JP7227471B2 - seat and slide mechanism - Google Patents

Description

The present invention relates to a slide mechanism that slides a seat and a portion of the seat.

2. Description of the Related Art In recent years, many types of seats for vehicles and the like are provided with extensions, such as a seat surface, in order to provide comfort to the occupant of the seat. For example, in the extension of the seat surface, the portion of the seat cushion positioned on the thighs of the occupant is telescopically forward. The extension is provided with a lock mechanism for fixing the position of the seat (extension) after the position of the seat (extension) has been adjusted by the occupant.

Such a locking mechanism includes, for example, a latch provided with a projection such as a boss, a lever provided with a curved groove, and a coil spring that exerts a biasing force to return the projection such as the boss to the locked position. A lock mechanism for a vehicle seat has been disclosed (see, for example, Patent Document 1).

U.S. Pat. No. 7,578,554

However, in the locking mechanism described in Patent Document 1, since the groove has the lever, there is a problem that the rigidity and strength of the lever tend to be low. Also, when the lever is pulled to unlock, the protrusion may come out of the groove. Furthermore, if the lever has a groove, the structure of the lock mechanism becomes complicated, and there is also the problem that the positioning of the projection and the curved groove is complicated when assembling the seat.

Therefore, the object is to improve the rigidity and strength of the lever with a simple structure.

Another object is to facilitate assembly of the seat.

A seat for achieving the above object comprises a fixed frame, a movable frame slidable relative to the fixed frame, a slide supporting member attached to the fixed frame and having a rack gear, and attached to the movable frame, or a slide member integrated with the movable frame and slidably supported by the slide support member; and the slide member slides between a first position and a second position pulled out from the first position. A lever having a lever main body movably supported, a grip portion that moves integrally with the lever main body, and a latch rotatably supported by the slide member are provided. The lever body has a first projection on a surface facing the latch, and the latch has a latch gear that meshes with the rack gear and can contact the first projection when the lever body is slidably moved from the first position to the second position. and a first contact portion. The latch is configured to be rotatable from a locked position where the latch gear meshes with the rack gear to an unlocked position where the latch gear is disengaged from the rack gear by a biasing force from the first protrusion to the first contact portion.

According to such a configuration, since the latch is operated by the first projection of the lever, the lever does not need a groove for receiving the projection of the latch. Therefore, it is possible to improve the rigidity and strength of the lever by simplifying the structure of the lever. Further, during assembly, the seat can be easily assembled because the lever for unlocking the latch and the latch that can be locked and unlocked by the lever are simply installed on the slide member. Furthermore, since the unlocking by the latch is due to the biasing force from the first projection to the first contact portion, the projection does not slip out of the groove.

The first projection may slide on the first contact portion as the latch rotates to the unlocked position.

The lever body has a second projection located closer to the grip than the first projection on the surface facing the latch, and the latch slides the lever body from the second position to the first position. has a second contact portion capable of coming into contact with the second projection, and the latch is rotatable from the unlocked position to the locked position by the biasing force from the second projection to the second contact portion. may be configured.

According to such a configuration, the latch can be locked only by the biasing force from the second protrusion provided on the lever to the second contact portion of the latch, so the structure of the lock mechanism becomes simple. Furthermore, since the locking by the latch is based on the urging force from the second projection to the second contact portion, it is possible to solve the problem that the projection is easily pulled out of the groove, and the locking by the locking mechanism is facilitated.

The second protrusion may slide with the second contact portion as the latch rotates to the locked position.

The latch further has a third contact portion that contacts the side surface of the lever body in the unlocked position, the third contact portion and the side surface of the lever body contact each other, and the first protrusion to the first contact portion is in contact with the third contact portion. By restricting rotation of the latch due to the biasing force, the first contact portion may restrict movement of the first protrusion in the lever pull-out direction.

According to such a configuration, since the third contact portion of the latch and the side surface of the lever main body are brought into contact with each other, movement of the lever in the pull-out direction is restricted, so that the lever can be prevented from slipping out of the slide member.

When the lever body is at the first position, the second protrusion may contact the latch to restrict rotation of the latch from the locked position.

According to this configuration, when the latch returns to the lock position after the sliding member is slid to adjust the position of the movable frame, the rotation of the latch is restricted, so that the movable frame remains in the adjusted position. can be prevented from easily moving from

The seat may further include a biasing member having one end engaged with the lever body and the other end engaged with the slide member for biasing the lever body toward the first position.

According to this structure, simply by releasing the grip of the lever, the lever returns to the first position, and accordingly the latch returns from the unlocked position to the locked position, so unlocking and relocking are easy. becomes.

