (a hard member 35 described later) is removed.

  As shown in FIGS. 6A and 6B, in this embodiment, most of the movable member 29 (excluding the hard member 35) and the slider 26 are integrally formed of resin. The movable member 29 has an intermediate part 30 and an arm part 31.

  The intermediate portion 30 is a portion connected to the end portion of the slider 26 and supports a pair of arm portions 31. As shown in FIGS. 4A and 4B, the intermediate portion 30 (and the slider 26) is accommodated in the space 7.

  The arm portion 31 is provided on both the y direction side and the −y direction side of the intermediate portion 30. Each arm portion 31 and the intermediate portion 30 are connected by a support portion 301 that extends along the y-axis from the −z direction side end portion of the intermediate portion 30. As shown in FIGS. 4A and 4B, the respective arm portions 31 are accommodated in the space 9. Further, each support portion 301 is disposed at a position between the end portion on the −z direction side of the mouth plate portion 6 and the bottom plate portion 3.

  In FIGS. 4A and 4B and FIGS. 6A and 6B, a groove-like space surrounded by the arm portion 31, the support portion 301, and the intermediate portion 30 is shown as a passage 32. The passage plate 32 accommodates the mouth plate portion 6 of the lower rail 1.

  The arm portion 31 is formed with a through-hole 33 having a rectangular cross section that penetrates substantially along the x-axis. The guide portion 16 formed at the end portion of the arm plate portion 14 is inserted into the through hole 33. As shown in FIGS. 5A and 5B, the guide portion 16 has a smaller dimension (width) along the z-axis than other portions of the arm plate portion 14. In addition, the longitudinal direction of the guide portion 16 is inclined with respect to the x-axis so that the guide portion 16 approaches the upper plate portion 5 toward the distal end side. An end surface on the z direction side of the guide portion 16 is an inclined surface 16 a formed on a part of the upper rail 2. The inclined surface 16a is a surface that is inclined with respect to the horizontal plane so that the inclined surface 16a is directed toward the z direction as the distance from the lock member 18 increases.

  The inner wall surface of the through hole 33 is substantially parallel to the surface of the guide portion 16 facing the inner wall surface. For this reason, the inner wall surface (that is, the top surface) of the through hole 33 on the z direction side is an inclined surface in the same manner as the inclined surface 16a. The same applies to the inner wall surface (that is, the bottom surface) of the through hole 33 on the −z direction side.

  A through hole 31 a penetrating in the z direction is formed in the arm portion 31 at a position opposite to the intermediate portion 30 with the through hole 33 interposed therebetween. A portion closer to the side plate portion 4 than the through hole 31 a is an elastic wall 34. The elastic wall 34 is in contact with the inner wall surface of the side plate portion 4.

  Before the movable member 29 and the slider 26 are accommodated in the lower rail 1, the width of the movable member 29 along the y direction is slightly larger than the width of the space sandwiched between the pair of side plate portions 4. Yes. For this reason, in a state where the movable member 29 and the slider 26 are housed inside the lower rail 1, the respective elastic walls 34 are elastically deformed toward the intermediate portion 30 side. For the same reason, the support portion 301 is also slightly elastically deformed. Since most of the movable member 29 is formed of resin, the movable member 29 is configured to be able to absorb an error in dimensional accuracy by its elastic deformation.

  4A and 5A show the locked state, and FIGS. 4B and 5B show the unlocked state. In the unlocked state shown in FIG. 4B and the like, a gap is formed between the movable member 29 and the inner wall surface of the upper plate part 5 (hereinafter referred to as “contacted surface 5a”). ing. That is, the movable member 29 that is a member held by the upper rail 2 is in a state of being separated from the abutted surface 5 a that is a part of the lower rail 1. For this reason, no frictional force or the like is generated between the movable member 29 and the abutted surface 5a, and the lower rail 1 can move smoothly along the x-axis.

  When the occupant operates the handle 20 to switch from the unlocked state to the locked state, the movable member 29 moves away from the lock member 18 as described above. At this time, as shown in FIG. 5A, since the movable member 29 moves along the inclined surface 16a, the gap between the movable member 29 and the abutted surface 5a gradually decreases, Eventually it becomes zero. At this time, the movable member 29 is sandwiched between the inclined surface 16a and the contacted surface 5a like a wedge and is in contact with and pressed against the contacted surface 5a. As a result, a force along the z direction and a frictional force along the x direction act between the movable member 29 and the contacted surface. Thereby, rattling (relative displacement along the z-axis) between the lower rail 1 and the upper rail 2 is suppressed.

  As described above, in this embodiment, an interlocking mechanism (a mechanism including the lever 22, the slider 26, and the guide portion 16) that moves the movable member 29 along the movement direction of the upper rail 2 in conjunction with the movement of the lock member 18. It has. When the interlocking mechanism moves the movable member 29, the movable member 29 is guided along the inclined surface 16a formed on the upper rail 2, thereby changing the distance between the movable member 29 and the contacted surface 5a. It is the composition to do. With such a configuration, it is possible to smoothly move the upper rail 2 in the unlocked state, but it is possible to suppress rattling of the upper rail 2 in the locked state.

