JP2005029104A - Vehicular seat device - Google Patents

Abstract

<P>PROBLEM TO BE SOLVED: To provide a vehicular seat device capable of smoothly and surely operating a slide memory mechanism by simplifying a structure for operating the slide memory mechanism. <P>SOLUTION: This vehicular seat device is provided with a seat cushion moving along the slide direction together with a lower rail on a floor side and an upper rail fixed on a seat side, and the slide memory mechanism storing a position of a seat when a seat back is tilted forward and restricting the movement of the seat to the rear part of the stored position. The side memory mechanism is provided with a memory lock lever movable along a memory position wherein the memory lock lever cannot relatively move with respect to the lower rail and a memory release position wherein the memory lock lever can move along the lower rail and always energized to the memory position, and an operation means for moving a catch lever releasing fitting of the memory lock lever and an upper rail side fittable to each other and movable to a lock position wherein the memory lock lever is allowed to be returned to the memory part between an unlock position and the lock position. <P>COPYRIGHT: (C)2005,JPO&NCIPI

Description

  The present invention relates to a vehicle seat device.

  In a vehicle seat device, there is a type with a slide memory function for storing a slide position of an upper rail (seat) with respect to a lower rail. Such a slide memory function is used during a so-called walk-in operation in which the seat back of the front seat tilts forward and slides forward when entering and exiting the rear seat. And as a prior art of the sheet apparatus which has a slide memory function, there exists patent document 1, for example.

  In the vehicle seat device of Patent Document 1, the movement of the seat back of the seat fixed to the upper rail and the movement of the slide memory mechanism are linked. That is, if the seat back is in the upright position, the shoe, which is a constituent member of the slide memory mechanism, can move relative to the lower rail by moving to the memory release position, so the slide memory mechanism does not work. On the other hand, if the seat back is moved to the forward tilt position, the shoe cannot move relative to the lower rail by moving to the memory position, and the seat cannot move rearward from the shoe, so that the memory function works.

The movement when the seat back is raised will be described in more detail. When the seat back rises, the cable that links the lock member and the seat back, which is swingably provided on the upper rail, is loosened and is urged to rotate by a spring. The locking member is rotated in a predetermined direction, and the catch member that controls the locked state of the shoe and the lower rail is swung by the pin-like second finger provided on the locking member. The lock is released. At the same time as this operation, the pin-shaped first finger provided on the lock member engages the rear end surface of the shoe. Therefore, when the seat (upper rail) is moved forward, the moving force of the seat passes through the first finger. The shoe is transmitted to the shoe, and the shoe moves forward together with the seat.
JP-A-8-253064

  As described above, in the vehicle seat device disclosed in Patent Document 1, the lower rail and the shoe unlocking operation when the seat back is raised, and the operation of transmitting the seat moving force to the shoe are provided with two pins ( (1st finger and 2nd finger) respectively, in order to perform both of these operations smoothly, a high manufacturing accuracy is required for the lock member, and especially when the arrangement of the two pins is slightly shifted, There is a drawback that these operations are not performed smoothly.

  SUMMARY OF THE INVENTION An object of the present invention is to provide a vehicle seat device that can operate a slide memory mechanism smoothly and reliably by simplifying the structure of the mechanism that operates the slide memory mechanism.

  The vehicle seat device of the present invention includes a floor rail on the floor surface, an upper rail that is slidable with respect to the lower rail and fixed to the seat side, a seat cushion that is supported by the upper rail and moves in a sliding direction together with the upper rail, , A seat back that is pivotably supported between a seating standing position and a forward tilt position with respect to the seat cushion; and a seat position when the seat back is tilted forward; A vehicle seat apparatus comprising: a slide memory mechanism that regulates rearward seat movement; a memory position where the slide memory mechanism cannot move relative to the lower rail; and a memory release position where the slide memory mechanism can move along the lower rail. Engagement protrusions or engagement recesses that are always urged toward the memory position and that are detachable from each other. And a memory lock lever provided on the upper rail side and having the other of the engagement protrusion or the engagement recess, and the memory lock lever is engaged with the engagement protrusion and the engagement recess being engaged. An unlock position for moving to the memory release position against the urging force, and disengagement of the engagement protrusion and the engagement recess to allow the memory lock lever to return to the memory position. And a lock lever movable between the lock position and an operating means for moving the catch lever to the unlock position and the lock position.

