JPH0627297U - Sheet device having walk-in function - Google Patents

Abstract

(57) [Abstract] [Purpose] To provide a seat device with a walk-in function that can be easily assembled, does not malfunction even in a harsh environment, and can be securely slide-locked at a memory position. [Structure] A pin that rotates together with the upper arm 16 side
41, a memory protrusion 71 provided at a predetermined position on the upper surface side of the lower rail 11, and an upper end pivotally supported on the lower arm 15 side and a lower end side slidably on the upper surface side of the lower rail 11. The memory protrusion detection member 73 to be abutted and the bent portion at the center are lowered.
A hook 77a for pivotally supporting the pin 41 at the upper end, and a hook 77a for locking the pin 41 at the upper end, and a locking member 77 capable of transmitting the acting force from the memory projection detecting member 73 at the lower end; When the rail 12 slides backward, the locking member 77 is rotated in conjunction with the memory projection detection member 73 being pushed up by the memory projection 71 to release the locking with the pin 41, and the upper upper -M 16
A seat device in which the upper rail 12 is locked to the lower rail 11 in synchronism with the operation of reversing.

Description

[Detailed description of the device]

[0001]

[Industrial applications]

 The present invention relates to a sheet device having a walk-in function. More specifically, the present invention relates to a device in which an upper rail made slidable by a walk-in function is again locked to a lower rail at a predetermined memory position.

[0002]

[Prior art]

 (1) A seat device provided with a walk-in function and used as a front seat of a two-door vehicle is provided. The walk-in function is a function that allows the seat back of the front seat to be tilted forward from the rear seat side by a simple operation so that the slide lock of the front seat can be released and the seat can be moved forward. . This facilitates getting in and out of the rear seats.

(2) In addition to the above-mentioned walk-in function, a sheet device provided with a function (memory function) of automatically relocking at a certain position when moving (returning) backwards is provided. Has been done. In this device, if the seat back of the front seat that has been moved to the front end position by the walk-in function is caused (reset) and then moved to the rear, the slide lock occurs when passing through the above-mentioned position. The mechanism is actuated and the upper rail is locked again with respect to the lower rail, and the movement of the seat is stopped.

[0004]

[Problems to be solved by the device]

 The conventional memory function of (2) above is realized, for example, by the mechanism shown in FIG. FIG. 5 is a diagram showing a slide lock mechanism according to the embodiment of the present invention. Since this mechanism is the same as the conventional one, description will be given here also with reference to FIG.

First, when the seat back (not shown in FIG. 6) is tilted forward, the inner wire 56b is pulled in conjunction with this and the interlocking arm 57 is rotated counterclockwise in the figure. . The release handle shaft 50 is also rotated in the same manner in conjunction with the communication arm 57, and the claw portion 53a (FIG. 5) at the tip of the lock member 53 integrated with the release handle shaft 50 locks the lower rail. Exit through hole 55. As a result, the slide lock between the upper rail 12 and the lower rail 11 is released. The lock holes 55 are formed along the side wall of the lower rail 11 at regular intervals, and when the above-mentioned claw portion 53a enters any one of the lock holes 55, the upper rails 55a. -Rule 12 and lower 11 are locked in that position. This is the slide lock mechanism.

By the way, a locking portion 57a is formed at the upper end portion of the interlocking arm 57, and the locking portion 57a is formed in the memory plate at the time of the above rotation (rotation at the time of unlocking). The lower surface 65 of the lower surface 65 is inserted into the corresponding hole 65a and locked. Therefore, it is possible to prevent the interlocking arm 57 from rotating in the reverse direction, in other words, preventing the claw portion 53a from entering the lock hole 55 again and entering the slide lock state. The memory plate 65 is a plate material having spring elasticity provided so as to project from the upper arm 16.

Next, a mechanism in which the slide lock is performed by the memory function will be described. As shown in FIG. 6, a memory protrusion 63 is provided at a memory position (a predetermined position in the longitudinal direction of the lower rail) on the upper surface of the lower rail 11. Further, on the lower surface side of the memory plate 65, a protruding portion 65b for detecting the memory protrusion is provided at a portion corresponding to the memory protrusion 63.

