JP2014101667A - Runner structure for sliding door - Google Patents

Abstract

PROBLEM TO BE SOLVED: To provide a runner structure for a sliding door such that a door panel can be attached to and detached from a guide rail provided on a door frame.SOLUTION: A runner structure for a sliding door has: a guide roller 20 which travels along a guide rail 12 provided on a door frame 11; and a unit member 30 fixed to the sliding door 13. The unit member 30 includes: a case member 31; a related member (a gear member 32 and a damper link 36) provided for the case member 31 and related to a bar member (a rack member 14 and a timing bar 15) provided in a guide rail 12; and a support shaft block body 21 which has a pair guide roller connected part 23 at an upper end and an engagement lock member 21c, which can be engaged and locked to the case member 31 by insertion along the guide rail 12, and also unlocked through an external operation, at a lower end, and the guide roller connected part 23 of the support block body 21 extends in a direction horizontally orthogonal to a longitudinal direction of the guide rail 12 to support the guide roller 20 in a cantilever manner.

Description

  In the present invention, the guide roller provided at the upper end of the door plate is positioned and travels in the guide rail provided at the upper edge of the door frame, and the related member of the rotational force accumulating mechanism provided at the upper end of the door plate guides. The present invention relates to a sliding door runner structure that is applied to a sliding door having an automatic door closing function that enters a rail and engages and moves with a bar member provided on a door frame.

Conventional sliding door runner structures of this type are disclosed in Patent Documents 1 and 2.
In the sliding door runner structure disclosed in Patent Document 1, a door rail provided at the upper corners of the door plate and a hook of a soft closer are positioned on a guide rail provided at an upper edge of the door frame.
In the self-closing sliding door device disclosed in Patent Document 2, the runner members provided at the upper corners of the door plate are positioned in the rail provided at the upper edge of the door frame and run on the rail. The drive gear provided on the door plate rotates in mesh with the rack attached to the door.

JP 2006-112115 A JP 2005-054483 A

  According to the techniques described in Patent Documents 1 and 2, when trying to remove the door pulley from the rail in the direction perpendicular to the rail, the sliding door cannot be removed because the hook or drive gear of the soft closer interferes with the rail. There is a problem.

  The present invention has been devised in view of the above-described points, and the guide roller provided on the door plate side engages and runs in the guide rail provided on the door frame side, and on the door plate side. An object of the present invention is to provide a sliding door runner structure in which a door plate can be attached and detached in a self-closing type sliding door device in which a related member provided is engaged with a bar member provided on the door frame side.

In order to achieve the above object, the sliding door runner structure of the present invention includes a guide roller that travels along a guide rail provided on the upper edge of the door frame, a unit member that is fixed to the upper end corner of the door plate, The unit member includes a case member attached to a door plate, a case member provided on the case member, projecting into the guide rail and related to a bar member provided in the guide rail, and an upper end. An engagement lock member that includes a guide roller connection portion that is connected to the guide roller, and that engages and locks the case member in a direction along the guide rail at the lower end and can be unlocked by an external operation. And a support roller connecting portion of the support block body in a direction perpendicular to the longitudinal direction of the guide rail. Beauty provided, characterized in that for supporting the guide rollers cantilevered.

According to this configuration, in order to suspend the door plate, the guide roller connected to the spindle block body separated from the door plate is first inserted into the guide rail from below and moved to the guide rail in the horizontal direction. Next, the related members included in the unit member provided on the door plate are inserted into the guide rail from below and engaged with the bar member provided in the guide rail, and the spindle block body is assembled to the door plate. The attached case member is inserted and locked in the direction along the guide rail. In order to remove the door plate, a support member is inserted into the lower end so that the door plate does not descend, and then the engagement lock member is externally operated to release the engagement between the spindle block body and the case member. The block body is moved and separated in the direction along the guide rail. Next, the lower support member is removed, the door plate is lowered, and the related member is detached from the guide rail.
As described above, the guide roller provided on the door plate side travels by engaging with the guide rail in the guide rail provided on the door frame side, and the related member provided on the door plate side is provided on the door frame side. In the self-closing type sliding door device engaged with the door plate, the door plate can be attached and detached. Further, since the support shaft block body including the guide roller and supporting the guide roller in a cantilever manner is provided so as to be engageable / unlockable with respect to the door plate, the members can be shared on the left and right of the door plate.

  It is preferable that the case member is detachably included in a direction along the guide rail and engages with a receiving portion that is recessed from a side end of a corner portion of the door plate.

  According to this configuration, in addition to the support block body being freely engageable / unlockable with respect to the door plate, the case member can also be moved in the direction along the guide rail and separated from the door plate. . Therefore, the door plate can be attached and detached by removing the unit member from the door plate without removing the spindle block body from the guide rail.

