JP4071167B2 - Electric storage structure for vehicle seat - Google Patents

Description

[0001]
BACKGROUND OF THE INVENTION
The present invention relates to an electric storage structure for a vehicle seat that electrically stores and restores a rearmost rear seat disposed behind a front seat.
[0002]
[Prior art]
Some vehicles are provided with a first rear seat and a second rear seat behind the front seat so that 6 to 7 people can get on the vehicle. For example, a vehicle that folds the second rear seat to form a large space in the passenger compartment is known. (For example, refer to Patent Document 1).
[0003]
[Patent Document 1]
Japanese Utility Model Publication No. 5-40029 (page 5-6, FIG. 3)
[0004]
39 is a cross-sectional view of FIG. The code was reassigned.
In the vehicle seat storage structure 300, the second rear seat 301 provided at the rearmost part of the automobile is disposed at a position indicated by a solid line (hereinafter referred to as a "sitting position") so that a normal occupant 302 can be seated. For example, when placing a large load in the passenger compartment 303, the second rear seat 301 is configured to be stored in the rear floor storage recess 304.
An example of storing the vehicle seat storage structure 300 in the floor storage recess 304 will be described in detail with reference to the following drawings.
[0005]
40A to 40C are views for explaining the operation of the conventional vehicle seat storage structure.
In (a), when the second rear seat 301 of the vehicle seat storage structure 300 is stored in the floor storage recess 304, the seat back 306 is first moved forward as shown by the arrow and overlapped with the seat cushion 307.
[0006]
In (b), the headrest 308 is removed from the seat back 306 overlapped with the seat cushion 307 and stored in the headrest storage unit 309 (see (b)) provided in the passenger compartment 303.
Next, the seat cushion 307 is swung back (swinged) integrally with the seat back 306 as indicated by an arrow about the support shaft portion 310 as an axis.
In (c), the seat cushion 307 and the seat back 306 (second rear seat 301) are stored in the floor storage recess 304.
[0007]
Here, the second rear seat 301 itself is relatively heavy, and a large operating force is required to swing the second rear seat 301 manually behind the vehicle body and store it in the floor storage recess 304.
In addition, when the second rear seat 301 is stored in the floor storage recess 304, it is necessary to swing manually while releasing the lock of the second rear seat 301.
[0008]
For this reason, when the second rear seat 301 is stored in the floor storage recess 304, it takes time and effort, and there is room for improvement.
As means for improving this problem, for example, it is conceivable to electrically store the second rear seat 301 in the floor recess 304.
[0009]
[Problems to be solved by the invention]
Thus, in order to electrically store the second rear seat 301 in the floor storage recess 304, the seat back 306 needs to be moved forward electrically.
As a method of electrically moving the seat back 306 forward, there is a method of releasing the locked state of the seat back 306 using an actuator such as an electric motor and causing the seat back 306 to move forward to the seat cushion 307 by the spring force of the spring. Conceivable.
[0010]
By the way, when the seat back 306 is configured to be moved forward electrically, the seat back 306 cannot be moved forward electrically when, for example, an electric circuit including an electric motor is in a non-energized state.
However, in consideration of usability of the automobile, for example, even when an electric circuit including an electric motor or the like is in a non-energized state, the posture of the seat back 306 can be appropriately changed according to the use of the automobile. preferable.
For this reason, the seat back 306 can be electrically moved forward, and in addition, the seat back 306 can be manually moved forward.
[0011]
Accordingly, an object of the present invention is to provide an electric seat storage structure for a vehicle seat in which the operation of moving the seat back forward can be performed either automatically or manually.
[0012]
[Means for Solving the Problems]
In order to achieve the above object, according to a first aspect of the present invention, there is provided a vehicle in which a seat back is attached to a seat cushion so that the seat back can be tilted up and down, and the seat back is rocked by an actuator so In the electric seat storage structure, the operation cable for unlocking the lock mechanism is bifurcated, the actuator is connected to one of the bifurcated cables, and the manual operation unit is connected to the other cable. The release can be performed either automatically or manually.
[0013]
The operation cable for releasing the lock of the lock mechanism is bifurcated, the actuator is connected to one side, and the manual operation unit is connected to the other side, so that the lock can be released either automatically or manually.
Therefore, the seat back can be moved forward electrically by releasing the lock of the lock mechanism with the actuator. On the other hand, for example, even when the electric circuit including the actuator is in a non-energized state, the seat back can be moved forward by the manual operation unit.
Thereby, the attitude | position of a seat back can be changed suitably according to the use of a motor vehicle.
[0014]
According to a second aspect of the present invention, the operation cable is built in the seat back and is loosened into an S shape, a U shape, or the like.
[0015]
The operation cable is built into the seat back with the S-shaped or U-shaped cable loosened. Therefore, when the occupant leans against the seat back and the seat back is deformed, the deformation of the seat back is absorbed by the looseness of the operation cable, and it is possible to prevent an external force exceeding a specified value from being applied to the operation cable.
[0016]
DETAILED DESCRIPTION OF THE INVENTION
Embodiments of the present invention will be described below with reference to the accompanying drawings. The drawings are viewed in the direction of the reference numerals.
FIG. 1 is a schematic view showing a vehicle provided with an electric storage structure for a vehicle seat according to the present invention.
The vehicle 10 includes a front seat 13 including a driver seat and a passenger seat on a floor 12 that constitutes a passenger compartment 11, a first rear seat 14 behind the front seat 13, and a second rear seat behind the first rear seat 14. (Vehicle seat) An electric storage structure 20 for a vehicle seat that changes the posture of the vehicle seat 15 and stores it in the floor storage recess 16 is provided.
The second rear seat 15 is configured such that the seat back is left and right independent.
Hereinafter, the electric storage structure 20 for a vehicle seat will be described in detail.
[0017]
FIG. 2 is a perspective view showing an electric storage structure for a vehicle seat according to the present invention.
The vehicle seat electric storage structure 20 includes a second rear seat 15. The second rear seat 15 is provided with a seat cushion 21 on the floor 12, and left and right seat backs (seat backs) 22, 23 are provided at the rear of the seat cushion 21 so as to be able to move forward and backward. A left headrest 24 is provided so that it can be moved forward and backward, and a right headrest 25 is provided on the top of the right seat back 23 so that it can be moved forward or backward.
A seat operation button 26 (see also FIGS. 7 and 8) is provided at a position behind the second rear seat 15 and away from the side surface of the second rear seat 15.
[0018]
FIG. 3 is a perspective view showing in detail an electric storage structure for a vehicle seat according to the present invention.
In the electric storage structure 20 for a vehicle seat, left and right support shafts (support shafts) 31 and 32 are attached to the left and right rear ends of a cushion frame 27 constituting a seat cushion 21 (see FIG. 2), and the right support shaft 32 is attached. The left support shaft 31 is attached to the swing drive mechanism 35 and the swing drive mechanism 35 is attached to the floor 12 while being rotatably attached to the floor 12 via the mounting member 33.
[0019]
In addition, the vehicle seat electric storage structure 20 includes left and right cushion lock mechanisms (cushion lock mechanisms) 36 and 37 at the left and right front ends of the cushion frame 27, respectively. The control part 42 is provided in the center part 41 (refer FIG. 2).
Specifically, the three leg portions 46 are extended from the control unit 42, and the three leg portions 46 are connected to bolts 43 ..., nuts 45 ... (... indicate a plurality. ) Or the like, and attached to the approximate center of the cushion frame 27.
[0020]
By providing a dome-shaped frame 48 as a cover member above the control unit 42, the control unit 42 is covered with the dome-shaped frame 48. As a result, the control unit 42 is protected by the dome-shaped frame 48.
The dome-shaped frame 48 is fastened together with bolts 43... And nuts 45.
As an example, the controller 42 has an outer frame formed in a rectangular box and is built in the central portion 41 of the seat cushion 21 as shown in FIG.
[0021]
In addition, although the example which attached the control part 42 with volt | bolt 43 ..., nut 45 ... was demonstrated in embodiment, it is also possible to attach the control part 42 with another means.
In the embodiment, the outer frame of the control unit 42 is described as a rectangular box. However, the shape of the control unit 42 is not limited to this, and other shapes may be employed.
[0022]
Since the control part 42 is built in the central part 41 (see FIG. 2) from which the seating parts 38 and 39 of the seat cushion 21 are removed, the occupant can take a part of the seat cushion 21 away from the control part 42 (that is, seating). Can sit in the region 38,39).
Therefore, when the occupant sits on the second rear seat 15, the control unit 42 does not impair the occupant's sitting comfort.
[0023]
Further, the electric storage structure 20 for the vehicle seat swings the left back frame 51 of the left seat back 22 (see FIG. 2) in the longitudinal direction of the vehicle body via the left reclining adjuster 50 on the left side of the rear end of the cushion frame 27. The right back frame 54 of the right seat back 23 (see FIG. 2) is attached to the right side of the rear end portion of the cushion frame 27 via the right reclining adjuster 53 so as to be swingable in the longitudinal direction of the vehicle body. .
[0024]
In addition, the electric storage structure 20 for a vehicle seat is provided with a left lock release mechanism 57 for releasing the left lock mechanism (lock mechanism) 56 of the left reclining adjuster 50 on the left back frame 51 via a mounting bracket 58, and the right reclining. A right lock release mechanism 62 for releasing the right lock mechanism (lock mechanism) 61 of the adjuster 53 is provided on the right back frame 54 via a mounting bracket 63, and the seat operation button 26 is provided behind the left seat back 22 (see FIG. 2). This is provided in the interior decoration garnish 18 (see FIGS. 7 and 8).
[0025]
The swing drive mechanism 35 transmits the rotation of the cushion drive motor (actuator) 65 to the left support shaft 31 via the reduction gear group 66 (see FIG. 6), for example, by reversing the cushion drive motor 65. The left support shaft 31 is rotated forward and the cushion drive motor 65 is rotated forward so that the left support shaft 31 is reversed.
The cushion drive motor 65 and the reduction gear group 66 are attached to the floor 12 via the bracket 123. The cushion drive motor 65 is connected to the control unit 42 via the first harness 68.
[0026]
The left cushion lock mechanism 36 includes a cushion lock actuator 70, a lock / release detection switch 71, and a latch switch 72 shown in FIG.
The cushion lock actuator 70, the lock / release detection switch 71 and the latch switch 72 are connected to the control unit 42 via the second harness 73.
Since the right cushion lock mechanism 37 has the same configuration as the left cushion lock mechanism 36, the same reference numerals as those of the left cushion lock mechanism 36 are assigned to the components of the right cushion lock mechanism 37, and description thereof is omitted.
[0027]
The left lock mechanism 56 of the left reclining adjuster 50 includes a lock-on detection switch 75, a forward tilt detection switch 76, and a lock-off detection switch 77 shown in FIG.
The lock-on detection switch 75, the forward tilt detection switch 76, and the lock-off detection switch 77 are connected to the control unit 42 via the third harness 78.
Since the right lock mechanism 61 has the same configuration as the left lock mechanism 56, the same reference numerals as those of the left lock mechanism 56 are assigned to the components of the right lock mechanism 61, and description thereof is omitted.
