EP2678507B1 - Glass pane sliding door - Google Patents

Description

The invention relates to a sliding glass door, with a door, which is guided with a drive in a track rail, limiting the path of the door leaf limiting device, a damper unit with retracting function and a coupler, which engages with an engaging portion of the damper detent, wherein the damper unit the door leaf initially decelerates in the process towards an end position and then drives into the end position.

It is known to provide sliding doors with a damper, which slows down the closing movement before reaching the end stop, so that a hard hitting the door leaf against the end stop is avoided. The damper absorbs the kinetic energy of the door leaf during the closing movement of the sliding door. However, such a damper does not ensure that the door exactly, in its closed position and remains there. It could happen that the door bounces when impacting against an end stop from this and moves back again. Furthermore, dampers are known which are additionally equipped with a spring which draws the engaging part of the damper in the direction of the damper end position. With such a damper, which may be attached to both the door leaf and on the running rail, it is achieved that is triggered by the attack of a coupling part on the engaging part of the damper of the damper. If the door has a high speed, it is braked by the damping function of the damper. Thereafter, the resilience of the arranged in the damper spring outweighs, so that this causes the door leaf is gently driven against the damping force in its end position.

In sliding doors, in principle, the problem of mutual coordination between the stationary connected to the track elements and the elements connected to the door leaf. When installing, great care must be taken to ensure that the closing position of the door leaf is exactly taken with a damper. In this case, a precise vote of the position of the engaging part and coupling part is required.

Out DE 10 2009 005 441 A1 which document discloses the features of the preamble of the claim, the applicant is a sliding door is known in which the limiting device forms a structural unit with the damper. This unit is arranged on the running rail. The coupler is designed as an arm running parallel to the running rail, which protrudes from the drive and has a stop face, which cooperates with the limiting device. The arm is according to DE 10 2009 005 441 A1 made of a strip of flat material and elastic. Since in this sliding door designed as an arm coupler abuts' the limiting device, it can lead to an elastic deformation of the arm, so that a defined position of the stationary arranged on the running rail components and arranged on the door components can not be guaranteed. This can cause damage to the damper or even to the door leaf. In addition, the provision of the coupler on a parallel to the running rail arm is a very complex construction, which is costly and leads to a drive with relatively large dimensions.

JP 2003 214023 A discloses a display case with sliding glass doors each having a retracting lock mechanism in which a coupler of a drive latchingly engages an engaging member, the coupler being disposed on the portion of the drive cooperating with a restrictor and centered on the drive.

The invention is therefore based on the object to further develop the known from the prior art sliding door, so that the risk of malfunction is avoided by deforming the coupler, at the same time a compact design of the drive is made possible. In a further development of

Invention is a simple assembly of the sliding door are made possible, with a faulty arrangement of damper unit, coupler and limiting device is virtually impossible.

The sliding glass door according to the present invention is defined by claim 1. The invention provides a sliding glass door with a running rail, one on it
with at least one drive guided door and a limitation of the path of the door limiting device, a damper unit with retraction function and a coupler, which engages detent with an engaging portion of the damper unit, before, wherein the damper unit slows down the door during the process toward an end position and then in the end position is driving. The invention is characterized in that the coupler is arranged at the rear end in the direction of the end position on the drive.

The coupler is disposed on the drive at the rear end of the drive toward the end position. In other words, when the drive moves toward the end position, the coupler is at the rear end of the drive. Before the coupler engages with the Angriffteil, the drive is thus moved to a large extent in the region of the damper unit. During deceleration of the movement of the drive in the end position, the damper unit thus exerts a pulling movement on the drive. When executing the feed function then the drive is pushed by the damper unit in the end position. The fact that the coupler is arranged at the rear end of the drive in the direction of travel, it is avoided that the coupler carrying part of the drive is deformed by the interaction of the drive with the limiting device. As a result, a malfunction of the damping of the drive, which can lead to destruction of the damper unit or the door, avoided.