  It is preferable that the spindle block bodies attached at the door tips and the door butt of the door plate are common.

  According to this configuration, cost reduction can be realized by using a common type of the support block body.

  According to the present invention, the guide roller provided on the door plate side runs while engaging in the guide rail in the guide rail provided on the door frame side, and the related member provided on the door plate side is provided on the door frame side. In the self-closing type sliding door device that engages with the bar member, a sliding door runner structure that can attach and detach the door plate can be provided.

It is a schematic perspective view which shows the whole structure of the self-closing type sliding door concerning the 1st Embodiment of this invention and incorporating the runner structure for sliding doors provided with the rotational force accumulating mechanism. It is a partially broken top view which shows the guide rail integrated in the runner structure for sliding doors shown in FIG. It is a left view of the guide rail shown in FIG. It is a front view which shows the attachment state of the guide rail of the guide rail shown in FIG. 1, a rack member, and a timing bar. It is an expansion perspective view which shows the guide roller integrated in the runner structure for sliding doors of FIG. It is a disassembled perspective view which shows the guide roller of FIG. It is a schematic front view which shows the inside of the runner structure for sliding doors of FIG. 1 of the state adjusted so that a sliding door may become a minimum position. It is a partially broken side view which shows the runner structure for sliding doors of FIG. 1 at the time of a damper action | operation. It is a disassembled perspective view which shows the runner structure for sliding doors of FIG. It is a schematic front view which shows the inside of the runner structure for sliding doors of FIG. 1 of the state adjusted so that a sliding door may become an upper limit position. It is a schematic front view which shows the unit member of the runner structure for sliding doors at the time of the temporary stop function start of a rotational force energy storage mechanism. It is a schematic front view which shows the unit member of the runner structure for sliding doors at the time of the temporary stop function action | operation of a rotational force accumulation mechanism. It is a schematic front view which shows the unit member of the runner structure for sliding doors at the time of the temporary stop function of a rotational force energy storage mechanism. It is a schematic front view which shows the runner structure for sliding doors of FIG. 1 adjusted so that a sliding door may become a minimum position. It is a schematic front view which shows the runner structure for sliding doors of FIG. 1 adjusted so that a sliding door may become an upper limit position. It is a schematic perspective view which shows the construction state which incorporates a sliding door in a door frame using the runner structure for sliding doors of FIG. It is a schematic front view which shows the construction state in FIG.

FIG. 1 is related to one Embodiment of this invention, and has shown the state integrated in the sliding door of the runner structure for sliding doors which self-closes using the rotational force which a rotational force accumulation mechanism accumulates.
In FIG. 1, a sliding door runner structure 10 moves a sliding door (door plate) 13 in a longitudinal direction (X direction) along a guide rail 12 provided on an upper edge of a door frame 11 of an opening provided in a building or the like. The guide roller 20 travels along the guide rail 12 and a unit member 30 attached to the upper end of the sliding door 13 and connected to the guide roller 20.

  In the sliding door runner structure 10 configured as described above, the characteristic part of the embodiment according to the present invention is that the unit member 30 is attached to the case member 31 attached to the sliding door 13 and the case member 31 as shown in FIGS. Related members (gear member 32 and damper link 36) related to the bar members (rack member 14 and timing bar 15) provided in the guide rail 12 and projecting into the guide rail 12, and the guide roller 20 at the upper end And an engagement lock member that can be engaged and locked with the case member 31 in the direction along the guide rail 12 and unlocked by an external operation. A support block block 21 provided with 21c, and the guide roller connecting portion 23 of the support block body 21 is a guide rail. A structure for supporting the cantilevered guide roller 20 is provided to extend in a direction orthogonal horizontally to the second longitudinal direction. Accordingly, the door plate can be attached and detached, and the support shaft block body 21 provided with the engagement lock member 21c can be made common to the left and right sides, that is, the door tip and the door bottom of the door plate. According to this configuration, the cost reduction can be realized by using a common type of the support shaft block body 21.

In the sliding door runner structure 10 configured as described above, the characteristic part of the embodiment according to the present invention is that the case member 31 in FIG. 5 has a guide rail 12 that is recessed with respect to the accommodating portion that is recessed from the side end of the corner of the sliding door 13. And is detachably included in the direction along the line. Thereby, a doorplate can also be attached or detached by removing a unit block from a doorplate, without removing a spindle block body.
The details will be described below.

As shown in FIGS. 2 and 3, the guide rail 12 is made of, for example, a long aluminum material having a hollow cross section, and the lower portion in the Z direction is open, and as shown in FIG. The lower edge of one side (in the illustrated case, the rear side) of the lateral direction (Y direction) perpendicular to the longitudinal direction is folded inward to form a rail portion 12a whose tip is directed upward.
As shown in FIG. 3, the guide rail 12 includes a rack member 14 and a timing bar 15 that extend in the longitudinal direction along the front side of the guide rail 12.

