KR20180048388A - Sliding door stopping device - Google Patents

Abstract

The present invention provides a sliding door stopping device which can stably set a magnitude of a release force. The sliding door stopping device (10) is attached to one among a door frame (2) and a sliding door (4) attached to the door frame (2) to stop the sliding door (4) on an arbitrary position with respect to the door frame (2). A stopper member (16) can be pivotally moved around a pivotal motion center axis (C2) with respect to a support member (12), and a position of the pivotal motion center axis (C2) is arranged to be changed. The stopper member (16) moves between a stopping position to stop a pivotal motion to allow a friction stopping matching unit (26) to pass between the pivotal motion center axis (C2) and an upper surface (3a) of a rail (3), and a release position where the pivotal motion center axis (C2) is farther away from the upper surface (3a) of the rail (3) than the stopping position to allow a pivotal motion. The stopper member (16) is pressed towards the stopping position by a spring (18).

Description

 [0001] SLIDING DOOR STOPPING DEVICE [0002]

The present invention relates to a sliding shutoff device for stopping (stopping) a sliding door at an arbitrary position with respect to a door frame.

In the sliding mechanism in which the sliding door slides with respect to the door frame, particularly, in the case of having the urging means for urging the sliding door in the closing direction, the sliding door stop device (free Stop device) may be installed. As shown in Patent Document 1, for example, a sliding stopper has a stopper member to which a pivotal motion is freely attached to a support member fixed to a sliding door. The stopper member is formed of an elastic material having a large coefficient of friction such as rubber at its tip, and the elastic portion at the tip end is disposed so as to slide on a rail surface on which an arc of the sliding door travels. When the sliding door is moving in the opening direction, the elastic portion at the tip end of the stopper member is positioned rearward (closing direction) with respect to the pivotal movement center axis of the stopper member and slidingly moves on the rail without being subjected to large frictional force. On the other hand, when the sliding door moving in the opening direction changes its moving direction in the closing direction, the position of the elastic part with respect to the pivotal moving center of the stopper member becomes forward in the moving direction of the sliding door, It is in a state of being held between the rail by the frictional force. As a result, the resilient portion is pressed against the rail by the greater force, and the frictional force received from the resilient portion rail also becomes larger. By this large frictional force, the sliding door is in a stopped state in which movement in the closing direction is blocked. When a force in a closing direction of a certain size or more is applied to the sliding door in this stopped state, the resilient portion of the stopper member is elastically deformed by receiving a larger force from the rail and the length from the pivotally moving center axis to the contact point with the rail is shortened The stopper member pivotally moves to a position where the resilient portion is located rearward (in the opening direction) relative to the pivotal motion center of the elastic member while passing the elastic portion between the pivotal movement center axis and the rail. As a result, the frictional force for stopping the sliding door is released and the stationary state is released, and the sliding door can freely move toward the closing direction.

Japanese Patent No. 2683321

In the above-described sliding door stop device, the size of the sliding door force (hereinafter referred to as the releasing force) required when releasing the stopping state of the sliding door and moving the sliding door in the closing direction causes the stopper member to pivot And the amount of elastic deformation of the elastic portion when pivoting is made to pass between the motion central axis and the rail. That is, if the distance between the pivotal movement center axis and the rail is set short, the necessary amount of elastic deformation becomes large, and the required release force also becomes large. Conversely, if the distance between the pivot center of motion and the rail is set long, the amount of necessary elastic deformation becomes small, and the releasing force also becomes small. If the releasing force is too large, the sliding door may be lifted from the rail by the stopper member before the elastic member is elastically deformed by a required amount. On the contrary, if the release force is too small, the stopping state is released only by the force of the urging means pulling the sliding door to the closed position, and the sliding door can not be stopped at an arbitrary opening position.

