The invention relates to a sliding door with at least one door panel which is supported by at least one carriage movably supported by a guide rail which is mounted to a wall or a ceiling. The guide rail is provided with at least one door stop with an abutment against which a contact element connected to the door panel is positioned in an end position of the door panel.
Such a sliding door wherein the door panel is formed by a glass pane is produced and sold by applicant. Above the door panel, the sliding door includes for example a horizontal guide rail which is mounted to a building wall and on which the door panel is supported by means of two carriages in longitudinally spaced relationship. The carriages are connected at their bottom, ends to the glass pane forming the sliding door. At the upper end of each carriage a support roller is rotatably supported which is so disposed on a guide rail that the door is movable along the guide rail from an open to a closed position. In this closed position, the door panel completely covers a door opening in the housing wall and, in the open position, the door panel is at the side of the door opening in front of the house wall. In order to prevent the carriages from being moved accidentally off the ends of the guide rail, a door stopper is attached adjacent the ends of the guide rail. The door stopper includes an abutment against which the carriage is positioned when the door panel is opened or closed. The known sliding door has been well accepted in practice particularly because of its attractive design wherein all parts of the sliding door including the carriage are visible. Still the sliding door does have some disadvantages. In particular, with a rapid opening or closing of the sliding door, the carriage rebounds somewhat so that the door is then not fully closed or fully open.
It is therefore the object of the present invention to provide a sliding door of the type as described above wherein however an undesired movement of the door out of the closed or open end positions is largely prevented.
In a sliding door with a door panel supported by a carriage disposed on a guide rail so as to be movable between spaced door stops, the door stops include shock absorbers and the carriage has contact elements for contact with the shock absorbers. The shock absorbers further include return springs which are compressed by the engagement of the sliding door panel, the sliding door panel being lockable in its end positions by a locking arrangement for retaining it in an end position.
The impact of the contact element on the door stop is dampened by the shock absorber which is pushed back and decelerates the door panel along the displacement path of the shock absorber without noise. When the door panel has been substantially or even fully stopped, a locking arrangement engages the shock absorber so that an accidental rebound of the door panel out of its end position is avoided. An engagement of the locking arrangement can occur at any point between the rest position of the abutment and the fully retracted position of the abutment. Preferably, the location where the locking arrangement locks is the farthest inward travel position of the abutment. But it is also possible that the locking arrangement is so designed that it engages at a location between the rest position of the abutment and its inward travel end position. In this case, the door panel is first decelerated to a standstill and then, for example, by the force of the return spring, moved a small distance in the opposite direction to the position in which it is locked by the locking device. The retaining force of the locking device is greater than the return force of the return spring so that the door panel, after being engaged by the locking device, remains in this position until it is moved by the user out of this locked position by applying an external force. Then the door panel can be moved easily by hand along the guide rail. The shock absorber comprises preferably a cylinder with an oil damped piston. The return spring is preferably integrated into the shock absorber housing. It may be a mechanical spring or a gas spring. The sliding door according to the invention is of simple design wherein all essential parts of the sliding door may be arranged so that they are easily visible.
In a preferred embodiment of the invention, the door stop includes a base part which is movable along the guide rail and which can be fixed to the guide rail at different locations, the shock absorber being disposed between the base part and the door panel abutment. The position where the door stop is arranged on the guide rail can then be adapted during installation of the sliding door by moving the base part along the guide rail in a simple manner depending on the local conditions and/or the wishes of the user of the sliding door. The adjustable connection between the doorstop and the guide rail can be established in a force- and/or form-locking manner.
In an advantageous embodiment of the invention, the locking arrangement on the base part includes a locking pin disposed at the side of the guide rail which is provided with at least one recess formed at the side thereof wherein the door panel includes a locking element which with the shock absorber being in an operating position, engages the recess in a direction transverse to extension of the guide rail in such a way that the door panel is arrested relative to the guide rail. The recess is preferably arranged, at the top side of the arresting pin and the locking element extends, in its locking position, into the opening from the top so that the locking element and the door panel connected thereto can be moved out of the locking position by slightly lifting the door panel. As a result of the force required for the lifting of the door panel and/or the carriage, an unintended movement of the door out of the locking position is prevented.
In a preferred embodiment of the invention, the arresting pin includes a first end area which is connected to the base part and a second end area which is spaced from the first area in the longitudinal direction of the guide rail and which can be pivoted out of its rest position elastically transverse to the direction in which the guide rail extends relative to the first end area. The second end area can then be pivoted out during engagement and disengagement of the locking element relative to the first end area transverse to the direction in which the guide rail extends. In this way, the locking arrangement can be operated with little friction.
It is advantageous if the engagement element or the recess has at least one inclined area in a vertical plane extending in, or parallel to, a longitudinal extension direction of the guide rail. The engagement element is then guided to, and retained at, the lowest point as soon as the inclined area of the engagement element reaches the recess and/or the inclined area of the recess comes into contact with the engagement element. As a result of this engagement function, the locking arrangement can be safely engaged even when the engagement element reaches the stop location at different speeds.