[0028]
As shown in FIG. 13, the left lock release mechanism 57 includes a drive motor (actuator) 80 and upper and lower Hall sensors 81 and 82.
Since the right lock release mechanism 62 has the same configuration as the left lock release mechanism 57, the same reference numerals as those of the left lock release mechanism 57 are assigned to the components of the right lock release mechanism 62, and description thereof is omitted.
The drive motor 80 and the upper and lower hall sensors 81 and 82 are connected to the control unit 42 via the fourth harness 83.
[0029]
The storage switch 28 and the return switch 29 operated by the sheet operation button 26 are connected to the control unit 42 via the fifth harness 85. The fifth harness 85 extends from the middle to the control unit 42 integrally with the first harness 68.
The sheet operation button 26 includes a storage operation unit 26a and a return operation unit 26b. The storage switch 28 can be turned on by pressing the storage operation portion 26a, and the return switch 29 can be turned on by pressing the return operation portion 26b.
[0030]
FIG. 4 is a perspective view showing a state in which the vehicle seat of the electric storage structure for the vehicle seat according to the present invention is disassembled from the vehicle body.
Left and right rear members (rear members) 91 and 92 are arranged at a predetermined interval in the vehicle width direction, a floor 12 is provided between the rear members 91 and 92, and the floor 12 is located above the left rear member 91. The swing drive mechanism 35 is attached to the part 93, the left support shaft 31 is extended from the swing drive mechanism 35 toward the center of the vehicle body, and the attachment member 33 is attached to the upper part 94 of the right rear member 92 in the floor 12. The right support shaft 32 extends from the mounting member 33 toward the center of the vehicle body, and the left and right support shafts 31 and 32 are arranged coaxially.
[0031]
The left and right mounting plates 96, 97 are respectively attached to the ends of the left and right support shafts 31, 32, and the left and right plates 96, 97 are respectively attached to the left and right bottom portions (bottom portions) 98, 99 of the seat cushion 21. • Attach as shown by the arrow.
As a result, the seat cushion 21 can be swung back and forth about the left and right support shafts 31 and 32.
[0032]
Since the seat cushion 21 swings in the front-rear direction about the left and right support shafts 31 and 32, a relatively large force is applied to the left and right support shafts 31 and 32. For this reason, it is preferable to attach the left and right support shafts 31, 32, that is, the swing drive mechanism 35 and the attachment member 33 to a portion having high rigidity.
[0033]
Therefore, a left reinforcing plate 104 is provided in a portion of the left rear wheel house (wheel house) 102 in the vicinity of the swing drive mechanism 35, and a portion of the right rear wheel house (wheel house) 103 in the vicinity of the mounting member 33. By providing the right reinforcing plate 105, the rigidity of the portion of the rear wheel house 102, 103 near the left and right support shafts 31, 32 is increased.
In addition, the left and right rear members 91 and 92 are members having high rigidity.
[0034]
In this way, the rigidity of the rear wheel houses 102 and 103 in the vicinity of the swing drive mechanism 35 and the mounting member 33 is increased, and the left and right rear members 91 and 92 having high rigidity are connected to the swing drive mechanism 35 and By attaching the attachment member 33, the attachment accuracy of the left and right support shafts 31, 32 can be suitably maintained.
Thereby, the seat cushion 21 can be smoothly swung between the seating position P1 (position shown in FIG. 2) and the storage position P2 (see FIG. 33).
[0035]
By the way, when the seat cushion 21 is returned to the seating position P1, in order to lock the seat cushion 21 to the seating position P1, latches 167 and 167 (see FIG. 12 for the front side and the back side for illustration) are not shown. ) And left and right strikers 107 and 107 (see FIGS. 10 and 12 for the left striker 107) on the floor 12, and when the seat cushion 21 is returned to the seating position P1, the latches 167 and 167 are The strikers 107 and 107 need to be locked.
[0036]
However, when the seat cushion 21 is electrically returned to the seating position P1, the latches 167 and 167 abut against the left and right strikers 107 and 107 with a relatively strong force as compared with the case where the seat cushion 21 is manually returned. It is possible.
Therefore, the right striker 107 is attached to the upper portion 112 of the right rear member 92 in the floor 12 and in front of the mounting member 33, and the upper portion 111 of the left rear member 91 in the floor 12 (FIG. 10, FIG. 10). 12), and the left striker 107 (see FIGS. 10 and 12) is attached in front of the swing drive mechanism 35.
[0037]
Further, class members 115 are provided in the vicinity of the left and right strikers 107 and 107. The cross member 115 is disposed on the floor 12 and is provided with left and right end portions (ends) on left and right gussets (gussets) 116 and 116 (see FIG. 18 for the left gusset 116) that also serve as reinforcement for the left and right rear wheel houses 102 and 103. Part) 115a, 115a (left end part 115a refer to FIG. 18) is connected.
[0038]
By forming the left and right gussets 116 and 116 relatively large, the force applied to the left and right gussets 116 and 116 is preferably dispersed. Furthermore, the left and right rear wheel houses 102 and 103 can be reinforced by attaching relatively large left and right gussets 116 and 116 to the left and right rear wheel houses 102 and 103. Therefore, the rigidity of the left and right rear wheel houses 102 and 103 can be increased.
[0039]
The left and right rear members 91 and 92 are highly rigid members, and the cross member 115 is provided as a reinforcing member in the vicinity of the left and right strikers 107 and 107, so that the rigidity around the left and right strikers 107 and 107 can be increased. it can.
Further, by connecting the left and right ends 115a and 115a of the cross member 115 to the left and right gussets 116 and 116, which also serve as reinforcements for the left and right rear wheel houses 102 and 103, respectively, The rigidity of the left and right strikers 107 and 107 in the wheel houses 102 and 103 can be increased.
Therefore, even when the latches 167 and 167 (see FIG. 12) abut against the left and right strikers 107 and 107 with a relatively strong force, the left and right strikers 107 and 107 can be suitably held at predetermined positions.
[0040]
An opening 115b is formed in the center of the cross member 115, and an air duct 117 (shown by an imaginary line) of a rear seat air conditioner (not shown) is attached to the opening 115b.
The air duct 117 will be described later.
[0041]
FIG. 5 is a perspective view showing a state in which a spring is attached to the right support shaft of the electric storage structure for a vehicle seat according to the present invention.
In the floor 12 shown in FIG. 4, an attachment member 33 is attached to an upper portion 94 of the right rear member 92 with attachment bolts 118, 118, and the right support shaft 32 is rotatably attached to the attachment member 33. A right mounting plate 97 is fixed to the tip, a coiled spring 121 is mounted on the right support shaft 32 protruding from the mounting member 33, and one end 121a of the spring 121 is inserted into the insertion holes 33a and 33a of the mounting member 33, The other end 121 b of the spring 121 is inserted into the insertion hole 97 a of the right mounting plate 97.
The left mounting plate 97 is mounted on the right bottom 99 (see also FIG. 4) of the seat cushion 21 with mounting bolts 101, so that the seat cushion 21 can be seated with the right support shaft 32 as an axis. It can swing between the storage position P2 (see FIG. 33) and the storage position P2 (see FIG. 24A).
[0042]
As described above, by attaching the spring 121 to the right support shaft 32, the repulsive force of the spring 121 gradually increases as the seat cushion 21 moves from the seating position P1 toward the storage position P2, as indicated by the arrow Fo1.
That is, in a state where the seat cushion 21 is disposed at the seating position P1 (the position shown in the figure), the repulsive force of the spring 121 is minimized as indicated by the arrow Fo1.
On the other hand, when the seat cushion 21 is swung to the rear storage position P2, the repulsive force of the spring 121 becomes maximum as shown by the arrow Fo1.
The reason why the spring 121 is attached to the right support shaft 32 will be described in detail with reference to FIGS.
[0043]
The adjustment of the repulsive force of the spring 121 is not limited to the above-described example. For example, in addition to the spring 121, by providing a spring having a repulsive force opposite to the repulsive force of the spring 121, the repulsive force is substantially 0 in a state where the seat cushion 21 is swung backward from the seating position P1 to the intermediate position. Thus, the repulsive force may be adjusted so as to become maximum as shown by the arrow Fo1 when swinging from the intermediate position to the storage position P2.
[0044]
FIG. 6 is a perspective view showing the swing drive mechanism of the electric storage structure for a vehicle seat according to the present invention.
The swing drive mechanism 35 includes a reduction gear group 66 disposed on the bracket 123, and a cushion drive motor 65 that drives the reduction gear group 66 on the outer surface (side surface) of the bracket 123 and above the reduction gear group 66. (Actuator) was placed vertically.
The swing drive mechanism 35 transmits the rotation of the cushion drive motor 65 to the left support shaft 31 via the reduction gear group 66.
[0045]
The reduction gear group 66 has a pinion gear 127 attached to the drive shaft 126 of the cushion drive motor 65, the first intermediate gear 128 meshed with the pinion gear 127, and the second intermediate gear 129 coaxially with the first intermediate gear 128. The third intermediate gear 131 is meshed with the second intermediate gear 129, the fourth intermediate gear 132 is meshed with the third intermediate gear 131, and the fourth intermediate gear 132 is attached to the left support shaft 31.
[0046]
A left attachment plate 96 is attached to the end of the left support shaft 31, and the left attachment plate 96 is attached to the left bottom portion 98 (see FIG. 4) of the seat cushion 21.
As a result, the seat cushion 21 (see FIGS. 2 and 4) swings between the seating position P1 (see FIG. 24A) and the storage position P2 (see FIG. 33) about the left support shaft 31 as an axis. be able to.
[0047]
According to this swing drive mechanism 35, by rotating the cushion drive motor 65 in the reverse direction, the pinion gear 127 rotates as indicated by arrow a, and the rotation of the pinion gear 127 rotates the first intermediate gear 128 as indicated by arrow b.
As the first intermediate gear 128 rotates, the second intermediate gear 129 also rotates as shown by arrow b, and as the second intermediate gear 129 rotates, the third intermediate gear 131 rotates as shown by arrow c. The rotation of the third intermediate gear 131 causes the fourth intermediate gear 132 to rotate as indicated by the arrow d, and the left support shaft 31 rotates as indicated by the arrow d together with the fourth intermediate gear 132.
Accordingly, the seat cushion 21 (see FIGS. 2 and 4) swings backward with the left support shaft 31 as an axis.
[0048]
On the other hand, by rotating the cushion drive motor 65 in the forward direction, the seat cushion 21 (see FIGS. 2 and 4) swings forward with the left support shaft 31 as an axis.
The pinion gear 127, the first intermediate gear 128, the second intermediate gear 129, the third intermediate gear 131, and the fourth intermediate gear 132 are covered with a cover 134 (see FIG. 7).
[0049]
In this embodiment, an example in which the cover 134 is assembled to the bracket 123 and the pinion gear 127, the first intermediate gear 128, the second intermediate gear 129, the third intermediate gear 131, and the fourth intermediate gear 132 are covered with the cover 134 will be described. However, the bracket 123 and the cover 134 can be integrated to form a gear case.
[0050]
FIG. 7 is a perspective view showing a state in which the swing drive mechanism of the electric storage structure for a vehicle seat according to the present invention is attached to the floor.