In addition, it has been found that can be realized by the inventive design of the drive a very compact drive. The construction according to the invention moreover makes it possible for the drive to be fastened to the door leaf in such a way that the roller is arranged very close to a lateral edge of the door leaf, thereby enabling a particularly advantageous guidance of the door leaf. In this case, no projection of the drive to the door is necessary. In addition, can even the door leaf projecting beyond the drive in the direction of the end position, so that in the end position the door leaf is flush with the running rail. This is possible, for example, by the limiting device cooperating with a part of the drive, which is arranged laterally of the door leaf.

Of course, it is possible for a sliding door according to the invention that two drives according to the invention are attached to a door leaf, wherein these are arranged mirror-inverted. With a first damper unit also mirror-inverted arranged second damper unit is thus allowed that the door leaf of the sliding door according to the invention in the process in both end positions, i. both the closed position and the open position, braked and guided accordingly. When providing two drives, an advantageous guidance of the door leaf is possible because the drives can be arranged widely spaced due to the compact design.

A development of the invention provides that the damper unit and the limiting device have mutually adapted positioning elements for the defined positioning of the limiting device on the damper unit.

By providing positioning elements, a defined positioning of the limiting device on the damper unit is made possible and at the same time a faulty arrangement on the limiting device is avoided. In this case, the damper unit can first be mounted in the running rail in a simple manner, before the limiting device can be fastened to the running rail at a position defined by the positioning elements relative to the damper unit.

According to the invention it can be provided that the drive has a length which is less than the length of the damper unit, wherein the drive in the End position is completely in the region of the running rail, in which the damper unit is arranged. Thus, a particularly compact design of the drive is realized.

At the same time, the damper unit has a sufficient size to accommodate the necessary for a reliable damping and collection function of the door leaf elements.

The invention provides that the limiting device has a first stop surface and the drive at the end facing in the direction of the end position, a second stop surface which abut each other in the end position. The provision of two stop surfaces makes it possible to limit the movement of the drive in a particularly advantageous manner. In this case, stop buffers may be provided on one or both stop surfaces, which cause a gentle impact of the drive on the limiting device.

The distance in the longitudinal direction of the running rail between the engaging part of the damper unit in a damper end position and the first stop surface of the limiting device corresponds to the distance in the longitudinal direction of the running rail between the coupler and the second stop surface of the drive. In this way it can be ensured that upon reaching the previously defined damper end position, the drive strikes against the first stop surface of the limiting device with the second stop surface. It is provided that the damper end position is a position in which the damper unit is not fully retracted. This can prevent that before or when reaching the end position of the drive it comes to a striking of the damper unit. Due to the fact that the drive always strikes against the limiting device due to the construction according to the invention, before the damper unit is completely retracted, damage to the damper unit is avoided.

According to a preferred embodiment of the invention, it is provided that the positioning elements of the damper unit and the limiting device have a shape adapted to one another. In this way, an arrangement of the limiting device to the damper unit in a defined position in a particularly simple manner possible.

It can be provided that the positioning element of the limiting device is a dowel pin and the positioning element of the damper unit adapted to the dowel hole. Such positioning elements are manufactured in a particularly simple manner and errors in the assembly are avoided, since positioning elements can be brought together only in one way. Of course, it is also possible that positioning elements are used in a different form or that a dowel pin on the damper unit and a bore adapted to the dowel pin is arranged on the limiting device.

A preferred embodiment of the invention provides that the coupler engages in a recess of the attack part of the Dämpfereihheit, wherein the coupler is preferably a protruding from the carriage nose. Such a configuration of the coupler has proven to be particularly advantageous. In particular, when the nose formed as a coupler protrudes upwards from the drive, it is advantageous, since in the engaging into the recess of the engaging part a change in height of the drive, for example by a height adjustment of the drive, only leads to a displacement of the nose, so that slipping out of the coupler is prevented from the recess. A method of the drive over slight bumps thus does not lead to slipping out of the coupler part of the recess of the engaging part.

According to a preferred embodiment of the invention it is provided that the engaging part of the damper unit is guided in a slotted guide. Such a guide of the Angriffteils is particularly advantageous because the orientation of the recess of the Angriffteils can be changed via the slotted guide. As a result, a reliable engagement of the coupler is ensured with the engaging part during the damping and retraction phase by the damper unit.