Expediently, the locking element is in the form of a catcher roller which is rotatable about an axis extending at a right angle with respect to the longitudinal direction of the guide rail. By means of the catcher roller, the locking arrangement can be operated with little friction. In addition, the catcher roller forms a visually attractive form of the locking arrangement.
The catcher roller is provided at its circumference with a concave recess in which the arresting pin is accommodated when the door panel is arrested relative to the guide rail. The catcher roller can then easily engage, and be locked in, the recess of the arresting pin and is centered on the arresting pin in the locking position in the direction of its axis.
In a preferred embodiment of the invention, the carriage includes at least one roller roiling on the guide rail which roller has a circumferential groove by which the guide rail is accommodated, the arresting pin being arranged closely below the guide rail so that it prevents the roller from being lilted out of the guide rail. With this feature, a jumping of the roller off the guide rail is prevented even during a hard impact of the stop element on the engagement member of the door stop.
The guide rail has preferably a cylindrical cross-section wherein the base part has a bore which is adapted to the cross-section of the rail which extends through the bore. In this way, an attractive design of the doorstop is obtained wherein the door stop forms optically a unit with the guide rail.
In an advantageous embodiment of the invention, the base part includes a dead end bore which extends parallel to the guide rail in which the cylinder of the shock absorber is at least partially fitted. The cylinder may be fixed in the dead end bore in a form- force- and/or material-locking manner.
The base part of the door stop has preferably a circular cylindrical outer surface which is arranged on the guide rail such that its cylinder axis extends transverse to the longitudinal center axis of the throughbore of the base part is spaced from the cylinder axis. That is, the base part is arranged asymmetrically with respect to the guide rail whereby in spite of the circular cylindrical form of the base part a compact doorstop is obtained.
Below the invention will be described in greater detail with reference to the accompanying drawings.
A sliding door as indicated in
The guide rail 4 has a circular cylindrical or tubular cross-section and is mounted to a building wall 6 by wall mounts 5 which are spaced from one another in the longitudinal direction of the guide rail 4. As shown in
A section of each mounting bolt 7 spaced from the building wall 6 extends horizontally and transversely to the extension of the guide rail through an opening in the guide rail. The guide rail 4 is secured in its position by screws which are not shown in the drawings so as to prevent axial movement of the guide rail 4.
Below the guide rail 4, the door panel 2 is arranged about parallel to the surface of the building wall 6. The door panel 2 is mounted to the carriages 3 by screw elements which extend through fitted openings in the glass pane and are screwed to the carriages 3. The carriages 3 are spaced from each other in the longitudinal direction of the guide rail 4 and arranged adjacent the side edges of the door panel 2.
The support roller 11 of each carriage 3 is rotatably supported by a horizontal shaft 12 which is mounted to the carrier member 10 of the respective carriage 3 and which is arranged, in a top view, to extend at a right angle with respect to the longitudinal direction of the guide rail 4. As apparent particularly well from
Adjacent each end of the guide rail 4 a door stop 14 is mounted to the guide rail. The stop has a cylindrical surface and a center axis which extends normal to, but somewhat below, the longitudinal center axis of the guide rail 4, which passes through the bore. At its bottom, the base part 15 has a flattened area which forms a recess with respect to the cylindrical surface of the base part and which is disposed above the door panel 2. The flattened area extends parallel to the top edge of the door panel 2.
At the side facing away from the building wall, the base part 15 is closed by an ornamental screw 16 whose head completely covers the front side of the base part 15. Behind the screw head, the base part 15 includes a threaded bore which, is not shown in the drawing but in which a clamping screw is disposed for locking the bass part 15 to the guide rail 4. With the clamping screw loosened, the base part 15 can be moved along the guide rail 4.
The doorstop 14 has a stop area 17 which is engaged by an engagement element 18 arranged on the carrier 10 of the carriage when the door panel is in its end position adjacent the respective door stop 14. As shown in
The stop area 17 is supported on the base part 15 by a hydraulic shock absorber 20. The shock absorber 20 is shown in
The shock absorber 20 additionally includes a return spring, which is not shown in the drawings, by the return force of which the piston is moved out of an end position adjacent the bottom of the cylinder part into an operating position in which the piston is spaced from the bottom of cylinder part. Accordingly, the shock absorber 20 has in its rest position, a greater length than in its end position. The return spring may be a mechanical spring or a pressurized gas spring wherein gas is enclosed in part of the cylinder interior.
When the carriage 3 is disposed with its engagement element 18 in contact in the stop area 17 and the shock absorber 20 is compressed or respectively, in its operating position, the door panel 2 is in its end position at the respective door stop 14. The door panel is then locked to the guide rail 4 by means of a locking arrangement.
As clearly shown in
The locking arrangement further includes an engagement element 25 in the form of a catch roller which when the shock absorber 20 is in its operating position engages in the annular groove 22 of the locking pin 21 so that the carriage 3 with the door panel 2 is locked to the guide rail 4 (
In the locking position as shown in
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