A slide mechanism for achieving the above object is a slide mechanism in which a fixed frame and a movable frame of a seat are slidably combined with each other, comprising a slide support member attached to the fixed frame and having a rack gear; a slide member attached to the frame and slidably supported by the slide support member; and slidably movable with respect to the slide member between a first position and a second position drawn out from the first position. A lever having a supported lever body, a grip portion that moves integrally with the lever body, and a latch that is rotatably supported by the slide member are provided. The lever body has a first projection on a surface facing the latch, and the latch has a latch gear that meshes with the rack gear and can contact the first projection when the lever body is slidably moved from the first position to the second position. and a first contact portion. The latch is configured to be rotatable from a locked position where the latch gear meshes with the rack gear to an unlocked position where the latch gear is disengaged from the rack gear by an urging force from the first protrusion to the first contact portion. do.

According to such a configuration, since the latch is operated by the first projection of the lever, the lever does not need a groove for receiving the projection of the latch. Therefore, it is possible to improve the rigidity and strength of the lever by simplifying the structure of the lever. Further, during assembly, the seat can be easily assembled because the lever for unlocking the latch and the latch that can be locked and unlocked by the lever are simply installed on the slide member. Furthermore, since the unlocking by the latch is due to the biasing force from the first projection to the first contact portion, the projection does not slip out of the groove.

According to the invention, since the latch is actuated by the first projection of the lever, the lever does not need a groove for receiving the projection of the latch. Therefore, it is possible to improve the rigidity and strength of the lever by simplifying the structure of the lever. Further, during assembly, the seat can be easily assembled because the lever for unlocking the latch and the latch that can be locked and unlocked by the lever are simply installed on the slide member. Furthermore, since the unlocking by the latch is due to the biasing force from the first projection to the first contact portion, the projection does not slip out of the groove.

Further, since the latch can be locked only by the biasing force from the second protrusion provided on the lever to the second contact portion of the latch, the structure of the lock mechanism can be simplified. Furthermore, since the locking by the latch is based on the urging force from the second projection to the second contact portion, it is possible to solve the problem that the projection is likely to slip out of the groove, and to facilitate the locking by the locking mechanism.

The latch further has a third contact portion that contacts the side surface of the lever body in the unlocked position. Since the movement is restricted, it is possible to prevent the lever from coming off the slide member.

Further, when the lever body is in the first position, the second projection contacts the latch and restricts the rotation of the latch from the locked position, so that the slide member is slid to adjust the position of the movable frame. When the latch returns to the lock position after the adjustment, the rotation of the latch is restricted, so that the movable frame can be prevented from easily moving from the adjusted position.

Further, by providing a biasing member having one end engaged with the lever main body and the other end engaged with the slide member for biasing the lever main body toward the first position, the grip portion of the lever is displaced. Simply by releasing the hand, the lever returns to the first position, and the latch also returns from the unlocked position to the locked position, thereby facilitating unlocking and relocking.

1 is an exploded perspective view showing the overall configuration of a seat; FIG. 1 is a perspective view showing the overall configuration of a seat, (a) showing a state where a movable frame is at a first position, and (b) showing a state where the movable frame is at a second position; FIG. It is the perspective view (a) and front view (b) which show a slide support member. FIG. 4 is an exploded perspective view showing the slide member, lever, latch and biasing member; FIG. 4A is a plan view showing the slide mechanism, in which (a) shows the lever in the first position when the latch is in the lock position, and (b) shows the lever in the first position when the latch is in the lock position; , and the first projection contacts the first contact portion. Fig. 5(a) is a plan view showing the slide mechanism, in which (a) shows the state immediately after the lever is further pulled out from the state shown in Fig. 5(b) and the latch is unlocked; Pulled out to show the latch fully unlocked. 7A is a plan view showing the slide mechanism, FIG. 7A showing a state in which the slide member is slid relative to the slide support member with the lever in the second position, and FIG. The lever slides from the state toward the first position, and the second protrusion contacts the second contact portion. 7A is a plan view showing the slide mechanism, FIG. 7A shows a state in which the lever has further slid toward the first position from the state of FIG. 7B, and the latch gear has begun to mesh with the rack gear, and FIG. The lever is shown returned to the first position and the latch returned to the locked position. Fig. 9A is a perspective view showing the slide mechanism, in which (a) shows a state in which the latch is attached to the slide member and the lever is inserted halfway; state. 10(a) is a perspective view showing the slide mechanism, in which (a) shows a state in which the latch is further rotated from the state shown in FIG. 9(b) and a biasing member is attached to the slide member; ) is attached to the movable frame. FIG. 10 is a perspective view showing the slide mechanism, showing a state when the slide member attached to the movable frame is installed on the slide support member attached to the fixed frame;

A sheet according to an embodiment of the present invention will be described in detail with reference to the drawings as appropriate. In the following description, front and rear, left and right, and up and down directions are directions based on the person sitting on the seat.

As shown in FIG. 1, the seat 1 is, for example, a vehicle seat, and is mainly composed of a seat cushion frame 3 that forms the skeleton of the seat cushion and a seat back frame 2 that forms the skeleton of the seat back. ing.

