JP7140971B2 - seat slide device - Google Patents

Description

The present invention relates to a seat slide device for sliding a vehicle seat forward and backward.

Conventionally, as a seat slide device for sliding a vehicle seat back and forth, for example, a seat slide device disclosed in Patent Document 1 is known. This seat slide device comprises a lower rail member fixed to the vehicle body, an upper rail member fixed to the seat so as to be slidable relative to the lower rail member, and a screw shaft extending rearward inside the upper rail member. , is equipped with The seat slide device also includes a bracket that rotatably supports the screw shaft through which the bracket is fixed to the upper rail member using a bolt. The screw shaft is screwed into a nut member fixed to the lower rail member, and the upper rail member is slid forward and backward with respect to the lower rail member according to the rotation direction of the screw shaft.

JP 2011-173556 A

By the way, in the configuration as described above, since the required length of the screw shaft changes according to the amount of slide, it is necessary to prepare a screw shaft having a length corresponding to the amount of slide required for each amount of slide. , there is a problem that it is difficult to standardize parts such as the screw shaft. In addition, as the amount of sliding increases, the length of the screw shaft increases, which makes it difficult to reduce the weight of the seat slide device. Also, for example, even with a seat slide device using a rack and a pinion, it is necessary to prepare a rack having a length corresponding to the slide amount, and there is a similar problem that standardization and weight reduction are difficult.

SUMMARY OF THE INVENTION An object of the present invention is to provide a configuration that allows the same slide mechanism to be used regardless of the amount of slide.

In order to achieve the above object, the invention of claim 1 described in the scope of claims is
a lower rail (20) fixed to a floor surface and having a plurality of engagement holes (27) formed at equal intervals along the sliding direction;
an upper rail (30) fixed to the seat and provided slidably with respect to the lower rail;
a motor (41) that rotates when sliding;
a slide mechanism (50) that is assembled to the upper rail and slides the upper rail with respect to the lower rail in accordance with the rotational force of the motor;
A seat slide device (10) comprising:
The slide mechanism is
an input side gear (61) that rotates according to the rotational force of the motor;
a first gear (62) coaxially provided with an arc-shaped first slide gear (62a);
a second gear (63) coaxially provided with a second slide gear (63a);
A lock part (70) formed on one side with a rack (71) that can be engaged with the first slide gear and the second slide gear and with a predetermined number of engagement claws (72) that can be engaged with the engagement holes. )When,
an urging force for urging the lock portion in a direction of pressing the rack against one of the first slide gear and the second slide gear and in a direction of engaging the engaging pawl with the engaging hole; a part (80);
with
one of the first gear and the second gear meshes with both the other gear and the input side gear;
Since the first slide gear is formed in an arc shape, the rack has a first meshing state in which it meshes with the first slide gear according to the biasing force of the biasing portion, and a state in which the rack engages with the first slide gear. maintained in one of a second meshing state in which the second slide gear meshes in a non-engaged state, and
In the first slide gear, the engagement between the engaging pawl and the engaging hole is released during the first meshing state so that the engaging pawl can be engaged with the next engaging hole. the lock portion is formed to move relative to the first slide gear at a predetermined distance along the slide direction to a position of
The second slide gear moves along the slide direction at the predetermined distance with the engagement pawl and the engagement hole engaged in the second meshed state. It is characterized in that it is formed so as to move relative to the locking part.

The invention of claim 2 is
a lower rail (20) fixed to a floor surface and having a plurality of engagement holes (27) formed at equal intervals along the sliding direction;
an upper rail (30) fixed to the seat and provided slidably with respect to the lower rail;
a motor (41) that rotates when sliding;
a slide mechanism (50) that is assembled to the upper rail and slides the upper rail with respect to the lower rail in accordance with the rotational force of the motor;
A seat slide device (10) comprising:
The slide mechanism is
an input side gear (61) that rotates according to the rotational force of the motor;
a first gear (62) coaxially provided with an arc-shaped first slide gear (62a);
a second gear (63) coaxially provided with a second slide gear (63a);
A rack (71) that can be engaged with the first slide gear and the second slide gear is formed on one side, and a predetermined number of engagement claws (72) that can be engaged with the engagement holes are formed on the other side. a lock portion (70a) that
biasing the lock portion in a direction of pressing the rack against one of the first slide gear and the second slide gear and in a direction of releasing the engagement between the engaging pawl and the engaging hole; a biasing portion (80) to
with
one of the first gear and the second gear meshes with both the other gear and the input side gear;
Since the first slide gear is formed in an arc shape, the rack has a first meshing state in which it meshes with the first slide gear according to the biasing force of the biasing portion, and a state in which the rack engages with the first slide gear. maintained in one of a second meshing state in which the second slide gear meshes in a non-engaged state, and
In the second slide gear, the engagement between the engaging pawl and the engaging hole is released during the second meshing state so that the engaging pawl can be engaged with the next engaging hole. the lock portion is formed to move relative to the second slide gear at a predetermined distance along the slide direction to a position of
The first slide gear engages the engagement pawl with the engagement hole during the first meshing state so that the first slide gear moves along the slide direction at the predetermined distance from the lock portion. characterized by being formed so as to move relative to the
It should be noted that the symbols in parentheses above indicate the corresponding relationship with specific means described in the embodiments to be described later.