  The lower rail or a fixing member fixed to the lower rail is formed with a plurality of memory lock holes or memory lock protrusions that are detachable from each other, arranged in the longitudinal direction thereof, and the memory lock lever is provided with the memory lock hole or memory lock. It is practical to hold the memory lock lever at the memory position by forming the other of the lock protrusions and engaging the memory lock hole with the memory lock protrusion.

  Further, the slide memory mechanism includes a slide stopper protrusion that cannot move relative to the upper rail when the memory lock lever is at the memory position, and the upper rail has the memory lock lever at the memory position. It is preferable to have a stopper projection that sometimes prevents the sheet from moving backward from the corresponding contact position by abutting with the slide stopper.

  Furthermore, it has a slide lock mechanism that can be shifted between a locked state that restricts the sliding of the upper rail with respect to the lower rail and an unlocked state that allows the sliding, and the operation means includes the slide lock mechanism in a locked state. A loop handle that is switched to an unlocked state. When the slide lock mechanism is in the locked state, the loop handle is moved to the lock position, and when the slide lock mechanism is in the unlocked state. The catch lever can be moved to the unlock position.

  Further, the operating means is a pulling wire that transmits the movement of the seat back to the catch lever. When the pulling wire is moved to the standing position, the catch lever is moved to the unlock position, When the seat back moves to the forward tilt position, the catch lever may be moved to the lock position.

  Further, when the operation means is a pulling wire, the catch lever is pivotally attached to the upper rail so as to swing according to the operation of the pulling wire, and is always attached toward the unlock position. The slide memory mechanism includes a slide piece that moves together with the memory lock lever in the longitudinal direction of the lower rail, and the slide piece includes a recess for storing the memory lock lever; The catch lever positioned in front of the slide piece moves rearward and comes into contact with the catch lever while swinging the catch lever toward the lock position. It is preferable to have a guide surface that guides the engaging protrusion to the storage recess.

  According to the present invention, the slide memory mechanism can be operated smoothly and reliably by simplifying the structure of the mechanism for operating the slide memory mechanism.

First, a first embodiment of the present invention will be described with reference to FIGS.
The front seat (passenger seat or driver's seat) 11 of the vehicle shown in FIGS. 1 and 2 has a seat cushion 12 that supports the butt of the seated person and a seat back 13 that supports the back of the seated person. In the seat cushion 12 and the seat back 13, a metal seat cushion frame 14 (see FIG. 4) and a seat back frame (not shown) are embedded as a pair of left and right seats, respectively. The cushion frames 14 and the seat back frames are connected by a metal connecting member (not shown) that faces in the left-right direction. Further, the rear end portions of the left and right seat cushion frames 14 and the lower end portions of the seat back frames are pivotally attached to each other by a rotating shaft 11x facing in the left-right direction.

  The seat back 13 (seat back frame) is rotatable between an initial standing position (standing position) shown in FIG. 1 and a forward tilting position shown in FIG. 2, and is always moved forward by a biasing means (not shown). It is urged to rotate toward the tilted position. The seat 11 is provided with an angle holding mechanism (not shown) that switches between a locked state and an unlocked state and is always in a locked state. If the angle holding mechanism is left in the locked state when the seat back 13 is in the initial standing position (standing position), the seat back 13 is held in this state, and if the angle holding mechanism is in the unlocked state, the seat back 13 Can be turned to the forward tilt position side. Further, the seat 11 includes a reclining handle (not shown) linked to the angle holding mechanism. By operating the reclining handle, the angle holding mechanism can be switched between a locked state and an unlocked state.

The reclining handle is urged so as to be always locked by the urging means (not shown), and when the occupant operates the reclining handle to be unlocked, the angle holding mechanism is unlocked. The seat back 13 tends to move to the forward tilt position by the urging means.
Further, the seat back can be reclined by setting the angle holding mechanism to the unlocked state. That is, when the seated person presses the seat back 13 backward with the back while the angle holding mechanism is in the unlocked state, the seat back 13 moves rearward from the initial standing position shown in FIG. When the seat back reaches the desired standing position of the seat occupant, if the seat occupant releases his hand from the reclining handle, the reclining handle returns to the locked state and the angle holding mechanism is locked, so the seat back 13 Is held in that position.

The left and right seat cushion frames 14 are fixed to a pair of left and right upper rails 15, respectively. The left and right upper rails 15 are respectively supported by a pair of left and right lower rails 16 fixed to the floor panel (floor surface) 10 of the vehicle body, and are slidable along the longitudinal direction (front-rear direction) of the lower rails 16. . The position of the seat 11 in the front-rear direction can be changed by sliding the upper rail 15 relative to the lower rail 16.
The seat cushion frame 14 and the upper rail 15 may be an integral member, or a lifter mechanism for height adjustment may be provided between the seat cushion frame 14 and the upper rail 15.