As shown in FIG. 4, the rack member 14 is disposed over substantially the entire length of the guide rail 12, and rack teeth 14 a having a predetermined pitch are formed on the lower edge thereof. In the case of illustration, the rack member 14 is divided into a plurality of parts in the length direction, and is continuously arranged by abutting the end portions.
Here, as shown in FIG. 3, the rack member 14 is engaged with the guide rail 12 by engaging the engaging portion 14 b provided on the upper side with the engaging groove 12 b provided on the upper edge of the guide rail 12. In contrast, it is held over its entire length. Thereby, the rack member 14 is held in a stable state with respect to the guide rail 12 over its entire length.

As shown in FIG. 4, the timing bar 15 is disposed from a position separated by a predetermined distance L from the end portion (left end in the case of illustration) of the guide rail 12 on the sliding door closing direction (X1 direction) side. The region near the left end is provided with a tapered portion 15a formed to be inclined upward toward the left end. In the case of illustration, the timing bar 15 is divided into a plurality of parts in the length direction, and the end portions are abutted and connected via the connecting portion 15b, so that the bottom surface is continuous. Two aspects are defined. The overall length of the timing bar 15 is about half of the entire length of the guide rail 12, and by adjusting the predetermined distance L, it is possible to adjust the brake application position. In addition, when the timing bar 15 is completely moved to the end of the guide rail 12 on the sliding door opening direction (X2 direction) side (the right end in the case of illustration), the tapered portion 15a is substantially at the center of the entire length of the guide rail 12. In this case, the brake is always applied to the movement of the door in the closing direction. Even in this case, since the entire length of the timing bar 15 falls within half of the guide rail 12 on the sliding door opening direction (X2 direction) side, there is no need to cut the timing bar 15.
Here, as shown in FIG. 3, the timing bar 15 is configured such that the engaging portion 15 c provided on the upper side engages with the engaging groove 14 c provided on the rack member 14, whereby the rack member 14 and the guide rail 12. Is held against. Thereby, the timing bar 15 is held in a stable state with respect to the guide rail 12 via the rack member 14 over the entire length thereof.

  Further, the engaging groove 14 c of the rack member 14 and the engaging portion 15 c of the timing bar 15 include a latch mechanism (not shown) in the longitudinal direction (X direction), and the timing bar 15 is connected to the rack member 14. Thus, the position can be adjusted in the longitudinal direction (X direction).

As shown in FIGS. 5 and 6, the guide roller 20 includes a support shaft block 21, a support portion 22 arranged so as to be movable in the X direction and the Z direction within the support shaft block body 21, and a support portion 22. On the other hand, it has a wheel 24 attached to an axle 23 extending laterally (Y direction).
The spindle block body 21 is molded from a plastic material such as POM (polyacetal) and has a hollow, substantially rectangular parallelepiped outer shape that is open at the top. As will be described later, the shaft block body 21 is in a recessed portion provided in the unit member 30. It is detachably attached to the unit member 30 from the locking piece 21c.

The support portion 22 is formed of SPCC (rolled steel plate) or ZDC (zinc die cast) material, and is inserted into the support block body 21 from the open upper portion of the support block body 21, and from the support block body 21. A mounting hole 22a for the axle 23 is provided in a portion protruding upward.
Furthermore, the support part 22 has the diagonal slot 22b extended upward toward the closed side of a sliding door in the part inserted in the spindle block body 21. As shown in FIG.
On the other hand, slots 21b extending horizontally in the longitudinal direction are formed in the front and rear wall portions of the support shaft block body 21.
A pin 25 extending so as to penetrate the support block 21 in the front-rear direction is inserted into the oblique slot 22b of the support portion 22, the horizontal slot 21b of the support block 21, and the horizontal slot 26b of the reinforcing plate 26. An adjusting screw 21a is screwed into the screw hole drilled in.
As described above, the support portion 22 can be moved and adjusted in the vertical direction as the support block body 21 moves in the longitudinal direction. By rotating the adjustment screw 21a forward and backward, 25 moves in each slot which is a long hole, and the support part 22 moves up and down in the spindle block body 21 along with this, and is fixed at the adjusted position.

The support block 21 has a front wall, a right side wall, and a rear wall reinforced by a reinforcing plate 26 made of a metal material such as SPCC (rolled steel plate).
Further, as shown in FIG. 6, the spindle block body 21 includes a locking piece 21 c that extends to the left on the lower surface, and when the locking piece 21 c is inserted into the recessed portion of the unit member 30, By engaging with a locking portion (not shown) provided in the recessed portion, the locking portion is locked in the recessed portion, and by pushing up the tip of the locking piece 21c, the engagement with the locking portion is released. It has come to be.