It can be provided that the engaging part of the damper unit is designed as a fork. About a fork, the invention provided in the recess recess can be formed in a simple manner. The trained as a fork engaging part can be designed to be pivotable. It can be provided that, when moving the drive in the direction of the end position, the slide guide causes the pivoting of the fork from a starting position in a pivoted position and holds the fork in the pivoted position. When moving the drive from the end position, the slide guide can initially hold the fork in the pivoted position and cause the pivoting of the fork to reach the starting position.

The provision of the slotted guide thus allows in a simple manner that the trained as a fork attacking part while moving the drive in the direction of the end position both absorb a force exerted by the drive force and transmitted to the damper unit and exerted during the collection function of the damper unit Force can transfer to the drive. Furthermore, the slotted guide allows the process of the drive from the end position, a force can be transmitted from the drive to the damper unit, so that a spring of the damper unit can be stretched.

The damper unit can be arranged above or to the side of a track of the track rail.

A preferred embodiment of the invention provides that the damper unit comprises a piston-cylinder unit and a spring arranged parallel to the piston-cylinder unit. About the piston-cylinder unit, a damping function can be realized in a particularly advantageous manner. The arranged parallel to the piston-cylinder unit spring, however, can cause the collection function of the damper unit.

The damper unit may be individually and together with the limiting device on the running rail in the longitudinal direction to be displaced and locked.

The sliding door according to the invention is particularly, but not exclusively, suitable as a sliding glass door. The drive is part of a metal upper bracket for the glass door leaf. Therefore, it is particularly advantageous if the assembly is mounted in total and in a simple manner in the correct mutual assignment of the components.

Fig. 1

eine schematische Seitenansicht einer Schiebetür und

Fig. 2

eine schematische Draufsicht auf die Schiebetür von Fig. 1.

In the following an embodiment of the invention will be explained in more detail with reference to the drawings, in which:

Fig. 1

a schematic side view of a sliding door and

Fig. 2

a schematic plan view of the sliding door of Fig. 1 ,

In Fig. 1 and 2 a sliding door 1 is shown schematically. Fig. 1 shows a side view of the sliding door while Fig. 2 represents a top view.

The sliding door 1 has a running rail 10, which is horizontally mounted on a door opening and a drive 13 leads, to which a door leaf 12 is suspended suspended. In the illustrated embodiment, two drives 13 are provided on the door leaf 12, of which only one is visible. The drives 13 are arranged mirror-inverted on the door leaf 12. The drives 13 have rollers 14, which are guided in a raceway 16 of the running rail 10 and roll there friction.

Above the track 16 of the running rail 10, a damper unit 20 is arranged with retraction function. At a defined position with respect to the damper unit 20, a limiting device 15, which limits the travel path of the door leaf 12, is further fastened in the running rail 10. In order to ensure the defined positioning of the limiting device 15 with respect to the damper unit 20 during assembly of the sliding door, the damper unit 20 and the limiting device 15 have mutually adapted positioning elements. In the In Fig. 1 illustrated embodiment, a dowel pin 23 is provided on the limiting device 15, which engages in a matched to the dowel pin 23 bore 22 in the damper unit 20. The positioning elements of the damper unit 20 and the limiting device 15 thus have a shape adapted to one another.

The damper unit 20 has an engaging part 17 into which a coupler 30 of the drive 13 can engage with a detent. For this purpose, the engaging part 17 has a recess 25, in which the coupler 30, which is formed in the illustrated embodiment as from the drive 13 upwardly projecting nose, can intervene.

When moving the drive 13 in the direction of an end position, in the Fig. 1 is indicated by a corresponding arrow, the coupler 30 engages in the engaging part 17 of the damper unit 20. The damper unit 20 brakes the door leaf 12 first and then drives it into the in Fig. 1 shown end position. For this purpose, the damper unit 20 on a piston-cylinder unit, not shown, which causes a damping function and thus the braking of the door leaf. Parallel to the piston-cylinder unit, the damper unit 20 on a spring which drives the door leaf 12 by its spring force in the end position.

In the end position, the drive 13 is struck on the limiting device 15, so that a first stop surface 15a of the limiting device 15 rests against a second stop surface 13a of the drive 13. The first stop surface 15 a of the limiting device 15 is in the in Fig. 1 illustrated embodiment formed by a stop buffer 35, which may be formed for example as a rubber buffer.

