EP2957697A1 - Closure device for sliding doors and window or door - Google Patents

Abstract

A collection device for sliding doors (6), in particular for a window or a door, comprises a housing (11) on which a first carrier (12) is displaceably mounted along a first guide (13, 14), wherein the first carrier (12) is biased by a first power storage (17) in a closed position and on the first guide (13, 14) in a tensioned position of the energy accumulator (17) can be latched, wherein a second driver (20) is provided, which via a second energy storage ( 27) is biased in a closed position, wherein the second driver (20) via at least a portion of the feed path of the first driver (12) along the first guide (13, 14) with the first driver (12) can be coupled. As a result, the pull-in forces can be flexibly adjusted.

Description

The present invention relates to a collection device for sliding doors, in particular for a window or a door, with a housing on which a first driver along a first guide is slidably mounted, wherein the first driver is biased by a first energy storage in a closed position and on the first guide can be latched in a cocked position of the energy storage, as well as a window or a door.

The DE 20 2014 001 516 discloses a collection device for a sliding leaf of a window or a door, in which a gas spring is used as a force storage and damping element. The gas spring is coupled via a push rod with a driver, which can be brought into engagement with a stationary stop to damp the sliding door. The disadvantage here is that the use of a gas pressure damper for the damping and the retraction force only makes it possible to adapt to differently sized sliding sashes poorly. In addition, the damping behavior over the feed path can not be optimally adapted to the retraction movement.

It is therefore an object of the present invention to provide a collection device for sliding doors, which allows flexible adaptation of the pull-in forces on the collection path.

This object is achieved with a collection device for sliding doors with the features of claim 1.

The intake device according to the invention comprises a first carrier, which is displaceably mounted along a first guide and is biased by a first energy storage in a closed position, and additionally a second driver, which is biased via a second energy storage in a closed position, wherein the second driver over at least a part of the feed path of the first driver along the first guide can be coupled to the first driver. As a result, the first and the second driver can act together on a part of the Einzugsweges on the sliding door to move them in the closing direction. This allows a flexible design of the pull-in force, since in an initial region of the feed path only an energy storage is effective while acting on an end portion of the feed path at least a second energy storage on the first driver, so that the pull-in forces are higher in the end than in the initial area. This allows an adaptation of the pull-in forces along the feed path, which makes sense especially for heavy sliding doors, because to slow down heavy doors, strong dampers are necessary, which could cause the sliding door to stop in an open position if the pull-in forces are too low. Therefore, the increase in the pull-in force is advantageous shortly before reaching the closed position. In addition, a damper with increasing damping force can be used, so that the damping forces can be increased in the closing direction.

According to a preferred embodiment, the second carrier is movable along a second guide and the second carrier in a position with a tensioned second energy storage on the second guide locked. The second driver can thus be transferred from a parking position in which it is decoupled from the first driver in a coupled to the first driver position, and then to move the first driver by the force of the first and second energy storage in the closing direction.

Preferably, the first guide for the first driver is at least twice as long as the second guide for the second driver. The first guide can move the first driver over a long distance, with rather low spring forces are used, while the second guide is at most half as long as the first guide, in which case the second driver is coupled to the first driver and act high spring forces. The spring force of the second energy storage can be greater than the power of the first energy storage, for example, at least 20%, in particular at least 40% larger.

In a further embodiment, a coupling member is held on the first driver, which can be brought into engagement with the second driver. The coupling member may optionally be formed integrally with the first driver or as a separate component, which is for example mounted pivotably on the first driver.

The coupling member may be held movably together with the first driver on the first guide and be coupled over a certain distance with the second driver. For this purpose, the coupling member may have a projection which can be inserted into a receptacle on the second driver. Conversely, the driver can also have a projection, which can be brought into engagement with a receptacle on the coupling member.

The first guide and / or the second guide preferably have a substantially linear guide track with at least one angled end section. Such guideways with an angled end portion have proven to be susceptible to wear and can ensure a secure locking of the driver on the angled end portion to park the driver there.