Therefore, when the seat back moved to the front end position is caused to move backward, the protrusion 65b for detecting the memory protrusion is pushed upward when passing the position of the memory protrusion 63. As a result, the engaging portion 57a of the interlocking arm 57 is pulled out from the hole portion 65a of the memory plate 65. As a result, the release handle shaft 50 integrated with the interlocking arm 57 is locked in the locking direction (the direction in which the claw portion 53a enters the lock hole 55 by the biasing force of the torsion spring 54 (see FIG. 1)). ), The upper rail 12 and the lower rail 11 are locked in that position.

As described above, in the conventional memory function shown in FIG. 6, the spring elasticity of the memory plate 65 causes the hole 65a of the memory plate 65 and the locking portion 57a of the interlocking arm 57 to lock / lock. Achieved unlocking. For this reason, strict precision is required at the time of assembly, and in a severe environment such as vibration, the slide lock mechanism may malfunction. The present invention has been made in view of the above circumstances, and an object thereof is to provide a device that can be easily assembled and does not malfunction even in a harsh environment.

[0010]

[Means for Solving the Problems]

 In the present invention, the upper rails are slidably mounted on the pair of left and right lower rails, and the pair of left and right lower arms are integrally attached to the upper rails, respectively. Of the upper arm is rotatably supported at the rear ends of the lower arms, and the upper arm is interlocked with the operation of tilting the upper arm forward. In a seat device in which the upper rail is slidable with respect to the lower rail by releasing the lock between the rail and the lower rail; A pin provided on the upper arm side and rotated integrally with the upper arm, a memory protrusion provided at a predetermined position on the upper surface side of the lower rail, and an upper end portion. The lower arm is rotatably supported on the lower arm side and the lower end side is on the upper side of the lower rail. A memory protrusion detection member that is movably abutted, a substantially V-shaped bent portion rotatably supported on the lower arm side, and a hook for locking the pin at the upper end portion. And a locking member having a lower end portion configured to be able to transmit the acting force from the memory protrusion detection member; the pin is hooked by the locking member when the upper arm is tilted forward. It is generated by locking the upper arm so that the upper arm does not rise, and the lower end of the memory protrusion detecting member is pushed up by the memory protrusion when the upper rail slides. The lower end of the locking member receives the acting force to rotate the locking member, whereby the locking between the hook and the pin is released, and the upper arm is reclined. The prohibition is released and the upper arm is restarted. To the upper - les - the Le Loiret - wo was to lock against Le - a winding device - sheet having Quinn function.

[0011]

[Action]

 When the seat back of the seat at the front end position is moved to the rear, the lower end side of the memory protrusion detection member is pushed upward when passing through the memory protrusion, and the upper end is covered. It is rotated around the pivot position. Further, the turning force is transmitted to the lower end portion side of the locking member, whereby the locking member is also rotated around the pivotally supported position of the bent portion. In this way, the engagement between the engagement member on the lower arm side and the pin on the upper arm side is released, and the upper arm is rotatable with respect to the lower arm. Also, when the upper arm is rotatable with respect to the lower arm, the seat back is not caused because the rearward biasing force is applied to the seat back by the hand as described above. Being (being set back). Also, in conjunction with this operation, the upper rail is locked with respect to the lower rail.

[0012]

【Example】

 Embodiments of the present invention will be described below. FIG. 1 is a schematic side view of a sheet device of an embodiment, and FIG. 2 is a schematic perspective view showing the appearance of members for realizing the memory function of the device. 3 is a sectional view taken along the line aa of FIG. 1, FIG. 4 is a sectional view taken along the line bb, and FIG. 5 is a sectional view taken along the line cc.

The seat device is used as a front seat of a two-door vehicle. As shown in the figure, the seat apparatus of the present invention has a pair of left and right lower rails 11 fixed in parallel to the floor surface (however, only the left side in FIG. 1; 12 are slidably provided, and a pair of left and right lower arms 15 for supporting the seat cushion 19 are integrally attached to each upper rail 12, and further for supporting the seat back 20. The lower ends of a pair of left and right upper arms 16 are rotatably supported by a support shaft 17 at the rear end of the lower arm 15.