  When the deformation of the movable member 29 hardly causes a problem, the entire movable member 29 may be formed of resin. However, when the entire movable member 29 is formed of resin, relatively soft resin is sandwiched between the inclined surface 16a and the contacted surface 5a in the locked state. When the vehicle travels in this state, the movable member 29 made of resin may be deformed by the influence of vibration and may be pushed deeper between the inclined surface 16a and the contacted surface 5a. In this case, the movable member 29 is sandwiched with a strong force between the inclined surface 16a and the contacted surface 5a. After this state, when the occupant operates the handle 20 to switch from the locked state to the unlocked state, the handle 20 is affected by the fact that the movable member 29 is strongly sandwiched as described above. The force necessary for the operation of the vehicle, that is, the force to be applied by the occupant increases. As a result, the passenger may feel uncomfortable.

  Further, depending on how the movable member 29 is deformed or bent due to the vibration of the vehicle, a gap is generated between the movable member 29 and the abutted surface 5a, and an abnormal noise due to the rattling of the upper rail 2 is generated. There is also a possibility of end. As a result, there is a risk of discomfort to the passenger.

  Therefore, in the present embodiment, by forming a part of the movable member 29 that is sandwiched between the inclined surface 16a and the contacted surface 5a with a member that is harder than the other parts, the above-described problem occurs. Has solved.

  As shown in FIG. 6A, a through hole 310 that penetrates the portion along the z axis is formed in a portion of the arm portion 31 that is on the z direction side of the through hole 33. The through hole 310 is connected to the inside of the through hole 33. The hard member 35 is fitted into the through hole 310 from the z direction side. The through hole 310 is a stepped hole, and the hard member 35 does not fall into the through hole 33. In the present embodiment, the hard member 35 is made of metal (harder than resin). The surface 351 on the z direction side of the hard member 35 faces the abutted surface 5 a of the lower rail 1. That is, the surface 351 of the hard member 35 is a portion that contacts the abutted surface 5a in the locked state.

  Further, the surface 352 on the −z direction side of the hard member 35 is a surface that partitions the z direction side of the through hole 33. For this reason, as shown in FIGS. 4A and 4B and FIGS. 5A and 5B, the inclined surface 16 a is in contact with the surface 352 of the hard member 35.

  In the locked state shown in FIGS. 4A and 5A, the hard member 35 is sandwiched between the inclined surface 16a and the contacted surface 5a. The hard member 35 is less likely to be deformed than a resin and is less likely to bend. For this reason, even if the vibration of the vehicle occurs, the movable member 29 including the hard member 35 is not pushed deeper between the inclined surface 16a and the contacted surface 5a. Since the movable member 29 is not sandwiched with a strong force, a state in which an occupant can smoothly perform an operation for switching from the locked state to the unlocked state with a relatively light force is maintained.

  Further, since the movable member 29 is hardly deformed or bent due to the vibration of the vehicle, there is no gap between the movable member 29 and the contacted surface 5a. For this reason, in this embodiment, it is possible to reliably prevent the occurrence of abnormal noise due to the rattling of the upper rail 2.

  In the present embodiment, a part of the movable member 29 that is sandwiched between the inclined surface 16a and the contacted surface 5a is formed of metal instead of resin. Instead of such an aspect, the entire portion of the movable member 29 that is sandwiched between the inclined surface 16a and the abutted surface 5a may be formed of metal instead of resin.

  In the present embodiment, a plurality of movable members 29 are provided along the moving direction (direction along the x axis) of the upper rail 2. For this reason, there is no case where force is received in the direction in which the upper rail 2 rotates with the single movable member 29 as a fulcrum. As a result, rattling of the upper rail 2 with respect to the lower rail 1 is further prevented.

  The effect of providing the sliding member 15 will be described with reference to FIG. FIG. 7A schematically shows that the occupant M moves the seat ST back and forth by setting the seat slide device 100 in the unlocked state while sitting on the seat ST. Further, in FIG. 7B, the seat slide device 100 is unlocked in a state where the occupant M is not seated on the seat ST (a state standing in the vicinity of the seat ST), and the seat ST is moved back and forth. This is shown schematically.

  In the state shown in FIG. 7A, the vertical load applied to the seat ST is relatively large due to the weight of the occupant M. The load is a force that presses the lower surface 15S of the sliding member 15 against the sliding surface 3S. For this reason, the frictional force applied between the sliding member 15 and the sliding surface 3S, that is, the sliding resistance received by the sliding member 15 when the upper rail 2 is moved back and forth is relatively large.

  In general, the floor to which the seat slide device 100 is attached is often inclined downward toward the front side. For this reason, if the sliding resistance when the seat ST is moved is too small, the seat ST on which the occupant M is seated slides forward due to its own weight, which may cause the occupant M to feel uneasy. is there.

  However, in the seat slide device 100 according to the present embodiment, the sliding resistance when the occupant M is seated on the seat ST as shown in FIG. 7A increases as described above. For this reason, even if it becomes an unlocked state, the phenomenon that the sheet ST slides with its own weight along the downward slope can be prevented. Note that the increase in sliding resistance is such that the seat ST is prevented from sliding under its own weight, so that the work load for the occupant M to slide the seat ST does not become excessive.

