JP2520670Y2 - Sliding door check mechanism - Google Patents

Description

DETAILED DESCRIPTION OF THE INVENTION [Industrial field of application] The present invention relates to a check mechanism for a sliding door of, for example, a van type automobile.

[Background of the invention]

As shown in FIG. 5, in a van-type automobile (1), a slide door (2) is slidably supported at an upper portion by an upper guide rail (3) arranged inside an upper edge of a vehicle body, and an intermediate portion is It is slidably supported by an intermediate guide rail (4) arranged on the outer surface of the vehicle body. Then, in order to stabilize the slide door (2) in the fully opened state, it is necessary to apply a check force when the sliding door (2) is closed from the fully opened state.

[Conventional technology]

Conventionally, as shown in FIGS. 6 and 7, there is a hole (33) A near the rear end of the outer wall (31) A of the upper guide rail (3) A.
And an end of an elastic plate (34) A formed by bending a protrusion (35) A protruding inside the hole (33) A on the outside of the outer wall (31) A by welding (36) A or the like. A locking check mechanism was provided.

In the check mechanism, the guide rail (3) A
Between the outer wall (31) A and the inner wall (32) A of the slide door (2) A, the arm (21) A inserted from the front of the upper edge into the dovetail grooves (37) A, (38) A. The horizontal roller (22) A is rotatably supported by the shaft (23) A and is guided by the arm (21) A, and is rotatably supported by the arm (21) A through the shaft (23) A. The vertical roller (24) A is in contact with the lower surface of the guide rail (3) A. As the slide door (2) A opens and closes, the horizontal roller (22) A
A check force is applied when the person gets over the protrusion (35) A of the elastic plate (34) A.

[Problems to be solved by the device]

In the above conventional configuration, the check force cannot be adjusted by the opening direction and the closing direction of the slide door (2) A, and if the check force is increased to stabilize the slide door in the fully opened state, It requires a large amount of force to fully open, the elastic plate material is prone to deterioration, it is difficult to obtain a permanently stable check force, and it is difficult to freely tune the check force. was there.

[Means for solving the problem]

As a means for solving the above conventional problems, the present invention provides a hole (33) in a side wall (31) of a guide rail (3) of a roller (22) of a slide door (2), and the hole (33).
A cover (5) is attached from the outer side of the guide rail (3), and an elastic plate (34) is formed in the cover (5) by bending a protrusion (35) protruding inside the hole (33). The cover (5) and the side wall (31) of the guide rail (3) are widely closed in the opening direction of the slide door (2). The check mechanism of the slide door (2) narrowed in the direction and the guide rail (3) side wall (31) of the slide door (2) are provided with a hole (33), and the slide door (3) is provided outside the hole (33). An elastic rod (61) whose end in the closing direction of 2) serves as a fulcrum (62) is passed over, and a check piece (6) protruding to the inside of the hole (33) to the elastic rod (61). The present invention provides a check mechanism of a slide door (2) to which is attached slidably.

[Action]

According to the first aspect of the invention, when the slide door (2) is closed from the fully opened state, the roller (22) projects into the hole (33) of the side wall (31) of the guide rail (3) and the elastic plate (34). (3) is pushed to slide the elastic plate (34) in the closing direction. The gap (52) between the cover (5) attached to the outside of the hole (33) of the guide rail (3) and the side wall (31) of the guide rail (3) is the closing direction of the slide door (2). Since it is narrower, the amount of protrusion of the protrusion (35) of the elastic plate (34) from the hole (33) is increased, and the protrusion (35) is inserted into the hole of the guide rail (3). Push in the part (33) to deform it, and
When 2) gets over, the amount of deformation of the protrusion (35) becomes large and the check force becomes large. On the contrary, when the slide door (2) is closed, the roller (22) pushes the protrusion (35) of the elastic plate (34) to slide the elastic plate (34) in the opening direction. The cover (5) and the guide rail (3)
Since the gap (51) between the side wall (31) and the side wall (31) is wide in the opening direction of the slide door (2), the protrusion amount of the protrusion (35) from the hole (33) is small, and the protrusion (35) is small. When the roller (22) pushes and deforms the portion (35), the amount of deformation becomes small and the check force becomes small.