  The wheel 24 is disposed rearward from the center of the spindle block body 21 and rides on the rail portion 12a provided rearward of the guide rail 12, thereby rolling on the rail portion 12a by so-called one-wheel support. Move.

As shown in FIGS. 7, 8, and 9, the unit member 30 as the rotational force accumulating mechanism includes a case member 31, a gear member 32, a base member 33, a damper link 36, and a rotary damper 38.
As shown in FIG. 9, the case member 31 swings around a first case member 34 attached to the upper end of the sliding door 13 and a rotation center axis 34 a extending in the Y direction with respect to the first case member 34. It has the 2nd case member 35 supported so that it was possible, and the damper link 36 attached to the 2nd case member 35. FIG.

The first case member 34 includes two parts, that is, a first part 34b and a second part 34c, and a guide member 34d.
The first portion 34 b includes a recessed portion 34 e that receives the support block body 21 of the guide roller 20.
The second portion 34c has a bottom portion and both side walls located on both sides in the longitudinal direction, and receives the second case member 35 in a space defined by these both side walls.

Here, the second portion 34c swings around the rotation center shaft 34a near the end in the sliding door closing direction X1, and the opposite side is supported so as to be movable in the vertical direction (Z direction). .
The first portion 34b and the second portion 34c are combined with each other and fixed to form an integrated first case member 34.

Further, the guide member 34d has both side walls projecting from the second portion 34c to the sliding door opening direction side, and the both side walls sandwich the second case member 35 from both sides to form the second case. It acts as a guide when the member 35 swings.
The guide member 34d is also integrated as a first case member 34 with respect to the first portion 34b and the second portion 34c.

Similarly, the second case member 35 has a bottom portion and both side walls, and a gear member 32, a base member 33, a damper link 36, and a rotary damper 38 are received between the both side walls.
Here, the second case member 35 has a sliding door opening direction by a compression spring 37 provided between the contact portion 35a provided below the end portion in the sliding door closing direction X1 and the first case member 34. It is biased towards X2. Thereby, the second case member 35 swings around the rotation center axis 34a, and the entire second case member 35 is urged upward in the Z direction.

The damper link 36 is supported so as to be swingable around the rotation center axis 34 a of the first case member 34, and one arm portion 36 a faces upward so that the arm portion 36 a can come into contact with the lower surface of the timing bar 15. The other arm portion 36b supports the rotary shaft of the rotary damper 38 via the pedestal portion 38d.
Further, the damper link 36 is biased toward the sliding door opening direction X2 by the biasing spring 36c, thereby imparting left-turning performance in FIG.
When the unit member 30 moves in the sliding door opening direction X2, one arm portion 36a of the damper link 36 slides along the tapered portion 15a of the timing bar 15, so that the timing bar 15 can be smoothly moved. It is guided to the lower surface and comes into contact with the lower surface of the timing bar 15.

The rotary damper 38 includes a damper portion 38a and a gear portion 38b that is coaxial with and integrated with the damper portion 38a.
The damper portion 38a acts to suppress the rotation of the gear portion 38b.
Here, when one arm portion 36a of the damper link 36 is in contact with the lower surface of the timing bar 15, the gear portion 38b does not mesh with the gear member 32 and the arm portion 36a as shown in FIG. Is located in a portion where the timing bar 15 is not provided, the damper link 36 is urged by the urging spring 36c, so that the gear portion 38b meshes with the gear member 32 as shown in FIG. To do.
The rotary shaft 38c of the rotary damper 38 is disposed in arc-shaped slits 34f provided on both side walls of the second portion 34c of the first case member 34, thereby swinging the damper link 36. Accordingly, the inside of the slit 34f is smoothly moved.

  The gear member 32 is rotatably supported around a shaft body 32 a extending in the Y direction at an upper portion near the center in the longitudinal direction of the second case member 35, and its teeth 32 b are attached to the guide rail 12. The gear member 32 rotates as the unit member 30 meshes with the rack teeth 14 a of the rack member 14 and moves in the longitudinal direction (X direction) of the unit member 30.

  The gear member 32 is pressed against the rack member 14 of the guide rail 12 by the second case member 35 being biased upward in the Z direction by the action of the compression spring 37. As a result, the gear member 32 always reliably meshes with the rack teeth 14a of the rack member 14 even if the rack member 14 is distorted or misaligned due to an assembly error.

Further, a spring case 32 c is integrally attached to the gear member 32. A mainspring 32e (spiral spring; not shown) is built in the mainspring case 32c, and the sliding door is moved in the sliding door opening direction X2, and the gear member 32 rotates along the rack member 14, The spring 32e is wound up by the rotation of the gear member 32, and the gear member 32 is reversely rotated by the restoring force of the spring 32e, so that the sliding door automatically moves in the sliding door closing direction X1.
Here, the mainspring case 32c is formed in a flat cylindrical shape whose outer shape is centered on the shaft body 32a.