The seat cushion frame 3 is installed on the floor of the vehicle via slide rails (not shown). As a result, the seat 1 can be adjusted in its longitudinal position. The seat cushion frame 3 of this embodiment includes a fixed frame 3a, a movable frame 4 provided at the front end of the fixed frame 3a, and a slide mechanism 100 that slidably combines the fixed frame 3a and the movable frame 4 with each other. ing.

The fixed frame 3a includes a pair of left and right side frames 5, a plate-shaped pan frame 6 connecting the front ends of the pair of left and right side frames 5, and a connecting pipe connecting the rear ends of the pair of left and right side frames 5. 7. An S spring 8 having both ends connected to each of the pair of left and right side frames 5 is also provided.

The side frame 5 is a metal frame extending in the front-rear direction. The pair of side frames 5 are arranged with a space left and right.

The pan frame 6 has left and right side frame portions 61 placed on the pair of left and right side frames 5 and a pressure receiving portion 62 extending in a plate shape between the left and right side frame portions 61 . The left and right side frame portions 61 are installed so as to be fitted into the front end portions of the side frames 5, respectively, and fixed to the side frames 5 by welding or the like. Thereby, the pan frame 6 is fixed to the side frame 5 so as not to move relative to the side frame 5 .

A movable frame 4 is slidably installed on the pressure receiving portion 62 via a slide mechanism 100 . A slide mechanism installation portion 62 a for installing the slide support member 110 of the slide mechanism 100 is provided at substantially the center of the pressure receiving portion 62 . The slide mechanism installation portion 62a has a recessed shape with a width equal to or greater than the length of the slide support member 110 in the left-right direction. One first fixing hole 62b is formed at each of the left and right ends of the bottom surface of the slide mechanism installation portion 62a (the installation surface of the slide support member 110) (only one is shown in FIG. 1).

Both the left and right sides of the slide mechanism installation portion 62a are bank portions 62c that are higher than the bottom surface of the slide mechanism installation portion 62a. The height of the bank portion 62c is not particularly limited as long as the movable frame 4 can slide relative to the pan frame 6 when the movable frame 4 is installed on the fixed frame 3a via the slide mechanism 100. FIG.

The movable frame 4 is provided so as to be movable forward and backward relative to the fixed frame 3a. Specifically, the movable frame 4 has a rear position where the movable frame 4 is positioned at the rearmost position with respect to the fixed frame 3a as shown in FIG. It is slidable back and forth between a front position positioned forward with respect to the fixed frame 3a. Here, as shown in FIG. 2B, the slide member 120 is slid forward with respect to the slide support member 110 in a state in which the grip portion 132 is grasped and the lever 130 is pulled out. The attached movable frame 4 can be slid forward. The movable frame 4 has two (four in total) second fixing holes 41 aligned in the front-rear direction at positions to the left and right of the center in the left-right direction.

The pan frame 6 and the movable frame 4 are made of metal, for example, but may be made of resin.

As shown in FIGS. 3 and 4, the slide mechanism 100 includes a slide support member 110, a slide member 120 slidably supported by the slide support member 110, a lever 130, a latch 140, and a biasing member 150. and

The slide support member 110 is made of resin and attached to the pan frame 6 of the fixed frame 3a. Specifically, the slide support member 110 is attached to the slide mechanism installation portion 62a of the pressure receiving portion 62 (see FIG. 1 and FIG. 11 described later).

As shown in FIG. 3, the slide support member 110 connects a pair of side portions 112 spaced apart in the left and right direction, a connecting portion 111 connecting the rear ends of the side portions 112, and the front ends of the side portions 112. and a connecting portion 115 .

The pair of side portions 112 have substantially the same upper surface height. On the other hand, the height of the upper surfaces of the connecting portions 111 and 115 is lower than that of the side portion 112 . In addition, the upper surface of the connecting portion 115 on the front side is lower than the upper surface of the connecting portion 111 on the rear side.
Each side portion 112 has a guide groove 117 extending in the front-rear direction on its upper surface. In addition, projecting portions 117 a are formed on left and right inner edge portions of the guide grooves 117 of the respective side portions 112 so as to protrude left and right outward.

One side portion 112 arranged on the right side has rack gears 113 on the left and right inner surfaces. The rack gear 113 has a plurality of gear teeth arranged side by side in the front-rear direction.
The other side portion 112 located on the left side has locking projections 114 protruding leftward and rightward at the front end portion.

Each side portion 112 has a first fixing hole 119 penetrating in the vertical direction at a substantially central portion in the front-rear direction. This first fixing hole 119 is a hole into which a screw or the like is inserted for fixing the slide support member 110 to the fixing frame 3a.