  In FIG. 7A, the force required to slide the sheet ST in the x direction is indicated by an arrow AR11. Further, the force required to slide the sheet ST in the −x direction is indicated by an arrow AR12. The thickness of each arrow indicates the magnitude of the force. In the present embodiment, the magnitudes of the forces indicated by these arrows are the same as each other. Note that the “force required to slide the sheet ST” indicated by the arrow AR11 or the like is substantially equal to the sliding resistance that the sliding member 15 receives.

  In the state of FIG. 7B, the weight of the occupant M is not added to the seat ST. For this reason, the load in the vertical direction received by the sheet ST is relatively small. Accordingly, the frictional force applied between the sliding member 15 and the sliding surface 3S, that is, the sliding resistance received by the sliding member 15 when the upper rail 2 is moved back and forth is also relatively small. .

  As shown in FIG. 7B, in a state where the occupant M is not seated on the seat ST, even if the seat ST in the unlocked state slides forward due to its own weight, the occupant M may feel uneasy. There is no. For this reason, it is preferable to reduce the sliding resistance received by the sliding member 15 in the unlocked state and to reduce the work load for the occupant M to slide the seat ST as in the present embodiment.

  In FIG. 7B, the force required to slide the sheet ST in the x direction is indicated by an arrow AR21. Further, the force required to slide the sheet ST in the −x direction is indicated by an arrow AR22. The thickness of each arrow indicates the magnitude of the force. In the present embodiment, the magnitudes of the forces indicated by these arrows are the same as each other. However, the force is smaller than the force indicated by the arrow AR11 in FIG.

  By the way, when the passenger | crew M is a child, the weight is small compared with an adult. For this reason, the load in the vertical direction received by the sheet ST is smaller than that in the case of FIG. 7A and larger than that in the case of FIG. Accordingly, the sliding resistance received by the sliding member 15 in the unlocked state is smaller than that in the case of FIG. 7A and larger than that in the case of FIG. Thus, while ensuring the sliding resistance to such an extent that the seated occupant M does not feel uneasy, the work load for the occupant M to slide the seat ST is kept small enough that even a weak child can easily operate it. be able to.

  As described above, the seat slide device 100 according to the present embodiment is configured such that the sliding resistance received by the sliding member 15 when the upper rail 2 is moved changes depending on the vertical load received by the seat ST. Yes. For this reason, it is possible to appropriately change the sliding resistance when the sheet ST is slid without requiring a complicated mechanism.

  In the present embodiment, three sliding members 15 are provided, but the number of sliding members 15 may be two or less, or may be four or more.

  In this embodiment, the part (lower surface 15S) which contact | abuts the sliding surface 3S among the sliding members 15 is a flat surface. For this reason, the force applied to the sliding surface 3S from the sliding member 15 does not concentrate in a narrow range, and it is possible to prevent the sliding surface 3S from being damaged such as indentations. Thereby, the whole sliding surface 3S is maintained in a flat state, and a state in which the upper rail 2 can smoothly move back and forth is maintained. Further, the generation of abnormal noise when the upper rail 2 moves is also prevented.

  A second embodiment of the present invention will be described. As shown in FIG. 8, the seat slide device 100A according to the second embodiment has a configuration in which the sliding member 152 and the sliding member 153 in the first embodiment (FIG. 1) are replaced with rollers 15R, respectively. ing. As a result, in the present embodiment, the two rollers 15 </ b> R are provided on the upper rail 2 at a position on the rear side (−x direction side) of the sliding member 15. The seat slide device 100A is different from the seat slide device 100 only in this point, and is the same as the seat slide device 100 in other points. Hereinafter, differences from the first embodiment will be mainly described, and description of points that are common to the first embodiment will be omitted as appropriate.

  The roller 15 </ b> R is a wheel that is supported so as to be rotatable with respect to the arm plate portion 14. The roller 15R is placed on the upper surface (that is, the sliding surface 3S) of the bottom plate portion 3, and supports the upper rail 2 in a state that it can move in the direction along the x axis. That is, the upper rail 2 is supported with respect to the sliding surface 3S. When the sheet ST is slid, the sliding resistance at the portion of the roller 15R is almost zero.

  FIG. 9A schematically shows that the occupant M is in the unlocked state with the seat M sitting on the seat ST, and moves the seat ST back and forth. Further, in FIG. 9B, the seat slide device 100A is unlocked in a state where the occupant M is not seated on the seat ST (standing in the vicinity of the seat ST), and the seat ST is moved back and forth. This is shown schematically.

  In the state of FIG. 9A, the load in the vertical direction received by the sheet ST is relatively large. The load is a force that presses the lower surface 15S of the sliding member 15 against the sliding surface 3S. For this reason, the frictional force applied between the sliding member 15 and the sliding surface 3S, that is, the sliding resistance received by the sliding member 15 when the upper rail 2 is moved back and forth is relatively large. This is the same as the first embodiment shown in FIG.