As shown in FIG. 11, the base member 33 is formed in an arc shape along the lower portion of the mainspring case 32 c integrated with the gear member 32, and the end of the sliding door closing direction X1 side is , And is supported so as to be swingable around a rotation center shaft 33a extending in the Y direction.
Further, the end of the base member 33 on the sliding door opening direction X2 side is urged upward by a damper 39.
The urging force of the damper 39 is selected so that the load applied to the free roller 40 described later is smaller than the restoring force of the mainspring 32e.

A free roller 40 is disposed between the mainspring case 32 c and the base member 33.
The free roller 40 rolls in the gap between the mainspring case 32 c and the base member 33 as the gear member 32 and the mainspring case 32 c rotate. At that time, since the base member 33 is urged by the damper 39 in the direction approaching the mainspring case 32c, the free roller 40 receives a load due to a predetermined friction during rolling.
A pair of regulating rollers 33b and 33c are provided in a region near the end of the base member 33 on the sliding door opening direction X2 side. These regulating rollers 33b and 33c are pivotally supported with respect to the base member 33 by lateral rotation shafts 33d and 33e extending in the Y direction, respectively.
Here, the opening-side regulating roller 33b is arranged near the end of the base member 33 on the sliding door opening direction side, and the closing-side regulating roller 33c is closer to the rotation center shaft 33a than the opening-side regulating roller 33b. Has been placed.
The base member 33 is tapered so that the curved surface facing the mainspring case 32c gradually decreases from the opening-side regulating roller 33b toward the closing-side regulating roller 33c. Has been.

As a result, when the sliding door moves in the sliding door opening direction X2, the gear member 32 rotates counterclockwise in FIG. 7 to wind up the mainspring 32e, and the free roller 40 is accompanied with the counterclockwise rotation of the mainspring case 32c. However, the base member 33 is rotated clockwise against the urging force of the damper 39 to widen the gap between the base member 33 and the mainspring case 32c, while the gap between the base member 33 and the mainspring case 32c is opened. Rolls toward the regulating roller 33b.
Then, as shown in FIG. 11, when the free roller 40 rides on the opening-side regulating roller 33 b, the opening-side regulating roller 33 b can freely rotate, so that the free roller 40 idles. The gear member 32 can also rotate freely.

When the movement of the sliding door in the opening direction is stopped from this state, the gear member 32 is rotated to the right by the restoring force of the mainspring 32e accommodated in the mainspring case 32c. As shown in FIG. 3, the space between the mainspring case 32c and the base member 33 rolls toward the closing-side regulating roller 33c.
At that time, the free roller 40 is held between the mainspring case 32c and the base member 33 by the urging force of the damper 39, so that a load is applied, so that rolling is suppressed and the free roller 40 rotates at a low speed. become.
Here, by appropriately adjusting the urging force of the damper 39, the rotational speed of the free roller 40, the mainspring case 32c and the gear member 32, and the moving speed in the closing direction of the sliding door by the restoring force of the mainspring 32e are set. The required time during which the free roller 40 moves from the open-side regulating roller 33b to the closed-side regulating roller 33c can be arbitrarily set.

Then, as shown in FIG. 13, when the free roller 40 rolls and rides on the closed side regulation roller 33c, the free side roller 40 is idled because the closed side regulation roller 33c can freely rotate. The gear member 32 can also rotate freely.
In this way, the free roller 40 rolls between the regulating rollers 33b and 33c as the sliding door is opened and closed.

The sliding door runner structure 10 configured as described above operates as follows.
First, when the sliding door 13 is in the closed state, as shown in FIG. 10, one arm portion 36 a of the damper link 36 of the unit member 30 is located on the sliding door closing direction side of the timing bar 15. The gear portion 38 b of the rotary damper 38 is engaged with the gear member 32 by being rotated clockwise by the tension of the biasing spring 36 c.
At this time, as shown in FIG. 13, the free roller 40 idles due to riding on the restriction roller 33 c on the closed side.

When the operator moves the sliding door 13 in the sliding door opening direction X2 from such a closed state, the gear member 32 that meshes with the rack member 14 rotates counterclockwise as the sliding door 13 opens. At this time, with the rotation of the gear member 32, the mainspring 32e in the mainspring case 32c is wound up, and the free roller 40 rolls between the mainspring case 32c and the base member 33 toward the opening direction.
When the free roller 40 rides on the opening-side regulating roller 33b by the further rotation of the gear member 32, the free roller 40 idles.
When one arm portion 36a of the damper link 36 reaches the taper portion 15a of the timing bar 15, the one arm portion 36a of the damper link 36 is pushed down according to the taper portion 15a to resist the tension of the biasing spring 36c. Turn right. As a result, the gear portion 38 b of the rotary damper 38 is separated from the gear member 32.
In this way, the sliding door 13 is opened.