  The lower rail 16 is formed with a plurality of slide lock holes 16a along its longitudinal direction. On the upper rail 15 side, a lock claw (slide lock mechanism) 17a engageable with the slide lock hole (slide lock mechanism) 16a (see FIG. 10 and the like), and a pressed arm 17b positioned above the lock claw 17a And a slide lock plate 17 having a pivotal axis 17x. The axis of the rotation shaft 17x is parallel to the longitudinal direction of the lower rail 16, and the slide lock plate 17 is centered on the rotation shaft 17x, and the lock position (FIG. 12) engages the lock claw 17a with the slide lock hole 16a. , And can be rotated to the unlocking position (FIG. 13) to be removed. When the slide lock plate 17 is in the locked position, sliding of the upper rail 15 with respect to the lower rail 16 is restricted. The slide lock plate 17 is rotationally biased toward the lock position by a lock biasing spring 17c (shown only by arrows in FIGS. 12 and 13). The pressed arm 17 b is inserted into a square hole 15 a formed in the upper rail 15 and protrudes in the side surface direction on the opposite side of the upper rail 15.

  A loop bracket 18 is pivotally attached to the upper rail 15 via a rotation shaft 18x that is orthogonal to the rotation shaft 17x of the slide lock plate 17 (that is, the axis is directed to the seat left-right direction). The pressing portion 18 a provided at one end is in contact with the pressed portion 19 a of the lock open bracket 19. The lock open bracket 19 is coaxially rotatable with the loop bracket 18 (see FIG. 10), and a pressing portion 19b is provided at an end portion on the opposite side of the rotation shaft 18x that is the rotation center. The pressing portion 19b is inserted into the square hole 15a of the upper rail 15 and is positioned above the pressed arm 17b of the slide lock plate 17 (see FIGS. 12 and 13). When the loop bracket 18 is rotated clockwise in FIG. 5 via a loop handle (operating means) 18b provided on the loop bracket 18, the pressing portion 18a presses the pressed portion 19a and the lock open bracket 19 is the same. The pressing portion 19b of the lock open bracket 19 presses the pressed arm 17b, and the slide lock plate 17 can be rotated in the unlocking direction against the lock urging spring 17c.

  The seat 11 has a slide memory function for storing the position of the seat 11 before sliding when performing a walk-in operation of sliding forward while tilting the seat back 13 forward and backward when entering and exiting the rear seat. Note that the clockwise direction and the counterclockwise direction appearing in the following description relating to the slide memory function mean the rotational directions in the side views of FIGS.

  A catch lever 20 is pivotally attached to the upper rail 15 so as to be positioned on the side surface opposite to the side surface on which the loop bracket 18 and the lock open bracket 19 are supported. The catch lever 20 is rotatable about a rotation shaft 18x common to the loop bracket 18 and the lock open bracket 19 (see FIG. 10), and is engaged with a rear end portion on the opposite side to the rotation shaft 18x. It has a recess 20a. Further, the catch lever 20 is coupled to the stopper lever 22 via a torsion spring 20b.

  The stopper lever 22 is supported so as to rotate integrally with the loop bracket 18 coaxially (rotating shaft 18x). A lock open lever 21 is pivotally attached to the upper rail 15 via a rotating shaft 21x on the same side as the catch lever 20 and the stopper lever 22 are supported. The lock open lever 21 includes a pressing pin 21a (see FIGS. 12 and 13) that can contact the pressing portion 19b of the lock open bracket 19 protruding through the square hole 15a, and a wire engaging arm 21b. The torsion spring 21c is urged clockwise.

A memory rack (fixing member) 25 is fixed to the lower rail 16. The memory rack 25 is a long member parallel to the lower rail 16, and a plurality of memory lock holes 25a are formed along the longitudinal direction thereof. The memory rack 25 supports a slide piece 26 that is relatively movable in the longitudinal direction, and a memory lock lever 28 is provided in the slide piece 26. The memory lock lever 28 is in a vertical direction (a direction perpendicular to the sliding direction of the slide piece 26 with respect to the memory rack 25) in a concave portion 26 a (see FIG. 3, FIG. 5, etc.) provided in the slide piece 26 that faces in the vertical direction. ), And is supported so as not to move in the longitudinal direction of the slide piece 26, and a memory position (FIGS. 5, 7 to 9, which engages the memory lock claw (memory lock protrusion) 28a with the memory lock hole 25a. 14) and a memory release position (FIG. 6) for releasing the engagement. The memory lock lever 28 has an engagement protrusion 28 b located on the rotation locus of the engagement recess 20 a of the catch lever 20, and is urged to the memory position by the memory urging spring 27.
The slide bracket 18, the catch lever 20, the stopper lever 22, the memory rack 25, the slide piece 26, the memory biasing spring 27, and the memory lock lever 28 constitute a slide memory mechanism U 1.
Further, the memory unit MU <b> 1 is configured by the slide piece 26, the memory biasing spring 27, and the memory lock lever 28.