In the invention of claim 1, one of the first gear coaxially provided with the arc-shaped first slide gear and the second gear coaxially provided with the second slide gear is connected to the input side gear. meshes with both sides of the In addition, the lock portion has a rack that can be engaged with the first slide gear and the second slide gear, and a predetermined number of engagement claws that can be engaged with the engagement holes of the lower rail. The biasing portion biases in a direction to press against either one of the slide gear and the second slide gear and in a direction to engage the engagement pawl with the engagement hole. Since the first slide gear is formed in an arc shape, the rack is engaged with the first slide gear in a first meshing state and in meshing with the first slide gear according to the biasing force of the biasing portion. It is maintained in one of a second meshing state in which the second slide gear is meshed in a state in which the second slide gear is not engaged. Further, the first slide gear is locked to a position where the engaging pawl and the engaging hole are disengaged during the first meshing state and the engaging pawl can be engaged with the next engaging hole. A portion is formed to move relative to the first slide gear at a predetermined distance along the sliding direction, and the second slide gear engages the engaging pawl and the engaging hole during the second meshing state. In the mated state, the second slide gear is formed to move relative to the lock portion by the predetermined distance along the slide direction.

As a result, the second slide gear is in a reverse rotation relationship with respect to the first slide gear, and in the first meshing state, the engaging pawl in the disengaged state reaches a position where it can be engaged with the next engaging hole. The lock portion moves relative to the first slide gear at a predetermined distance along the slide direction, and in the second meshing state, the second slide gear engages with the lower rail at the predetermined distance along the slide direction. move relative to the lock portion. That is, when the first slide gear, the second slide gear, and the input side gear are included in the gear portion, each time the first slide gear makes one rotation, the slide mechanism enters the first meshing state with respect to the lower rail. After the locking portion moves a predetermined distance in the sliding direction, the gear portion moves the same predetermined distance so as to follow in the second meshing state. In this manner, the movement of the lock portion and the movement of the gear portion are alternately repeated so that the slide mechanism moves in the slide direction with respect to the lower rail. The same slide mechanism can be employed in a relatively short seat slide device. Therefore, it is possible to realize a seat slide device that can employ the same slide mechanism regardless of the slide amount without making the slide mechanism heavy due to the long slide amount.

In the invention of claim 2, one of the first gear coaxially provided with the arc-shaped first slide gear and the second gear coaxially provided with the second slide gear is connected to the input side gear. meshes with both sides of the Further, the lock portion has a rack formed on one side that can be engaged with the first slide gear and the second slide gear, and a predetermined number of engagement claws that can be engaged with the engagement holes of the lower rail on the other side. The biasing portion biases the rack in a direction to press the rack against either one of the first slide gear and the second slide gear and to release the engagement between the engaging pawl and the engaging hole. Since the first slide gear is formed in an arc shape, the rack is engaged with the first slide gear in a first meshing state and in meshing with the first slide gear according to the biasing force of the biasing portion. It is maintained in one of a second meshing state in which the second slide gear is meshed in a state in which the second slide gear is not engaged. Further, the second slide gear is locked to a position where the engaging pawl is disengaged from the engaging hole and the engaging pawl can be engaged with the next engaging hole during the second meshing state. is formed to move relative to the second slide gear at a predetermined distance along the sliding direction, and the first slide gear engages the engagement pawl with the engagement hole during the first meshing state. Then, the first slide gear is formed to move relative to the lock portion by the predetermined distance along the slide direction.