Here, when the operator stops the movement of the sliding door 13 in the opening direction and releases the hand, the gear member 32 tries to rotate right due to the restoring force of the mainspring 32e in the mainspring case 32c. When the roller 40 receives a load between the mainspring case 32c and the base member 33 due to the frictional force generated by the urging of the damper 39, the roller 40 slowly rolls toward the closing-side regulating roller 33c.
At this time, the moving speed of the sliding door 13 toward the closing side due to the rotation of the gear member 32 is very slow, so that it is observed that it is temporarily stopped.

When the free roller 40 rides on the closed regulation roller 33c after a predetermined time, the free roller 40 idles. As a result, the gear member 32 is not subjected to a load from the free roller 40, so that the gear member 32 rotates at a high speed by the restoring force of the mainspring 32e, and the sliding door 13 moves at a high speed in the closing direction.
Thereafter, when the sliding door 13 approaches the closed position and one arm portion 36a of the damper link 36 reaches the vicinity of the end portion on the closing side of the timing bar 15 and moves along the tapered portion 15a, the damper link 36 is attached. Since the pivoting is performed based on the tension of the bias spring 36c, the gear portion 38b of the rotary damper 38 is engaged with the gear member 32 as shown in FIG.
At this time, the damper portion 38 a of the rotary damper 38 suppresses the rotation of the gear member 32. Accordingly, the gear member 32 is rotated by the restoring force of the spring 32e, and slowly rotates at that time. Thereby, the sliding door 13 will move to a closed position slowly at low speed.

In this way, when the sliding door 13 is opened, the free roller 40 rolls from the position where the free roller 40 rides on the closing restriction roller 33c to the position where the free roller 40 rides on the opening restriction roller 33b. Here, even when the sliding door 13 is opened to an arbitrary position on the way, the free roller 40 surely rides on the opening-side regulating roller 33b.
When the sliding door 13 is opened and stopped, the free roller 40 slowly rolls between the mainspring case 32c and the base member 33, so that the gear member 32 also rotates at a low speed. Observed as if paused at the open stop position.
Therefore, even if the operator does not fully open the sliding door 13, even if the operator opens the sliding door 13 to an arbitrary halfway open position and releases his / her hand from the sliding door 13, the sliding door 13 is apparently temporarily opened at the halfway open position. Since the operation stops, the operator can slowly pass through the opening in which the sliding door 13 is installed without using the sliding door 13 and freely using both hands.

After that, when the predetermined time has elapsed and the free roller 40 rides on the restriction roller 33c on the closed side, the free roller 40 idles. As a result, the gear member 32 rotates at a high speed by the restoring force of the mainspring 32e, so that the sliding door 13 moves in the closing direction at a high speed along the guide rail 12 automatically, that is, without any operation by the operator. To do.
When the sliding door 13 approaches the closed position, one arm portion 36a of the damper link 36 is detached from the timing bar 15 through the taper portion 15a, so that the damper link 36 rotates and the gear portion 38b of the rotary damper 38 rotates. The gear member 32 meshes with the gear member 32 to brake the rotation of the gear member 32. Accordingly, the gear member 32 rotates slowly, and the sliding door 13 moves to the closed position at a low speed. Thereby, since it becomes low speed in the final stage which the sliding door 13 closes, even if the finger pinching etc. at the time of closing of the sliding door 13 generate | occur | produce, the impact by the sliding door 13 becomes small.

Here, depending on the installation accuracy of the opening in which the door frame 11 is installed, when the sliding door 13 is attached to the door frame 11, the gap between the upper edge of the sliding door 13 and the lower edge of the door frame 11 varies. There are things to do.
As described above, the case member 31 constituting the unit member 30 includes the first case member 34 and the second case member 35, and the second case member 35 becomes the first case member 34. The second case member 35 can be adjusted in the vertical direction by being supported so as to be swingable.
Thereby, since the second case member 35 is biased upward based on the tension of the compression spring 37, the gear member 32 always meshes with the rack member 14.

FIG. 14 shows the upper limit position in the vertical direction of the second case member 35.
In FIG. 14, the second case member 35 swings around the rotation center axis 34 a with respect to the first case member 34, and moves as a whole to the upper limit position. The distance between the upper edge of the first case member 34 and the lower end of the guide rail 12 is D1.
At this time, the gear member 32 supported by the second case member 35 moves upward together with the second case member 35, thereby being reliably engaged with the rack member 14.
The damper link 36 is in a state in which one arm portion 36a is largely swung upward, and the rotary shaft 38c of the rotary damper 38 is positioned near one end of the slot 34f of the first case member 34. The slot 34f does not restrict the swinging of the first case member 34, and is designed so that escape occurs. In this state, the gear portion 38 b of the rotary damper 38 is engaged with the gear member 32.

