EP3757325A1 - Sliding door system - Google Patents

Abstract

Sliding door system (1) with at least one running rail (3) extending in a longitudinal direction and a door leaf (100) guided on it with at least one drive (4), the drive (4) on an upper edge (100a) of the door leaf (100 ) is attached, and with a lock device (19) for locking the door leaf (100) in a closed position, the lock device (19) having a bolt device (21) with a bolt (31) and a bolt receptacle (23), the Bolt holder (23) has a bolt actuator (43) and a bolt retainer (45) spaced apart from the bolt actuator (43), the bolt (31) being insertable between the bolt actuator (43) and the bolt retainer (45) when the door leaf (100) is closed and the bolt actuator (43) guides the bolt (31) into a retaining position when the door leaf (100) is closed against an automatic return force, the bolt (31) in the retaining position holding the bolt retainer ( 45) engages behind and wherein the bolt device (21) has a bolt holding device (47) which holds the bolt (31) in the locking position of the lock device (19) in the retaining position.

Description

The present invention relates to a sliding door system with at least one running rail extending in a longitudinal direction and a door leaf guided thereon with at least one drive, the drive being attached to an upper edge of the door leaf, and with a lock device for locking the door leaf in a closed position , wherein the lock device has a bolt device with a bolt and a bolt receptacle.

Sliding door systems, especially for sliding glass doors, usually have a running rail in which a door leaf is guided over a drive. The path of the drive and thus of the door leaf is limited by a limiting device. Such a sliding door system is off, for example DE 20 2007 014 567 U1 previously known.

Sliding doors are often used to close off rooms. In order to prevent unauthorized access to a room closed with a sliding door, there is therefore the need to lock a sliding door by means of a lock. Known solutions mostly provide a lock which, similar to a conventional swing door, is arranged on a side edge of the door leaf. However, such a solution is difficult to implement, particularly in the case of sliding glass doors, or it is aesthetically unfavorable because the lock is visible due to the glass door.

Out DE 10 2013 217 541 A1 a sliding door system with a lock device is known to the applicant.

The lock device consists of a lock which is attached to the running rail and a flat arm protruding from the drive in the direction of travel, which acts as an engaging element for a bolt of the lock. The The bolt of the lock can be pivoted about a horizontal axis which runs in the direction of the running rail. As a result, a greater space requirement is required for pivoting the bolt in a direction transverse to the longitudinal direction of the running rail.

Particularly for support systems that are to be arranged in ceiling recesses or on adjacent walls, it is not desirable for the running rail to protrude laterally over the door leaf when the door leaf is closed.

At the same time, however, the drive of the door leaf should also be arranged at a small distance from the side edge of the door leaf so that the door leaf can be guided with high stability and smooth running.

Out DE 10 2016 217 664 B3 the applicant is therefore aware of a sliding door system with a lock in which the installation space in the longitudinal direction of the running rail can be kept small. A locking device of the lock forms a structural unit with a limiting device that limits the travel path of the drive. The locking device has a lock, an automatic restoring force moving the lock into an unlocking position. The bolt can be actuated into a locking position against the automatic restoring force via an electric drive.

In this known sliding door system, however, the outlay in terms of device technology for the electric drive is relatively great, in particular since the smallest possible installation space is to be achieved.

It is therefore the object of the present invention to create a sliding door system of the type mentioned at the outset in which the installation space in the longitudinal direction of the running rail can be kept small and at the same time a simple construction can be realized with little outlay in terms of device technology.
The invention is defined by the features of claim 1.

The sliding door system according to the invention has at least one running rail extending in a longitudinal direction and a door leaf guided thereon with at least one running gear, the running gear being attached to an upper edge of the door leaf. Furthermore, a lock device is provided for locking the door leaf in a closed position, the lock device having a bolt device with a bolt and a bolt holder, wherein the bolt holder has a bolt actuator and a bolt retainer spaced from the bolt actuator. The bolt can be inserted between the bolt actuator and the bolt retainer when the door leaf is closed, the bolt actuator guiding the bolt into a retaining position against an automatic return force when the door leaf is closed. In the retaining position, the bolt engages behind the bolt retainer, the bolt device having a bolt holding device which holds the bolt in the retaining position when the lock device is locked.