Slide stopping portions 116 projecting from the connecting portion 111 are provided on the rear sides of the left and right guide grooves 117, respectively. When the slide member 120 is positioned at the rearmost side (first position), the rear end surface 122b of the slide restricting portion 122 of the slide member 120 contacts the restricting surface 116a of the slide restricting portion 116 .

The connecting portion 111, the side portion 112, the connecting portion 115, and the slide stopping portion 116 are desirably molded integrally, but may be molded separately and then combined.

The slide member 120 is made of resin, is attached to the movable frame 4, and is slidably supported by the slide support member 110 (see FIGS. 1 and 10). The slide member 120 is slidable between a first position, which is the most rearward position with respect to the slide support member 110, and a second position, which is the most forward position from the first position. there is 4, the slide member 120 includes a body portion 121, a pair of left and right slide restricting portions 122, a pair of left and right connecting portions 123, a front plate 124, a front lever guide 125, and a center lever guide. 126 , a first rear lever guide 127 , a second rear lever guide 128 and a lever stopping portion 129 .

The body portion 121 has a substantially rectangular plate shape and has an opening 121a in the center portion. Further, the main body portion 121 has a through hole 121b penetrating in the vertical direction at the installation position of the latch 140 . Further, near the through hole 121b of the main body 121, a substantially arc-shaped rail 121c is provided so that the latch 140 can slide smoothly when it rotates. The rail 121 c has a role of reducing the frictional force between the latch 140 and the main body 121 by preventing the lower surface of the latch 140 (the surface facing the main body 121 ) from directly contacting the main body 121 .

The pair of left and right slide restricting portions 122 extend forward and backward along both left and right sides of the body portion 121 . Each of the pair of left and right slide restricting portions 122 has two second fixing holes 122a penetrating vertically. The two second fixing holes 122a of each slide restricting portion 122 are arranged side by side in the front-rear direction at positions corresponding to the positions of the second fixing holes 41 of the movable frame 4, and the slide member 120 is fixed to the movable frame 4. This is a hole into which a screw or the like is inserted to

Each of the pair of left and right slide restricting portions 122 has a protruding portion 122c extending in the front-rear direction and protruding inward from the upper end portion of the inner surface thereof. These projections 122c are engaged with the projections 117a on the edge of the guide groove 117 when the slide member 120 is combined with the slide support member 110 . This prevents the slide member 120 from coming off the slide support member 110 upward.

The pair of left and right connecting portions 123 connect the pair of left and right slide restricting portions 122 and the front plate 124 , respectively.

The front plate 124 is generally U-shaped with an open bottom, and this open portion consists of a side surface portion 124a and an upper surface portion 124b. Shaped and sized to fit. A concave portion 124c is formed in the upper surface portion 124b. The depth of this recess 124c is equal to or greater than the height of a first projection 133 and a second projection 134 of the lever 130, which will be described later.

The front lever guide 125 is provided on the front side of the opening 121a, and regulates the movement of the lever 130 so that the lever body 131 does not move left and right when the lever 130 slides. The front lever guide 125 is a substantially rectangular parallelepiped member having a through hole 125a penetrating in the front-rear direction. The through-hole 125a is formed to have a shape and a size that allows insertion of a lever body 131 of the lever 130, which will be described later. A concave portion 125b is formed on the upper surface of the through hole 125a. In this embodiment, the upper surface portion 124b of the front plate 124 and the upper surface of the through hole 125a are flush with each other. In addition, the horizontal position of the concave portion 125b is substantially the same as that of the concave portion 124c. The depth of the recess 125b is equal to or greater than the heights of the first projection 133 and the second projection 134 of the lever 130, similarly to the recess 124c.

The center lever guide 126 is provided so as to cover the opening 121a of the body portion 121 from below, and regulates the movement of the lever 130 so that the lever body 131 does not move left or right when the lever 130 slides. The center lever guide 126 has a lever insertion portion 126a, a biasing member setting portion 126b, and an engaging portion 126d.

The lever insertion portion 126a is provided so as to straddle the opening 121a of the body portion 121 to the left and right, and the lever main body 131 of the lever 130 can be inserted above the lever insertion portion 126a.

The biasing member installation portion 126b is connected to the rear end of the lever insertion portion 126a, and the biasing member 150 is installed above it. A biasing member engaging portion 126c with which one end of the biasing member 150 engages is provided at the rear end portion of the biasing member installation portion 126b.

The engaging portion 126d is connected to the rear end of the biasing member installation portion 126b, and has an engaging claw that engages with the locking projection 114 when the slide member 120 is combined with the slide support member 110. 126e is provided. By engaging the engaging claw 126e with the locking projection 114, the sliding member 120 can be prevented from moving further forward than the second position when the sliding member 120 slides forward.