For a compact construction, the first and / or the second guide are formed on the housing, preferably both guides are provided on the housing. The housing may be formed approximately U-shaped in cross-section and on opposite side walls of the housing, the first and / or second guide may be formed by slots or grooves. This allows a stable and accurate guidance of the first and the second driver.

Preferably, the collection device has one or more dampers for slowing down the movement of the sliding door. The one or more dampers may optionally be coupled to the first driver or act with a separate damping device on the sliding door.

For a compact design, it is also advantageous if an energy storage is designed as a compression spring and another energy storage as a tension spring. As a result, in a coupled position of the first driver with the second driver, the first and the second energy store can be arranged on opposite sides of the driver.

According to the invention, a window or a door is provided with a frame and at least one sliding door, in which a collection device according to the invention is provided. The collection device is preferably arranged concealed between a frame and a sash. As a sliding door in the context of the present invention, both a lifting-sliding door, a pure sliding door or a pivotable sliding door can be considered, which is held displaceably in a parallel parked position on the frame.

Figur 1

eine Ansicht eines erfindungsgemäßen Fensters oder einer Tür mit einer Einzugsvorrichtung für eine Schiebetür;

Figur 2

eine Ansicht der Einzugsvorrichtung in einer Schließposition;

Figur 3

eine Ansicht der Einzugsvorrichtung in einer leicht geöffneten Position;

Figur 4

eine Ansicht der Einzugsvorrichtung in einer ausgekoppelten Position;

Figuren 5A und 5B

zwei Detailansichten der Einzugsvorrichtung der Figur 2, und

Figuren 6A und 6B

zwei Detailansichten der Einzugsvorrichtung der Figur 1 in einer eingekoppelten Position.

The invention will be explained in more detail below with reference to an embodiment with reference to the accompanying drawings. Show it:

FIG. 1

a view of a window according to the invention or a door with a sliding door retraction device;

FIG. 2

a view of the feeder in a closed position;

FIG. 3

a view of the feeder in a slightly open position;

FIG. 4

a view of the feeder in a decoupled position;

FIGS. 5A and 5B

two detailed views of the collection device of FIG. 2 , and

Figures 6A and 6B

two detailed views of the collection device of FIG. 1 in a coupled position.

A window or a door 1 comprises a frame 2, on which a fixed field 3 and a sliding door 6 are arranged. The sliding door 6 comprises a casement 5 and an insulating glass pane 4 accommodated in the casement 5. The sliding leaf 6 can be actuated via a handle 7, in particular also being locked or unlocked and displaced. The Sliding door 6 can be designed as a lifting-sliding sash, sliding sash or parallel sliding sash 6 to be moved along guide rails on the frame 2.

In order to facilitate the handling of the sliding door 6, a collection device 10 is provided, which is arranged concealed in a gap between the sash 5 and the frame 2. The retraction device 10 comprises a housing 11, which may optionally be fixed to the casement 5 or the frame 2 and retracting forces on the sliding door 6 transmits.

In FIG. 2 the collection device 10 is shown in a sectional view through the housing 11. The intake device 10 comprises a driver 12, which is movable along a first guide with a linear portion 13 and an angled end portion 14. The driver 12 has for this purpose two spaced apart in the longitudinal direction of the housing 11 pins 35 on both sides, which engage respectively in the slot-shaped guide 13 and 14. The driver 12 further comprises an upwardly to the frame 2 open towards receiving, in which a projection 15 can be inserted, which is fixed via a holder 16 on the frame 2. It would of course also possible to fix the projection 15 on the sash 5 and the housing 11 on the frame 2, to exert a catchment effect on the sliding door 6.

The driver 12 is biased by a first power storage 17 in the form of a spring, which is designed here as a compression spring in the closing direction, ie to the right in FIG. 2 , The energy accumulator 17 is connected to a holder 18 with the driver 12, wherein the holder 18 engages with a pin 19 in the spring and holds it in position. The opposite end of the force accumulator 17 is fixed to the housing 11. The energy accumulator 17 has a large length for the travel of the driver 12, but a rather small spring force.