The swing drive mechanism 35 is attached to the rear portion of the left rear wheel house 102 on the floor 12 and an upper portion 93 of the left rear member 91 (see FIG. 4). Extending toward the center of the vehicle body, the left mounting plate 96 is attached to the tip of the left support shaft 31, and the left mounting plate 96 is attached to the left bottom 98 of the seat cushion 21 with mounting bolts 101.
[0051]
Here, since the width W1 of the left rear wheel house 102 is relatively large, a relatively large space 135 can be secured behind the left rear wheel house 102.
Therefore, as shown in FIG. 6, the cushion drive motor 65 of the swing drive mechanism 35 is disposed on the outer surface (side surface) 123 a (see FIG. 4) facing the outer side of the vehicle body of the bracket 123 and above the reduction gear group 66. The cushion drive motor 65 is arranged in a vertically oriented state and is accommodated in this relatively large space 135.
Thus, by disposing the cushion drive motor 65 outside the reduction gear group 66, the cushion drive motor 65 can be disposed by effectively using the relatively large space 135.
[0052]
Further, by attaching the cushion drive motor 65 of the swing drive mechanism 35 on the outer surface 123a of the bracket 123 and above the reduction gear group 66, the width W2 in the front-rear direction of the swing drive mechanism 35 can be kept small. it can.
In addition, by disposing the cushion drive motor 65 vertically, the drive motor 35 can be attached so as not to protrude rearward.
[0053]
Therefore, when the left rear wheel house 102, the swing drive mechanism 35, etc. are covered with the cover portion 18a of the garnish 18, the rear wall surface 18b of the cover portion 18a can be disposed close to the left rear wheel house 102 side.
Therefore, a large width W3 of the storage space 138 provided behind the swing drive mechanism 35 can be ensured.
The storage space 138 is a space that forms the left side portion of the luggage storage space 140 provided behind the second rear seat 15. Therefore, by increasing the width W3 of the storage space 138, it is possible to secure a large luggage storage space 140.
[0054]
FIG. 8 is a perspective view showing a state in which the swing drive mechanism of the electric storage structure for a vehicle seat according to the present invention is attached to the floor.
By ensuring a large width W3 in the front-rear direction of the storage space 135 provided behind the swing drive mechanism 35 (see FIG. 7), a long object such as a golf bag 141. be able to.
[0055]
By allowing a long object such as a golf bag 141... To be placed horizontally in the luggage storage space 140, it is possible to easily take in and out the luggage and improve usability.
In addition, by securing a large luggage storage space 140, the luggage storage space 140 can be used effectively in accordance with various applications, and usability can be further enhanced.
[0056]
FIGS. 9A and 9B are explanatory views of the swing drive mechanism of the electric storage structure for a vehicle seat according to the present invention, wherein FIG. 9A shows a comparative example and FIG.
In (a), in order to widen the interior space of the automobile, for example, the space in the vehicle width direction of the space 351 between the interior decoration garnish cover 350 and the rear side panel (not shown) is narrowed. It is possible to do.
In order to attach the swing drive mechanism 352 to this narrow space, the swing drive mechanism 352 normally has a drive motor 353 disposed behind the reduction gear group 352.
[0057]
When the drive motor 353 is disposed behind the reduction gear group 352, the rear wall surface 350a of the cover portion 350 needs to be largely separated from the left rear wheel 353.
Therefore, the width W4 in the front-rear direction of the luggage storage space 355 behind the rear wall surface 350a of the cover portion 350 is reduced.
For this reason, it is difficult to load a long object such as a golf bag in the luggage storage space 355 sideways, leaving room for improvement from the viewpoint of usability.
[0058]
In (b), it is noted that a relatively large space 135 can be secured behind the left rear wheel house 102, and the cushion drive motor 65 of the swing drive mechanism 35 is disposed on the outer surface 123a of the bracket 123 and the reduction gear group. A cushion drive motor 65 is placed vertically above 66 (see FIGS. 6 and 7).
Thus, the cushion drive motor 65 can be attached so as not to protrude rearward, and the rear wall surface 18b of the cover portion 18a can be brought closer to the left rear wheel house 102 side.
[0059]
Therefore, it is possible to ensure a large width W3 in the front-rear direction of the luggage storage space 140 behind the rear wall surface 18b of the cover portion 18a.
For this reason, since long objects, such as the golf bag 141 ..., can be piled sideways in the luggage storage space 140, taking in / out of luggage becomes easy, and the usability can be improved.
[0060]
FIG. 10 is a cross-sectional view of a vehicle provided with an electric storage structure for a vehicle seat according to the present invention.
A swing drive mechanism 35 (see FIG. 4) and a mounting member 33 are attached to upper portions 93 and 94 of the left and right rear members 91 and 92 (see FIG. 4 for the left rear member 92) of the floor 12, respectively. The mounting plates 96, 97 (see FIG. 4 for the right mounting plate 97) are attached to the left and right bottom portions 98, 99 (see FIG. 4 for the right bottom portion 99) of the seat cushion 21 with mounting bolts 101.
As a result, the rear portion of the seat cushion 21 is swingably attached to the left and right support shafts 31 and 32 (see FIG. 4 for the right support shaft 32).
[0061]
Also, left and right strikers 107 and 107 (right) are placed in front of the swing drive mechanism 35 (see FIG. 4) and the mounting member 33 on the floor 12 and on the upper portions 111 and 112 of the left and right rear members 91 and 92, respectively. The striker 107 is attached to each of them (see FIG. 4).
The right and left cushion lock mechanisms 36 and 37 (see FIG. 3 for the right cushion lock mechanism 37) are respectively engaged with the left and right strikers 107 and 107, whereby the seat cushion 21 is locked at the seating position P1.
[0062]
In the vicinity of the left and right strikers 107, 107, specifically, in the upper portions 111 and 112 of the left and right rear members 91 and 92 in the floor 12, the left and right seat cushion lifting mechanisms 145 as the seat cushion lifting mechanism 145 145 (the right seat cushion push-up mechanism 145 is not shown) is provided.
[0063]
The left and right seat cushion push-up mechanisms 145 and 145 are members that push the seat cushion away from the floor by the spring force of a metal spring as the lift spring 146 when the seat cushion 21 is disposed at the seating position P1. is there.
Since the left and right seat cushion lifting mechanisms 145 and 145 are the same member, the left seat cushion lifting mechanism 145 will be described below, and the description of the right seat cushion lifting mechanism 145 will be omitted.
[0064]
In order to arrange the left seat cushion push-up mechanism 145 in the under-seat space 151 between the seat cushion 21 and the floor 12, the under-seat space 151 is set to be relatively large.
For this reason, it is possible to ensure a relatively large space 152 between the front end portion 21a of the seat cushion 21 and the floor 12. Therefore, the cross member 115 is attached using the relatively large space 152.
The cross member 115 is a reinforcing member disposed on the floor 12.
[0065]
Furthermore, the under-seat space 151 is made relatively large so that the air duct 153 of the rear seat air conditioner (not shown) is attached using the relatively large space 151.
The air outlet 154 of the air duct 153 extends toward the front of the vehicle body through the opening 115b (see FIG. 4) of the cross member 115.
[0066]
In this way, by using a metal spring as the lift spring 146 of the left seat cushion push-up mechanism 145, even if the under-seat space 151 becomes relatively large, the cross member 115 can be attached to the space 152, By attaching the air duct 153 to the space 151, the space 152 and the under-seat space 151 can be used effectively.
In the figure, reference numeral 155 denotes a floor sheet constituting the floor of the passenger compartment.
[0067]
FIG. 11 is a perspective view showing a right seat cushion push-up mechanism of the electric vehicle seat stowing structure according to the present invention.
The left striker 107 is formed in a substantially U shape, and a pair of lower end portions 107a and 107a of the left striker 107 are attached to a base 157, and a left seat cushion push-up mechanism 145 is attached to the base 157 with a mounting bolt 158 as an example.
The base 157 is attached to the upper portion 111 of the left rear member 91 (see FIG. 4) on the floor 12 by a pair of bolts as an example.
[0068]
The left seat cushion push-up mechanism 145 has a push-up member 162 attached to a support member 159 via a support pin 161 so as to be swingable (swingable), and a coil-like lift spring (metal spring) 146 attached to the support pin 161. , One end 146 a of the lift spring 146 is locked to the support member 159, and the other end 146 b of the lift spring 146 is attached to the push-up member 162.
[0069]
With the spring force of the lift spring 146, the push-up member 162 is swung in the direction of the arrow about the support pin 161, and the tip end portion 163 of the push-up member 162 is lifted upward.
Here, when the push-up member 162 is swung by a predetermined angle in the arrow direction, the base end portion 164 of the push-up member 162 is brought into contact with the contact portion 159a of the support member 159. Thereby, the rising amount of the front end portion 163 of the push-up member 162 is restricted to a predetermined position.
[0070]
As an example, the spring material of the lift spring 146 is made of spring steel, piano wire, or stainless steel.
Although an example in which a coiled spring is used as the lift spring 146 has been described, the type of spring is not limited to this, and other springs such as a leaf spring and a spiral spring can also be used.
[0071]
As described above, the left seat cushion push-up mechanism 145 is made of a compact member such as the support member 159, the support pin 161, the push-up member 162, and the lift spring 146, so that it can be made simple and compact. .
Therefore, the left seat cushion push-up mechanism 145 can be disposed in a relatively small space.
[0072]
FIG. 12 is an explanatory view showing a cushion lock mechanism and a seat cushion push-up mechanism of the electric vehicle seat stowing structure according to the present invention.
The left cushion lock mechanism 36 has a bracket 166 attached to the cushion frame 27 constituting the seat cushion 21, a latch 167 is rotatably attached to the bracket 166 via a latch pin 168, and a ratchet 169 is attached to a portion facing the latch 167. It is attached rotatably via 171.
[0073]
In addition, the left cushion lock mechanism 36 connects the front end portion of the operation rod 172 to the ratchet 169 via the connection pin 165, and connects the rear end portion of the operation rod 172 to the long hole 173a of the drive rod 173 via the slide pin 172a. The ratchet 169 is connected to the cushion lock actuator 70 via the operation rod 172.
The reason why the rear end portion of the operation rod 172 is slidably connected to the long hole 173a of the drive rod 173 via the slide pin 172a will be described later.
[0074]
Further, the left cushion lock mechanism 36 includes a lock / release detection switch 71 that detects the operation of the ratchet 169 and a latch switch 72 that detects the operation of the latch 167.
[0075]
According to the left cushion lock mechanism 36, by pulling the operation rod 172 with the cushion lock actuator 70, the ratchet 169 is swung around the ratchet pin 171 as shown by the arrow e to unlock the latch 167 (in an unlocked state). And the seat cushion 21 is separated from the floor 12.
By lifting the bracket 166 upward together with the cushion seat 21, the latch 167 rotates in the direction of arrow f about the latch pin 168 as an axis, and the left striker 107 is removed from the engagement groove 167 a of the latch 167.
[0076]
On the other hand, when the seat cushion 21 is returned to the seating position P1 (see FIG. 10), the latch 167 is engaged with the left striker 107 to be locked. Thereby, the floor 12 and the seat cushion 21 are connected, and the seat cushion 21 is held at the seating position P1.