  A slide stopper 29 is fixed to the upper rail 15. The slide stopper 29 can be engaged with a stopper protrusion 26b protruding from the top of the slide piece 26 (see FIG. 15).

Further, the seat back 13 is provided with a walk-in operation handle 30 (FIGS. 1 and 2), and the walk-in operation handle 30 and the angle holding mechanism are linked by a walk-in wire (not shown).
One end of the pulling wire 31 is fixed to the seat back frame, and the other end of the pulling wire 31 is fixed to the lock open lever 21 (see FIG. 5 and the like). The pulling wire 31 is relaxed when the seat back 13 is in the standing position, and is tensioned when the seat back 13 is moved to the forward tilt position.

A normal seat slide operation and a walk-in operation of the seat device having the above configuration will be described.
A solid line in FIG. 1 indicates a normal seating state of the seat 11. At this time, the back seat 13 is in the standing position (initial standing position) shown in FIG. 1, and the mechanism related to the seat slide is in the state shown in FIG.
In this state, the slide lock plate 17 is held at the lock position, and the sliding of the seat 11 is regulated by the engagement between the lock claw 17a and the slide lock hole 16a (FIG. 12). The memory lock lever 28 is held at the memory position by the biasing force of the memory biasing spring 27, and the movement of the memory unit MU1 with respect to the memory rack 25 is restricted by the engagement relationship between the memory lock pawl 28a and the memory lock hole 25a. ing.
The angle holding mechanism is also in a locked state.

First, a normal seat slide operation in which the seated person arbitrarily adjusts the position of the seat 11 in the front-rear direction will be described.
When the loop handle 18b is lifted upward in the normal seating state, the loop bracket 18 rotates clockwise from the position of FIG. 5 to the position of FIG. 6, and the pressing portion 18a presses the pressed portion 19a to lock the open bracket. 19 is rotated clockwise. With the rotation of the lock open bracket 19, the pressing portion 19b presses the pressed arm 17b, and the slide lock plate 17 rotates to the unlock position against the lock urging spring 17c (see FIG. 13). Thereby, the slide regulation of the upper rail 15 with respect to the lower rail 16 is released. Since the upper rail 15 is urged forward by a slide urging spring (not shown), when the slide restriction is released, the upper rail 15 slides forward with respect to the lower rail 16 as shown in FIG.

  Further, when the loop bracket 18 is rotated, the stopper lever 22 is also rotated clockwise, and the catch lever 20 coupled via the torsion spring 20b is rotated clockwise. Then, the engaging recess 20a of the catch lever 20 is engaged with the engaging protrusion 28b, and the memory lock lever 28 is pushed downward while being integrated with the memory lock lever 28, and the memory lock lever 28 is moved from the memory position to the memory release position. Move. Thereby, the sliding restriction of the memory unit MU1 with respect to the memory track 25 is released. Therefore, when the seat 11 (upper rail 15) is moved with respect to the lower rail 16 as shown by a two-dot chain line in FIG. 1, the catch lever 20 and the memory lock lever 28 are integrated, so that the memory unit MU1 is also seated. Slide with the whole. When the hand is released from the loop handle 18b, the slide lock plate 17 returns and rotates to the lock position, and the movement of the seat 11 is prohibited. At the same time, the memory lock lever 28 returns to the memory position.