The first rear lever guide 127 and the second rear lever guide 128 are provided at the rear end portion of the main body portion 121 so as to be separated from each other in the left-right direction. The movement of the lever 130 is regulated so that it does not. The first rear lever guide 127 is a substantially L-shaped member having a side wall 127a extending downward from the body portion 121 and a top surface 127b extending perpendicularly to the upper end of the side wall 127a. Similarly, the second rear lever guide 128 is a substantially L-shaped member having a side wall 128a and a top surface 128b. The length of the second rear lever guide 128 in the front-rear direction is shorter than the length of the first rear lever guide 127 in the front-rear direction so as not to hinder the rotation of the latch 140 .

The lever stop portion 129 is provided between the first rear lever guide 127 and the second rear lever guide 128, and when the lever 130 is in the first position, the lever stop portion 129 abuts against the first projection 133 and the lever 130 moves therefrom. The movement of the lever 130 is restrained so as not to move further rearward.

The lever 130 is made of resin, and has a lever body 131 and a grip portion 132 as shown in FIG.

The lever main body 131 is a plate-shaped member that is slidably supported with respect to the slide member 120 between a first position and a second position that is pulled out from the first position. Here, the first position of the lever 130 is the position when the lever main body 131 is on the rearmost side and the first projection 133 is in contact with the lever stopping portion 129 . The second position is a position when the lever main body 131 is pulled forward from the first position and cannot be pulled out any further.

Also, the lever body 131 has a first projection 133 and a second projection 134 on the surface facing the latch 140 . The second protrusion 134 is arranged at a position closer to the grip portion 132 than the first protrusion 133 is.

Further, the lever body 131 has an engaging hole 131a with which one end of the biasing member 150 (the end opposite to the end that engages with the biasing member engaging portion 126c) engages.

The grip part 132 is provided at the front end of the lever body 131 and moves integrally with the lever body 131 . The shape of the grip portion 132 is not particularly limited as long as it can be gripped by human hands.

Latch 140 is rotatably supported by slide member 120 . The latch 140 is made of resin, and has a latch body 141, a shaft portion 142, and a latch gear 143, as shown in FIG. The shaft portion 142 of the latch 140 is fitted into the through hole 121b of the slide member 120, so that the latch 140 can rotate about the shaft portion 142 as a rotation axis.

The latch body 141 has a first contact portion 141a and a second contact portion 141b. The first contact portion 141a is an outer side surface of the latch body 141 that can contact the first protrusion 133 when the lever body 131 is slid from the first position to the second position. The second contact portion 141b is a side surface of the latch body 141 that can contact the second projection 134 when the lever body 131 is slid from the second position to the first position.

The latch gear 143 has a plurality of gear teeth 143a that mesh with the gear teeth of the rack gear 113, and a third contact portion 143b. The latch gear 143 has a larger vertical thickness than the latch body 141 and protrudes downward (to the lever body 131 side) from the latch body 141 . The third contact portion 143b is a side surface of the latch gear 143 that contacts the side surface 131b of the lever body 131 when the latch 140 is at the unlocked position. The locked position is the position of the latch 140 when the latch gear 143 is engaged with the rack gear 113, and the unlocked position is the position of the latch 140 when the latch gear 143 is disengaged from the rack gear 113. is.

The latch 140 having the above configuration can be rotated from the locked position to the unlocked position by the biasing force from the first protrusion 133 to the first contact portion 141a. Also, the latch 140 can be rotated from the unlocked position to the locked position by the biasing force from the second projection 134 to the second contact portion 141b.

One end of the biasing member 150 engages with the engagement hole 131a of the lever body 131, and the other end engages with the biasing member engaging portion 126c of the slide member 120, and moves the lever body 131 toward the first position. Energize (see FIGS. 5-8 and 10 below). Examples of the biasing member 150 are not particularly limited as long as they have the above-described biasing function, and examples thereof include a tension coil spring, a leaf spring, a torsion bar, and rubber. FIG. 4 and the like show an example in which the biasing member 150 is an extension coil spring.

The biasing member 150 generates a predetermined initial load when the lever 130 is in the first position. Further, as the grip portion 132 is grasped and the lever 130 is pulled out from the first position, the load on the biasing member 150 increases, and the load is maximized when the lever 130 is at the second position. When the grip portion 132 is released, the restoring force of the tension coil spring urges the lever body 131 toward the first position, so the lever 130 returns to the first position.

Next, the operation of the slide mechanism 100 configured as above will be described.
First, FIG. 5(a) shows a state where the slide member 120 and the lever 130 are at the first position and the latch 140 is at the lock position. At this time, the rear end surface 122b of the slide restricting portion 122 of the slide member 120 is in contact with the restricting surface 116a of the slide restricting portion 116. As shown in FIG. Also, the first projection 133 of the lever 130 abuts against the lever stopping portion 129 of the slide member 120 and is separated from the first abutting portion 141 a of the latch 140 .