According to the second aspect of the invention, when the slide door (2) is closed from the fully opened state, the roller (22) projects inside the hole (33) of the outer wall (31) of the guide rail (3) (a check piece ( 6) Push and slide along the elastic rod (61) in the closing direction. Since the end of the elastic rod (61) in the closing direction is the fulcrum (62), when the elastic rod (61) is bent by pushing the tick piece (6), the tic piece (6) is closed. That is, the closer to the fulcrum (62), the greater the force required to bend the elastic rod (61). Therefore, when the sliding door (2) is closed, the tic piece (6) is pushed by the roller (22) and slides in the closing direction as described above, and is in a position near the fulcrum (62) of the elastic rod (61). Therefore, when the roller (22) pushes the tic piece (6) and gets over the tic piece (6), a large check force acts. On the contrary, when the slide door (2) is opened, the roller (22) slides the tic piece (6) in the opening direction, that is, in the direction away from the fulcrum (62) of the elastic rod (61). Since (6) is located far from the fulcrum (62), the force required to bend the elastic rod (61) through the tic piece (6) becomes small, and the check force becomes small.

[Effect of device]

Therefore, in the present invention, since the check force when opening the slide door is small, the opening operation of the slide door can be performed smoothly, and the great check force works when closing the slide door, so that the slide door is stable in the fully opened state. In addition, since a large external force is applied to the elastic plate and the elastic rod only when the sliding door is closed, the deterioration of the elastic plate and the elastic rod is slow to progress and a stable and stable check force can be obtained. Can be performed arbitrarily.

〔Example〕

1 to 3 show an embodiment according to the first claim. In the figure, an arm (21) is extended from the upper edge of the slide door (2), and a horizontal roller (2) is attached to the arm (21) via a shaft (23) as in the conventional example shown in FIG.
2) and a vertical roller (23) not shown are supported by the horizontal roller (22) between the outer wall (31) and the inner wall (32) of the upper guide rail (3). ), (38) are held and guided. A laterally long hole (33) is provided near the rear end of the outer wall (31) of the guide rail (3), and the hole (33) is covered outside the outer wall (31). A cover (5) is attached, and an outer surface (51) of the cover (5) is closed in a direction of closing a gap (52) between the cover (5) and an outer wall (31) of the guide rail (3). Is inclined so that the width W ₁ thereof is smaller than the width W _{2 in the} opening direction. An elastic plate (3) having a protrusion (35) formed at the center is provided in the gap (52) between the outer wall (31) of the guide rail (3) and the cover (5).
4) is slidably inserted back and forth, and the projection (35) of the elastic plate (34) projects inward from the hole (33) of the guide rail (3).

In the above configuration, when the slide door (2) is slid in the closing direction as shown by the arrow in FIG. 2 from the completely opened state, the horizontal roller (22) pushes the elastic plate (34) in the closing direction. To slide the slide door (2) in the closing direction, the horizontal roller (22) of the slide door (2) is moved by the elastic plate (34).
It is necessary to push over the projection (35) of the guide rail (3) through the hole (33) of the guide rail (3) to get over it. On the contrary, when the slide door (2) is opened, the horizontal roller (22) of the slide door (2) pushes the elastic plate (34) in the opening direction to slide it as shown by the arrow in FIG. The horizontal roller (22) is the protrusion (35) of the elastic plate (34).
Is pushed in from the hole (33) of the guide rail (3) and deformed to get over, so that the slide door (2) is completely opened. In the sliding of the sliding door (2) in the closing direction and the opening direction, the width of the gap (52) between the cover (5) and the outer wall (31) of the guide rail (3) in the closing direction as described above. Since W ₁ is smaller than the width W _{2 in the} opening direction, when the elastic plate (34) slides in the closing direction as shown in FIG. 2, the protrusion (35) of the elastic plate (34)
When the elastic plate (34) slides in the opening direction as shown in FIG. 3, the protrusion amount of the guide rail (3) protruding from the hole (33) of the outer wall (31) becomes large. The amount of protrusion of the protrusion (35) from the hole (33) is reduced. Therefore, when the slide door (2) slides in the closing direction, the horizontal roller (22) pushes and deforms the protrusion (35) of the elastic plate (34) to increase the deformation amount, and the slide door (2) opens in the opening direction. When it slides to the side, the projection (35) of the elastic plate (34) is moved by the horizontal roller (22).
The amount of deformation that pushes and deforms is small. Therefore, a large check force is generated when the slide door (2) is closed from the completely open state, and a small check force is generated when the slide door (2) is opened. The check force can be tuned by the elasticity of the elastic plate (34) and the height and shape of the protrusion (35).