Even in this case, as in the invention of claim 1, each time the first slide gear rotates once, the lock portion of the slide mechanism is moved in the slide direction by a predetermined distance in the second meshing state with respect to the lower rail. After the movement, the same predetermined distance is moved so that the gear portion follows in the first meshing state. Therefore, it is possible to realize a seat slide device that can employ the same slide mechanism regardless of the slide amount without making the slide mechanism heavy due to the long slide amount.

In claim 3, the first gear and the second gear are formed to have the same shape so that the first slide gear and the second slide gear have the same shape. By adjusting the number of teeth, pitch circle diameter, rotation center position, etc. of each gear, even if the first and second slide gears and the first and second slide gears have the same shape, the movement of the lock part and the It is possible to realize a slide mechanism that slides so as to alternately repeat the movement of the gear portion. As a result, the gear portion can be further standardized.

1 is a perspective view showing a schematic configuration of a seat slide device according to a first embodiment; FIG. 2A is a plan view of the seat slide device shown in FIG. 1, and FIG. 2B is a side view of the seat slide device shown in FIG. FIG. 2 is an explanatory diagram showing an enlarged view of the seat slide device shown in FIG. 1 as seen from the rear side; FIG. 2 is a block diagram schematically showing the electrical configuration of the seat slide device; FIG. It is explanatory drawing which shows an upper rail etc. from FIG. 1 except a lower rail, FIG. 5(A) shows a top view, FIG. 5(B) shows a side view. 5 is an explanatory diagram showing an enlarged view of the upper rail and the like shown in FIG. 4 as viewed from the rear side; FIG. FIG. 5B is a sectional view showing the XX section of FIG. 5B; It is explanatory drawing of a locking part, Fig.8 (A) shows a front view, FIG.8(B) shows a side view, FIG.8(C) shows a bottom view. It is a timing chart figure explaining the operating principle of the slide using a slide mechanism. FIG. 11 is an explanatory diagram for explaining a main part of a seat slide device according to a second embodiment; FIG. 11A is an explanatory diagram illustrating a modification of the gear portion, and FIG. 11A shows a state in which the lock portion unlocked from the gear portion in the second meshing state is relatively movable in the sliding direction; FIG. 11(B) shows a state in which the gear portion is relatively movable in the sliding direction with respect to the locking portion in the locked state in the first meshing state.

[First embodiment]
A seat slide device according to a first embodiment of the present invention will be described below with reference to the drawings.
A seat slide device 10 according to the present embodiment is a device for fixing a vehicle seat (not shown) configured as an electric slide seat to a floor surface (not shown) such as a vehicle floor so as to be slidable back and forth. 1 to 3, the seat slide device 10 mainly includes a lower rail 20 fixed to the floor surface, an upper rail 30 fixed to the vehicle seat, and the upper rail 30 attached to the lower rail 20. A pair of left and right slide mechanisms 50 for sliding the two are provided.

Further, as shown in FIG. 4, the seat slide device 10 includes a motor 41 for driving the pair of slide mechanisms 50, and an operation portion 42 operated when adjusting the slide position of the upper rail 30 with respect to the lower rail 20. , and a control unit 43 for rotationally driving the motor 41 according to the operation of the operation unit 42 . Each element constituting the seat slide device 10 will be described in detail below, with the longitudinal direction of the seat slide device 10 (horizontal direction in FIG. 2) as the front-rear direction. 1 and 2 show one rail including a pair of lower rail 20 and upper rail 30, etc., and the illustration of the other rail is omitted for the sake of convenience.

2 and 3, the lower rail 20 has a bottom wall 21 fixed to the floor and one-side guide portions provided on both sides of the bottom wall 21. 22a and the other side guide portion 22b. The one-side guide portion 22a and the other-side guide portion 22b surround and guide the roller 33 supported by the upper rail 30. A top surface 23 and a bottom surface 24, which are arranged so that the roller 33 rolls and contacts them, and a connecting surface 25 which connects the top surface 23 and the bottom surface 24 are formed. An inner wall portion 26 extends from the inner end of the upper surface 23 to each of the one-side guide portion 22a and the other-side guide portion 22b. A plurality of engaging holes 27 engageable with respective engaging claws 72 of the locking portion 70 (to be described later) are formed at equal intervals along the longitudinal direction in the inner wall portion 26 that continues to the one-side guide portion 22a.