The material used for the elastic portion is selected from those satisfying the conditions as the stopper member such as the size of the friction coefficient, the durability against abrasion, and the rigidity required to receive the frictional force necessary for stopping the sliding door. It is difficult to adopt a material which becomes a relatively hard material and can obtain a large amount of elastic deformation. Therefore, the amount of elastic deformation of the elastic portion for generating a releasing force of an appropriate size can not be reduced to as small as several millimeters. Therefore, even if the mounting position of the sliding stopper is slightly shifted, the magnitude of the displacement of the actual elastic deformation amount from the design value of the elastic deformation amount becomes large as a ratio to the design value, and accordingly, the releasing force is largely changed. Further, even if an appropriate releasing force can be set at the time of initial installation, the elastic portion gradually wears by repeating opening and closing of the sliding door, and the amount of elastic deformation becomes smaller as the wear progresses, so that the releasing force gradually decreases. Further, when the elasticity of the elastic part of the elastic part deteriorates for a long period of time and the elastic modulus thereof changes, the magnitude of the release force also changes. That is, there is a problem in that it is difficult to stably set the releasing force in the conventional sliding shutoff device.

SUMMARY OF THE INVENTION Accordingly, the present invention has been made in view of the above problems, and an object thereof is to provide a sliding shutoff device capable of more stably setting the release force.

That is,

A sliding shut-off device attached to one of a door frame and a sliding door attached to the door frame, for stopping the sliding door at an arbitrary position with respect to the door frame,

A support member fixed to one of the door frame and the sliding door,

A pivotally movable center axis of the pivot-type movable center axis relative to the support member, the pivotally movable center axis axis being displaceable with respect to the pivot axis of the support member, and extending in the opening and closing direction of the sliding door on the other of the door frame and the sliding door A stopper member having a friction engagement portion frictionally engaged with the disposed sliding movement surface,

A spring for biasing the stopper member

And,

Wherein the stopper member is displaceable between a locking position and a locking release position in which the pivotal movement center axis is farther from the sliding movement surface than in the locking position, The friction engagement portion is prevented from pivotally moving to pass the friction engagement portion between the pivotal movement center axis and the sliding movement surface, and at the engagement release position, The pivoting movement is allowed to pass between the sliding movement surfaces,

And the spring urges the stopper member toward the engagement position.

In the sliding shutoff apparatus, the stopper member is disposed so as to be displaced so that the position of the pivotal movement center axis thereof is away from the sliding movement surface, and is urged by a spring toward a close engagement position by the sliding movement surface. Therefore, when the stopper member stops the sliding shuttle between the sliding movement surface and the stopper member, the stopper member pivotally moves so as to allow the friction engagement portion to pass between the pivotal movement center axis and the rail, The releasing force to the sliding door, which is necessary for the sliding operation, is determined mainly by the urging force of the spring. That is, in the sliding shutoff apparatus, the releasing force does not depend on the magnitude of the elastic deformation of the friction engagement portion but mainly depends on the magnitude of the urging force of the spring. The spring is easier to obtain a larger displacement amount than the elastic material as the friction engagement portion. Therefore, the sliding shutoff device in which the release force is set by the biasing force of the spring can reduce the change in the magnitude of the release force due to the displacement of the attachment position and the wear of the friction engagement portion, It becomes possible to stably set the temperature. Further, since it is not necessary to constitute the friction engagement portion with a material that is liable to be elastically deformed, the range of selection of the material of the friction engagement portion is broadened, and conventionally, Materials and the like can be selected.

Preferably,

Further comprising a link member pivotably attached to the support member,

Wherein the stopper member is pivotally attached to the link member at a position distant from the pivotally moving center axis of the link member, and the link member is pivotally moved so that the stopper member is engaged with the support member And the engagement release position.

More preferably, the spring indirectly biases the stopper member through the link member.

So that the spring biases the link member in a position away from the pivotally moving center axis of the link member with respect to the pivotally moving center axis of the stopper member.

With this configuration, the force applied to the stopper member by the urging force of the spring is increased by the principle of the lever, so that even if a spring having a relatively weak elastic force is used, it is possible to apply a large force to the stopper member.