The intake device further comprises a second driver 20 which is movable along a guide, wherein the guide has a linear portion 21 and an angled end portion 22. The guide is formed by slots on opposite side walls of the housing 11, wherein the driver 12 is movable by two spaced apart in the longitudinal direction of the housing 11 pin 23 in the guide. The driver 20 has a receptacle 24 into which a projection 31 of a coupling member 30th is insertable. The coupling member 30 is connected to the driver 12, wherein for this purpose an elongated hole is formed on the driver 12, in which a pin 32 of the coupling member 30 engages. The coupling member 30 is also movably mounted in the first guide, wherein the coupling member for this purpose has on opposite sides protruding pins 34 which engage in the linear portion 13 of the first guide.

The second driver 20 is also biased by a second energy storage 27 in the closing direction, wherein the second energy storage 27 is formed as a spring, in the illustrated embodiment as a tension spring. The energy accumulator 27 is fixed to an end portion 26 in the form of a hook on a holding portion 25 of the second driver 20 and is tensioned in the process in the opening direction.

If the sliding door 6 is moved from the closed position in the opening direction, the housing 11 moves in FIG. 1 to the right, so that the driver 12 is moved along the first guide to the left, as in FIG. 3 is shown. After a short travel, the second driver 20 passes from the linear portion 21 to the angled end portion 22 and pivots it, so that the receptacle 24 releases the projection 31 and the connection between the coupling member 30 and the second driver 20 is separated. The second driver 20 is then latched to the angled end portion 22 and arranged in a parking position.

If the sliding door 6 is now moved further in the opening direction, now only the first energy store 17 acts on the first driver 12 until the in FIG. 4 shown position is reached. Then, the first driver 12 has arrived at the angled end portion 14 and pivots such that the projection 15 is released from the receptacle on the driver 12. The first driver 12 is now latched to the angled end portion 14, wherein the coupling member 30 is held on the first driver 12, only the pin 32 is moved along the slot 33 during the pivoting movement of the first driver 12. The sliding door 6 can now be moved independently of the collection device 10.

If the sliding door 6 is now moved in the closing direction, first the projection 15 engages with the first driver 12, so that the first energy accumulator 17 pulls the sliding door 6 with a small spring force in the closing direction. This is advantageous so that not too high closing forces act, the sliding door 6 could accelerate additionally. In a method in the closing direction is then after a certain distance, preferably only after a distance of more than 50% of the total distance of the first driver 12, so the feed path, the second driver 20 is brought into engagement with the coupling member 30 by the projection 31st engages in the receptacle 24. Then act on the first driver 12 and the second driver 20, both power storage 17 and 27 on the sliding door 6, which is now close to the in FIG. 2 is shown closed position and can then be moved over the corresponding forces in the retraction position.

Through the use of two force accumulators 17 and 27, it is possible to use dampers which initially slow down the sliding door 6 during a closing movement with little force, but then cause high damping forces before reaching the closed position, in order to reliably prevent the sliding door 6 from striking , If high damping forces act, however, it is also necessary to apply high forces in the closing direction, which can be achieved by coupling the second driver 20 so that the second energy store 27 also pulls the sliding door 6 in the closing direction.

The second force accumulator 27 can therefore have a higher spring force than the first force accumulator 17.

In the FIGS. 5A and 5B is the collection device 10 in the region of the first driver 12 shown in section. At the first driver 12, a receptacle 36 for coupling the projection 15 is formed. Further, the driver 12 includes a slot 33 in which the pin 32 of the coupling member 30 is guided. As in FIG. 5B can be seen, the driver 12 is located substantially in a central plane of the housing 11 which is U-shaped in cross-section, wherein the first and the second guide are formed by slots or grooves in the two side walls of the housing 11.

In the Figures 6A and 6B the collection device is shown in the coupled state, in which the projection 15 of the holder 16 is in engagement with the first driver 12. The holder 16 may be screwed to the frame 2.