In this state, the front end portion 163 of the push-up member 162 constituting the left seat cushion push-up mechanism 145 contacts the lower portion 166a of the bracket 166 of the left cushion lock mechanism 36.
A spring force Fo2 of the lift spring 146 acts on the push-up member 162 in the direction of the arrow, and the seat cushion 21 is pushed up so as to be separated from the floor 12 by this spring force Fo2.
[0077]
Here, a metal spring is employed as the lift spring 146 for the left seat cushion push-up mechanism 145, and the lift cushion 146 pushes the seat cushion 21 away from the floor.
By using a metal spring as the lift spring 146, the elastic force of the lift spring 146 is not impaired like an elastic rubber even in a low temperature region.
[0078]
Therefore, even when the occupant is not seated on the seat cushion 21, the latch 167 and the left striker 107 can be securely locked, and as an example, the play between the latch 167 and the left striker 107 can be eliminated.
As a result, the state in which the seat cushion 21 is held at the seating position P1 (see FIG. 10) can be maintained, so that the latch 167 and the left striker 107 interfere with each other when the vehicle travels, and vibration noise is generated. Can be prevented.
[0079]
Here, when the seat cushion 21 is returned to the seating position P1, the seat cushion 21 comes into contact with the left seat cushion push-up mechanism 145, and a contact force is generated in the left seat cushion push-up mechanism 145.
By providing the left seat cushion push-up mechanism 145 with the lift spring 146, the contact force applied to the left seat cushion push-up mechanism 145 can be absorbed by the lift spring 146.
This can prevent a relatively large force from being applied to the floor.
[0080]
By the way, the rear end portion of the operation rod 172 of the left cushion lock mechanism 36 is slidably connected to the elongated hole 173a of the drive rod 173 via the slide pin 172a, so that the operation can be performed without driving the cushion lock actuator 70. The rod 172 can be pulled back manually.
By manually pulling the operating rod 172 rearward, the latch 167 can be unlocked by swinging the ratchet 169 about the ratchet pin 171 as shown by the arrow e in the same manner as when the cushion lock actuator 70 is driven. it can.
[0081]
In this embodiment, the example in which the left and right seat cushion push-up mechanisms 145 are attached to the floor 12 side has been described. However, the left and right seat cushion push-up mechanisms 145 can be provided on the seat cushion 21 side.
Also in this case, the same effect as this embodiment can be obtained.
[0082]
Here, the cross member 115 is removed from the lower surface of the floor 12 by attaching the cross member 115 on the floor 12 in front of the left seat cushion push-up mechanism 145. Therefore, a large mounting space can be secured for arranging a fuel tank (not shown) or the like on the lower surface of the floor 12.
Thereby, the freedom degree of the layout at the time of attaching a fuel tank etc. to the lower surface of the floor 12 can be raised.
An air duct 153 of a rear seat air conditioner (not shown) is attached behind the cross member 115.
[0083]
FIG. 13 is a view for explaining a lock mechanism and a lock release mechanism of the reclining adjuster of the electric vehicle seat stowing structure according to the present invention.
The left lock mechanism 56 of the left reclining adjuster 50 has a base 174 attached to the cushion frame 27 with mounting bolts 175... And a plate 177 attached to the base 174 via a rotating shaft 176 so as to be swingable in the longitudinal direction of the vehicle body. The first and second gears 178 and 179 for locking are provided at the upper end of the base 174, and the lock gear 181 that can mesh with the first and second gears 178 and 179 is formed on the lower swing lever 182 to swing downward. The lever 182 is swingably attached to the plate 177 via the lower pin 183, and the intermediate swing lever 184 that presses the tip of the lower swing lever 182 is swingably attached to the plate 177 via the intermediate pin 185. The upper swing lever 188 in which the operation pin 186 of the swing lever 184 is fitted into the fitting hole 187 is inserted through the upper pin 189. Swingably to the plate 177 Te, in which looped over the spring 191 pulling on the lower swing lever 182 and the upper swing lever 188.
[0084]
By urging the upper swing lever 188 with the upper pin 189 as an axis by the spring force of the tension spring 191 as shown by the arrow h, the operation pin 186 in the fitting hole 187 is moved by the upper swing lever 188 as shown by the arrow i. Press.
Accordingly, the lock gear 181 of the lower swing lever 182 is engaged with the first gear 178 by pushing the tip of the lower swing lever 182 downward with the tip of the intermediate swing lever 184. Therefore, the plate 177 can be held at a predetermined position.
[0085]
The left lock mechanism 56 of the left reclining adjuster 50 includes a lock-off detection switch 77 that detects the operation of the upper swing lever 188, and includes a forward tilt detection switch 76 that is operated by a cam 192 provided on the plate 177 side. A lock-on detection switch 75 that detects the operation of the intermediate swing lever 184 is provided.
The left lock release mechanism 57 is connected to the upper swing lever 188 of the left lock mechanism 56 via the operation cable 195.
[0086]
The left lock release mechanism 57 includes an operation cable 195 that operates the upper swing lever 188 of the left lock mechanism 56 to release the lock, and the operation cable 195 is bifurcated at the connecting portion 200, and one of the two cables. (Second cable) 201 is connected to the left automatic unlocking portion 196, and the other cable (third cable) 202 of the two branches is connected to the left manual unlocking portion 197, thereby unlocking the left lock mechanism 56. Can be carried out either automatically or manually.
[0087]
The operation cable 195 connects the tip end portion 194a of the first inner cable 194 constituting the first cable 198 to the upper swing lever 188 via the connecting pin 199, and connects the first inner cable 194 via the connecting portion 200 to the first inner cable 194. The second inner cable 208 of the two cables 201 and the third inner cable 209 of the third cable 202 are connected in a bifurcated manner.
In addition, the operation cable 195 connects the second inner cable 208 of the second cable 201 to the left automatic unlocking portion 196 and connects the third inner cable 209 of the third cable 202 to the left manual unlocking portion 197. Is.
[0088]
The left automatic unlocking unit 196 has a mounting bracket 58 attached to the left back frame 51 (see FIG. 3), a drive motor 80 is provided on the mounting bracket 58, and the lifting shaft 203 protrudes from the driving motor 80. 204, the extended portion 205 of the magnet 204 is inserted into the guide 206, and the upper and lower Hall sensors 81 and 82 are attached to the portions of the mounting bracket 58 corresponding to the upper and lower ends of the lifting shaft 203, respectively. It is a thing.
[0089]
Further, the left automatic unlocking portion 196 is obtained by attaching a connecting piece 207 to the tip of the elevating shaft 203 and connecting the base end portion 208b of the second inner cable 208 to the connecting piece 207.
[0090]
The left manual unlocking portion 197 is formed with a concave portion 22b (see also FIG. 4) on the back surface 22a of the left seat back 22, and a manual lever (manual operation portion) 211 is disposed in the concave portion 22b. The arm 213 is attached to the lower end portion of the manual lever 211, the base end portion 209 b of the third inner cable 209 is connected to the distal end portion of the arm 213, and the pin 202 is connected. A coil spring 215 is attached, and the manual lever 211 is urged in the direction of arrow j by the spring force of the coil spring 215.
[0091]
Here, in this embodiment, the example in which the manual lever 211 of the left manual unlocking portion 197 is provided on the back surface 22a of the left seat back 22 has been described, but the manual lever 211 is not limited to the back surface 22a of the left seat back 22. It can be provided as appropriate in other parts.
[0092]
FIG. 14 is a cross-sectional view showing a connecting portion of the electric storage structure for a vehicle seat according to the present invention.
The connecting portion 200 has a slider 218 slidably disposed in the direction of the arrow in a cylindrical casing 217, and a base end portion 194 b of the first inner cable 194 is connected to the center of the slider 218 by a first stopper 225. By connecting the tip end portion 208a of the second inner cable 208 to the right end portion of 218 with the second stopper 226 and connecting the tip end portion 209a of the third inner cable 209 to the left end portion of the slider 218 with the third stopper 227, The second and third inner cables 208 and 209 are connected to the one inner cable 194 in a bifurcated manner.
The second and third stoppers 226 and 227 are removably attached to the attachment holes of the slider 218.
[0093]
The connecting portion 200 includes a base end portion 219a of the first outer cable 219 attached to one end portion (lower end portion) 217a of the casing 217, and a cap 221 that covers the other end portion (upper end portion) 217b of the casing 217. The distal end portion 222 a of the cable 222 is attached to the cap 221, and the distal end portion 223 a of the third outer cable 223 is attached to the cap 221.
[0094]
Here, the first outer cable 219 and the first inner cable 194 constitute a first cable 198, and the second outer cable 222 and the second inner cable 208 constitute a second cable 201. Further, the third outer cable 223 and the third inner cable 209 constitute the third cable 202.
[0095]
Returning to FIG. 13, according to the left lock release mechanism 57, the second and third cables 201 and 202 are connected to the first cable 198 via the connecting portion 200, and the left cable is automatically locked to the second cable 201. The release portion 196 can be connected, and the left manual lock release portion 197 can be connected to the third cable 202.
[0096]
In FIG. 13, the example in which the left automatic unlocking unit 196 and the left manual unlocking unit 197 of the left unlocking mechanism 57 are connected to the left locking mechanism 56 via the operation cable 195 has been described. Similarly to the left lock release mechanism 57, the right lock release mechanism 62 shown in FIG. 4 also connects the right automatic lock release unit 196 and the right manual lock release unit 197 (see FIG. 4) to the left lock mechanism 62 via the operation cable 195. Has been.
Since the right lock release mechanism 62 is the same component as the left lock release mechanism 57, the same reference numerals as those of the left lock release mechanism 57 are used and description thereof is omitted.
[0097]
In FIG. 3, only the left and right automatic unlocking portions 196 and 196 are illustrated as the left and right unlocking mechanisms 57 and 62, and the left and right manual unlocking portions 197 and 197 are omitted for easy understanding. .
[0098]
FIG. 15 is a view for explaining an example in which the locking mechanism of the reclining adjuster of the electric storage structure for a vehicle seat according to the present invention is released by the left automatic unlocking portion.
According to the left automatic unlocking unit 196, by driving the drive motor 80, the elevating shaft 203 is lowered, and the slider 218 of the coupling unit 200 is pulled upward by the second inner cable 208.
At this time, the third stopper 227 comes out of the mounting hole of the slider 218, and the third inner cable 209 is kept stationary.
[0099]
By pulling up the slider 218 upward, the first cable 194 is pulled up, and the upper swing lever 188 is rotated clockwise (in the direction of the arrow) against the spring force of the tension spring 191 by the first cable 194.
As a result, the lock gear 181 of the lower swing lever 182 can be separated from the first gear 178, and the plate 177 can be tilted in the longitudinal direction of the vehicle body with the rotary shaft portion 176 as an axis.
[0100]
FIG. 16 is a view for explaining an example in which the lock mechanism of the reclining adjuster of the electric storage structure for a vehicle seat according to the present invention is released by the left manual lock release portion.
According to the left automatic unlocking portion 196, the arm 213 is raised in the direction of the arrow by swinging the manual lever 211 in the direction of the arrow against the spring force of the coil spring 215. By raising the arm 213 in the direction of the arrow, the slider 218 of the connecting portion 200 is pulled upward by the third inner cable 209.