Preferably, an urging force adjusting member, which is engaged with one end of the spring and adjusts the amount of compression of the spring, may be further provided.

By providing such an urging force adjusting member, it is possible to adjust the urging force of the spring after attaching the sliding stopper, and it is possible to facilitate the unevenness of the releasing force due to the error of the attachment position of the sliding shutoff device or the dimensional error of each member To be corrected. It is also possible to change the release force later depending on the use situation.

And a biasing member for biasing the stopper member in the engagement position in the pivoting motion direction about the axis of the pivotal movement center of the stopper member, wherein the biasing member biases the stopper member The friction engagement portion may be pressed against the sliding movement surface.

With this configuration, it is possible to further increase the frictional resistance against the sliding movement surface of the friction engagement portion.

At this time,

Wherein the biasing member has a first portion located on one side of the stopper member in the opening and closing direction of the sliding door and a second portion located on the other side,

When the frictional engagement portion is engaged with the sliding movement surface at the side of the closing direction of the sliding door with respect to the pivotal movement center axis of the stopper member when the stopper member is in the engagement position, And the frictional engagement portion is engaged with the sliding movement surface on the side of the opening direction of the sliding door with respect to the pivotal movement center axis of the stopper member, The second portion biases the stopper member to press the friction engagement portion on the sliding movement surface.

Also

Wherein the sliding motion surface has an arc-shaped cross-sectional shape,

The friction engaging portion has a concave portion curved to conform to the transverse sectional shape of the sliding movement surface so that the concave portion contacts the sliding movement surface when the stopper member is at the engaging position.

With this configuration, the sliding engagement portion can be brought into contact with the sliding movement surface having the arc-shaped cross-sectional shape in a larger area. As a result, a greater frictional resistance is generated, and it is possible to more reliably stop the sliding door.

DESCRIPTION OF THE PREFERRED EMBODIMENTS Hereinafter, embodiments of a sliding shutoff apparatus according to the present invention will be described with reference to the accompanying drawings.

According to the present invention, there is provided a sliding shutoff device capable of more stably setting the size of the release force.

Brief Description of the Drawings Fig. 1 is a view schematically showing a sliding mechanism provided with a sliding shutoff device according to an embodiment of the present invention.
Fig. 2 is a cross-sectional view taken along the line II-II in Fig. 1, and shows the front view of the sliding shutoff device according to the first embodiment of the present invention.
3 is a cross-sectional view of the sliding shutoff device on the line III-III in Fig.
Fig. 4 is a first view showing an operating state of the sliding shutoff apparatus, showing a state when the sliding door is moving in the opening direction. Fig.
Fig. 5 is a second diagram showing an operating state of the sliding shutoff apparatus, showing a state when the sliding door is in a stopped state. Fig.
Fig. 6 is a third view showing the operation state of the sliding shutoff device, showing the state when the stopper member is in the disengagement position. Fig.
Fig. 7 is a view showing the operation state of the sliding shutoff apparatus and showing the state when the shutoff state is released. Fig.
Fig. 8 is a cross-sectional view taken along the line II-II in Fig. 1, and shows the front view of the sliding shutoff device according to the second embodiment of the present invention.
Fig. 9 is a sectional view of the sliding shutoff device on line IX-IX in Fig. 8; Fig.
10 is a view schematically showing another sliding mechanism provided with a sliding shutoff device.
11 is a view schematically showing another sliding mechanism provided with a sliding shutoff device.