Because the bolt actuator guides the bolt into the restraint position when the door is closed, no separate drive is required for the bolt, which reduces the complexity of the bolt device. The bolt is driven by the closing movement of the door. For example, the latch operator can push the latch into the restraint position.

The special feature of the sliding door system according to the invention is that the bolt is moved into the retention position with each closing process of the door leaf. However, locking only takes place when the bolt holding device is actuated, which holds the bolt in the retaining position in the locked state of the lock device. This has the particular advantage that the movement of the bolt into the retaining position and the actual locking process by holding the bolt over the bolt holding device are two different processes. The door sash can be opened when the bolt holding device does not hold the bolt, so that when the door sash is opened, the bolt is returned from the retaining position to a basic position by means of the automatic return force becomes. Without further influence from the outside, the bolt is always in the basic position after the door leaf has been opened, so that the door leaf can then be closed without any problems. There is therefore no risk of the bolt being in its retaining position when the door leaf is open and an unintentional collision between the bolt receptacle and the bolt can occur. In the sliding door system according to the invention, the bolt holding device can also be designed in such a way that the bolt holding device can be activated before the door leaf is closed and the bolt is then lifted from the basic position into the retaining position by the bolt actuator despite the holding force of the bolt holding device and then by the bolt holding device in the Retention position can be held. This can be possible, for example, in designs of the bolt holding device in which the bolt holding device holds the bolt by means of a frictional connection. There are also versions of the bolt holding device possible in which the bolt holding device holds the bolt by means of a form fit in the retention position. With such designs it is also possible to activate the bolt holding device before the door leaf is closed, the bolt then being able to snap into the bolt holding device when the door is closed. The activation of the bolt holding device before the door leaf is closed has the advantage that the locking process of the door leaf can be initiated regardless of its position, whereby it is ensured that the door leaf is locked in its closed position after the next procedure.

In the sliding door system according to the invention, the bolt can thus engage in the bolt receptacle when the door leaf is closed, and the bolt receptacle retains the bolt when the lock device is locked. It can be provided that, in the retention position, the bolt is arranged between the bolt actuator and bolt retainer.

The automatic return force can for example take place via gravity. Alternatively, it can also be provided that a Spring device is arranged, which pulls the bolt in the direction of the home position.

In the sliding door system according to the invention, it can be provided that the bolt actuator guides the bolt when the door leaf is opened in the unlocked state of the lock device from the restraint position into the basic position, the automatic return force pressing the bolt against the bolt actuator. As a result, the bolt can be guided in an advantageous manner when the door leaf is opened, since the bolt always rests against the bolt actuator due to the return force.

It can be provided that the bolt holding device can be actuated electrically, whereby when the bolt holding device is switched off, it releases the bolt so that the bolt can then be moved into the basic position due to the independent return force when the door leaf is opened. In the event of a power failure, for example, the door leaf of the sliding door system according to the invention can therefore always be opened.

It is preferably provided that the bolt has a pivot bearing and the bolt actuator guides the bolt in a pivoting movement. As a result, the bolt can be guided in a particularly advantageous manner into the retention position in which the bolt engages behind the bolt retainer.

The pivot bearing can for example have an axis of rotation arranged in the horizontal direction transversely to the longitudinal direction of the running rail. In other words: the bolt can be pivoted in a vertical plane extending in the longitudinal direction of the running rail. In this case, the bolt actuator and the bolt retainer are arranged spaced apart in the vertical direction, preferably one above the other. Of course, it is also possible that the bolt is arranged "horizontally" so that the entire arrangement is rotated by 90 °. In this case, the bolt can move in a horizontal plane and the bolt actuator and bolt retainer are arranged at a distance from one another in a horizontal direction transverse to the longitudinal direction of the running rail.