  When the seat ST is moved forward, a force in a direction tilting forward is applied to the seat ST. For this reason, the force with which the sliding member 15 is pushed against the sliding surface 3S is larger than the force with which the roller 15R is pushed against the sliding surface 3S. However, the magnitude of the force is substantially the same as in the first embodiment. For this reason, the sliding resistance (arrow AR11) which the sliding member 15 receives becomes a magnitude | size comparable as the case of Fig.7 (a).

  On the other hand, when moving the seat ST to the rear side, a force in a direction tilting to the rear side is applied to the seat ST. For this reason, the force with which the sliding member 15 is pushed against the sliding surface 3S is smaller than the force with which the roller 15R is pushed against the sliding surface 3S. Although the roller 15R is strongly pressed against the sliding surface 3S, the sliding resistance is not increased accordingly. As a result, the magnitude of the sliding resistance received by the sliding member 15 (arrow AR12) is smaller than in the case of FIG.

  Thus, in the present embodiment, the sliding resistance when moving the sheet ST in the x direction is larger than the sliding resistance when moving the sheet ST in the −x direction. As already described, the floor to which the seat slide device 100 is attached is often inclined downward toward the front side. Therefore, according to the seat slide device 100A according to the present embodiment, the workload of the occupant M when moving the seat ST forward and the workload of the occupant M when moving the seat ST forward. Can be approximately equal.

  In the state of FIG. 9B, the load in the vertical direction received by the sheet ST is relatively small. For this reason, the frictional force applied between the sliding member 15 and the sliding surface 3S, that is, the sliding resistance received by the sliding member 15 when the upper rail 2 is moved back and forth is relatively small. This is the same as the first embodiment shown in FIG.

  In the state of FIG. 9B as well, the sliding resistance (arrow AR21) when the sheet ST is moved to the x direction side is the sliding resistance (arrow AR21) when the sheet ST is moved to the −x direction side. It becomes larger than the arrow AR22). That is, the force indicated by the arrow AR21 in FIG. 9B is the same level as that in FIG. 7A, and the force indicated by the arrow AR22 in FIG. 9B is the same as that in FIG. Smaller than the case.

  For this reason, when the occupant M is not seated, the work load of the occupant M when moving the seat ST forward while reducing the sliding resistance as compared to the seated state of FIG. The work load of the occupant M when moving the seat ST forward can be made substantially equal.

  In the present embodiment, two rollers 15R are provided, but the number of rollers 15R may be one or three or more. In any case, it is only necessary that the roller 15R is provided at a position on the rear side (−x direction side) of the sliding member 15.

  In the case where the floor to which the seat slide device 100 is attached is inclined downward toward the rear side as opposed to the above, the roller 15R and the sliding member 15 shown in FIG. It is good. That is, it is good also as a structure by which the roller 15R was provided in the position which becomes the front side (x direction side) rather than the sliding member 15 among the upper rails 2. FIG. Even in such an aspect, the workload of the occupant M when moving the seat ST forward and the workload of the occupant M when moving the seat ST forward can be made substantially equal. .

  A third embodiment of the present invention will be described with reference to FIGS. The seat slide device 100B according to the third embodiment is different from the first embodiment in a partial shape of the lever 22 and the like. Hereinafter, differences from the first embodiment will be mainly described, and description of points that are common to the first embodiment will be omitted as appropriate.

  In addition, in FIG. 10 thru | or FIG. 12, the shape of the movable member 29 is typically drawn. Specifically, only a portion (a part of the arm portion 31) interposed between the upper plate portion 5 and the guide portion 16 of the movable member 29 is shaped like a wedge connected to the tip of the slider 26. It is drawn in. The actual specific shape of the part is the same as that of the first embodiment shown in FIG.

  FIG. 10 shows an internal configuration of the seat slide device 100B in the locked state. In the present embodiment, the shape of the lever 22 provided on the x direction side and the shape of the lever 22A provided on the −x direction side are not symmetrical as shown in FIG. 2 and are different from each other. ing. A transmission portion 24a is not formed on the lever 22A provided on the −x direction side, that is, the rear side of the vehicle, and a connection portion 27 is formed instead. The connecting portion 27 is formed so as to protrude upward from a portion of the lever 22A on the rear side of the upper arm portion 24. A wire WR is connected in the vicinity of the upper end portion of the connection portion 27.

  In the present embodiment, as shown in FIG. 7B, when the backrest portion of the seat ST is tilted forward, the wire WR is drawn to the −x direction side. In FIG. 10, the backrest portion of the seat ST is not tilted, and the occupant M can be seated as shown in FIG.

  In the locked state shown in FIG. 10, the transmission portion 24 a of the lever 22 is not lifted by the lock member 18. For this reason, the upper arm portions 24 of the lever 22 and the lever 22 </ b> A are brought close to each other by the force of the coil spring 28. Each movable member 29 receives a force in a direction away from the lock member 18. At this time, the front and rear movable members 29 are sandwiched between the inclined surface 16a and the contacted surface 5a like a wedge and are in contact with and pressed against the contacted surface 5a. Yes. Thereby, rattling (relative displacement along the z-axis) between the lower rail 1 and the upper rail 2 is suppressed.