The sliding door mechanism 1 in which the sliding shutters 10 and 60 according to the embodiment of the present invention are installed is mounted on the rail 3 provided on the door frame 2 as shown in Fig. The slide doors 4 are slid with respect to the door frame 2 so as to open and close by allowing the respective carriages 6a and 6b of the two hanger members 5a and 5b installed on the door frame 2 to run. The door frame 2 is attached with a draw-in spring device 7 and the tip end of the wire 7a extending from the draw-in spring device 7 is connected to the hanger 5a on the side of the door leading end 4a of the sliding door 4 Respectively. Since the draw-in spring device 7 is configured to draw the wire 7a by the built-in spring mechanism, the sliding door 4 always exerts a force in the closing direction. Therefore, when the sliding door 4 is released from the sliding door 4 while the sliding door 4 is opened, the sliding door 4 is pulled toward the closing direction by the action of the drag-in spring device 7. The door frame 2 is further provided with a braking rack 8 and a sliding device 4 is provided with a braking device 9 to be engaged with the braking rack 8. The braking device 9 is a kind of damper using a fluid friction resistance and is engaged with the braking rack 8 on the side of the door frame 2 when the sliding door 4 tries to close to move the sliding door 4 in the closing direction So that the sliding door 4 is slowly closed. 1, the sliding shutters 10 and 60 according to the present invention are fixed to the hanger 5b on the door rear portion 4b side of the sliding door 4. In the sliding door mechanism 1 shown in Fig. The sliding shutters 10 and 60 temporarily stop the sliding door 4 when the sliding door 4 is released from the sliding door 4 when the sliding door 4 is opened.

The sliding door stopper 10 according to the first embodiment of the present invention is fixed to the sliding door 4 through the hanger 5b on the door rear portion 4b side of the sliding door 4 as shown in Figs. A link member 14 pivotally attached to the support member 12 and a stopper member 16 pivotally attached at an intermediate position between the link member 14 And a spring 18 for biasing the tip end 14a of the link member 14 downward. The link member 14 is rotatably attached to the support member 12 by a rotation shaft 20 fixed to the support member 12. [ The stopper member 16 is provided on the rotary shaft 22 fixed to the link member 14 at a position apart from the pivotal movement center axis C1 of the link member 14 and made of a material having a low frictional resistance such as PTFE resin Is pivotally attached to the link member (14) through a sliding motion ring (24). A frictional engagement portion 26 made of a rubber material having a relatively large frictional resistance is provided at the distal end of the stopper member 16. The lower end 18a of the spring 18 is held in a spring seat 28 fixed to the tip end 14a of the link member 14 and the upper end 18b of the spring 18 is held in the urging force adjusting member 30, Respectively. The urging force adjusting member 30 has an adjusting screw 32 screwed to the top wall portion 12a of the supporting member 12 and an adjusting screw 32 which holds the upper end 18b of the spring 18, And a spring guide 34 which is pressed against the upper end 18b of the spring 18 by a lower end 32a of the spring 32. By rotating the adjustment screw 32 relative to the support member 12, To adjust the compression amount of the spring 18. The position at which the spring 18 biases the link member 14 is located at a distance from the pivotal movement center axis C1 of the link member 14 to the pivotal movement center axis C2 of the stopper member 16 . As a result, the urging force of the spring 18 is increased and added to the stopper member 16. A support pin 36 fixed to the support member 12 is provided below the tip end 14a of the link member 14. The link member 14 abuts against the support pin 36, As shown in Fig.

1, when the sliding shutoff device 10 is attached to the hanger 5b on the door rear portion 4b side of the sliding door 4, the frictional engagement portion 26 of the stopper member 16 Is in contact with the upper surface 3a of the rail 3 on which the carriage 6b of the hanger 5b rolls. 4, when the sliding door 4 is moved in the opening direction (right direction in FIG. 4) in this state, the frictional engagement portion 26 of the stopper member 16 is moved in the opening / closing direction of the sliding door 4 And the upper surface 3a of the rail 3 arranged to extend extends as a sliding movement surface and slides on the upper surface 3a. At this time, the frictional force received by the frictional engagement portion 26 from the rail 3 is transmitted to the stopper member 16 in the direction in which the stopper member 16 is pivoted by clockwise rotation, that is, in the direction of moving the frictional engagement portion 26 upward The load applied to the rail 3 by the friction engagement portion 26 is only small due to the weight of the stopper member 16 and is very small. The frictional force between the friction engagement portion 26 and the rail 3 is also small. Therefore, when the sliding door 4 is moved in the opening direction in the state of Fig. 4, the sliding door stopper 10 hardly generates a resistance force.