FIG. 15 shows the lower limit position of the second case member 35 in the vertical direction.
In FIG. 15, the second case member 35 swings around the rotation center axis 34 a with respect to the first case member 34, and the entire second case member 35 moves downward and is positioned at its lower limit position. The distance between the upper edge of the first case member 34 and the lower end of the guide rail 12 is D2.
At this time, the gear member 32 supported by the second case member 35 moves downward together with the second case member 35, thereby being reliably engaged with the rack member 14.
Also in this case, the gear portion 38 b of the rotary damper 38 is engaged with the gear member 32.

  In this way, the distance between the upper edge of the first case member 34 and the lower end of the guide rail 12 due to the vertical swing of the second case member 35 relative to the first case member 34 is from D1. Since it adjusts between D2, even if the installation precision of an opening part is low, it is possible to install the sliding door 13 appropriately.

In relation to the vertical movement adjustment of the second case member 35, even if the guide rail 12 and the rack member 14 are not arranged straight in the longitudinal direction due to distortion or the like, the guide of the sliding door 13 is used. As the second case member 35 moves in the vertical direction along with the movement along the rail 12, the gear member 32 meshes with the rack member 14 following the distortion of the rack member 14. Thereby, the gear member 32 always meshes with the rack member 14, and stable operation can be ensured.
Therefore, conventionally, the height of the sliding door is adjusted by adjusting the position of the wheel of the guide roller in the vertical direction, and it has been impossible to cope with such distortion of the guide rail 12 and the like. According to the sliding door runner structure 10 according to the embodiment of the present invention, the vertical adjustment of the movement of the second case member 35 can sufficiently cope with the distortion of the rack member 14 and the like.

In addition, when the second case is moved and adjusted in this way, the damper link 36 also moves up and down with respect to the timing bar 15, but one arm portion 36a of the damper link 36 is The gear portion 38b of the rotary damper 38 meshes with the gear member 32 even when it swings upward greatly.
Therefore, the deceleration immediately before the closing position when the sliding door 13 is closed by the damper link 36 and the timing bar 15 is not affected by the swinging of the second case member 35 and the sliding door 13 is closed. When the sliding door 13 reaches immediately before the closing position, the closing speed of the sliding door 13 can be surely reduced at an appropriate timing.
Note that the contact position in the longitudinal direction between the damper link 36 and the taper portion 15a of the timing bar 15 slightly changes due to the vertical movement adjustment of the second case. It is also possible to accurately adjust to a predetermined longitudinal position by adjusting the movement in the longitudinal direction.

Next, in FIG.16 and FIG.17, the procedure which installs the sliding door 13 in the door frame 11 using the sliding door runner structure 10 of the said structure is demonstrated.
First, the guide rail 12 assembled with the rack member 14 and the timing bar 15 is attached to the lower surface of the upper edge of the door frame 11. A unit member 30 is attached to the upper end of the sliding door 13 adjacent to the end in the closing direction.
Subsequently, the guide roller 20 is mounted on the guide rail 12 on the door frame 11 side. In this case, the guide roller 20 is inclined so that the wheel 24 faces upward, and the wheel 24 is inserted into the inside from the open lower end of the guide rail 12, and the lower end of the wheel 24 is inserted into the rail portion 12 a of the guide rail 12. Put it on. Then, the guide roller 20 is mounted on the guide rail 12 by raising the entire guide roller 20 upright.

Then, the first case member of the unit member 30 attached to the sliding door 13 while the upper end of the sliding door 13 is positioned in the opening so as to face the lower edge of the door frame 11 and the guide roller 20 is moved in the X direction. 34 is inserted into the recessed portion 34e.
Here, when the guide roller 20 is completely inserted into the recessed portion 34e, the engagement lock member 21c engages with the locking portion in the recessed portion 34e, and the guide roller 20 is locked in the recessed portion 34e. .

When removing the sliding door 13 from the door frame 11, the guide roller 20 is easily detached from the unit member 30 by operating the engagement lock member 21 c to release the lock.
In this manner, according to the sliding door runner structure 10 according to the present invention, the sliding door 13 can be easily and detachably installed on the door frame 11.

The present invention can be implemented in various forms without departing from the spirit of the present invention.
For example, in the embodiment described above, the base member 33 is urged upward by the damper 39, but is not limited thereto, and may be urged upward by an elastic member such as a compression spring. .
In the embodiment described above, the sliding door 13 is urged in the closing direction by the restoring force of the mainspring 32e incorporated in the gear member 32. However, the sliding door 13 is not limited to this and is urged by other urging means. It may be biased in the closing direction.
For example, as the urging means, the guide rail 12 may be arranged so as to be inclined so as to become lower in the closing direction. Thereby, the sliding door 13 suspended and supported by the guide rail 20 by the guide roller 20 is always moved in the closing direction by the component force in the closing direction generated by the inclined guide rail 12 based on the weight of the sliding door 13. You will receive an energizing force.