The upper rail 30 is an upper rail for an electric slide seat, and is assembled with a slide mechanism 50 for performing slide control using rotational driving of a motor 41 . As shown in FIGS. 5 and 6, the upper rail 30 includes a first upper rail 31 and a second upper rail 32 arranged as a left and right pair. Rollers 33 are rotatably supported.

Between the first upper rail 31 and the second upper rail 32, two substantially cylindrical guide portions 34 are provided for guiding the lock portion 70 in the sliding direction. As shown in FIGS. 5B and 6, the first upper rail 31 has openings 31a, 31b, and 31c elongated in the sliding direction, through which a part of the lock portion 70 guided by the guide portion 34 is inserted. It is formed to be

The slide mechanism 50 includes a gear portion 60 , a lock portion 70 and an urging portion 80 . As shown in FIG. 7, the gear portion 60 includes an input side gear 61 that rotates according to the rotational force of the motor 41, a first gear 62 and a second gear 63, and gears 61 to 63 that are assembled to the upper rail 30. and a gear case 64 that rotatably supports 63 . The first gear 62 is coaxially provided with an arcuate first slide gear 62a, and the second gear 63 is coaxially provided with a circular second slide gear 63a. The second gear 63 meshes with both the first gear 62 and the input side gear 61, and the first gear 62 and the second gear 63 have a reverse rotation relationship. 7 and FIG. 9, which will be described later, the teeth of each gear in the gear portion 60 are omitted for convenience and are illustrated by circular or arc-shaped pitch circles.

The gear case 64 is formed with an opening 64a for exposing the first slide gear 62a and the second slide gear 63a to the first upper rail 31 side. The first gear 62 and the second gear 63 are supported by the gear case 64 through the opening 64a such that the first slide gear 62a and the second slide gear 63a face the opening 31a of the first upper rail 31. . In particular, as can be seen from FIG. 7, the first gear 62 and the second gear 63 have a pitch circle larger than that of the second slide gear 63a when the first slide gear 62a is circular. It is supported by the gear case 64 so as to be on the side.

As shown in FIG. 8, the lock portion 70 includes a rack 71 that can be meshed with the first slide gear 62a and the second slide gear 63a, and a predetermined number of engagement claws 72 that can be engaged with the engagement holes 27 of the lower rail 20. and a connecting portion 73 that connects the rack 71 and each engaging claw 72 . The rack 71 and each engaging claw 72 are formed to extend in the same direction from the upper end and lower end of one side of the connecting portion 73 . Each engaging claw 72 is formed to engage with the engaging hole 27 of the lower rail 20 when the rack 71 is meshed with the second slide gear 63a. In particular, each engaging claw 72 is formed so that the width thereof becomes narrower toward the tip side in order to smoothly engage with the engaging hole 27 . The connecting portion 73 is formed with an opening 74 elongated in the sliding direction through which the guide portions 34 are inserted when the upper rail 30 is assembled.

As shown in FIG. 6, the locking portion 70 configured in this manner has both the guide portions 34 inserted through the opening 74 of the connecting portion 73, the rack 71 inserted through the opening 31a, and the engaging claws 72 extending through the opening 31b. It is attached to the upper rail 30 so as to be inserted into the .

In this assembled state, the locking portion 70 is in a state in which it can be guided in the sliding direction by both guide portions 34 inserted through the openings 74 . Also, the rack 71 faces the first slide gear 62 a and the second slide gear 63 a of the gear portion 60 assembled to the upper rail 30 .

The urging portion 80 is configured as a coil spring, and is arranged to urge the connecting portion 73 of the lock portion 70 toward the first upper rail 31 when assembled to the second upper rail 32 . there is For this reason, the urging portion 80 is in a direction to press the rack 71 against either the first slide gear 62a or the second slide gear 63a, and engages each of the engaging claws 72 with the opposing engaging holes 27. It functions to bias the locking portion 70 in the direction.

In such an energized state, the arc-shaped first slide gear 62a may be positioned closer to the rack 71 than the circular-shaped second slide gear 63a, so that the rack 71 is positioned closer to the first slide gear 62a than the second slide gear 63a. A meshing state in which the gear 62a is meshed (hereinafter also referred to as a first meshing state), and a meshing state in which the rack 71 is meshed with the second slide gear 63a while not meshing with the first slide gear 62a (hereinafter also referred to as a second slide gear 62a). (also referred to as a meshed state) or maintained in either state.