  FIG. 11 shows an internal state of the seat slide device 100B in the unlocked state. In this state, the transmission portion 24 a of the lever 22 is lifted by the lock member 18, whereby the lever 22 rotates counterclockwise around the rotation shaft 23. As a result, the movable member 29 on the x direction side is moved to the −x direction side, and the movable member 29 is extracted from between the inclined surface 16a and the contacted surface 5a. Thereafter, no frictional force is generated between the movable member 29 on the x direction side and the contacted surface 5a.

  On the other hand, since the transmission portion 24a is not formed on the lever 22A, the lever 22A is not lifted by the lock member 18 even in the unlocked state of FIG. As the lever 22 rotates counterclockwise, the force in the x direction received by the lever 22A from the coil spring 28 increases. The lever 22A rotates counterclockwise around the rotation shaft 23 by the force. As a result, the movable member 29 on the −x direction side has moved to the −x direction side, and the movable member 29 is further pushed between the inclined surface 16a and the contacted surface 5a. .

  In such a state, when the sheet ST moves to the x direction side (front side), the frictional force from the contacted surface 5a is applied to the −x direction side of the movable member 29 on the −x direction side. It is done. As a result, the movable member 29 on the −x direction side tends to move relative to the −x direction side along the inclined surface 16a, so that the movable member 29 is further pushed between the inclined surface 16a and the contacted surface 5a. . As a result, the frictional force between the movable member 29 and the contacted surface increases, and the sliding resistance received by the sheet ST during movement increases. The sliding resistance in this case is substantially equal to the frictional force between the movable member 29 and the abutted surface 5a plus the frictional force between the sliding member 15 and the slidable surface 3S.

  On the other hand, when the sheet ST moves to the −x direction side (rear side), the frictional force from the abutted surface 5a is applied to the movable member 29 on the −x direction side on the x direction side. As a result, the movable member 29 on the −x direction side tends to move relative to the x direction side along the inclined surface 16a, and thus is extracted from between the inclined surface 16a and the contacted surface 5a. As a result, the frictional force between the movable member 29 and the contacted surface is substantially zero, and the sliding resistance received by the sheet ST during movement is reduced. The sliding resistance in this case is approximately equal to the frictional force between the sliding member 15 and the sliding surface 3S.

  Thus, in the present embodiment, the sliding resistance when moving the sheet ST in the x direction is larger than the sliding resistance when moving the sheet ST in the −x direction. Therefore, according to the seat slide device 100B according to the present embodiment, the work load of the occupant M when moving the seat ST to the x direction side and the work of the occupant M when moving the seat ST to the -x direction side. The load can be made approximately equal.

  Also in this embodiment, similarly to the first embodiment, the sliding resistance received by the sliding member 15 when the upper rail 2 is moved is configured to change depending on the vertical load received by the sheet ST. For this reason, it is possible to appropriately change the sliding resistance when the sheet ST is slid without requiring a complicated mechanism.

  FIG. 12 shows a state in which the backrest of the seat ST is tilted forward and the wire WR is pulled backward. In this state, the upper end of the connection portion 27 is pulled by the wire WR, whereby the lever 22A rotates around the rotation shaft 23 in the clockwise direction. As a result, the movable member 29 on the −x direction side has moved to the x direction side, and the movable member 29 is extracted from between the inclined surface 16a and the contacted surface 5a. In the state of FIG. 12, no frictional force is generated between the movable member 29 and the contacted surface 5a on either the front side or the rear side. For this reason, the sliding resistance when the sheet ST is moved is substantially equal to the frictional force between the sliding member 15 and the sliding surface 3S regardless of the moving direction.

  That is, in the present embodiment, the state in which the sliding resistance when moving the seat ST differs depending on the moving direction and the state where the sliding resistance is the same regardless of the moving direction are automatically switched depending on the inclination angle of the backrest. It has a configuration.

  For this reason, when the occupant M is seated, the sliding resistance to the front side can be increased to prevent the occupant from feeling uneasy. Further, when the occupant M is not seated, the sliding resistance can be reduced without depending on the moving direction of the seat ST, and the work load on the occupant M can be reduced.

  In the present embodiment, similarly to the second embodiment of FIG. 8, the roller 15 </ b> R may be provided on the rear side (−x direction side) of the sliding member 15.

  A fourth embodiment of the present invention will be described with reference to FIGS. Hereinafter, differences from the first embodiment will be mainly described, and description of points that are common to the first embodiment will be omitted as appropriate.

  FIGS. 13 to 15 show the configuration of a portion excluding the lower rail 1 in the seat slide device 100C according to the present embodiment. The movable member 29 in the present embodiment has a configuration in which a first connection portion 302 and a second connection portion 303 are formed between the support portion 301 and the arm portion 31. The 1st connection part 302 is a part formed so that it might extend to the z direction side from the outer edge part along the y-axis among the support parts 301. FIG. The second connection portion 303 is a portion formed to extend from the z-direction side end portion of the first connection portion 302 toward the outside along the x-axis.

  In the arm portion 31 in the present embodiment, the through hole 33 as in the first embodiment is not formed, and a groove 330 is formed instead. The groove 330 is a concave groove formed so as to recede from the end face of the arm portion 31 on the −z direction side toward the z direction side. A vertical portion 420 described later is inserted into the groove 330 from the −z direction side.