At this time, the second stopper 226 comes out of the mounting hole of the slider 218, and the second inner cable 208 is kept stationary.
[0101]
By pulling up the slider 218 upward, the first cable 194 is pulled up, and the upper swing lever 188 is rotated clockwise (in the direction of the arrow) against the spring force of the tension spring 191 by the first cable 194.
As a result, the lock gear 181 of the lower swing lever 182 can be separated from the first gear 178, and the plate 177 can be tilted in the longitudinal direction of the vehicle body with the rotary shaft portion 176 as an axis.
[0102]
Returning to FIG. 13, according to the left lock release mechanism 57, the second and third cables 201 and 202 are connected to the first cable 198 via the connecting portion 200, and the left cable is automatically locked to the second cable 201. By connecting the release portion 196 and connecting the left manual lock release portion 197 to the third cable 202, the unlocking of the left lock mechanism 56 of the left reclining adjuster 50 can be performed either automatically or manually.
[0103]
As a result, normally, the left seat back 22 can be tilted by releasing the lock of the left lock mechanism 56 using the left automatic lock release unit 196.
On the other hand, for example, there may be a case where the left seat back 22 is desired to be tilted when the main switch of the automobile is off, that is, when the drive motor 80 of the left automatic unlocking unit 196 is not driven.
In this case, by using the left manual unlocking portion 197, the left lock mechanism 56 can be unlocked and the left seat back 22 can be manually tilted back and forth.
[0104]
Returning to FIG. 3, the operation cable 195 of the left lock release mechanism 57 is incorporated in the left seat back 22 (see FIG. 2) and is loosened in a substantially S shape.
By incorporating the operation cable 195 into the left seat back 22 in a state of being loosened in a substantially S shape, when the occupant leans against the left seat back 22 and the left seat back 22 is deformed, the left seat back 22 is deformed. It can be absorbed by the looseness of the operation cable 195, and the operation cable 195 can be prevented from being pulled by an external force.
[0105]
In FIG. 3, an example in which the operation cable 195 is loosened in an approximately S shape and prevented from being pulled by an external force has been described. However, the operation cable 195 is not limited to an approximately S shape, for example, an approximately U shape. The same effect can be obtained by slacking to other shapes.
[0106]
In FIG. 3, the operation cable 195 of the left lock release mechanism 57 has been described. However, the operation cable 195 of the right lock release mechanism 62 is also substantially S-shaped or similar to the operation cable 195 of the left lock release mechanism 57. The same effect can be obtained by loosening in a substantially U shape.
[0107]
Next, a procedure for assembling the electric storage structure 20 for a vehicle seat will be described with reference to FIGS.
FIG. 17 is a flowchart showing the assembly procedure of the electric storage structure for a vehicle seat according to the present invention, and STxx in the figure indicates a step number.
ST01: A cross member is attached to the floor, and left and right reinforcing plates are attached to the left and right rear wheel houses.
ST02: The right support shaft is mounted on the floor, the right mounting plate provided on the right support shaft is disposed at a predetermined angle, the left support shaft is mounted on the floor via a swing drive mechanism, and the left support shaft The left mounting plate provided in is arranged in a state inclined at a predetermined angle.
[0108]
ST03: The left and right strikers are respectively attached at positions separated from the left and right support shafts by a predetermined distance.
ST04: The seat cushion is tilted according to the tilt angle of the left and right mounting plates in a state where the seat back is tilted to the seat cushion side. In this state, the seat cushion is moved toward the left and right mounting plates.
[0109]
ST05: The left locking bracket provided on the left bottom of the seat cushion is engaged with the left mounting plate, and the right locking bracket provided on the right bottom is engaged with the right mounting plate.
Thereby, the left and right mounting plates are temporarily fixed to the bottom of the seat cushion.
[0110]
ST06: With the left and right mounting plates temporarily fixed to the bottom of the seat cushion, the seat back and the seat cushion are supported by the left and right support shafts and swing to the floor storage recess.
ST07: Attach left and right mounting plates to the bottom of the left and right sides of the seat cushion with mounting bolts.
Hereinafter, the contents of ST01 to ST07 will be described in detail.
[0111]
18 (a) and 18 (b) are first assembly process diagrams illustrating a procedure for assembling the electric storage structure for a vehicle seat according to the present invention. (A) is an explanation for ST01, and (b) is an explanation for ST02.
In (a), a cross member 115 is arranged on the floor 12 and attached to the left and right rear wheel houses 102 and 103 via the left and right gussets 116 and 116, respectively.
Further, left and right reinforcing plates 104 and 105 are attached to the left and right rear wheel houses 102 and 103, respectively.
[0112]
In (b), the swing drive mechanism 35 is attached to the upper portion 93 of the left rear member 91 in the floor 12, and the left support shaft 31 is provided in the swing drive mechanism 35. A left mounting plate 96 is attached to the end of the left support shaft 31.
Further, the mounting member 33 is attached to the upper portion 94 of the right rear member 92 in the floor 12, and the right support shaft 32 is provided on the mounting member 33. A right mounting plate 97 is attached to the end of the right support shaft 32.
The left and right mounting plates 96 and 97 are kept inclined at a predetermined angle.
[0113]
Here, the state in which the left and right mounting plates 96 and 97 are respectively inclined by a predetermined angle means, for example, that the left and right mounting plates 96 and 97 are stopped at a position where the seat cushion 21 is swung to an intermediate position. It is preferable to be in a state of being inclined by a predetermined angle.
As a method for keeping the left and right mounting plates 96 and 97 inclined at a predetermined angle, for example, a method of adjusting the spring force of the coiled spring 121 can be considered. Specifically, for example, a method of attaching a spring having a spring force opposite to the spring force of the spring 121 can be considered, but adjustment of the spring force is not limited to this.
It is also possible to keep the left and right mounting plates 96 and 97 inclined at a predetermined angle using a jig.
[0114]
19 (a) and 19 (b) are second assembly process diagrams for explaining the procedure for assembling the electric storage structure for a vehicle seat according to the present invention. (A) is an explanation for ST03, and (b) is an explanation for ST04.
In (a), the left and right strikers 107 and 107 are attached using the positioning jig 230. This positioning jig 230 has a rear end recess 231 formed in the rear end 230a, a front end recess 232 formed in the front end 230b, and the interval between the rear end recess 231 and the front end recess 232 is set to a predetermined interval L. It is a thing.
[0115]
Specifically, the left striker 107 is placed on the floor 12 at an upper portion 111 of the left rear member 91 (see FIG. 18B) and in front of the swing drive mechanism 35.
Since the pair of lower end portions 107a and 107a (see FIG. 11) of the striker 107 are attached to the base 157, when the base 157 is placed on the upper part 111, the striker 107 can be arranged in a state of standing on the upper part 111. .
[0116]
Next, the rear end concave portion 231 of the positioning jig 230 is fitted into the left support shaft 31, and the front end concave portion 232 of the positioning jig 230 is fitted into the left striker 107. Accordingly, the left striker 107 can be positioned at a position separated from the left support shaft 31 by a predetermined distance L.
In this state, the left striker 107 is fixed by attaching the base 157 to the upper portion 111 with the attaching bolt 158 (see also FIG. 11).
[0117]
Similar to the left striker 107, the right striker 107 is fixed to the front portion 112 (see FIG. 4) of the right rear member 92 on the floor 12 and in front of the mounting member 33.
[0118]
In (b), with the left and right seat backs 22, 23 (see FIG. 2) tilted toward the seat cushion 21, the seat cushion 21 is tilted according to the tilt angles of the left and right mounting plates 96, 97.
In this state, the seat cushion 21 is moved in the horizontal direction as shown by the arrow k toward the left and right mounting plates 96, 97, and the left and right bottom portions 98, 99 of the seat cushion 21 are moved to the left and right mounting plates 96, 97, respectively. Abut.
In this state, the seat cushion 21 is lowered as indicated by an arrow l.
The seat cushion 21 includes left and right locking brackets 235 and 236 on the left and right bottom portions 98 and 99, respectively.
[0119]
20 (a) and 20 (b) are third assembly process diagrams for explaining the procedure for assembling the electric storage structure for a vehicle seat according to the present invention. (A), (b) is description about the front part of ST05.
In (a), the left locking bracket 235 of the seat cushion 21 is moved toward the engaging portion 96a of the left mounting plate 96 as indicated by an arrow l.
The left locking bracket 235 floats from the left bottom 98 of the seat cushion 21 by a height H. Therefore, the engaging portion 96 a of the left mounting plate 96 can be inserted between the left bottom portion 98 and the left locking bracket 235.
[0120]
In (b), the right locking bracket 236 of the seat cushion 21 is moved toward the engaging portion 97a of the right mounting plate 97 as indicated by an arrow l.
The right locking bracket 236 floats from the right bottom 99 of the seat cushion 21 by a height H. Therefore, the engaging portion 97 a of the right mounting plate 97 can be inserted between the right bottom portion 99 and the right locking bracket 236.
[0121]
FIGS. 21A to 21C are fourth assembly process diagrams for explaining the procedure for assembling the electric storage structure for a vehicle seat according to the present invention. (A)-(c) is description about the rear part of ST05.
In (a), the left locking bracket 235 is engaged with the left mounting plate 96 by inserting the engaging portion 96 a of the left mounting plate 96 between the left bottom 98 of the seat cushion 21 and the left locking bracket 235. Engages with part 96a.
Thereby, the left mounting plate 96 can be temporarily fixed to the left bottom 98 of the seat cushion 21.
At this time, the opening 235 a of the left locking bracket 235 is aligned with one of the mounting holes 96 b... Of the left mounting plate 96.
[0122]
In (b), the engagement portion 97a of the right mounting plate 97 is inserted between the right bottom portion 99 of the seat cushion 21 and the right locking bracket 236, whereby the right locking bracket 236 is engaged with the right mounting plate 97. Engage with the portion 97a.
As a result, the right mounting plate 97 can be temporarily fixed to the right bottom 99 of the seat cushion 21.
At this time, the opening 236 a of the right locking bracket 236 is aligned with one of the mounting holes 97 b of the right mounting plate 97.
[0123]
In (c), the left and right bottom shafts 98 and 99 of the seat cushion 21 are connected to the left and right support shafts 31 and 32 (right support shafts) via the left and right mounting plates 96 and 97 (the right mounting plate 97 is shown in (b)). 32 is supported by (shown in (b)).
[0124]
22 (a) and 22 (b) are fifth assembly process diagrams for explaining a procedure for assembling the electric storage structure for a vehicle seat according to the present invention. (A) is an explanation for ST06, and (b) is an explanation for ST07.
In (a), while supporting the left and right seat backs 22 and 23 and the seat cushion 21 with the left and right support shafts 31 and 32, the seat cushion 21 is swung to the floor storage recess 16 as indicated by an arrow m.
[0125]
Thereby, the left and right seat backs 22 and 23 and the seat cushion 21 can be stored in the floor storage recess 16.
At this time, the engagement portion 96a of the left attachment plate 96 is kept engaged with the left engagement bracket 235, and the engagement portion 97a of the right attachment plate 97 is kept engaged with the right engagement bracket 236.
Therefore, the left and right mounting plates 96 and 97 can be temporarily fixed to the left and right bottom portions 98 and 99 of the seat cushion 21.