It is preferably provided that the bolt holding device is designed as a controllable magnet and the bolt is at least partially made of a ferromagnetic material. In the invention, it can thus be provided in an advantageous manner that the bolt holding device holds the bolt magnetically in the retaining position. As a result, the lock device can advantageously be operated electrically by using an electromagnet. It can be provided, for example, that the magnet attracts the bolt when it is actuated until the bolt rests against the magnet. As a result, the bolt can be held in the retaining position in a particularly advantageous manner by means of the bolt holding device. The fact that the bolt rests against the magnet creates a frictional force between the magnet and bolt, whereby the bolt can advantageously be held in the restraint position. It is preferably provided that the magnet attracts the bolt in a direction transverse to the plane in which the bolt can be moved from the basic position into the retention position. In the case of a pivotable bolt, the magnet thus attracts the bolt transversely to the pivoting plane. Thus the magnet acts transversely to the direction in which the automatic return force acts. The frictional force created between the magnet and the bolt thus counteracts the automatic return force. Such an arrangement has the particular advantage that when the magnet is switched off, the bolt is advantageously released.

In embodiments of the sliding door system according to the invention in which the bolt holding device is designed as a controllable magnet, the bolt holding device can advantageously be activated before the door leaf is closed and the bolt can be lifted from the basic position into the retaining position by the bolt actuator despite the holding force of the bolt holding device will.

The magnet can for example be a pot magnet.

It is preferably provided that the bolt has an elongated hole, the elongated hole being arranged opposite the magnet. With others In other words: the bolt does not completely cover the contact surface of the magnet. It can be provided in particular that the elongated hole is narrower than the contact surface of the magnet.

By providing the elongated hole, it can be ensured that any residual magnetism that remains in the bolt after the magnet has been switched off, which was caused by the magnet, is low, so that the bolt can be released from the magnet very quickly.

In a preferred embodiment of the invention, the locking device is arranged in the running rail and the locking receptacle is arranged on the drive or door leaf. In other words: the bolt device is attached in or on the running rail and the bolt holder is carried along with the door leaf. For example, the bolt receptacle can be part of the drive or be attached to it. By arranging the bolt device in the running rail, the movable parts of the lock device and in particular the bolt holding device are arranged in a stationary manner and do not have to be carried along by the door leaf. Only the bolt receptacle, which is of simple construction, is carried along by the door leaf, which means that the sliding door system according to the invention is less susceptible to wear.

In a particularly preferred embodiment of the invention it is provided that the locking device is attached to a limiting device for limiting the path of travel of the door leaf. The locking device can thus form a structural unit with the limiting device. This simplifies the assembly of the sliding door system according to the invention, since only the combination of limiting device and locking device has to be fastened in the running rail. In addition, installation errors are avoided, since it is ensured that the bolt is in the correct position in relation to the end position of the door leaf predetermined by the limiting device.

It is preferably provided that the bolt actuator and the bolt retainer are designed as projections, which are preferably located in extend in the horizontal direction transversely to the longitudinal direction of the running rail. In this way, the bolt actuator and the bolt retainer can be provided in a structurally simple manner.

It is preferably provided that the bolt actuator and the bolt retainer are designed symmetrically to a central plane of the bolt retainer running longitudinally of the bolt retainer. As a result of the symmetrical arrangement, the bolt holder can advantageously be used on a drive arranged on the left or right side by correspondingly turning the bolt holder. The bolt holder can be arranged, for example, as an additional attachment on a drive. The bolt receptacle can also be part of a carriage of the drive, for example. In one embodiment of the lock device in which the bolt is moved in a vertical plane and the bolt actuator and bolt retainer are located one above the other in the vertical direction, the center plane of the bolt receptacle runs horizontally.