Also, the second projection 134 of the lever 130 is in contact with the second contact portion 141b of the latch 140 . Furthermore, the gear teeth 143a of the latch gear 143 of the latch 140 are in mesh with the gear teeth of the rack gear 113 of the slide support member 110, and the latch 140 is in the locked position. Therefore, the slide member 120 cannot be slid with respect to the slide support member 110 .

From the state shown in FIG. 5(a), when the grip portion 132 is grasped and the lever main body 131 is pulled out forward, the first projection 133 of the lever 130 moves to the lever stopping portion 129 as shown in FIG. 5(b). , and contacts the first contact portion 141 a of the latch 140 . Also, the second protrusion 134 is separated from the second contact portion 141 b of the latch 140 . At this time, the rotation of the latch 140 toward the unlocked position has not yet started, and the gear teeth 143 a of the latch gear 143 are still meshing with the gear teeth of the rack gear 113 . That is, latch 140 is in the locked position. The biasing member 150 is extended from the state shown in FIG. 5A, and the load on the biasing member 150 is increased by the amount of the lever main body 131 being pulled out.

When the lever body 131 is further pulled forward from the state shown in FIG. 5(b), a forward biasing force is applied from the first projection 133 to the first contact portion 141a as shown in FIG. 6(a). Granted. This biasing force causes the latch 140 to start rotating from the locked position to the unlocked position, and the gear teeth 143 a of the latch gear 143 are disengaged from the rack gear 113 . As the latch 140 rotates, the first projection 133 moves along the first contact portion 141a so as to slide on the first contact portion 141a. Note that the second protrusion 134 remains separated from the second contact portion 141b. Also, the biasing member 150 is further extended than in the state of FIG. 5(b), and the load generated by the biasing member 150 is even greater than in the state of FIG. 5(a).

From the state shown in FIG. 6(a), the lever body 131 is pulled out further forward, and when the lever body 131 reaches the second position, the first projection 133 moves toward the first contact as shown in FIG. 6(b). The urging force on the contact portion 141 a rotates the latch 140 to the unlocked position, and the latch gear 143 is completely unlocked from the rack gear 113 . As the latch 140 rotates, the first projection 133 slides on the first contact portion 141a and further moves along the first contact portion 141a from the state shown in FIG. 6(a).

Thus, the latch 140 rotates from the locked position to the unlocked position due to the biasing force from the first projection 133 to the first contact portion 141a.

Here, when the latch 140 is at the unlocked position, the third contact portion 143b of the latch 140 contacts the side surface 131b of the lever body 131, so that the latch 140 is restricted from rotating beyond the unlocked position. be done. Therefore, even if the biasing force is applied from the first protrusion 133 to the first contact portion 141a in an attempt to pull the lever body 131 further forward from the second position, the latch 140 does not rotate beyond the unlocked position. The first contact portion 141a restricts the movement of the first protrusion 133 in the pull-out direction of the lever 130. As shown in FIG. As a result, the lever 130 cannot be moved further from the second position in the pull-out direction.

Note that the second protrusion 134 remains separated from the second contact portion 141b. Further, the biasing member 150 is in the maximum extended state, and the load of the biasing member 150 is maximum when the lever 130 is at the second position.

Subsequently, from the state shown in FIG. 6(b), that is, the state in which the slide member 120 is at the first position, the lever 130 is at the second position, and the latch 140 is at the unlocked position, the ), the slide member 120 can be slid forward with respect to the slide support member 110 . As a result, although not shown, the movable frame 4 to which the slide member 120 is attached can be slid from the first position to the second position with respect to the fixed frame 3a. At this time, since the lever 130 is kept pulled out to the second position, the latch 140 is in the unlocked position while the slide member 120 is moving, and the biasing member 150 is in a state where the maximum load is applied. maintained.

When the slide member 120 reaches the forwardmost position, the engagement claw 126e of the engagement portion 126d engages with the locking projection 114 of the slide support member 110, and the movement of the slide member 120 is restricted. As a result, the slide member 120 cannot be pulled out further forward.

In the state shown in FIG. 7( a ), when the grip portion 132 is released and the force for pulling out the lever body 131 is removed, the load is no longer applied to the biasing member 150 . As a result, the biasing member 150 is contracted by, for example, the restoring force of the tension coil spring, and the lever body 131 is biased toward the first position. Due to the biasing force of the biasing member 150, the lever body 131 slides rearward as shown in FIG. 7B, and the second projection 134 contacts the second contact portion 141b again. At this time, while the first protrusion 133 is separated from the first contact portion 141a, the rotation of the latch 140 toward the locked position has not yet started, and the gear tooth 143a of the latch gear 143 remains disengaged from the rack gear 113. be. That is, latch 140 is in the unlocked position.