The upper rail 30 to which the slide mechanism 50 configured as described above is assembled is assembled to the lower rail 20 such that each roller 33 is guided by the one-side guide portion 22a and the other-side guide portion 22b. In this assembled state, when the rack 71 of the lock portion 70 urged by the urging portion 80 is engaged with the second slide gear 63a, the engaging pawl 72 inserted through the opening 31b is engaged with the engaging hole 27. As a result, the upper rail 30 is brought into a non-slidable locked state with respect to the lower rail 20 .

Next, the characteristic configuration of this embodiment will be described in detail.
In this embodiment, the first slide gear 62a engages the lock portion 70 by pushing the rack 71 in the unlocking direction by a predetermined amount or more against the biasing force of the biasing portion 80 in the first meshing state. It is arranged so that the engagement between the claw 72 and the engagement hole 27 of the lower rail 20 is released. Further, in the first meshing state during one rotation of the first slide gear 62a, while the amount of pushing of the rack 71 becomes equal to or greater than the above predetermined amount, the lock portion 70 is engaged with the first slide gear 62a at a predetermined distance along the sliding direction. The engaging claw 72 is formed so as to mesh with the next engaging hole 27 when the rack 71 moves relative to the first slide gear 62a and the pushing amount of the rack 71 changes to less than the predetermined amount. That is, the first slide gear 62a is adjusted so that the predetermined distance is the distance in the sliding direction from the engaged engagement hole 27 to the engagement hole 27 to be engaged next. This adjustment can be made according to the number of teeth of the first slide gear 62a, the diameter of the pitch circle, the position of the center of rotation, and the like.

Further, the second slide gear 63a is arranged so that the engagement state between the engagement claw 72 of the lock portion 70 and the engagement hole 27 of the lower rail 20 is maintained in the second engagement state. Further, the second slide gear 63a is adjusted so as to move relative to the lock portion 70 engaged with the lower rail 20 along the sliding direction by the predetermined distance in the second meshing state during one rotation. It is This adjustment can be made according to the pitch circle diameter of the second slide gear 63a, the rotation center position, and the like.

As for the operating principle of the slide using the slide mechanism 50 configured in this way, refer to the timing chart shown in FIG. and detailed below.

As shown in FIG. 9A, in the second meshing state, the engaging claw 72 of the locking portion 70 and the engaging hole 27 of the lower rail 20 are engaged, and the second slide gear 63a is engaged with the rack 71 of the locking portion 70. As shown in FIG. is engaged with Therefore, the gear portion 60 relatively moves in the sliding direction with respect to the lock portion 70 engaged with the lower rail 20 according to the rotation of the second slide gear 63a.

Then, as shown in FIG. 9B, when the first slide gear 62a and the rack 71 begin to mesh with each other and shift from the second meshed state to the first meshed state, the rack 71 is pushed by the first slide gear 62a. First, the locking portion 70 begins to move in the unlocking direction against the biasing force of the biasing portion 80 .

After that, as shown in FIG. 9C, when the rack 71 is pushed by a predetermined amount or more by the first slide gear 62a, the engagement between the engaging claw 72 of the locking portion 70 and the engaging hole 27 of the lower rail 20 is released. be done. In this released state, as can be seen from FIG. 9C, the lock portion 70 starts to move relative to the first slide gear 62a along the slide direction in accordance with the rotation of the first slide gear 62a. Furthermore, by rotating the first slide gear 62a, the lock portion 70 moves further relative to the first slide gear 62a along the slide direction.

Then, as shown in FIG. 9(D), even if the push amount of the rack 71 starts to decrease as the first slide gear 62a rotates further, the lock portion 70 remains locked while the push amount is equal to or greater than the predetermined amount. relative movement in the sliding direction is continued.

After that, when the pushing amount of the rack 71 becomes less than the predetermined amount, the lock portion 70 moves along the sliding direction at the predetermined distance (corresponding to the distance to the three adjacent engagement holes 27 in the example of FIG. 9). Since it is moving and the engaging claw 72 has moved to the engaging hole 27 to be engaged next, each engaging claw 72 starts engaging with the opposing engaging hole 27 .