It is preferably provided that the carriage has a carriage guided in the running rail and a fastening device connected to the carriage. The drive is fastened to an upper edge of the door leaf via the fastening device. The carriage can be fastened to the fastening device via at least one fastening means, for example via at least one screw extending in the longitudinal direction of the running rail. The at least one fastening means can press the carriage and the fastening device against one another in the longitudinal direction of the running rail, with at least one projection being arranged on the carriage which extends in the longitudinal direction of the running rail and engages in a recess of the fastening device and / or at least one projection on the fastening device Projection is arranged, which extends in the longitudinal direction of the running rail and engages in a recess of the carriage.

The sliding door system according to the invention makes it possible, in a simple manner, that the carriage initially has a compact design Running rail can be used and then moved in the longitudinal direction of the running rail to be connected to the fastening device of the door leaf. The at least one projection, which extends in the longitudinal direction of the running rail, engages in the corresponding recess so that the weight force can be transmitted from the fastening device to the carriage via a form fit.

In a preferred embodiment of the sliding door system according to the invention it is provided that the bolt receptacle has a space extending in the horizontal direction from the bolt actuator and the bolt retainer, into which the bolt is inserted in the retention position, the space extending in the horizontal direction over the bolt in the restraint position also has extending free space which extends in the horizontal direction over a length X, the length X being greater than the maximum spring travel of an elastic stop buffer for the door leaf. The elastic stop buffer can for example be part of the limiting device. The invention thus provides that the bolt receptacle not only has a space extending in the horizontal direction into which the bolt is inserted in the retention position, but also that this space also forms a free space. If the stop buffer is deflected when the door leaf hits, the bolt can thus dip into the free space, so that the bolt is prevented from hitting the bolt receptacle and thus damaging the bolt. In other words: the space formed in the bolt receptacle is longer than the part of the bolt that plunges into the space in the retaining position, which prevents the bolt from hitting the space.

It is preferably provided that the bolt has a first guide surface which has a contoured course, the bolt actuator resting against the first guide surface when the bolt is guided. In other words, the first guide surface has a predetermined course with a contour. For example, the contour can consist of straight and curved sections. It can also be provided that the latch actuator has a second guide surface which has an arcuate shape, the second guide surface resting against the first guide surface when the bolt is guided. The first guide surface can have, for example, a first straight section with a first slope, a second straight section with a second slope and further curved sections. When the bolt is inserted into the bolt receptacle, the bolt actuator initially rests against the first section and presses the bolt in the direction of the bolt retention position. The bolt actuator then presses against the second section of the first guide surface. The shape of the first guide surface ensures that the bolt is advantageously pressed into the retention position. The course of the first guide surface also ensures that even with embodiments of the sliding door system in which the bolt receptacle is arranged on the drive and can be adjusted in the vertical direction by adjusting the height of the door leaf relative to the bolt device, it functions reliably. The arcuate course of the second guide surface, which is arranged on the bolt actuator, ensures that tilting between the first guide surface and the second guide surface is avoided.

It is preferably provided that the bolt retainer has a bolt contact surface which is arranged on the side of the bolt retainer facing away from the bolt device, runs obliquely in the longitudinal direction of the bolt receptacle away from the bolt device and in the direction of the bolt actuator, the bolt having a hook-shaped section, which has a locking surface which runs obliquely in the same direction in the retention position of the locking bar. In the case of a bolt that can be moved in a vertical plane so that the bolt actuator and the bolt retainer are located one above the other, the bolt contact surface thus slopes away in a direction away from the bolt device. The locking surface running obliquely in the same direction thus advantageously enables reaching from behind, so that when the door leaf is pulled open with the locking bar held in the retention position prevents the bolt retainer from pushing the bolt in the direction of the home position.

On the side facing the locking device, the locking retainer can also have an inclined surface which runs obliquely in the longitudinal direction of the locking device away from the locking device and in the direction of the locking actuator. This ensures that in the event of a manipulative incorrect operation of the lock device, in which the bolt is manually pressed into the retaining position when the door leaf is open and the bolt holding device is actuated so that the lock device is already in the locked state, the bolt will be released when the door leaf is closed is pressed by the inclined surface of the bolt retainer in the direction of the bolt actuator until the bolt can be inserted between the bolt retainer and the bolt actuator. Such a function is only possible in designs of the lock device in which the bolt holding device holds the bolt by means of a frictional connection, the bolt being moved against the holding force.