From the state shown in FIG. 7(b), when the lever main body 131 slides further rearward with respect to the slide member 120 due to the biasing force of the biasing member 150, the second protrusion 134 is moved as shown in FIG. 8(a). A rearward biasing force is applied to the second contact portion 141b. This urging force causes the latch 140 to start rotating from the unlocked position to the locked position, and the gear teeth 143 a of the latch gear 143 begin to mesh with the rack gear 113 . As the latch 140 rotates, the second protrusion 134 moves along the second contact portion 141b so as to slide on the second contact portion 141b. Note that the first protrusion 133 remains separated from the first contact portion 141a. Also, the biasing member 150 is further contracted than in the state of FIG. 7(b).

From the state shown in FIG. 8(a), the lever body 131 slides further rearward due to the biasing force of the biasing member 150, and when the lever body 131 reaches the first position, as shown in FIG. 8(b). , the biasing force from the second protrusion 134 to the second contact portion 141b rotates the latch 140 to the locked position, and the gear teeth 143a of the latch gear 143 are completely meshed with the rack gear 113. As shown in FIG. As the latch 140 rotates, the second projection 134 slides on the second contact portion 141b and further moves along the second contact portion 141b from the state shown in FIG. 8(a).

Thus, the latch 140 is configured to be rotatable from the unlocked position to the locked position by the biasing force from the second projection 134 to the second contact portion 141b.

Here, when the lever body 131 is at the first position and the latch 140 is at the locked position, the second protrusion 134 contacts the second contact portion 141b, thereby moving the latch 140 from the locked position. Regulate rotation. More specifically, the latch 140 is sandwiched between the rack gear 113 and the second projection 134 by the second projection 134 coming into contact with the second contact portion 141b. At this time, since the latch 140 is in the lock position and the position of the lever body 131 is fixed, the position of the second projection 134 is also fixed. Therefore, it is possible to prevent the latch 140 from rotating from the locked position to the unlocked position without receiving the biasing force from the first projection 133 to the first contact portion 141a.

Next, a method of assembling the seat 1 configured as described above will be described.
First, as shown in FIG. 9A, the shaft portion 142 of the latch 140 is inserted into the through hole 121b formed in the body portion 121 of the slide member 120, and the latch 140 is rotatably installed in the body portion 121. do.

Next, the lever 130 is inserted into the opening 121a of the front lever guide 125. As shown in FIG. At this time, the first projection 133 and the second projection 134 are aligned with the concave portion 124c and the concave portion 125b of the slide member 120 and passed through.

As shown in FIG. 9(b), the lever 130 is further inserted into the slide member 120. Then, as shown in FIG. Specifically, the lever main body 131 of the lever 130 is inserted into the lever insertion portion 126a of the center lever guide 126 and the rear lever guides (the first rear lever guide 127 and the second rear lever guide 128) in this order, and the first projection 133 is inserted. It is brought into contact with the lever stopping portion 129 . When the lever main body 131 is inserted until the first projection 133 abuts against the lever stopping portion 129, the grip portion 132 is stored in the open portion of the front plate 124, that is, the portion surrounded by the side portion 124a and the top portion 124b. be done. Further, when the latch body 141 is at a position further away from the lever body 131 than at the locked position, the lever body 131 is not supported by the slide member 120 and is free from the slide member 120 beyond the first position. is in a state of withdrawal to

Subsequently, as shown in FIG. 10(a), the latch 140 is rotated to the lock position. Thereby, the sliding movement of the lever 130 is restricted between the first position and the second position. Also, one end of the biasing member 150 is engaged with the engaging hole 131 a of the lever body 131 and the other end is engaged with the biasing member engaging portion 126 c of the slide member 120 .

Lever 130 , latch 140 and biasing member 150 are installed on slide member 120 as described above.

Further, as shown in FIG. 10(b), the slide member 120 having the lever 130, the latch 140 and the biasing member 150 is attached to the movable frame 4. As shown in FIG. When attaching the slide member 120 to the movable frame 4, the positions of the second fixing hole 41 of the movable frame 4 and the second fixing hole 122a of the slide member 120 are aligned, and the second fixing hole 122a and the second fixing hole 41 are aligned. The slide member 120 is fixed to the movable frame 4 by inserting a fastener (not shown) such as a screw through the opening.

Further, as shown in FIG. 11, a slide support member 110 is attached to the slide mechanism installation portion 62a of the pan frame 6 of the fixed frame 3a. When attaching the slide support member 110 to the fixed frame 3a, the positions of the first fixing holes 62b of the fixed frame 3a and the first fixing holes 119 of the slide support member 110 are aligned, and screws or the like are inserted into the first fixing holes 119. The slide support member 110 is fixed to the fixed frame 3a by inserting a non-removable fixture.