Then, as shown in FIG. 9E, when the first slide gear 62a rotates to a rotation angle at which it does not mesh with the rack 71, the first meshing state shifts to the second meshing state. In this state, each of the engaging claws 72 has just finished engaging with the engaging hole 27, and the rotation of the second slide gear 63a with respect to the rack 71 with which the second slide gear 63a meshes. relative movement along the sliding direction accordingly. That is, the gear portion 60 begins to move relative to the lock portion 70 engaged with the lower rail 20 along the sliding direction in accordance with the rotation of the second slide gear 63a.

After that, the gear portion 60 relatively moves along the slide direction according to the rotation of the second slide gear 63a until the first slide gear 62a starts to mesh with the rack 71. As shown in FIG. The second slide gear 63a is formed to move relative to the lock portion 70 engaged with the lower rail 20 along the sliding direction by the predetermined distance in the second meshing state during one rotation. Therefore, the gear portion 60 relatively moves along the sliding direction by the predetermined distance during the second meshing state.

As described above, in the slide mechanism 50, after the lock portion 70 moves relative to the gear portion 60 along the sliding direction by the predetermined distance during the first meshing state, the gear portion 60 moves during the second meshing state. It moves relative to the lock portion 70 along the sliding direction by the predetermined distance. That is, the slide mechanism 50 moves in the slide direction with respect to the lower rail 20 by alternately repeating the movement of the lock portion 70 and the movement of the gear portion 60 . Therefore, the upper rail 30 to which the slide mechanism 50 is assembled can be slid with respect to the lower rail 20 according to the rotation of the motor 41 .

In this embodiment, the second gear 63 is configured to mesh with both the first gear 62 and the input side gear 61. may be configured to mesh with both.

As described above, in the seat slide device 10 according to the present embodiment, the first gear 62 coaxially provided with the arc-shaped first slide gear 62a and the second gear provided coaxially with the second slide gear 63a 63 meshes with both the other and the input side gear 61 . A lock portion formed on one side with a rack 71 that can be engaged with the first slide gear 62a and the second slide gear 63a and a predetermined number of engagement claws 72 that can be engaged with the engagement holes 27 of the lower rail 20. Reference numeral 70 denotes a direction in which the rack 71 is pressed against either the first slide gear 62a or the second slide gear 63a, which is the direction in which the engaging claw 72 is engaged with the engaging hole 27 by a biasing portion 80. Forced. Since the first slide gear 62a is formed in an arc shape, the rack 71 is in a first meshing state in which the first slide gear 62a is meshed with the first slide gear 62a according to the biasing force of the biasing portion 80. A second meshing state in which the second slide gear 63a is meshed with the second slide gear 63a while not meshing with the gear 62a is maintained. In the first slide gear 62a, the engagement between the engaging claw 72 and the engaging hole 27 is released during the first meshing state, and the engaging claw 72 engages the next engaging hole 27. The lock portion 70 is formed to move relative to the first slide gear 62a by a predetermined distance along the sliding direction to a possible position, and the second slide gear 63a is engaged during the second meshing state. The second slide gear 63a is formed to move relative to the lock portion 70 by the predetermined distance along the slide direction while the claw 72 and the engagement hole 27 are engaged with each other.

As a result, the second slide gear 63a rotates in the opposite direction to the first slide gear 62a, and in the first meshing state, the disengaged engaging pawl 72 engages the next engaging hole 27. The lock portion 70 moves relative to the first slide gear 62a along the sliding direction by a predetermined distance to a possible position, and in the second meshing state, the second slide gear 63a moves along the sliding direction by the predetermined distance. relative to the lock portion 70 engaged with the lower rail 20 . That is, each time the first slide gear 62a rotates once, the lock portion 70 of the slide mechanism 50 moves in the sliding direction by a predetermined distance with respect to the lower rail 20 in the first engagement state, and then enters the second engagement state. The same predetermined distance is moved so that the gear part 60 follows. In this manner, the movement of the lock portion 70 and the movement of the gear portion 60 are alternately repeated so that the slide mechanism 50 moves in the sliding direction with respect to the lower rails 20, so that the seat slide device has a relatively long sliding distance. The same slide mechanism can be employed in a seat slide device having a relatively short slide amount. Therefore, it is possible to realize a seat slide device that can employ the same slide mechanism regardless of the slide amount without making the slide mechanism heavy due to the long slide amount.