Next, the walk-in operation will be described.
When the seated person gets off the seat 11 and operates the walk-in operation handle 30, the walk-in wire is pulled and the angle holding mechanism is unlocked, and the seat back 13 is tilted forward by the rotational biasing force of the biasing means. Move to position. Then, the pulling wire 31 that has been in a relaxed state is tensioned. As a result, the lock open lever 21 rotates counterclockwise from the position of FIG. 5 to the position of FIG. 7 against the torsion spring 21c. When the lock open lever 21 rotates counterclockwise, the pressing pin 21a presses the pressing portion 19b downward, and the lock open bracket 19 rotates clockwise. The slide lock plate 17 is rotated to the unlock position against 17c (FIG. 13).
In FIG. 13, the pressing pin 21 a of the lock open lever 21 does not press the pressing portion 19 b of the lock open bracket 19, but this is the case of the above-described normal slide operation, and in the walk-in operation, the pressing pin 21 a is illustrated in FIG. It moves below the position of 13 and presses the pressing part 19b. At this time, since the pressed portion 19a of the lock open bracket 19 is separated (escapes) from the pressing portion 18a, the loop bracket 18 does not rotate, and the stopper lever 22 and the catch lever 20 do not rotate. If the catch lever 20 is not rotated, the memory lock lever 28 is not moved from the memory position. That is, the entire seat 11 (upper rail 15) is slidable with respect to the lower rail 16, but the memory unit MU1 is in a state of FIG.

  As described above, since the upper rail 15 is urged forward by a slide urging spring (not shown), when the slide lock plate 17 is rotated to the unlock position as a result of the walk-in operation, the upper rail 15 is shown in FIG. Slide forward relative to the lower rail 16. At this time, the memory unit MU1 remains fixed at a position before the sheet 11 moves. This is the walk-in state indicated by the two-dot chain line in FIG.

  When returning from the walk-in state, the seat 11 is slid backward. Then, as shown in FIG. 9, the slide stopper 29 comes into contact with the stopper projection 26 b of the slide piece 26, and the sheet 11 can no longer retreat. Since the slide piece 26 has not moved from the beginning of the walk-in operation, the retreat restriction position is the stored seat position. When the seat back 13 is raised from the forward tilted position, the pulling wire 31 is relaxed and the lock open lever 21 returns to the normal seating position shown in FIG. 5, and the lock open bracket 19 is pressed accordingly. The pressing state on the arm 17b is released, the slide lock plate 17 returns to the lock position, and the seat 11 is fixed.

As described above, according to the seat device of the present embodiment, during the normal seat sliding operation, the unlock operation of the memory rack 25 and the memory lock lever 28 fixed to the lower rail 16 and the sliding movement of the seat 11 (upper rail 15). Since the operation of transmitting the force to the memory unit MU1 is performed only by the engaging recess 20a of the catch lever 20, these two operations are performed surely and smoothly, and the catch lever 20 needs to be produced with high accuracy. Nor.
Furthermore, since the memory lock lever 28, which is a member that exhibits a memory function, is moved to the memory position and the memory release position by only the catch lever 20, and is moved in the front-rear direction, a slide memory is provided as compared with the prior art. The structure of the mechanism is simple, and the manufacturing cost can be kept low.

Next, a second embodiment of the present invention will be described with reference mainly to FIGS.
Note that the same members as those in the first embodiment are denoted by the same reference numerals, and detailed description thereof is omitted.

This embodiment is different from the first embodiment in a mechanism (memory control mechanism) for moving the memory lock lever 28, which is a member of the slide memory mechanism U2, between the memory position and the memory release position. .
Furthermore, in the first embodiment, this mechanism is interlocked with the movement of the loop handle 18b and not with the movement of the seat back 13, but in this embodiment, this mechanism is the operation of the seat back 13. Is interlocked with the movement of the loop handle 18b.
Hereinafter, these differences will be described in detail.

First, a memory control mechanism for moving the memory lock lever 28 between the memory position and the memory release position will be described.
The catch lever 40 of the present embodiment has a substantially V shape in a side view, and a V-shaped apex portion 40a is pivotally attached to the upper rail 15 (not shown in FIGS. 17 to 19) via a rotation shaft 41. Furthermore, the catch lever 40 is always urged to rotate clockwise in FIGS. 17 and 18 by a torsion spring 42 provided between the catch lever 40 and the upper rail 15. The rear end portion 40b of the catch lever 40 is provided with an engagement concave portion 40c similar to that of the first embodiment, and this engagement concave portion 40c can be freely engaged with and disengaged from the engagement protrusion 28b of the memory lock lever 28. It is.

An inclined guide surface (guide surface) 43a is formed at the front end portion of the slide piece 43 and is inclined rearward and obliquely upward, and a stopper projection 43b similar to that of the first embodiment is provided at the rear end portion. . Further, the slide piece 43 includes a storage recess 43c whose upper surface is open so that the memory lock lever 28 can be moved in the vertical direction and can be stored in the forward and backward directions. The memory lock lever 28 can take a memory position (position in FIG. 18) for engaging the memory lock pawl 28a with the memory lock hole 25a and a memory release position (position in FIG. 17) for releasing the engagement. The memory urging spring 27 is always urged toward the memory position.
As described above, the catch lever 40 is urged to rotate clockwise by the torsion spring 42, and the engagement recess 40c is normally engaged with the engagement protrusion 28b of the memory lock lever 28 in the storage recess 43c. Since the memory lock lever 28 is normally positioned against the urging force of the memory urging spring 27, the memory lock claw 28a extends from the memory lock hole 25a. It is located at the memory release position to escape (see FIG. 17).