5, when the sliding direction of the sliding door 4 is changed from the opening direction (the right direction as viewed in the figure) to the closing direction (the left direction as viewed in the drawing), the frictional engagement portion 26 is moved from the rail 3 The frictional force received is the direction in which the stopper member 16 is pivotally moved counterclockwise, that is, the direction in which the frictional engagement portion 26 is pressed against the rail 3. [ The distance from the pivotally moving center axis C2 of the stopper member 16 to the upper surface 3a of the rail 3 is greater than the distance from the pivotally moving center axis C2 to the frictional engagement portion 26) to the contact point (P) with the rail (3). When the stopper member 16 is in the engagement position as described above, the friction engagement portion 26 is moved between the pivotal movement center axis C2 and the upper surface 3a of the rail 3, Pivotal movement is prevented by clockwise rotation. The stopper member 16 to be pivoted by the counterclockwise rotation is in a state in which the stopper member 16 is caught between the link member 14 and the rail 3 and the friction engagement portion 26 is in contact with the rail 3 The load increases according to the force that the sliding door 4 is moved in the closing direction. As a result, the frictional force between the frictional engagement portion 26 and the rail 3 is increased, and the sliding shut-off device 10 is prevented from moving in the closing direction with respect to the rail 3. [ That is, the sliding door 4 to which the sliding shutoff device 10 is attached is in a stopped state in which it is prevented from moving in the closing direction.

When a force in the closing direction is applied to the sliding door 4 from the state of Fig. 5, a larger counterclockwise force acts on the stopper member 16 as seen in the figure. The force for pivotally moving the stopper member 16 is applied to the link member 14 via the rotation shaft 22. [ In this case, the link member 14 tries to pivot upward by force received from the stopper member 16. When the force applied to the link member 14 exceeds the urging force of the spring 18 as the force to the sliding door exceeds a predetermined magnitude, the link member 14 compresses the spring 18 Bore clockwise rotation) begins to pivot. The distance from the pivotally moving center axis C2 of the stopper member 16 to the upper surface 3a of the rail 3 is smaller than the distance between the pivotal movement center axis C2 of the stopper member 16 and the upper surface 3a of the rail 3, Is equal to the length from the central axis C2 to the contact point P with the rail 3 of the frictional engagement portion 26 and the stopper member 16 has the frictional engagement portion 26 as the pivotal movement center It becomes possible to pivotally move counterclockwise as viewed in the drawing so as to pass between the axis C2 and the rail 3. [ When the sliding door 4 is further moved in the closing direction, the stopper member 16 further pivots counterclockwise so that the friction engagement portion 26 is pivoted about the pivotally moving center axis C2 (The right side in the figure) in the moving direction, and the position in the vertical direction is also returned to the latching position. In this state, the frictional force between the frictional engagement portion 26 and the rail 3 is reduced, as described above with reference to Fig. Therefore, the sliding shutoff device 10 does not generate a substantially resistive force, and the sliding door 4 is automatically moved to the closed position only by the pulling force in the closing direction by the draw-in spring device 7, and is closed.

6, the stopper member 16 is detached from the rail 3 as shown in Fig. 6 in the process from the stop state of Fig. 5 to the stop releasing state of Fig. 7 in the sliding shut- To the engagement release position, whereby the stop state can be released. The releasing force required for displacing the stopper member 16 to the releasing position is determined mainly depending on the magnitude of the urging force of the spring 18 urging the stopper member 16 through the link member 14 do. In general, the spring 18 is easier to obtain a larger displacement than an elastic material made of rubber or the like as the friction engagement portion 26. Therefore, the slide shutting device 10 can reduce the change of the release force due to the displacement of the attachment position and the abrasion of the friction engagement portion 26 as compared with the conventional one, and the release force can be set more stably do. Further, in the sliding shut-off device 10 of the present invention, since the frictional engagement portion 26 does not necessarily have to be elastically deformed by the releasing force, it is possible to adopt a material having higher rigidity than that of the conventional one, A thin structure can be formed. That is, the selection range of the material and structure of the friction engagement portion 26 is widened.