[Second embodiment]
Next, a seat slide device according to a second embodiment will be described with reference to FIG.
In the second embodiment, the positional relationship between the rack 71 and the engaging claws 72 in the locking portion 70a is mainly different from that in the first embodiment.
Specifically, as can be seen from FIG. 10, the lock portion 70a according to the present embodiment has a rack 71 formed on one side of the connecting portion 73, and the other side opposite to this one side (back side). Each engaging claw 72 is formed in the . Therefore, in the lower rail 20, the engagement holes 27 are formed at equal intervals along the longitudinal direction with respect to the inner wall portion 26 that continues to the other side guide portion 22b. Further, openings 31 b and 31 c are formed in the second upper rail 32 according to each engagement hole 27 .

The urging portion 80 is directed to press the rack 71 against either the first slide gear 62a or the second slide gear 63a, and to release the engagement between the engaging claw 72 and the engaging hole 27. Also, it functions to bias the lock portion 70a.

In the second slide gear 63a, the engagement between the engaging claw 72 and the engaging hole 27 is released during the second meshing state, and the engaging claw 72 engages the next engaging hole 27. The lock portion 70a is formed to move relative to the second slide gear 63a by a predetermined distance along the slide direction to a possible position. Further, the first slide gear 62a engages the engagement claw 72 with the engagement hole 27 during the first meshing state, and the first slide gear 62a slides along the sliding direction at the predetermined distance. It is formed to move relative to 70a.

That is, in the present embodiment, one of the first gear 62 coaxially provided with the arc-shaped first slide gear 62a and the second gear 63 coaxially provided with the second slide gear 63a It meshes with both the input side gear 61 . A rack 71 that can be engaged with the first slide gear 62a and the second slide gear 63a is formed on one side, and a predetermined number of engagement claws 72 that can be engaged with the engagement holes 27 of the lower rail 20 are formed on the other side. The lock portion 70a is pushed in the direction of pressing the rack 71 against either the first slide gear 62a or the second slide gear 63a, and in the direction of releasing the engagement between the engaging claw 72 and the engaging hole 27. , is biased by the biasing portion 80 . Since the first slide gear 62a is formed in an arc shape, the rack 71 is in a first meshing state in which the first slide gear 62a is meshed with the first slide gear 62a according to the biasing force of the biasing portion 80. A second meshing state in which the second slide gear 63a is meshed with the second slide gear 63a while not meshing with the gear 62a is maintained. In the second slide gear 63a, the engagement between the engaging claw 72 and the engaging hole 27 is released during the second meshing state, and the engaging claw 72 engages the next engaging hole 27. The lock portion 70a is formed to move relative to the second slide gear 63a by a predetermined distance along the sliding direction to a possible position, and the first slide gear 62a is engaged during the first meshing state. The claw 72 is engaged with the engagement hole 27 so that the first slide gear 62a moves relative to the lock portion 70a by the predetermined distance along the slide direction.

Even in this manner, the lock portion 70a of the slide mechanism 50 slides in the second engagement state with respect to the lower rail 20 each time the first slide gear 62a rotates once, as in the first embodiment. After moving a predetermined distance in the direction, the same predetermined distance is moved so that the gear portion 60 follows in the first meshing state. Therefore, it is possible to realize a seat slide device that can employ the same slide mechanism regardless of the slide amount without making the slide mechanism heavy due to the long slide amount.

[Other embodiments]
It should be noted that the present invention is not limited to the above embodiments and the like, and may be embodied as follows, for example.
(1) The second slide gear 63a is not limited to being formed in a circular shape, and may be formed in an arc shape. In particular, like the gear portion 60a schematically illustrated in FIGS. 11A and 11B, the first slide gear 62a and the second slide gear 63a have the same semicircular arc shape. Even if the second gear 63 and the second gear 63 are formed in the same shape, by adjusting the number of teeth of each gear, the pitch circle diameter, the rotation center position, etc., the movement of the lock portion 70a and the gear portion according to the second embodiment can be adjusted. A slide mechanism 50 that slides alternately with the movement of 60a can be realized. 11A and 11B are explanatory diagrams for explaining modifications of the gear portion, and FIG. 11A shows a state in which the lock portion unlocked from the gear portion in the second meshing state moves relative to the gear portion in the sliding direction. FIG. 11(B) shows a state in which the gear portion can relatively move in the sliding direction with respect to the locking portion in the locked state in the first meshing state. As a result, the gear portion can be further standardized. The same effect can be obtained by adjusting the lock portion 70 according to the first embodiment.