In addition, a rear end portion of the link member 45 facing substantially in the front-rear direction is pivotally attached to the upper end portion of the lock open lever 21 via the rotation shaft 44. An engagement pin 40d that protrudes from the end opposite to the engagement recess 40c of the catch lever 40 and faces in the left-right direction is fitted in the elongated hole 45a that is formed in the front and rear direction. is doing.
Further, the end portion of the pulling wire (operation means) 31 is fixed to the attachment portion 45 b formed at the rear end portion of the link member 45.

In this way, the other end of the pulling wire 31 whose one end is fixed to the seat back frame is fixed to the attachment portion 45b of the link member 45, so that the movement of the seat back 13 is transmitted to the link member 45. It has become.
On the other hand, the seat device of the present embodiment does not include the stopper lever 22 provided in the first embodiment, and therefore the movement of the loop handle 18 b is not transmitted to the catch lever 40.
Further, the slide memory mechanism includes the seat back 13, the memory rack 25, the memory biasing spring 27, the memory lock lever 28, the pulling wire 31, the catch lever 40, the torsion spring 42, the slide piece 43, the rotating shaft 44, and the link member 45. U2 is configured.
Further, the memory urging spring 27, the memory lock lever 28, and the slide piece 43 constitute a memory unit MU2.

Next, a normal seat slide operation and a walk-in operation of the seat device according to the present embodiment will be described.
The normal seat slide operation is performed by the loop handle 18b as in the first embodiment. However, as described above, since the movement of the loop handle 18b is not transmitted to the catch lever 40, the loop handle 18b can be operated. The memory lock lever 28 remains in the memory release position (FIG. 17). Therefore, when the loop handle 18b is operated to unlock the upper rail 15 and the lower rail 16, the memory unit MU2 can slide with respect to the lower rail 16 together with the upper rail 15 (seat 11).

  The walk-in operation is performed by operating the walk-in operation handle 30 in a state where the seated person gets off the seat 11. When the walk-in operation handle 30 is operated, the angle holding mechanism is unlocked, the seat back 13 is moved to the forward tilt position by the rotation biasing force of the biasing means, and the pulling wire 31 in the relaxed state is tensioned. As a result, as shown in FIG. 18, the link member 45 moves forward from the position of FIG. 17, and the lock open lever 21 rotates counterclockwise in FIGS. Then, as in the first embodiment, the slide lock plate 17 is rotated to the unlock position, and the upper rail 15 (seat 11) can slide with respect to the lower rail 16.

Further, as the link member 45 moves forward, as shown in FIG. 18, the rear end of the long hole 45 presses the engagement pin 40 d forward, and the catch lever 40 rotates against the urging force of the torsion spring 42. It rotates counterclockwise around the moving shaft 41. Then, the engagement of the engagement recess 40c of the catch lever 40 and the engagement protrusion 28b of the memory lock lever 28 is released, and the memory lock claw 28a is moved by the urging force of the memory urging spring 27. It moves to the memory position that engages with the memory lock hole 25a.
As a result, the entire seat 11 (upper rail 15) can slide with respect to the lower rail 16, but the memory unit MU2 enters a walk-in state in which it cannot move relative to the memory rack 25.

  When the seat 11 is slid rearward from this walk-in state, the slide stopper 29 (not shown in FIGS. 16 to 18) abuts against the stopper projection 43b of the slide piece 43, and the seat 11 cannot be further retracted. Since the slide piece 43 has not moved from the beginning of the walk-in operation, the retreat restriction position is the stored seat position. When the seat back 13 is raised from the forward tilt position to the standing position, the slide lock plate 17 is moved. Returns to the locked position, and the seat 11 is fixed.