[0126]
In (b), the mounting bolts 101 are inserted into the mounting holes 96b of the left mounting plate 96 and screwed into the left bottom portion 98 of the seat cushion 21, so that the mounting bolt 101. A left mounting plate 96 is attached to the left bottom portion 98.
Here, the seat cushion 21 is stored in the floor storage recess 16 (see FIG. 22A) and the left bottom 98 of the seat cushion 21 is directed upward, so that the seat cushion 21 is fixed when the left mounting plate 96 is fixed. Can keep out of the way.
[0127]
In (c), by inserting the mounting bolts 101... Into the mounting holes 97 b... Of the right mounting plate 97 and screwing it into the right bottom 99 of the seat cushion 21, the mounting bolts 101. A right mounting plate 97 is attached to the right bottom 99.
Here, when the seat cushion 21 is stored in the floor storage recess 16 (see FIG. 22A) and the right bottom portion 99 of the seat cushion 21 is directed upward, the seat cushion 21 is fixed when the right mounting plate 97 is fixed. Can keep out of the way.
Thereby, the process of assembling the electric storage structure 20 for the vehicle seat is completed.
[0128]
According to the method for assembling the electric storage structure 20 for a vehicle seat, left and right locking brackets 235 and 236 are provided on the left and right bottom portions 98 and 99 of the seat cushion 21, and the left and right locking brackets 235 and 236 are The mounting plates 96 and 97 can be engaged.
By engaging the right and left locking brackets 235 and 236 with the left and right mounting plates 96 and 97, the left and right mounting plates 96 and 97 can be simply temporarily fixed to the left and right bottom portions 98 and 99 of the seat cushion 21. it can.
[0129]
Further, the seat cushion 21 is swung backward about the left and right support shafts 31 and 32 and stored in the floor storage recess 16. Accordingly, the seat cushion 21 can be easily positioned at the storage position P2 (see FIG. 33) in a state where the left and right attachment plates 96 and 97 are temporarily fixed to the left and right bottom portions 98 and 99 of the seat cushion 21.
[0130]
In addition, when the left and right mounting plates 96 and 97 are fixed by storing the seat cushion 21 in the floor storage recess 16 and the left and right bottom portions 98 and 99 of the seat cushion 21 facing upward, You can avoid getting in the way of work.
Thereby, the assembling work of the seat cushion 21 can be easily performed without taking time.
[0131]
By the way, the electric storage structure 20 for a vehicle seat includes left and right strikers 107 and 107 on the floor 12 in order to lock the seat cushion 21 to the seating position P1 (see FIG. 10). In order to engage the seat cushion 21 with these strikers 107 and 107, the left and right strikers 107 and 107 are separated from the left and right support shafts 31 and 32 by a predetermined distance L (see FIG. 19A). It is necessary to attach to.
[0132]
However, for example, left and right rear wheel houses 102 and 103 are provided in the vicinity of the left and right strikers 107 and 107 and the left and right support shafts 31 and 32, and these members 102 and 103 connect the left and right strikers 107 and 107 to each other. It may be a hindrance during installation.
For this reason, it takes time to attach the left and right strikers 107, 107, and there is a possibility that a heavy burden is placed on the operator.
[0133]
Therefore, by positioning the left and right strikers 107 and 107 using the positioning jig 230, the left and right strikers 107 and 107 can be easily mounted without taking time, and the mounting burden on the operator is further reduced. To be able to.
[0134]
Next, operation | movement of the electric storage structure 20 of a vehicle seat is demonstrated based on FIGS. It should be noted that the left and right seat backs 22 and 23 and the left and right headrests 24 and 25 operate in the same way when the operation of the electric storage structure 20 for a vehicle seat is performed. Only the seat back 22 and the left headrest 24 will be described, and the description of the right seat back 23 and the right headrest 25 will be omitted.
[0135]
First, the storing operation of the vehicle seat 20 will be described with reference to FIGS.
FIG. 23 is a flowchart for explaining the storing operation of the electric storage structure for a vehicle seat according to the present invention.
ST10: The tailgate is opened and the seat operation button is pressed to turn on the storage switch.
ST11: The lock mechanism is unlocked and the seat back is moved forward by spring force.
[0136]
ST12: After locking the seat back to the forward position, the seat cushion is unlocked.
ST13: The seat cushion is swung to the rear of the vehicle body.
ST14: Second rear seat (seat cushion and left seat back)
Store in the floor storage recess.
Hereinafter, the contents of ST10 to ST14 will be described in detail.
[0137]
FIGS. 24A and 24B are first operation explanatory views for explaining the storing operation of the electric storage structure for a vehicle seat according to the present invention. (A) is ST10 and (b) is an explanation of the first half of ST11.
In (a), the user 240 opens the tailgate 241 provided at the rear of the vehicle body 19 upward. When the tailgate 241 is opened, a tailgate opening switch (not shown) is turned on.
Next, the storage switch 28 is turned on by pressing the storage operation part 26 a of the seat operation button 26 provided behind the second rear seat 15 with the finger 242.
[0138]
In (b), after the control unit 42 (see (a)) detects that the tailgate opening switch is on, the drive motor 80 of the left automatic unlocking unit 196 is driven. By driving the drive motor 80, the elevating shaft 203 is moved downward as indicated by an arrow A.
As the elevating shaft 203 moves downward, the second inner cable 208 of the second cable 201 is pulled by the connecting piece 207 as indicated by an arrow B.
[0139]
FIGS. 25 (a) and 25 (b) are second operation explanatory views for explaining the storing operation of the electric storage structure for a vehicle seat according to the present invention, explaining the middle of ST11.
In (a), by pulling the second inner cable 208 (see FIG. 24B) of the second cable 201, the first inner cable 194 is pulled up as shown by the arrow B through the connecting portion 200 shown in FIG.
[0140]
By pulling up the first inner cable 194 as indicated by arrow B, the upper swing lever 188 is rotated as indicated by arrow C about the upper pin 189 as an axis. As a result, the operation pin 186 in the fitting hole 187 is moved by the upper swing lever 188, and the intermediate swing lever 184 is rotated as indicated by the arrow D about the intermediate pin 185 as an axis.
[0141]
In (b), the tip end 184a of the intermediate swing lever 184 is removed from the tip end 182a of the lower swing lever 182 and the protruding piece 182b of the lower swing lever 182 is pressed by the intermediate cam surface 184b of the intermediate swing lever 184.
By pressing the projecting piece 182b of the lower swing lever 182, the lower swing lever 182 is rotated as indicated by an arrow E about the lower pin 183 as an axis, and the lock gear 181 of the lower swing lever 182 is lifted upward.
[0142]
Accordingly, the meshing between the lock gear 181 and the first gear 178 is released, and the lock state of the left lock mechanism 56 is released.
By releasing the lock state of the left lock mechanism 56, the plate 177 is moved forward as indicated by an arrow F with the rotating shaft portion 176 as an axis by the spring force of the spiral spring (spiral spring) 243 provided in the left reclining adjuster 50. Defeat.
At this time, the lock-off detection switch 77 is turned on by the upper swing lever 188. The spiral spring 243 is the same as a spring used for moving a normal seat back forward, and a detailed description thereof will be omitted.
[0143]
FIG. 26 is a third action explanatory view for explaining the storing operation of the electric storage structure for a vehicle seat according to the present invention, which explains the middle of ST11.
When the lock-off detection switch 77 shown in FIG. 25B is turned on, the control unit 42 (see FIG. 3) detects that the lock-off detection switch 77 is turned on, and the drive motor 80 of the left automatic lock release unit 196 is stopped. .
As a result, the second inner cable 208 of the second cable 201 is kept pulled downward.
[0144]
In the unlikely event that a malfunction occurs in the lock-off detection switch 77, when the magnet 204 reaches the lower hall sensor 82, the lower hall sensor 82 detects the magnet 204 and performs control based on the detection signal of the lower hall sensor 82. The drive motor 80 is stopped by the unit 42.
Thereby, it is possible to protect the drive motor 80 by preventing the elevating shaft 203 from being lowered excessively.
[0145]
FIGS. 27 (a) and 27 (b) are fourth action explanatory views for explaining the storing operation of the electric storage structure for a vehicle seat according to the present invention, and explain the middle of ST11.
In (a), when the plate 177 completes the forward tilt, the forward tilt detection switch 76 is pushed by the cam 192 and turned on.
In (b), the control unit 42 (see FIG. 3) detects that the forward tilt detection switch 76 shown in (a) is turned on, and the drive motor 80 of the left automatic unlocking unit 196 is driven to move the lifting shaft 203 to the arrow. Move upwards like G.
[0146]
When the elevating shaft 203 rises to a predetermined position and the magnet 204 reaches the upper hall sensor 81, the upper hall sensor 81 detects the magnet 204. Based on the detection signal of the upper hall sensor 81, the control unit 42 stops the drive motor 80.
Thereby, the downward tensile force of the second inner cable 208 of the second cable 201 is released.
[0147]
28 (a) and 28 (b) are fifth action explanatory views for explaining the storing operation of the electric storage structure for a vehicle seat according to the present invention, and the latter half of ST11 is described.
In (a), by releasing the downward tensile force of the second inner cable 208 of the second cable 201 shown in FIG. 27 (b), the upper swing lever 188 and the upper pin 189 are moved by the spring force of the tension spring 191. The axis rotates as shown by the arrow H.
[0148]
Thereby, the operation pin 186 in the fitting hole 187 is pressed by the upper swing lever 188 as shown by the arrow I. Therefore, the intermediate swing lever 182 is rotated about the intermediate pin 185 as shown by an arrow J, and the tip 182a of the lower swing lever 182 is pushed downward by the tip 182a of the intermediate swing lever 182.
By pressing the tip 182 a of the lower swing lever 182, the lock gear 181 of the lower swing lever 182 is engaged with the second gear 179. Therefore, the left lock mechanism 56 is locked, and the plate 177 is held in the forward tilt position.
[0149]
(B) moves the left seat back 22 together with the plate 177 to the forward tilt position P3, and locks the left lock mechanism 56 (see (a)), thereby moving the left seat back 22 to the forward tilt position P3. Shows the locked state.
[0150]
Returning to (a), by rotating the intermediate swing lever 182 around the intermediate pin 185 as shown by the arrow J, the lock-on detection switch 75 is turned on.
[0151]
FIGS. 29 (a) and 29 (b) are sixth action explanatory views illustrating the storage operation of the electric storage structure for a vehicle seat according to the present invention, and explain the first half of ST12.
In (a), the controller 42 (see FIG. 3) detects that the lock-on detection switch 75 (see FIG. 28 (a)) is turned on, and the cushion lock actuator 70 is actuated to move the operation rod 172 as shown by the arrow. .
As a result, the ratchet 169 swings as indicated by the arrow K about the ratchet pin 171 as an axis.
[0152]
In (b), the lock piece 169a of the ratchet 169 is removed from the lock claw 167b of the latch 167, and the lock of the latch 167 is released. At the same time, the lock / release detection switch 71 is operated with the pin 165 to turn it on.
[0153]
FIGS. 30 (a) and 30 (b) are seventh action explanatory views illustrating the storage operation of the electric storage structure for a vehicle seat according to the present invention, and the latter half of ST12 is described.