In the above, the upper rail 12 has an inverted T-shaped cross section as shown in FIG. 5, and the bottom portion thereof is accommodated in a lower rail 11 having a box-shaped cross section. It is fitted in the lower rail 11 so as to be placed on the roller 45. As a result, the upper rail 12 is slidable in the rail direction with respect to the lower rail 11.

Further, the walk-in function is realized as follows. First, when the pedal 33 is pushed down or the release handle 31 is pulled up, the pin 35b restricted by the long hole 31b of the release handle 31 is urged counterclockwise in the figure. Since the pin 35b is a pin that is integrally erected from the swing lock member 35, the swing lock member 35 is also rotated in the same direction about the support shaft 29. Therefore, the rocking lock tooth 35a, which is meshed with the ratchet tooth 40a of the ratchet 40, is separated from the ratchet tooth 40a, and the meshing therebetween is released.

The ratchet 40 is integral with the upper arm 16, and the swing lock member 35 is pivotally supported on the lower arm 15 by a support shaft 29. Therefore, when the engagement between the rocking lock tooth 35a and the ratchet tooth 40a is released as described above, the upper arm 16 becomes free from the lower arm 15 and is rotatable. The upper arm 16 is constantly subjected to a counterclockwise biasing force by a rotating spring 24 (see FIGS. 3 and 4). Therefore, when the upper arm 16 is rotatable as described above, it is immediately rotated forward (tilted) by the urging force of the rotating spring 24. In this way, the seatback 20 is tilted forward.

When the upper arm 16 (that is, the seatback 20) is tilted forward, one end of the inner wire 56b having one end fixed to the upper arm 16 is moved to the upper arm. The inner wire 56b is pulled as a result of the rotation of the inner wire 56b. The other end of the inner wire 56b is connected to an interlocking arm (not shown) as in the case of the paragraph number "0005" (conventional). Therefore, when the inner wire 56b is pulled as described above, the interlocking arm rotates in the same manner as in the case of the paragraph number "0005", and the slide lock is similarly released.

In the conventional interlocking arm 57 shown in FIG. 6, a locking portion 57a is formed at the upper end, and the locking portion 57a enters into the hole 65a of the memory plate 65 and is locked. As a result, the rotation of the interlocking arm 57 in the reverse direction (re-slide lock) is prohibited, but the interlocking arm (not shown) of the apparatus of this embodiment has no locking portion 57a. There is also no memory plate 65.

In the apparatus of the present embodiment, the mechanism shown in FIG. 2 (and FIG. 1) prohibits the upper arm 16 from being raised (rearward), whereby the release handle shaft 50 rotates in the opposite direction. (Re-slide lock) is prohibited.

First, the ratchet 40 integrated with the upper arm 16 is provided with a pin 41 standing in the direction of the lower arm 15 (lateral direction), as shown in FIG. 2 (a). As shown in FIG. 2B, the tip loosely penetrates the arc-shaped long hole 15a formed in the lower arm 15 and projects from the plate surface of the lower arm 15. The curvature of the long hole 15a is the same as the locus of the pin 41 rotated with the rotation of the ratchet 40.

On the other hand, a locking plate 77 and a memory projection detecting plate 73 are pivotally supported on the lower arm 15 so as to be rotatable as shown in FIG. The lower end portion and the central portion of the memory protrusion detection plate 73 are connected by a link 75. Further, a memory protrusion plate 71 is provided at a predetermined position on the upper surface of the lower rail 11 (a position corresponding to the timing for operating the slide lock mechanism, hereinafter referred to as a memory position).

As described above, when the upper arm 16 is tilted forward, the ratchet 40 is also rotated integrally. Therefore, the pin 41 reaches the lower end position in FIG. 2B and is locked by the hook 77a at the upper end of the locking plate 77. As a result, the raising (backward) of the upper arm 16 is prohibited. When the upper arm 16 is prohibited from being pulled up (rearward), the inner wire 56b is held in the pulled state, so that the interlocking arm and the interlocking arm are integrated with each other. The release handle shaft 50 is also held in the rotated state (slide lock released state), and thus the re-slide lock is prohibited.