In the illustrated embodiment, a first driver and a second driver 20 is provided, which are each biased via an energy storage 17 and 27 in the closing direction, wherein the travel of the second driver 20 is significantly shorter than that of the first driver 12, preferably by more than 30%. It is also possible to provide more than two drivers, for example, three drivers, each of which can be moved along a guide and can be moved by its own energy storage in the closing direction. Due to the cascade-like coupling of the driver 12, 20 and any other driver, it is possible to adjust the closing force on the sliding door 6 flexible, in particular the shooting force can be formed much larger shortly before reaching the closed position than after coupling with the retraction device 10th

Therefore, the collection device is particularly suitable for heavy sliding doors of over 100kg, especially more than 150kg, to building openings that can be designed as lifting-sliding doors, sliding parallel sliding doors or linearly movable sliding doors.

LIST OF REFERENCE NUMBERS

1

door

2

frame

3

fixed panel

4

insulating glass pane

5

casement

6

sliding door

7

handle

10

retraction device

11

casing

12

takeaway

13

linear section

14

angled end section

15

head Start

16

holder

17

power storage

18

holder

19

spigot

20

takeaway

21

linear section

22

angled end section

23

spigot

24

admission

25

holding section

26

end

27

power storage

30

coupling member

31

head Start

32

spigot

33

Long hole

34

spigot

35

spigot

36

admission

Claims (15)

Feeding device for sliding doors (6), in particular for a window or a door, with a housing (11) on which a first carrier (12) along a first guide (13, 14) is slidably mounted, wherein the first driver (12) a first force accumulator (17) is biased into a closed position and on the first guide (13, 14) in a tensioned position of the energy accumulator (17) can be latched, characterized in that a second driver (20) is provided, which via a second Power storage (27) is biased into a closed position, wherein the second driver (20) via at least a portion of the feed path of the first driver (12) along the first guide (13, 14) with the first driver (12) can be coupled. Feeding device according to claim 1, characterized in that the second driver (20) along a second guide (21, 22) is movable and the second driver (20) in a position with a tensioned second energy accumulator (27) on the second guide (21, 22) can be locked. Feeding device according to claim 1 or 2, characterized in that the first guide (13, 14) for the first driver (12) is at least twice as long as the second guide (21, 22) for the second driver (20). Feeding device according to one of the preceding claims, characterized in that on the first driver (12) a coupling member (30) is held, which is engageable with the second driver (20). Feeding device according to claim 4, characterized in that the coupling member (30) on the first guide (13, 14) is held movable. Feeding device according to claim 4 or 5, characterized in that the coupling member (30) has a projection (31) which can be inserted into a receptacle (24) on the second driver (20). Feeding device according to one of the preceding claims, characterized in that the first guide and / or the second guide a substantially linear guideway (13, 21) with an angled end portion (14, 22). Feeding device according to one of the preceding claims, characterized in that the first and / or the second guide (13, 14, 21, 22) on the housing (11) are formed. Feeding device according to claim 8, characterized in that the housing (11) has a cross-sectionally approximately U-shaped contour and on opposite side walls of the housing (11) the first and / or second guide (13, 14, 21, 22) through slots or grooves are formed. Feeding device according to one of the preceding claims, characterized in that the collection device (10) has one or more dampers for braking the movement of the sliding door (6). Feeding device according to one of the preceding claims, characterized in that the force of the second energy store (27) is greater than the force of the first energy store (17), in particular by at least 30% larger. Feeding device according to one of the preceding claims, characterized in that an energy store (17) is designed as a compression spring and the other energy store (27) is designed as a tension spring. Feeding device according to one of the preceding claims, characterized in that the first and the second energy store (17, 27) on opposite sides of the first and the second driver (12, 20) are arranged in the coupled position. Window or door, with a frame (2) on which at least one sliding door (6) is movably held, characterized in that the sliding door (6) by a collection device (10) according to one of the preceding claims in a closed position retractable. Window or door according to claim 14, characterized in that the collection device (10) is arranged concealed between a frame (2) and a sash (5) of the sliding door (6).

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