In (a), the control unit 42 detects that the lock / release detection switch 61 (see FIG. 29B) is turned on, and the control unit 42 stops the cushion lock actuator 70 (see FIG. 29A). The cushion drive motor 65 of the swing drive mechanism 35 is driven.
The cushion drive motor 65 is driven to rotate the left support shaft portion 32 in the forward direction, and the seat cushion 21 is swung from the seating position P1 to the rear of the vehicle body as indicated by an arrow M in a state where the left seat back 22 is locked in the forward tilted position. .
[0154]
In (b), the bracket 166 of the left / left cushion lock mechanism 36 ascends as shown by an arrow M integrally with the seat cushion 21 (see (a)), so that the latch 167 provided on the bracket 166 rises.
Since the striker 107 is disposed in the engagement groove 167a of the latch 167, when the latch 167 is raised, the lower side 167c of the engagement groove 167a interferes with the striker 107, and the latch 167 has the latch pin 168 as an axis. Rotate as indicated by arrow N.
[0155]
FIGS. 31 (a) and 31 (b) are eighth action explanatory views for explaining the storage operation of the electric storage structure for a vehicle seat according to the present invention, and explain the first half of ST13.
In (a), the latch switch 72 is turned on, and the striker 107 comes out of the engagement groove 167a of the latch 167, and the lock of the left cushion lock mechanism 36 is released (unlocked).
The control unit 42 (see FIG. 3) detects that the latch switch 72 is turned on, and the control unit 42 operates the cushion lock actuator 70 to move the operation rod 172 as indicated by an arrow P.
[0156]
The ratchet 169 swings around the ratchet pin 171 as shown by an arrow Q and presses the cam surface 169b of the ratchet 169 against the cam surface 137d of the latch 167.
Thereby, the latch 167 can be held at the position where the striker 107 has come out of the engagement groove 167a.
[0157]
In (b), by releasing the lock of the left cushion lock mechanism 36, the seat cushion 21 can be continuously swung rearward as indicated by the arrow M about the left and right support shaft portions 31 and 32.
At this time, the control unit 42 detects the motor current of the cushion drive motor 65 and determines whether or not the detected value exceeds a threshold value.
[0158]
If the seat cushion 21 interferes with an obstacle (not shown) and the motor current value exceeds the threshold value, the cushion drive motor 65 is stopped.
On the other hand, when the seat cushion 21 does not interfere with the obstacle, since the motor current value is smaller than the threshold value, the seat cushion 21 is continuously swung back as shown by the arrow M.
[0159]
Here, as shown in FIG. 5, by attaching the spring 121 to the right support shaft 32, the repulsive force of the spring 121 is indicated by the arrow Fo1 as the seat cushion 21 moves from the seating position P1 to the storage position P2. Gradually increases.
Therefore, the repulsive force Fo1 of the spring 121 is small in the range from the vicinity of the seating position P1 to the vertical position P4.
As a result, the cushion drive motor 65 can smoothly swing the seat cushion 21 from the seating position P1 to the rear of the vehicle body as indicated by the arrow M.
[0160]
32 (a) and 32 (b) are ninth action explanatory views for explaining the storing operation of the electric storage structure for a vehicle seat according to the present invention, and the latter half of ST13 is described.
In (a), the seat cushion 21 is swung to the vertical position P4, and the seat cushion 21 is continuously swung as shown by the arrow M from the vertical position P4 to the rear of the vehicle body.
Here, when the seat cushion 21 exists in the range from the vertical position P4 to the storage position P2, the weights of the seat cushion 21 and the left seat back 22 are applied in the direction in which the seat cushion 21 is swung.
[0161]
On the other hand, the spring 121 (see FIG. 5) whose repulsive force Fo1 increases as the seat cushion 21 moves toward the storage position P2 is attached to the right support shaft 32, so that the seat cushion 21 exceeds the vertical position P4 and is stored. A relatively large repulsive force Fo1 of the spring 121 when swinging to P2 is ensured.
[0162]
Therefore, the weight of the seat cushion 21 and the left seat back 22 can be offset by the repulsive force Fo1 of the spring 121.
Thereby, the seat cushion 21 can be smoothly swung as shown by the arrow M from the vertical position P4 to the storage position P2.
[0163]
In (b), the seat cushion 21 is smoothly swung to the rear of the vehicle body and stored in the floor storage recess 16. At this time, the rear surface of the left headrest 24 comes into contact with the upper end 16 b of the rear wall 16 a that constitutes the floor storage recess 16.
As a result, a load Fo3 is applied to the rear surface of the left headrest 24 as indicated by an arrow, and the left headrest 24 is folded as indicated by an arrow R against a spring (not shown) that supports the left headrest 24.
In this state, the seat cushion 21 is continuously swung backward as shown by the arrow M.
[0164]
FIG. 33 is a tenth action explanatory view for explaining the storing operation of the electric storage structure for a vehicle seat according to the present invention, and explains ST14.
The seat cushion 21 contacts the bottom surface 16 c of the floor storage recess 16. The cushion drive motor 65 stops when the motor current value of the cushion drive motor 65 exceeds the threshold value.
Thereby, the process of accommodating the seat cushion 21 and the left seat back 22 (second rear seat 15) in the floor accommodating recess 16 is completed.
[0165]
Next, the returning operation of the vehicle seat electric storage structure 20 will be described with reference to FIGS.
FIG. 34 is a flowchart for explaining the return operation of the electric storage structure for a vehicle seat according to the present invention.
ST20: The tailgate is opened and the seat operation button is pressed to turn on the return switch. Thereby, the seat cushion is swung forward of the vehicle body.
[0166]
ST21: When the seat cushion is swung forward by a predetermined angle, the left seat back is released from the seat cushion.
ST22: The seat cushion is locked at the return position.
Hereinafter, the contents of ST20 to ST22 will be described in detail.
[0167]
FIGS. 35 (a) and 35 (b) are first operation explanatory views for explaining the return operation of the electric storage structure for a vehicle seat according to the present invention, where FIG. 35 (a) shows ST20 and FIG. 35 (b) shows ST21. It is.
In (a), the user 240 opens the tailgate 241 provided at the rear of the vehicle body 19 upward. When the tailgate 241 is opened, a tailgate opening switch (not shown) is turned on.
Next, the return operation portion 26b of the seat operation button 26 provided behind the second rear seat 15 is pushed with a finger to turn on the return switch 29.
[0168]
After the control unit 42 detects that the tailgate opening switch is on, the cushion drive motor 65 (see also FIGS. 2 and 3) of the swing drive mechanism 35 is driven. As a result, the cushion drive motor 65 is driven to swing the seat cushion 21 forward of the vehicle body as indicated by the arrow S integrally with the left seat back 22 about the left and right support shaft portions 31 and 32, and the floor storage recess 16. Take out from inside.
[0169]
The left headrest 24 is released from the rear wall 16a of the floor storage recess 16 by taking out the seat cushion 21 and the left seat back 22 together from the floor storage recess 16.
The left headrest 24 is returned to the use position (see FIG. 35B) by a supporting spring (not shown).
[0170]
In (b), the seat cushion 21 is continued forward of the vehicle body to swing.
Here, as described with reference to FIG. 32, the seat cushion 21 is attached to the right support shaft 32 with the spring 121 (see FIG. 5) in which the repulsive force Fo <b> 1 increases as the seat cushion 21 moves toward the storage position P <b> 2. Ensures a relatively large repulsive force Fo1 of the spring 121 when swinging from the vertical position P4 to the storage position P2.
[0171]
For this reason, when the seat cushion 21 swings from the storage position P2 to the vertical position P4, the weight of the seat cushion 21 and the left seat back 22 can be offset by the repulsive force Fo1 of the spring 121.
Thereby, the seat cushion 21 can be smoothly swung as indicated by the arrow S from the storage position P2 to the vertical position P4.
[0172]
36 (a) and 36 (b) are second action explanatory views for explaining the return operation of the electric storage structure for a vehicle seat according to the present invention, and explain the first half of ST22.
In (a), when the seat cushion 21 is swung toward the front of the vehicle body as indicated by the arrow S, the seat cushion 21 approaches the seating position P1.
[0173]
In (b), the upper side 167e of the engagement groove 167a of the latch 167 contacts the striker 107.
In this state, the bracket 166 and the latch 167 of the left cushion lock mechanism 36 are lowered as indicated by an arrow S integrally with the seat cushion 21 (see also (a)), and the upper side 167e of the engagement groove 167a is pushed up by the striker 107. Thus, the latch 167 rotates around the latch pin 168 as shown by an arrow U.
[0174]
FIGS. 37 (a) and 37 (b) are third action explanatory views for explaining the return operation of the electric storage structure for a vehicle seat according to the present invention, and the latter half of ST22.
In (a), the seat cushion 21 returns to the seating position P1 (see 37 (b)), the latch 167 returns to the lock position, and the latch switch 72 is turned off. The control unit 42 shown in FIG. 37B detects that the latch switch 72 is turned off, and stops the cushion drive motor 65 (see also FIGS. 2 and 3) of the swing drive mechanism 35.
[0175]
Thereby, the return operation of the second rear seat 15 is completed.
Thus, according to the electric storage structure 20 for a vehicle seat, the second rear seat 15 can be electrically stored in the floor storage recess 16 and can be returned from the floor storage recess 16 to the use position.
[0176]
Here, when the seat cushion 21 is returned to the seating position P <b> 1, the seat cushion 21, specifically, the lower portion 166 a of the bracket 166 comes into contact with the distal end portion 163 of the push-up member 162 constituting the left seat cushion push-up mechanism 145. .
However, since the front end portion 163 of the push-up member 162 is supported by the spring force of the lift spring 146, the front end portion 163 of the push-up member 162 is brought into contact with the front end portion 163 of the push-up member 162. Can be absorbed by the elastic change of the lift spring 146.
Accordingly, it is possible to prevent a relatively large force from being applied to the floor 12 when the seat cushion 21 is returned to the seating position P1.
[0177]
Further, the front end portion 163 of the push-up member 162 abuts against the lower portion 166a of the bracket 166, whereby the spring force Fo2 of the lift spring 146 acts in the direction of the arrow, and the seat cushion 21 is separated from the floor 12 by this spring force Fo2. Push up as you do.
Therefore, even when the occupant is not seated on the seat cushion 21, the latch 167 and the left striker 107 can be securely locked, and as an example, the play between the latch 167 and the left striker 107 can be eliminated.
[0178]
In (b), since the state where the seat cushion 21 is held at the seating position P1 can be maintained, the latch 167 (refer to FIG. 37 (b)) and the left striker 107 interfere with each other when the vehicle travels, and vibration noise is generated. Can be prevented from occurring.
[0179]
In addition, although the said embodiment demonstrated an example of the assembly method of the electric storage structure 20 for vehicle seats in FIGS. 17-22, it is also possible to employ | adopt the assembly method shown in the following figure.
FIGS. 38A to 38C are views for explaining another example of assembling the electric storage structure for a vehicle seat according to the present invention.
In (a), left and right L-shaped brackets 250 and 250 are attached to the left and right bottom portions 98 and 99 of the seat cushion 21, respectively.