In the sliding door system according to the invention it can also be provided that the drive has rollers on one side. The bolt receptacle can be arranged on the side of the drive opposite the rollers. This allows a very compact design of the drive. In particular, it can be provided that the bolt retainer is arranged together with the rollers on a carriage which can be fastened to the door leaf by means of a fastening device.

The latch can have a bulge area adjoining the latch surface of the hook-shaped section. With a bolt held in the retention position, the bolt retainer strikes exclusively against the bolt surface when the door leaf is opened, the bulge area preventing the bolt retainer from being able to push the bolt in the direction of the basic position.

The door leaf can for example consist entirely or partially of glass.
In the context of the invention, the door leaf is understood to mean the plate-shaped part of the sliding door / the door leaf. The drive is an add-on part on the door leaf and is therefore not to be understood as part of the door leaf.

Fig. 1

eine schematische perspektivische Darstellung des erfindungsgemäßen Schiebetürsystems,

Fig. 2

eine schematische Draufsicht auf den Türflügel mit an dem Türflügel befestigten Laufwerken und

Fig. 3

eine schematische Detaildarstellung der Schlossvorrichtung des erfindungsgemäßen Schiebetürsystems.

The invention is explained in more detail below with reference to the following figures. Show it

Fig. 1

a schematic perspective illustration of the sliding door system according to the invention,

Fig. 2

a schematic plan view of the door leaf with drives attached to the door leaf and

Fig. 3

a schematic detailed representation of the lock device of the sliding door system according to the invention.

In Figure 1 a sliding door system 1 according to the invention is shown schematically in a perspective illustration.

The sliding door system 1 according to the invention has a running rail 3 extending in the longitudinal direction, in which a door leaf with an in Figure 1 drive 4, not shown, is performed. The longitudinal direction is indicated by a double arrow. The running rail 3 has an essentially C-shaped cross section, the interior of the running rail 3 being concealed from the viewer via a panel 5.

The running rail 3 forms a running track 7 for the carriage 4.

In Figure 2 the door leaf 100 with two drives 4 attached thereto is shown in a schematic side view. The drives 4 are arranged on an upper edge 100a of the door leaf 100.

The running gear 4 consists of a carriage 9 and a fastening device 11. The fastening device 11 is fastened to the door leaf 100 in a clamping manner. The carriage 9 is fastened to the fastening device 11 by fastening means (not shown).

How out Figure 2 As can be seen, the bogies 4 are arranged in mirror image, that is to say, the bogies are each arranged on the side of the fastening device 11 facing the respective outer edge 100b of the door leaf 100. As a result, the carriages 9 can be arranged very close to the outer edge 100b, as a result of which a large distance can be created between the carriages 9, whereby a particularly smooth running of the door leaf 100 can be achieved.

The carriages 9 each have two rollers 13 which are rotatably fastened to a roller block 15. The roller block 15 is mounted on an axle 17, the axle 17 being located between the two rollers 13. In particular, the roller block 15 can be designed in the form of a plate. Via the mounting of the axle 17, the roller block can execute a rocker-like movement so that if one of the rollers 13 threatens to lift off due to an unevenness, the other roller 13 is pressed in the direction of the track. The rollers 13 can roll on the running track 7 of the running rail 3. As a result of the design of the carriage 9, the door leaf 100 can be guided in the running rail 3 with particular smoothness and it is ensured that both rollers 13 carry approximately the same load.

In Figure 3 a lock device 19 of the sliding door system 1 according to the invention is shown schematically in a detailed representation.

The lock device 19 consists of a bolt device 21 and a bolt receptacle 23.

The bolt holder 23 is arranged on the carriage 9 on the side opposite the rollers. How out Figure 3 can be seen is the Axis 17 of the roller block 15 for the rollers 13 secured on this side by means of a nut 17a.