  Also in this embodiment, the same interlocking mechanism as that described in the first embodiment is provided. Therefore, when the occupant operates the handle 20 and the operation portion 18b is pushed down to the −z direction side to be in the locked state, each movable member 29 moves in the direction away from the lock member 18 along the x axis. Further, when the operation unit 18b is lifted to the z direction side to be in the unlocked state, each movable member 29 moves in a direction approaching the lock member 18 along the x axis.

  Of the two metal plates 11 included in the upper rail 2, those arranged on the y-direction side are also referred to as “first metal plate 111” below. Of the two metal plates 11, the one arranged on the −y direction side is also referred to as a “second metal plate 112” below. Further, the portion of the upper rail 2 where the lock member 18 is provided, that is, the portion constituted by the first metal plate 111 and the second metal plate 112 will be referred to as “main body portion 110” hereinafter. write.

  The upper rail 2 in this embodiment includes a pair of plate members 400 in addition to the main body 110. Further, in the present embodiment, the sliding member 15 is not provided on the arm plate portion 14, and the sliding member 500 is provided on the plate member 400 instead.

  The plate member 400 is provided on each of a portion on the x direction side and a portion on the −x direction side of the bottom surface of the main body 110. Each plate member 400 is provided with two sliding members 500. The shape of each plate member 400 is symmetrical with respect to the yz plane. Hereinafter, the configuration of the plate member 400 arranged on the x direction side and the sliding member 500 provided on the plate member 400 will be mainly described, and the description of the configuration of the other plate member 400 and the like will be omitted.

  As shown in FIG. 16, the plate member 400 is a plate-like member formed by pressing a metal plate. The plate member 400 includes a horizontal portion 410, a pair of vertical portions 420, and insertion portions 440 and 450.

  The horizontal portion 410 is a flat plate-like portion that is parallel to the bottom surface of the main body 110, that is, the end surface on the −z direction side (may be parallel to the xy plane). It is the part which touches.

  The vertical part 420 is a flat part formed so as to extend from the end part on the y direction side and the end part on the −y direction side of the horizontal part 410 toward the z direction side (upward side). . The vertical portion 420 is a portion that comes into contact with the arm plate portion 14 from the outside. An inclined surface 421 is formed at the tip of the vertical portion 420 on the z direction side. The inclined surface 421 is an inclined surface that goes toward the z direction as it goes toward the x direction. That is, the surface is inclined in the same manner as the inclined surface 16a in the first embodiment.

  The insertion portion 440 is a flat plate portion formed so as to extend from the end portion on the x direction side of the horizontal portion 410 toward the z direction side (upward side). The insertion portion 440 is a portion that is inserted between the first metal plate 111 and the second metal plate 112, specifically, between the side plate portions 13 that face each other. The dimension (width) of the insertion portion 440 along the y-axis is substantially equal to the distance between the side plate portions 13 facing each other.

  The insertion part 450 is a flat part formed so as to extend from the end part on the −x direction side of the horizontal part 410 toward the z direction side (upward side). The insertion portion 450 is a portion that is inserted between the first metal plate 111 and the second metal plate 112, specifically, between the side plate portions 13 that face each other, similarly to the insertion portion 440 described above. Yes. The dimension (width) of the insertion portion 450 along the y-axis is substantially equal to the distance between the side plate portions 13 facing each other.

  A protruding portion 411 that protrudes in the y direction is formed at a boundary portion of the horizontal portion 410 with the vertical portion 420 on the y direction side. In addition, a pair of notches 412 extending in the −y direction is formed at positions on both sides of the protruding portion 411 along the x axis in the horizontal portion 410. Further, a recess 413 is formed so as to recede toward the center along the x-axis from the position at the end of the notch 412 on the −y direction side.

  In addition, the shape of the plate member 400 is symmetrical with respect to the xz plane. For this reason, a protrusion 411, a notch 412, and a recess 413 similar to those described above are also formed at the boundary between the horizontal portion 410 and the vertical portion 420 on the −y direction side.

  The shape of the sliding member 500 will be described. In the present embodiment, the shapes of the sliding members 500 are the same. Therefore, in the following, the shape of the sliding member 500 arranged on the y direction side will be mainly described, and the description of the shape of the sliding member 500 arranged on the −y direction side will be omitted. FIG. 16 shows a state in which the sliding member 500 arranged on the y direction side is detached from the plate member 400 along the y axis.

  Similar to the sliding member 15 in the first embodiment, the sliding member 500 is a member formed entirely of resin. The sliding member 500 has a horizontal part 510 and a vertical part 520. The horizontal part 510 is a plate-like part parallel to the horizontal part 410 of the plate member 400. The surface on the z direction side of the horizontal portion 510 is a surface that contacts the surface on the −z direction side of the horizontal portion 410. Further, the surface 514 on the −z direction side of the horizontal portion 510 is in contact with the upper surface (sliding surface 3S) of the bottom plate portion 3 of the lower rail 1 in the same manner as the lower surface 15S of the sliding member 15 in the first embodiment. It is a flat surface that comes into contact.