(2) The predetermined distances by which the lock portion 70 and the gear portion 60 slide in response to one rotation of the first slide gear 62a are based on the currently engaged engagement hole 27, as shown in FIG. is not limited to being set as the distance to the three adjacent engagement holes 27, but may be set as the distance to the immediately adjacent engagement hole 27 or the distance to the two adjacent engagement holes 27. , to four or more adjacent engagement holes 27 .

(3) The present invention is not limited to use as a seat slide device for seats mounted on vehicles such as automobiles and trains, but also as a seat slide device for seats mounted on vehicles such as airplanes and ships. may be adopted.

DESCRIPTION OF SYMBOLS 10... Seat slide apparatus 20... Lower rail 27... Engagement hole 30... Upper rail 41... Motor 50... Slide mechanism 60, 60a... Gear part 61... Input side gear 62... First gear 62a... First slide gear 63... Second Gear 63a Second slide gear 70, 70a Lock portion 71 Rack 72 Engaging claw 80 Biasing portion

Claims (3)

a lower rail that is fixed to the floor and has a plurality of engagement holes formed at equal intervals along the sliding direction;
an upper rail fixed to the seat and provided slidably with respect to the lower rail;
a motor that rotates when sliding;
a slide mechanism assembled to the upper rail for sliding the upper rail relative to the lower rail in accordance with the rotational force of the motor;
A seat slide device comprising
The slide mechanism is
an input-side gear that rotates according to the torque of the motor;
a first gear coaxially provided with an arc-shaped first slide gear;
a second gear coaxially provided with a second slide gear;
a lock portion formed on one side with a rack that can be engaged with the first slide gear and the second slide gear and with a predetermined number of engagement claws that can be engaged with the engagement holes;
an urging force for urging the lock portion in a direction of pressing the rack against one of the first slide gear and the second slide gear and in a direction of engaging the engaging pawl with the engaging hole; Department and
with
one of the first gear and the second gear meshes with both the other gear and the input side gear;
Since the first slide gear is formed in an arc shape, the rack has a first meshing state in which it meshes with the first slide gear according to the biasing force of the biasing portion, and a state in which the rack engages with the first slide gear. maintained in one of a second meshing state in which the second slide gear meshes in a non-engaged state, and
In the first slide gear, the engagement between the engaging pawl and the engaging hole is released during the first meshing state so that the engaging pawl can be engaged with the next engaging hole. the lock portion is formed to move relative to the first slide gear at a predetermined distance along the slide direction to a position of
The second slide gear moves along the slide direction at the predetermined distance with the engagement pawl and the engagement hole engaged in the second meshed state. A seat slide device characterized by being formed so as to move relative to a lock portion. a lower rail that is fixed to the floor and has a plurality of engagement holes formed at equal intervals along the sliding direction;
an upper rail fixed to the seat and provided slidably with respect to the lower rail;
a motor that rotates when sliding;
a slide mechanism assembled to the upper rail for sliding the upper rail relative to the lower rail in accordance with the rotational force of the motor;
A seat slide device comprising
The slide mechanism is
an input-side gear that rotates according to the torque of the motor;
a first gear coaxially provided with an arc-shaped first slide gear;
a second gear coaxially provided with a second slide gear;
a lock portion formed on one side with a rack that can be engaged with the first slide gear and the second slide gear, and formed with a predetermined number of engaging claws that can be engaged with the engaging holes on the other side;
biasing the lock portion in a direction of pressing the rack against one of the first slide gear and the second slide gear and in a direction of releasing the engagement between the engaging pawl and the engaging hole; a biasing portion that
with
one of the first gear and the second gear meshes with both the other gear and the input side gear;
Since the first slide gear is formed in an arc shape, the rack has a first meshing state in which it meshes with the first slide gear according to the biasing force of the biasing portion, and a state in which the rack engages with the first slide gear. maintained in one of a second meshing state in which the second slide gear meshes in a non-engaged state, and
In the second slide gear, the engagement between the engaging pawl and the engaging hole is released during the second meshing state so that the engaging pawl can be engaged with the next engaging hole. the lock portion is formed to move relative to the second slide gear at a predetermined distance along the slide direction to a position of
The first slide gear engages the engagement pawl with the engagement hole during the first meshing state so that the first slide gear moves along the slide direction at the predetermined distance from the lock portion. A seat slide device characterized in that it is formed so as to move relative to. 3. The first gear and the second gear are formed to have the same shape so that the first slide gear and the second slide gear have the same shape. seat slide device.

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