[0180]
The left and right seat backs 22, 23 are folded on the seat cushion 21, and the lower ends of the left and right seat backs 22, 23 are placed on the bottom of the floor storage recess 16 with the seat cushion 21 inclined at a predetermined angle.
In this state, the seat cushion 21 is moved in the direction of the arrow. Here, the left and right mounting plates 96 and 97 (see also FIG. 20) are set to be inclined at a predetermined angle.
[0181]
In (b), the left and right bottom plates 98 and 99 of the seat cushion 21 are in contact with the left and right mounting plates 96 and 97 (see also FIG. 20).
In this state, while the locking claws 251 and 251 of the left and right L-shaped brackets 250 and 250 are locked to the left and right mounting plates 96 and 97, the front end portion of the seat cushion 21 is swung downward as indicated by an arrow.
[0182]
In (c), the seat cushion 21 and the left and right seat backs 22 and 23 are accommodated in the floor storage recess 16, and the left and right bottom portions 98 and 99 of the seat cushion 21 face upward.
At this time, the left and right mounting plates 96, 97 are guided by the locking claws 251, 251 of the left and right L-shaped brackets 250, 250 and remain in contact with the left and right bottom portions 98, 99 of the seat cushion 21. 21 is followed.
Therefore, the left and right bottom portions 98 and 99 of the seat cushion 21 are kept pressed against the left and right mounting plates 96 and 97.
[0183]
After the seat cushion 21 is stored in the floor storage recess 16 so that the left and right bottom portions 98 and 99 of the seat cushion 21 face upward, the seat cushion 21 is pulled rearward as shown by the arrows, and the left and right mounting plates 96 and 97 are The locking claws 251 and 251 of the L-shaped brackets 250 and 250 are securely locked.
Thereby, the seat cushion 21 is positioned with respect to the left and right mounting plates 96, 97, and the mounting holes 96b ..., 97b ... of the left and right mounting plates 96, 97 (FIGS. 21A and 21B). Align the screw hole (not shown) of the seat cushion 21 with the reference).
[0184]
In this state, the mounting bolts 101 (see FIGS. 22B and 22C) are screwed into the screw holes of the seat cushion 21 through the mounting holes 96b, 97b,. The attachment plates 96 and 97 can be attached to the left and right bottom portions 98 and 99 of the seat cushion 21.
In this manner, the left and right bottom portions 98, 99 of the seat cushion 21 can be kept pressed against the left and right mounting plates 96, 97, and the mounting bolts 101 can be screwed from above.
[0185]
Therefore, even if this method for assembling the vehicle seat electric storage structure 20 is adopted, the left and right mounting plates 96, 97 are the same as the method for assembling the vehicle seat electric storage structure 20 shown in FIGS. Can be easily performed without spending time on the left and right bottom portions 98, 99 of the seat cushion 21.
[0186]
Furthermore, in the said embodiment, although the example which applied the electric storage structure 20 of the vehicle seat to the 2nd rear seat 15 of the vehicle in which 6-7 persons can ride is demonstrated, the electric storage structure 20 of a vehicle seat is not restricted to this. The present invention can also be applied to a rear seat of a vehicle on which 4 to 5 people can ride.
[0187]
In the above embodiment, the left and right unlocking mechanisms 57 and 62 are incorporated in the left and right seat backs 22 and 23, respectively. However, the present invention is not limited to this, and the left and right unlocking mechanisms 57 and 62 are seat cushions. It is also possible to incorporate in 21.
[0188]
Furthermore, in the above-described embodiment, the example in which the swing drive mechanism 35 is provided on the left side of the floor 12 and the mounting member 33 is provided on the right side of the floor 12 has been described. It is also possible to provide the drive mechanism 35 and provide the attachment member 33 on the left side of the floor 12.
[0189]
【The invention's effect】
The present invention exhibits the following effects by the above configuration.
According to the first aspect, the operation cable for releasing the lock of the lock mechanism is bifurcated, the actuator is connected to one side, and the manual operation unit is connected to the other side, so that the lock can be released either automatically or manually.
[0190]
Therefore, the seat back can be moved forward electrically by releasing the lock of the lock mechanism with the actuator. On the other hand, for example, even when the electric circuit including the actuator is in a non-energized state, the seat back can be moved forward by the manual operation unit.
Thereby, the attitude | position of a seat back can be changed suitably according to the use of a motor vehicle, and usability can be improved.
[0191]
According to a second aspect of the present invention, the operation cable is incorporated in the seat back in a state of being slacked into an S-shape, a U-shape, etc., so that when the occupant leans against the seat back and the seat back is deformed, the deformation of the seat back is controlled. Can be absorbed by slack.
Thereby, it can prevent that the external force exceeding a regulation value is applied to an operation cable, and can maintain the operativity of an operation cable suitably.
[Brief description of the drawings]
FIG. 1 is a schematic view showing a vehicle provided with an electric storage structure for a vehicle seat according to the present invention.
FIG. 2 is a perspective view showing an electric storage structure for a vehicle seat according to the present invention.
FIG. 3 is a perspective view showing in detail an electric storage structure for a vehicle seat according to the present invention.
FIG. 4 is a perspective view showing a state in which the vehicle seat of the electric storage structure for a vehicle seat according to the present invention is disassembled from the vehicle body.
FIG. 5 is a perspective view showing a state in which a spring is attached to the right support shaft of the electric storage structure for a vehicle seat according to the present invention.
FIG. 6 is a perspective view showing a swing drive mechanism of an electric storage structure for a vehicle seat according to the present invention.
FIG. 7 is a perspective view showing a state in which the swing drive mechanism of the electric seat storage structure for a vehicle seat according to the present invention is attached to the floor.
FIG. 8 is a perspective view showing a state in which the swing drive mechanism of the electric seat storage structure for a vehicle seat according to the present invention is attached to the floor.
FIG. 9 is an explanatory view of the swing drive mechanism of the electric storage structure for a vehicle seat according to the present invention.
FIG. 10 is a cross-sectional view of a vehicle equipped with an electric storage structure for a vehicle seat according to the present invention.
FIG. 11 is a perspective view showing a right seat cushion push-up mechanism of the electric storage structure for a vehicle seat according to the present invention.
FIG. 12 is an explanatory view showing a cushion lock mechanism and a seat cushion push-up mechanism of an electric seat storage structure for a vehicle according to the present invention.
FIG. 13 is a view for explaining a lock mechanism and a lock release mechanism of a reclining adjuster of an electric seat storage structure for a vehicle seat according to the present invention.
FIG. 14 is a cross-sectional view showing a connecting portion of an electric storage structure for a vehicle seat according to the present invention.
FIG. 15 is a view for explaining an example in which the lock mechanism of the reclining adjuster of the electric storage structure for the vehicle seat according to the present invention is released by the left automatic unlocking unit;
FIG. 16 is a view for explaining an example in which the lock mechanism of the reclining adjuster of the electric storage structure for a vehicle seat according to the present invention is released by the left manual lock release unit;
FIG. 17 is a flowchart showing a procedure for assembling the electric storage structure for a vehicle seat according to the present invention.
FIG. 18 is a first assembly process diagram illustrating a procedure for assembling the electric storage structure for a vehicle seat according to the present invention.
FIG. 19 is a second assembly process diagram for explaining the procedure for assembling the electric storage structure for a vehicle seat according to the present invention.
FIG. 20 is a third assembly process diagram for explaining the procedure for assembling the electric storage structure for a vehicle seat according to the present invention.
FIG. 21 is a fourth assembly process diagram illustrating the procedure for assembling the electric storage structure for a vehicle seat according to the present invention.
FIG. 22 is a fifth assembly process diagram illustrating the procedure for assembling the electric storage structure for a vehicle seat according to the present invention.
FIG. 23 is a flowchart illustrating the storing operation of the electric storage structure for a vehicle seat according to the present invention.
FIG. 24 is a first operation explanatory view illustrating the storing operation of the electric storage structure for a vehicle seat according to the present invention.
FIG. 25 is a second operation explanatory diagram illustrating the storing operation of the electric storage structure for a vehicle seat according to the present invention.
FIG. 26 is a third action explanatory diagram illustrating the storing operation of the electric storage structure for the vehicle seat according to the present invention.
FIG. 27 is a fourth action explanatory view illustrating the storage operation of the electric storage structure for a vehicle seat according to the present invention.
FIG. 28 is a fifth action explanatory diagram illustrating the storing operation of the electric storage structure for a vehicle seat according to the present invention.
FIG. 29 is a sixth action explanatory view illustrating the storage operation of the electric storage structure for a vehicle seat according to the present invention.
FIG. 30 is a seventh action explanatory view illustrating the storing operation of the electric storage structure for a vehicle seat according to the present invention.
FIG. 31 is an eighth action explanatory view illustrating the storage operation of the electric storage structure for a vehicle seat according to the present invention.
FIG. 32 is a ninth action explanatory view illustrating the storage operation of the electric storage structure for a vehicle seat according to the present invention.
FIG. 33 is a tenth action explanatory diagram illustrating the storage operation of the electric storage structure for a vehicle seat according to the present invention.
FIG. 34 is a flowchart for explaining the return operation of the electric storage structure for a vehicle seat according to the present invention.
FIG. 35 is a first operation explanatory diagram illustrating a return operation of the electric storage structure for a vehicle seat according to the present invention.
FIG. 36 is a second action explanatory diagram illustrating the return operation of the electric storage structure for a vehicle seat according to the present invention.
FIG. 37 is a third action explanatory diagram illustrating the return operation of the electric storage structure for a vehicle seat according to the present invention.
FIG. 38 is a view for explaining another example of assembling the electric storage structure for a vehicle seat according to the present invention.
39 is a cross-sectional view of FIG. 3 of Patent Document 1. FIG.
FIG. 40 is a view for explaining the operation of a conventional vehicle seat storage structure.
[Explanation of symbols]
DESCRIPTION OF SYMBOLS 10 ... Vehicle, 12 ... Floor, 15 ... 2nd rear seat (vehicle seat), 20 ... Electric storage structure of a vehicle seat, 21 ... Seat cushion, 22 ... Left seat back (seat back), 23 ... Right seat back ( Seat back), 56 ... Left lock mechanism (lock mechanism), 57 ... Left lock release mechanism, 61 ... Right lock mechanism (lock mechanism), 62 ... Right lock release mechanism, 80 ... Drive motor (actuator), 195 ... Operation cable DESCRIPTION OF SYMBOLS 196 ... Left automatic lock release part, 197 ... Left manual lock release part, 200 ... Connection part, 201 ... 2nd cable (one cable of two branches), 202 ... Third cable (the other cable of two branches) ), 211... (Manual lever) manual operation unit.

Claims (2)

In the electric storage structure for a vehicle seat in which the seat back is attached to the seat cushion so that the seat back can be tilted, the seat back is swung by an actuator, and the seat back at the tilted position can be locked by a lock mechanism.
The operation cable for unlocking the lock mechanism is bifurcated, and the actuator is connected to one of the two cables and the manual operation unit is connected to the other cable, so that the lock mechanism can be unlocked either automatically or manually. An electric storage structure for a vehicle seat, characterized in that it can be implemented. 2. The electric storage structure for a vehicle seat according to claim 1, wherein the operation cable is built in a seat back and is loosened into an S shape, a U shape, or the like.

Images