In the above-described embodiment, the timing bar 15 includes the tapered portion 15a at the end portion on the closing direction side, but is not limited thereto, and may include a tapered portion at the end portion on the opening direction side. As a result, when one arm portion 36a of the damper link 36 is in contact with the timing bar 15, if the gear portion 38b of the rotary damper 38 is engaged with the gear member 32, the sliding door 13 is similarly closed. When the sliding door 13 reaches just before the closed position, the gear member 32 is decelerated by the action of the rotary damper 38.
In the above-described embodiment, the damper link 36 is urged by the urging spring 36 c so as to mesh the gear portion 38 b of the rotary damper 38 with the gear member 32. The rotation shaft 38c may be urged to the operating side directly by the urging member.

In the above-described embodiment, the rotary damper 38 is related to the rack member 14 via the gear portion 38b and the gear member 32, and is configured to reduce the closing speed of the sliding door 13. The damper 38 may be directly related to the rack member 14 to brake the case member 31 or the unit member 30 with respect to the rack member 14.
In the embodiment described above, the rotary shaft 38c of the rotary damper 38 is connected to the arm portion 36b of the damper link 36 via the pedestal portion 36d. However, the present invention is not limited to this, and the rotary shaft 38c is connected to the damper link 36. Although not provided, it may be slidable or swingable, and may be configured to be pushed to the working side and the non-working side by the arm portion 36b.

  In the above-described embodiment, the guide rail, the rack member, and the timing bar are attached to the upper edge of the door frame 11, and the guide roller and the unit member are attached to the upper end of the sliding door 13. The guide rail, the rack member, and the timing bar may be attached to the lower edge of the door frame 11, and the guide roller and the unit member may be attached to the lower end of the sliding door 13.

  Furthermore, in the above-described embodiment, the guide rail, the rack member, and the timing bar are attached to the door frame side, and the guide roller and the unit member are attached to the sliding door side. The rack member and the timing bar may be attached, and the guide roller and the unit member may be attached to the door frame side.

  As described above, according to the above-described embodiment, an extremely excellent sliding door runner structure that can automatically close the sliding door with respect to the door frame with a simple configuration is provided.

DESCRIPTION OF SYMBOLS 10 Sliding door runner structure 11 Door frame 12 Guide rail 12a Rail part 12b Engaging groove 13 Sliding door (door plate)
14 rack member 14a rack tooth 14b engaging portion 14c engaging groove X1 sliding door closing direction X2 sliding door opening direction L predetermined distance 15 timing bar 15a taper portion 15b connecting portion 15c engaging portion 20 guide roller 21 spindle block body 21a adjusting screw 21b Slot 21c Engagement lock member 22 Support portion 22a Mounting hole 22b Diagonal slot 23 Axle 24 Wheel 25 Fixing pin 26 Reinforcement plate 30 Unit member 31 Case member 32 Gear member 32a Shaft body 32b Teeth 32c Spring case 32d Clip member 32e Spring 33 Base member 33a Rotation center shaft 33b Restriction roller 33c Restriction rollers 33d, 33e Rotation shaft 34 First case member 34a Rotation center shaft 34b First portion 34c Second portion 34d Guide member 34e Recessed portion 34f Slit 35 Second case member 35a Abutting portion 36 Damper link 36a Arm portion 36b Arm portion 36c Biasing spring 37 Compression spring 38 Rotary damper 38a Damper portion 38b Gear portion 38c Rotating shaft 39 Damper 40 Free roller 41 Shaft retaining ring 42 Stopping Kimono

Claims (3)

A guide roller that travels along a guide rail provided on the upper edge of the door frame;
A unit member fixed to the upper end corner of the door plate,
The unit member is
A case member attached to the door plate;
A relation member provided on the case member, projecting into the guide rail, and related to a bar member provided in the guide rail;
An engagement lock that has a guide roller connecting portion that is connected to the guide roller at the upper end, and that can be inserted into the case member in the direction along the guide rail and locked at the lower end and unlocked by an external operation. A spindle block body provided with a member,
A sliding door runner characterized in that the guide roller connecting portion of the spindle block body extends in a direction perpendicular to the longitudinal direction of the guide rail and is supported in a cantilever manner. Construction.   2. The sliding door runner according to claim 1, wherein the case member is detachably included in the accommodating portion recessed from the side end of the corner portion of the door plate in a direction along the guide rail. Construction.   The runner structure for sliding doors according to claim 1 or 2, wherein the supporting shaft block bodies attached at the door tips and the door butt of the door plate are common.

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