The locking device 21 forms a structural unit together with a limiting device 25. The limiting device 25 limits the path of the drive 4 in the longitudinal direction of the running rail 3. The longitudinal direction of the running rail 3 is in the Figure 3 represented by a double arrow. The limiting device 25 has a stop buffer 27 against which the carriage 9 when the door leaf 100 is moved into its end position, which is shown in FIG Figure 3 is shown, abuts.

The structural unit consisting of the locking device 21 and the limiting device 25 is fastened in the running rail 3 via a clamping device 29. The locking device 21 has a locking bar 31 which extends essentially in the longitudinal direction of the running rail 3 and has a hook-shaped section 31a at its end.

The bolt 31 is mounted pivotably in a vertical plane extending in the longitudinal direction of the running rail 3. For this purpose, the bolt 31 has a pivot bearing 33 which engages the end of the bolt 31 opposite the hook-shaped section 31a. The pivot bearing 33 forms an axis of rotation for the bolt 31 running horizontally transversely to the longitudinal direction of the running rail 3. The bolt 31 also has a guide device 35 consisting of a guide hole 37 with a bolt inserted into the guide hole 37. The pivoting movement of the bolt 31 is guided via the guide device 35 and limited upwards and downwards.

How out Figure 3 As can be seen, the bolt 31 engages in the bolt receptacle 23. For this purpose, the bolt receptacle 23 forms a space 41 in which, in the end position of the door leaf 100, the hook-shaped section 31a and a further part of the bolt are located. At the end facing the locking device 21, the locking receptacle 23 has a locking actuator 43 and a locking retainer 45 which are mutually aligned in the vertical direction are spaced apart. The bolt device 21 also has a bolt holding device 47, which holds the bolt 31 in the locked state of the door leaf 100 in the in Figure 3 Holds shown retention position.

In a state in which the bolt 31 has not yet been inserted into the bolt receptacle 23 and the bolt holding device 47 is deactivated, the bolt 31 is in a basic position in which the bolt 31 due to an automatic return force formed by gravity with the upper end of the Long guide hole 37 rests on the bolt 39. During the closing movement of the door leaf 100, the bolt 31 is first inserted with the hook-shaped section 31a into the opening formed between the bolt actuator 43 and the bolt retainer 45. The bolt actuator 43 pushes against a first guide surface 31b of the bolt device 21 and, as the door leaf 100 moves further in the direction of the end position, pushes the bolt 31 against the automatic return force and regardless of whether the bolt holding device 47 is activated or deactivated, upwards in the direction the in Figure 3 shown retention position. For this purpose, the bolt actuator 43 has a second guide surface 43a, which has an arcuate shape, as a result of which a hooking between the bolt actuator 43 and bolt 31 is avoided.

The first guide surface 31b has a partially curved course, with a first section running obliquely at a first angle and an adjoining second section running at a second angle. The second guide surface 43a of the bolt actuator 43 thus first rests on the first section of the first guide surface 31b and then on the second section. The first guide surface 31b is designed in such a way that the bolt 31 even when the door leaf is adjusted in height, in which the drive 4 is adjusted in height relative to the rollers and the roller block and thus also a relative adjustment between the bolt receptacle 23 and the bolt device 21 in vertical direction, works reliably.

The bolt holding device 47 is designed as a controllable magnet which forms a contact surface 47a. The bolt 31 is made of a ferromagnetic material. When the magnet is actuated, it pulls the bolt 31 in the horizontal direction transversely to the longitudinal direction of the running rail 3, so that the bolt 31 rests partially on the contact surface 47a of the magnet. As a result, a frictional connection is formed between the magnet and the bolt 31, so that the bolt cannot return to the basic position due to the automatic return force.

In the case of the sliding door system 1 according to the invention, the locking device 47 can be activated before the door leaf 100 is closed. When the door leaf 100 is closed, the bolt 31 is then raised from the basic position into the retention position by the bolt actuator 43 despite the holding force of the bolt retaining device 47 and then held in the retaining position by the bolt retaining device 47.