Further, when the seat 11 is slid rearward from the walk-in state, the rearward movement of the seat 11 is stopped before the slide stopper 29 contacts the stopper protrusion 43b of the slide piece 43 by mistake or intentionally. Then, the seat back 13 may be returned to the standing position at that position, and the seat 11 may be locked with respect to the lower rail 16.
In such a case, when the lock of the slide lock plate 17 is released by a normal seat slide operation and the seat 11 is moved backward until the slide stopper 29 comes into contact with the stopper projection 43b, in the middle of FIG. As shown in FIG. 4, the rear end portion 40 b of the catch lever 40 contacts the inclined guide surface 43 a of the slide piece 43. Since the rear end portion 40b of the catch lever 40 is urged to rotate counterclockwise by the urging force of the torsion spring 42, the rear end portion 40b moves rearward while sliding on the upper surface of the slide piece 43 after getting over the inclined guide surface 43a. Soon, it falls into the recess 43c for storage. Finally, the catch lever 40 automatically returns to the unlock position as shown in FIG.

  As described above, according to the present embodiment, during the walk-in operation, the unlocking operation of the memory rack 25 and the memory lock lever 28 fixed to the lower rail 16 and the sliding movement force of the seat 11 and the upper rail 15 (catch lever) are performed. Since the operation of transmitting to the memory unit MU2 is performed only by the engaging recess 40c of the catch lever 40, these two operations are performed reliably and smoothly, and it is not necessary to produce the catch lever 40 with high accuracy. . Furthermore, since the memory lock lever 28, which is a member that exhibits the memory function, is moved to the memory position and the memory release position by only the catch lever 40 and moved in the front-rear direction, the member that exhibits the memory function Since the memory lock lever 28 is moved to the memory position and the memory release position only by the catch lever 40, the structure of the slide memory mechanism is simpler than the conventional structure, and the manufacturing cost can be kept low. It is possible.

  Further, when the seat 11 is slid rearward from the walk-in state, the rearward movement of the seat 11 is temporarily stopped and locked to the lower rail 16 before the slide stopper 29 comes into contact with the stopper projection 43b of the slide piece 43. Then, if the seat 11 is moved backward until the slide stopper 29 comes into contact with the stopper projection 43b by a normal seat slide operation, the catch lever 40 can be automatically and smoothly returned to the unlock position. It has become.

As described above, the present invention has been described using the two embodiments. However, the present invention is not limited to these embodiments, and various modifications can be made according to the object of the invention.
For example, the lower rail 16 is formed with a plurality of lock claws 17a arranged in the longitudinal direction, and the slide lock plate 17 is provided with one slide lock hole 16a that can be engaged with and disengaged from the lock claws 17a, It is also possible to provide an engagement protrusion 28b at the tip of 40 and an engagement recess 20a that can be engaged with and disengaged from the engagement protrusion 28b at the upper end of the memory lock lever 28.
Further, the memory rack 25 is omitted, and a bowl-shaped part capable of storing the memory pieces 26 and 43 is formed in a part of the lower rail 16, and a memory lock hole 25 a is formed in the bowl-shaped part, or the memory rack 25 Alternatively, the memory lock claw 28a may be provided in the hook-shaped portion, and the memory lock hole 25a may be provided in the memory lock lever 28.

It is a side view which shows the normal seating state of the vehicle seat apparatus of the 1st Embodiment of this invention, and the sliding state to the front. It is a side view which shows the walk-in operation state of the sheet apparatus. It is a disassembled perspective view of the seat slide mechanism of the seat apparatus. It is a side view of the seat slide mechanism of the seat device. It is a side view which shows the seat slide mechanism in a normal seating state. It is a side view of the seat slide mechanism in a normal slide state. It is a side view of a seat slide mechanism immediately after performing a walk-in operation. It is a side view which shows the seat slide mechanism of the walk-in state which left the memory unit and slid the seat forward. FIG. 6 is a side view of the seat slide mechanism when the seat is retracted from the walk-in state to the memory position. It is sectional drawing which follows the AA line of FIG. It is sectional drawing which follows the BB line of FIG. It is sectional drawing of the slide lock state which follows the CC line of FIG. It is sectional drawing of the slide lock release state in alignment with the C'-C 'line of FIG. It is sectional drawing which follows the DD line | wire of FIG. It is sectional drawing which follows the EE line | wire of FIG. It is a disassembled perspective view of the slide memory mechanism and its peripheral member of the sheet | seat apparatus of the 2nd Embodiment of this invention. It is a side view which shows a slide memory mechanism and its peripheral member when a seat back exists in a standing position. It is a side view showing a slide memory mechanism and its peripheral members when the seat back is tilted forward. After the walk-in operation, the seat is moved backward, once locked in front of the memory position, and then moved back to the memory position again, the tip of the catch lever is in contact with the inclined guide surface of the slide piece. FIG.