The sliding shutoff device 60 according to the second embodiment of the present invention shown in Figs. 8 and 9 is incorporated into the sliding door mechanism 1 as shown in Fig. 1, similarly to the sliding shutoff device 10 according to the first embodiment The sliding door 4 is stopped at an arbitrary position.

A recess 76a is formed in the frictional engagement portion 76 of the stopper member 66 of the sliding shutoff device 60 in question. The concave portion 76a is curved along the upper surface 3a of the rail 3 having an arc-shaped transverse sectional shape and the friction engagement portion 76 is formed so as to be in contact with the upper surface 3a of the rail 3 Thereby making contact with a large area. As a result, the frictional engagement portion 76 receives a greater frictional force from the rail 3 when pivotally moving from the engagement position to the engagement release position, and the sliding door 4 can be more reliably stopped.

The sliding shutoff device 60 further includes a leaf spring 88 fixed to the support member 62 as shown in Fig. The plate spring 88 has a central portion 88a fixed by a rivet 90 and a first portion 88b and a second portion 88c extending downward from both ends of the leaf spring 88 with the stopper member 66 sandwiched therebetween. ), And is generally U-shaped. The stopper member 66 is directed to the rear side (left as viewed in the drawing) with respect to the opening direction (right direction in the figure) of the sliding door 4 and the frictional engagement portion 76 is in contact with the stopper member 66 In the state in which the first portion 88b is engaged with the upper surface 3a of the rail 3 at the side closer to the closing direction (the left direction as viewed in the drawing) than the pivotally moving center axis C2 of the stopper member 66 , And the stopper member 66 is biased counterclockwise as viewed in the drawing toward the opening direction side. As a result, the concave portion 76a of the frictional engagement portion 76 is pressed against the rail 3. When the sliding door 4 is moved in the opening direction, the dust on the rail 3 is removed by the frictional engagement portion 76 pressed against the rail 3. Particularly, since the corner portion 76b on the outside of the concave portion 76a which is the front position in the moving direction comes into contact with the rail 3, the dust is effectively removed mainly from the corner portion 76b, and the sliding door 4 The dust is not adhered to the other surface of the friction engagement portion 76 that contacts the rail 3. When the sliding door 4 starts to move in the closing direction (left direction as viewed in the drawing), the frictional engagement portion 76 has already been pushed by the rail 3 with a certain amount of force, Is in a state in which it is difficult to slide on the rail 3. Therefore, the stopper member 66 is held between the rail 3 and the stopper member 66, so that the sliding door 4 can be stopped more quickly and reliably. When the sliding door 4 is pulled by a certain amount of force in the closing direction, the stopper member 66 pivots counterclockwise as viewed in the figure and is released from the stop state as in the first embodiment described above. The frictional engagement portion 76 abuts against the pivotal movement center axis C2 of the stopper member 66 in the opening direction (in the figure, in the figure) from the stopper member 66 toward the rear side The second portion 88c of the leaf spring 88 is in contact with the side surface 66b on the opposite side of the stopper member 66. When the leaf spring 88 is in the engaged state with the upper surface 3a of the rail 3, And the stopper member 66 is biased clockwise as viewed in the figure toward the side in the closing direction. As a result, the other recessed portion 76a of the friction engagement portion 76 is pressed against the rail 3. Therefore, even when the sliding door 4 is moved in the closing direction, the dust on the rail 3 is removed by the angular portion 76b of the recess 76a in the frictional engagement portion 76. Further, the leaf spring 88 may be fixed to another portion of the link member 64 or the like instead of the support member 62. It is also possible to use a different type of biasing member such as two separate springs instead of the plate spring 88 as shown in the drawing.