  The vertical portion 520 is a plate-like portion parallel to the vertical portion 420 of the plate member 400. The vertical portion 520 is formed so as to extend in the z direction from the end portion on the y direction side of the horizontal portion 510. The surface on the −y direction side of the vertical portion 520 is a surface that contacts the surface on the y direction side of the vertical portion 420.

  A pair of protrusions 511 are formed on the surface of the horizontal portion 510 on the z direction side. Each protrusion 511 is formed so as to protrude in the z-direction side, and is formed so as to extend along the y-axis. In addition, a protrusion 512 that protrudes toward the center along the x axis is formed at the tip of each protrusion 511 on the −y direction side. A through hole 513 is formed in a portion between the pair of protrusions 511 in the vertical portion 520 so as to penetrate the vertical portion 520 along the y axis.

  The entire sliding member 500 may be formed of resin as in the present embodiment, but only the portion that contacts the sliding surface 3S is formed of resin, and the other portions are different. It may be formed of a material.

  The sliding member 500 arranged on the y direction side can be fitted and fixed to the plate member 400 by moving it from the position shown in FIG. 16 to the −y direction side. At this time, the protruding portion 411 of the plate member 400 is inserted into the through hole 513 of the sliding member 500. Further, the pair of protrusions 511 formed on the sliding member 500 is fitted into the pair of notches 412 formed on the plate member 400. At this time, since the convex portion 512 formed on the protrusion 511 is hooked on the concave portion 413 formed on the notch 412, the sliding member 500 once fitted is prevented from being detached from the plate member 400. Is done. The sliding member 500 disposed on the −y direction side is also fitted and fixed to the plate member 400 with the same configuration as described above.

  The plate member 400 in which the pair of sliding members 500 are fitted and fixed is welded and fixed to the bottom surface of the main body 110. In FIG. 14, a portion where the plate member 400 is welded to the main body 110 is indicated by a dotted line DL.

  As shown in the figure, the first metal plate 111 and the second metal plate 112 are separated from each other at the lower end of the main body 110, and the plate member 400 is welded so as to connect these separated portions. It is fixed. That is, the horizontal portion 410 of the plate member 400 is welded and fixed to both the first metal plate 111 and the second metal plate 112.

  In the seat slide device 100 </ b> C according to the present embodiment, a total of four sliding members 500 are fixed by being fitted to the plate member 400. When the seat moves in the front-rear direction, each sliding member 500 moves along the x-axis while sliding on the sliding surface 3S. At that time, since a frictional force is generated between the surface 514 and the sliding surface 3S, the upper rail 2 moves while receiving a sliding resistance due to the frictional force. The effect of providing such a sliding member 500 is the same as the effect already described with reference to FIG.

  In the present embodiment, the sliding member 500 can be easily attached to the upper rail 2 as compared with the first embodiment in which the sliding member 15 is attached via the shaft SH. For this reason, the manufacturing cost of the seat slide device 100C can be suppressed.

  As shown in FIG. 15, in each arm portion 31, both the vertical portion 420 and the side plate portion 13 are inserted from the −z direction side inside the groove 330. In the present embodiment, the end surface on the z direction side of the vertical portion 420, that is, the entire inclined surface 421 is disposed at a position that is further on the z direction side than the end surface on the z direction side of the side plate portion 13. For this reason, the inner wall surface (that is, the top surface) of the groove 330 on the z direction side is in contact with the inclined surface 421. Note that the inner wall surface of the groove 330 on the z-direction side is substantially parallel to the inclined surface 421 facing the groove 330.

  When the occupant operates the handle 20 to switch from the unlocked state to the locked state, the movable member 29 moves away from the lock member 18 as described in the first embodiment. At this time, the arm portion 31 of the movable member 29 moves along the inclined surface 421 and is sandwiched between the inclined surface 421 and the contacted surface 5a like a wedge. Thereby, rattling between the lower rail 1 and the upper rail 2 is suppressed. Thus, the inclined surface 421 of the plate member 400 in the present embodiment functions as a substitute for the inclined surface 16a in the first embodiment.

  The inclined surface 421 is formed on a part of a relatively small plate member 400. For this reason, it is possible to form the inclined surface 421 easily and accurately as compared to the configuration in which the inclined surface 16a is formed on a part of a relatively large member as in the first embodiment.

  In realizing the function of suppressing rattling, it is preferable that the distance from the surface 514 of the sliding member 500 to the inclined surface 421 is uniform for each sliding member 500. In the present embodiment, the distance is determined only by the plate member 400 that is a relatively small member and the sliding member 500. For this reason, it is relatively easy to increase the accuracy of the distances and make the distances equal.

  On the other hand, in the first embodiment, the lower surface of the sliding member 15 includes the metal plate 11 that is a relatively large and complicated member, the shaft SH provided on the metal plate 11, and the sliding member 15. The distance from 15S to the inclined surface 16a is determined. For this reason, compared with this embodiment, it is difficult to make the said distance uniform equally. Thus, also in the implementation | achievement of the function which suppresses rattling, this embodiment is more preferable than 1st Embodiment.