The coupler 30 is arranged on the drive 13 at the rear end 18 in the direction of the end position. The coupler 30 is thus arranged on the side facing away from the second stop surface 13a of the drive 13 side of the drive 13, so that it is prevented by striking the drive 13 on the limiting device 15 to a deformation of the coupler 30 or the rear end 18th that carries the coupler 30 may come.

Thus, it can be ensured that a distance d between the second stop surface 13a on the drive 13 and the coupler 30 is fixed. The distance d corresponds to the distance D between the engaging part 17 and the damper unit 20 in a damper end position and the first stop surface 15a of the limiting device 15. The distances d and D extend respectively in the longitudinal direction of. Running rail 10. The damper end position is the in the Fig. 1 shown position of the damper unit 20, wherein in this damper end position, the damper unit 20 is not fully retracted. Such a construction prevents the forces generated when striking the drive 13 to the limiting device 15 must be absorbed by the damper unit 20, so that damage to the damper unit 20 is prevented. Since the distances d and D are predetermined by design and are immutable by the distance d are given by the dimensions of the drive and the distance D is determined by the defined positioning of the limiting device 15 to the damper unit 20, it is ensured that the drive 13 basically only abuts against the limiting device 15.

The door leaf 12 can project beyond the drive 1.3 in the direction of the end position, so that in the end position the door leaf 12 is flush with the running rail 10. This is particularly advantageous when mounting the sliding door 1 according to the invention adjacent to a wall. The limiting device 15 cooperates with a part of the drive 13, which is arranged laterally of the door leaf 12, so that a part of the door leaf is moved in the direction of observation via the limiting device 15. The compact design of the drive 13, it is possible that, although the door protrudes laterally for visual reasons, the roller 14 is still relatively close to a lateral edge 12a of the door leaf 12 is arranged, so that when providing two drives a large distance between the rollers 14 of the drives 13 is present, whereby an advantageous and stable guidance of the door leaf 12 is made possible.

How out Fig. 2 can be seen, the engaging part 17 is formed as a fork. When the drive 13 is moved into the end position, the engaging part 17 is initially in a starting position, in which the recess 25 extends substantially in the longitudinal direction of the running rail. This is the result Recess 25 in a position that the coupler 30 can engage in the recess 25 during the process of the drive. During further movement of the drive 13 in the direction of the end position, the engaging part 17 is pivoted. For this purpose, the engaging part 17 is guided in the damper unit 20 in a slotted guide 40, which causes the pivoting of the engaging part 17.

The coupler 30 of the drive 13 abuts against the end part of the fork 17 a in the direction of the end position, so that a force is exerted by the drive 13 on the damper unit 20. The damper unit 20 now brakes the drive 13 by the damping function. In the further course of the travel of the drive 13 outweighs the clamping force of existing in the damper unit 20 spring, so that the engaging member 17 is pulled in the direction of the end position. The in the end position rear portion 17b of the engaging member 17 is now applied to the coupler 30 and exerts a force on the drive 13, so that this in the in Fig. 1 and 2 shown end position is pressed. The slotted guide 40 thereby causes the engaging part 17 remains in the pivoted position and the forces described can be transmitted.

Upon movement of the door leaf 12 from the end position of the Koppler.30 exerts a force on the rear end 17b of the engaging member 17, so that the spring of the damper unit 20 is tensioned. Through the slotted guide 40, the engaging part 17 is then pivoted to the starting position in the further method of the drive 13, so that the coupler 30 is released.

The construction causes the drive 13 can be made very compact. Furthermore, the drive 13 can be arranged very close to a lateral edge 12a of the door leaf 12, so that when using two drives 13 on a door leaf 12, the drives 13 are very far apart and thus effect an advantageous guidance of the door leaf 12. The drive 13 may have a length that is less than that Length of the damper unit 20. In this case, the drive 13 is in the end position shown in the figures completely in the region of the running rail 10, in which the damper unit 20 is arranged. In other words, in the embodiment shown in the figures, the drive 13 is moved completely below the damper unit 20.