The sliding shutters 10 and 60 according to the present invention may be attached to the side of the door frame 2 as shown in Fig. 10, sliding movement rails 110 arranged so as to extend in the opening and closing direction of the sliding door 4 are provided between the two hanger units 105a and 105b provided on the sliding door 4, respectively. The frictional engagement portions 26 and 76 of the sliding shutters 10 and 60 slide on the upper surface 110a of the sliding rail 110 and engage and frictionally engage with the upper surface 110a of the sliding rail 110, 4 is stopped at an arbitrary position and the stop state is released.

The sliding shutters 10 and 60 according to the present invention may also be attached to the door front end 4a side of the sliding door 4 as shown in Fig. In the sliding mechanism 201 shown in Fig. 11, by attaching the sliding shutters 10 and 60 at such positions, the frictional engaging portions 26 and 76 of the rail 3 Is in a state accessible from the outside. When the sliding contact portion of the friction engagement portions 26 and 76 is contaminated with dust or oil or the like, a sufficient frictional force is not generated between the frictional engagement portions 26 and 76 and the rail 3, The frictional engagement portions 26 and 76 may slide against the rail 3 and the sliding door 4 may move in the closing direction. 1, the sliding shutters 10 and 60 are disposed on the door rear portion 4b side so that the frictional engagement portions 26 and 26 of the rail 3 can be freely rotated, 76 are located between the hanger 5a, 5b of the sliding door 4, particularly when the sliding door 4 is structured to enter the sliding door in the open position, And it is not easy to clean. On the other hand, if the sliding shutters 10 and 60 are arranged as shown in Fig. 11, the portion of the rail 3 which needs to be cleaned is not arranged in the sleeves, so that the cleaning of the portions can be facilitated.

The sliding shutoff apparatus according to the present invention is not limited to the above embodiment, and various modifications are possible. For example, the sliding shutoff device of the present invention may be attached so as to be fixed to one of the door frame 2 and the sliding door 4, and the attachment position may be a place other than the above-described embodiment. In the case where the sliding shutters 10 and 60 are attached to the sliding door 4 as shown in Figs. 1 and 11, when the sliding door 4 moves, the frictional engaging portions 26 and 76 slide The sliding movement surfaces of the hangers 5a and 5b may be located at positions other than the upper surface 3a of the rail 3 to which the rollers 6a and 6b of the hanger 5a and 5b are rotated to engage, Alternatively, a separate sliding rail may be provided, or a part of the door frame 2 may be used as a sliding movement surface. Also, in the case where the sliding shutoff device is attached to the side of the door frame 2 as shown in Fig. 10, another place may be used as the sliding movement face, for example, the upper face of the sliding door 4 is used as the sliding movement face. The support members 12 and 62 may be members common to other devices of the sliding door 4 or the door frame 2, for example, a member integral with the hanger. The stopper members 16 and 66 are formed by vertically forming guide grooves on the support members 12 and 62 without passing through the link members 14 and 64 so that the stopper members 16 and 66 are engaged with the engagement positions along the guide grooves It may be displaced between the release positions. And the spring 18 may be arranged to directly engage the stopper members 16 and 66. [ The urging force adjusting member 30 may not have a configuration using the adjusting screw 32 as described above or may be configured to adjust the amount of compression of the spring 18 when the stopper members 16 and 66 are in the releasing position It may be an apparatus that can be used. Also, the urging force adjusting member 30 is not necessarily required, and it is possible to eliminate the urging force that does not require fine adjustment of the releasing force.