Explanation of symbols

U1 U2 Slide memory mechanism MU1 MU2 Memory unit 10 Floor panel (floor surface)
11 Seat 11x Rotating shaft 12 Seat cushion 13 Seat back 14 Seat cushion frame 15 Upper rail 15a Square hole 16 Lower rail 16a Slide lock hole (slide lock mechanism)
17 Slide lock plate 17a Lock claw (slide lock mechanism)
17b Pressed arm 17c Lock urging spring 17x Rotating shaft 18 Loop bracket 18a Pressing portion 18b Loop handle (operating means)
18x Rotating shaft 19 Lock open bracket 19a Pressed portion 19b Pressed portion 20 Catch lever 20a Engaging recess 20b Torsion spring 21 Lock open lever 22 Stopper lever 25 Memory rack (fixing member)
25a Memory lock hole 26 Slide piece 26a Storage recess 26b Stopper projection 27 Memory bias spring 28 Memory lock lever 28a Memory lock claw (memory lock projection)
28b engagement protrusion 29 slide stopper 30 walk-in operation handle 31 pulling wire (operation means)
40 Catch lever 40a Vertex 40b Rear end 40c Engaging recess 40d Engaging pin 41 Rotating shaft 42 Torsion spring 43 Slide piece 43a Inclined guide surface (guide surface)
43b Stopper projection 44 Rotating shaft 45 Link member 45a Long hole 45b Mounting portion

Claims (6)

A lower rail on the floor side and an upper rail that is slidable relative to the lower rail and fixed to the seat side;
A seat cushion supported by the upper rail and moving in a sliding direction together with the upper rail;
A seat back that is pivotably supported between a seating standing position and a forward tilting position with respect to the seat cushion;
A slide memory mechanism for storing a seat position when the seat back is tilted forward and restricting movement of the seat backward from the storage position;
In a vehicle seat device comprising:
The slide memory mechanism is
The memory is movable between a memory position that cannot move relative to the lower rail and a memory release position that can move along the lower rail, and is always urged toward the memory position and can be engaged with and disengaged from each other. A memory lock lever having one of a mating protrusion or an engaging recess;
The memory is provided on the upper rail side and has the other of the engagement protrusion or the engagement recess, and the memory lock lever is resisted against the urging force while the engagement protrusion and the engagement recess are engaged. It is possible to move between the unlock position for moving to the release position and the lock position for releasing the engagement between the engagement protrusion and the engagement recess and allowing the memory lock lever to return to the memory position. Catch lever,
Operating means for moving the catch lever to the unlock position and the lock position;
A vehicle seat device comprising: The vehicle seat device according to claim 1,
A plurality of memory lock holes or memory lock protrusions that are detachable from each other are formed side by side in the longitudinal direction on the lower rail or the fixing member fixed to the lower rail,
Form the other of the memory lock hole or the memory lock protrusion on the memory lock lever,
A vehicle seat device that holds the memory lock lever at the memory position by engaging the memory lock hole with a memory lock protrusion. The vehicle seat device according to claim 1 or 2,
The slide memory mechanism includes a slide stopper protrusion which is not movable relative to the upper rail when the memory lock lever is at the memory position;
The vehicle seat device having a stopper protrusion that prohibits the seat from moving backward from the contact position when the upper rail contacts the slide stopper when the memory lock lever is at the memory position. The vehicle seat device according to any one of claims 1 to 3,
A slide lock mechanism capable of transitioning between a locked state that restricts sliding of the upper rail with respect to the lower rail and an unlocked state that allows the sliding;
The operating means is a loop handle for switching the slide lock mechanism between a locked state and an unlocked state;
The loop handle moves the catch lever to the locked position when the slide lock mechanism is in the locked state, and moves the catch lever to the unlock position when the slide lock mechanism is in the unlocked state. Vehicle seat device to be moved. The vehicle seat device according to any one of claims 1 to 3,
The operating means is a tow wire that transmits the movement of the seat back to the catch lever;
The pulling wire moves the catch lever to the unlock position when the seat back moves to the standing position, and moves the catch lever to the lock position when the seat back moves to the forward tilt position. apparatus. The vehicle seat device according to claim 5,
The catch lever is pivotally attached to the upper rail so as to swing in response to the operation of the pulling wire, and is always urged toward the unlock position.
The slide memory mechanism includes a slide piece that moves together with the memory lock lever in the longitudinal direction of the lower rail;
The slide piece has a recess for storing the memory lock lever, and the catch lever positioned in front of the slide piece moves backward to come into contact with the catch lever so that the catch lever is A vehicle seat device comprising: a guide surface that guides the engagement recess or the engagement protrusion of the catch lever to the storage recess while swinging toward the lock position.

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