BE1022034B1 - GUIDANCE SYSTEM FOR A SLIDING DOOR DEVICE - Google Patents

Abstract

This invention relates to a guiding system for a sliding door device, for guiding a sliding door leaf with a hollow profile (3), the cavity of which opens into the bottom edge of the sliding door leaf, comprising a guide rail (1) for installation under the sliding door leaf and a wheel-less and rigid guide element ( 2), which can be mounted telescopically at the bottom of the hollow profile (3), so that a downward force acts on this guide element (2), which drives the guide element (2) towards the guide rail (1), in order to prevent the sliding door leaf from sliding with respect to the guide rail (1), keeping the guide element (2) in contact with the guide rail (1).

Description

GUIDANCE SYSTEM FOR A SLIDE DEVICE

This invention relates to a guide system for a sliding door device for guiding a sliding door leaf of this sliding door device on its underside, wherein this sliding door leaf comprises a hollow profile, the cavity of which at one end of this profile opens into the lower edge of the sliding door leaf, comprising - a guide rail for installation under the sliding door leaf; - and a guide element, which is telescopically attachable at the bottom of the hollow profile, in such a way that a downward force acts on this guide element, which drives the guide element towards the guide rail, so that in the mounted state of the guide system, upon sliding of the sliding door leaf with respect to the guide rail, the guide element remains in contact with the guide rail.

In addition, this invention also relates to a sliding door device comprising - a sliding door leaf, which comprises a hollow profile, the cavity of which at one end of this profile opens into the lower edge of the sliding door leaf; - and an above-mentioned guidance system.

The sliding door leaf of such a sliding door device is typically suspended from an upper rail, wherein it is slidably arranged with respect to this upper rail between an open position and a closed position.

This sliding door leaf is guided at the bottom with the guide system to which this invention relates, so that it always hangs nicely vertically and does not deviate under the influence of transverse forces acting on it, such as for example wind load.

When placing the guide rail of such a sliding door device, it is often not easy to fit it perfectly and at the right angle. That is why in such a guidance system the guide element is provided telescopically, with a downward force acting on it, so that this guide element always remains in contact with the guide rail.

In the patent publications DE 10 2005 056 625 A1 and GB 1 256 533, examples of guide systems according to the preamble of the first claim are described and depicted. The guide wheel is in this case spring-loaded with a spring force which always drives it towards the guide rail.

In practice, these existing guidance systems do not appear to be sufficient to be able to cope with some common slopes and / or wind loads. If such a guide rail is to be placed, for example, on a terrace or a balcony, it will normally be placed under a certain slope, since such a terrace or balcony runs down this slope for drainage thereof. Moreover, when people take a seat on a balcony, the difference in height that such a guide rail bridges can take a few cm. This difference in height can also increase with expansions under different weather conditions. The guide element must therefore be telescopic so that such a height difference can be bridged.

The guide wheels from the guide systems of DE 10 2005 056 625 A1 and GB 1 256 533 can, because they are telescopically provided and spring-mounted in a hollow lateral profile of the sliding door device, be provided such that they deviate sufficiently far from the sliding door leaf to compensate for such height differences. Their confirmation, however, is insufficiently firm to be able to handle large wind loads repeatedly.

The object of this invention is to provide an alternative, more robust guiding system, in which large differences in height can be absorbed when the guide rail is placed and in which the sliding door device can absorb larger wind loads.

This object of the present invention is achieved by providing a guide system for a sliding door device for guiding a sliding door leaf of this sliding door device on its underside, said sliding door leaf comprising a hollow profile, the cavity of which at one end of this profile opens into the bottom edge of the sliding door leaf, comprising - a guide rail for arrangement under the sliding door leaf; - and a wheelless and rigid guide element, which is telescopically attachable at the bottom of the hollow profile, in such a way that a downward force acts on this guide element, which drives the guide element towards the guide rail, so that when mounted the guide system is displaced of the sliding door leaf with respect to the guide rail, the guide element remains in contact with the guide rail and which always extends partially in the hollow profile when it is telescopically arranged in the hollow profile and is in contact with the guide rail.

Because the guide element is now wheel-less and rigid and always extends partially in the hollow profile, when this guide element is arranged therein and is in contact with the guide rail, the weak link from the guide systems as described in DE 10 2005 056 625 A1 and GB 1 256 533 eliminated. This is because the attachment of a guide wheel can never be so robust and sturdy as a guide element per se, which is per se mounted telescopically in the hollow profile.

Moreover, this guiding system according to the present invention can also be manufactured much cheaper than the similar guiding systems known from the prior art.

The said downward force can take several forms here.

The guiding system can for instance comprise a spring which exerts a spring force on the guide element, so that this spring force forms part of the said downward force.