One… Sliding mechanism
2… doorframe
3 ... rail
3a ... Top surface
4… Sliding door
5a, 5b ... hanger
6a, 6b ... Car
7 ... Inlet spring device
7a ... wire
8… Brake Rack
9 ... Braking device
10 ... Sliding stop device
12 ... Supporting member
12a ... [0040]
14 ... Link member
14a ... Tip
16 ... The stopper member
18 ... spring
18a ... lower
18b ... Top
20 ... (Of the link member)
22 ... (Of the stopper member)
24 ... Sliding motion ring
26 ... Friction engaging portion
28 ... Spring seat
30 ... An urging force adjusting member
32 ... Adjusting screw
32a ... lower
34 ... Spring guide
36 ... Support pin
60 ... Sliding stop device
62 ... Supporting member
64 ... Link member
66 ... The stopper member
66a, 66b ... side
76 ... Friction engaging portion
76a ... Concave portion
76b ... Each part
88 ... Leaf spring
88a ... Central part
88b ... The first part
88c ... The second part
90 ... Rivet
101 ... Sliding mechanism
105a, 105b ... hanger
110 ... Sliding motion rail
201 ... Sliding mechanism
C1 ... (Of the link member 14)
C2 ... (Of the stopper member 16)
P ... Contact point

Claims (8)

A sliding shut-off device attached to one of a door frame and a sliding door attached to the door frame, for stopping the sliding door at an arbitrary open position with respect to the door frame,
A support member fixed to one of the door frame and the sliding door,
A pivotally movable center axis of the pivot-type movable center axis relative to the support member, the pivotally movable center axis axis being displaceable with respect to the pivot axis of the support member, and extending in the opening and closing direction of the sliding door on the other of the door frame and the sliding door A stopper member having a frictional engagement portion that is engaged with frictionally engaged sliding movement surfaces;
A spring for biasing the stopper member
And,
Wherein the stopper member is displaceable between a retaining position and a retaining position in which the pivotal movement center axis is farther from the sliding surface than in the retaining position, The pivotally movable portion is prevented from pivotally moving so as to allow the engagement portion to pass between the pivotal movement center axis and the sliding movement surface. In the engagement release position, the friction engagement portion is pivotally moved between the pivotal movement center axis and the sliding movement surface It is permissible to pivotally move so as to pass between the first and second passages,
And the spring urges the stopper member toward the engagement position. The apparatus according to claim 1, further comprising a link member pivotably attached to the support member,
Wherein the stopper member is pivotally attached to the link member at a position distant from the pivotally moving center axis of the link member, and the link member is pivotally moved so that the stopper member is engaged with the support member And the engaging portion is displaced between the engaging position and the engagement releasing position. The sliding shutoff device according to claim 2, wherein the spring indirectly biases the stopper member through the link member. The sliding shutoff device according to claim 3, wherein the spring biases the link member at a position away from the pivotal movement center axis of the link member with respect to the pivotal movement center axis of the stopper member. The sliding shutoff device according to any one of claims 1 to 4, further comprising an urging force adjusting member engaged with one end of the spring to adjust a compression amount of the spring. The biosensor according to any one of claims 1 to 5, further comprising a biasing member for biasing the stopper member in a pivoting motion direction around the axis of the pivotal movement center of the stopper member, And the frictional engagement portion of the stopper member is pressed against the sliding movement surface by an urging force. The biasing member according to claim 6, wherein said biasing member is a leaf spring having a first portion located on one side of said stopper member in a direction of opening and closing said sliding door and a second portion located on the other side,
When the frictional engagement portion is engaged with the sliding movement surface at the side of the closing direction of the sliding door with respect to the pivotal movement center axis of the stopper member when the stopper member is in the engagement position, And the frictional engagement portion presses the stopper member to press the frictional engagement portion against the sliding movement surface, wherein the frictional engagement portion is located on the sliding movement surface of the stopper member in the direction of the opening direction of the sliding door, Wherein the second portion biases the stopper member to press the friction engagement portion against the sliding movement surface. 8. The slide fastener according to any one of claims 1 to 7, wherein the sliding movement surface has an arc-shaped cross-sectional shape,
Wherein the frictional engagement portion has a concave portion curved so as to follow the cross-sectional shape of the sliding movement surface, and when the stopper member is in the engagement position, the concave portion contacts the sliding movement surface. Device.

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