Of course, the damper unit 20 does not necessarily have to be arranged above the track 16 and thus above the drive 13. Of course, the damper unit 20 can also be arranged laterally to the drive 13, the coupler 30 then having to protrude laterally from the drive 13.

The damper unit 20 is arranged displaceably in the longitudinal direction of the running rail 10. A displacement of the damper unit 20 can basically be done with or without the limiting device 15. By providing the positioning elements, in principle it can be ensured even when the damper unit 20 is displaced that the limiting unit 15 is arranged at the correct position. The damper unit 20 can be fastened to the running rail 10, for example, via a groove in the running rail 10 and to the groove adapted to the groove.

The door leaves 12 of the sliding door are designed, for example, as all-glass doors, the drive 13 being fastened to the door leaf 12 via a clamping connection.

Claims (12)

1. Glass pane sliding door comprising a runner rail (10), a door leaf (12) guided on said rail by at least one running gear (13), a limiting device (15) limiting the travel of the door leaf (12), a damper unit (20) with a retraction function and a coupler (30) lockingly engaging with an engagement part (17) of the damping unit (20), wherein the damping unit (20) first decelerates the door leaf (12) as it moves towards an end position and then drives the same to the end position,
   wherein the limiting device (15) comprises a first abutment surface (15a) and the running gear (13) comprises a second abutment surface (13a) at the end directed towards the end position, said abutment surfaces abutting against each other in the end position,
   characterized in that
   the coupler (30) is arranged on the running gear (13) at the rear end (18), seen in the direction of the end position,
   the distance (D) in the longitudinal direction of the runner rail (10) between the engagement part of the damping unit (20) in a damper end position and the first abutment surface (15a) of the limiting device (15) corresponds to the distance (d) in the longitudinal direction of the runner rail (10) between the coupler (30) and the second abutment surface (13a) of the running gear (13), wherein, in the damping end position, the damping unit (20) is not fully retracted.
2. Glass pane sliding door of claim 1, characterized in that the damping unit (20) and the limiting device (15) comprise positioning elements adapted to each other for a defined positioning of the limiting device with respect to the damping unit (20).
3. Glass pane sliding door of claim 1 or 2, characterized in that the running gear (13) has a length shorter than the length of the damping unit (20), wherein, in the end position, the running gear (13) is located entirely in the portion of the runner rail (10) in which the damping unit (20) is arranged.
4. Glass pane sliding door of one of claims 1 to 3, characterized in that the positioning elements of the damping unit (20) and the limiting device (15) are adapted to each other with regard to their shape.
5. Glass pane sliding door of claim 4, characterized in that the positioning element of the limiting device (15) is a dowel pin (23) and the positioning element of the damping unit (20) is a bore (22) adapted to the dowel pin (23).
6. Glass pane sliding door of one of claims 1 to 5, characterized in that the coupler (30) engages a recess in the engagement part (17) of the damping unit (20), wherein the coupler (30) preferably is a nose protruding from the running gear (13).
7. Glass pane sliding door of claim 6, characterized in that the engagement part (17) of the damping unit (20) is guided in a slotted guide means (40) and/or that the engagement part (17) of the damping unit (20) is designed as a fork.
8. Glass pane sliding door of claim 7, characterized in that the fork is pivotable.
9. Glass pane sliding door of claim 8, characterized in that, when moving the running gear (13) in the direction of the end position, the slotted guide means (40) causes the fork to pivot from an end position to a pivoted position and maintains the fork in the pivoted position.
10. Glass pane sliding door of claim 8 or 9, characterized in that, when moving the running gear (13) out of the end position, the slotted guide means (40) maintains the fork in the pivoted position and causes the fork to pivot before the initial position is reached.
11. Glass pane sliding door of one of claims 1 to 10, characterized in that the damping unit (20) is arranged above or laterally of a running track (16) of the runner rail (10) and/or that the damping unit (20) comprises a piston cylinder unit and a spring arranged in parallel with the piston cylinder unit.
12. Glass pane sliding door of one of claims 1 to 11, characterized in that the damping unit (20) is adapted to be shifted and locked on the runner rail (10) in the longitudinal direction, either alone or together with the limiting device (15).

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