Alternatively or additionally, the guide rail may comprise a hook element for hooking into a lateral recess of the guide element such that when an upward force acts on the guide element, the hooked hook element engages the guide element and exerts a downward restraining force on the guide element, wherein this downward restraining force forms part of the said downward force.

In each case the downward force will also comprise the force of gravity acting on the guide element. In a special embodiment, this downward force will only comprise this gravitational force and thus be formed by the gravitational force acting on the guide element.

In a special embodiment of a guiding system according to the present invention, the guiding element comprises a slot at the bottom and the guiding rail comprises an upright rib for engaging in said slot for guiding the guiding element.

In such an embodiment, the said slot preferably comprises a convex bottom. Furthermore, said slot preferably comprises two convex side walls, which laterally define the slot. In this way, any irregularities of the guide rail can be better absorbed.

If, in the mounted state of a guide system according to the present invention, the guide element touches the guide rail on its underside, this guide element is preferably convex on its underside, so as to be able to absorb irregularities of the guide rail.

If, in the mounted state of a guide system according to the present invention, the guide element touches the guide rail on one or more of its side walls, then these one or more side walls are preferably convex in order to be able to absorb irregularities of the guide rail.

In particular, the outer surface of the guide element, at the places provided for contacting the guide rail when mounted, is preferably convex.

Nowadays there are a lot of suitable materials on the market with which a guide element of a sliding door device according to the present invention can be made wheelless and rigid.

It goes without saying that such a material is chosen because of a combination of good sliding characteristics in order to be able to ensure the conductive function, a suitable wear resistance and good strength properties in order to also be able to absorb lateral loads.

To this end, the guide element can in particular be manufactured primarily from plastic and more specifically from high-quality plastic with optimum sliding characteristics. In particular, the guiding element can for instance mainly be manufactured from polyoxymethylene (POM) copolymer.

More specifically, such a guiding element can then be manufactured, for example, by injection molding.

The object of this invention is additionally achieved by providing a sliding door device comprising - a sliding door leaf, which comprises a hollow profile, the cavity of which at one end of this profile opens into the lower edge of the sliding door leaf; - a guide rail which is arranged under the sliding door leaf; - and a wheelless and rigid guide element which is telescopically arranged at the bottom of the hollow profile such that a downward force acts on this guide element, which drives the guide element towards the guide rail, so that the guide element is displaced when the sliding door leaf moves relative to the guide rail. keep in contact with the guide rail and which always extends partially in the hollow profile when it is telescopically arranged in the hollow profile and in contact with the guide rail.

The hollow profile of such a sliding door device preferably extends on a lateral side of the sliding door leaf.

A sliding door device according to the present invention preferably comprises an above-mentioned guide system according to the present invention as said guide system.

This invention will now be further elucidated with reference to the following detailed description of a preferred guiding system according to the present invention. The purpose of this description is to provide illustrative examples only and to indicate further advantages and details of this invention, and thus cannot be interpreted as limiting the scope of the invention or the patent rights claimed in the claims.

In this detailed description reference is made to the accompanying drawings by reference numerals, in which - in Figure 1 a first embodiment of a guide system according to the present invention is shown in side view, without guide rail and with the guide element in fully retracted position; Figure 2 shows a second embodiment of a guide system according to the present invention in side view, without guide rail; Figure 3 is a perspective view of the guide system of figure 1, without guide rail and with the guide element in a first extended position; Figure 4 shows the guide element from Figure 1 in perspective, without guide rail and with the guide element in a second extended position; Figure 5 shows the lower part of the guide system of Figure 1 in side view, with guide rail and with guide element telescopically arranged in a hollow profile of a sliding door device; Figure 6 shows the lower part of the guide system from Figure 2 in side view, with a first embodiment of a guide rail and with guide element telescopically arranged in a hollow profile of a sliding door device; Figure 7 shows the lower part of the guide system of Figure 2 in side view, with a second embodiment of a guide rail and with guide element arranged telescopically in a hollow profile of a sliding door device.

The guide systems shown in the figures all comprise a guide rail (1) which is provided for being arranged under a sliding door leaf of a sliding door device. Examples of such a guide rail (1) are shown in Figures 5 to 7.

In addition, these guide systems comprise a guide element (2) which is telescopically mountable in a hollow profile (3) of the sliding door leaf and has a shape at the bottom corresponding to the shape of the guide rail (1) for being able to be moved over this guide rail (1) conductively. . This hollow profile (3) was partially shown in Figures 5 to 7 at the bottom of the sliding door leaf.

The sliding door leaf is typically suspended in a head rail, slidable between an open position and a closed position. When the sliding door leaf is displaced relative to the top rail, the guide element (2) is included in the sliding movement of the sliding door leaf and is thereby guided by the guide rail (1).

In Figure 5, the guide rail (1) is designed as an L-shaped profile.