The activation of the bolt holding device 47 before the door leaf 100 is closed has the advantage that the locking process of the door leaf 100 can be initiated regardless of its position, whereby it is ensured that the door leaf 100 is locked in its closed position after the next procedure.

The bolt 31 has an elongated hole 49 opposite the magnet, so that only part of the contact surface 47a of the magnet rests on the bolt 31 when the magnet is actuated. This prevents excessive residual magnetism from remaining in the bolt 31 after the magnet, which can for example be a pot magnet, has been switched off, which could lead to a delay in the release of the bolt 31.

The bolt actuator 43 and the bolt retainer 45 are designed as projections which extend in the horizontal direction transversely to the longitudinal direction of the running rail 3. The bolt actuator 43 and the bolt retainer 45 are opposite one in the longitudinal direction of the bolt receptacle 23 and thus in In the longitudinal direction of the running rail 3, the horizontally extending center plane of the locking receptacle 23 is symmetrical.

The carriage 9 also has a symmetry to its center plane. As a result, the carriage 9 with the bolt receptacle 23 can also be rotated by 180 ° at another end of the door leaf 100 or on another door leaf.

The space 41 has in the longitudinal direction of the running rail a free space 41a extending beyond the bolt 31 in the restraint position. This extends in the horizontal direction over a length X which is greater than the maximum spring travel of the elastic stop buffer 27. This ensures that even if the carriage 9 hits the elastic stop buffer 27 at high speed, at which the stop buffer 27 is deflected , the bolt 31 does not strike against the end of the space 41.

The bolt retainer 45 has a bolt contact surface 45a which, on the side of the bolt retainer 45 facing away from the bolt device 21, obliquely in the longitudinal direction of the bolt receptacle 23 away from the bolt device 21 and in the direction of the bolt actuator 43, in Figure 3 so it runs diagonally downwards. The hook-shaped section 31a has a locking surface 31c which, in the retention position of the locking bar 31, runs obliquely in essentially the same direction. If, in the retaining position of the bolt 31 in the locked state, in which the bolt holding device holds the bolt in the retaining position, the door leaf 100 is moved in the direction of the opening position, the bolt surface 31c strikes the bolt contact surface 45a. The inclined course prevents the bolt retainer 45 from pushing the bolt 31 downward in the direction of its basic position.

On the side of the bolt retainer 45 facing the bolt device 21, an inclined surface 45b is arranged, which runs obliquely in the longitudinal direction of the bolt receptacle 23 away from the bolt device 21 and in the direction of the bolt actuator 43. The inclined surface 45b can be parallel to the Latch contact surface 45a run. This can ensure that in the event of a manipulative incorrect operation of the lock device 19 in which the bolt 31 is manually pressed into the retention position when the door leaf 100 is open and the bolt holding device 47 is actuated, so that the lock device 19 is already in the locked state When closing the door leaf 100, the bolt 31 is pressed by the inclined surface 45b of the bolt retainer 45 in the direction of the bolt actuator 43 until the bolt 31 can be inserted between the bolt retainer 45 and bolt actuator 43.

The lock device 19 of the sliding door system 1 according to the invention has the advantage that for the locking process of the lock device 19, only the bolt holding device 47 has to be actuated, which pulls the bolt 31 and holds it in the retaining position. The bolt holding device therefore does not have to cause any movement of the bolt 31. Rather, the movement of the bolt 31 is caused by the movement of the door leaf 100 or the automatic return force. As a result, the device-related complexity of the locking device 21 is kept low.