  Each sliding member 500 in the present embodiment is provided at a position overlapping the movable member 29 in the vertical direction. As a result, the z-direction force received by the upper rail 2 from the sliding member 500 and the -z-direction force received by the upper rail 2 from the movable member 29 are applied to the upper rail 2 at substantially the same position along the x axis. It will be. For this reason, compared with the structure in which each force is applied to the upper rail 2 at different positions along the x axis, the distortion generated in the upper rail 2 is reduced. Thus, in this embodiment, the rigidity of the upper rail 2 is enhanced by devising the positional relationship between the sliding member 500 and the movable member 29.

  By the way, when the vehicle collides, a force that lifts the upper rail 2 in the z direction side is applied to the upper rail 2 by the impact of the collision. The force tends to be applied particularly strongly in the position of the upper rail 2 at the end along the x-axis, that is, in the vicinity of the portion where each plate member 400 is provided.

  When such a force is applied, the main body portion 110 of the upper rail 2 tends to be deformed so that the respective arm plate portions 14 are opened outward, and to be deformed so that the respective side plate portions 13 are close to each other. That is, an attempt is made to deform the width W shown in FIG.

  However, in the present embodiment, as already described, the horizontal portion 410 of the plate member 400 is welded and fixed to both the first metal plate 111 and the second metal plate 112 that are separated from each other. For this reason, the deformation that reduces the width W of FIG. 15 is suppressed by the horizontal portion 410. Furthermore, in this embodiment, a part of the plate member 400 (insertion portions 440 and 450) is inserted between the first metal plate 111 and the second metal plate 112. For this reason, the deformation such that the width W of FIG.

  In addition, the outer side of each arm plate portion 14 is sandwiched between a pair of vertical portions 420. For this reason, the deformation in which each arm plate portion 14 opens outward is less likely to occur in the present embodiment.

  As described above, in the present embodiment, the plate member 400 can suppress deformation of the upper rail 2 when the vehicle collides.

  The embodiments of the present invention have been described above with reference to specific examples. However, the present invention is not limited to these specific examples. In other words, those specific examples that have been appropriately modified by those skilled in the art are also included in the scope of the present invention as long as they have the characteristics of the present invention. For example, the elements included in each of the specific examples described above and their arrangement, materials, conditions, shapes, sizes, and the like are not limited to those illustrated, and can be changed as appropriate. Moreover, each element with which each embodiment mentioned above is provided can be combined as long as technically possible, and the combination of these is also included in the scope of the present invention as long as it includes the features of the present invention.

100, 100A, 100B, 100C: seat slide device 1: lower rail 2: upper rail 15: sliding member 3: bottom plate portion 3S: sliding surface M: occupant ST: seat

Claims (11)

A seat slide device provided in a vehicle,
A lower rail fixed to the floor of the vehicle;
An upper rail fixed to the vehicle seat and supported in a movable state with respect to the lower rail,
The upper rail is provided with a sliding member that comes into contact with the sliding surface of the lower rail from above,
A seat slide device configured such that a sliding resistance received by the sliding member when moving the upper rail is changed by a vertical load received by the seat.   The seat slide device according to claim 1, wherein a plurality of the sliding members are provided along a moving direction of the upper rail.   3. The seat according to claim 1, wherein a roller for supporting the upper rail with respect to the sliding surface is provided at a position on the upper rail in a front side or a rear side with respect to the sliding member. Slide device.   The seat slide device according to any one of claims 1 to 3, wherein a portion of the sliding member that contacts the sliding surface is a flat surface. A lock member that performs an operation of switching between a locked state in which movement of the upper rail is restricted and an unlocked state in which movement of the upper rail is allowed;
A member held by the upper rail, wherein the member is in contact with a contact surface that is a part of the lower rail in the locked state, and is separated from the contact surface in the unlocked state; A movable member,
An interlocking mechanism for moving the movable member along the movement direction of the upper rail in conjunction with the movement of the locking member;
When the interlocking mechanism moves the movable member, the distance between the movable member and the contacted surface is changed by guiding the movable member along an inclined surface formed on the upper rail. The seat slide device according to claim 1, configured as described above. The upper rail has a configuration in which a plate-like plate member is fixed to a main body portion which is a portion where the lock member is provided,
The plate member is
A portion in contact with the bottom surface of the main body, and a horizontal portion parallel to the bottom surface;
A vertical portion extending upward from the horizontal portion,
The seat slide device according to claim 5, wherein the inclined surface is formed at a tip of the vertical portion.   The seat slide device according to claim 6, wherein the sliding member is fixed to the plate member.   The seat slide device according to claim 7, wherein the sliding member is provided at a position overlapping the movable member in a vertical direction. At the lower end of the main body, the first metal plate and the second metal plate are separated from each other,
The seat slide device according to claim 6, wherein the horizontal portion is welded and fixed to both the first metal plate and the second metal plate.   The seat slide device according to claim 9, wherein a part of the plate member is inserted between the first metal plate and the second metal plate.   The seat sliding device according to any one of claims 1 to 10, wherein at least a portion of the sliding member that abuts on the sliding surface is formed of resin.

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