FIG. 4 shows an embodiment according to the second claim.
In the figure, a wedge surface (63) for the opening direction is provided in the hole (33) of the outer wall (31) of the guide rail (3) that guides the horizontal roller (22) of the arm (21) of the slide door (2). The check piece (6) that it has is exposed, the check piece (6) is slidably attached to the elastic rod (61), and the elastic rod (61) is the end of the sliding door (2) in the closing direction. The portion serves as a fulcrum (62), and the check piece (6) is biased in the opening direction by a spring (64).
A cover (7) is attached to the outside of the outer wall (31) of the guide rail (3) so as to cover the check piece (6) and the elastic rod (61).

In the above structure, when the slide door (2) slides in the opening direction, the check piece (6) pushed to the end in the opening direction by the spring (64) is pushed through the hole (33) and gets over. When the slide door (2) slides from the fully opened state to the closing direction, the horizontal roller (22) pushes the check piece (6) against the elasticity of the spring (64) to slide the check piece (6) in the closing direction, and further the check piece (6). Push 6) into the hole (33) and climb over. When the check piece (6) is pushed into the hole (33) by the horizontal roller (22), the elastic rod (61) bends, but as described above, the slide door (2).
Since the check piece (6) is located on the elastic rod (61) far from the fulcrum (62) when opening, the force required to bend the elastic rod (61) through the check piece (6) is small, Moreover, the wedge effect of the wedge surface (63) of the check piece (6) makes it easier for the horizontal roller (22) to push the check piece (6) over and over it. On the other hand, when the slide door (2) slides in the closing direction from the fully opened state, the check piece (6) is located on the elastic rod (61) close to the fulcrum (62). The force deflecting through the check piece (6) is large, and thus the check force is large. The check force can be tuned by the elasticity and the length of the elastic rod (61).

[Brief description of drawings]

1 to 3 show an embodiment according to the first claim, and FIG. 1 is a sectional view corresponding to a portion SA-SA in FIG. 6 in a fully opened state of a slide door. 2 is a sectional view corresponding to the SA-SA portion when the sliding door slides in the closing direction, FIG. 3 is a sectional view corresponding to the SA-SA portion when the sliding door slides in the opening direction, and FIG. Is a cross-sectional view corresponding to the SA-SA portion showing an embodiment according to the second claim, FIG. 5 is a side view of an automobile body, and FIGS. 6 and 7 are conventional examples. FIG. 6 is a perspective view of the upper guide rail, and FIG. 7 is a partial sectional view taken along the line SA-SA in FIG. In the figure, (2) …… Sliding door, (22) …… Roller,
(3) …… Guide rail, (31) …… Outside wall, (33)…
… Hole, (34) …… elastic plate, (35) …… projection,
(5) …… Cover, (52) …… Gap, (6) …… Check piece, (61) …… Elastic rod, (62) …… Support point

Claims (2)

(57) [Scope of utility model registration request] 1. An elasticity in which a hole is formed in a side wall of a guide rail of a roller of a slide door, a cover is attached from the outside of the hole, and a protrusion protruding inside the hole is bent and formed. A slide door having a structure in which a plate is slidably accommodated along a guide rail, wherein a gap between the cover and the guide rail side wall is wide in the opening direction of the slide door and narrow in the closing direction. Check mechanism. 2. A hole is formed in a side wall of a guide rail of a slide door, and an elastic rod whose end point in the closing direction of the slide door serves as a fulcrum is provided outside the hole, and the elastic rod is provided with the hole. Checking mechanism for slide doors, characterized in that a check piece protruding inside the hole is slidably attached.