REFERENCE LIST

1

Sliding door system

3

Running rail

4th

drive

5

cover

7th

career

9

Carriage

11

Fastening device

13

Rollers

15th

Roller block

17th

axis

17a

mother

19th

Lock device

21st

Locking device

23

Bolt mount

25th

Limiting device

27

elastic stop buffer

29

Clamping device

31

bars

31a

hook-shaped section

31b

first guide surface

31c

Latch surface

33

Pivot bearing

35

Guide device

37

Elongated guide hole

39

bolt

41

room

41a

free space

43

Latch actuator

43a

second guide surface

45

Latch retainer

45a

Bolt contact surface

45b

Bevel

47

Bolt holding device

47a

Contact surface

49

Long hole

100

Door leaf

100a

upper edge

100b

outer edge

Claims (13)

Sliding door system (1) with at least one running rail (3) extending in a longitudinal direction and a door leaf (100) guided on it with at least one drive (4), the drive (4) on an upper edge (100a) of the door leaf (100 ) is attached, and with a lock device (19) for locking the door leaf (100) in a closed position, the lock device (19) having a bolt device (21) with a bolt (31) and a bolt receptacle (23), the Bolt receptacle (23) has a bolt actuator (43) and a bolt retainer (45) spaced apart from the bolt actuator (43), the bolt (31) being insertable between the bolt actuator (43) and the bolt retainer (45) when the door leaf (100) is closed and the bolt actuator (43) guides the bolt (31) into a retaining position when the door leaf (100) is closed against an automatic return force, the bolt (31) in the retaining position holding the bolt retainer ( 45) engages behind and wherein the bolt device (21) has a bolt holding device (47) which holds the bolt (31) in the locking position of the lock device (19) in the retaining position. Sliding door system according to claim 1, characterized in that the bolt actuator (43) guides the bolt (31) when the door leaf (100) is opened in the unlocked state of the lock device (19) from the retention position into a basic position, the return force of the bolt (31) presses against the latch actuator (43). Sliding door system according to Claim 1 or 2, characterized in that the bolt (31) has a pivot bearing and the bolt actuator (43) guides the bolt (31) in a pivoting movement. Sliding door system according to one of Claims 1 to 3, characterized in that the bolt holding device (47) is designed as a controllable magnet and the bolt (31) consists at least partially of a ferromagnetic material. Sliding door system according to Claim 4, characterized in that the bolt (31) has an elongated hole (49), the elongated hole being arranged opposite the magnet. Sliding door system according to one of Claims 1 to 5, characterized in that the locking device (21) is arranged in the running rail and the locking receptacle (23) is arranged on the carriage (4) or door leaf (100). Sliding door system according to Claim 6, characterized in that the locking device (21) is attached to a limiting device (25) for limiting the path of travel of the door leaf (100). Sliding door system according to one of claims 1 to 7, characterized in that the bolt actuator (43) and the bolt retainer (45) are designed as projections which preferably extend in the horizontal direction transversely to the longitudinal direction of the running rail. Sliding door system according to one of Claims 1 to 8, characterized in that the bolt actuator (43) and the bolt retainer (45) are designed symmetrically to a central plane of the bolt retainer (23) running in the longitudinal direction of the bolt retainer (23). Sliding door system according to one of Claims 1 to 9, characterized in that the bolt receptacle (23) has a space extending horizontally from the bolt actuator (43) and the bolt retainer (45) into which the bolt (31) is inserted in the retaining position The space in the longitudinal direction of the running rail has a free space which extends beyond the bolt (31) in the restraint position and which extends in the horizontal direction over a length x, the length x being greater than the maximum spring deflection of an elastic stop buffer (27 ) for the door leaf (100). Sliding door system according to one of Claims 1 to 10, characterized in that the bolt (31) has a first guide surface (31b) which has a partially curved course, the bolt actuator (43) when guiding the bolt (31) on the first guide surface (31b) is applied. Sliding door system according to claim 11, characterized in that the bolt actuator (43) has a second guide surface (43a) which has an arcuate shape, the second guide surface (43a) resting against the first guide surface (31b) when the bolt (31) is guided . Sliding door system according to one of Claims 1 to 12, characterized in that the bolt retainer (45) has a bolt contact surface (45a) which is inclined away from the bolt device (21) and in the direction of the bolt actuator (43) in the longitudinal direction of the bolt receiver (23). runs towards, wherein the bolt (31) has a hook-shaped section which has a locking surface (31c) which runs obliquely in the same direction in the retaining position of the bolt (31).

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