Next, a mechanism in which the slide lock is performed by the memory function will be described. First, by holding the seat back 20 moved to the front end position by hand and moving it backward, when the lower end portion of the memory protrusion detection plate 73 passes through the protrusion position 71a of the memory protrusion plate 71, The memory protrusion detection plate 73 is pushed upward and rotated clockwise in the figure. As a result, the link 75 is displaced leftward in the figure, and the lower end portion of the locking plate 77 is pulled leftward in the figure. Therefore, the locking plate 77 is rotated in the clockwise direction in the drawing around the support shaft 78, whereby the pin 41 is disengaged from the hook 77a of the locking plate 77, and the upper arm 16 is removed. It can be triggered (successive).

In this way, when the upper arm 16 can be raised (removed), the seat back 20 is biased rearward from the hand as described above, and therefore the seat back is provided. 20 is triggered. Further, since the inner wire 56b is loosened in conjunction with this operation, the release handle shaft 50 is rotated in the slide lock direction by the biasing force of the torsion spring 54. Therefore, the upper rail 12 is again locked to the lower rail 11.

[0025]

[Effect of device]

 As described above, according to the present invention, when the seat back is held by hand and moved backward, when the lower end side of the memory protrusion detection member passes through the memory protrusion, the hook on the upper end of the lower arm side locking portion Then, the engagement with the pin on the upper arm side is released. When the upper arm side and the lower arm side are released from the lock, the seat back is caused by the backward biasing force applied to the seat back by the hand (reset). The upper rail is locked with respect to the lower rail.

As described above, according to the present invention, the upper rail is reliably locked at the predetermined memory position with respect to the lower rail by a relatively simple operation of moving the seat back backward by hand. it can. Also, since the mechanism for that is simple, it is easy to assemble, and there is no risk of malfunctions in severe environments such as vibration.

[Brief description of drawings]

FIG. 1 is an explanatory view schematically showing a side surface of a sheet device according to an embodiment.

FIG. 2 is an explanatory view showing the external appearance of a mechanism for locking / unlocking the upper arm side and the lower arm side of the seat device of the embodiment.

3 is a cross-sectional view taken along the line aa of FIG.

FIG. 4 is a sectional view taken along line bb of FIG.

5 is a sectional view taken along line cc of FIG.

FIG. 6 is an explanatory diagram of a memory function of a sheet device having a conventional walk-in function.

[Explanation of symbols]

 11 Lower Rail 12 Upper Rail 15 Lower Arm 16 Upper Arm 40 Ratchet 41 Pin 71 Memory Protrusion Plate 73 Memory Protrusion Detection Plate 75 Link 77 Locking Plate 77a Hook

Claims (1)

[Scope of utility model registration request] 1. A pair of left and right lower lowers for supporting a seat cushion, wherein upper and lower rails are slidably provided to a pair of left and right lower rails fixed in parallel to a floor surface. -Attach the above-mentioned upper rails to each one integrally,
The lower ends of a pair of left and right upper arms for supporting the seat back are rotatably supported at the rear ends of the lower arms, respectively. A wok-in that makes the upper rail slidable with respect to the lower rail by releasing the lock between the upper rail and the lower rail in conjunction with the forward movement. In a sheet device having a function; provided on the upper arm side so as to project laterally,
A pin that is rotated integrally with the arm, a memory protrusion provided at a predetermined position on the upper surface side of the lower rail, an upper end portion rotatably supported on the lower arm side, and a lower end portion. Side, and a memory protrusion detecting member slidably abutting on the upper surface side of the lower rail, and a substantially V-shaped bent portion rotatably supported to the lower arm side, and an upper end portion of the memory protrusion detecting member. A locking member having a hook for locking the pin and having a lower end portion configured to be able to transmit the acting force from the memory projection detecting member; and when the upper arm is tilted forward. By locking the pin with the hook of the locking member, the rising of the upper arm is prohibited, and the lower end side of the memory protrusion detecting member is at the time of sliding of the upper rail. The action generated by being pushed up by the memory protrusion On the lower end side of the locking member to rotate the locking member, thereby releasing the locking of the hook and the pin and releasing the prohibition of the upright standing of the upper arm. Then, the upper rail is locked with respect to the lower rail in conjunction with the operation of reversing the upper arm; a seat device having a walk-in function.