Next, the slide member 120 attached to the movable frame 4 is combined with the slide support member 110 attached to the fixed frame 3a. When assembling, the protruding portions 122c of the left and right slide restricting portions 122 are engaged with the protruding portions 117a of the guide grooves 117 with the lever 130 pulled out, that is, with the lever main body 131 at the second position. The slide member 120 can be combined with the slide support member 110 by sliding the slide restricting portion 122 with respect to the guide groove 117 while the lever main body 131 is held at the second position. When the slide member 120 is fully inserted into the slide support member 110 , the engagement claw 126 e of the engagement portion 126 d engages the locking projection 114 of the slide support member 110 .

Although the embodiments of the present invention have been described above, the present invention is not limited to the above embodiments and can be modified as appropriate.

Although the slide member 120 is attached to the movable frame 4 in the above embodiment, the slide member 120 may be integrally formed with the movable frame 4 (the slide support member 110 also serves as the movable frame 4).

In the above embodiment, the slide mechanism 100 is applied to the extension of the seat cushion frame of the seat 1, but the slide mechanism 100 may be applied to the extension of the seatback frame 2, and the headrest for the seatback is drawn upward. It may be applied to a slide mechanism for The slide mechanism 100 can also be applied to seats in ships and airplanes other than vehicles, and can also be applied to seats such as office chairs other than vehicles.

In the above embodiment, the lever body 131 is provided with the second protrusion 134. However, for example, if a biasing member that biases the latch 140 toward the locked position is provided, the second protrusion 134 is not provided. can also be

1 Seat 3a Fixed Frame 4 Movable Frame 100 Slide Mechanism 110 Slide Support Member 113 Rack Gear 120 Slide Member 126d Engagement Part 126e Engagement Claw 130 Lever 131b Side 132 Grip Part 133 First Projection 134 Second Projection 140 Latch 150 Biasing Member

Claims (4)

a fixed frame;
a movable frame slidable relative to the fixed frame;
a slide support member attached to the fixed frame and having a rack gear;
a slide member attached to the movable frame or configured integrally with the movable frame and slidably supported by the slide support member;
a lever body slidably supported with respect to the slide member between a first position and a second position pulled out from the first position; and a grip part that moves integrally with the lever body. a lever having
a latch rotatably supported by the slide member;
The lever body has a first projection on a surface facing the latch, and a second projection arranged at a position closer to the grip than the first projection,
The latch includes a latch gear meshing with the rack gear, a first contact portion capable of coming into contact with the first projection when the lever body is slidably moved from the first position to the second position, and the lever body. a second contact portion capable of coming into contact with the second projection when slidably moved from the second position to the first position;
When the lever body moves from the second position to the first position, the latch is moved to the unlocked position where the latch gear is disengaged from the rack gear by the biasing force of the second projection to the second contact portion. to a locking position where the latch gear meshes with the rack gear, and in a state in which the lever body is at the first position, the second projection and the rack gear move the latch in a direction perpendicular to the slide movement direction of the lever body. sandwiching the latch to restrict the rotation from the lock position,
When the lever body moves from the first position to the second position, the second projection is retracted from the second contact portion, and the latch is moved from the first projection to the first contact portion. A seat characterized by being rotated from the locked position to the unlocked position by an urging force. The latch further has a third contact portion that contacts the side surface of the lever body in the unlocked position,
The third contact portion and the side surface of the lever body are brought into contact with each other, and rotation of the latch due to the biasing force from the first projection to the first contact portion is restricted, thereby the first contact 2. The seat according to claim 1 , wherein a portion restricts the movement of said first projection in the pull-out direction of said lever. 2. A biasing member having one end engaged with said lever body and the other end engaged with said slide member for biasing said lever body toward said first position, further comprising a biasing member. Or a sheet according to claim 2 . A slide mechanism for slidably combining a fixed frame and a movable frame of a seat,
a slide support member attached to the fixed frame and having a rack gear;
a slide member attached to the movable frame and slidably supported by the slide support member;
a lever body slidably supported with respect to the slide member between a first position and a second position pulled out from the first position; and a grip part that moves integrally with the lever body. a lever having
a latch rotatably supported by the slide member;
The lever body has a first projection on a surface facing the latch, and a second projection arranged at a position closer to the grip than the first projection,
The latch includes a latch gear meshing with the rack gear, a first contact portion capable of coming into contact with the first projection when the lever body is slidably moved from the first position to the second position, and the lever body. a second contact portion capable of coming into contact with the second projection when slidably moved from the second position to the first position;
When the lever body moves from the second position to the first position, the latch is moved to the unlocked position where the latch gear is disengaged from the rack gear by the biasing force of the second projection to the second contact portion. to a locking position where the latch gear meshes with the rack gear, and in a state in which the lever body is at the first position, the second projection and the rack gear move the latch in a direction perpendicular to the slide movement direction of the lever body. sandwiching the latch to restrict the rotation from the lock position,
When the lever body moves from the first position to the second position, the second projection is retracted from the second contact portion, and the latch moves from the first projection to the first contact portion. A slide mechanism that rotates from the locked position to the unlocked position by an urging force.

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