The raised leg (6) of the L-shaped profile (1) is directed vertically upwards. The guide element (2) is provided at the bottom with two legs (17) which define a slot (4), as can be seen in figures 1 and 3-4. The raised leg (6) of the L-shaped profile (1) engages between these legs (17) in the said slot (4). The bottom (5) of the slot (4) of the guide element (2) is convex, as can be seen in Figures 1 and 3, so that the guide element (2) can continue to run on the guide rail (1), even when irregularities would be present in the guide rail (1).

The lowered leg (19) of the L-profile (1) can be placed on a surface and attached to it.

In Figure 6, the guide rail (1) is designed as a substantially U-shaped profile. The guide element (2) is provided at the bottom with two legs (17) which define a slot (4), as can be seen in figure 2. This slot (4) has no function in this application. The guide element (2) here engages between the upright sides (18) of the U-shaped profile (1) and rests on the bottom of the U-shaped profile (1). In order to be able to cope with irregularities in the guide rail (1), the outer sides of the guide element (2) which are in contact with the guide rail (1) are convex, and the bottom of the guide element (2) is convex.

The U-shaped profile (1) can be placed with its bottom (20) on a surface and attached to it. Alternatively, this U-shaped profile (1) can optionally be incorporated into this substrate.

In Figure 7 the guide rail (1) is designed as a substantially T-shaped profile, the T of which is arranged upside down, so that a flat plate (21) can be attached to a surface and so that it can be positioned relative to this flat plate (21). an upstanding rib (6) extends substantially vertically upwards.

The raised rib (6) engages between these legs (17) in the slot (4) of the guide element (2). This upright rib (6) is convex, while the slot (4) is correspondingly concave, so that the guide element (2) can continue to run on the guide rail (1), even when irregularities are present in this guide rail (1).

It is clear that this embodiment from figure 7 will not be used in places where relatively large wind loads are expected, given that the raised rib (6) only engages over a minimum height in the slot (4) of the guide element (2), which his turn was carried out minimally. Where relatively large wind loads are expected, the embodiments from figures 5 and 6 are better suited, since the guide rail (1) and the guide element (2) are guided here at a greater height relative to each other. The embodiment from Figure 7 is better suited for applications where the lower wheel (1) needs to occupy as little space as possible, for example in places where it is easy to step or drive over this lower wheel (1) without hindrance.

The upright rib (6) of a guide rail (1) can optionally also be provided with a widening in which recesses corresponding to the slot (4) are provided in the legs (17) of the guide element (2), wherein this widening is hook-shaped can intervene. The ends of the legs (17) then engage correspondingly hook-shaped under the widening of the upright rib (6). Then when an upward force acts on the guide element (2) in this way, the ends of the legs (17) engage in a hook-like manner on the widening of the upright rib (6) and this widening engages in a hook-like manner on the legs (17). ). A downward restraining force thus acts on the guide element (2), which prevents the guide element (2) from coming loose from the guide rail (1).

Analogously, with the U-shaped profile (1) of Figure 6, the upstanding sides (18) towards the guide element (2) can be provided with a hook-shaped element, which can engage in a corresponding lateral recess of the legs (17) of the guide element (2).

In such embodiments, the hook-shaped parts of the legs (17) can then, for example, be at least partially elastic so that the guide element (2) can be clicked onto the guide rail (1) with the aid of these at least partially elastic hook-shaped parts of the legs (17) to become.

The hollow profile (3), a lower end of which is shown in Figures 5 to 7, is provided on a lateral side of the sliding door leaf. This sliding door leaf can, for example, be provided with a frame built around from profiles (3). These profiles (3) do not connect with each other in absentia. The profiles (3) provided on a lateral side of the sliding door leaf extend completely between the bottom edge and the top edge of the sliding door leaf. The profiles arranged at the top and bottom of the sliding door leaf extend between the lateral profiles. At least the lateral profile (3) shown is hollow, with its cavity at the ends of the profile (3) terminating at the top edge of the sliding door leaf and at the bottom edge of the sliding door leaf. Preferably, the other (not shown) lateral profile is also hollow in the same way and the guide system is provided with a second guide element, which can be telescopically arranged in this second lateral profile in an analogous manner.

To telescopically attach the guide element (2) in the hollow profile (3), it is telescopically arranged in a tube (8). On the underside of the sleeve (8) a mounting flange (9) is provided, which is provided with screw holes (10), as can be seen in figures 3 and 4. After fitting the sleeve (8) in the cavity of the hollow profile (3), it can be screwed to the hollow profile (3) by applying screws through the screw holes (10), as can be seen in figures 5 to 7. In the mounting flange (9) there is a central opening (16), corresponding to the guide element (2), so that the guide element (2) is arranged so as to be slidable through it. Fixed to the guide element (2) a guide pin (12) is arranged laterally, which engages through a guide slot (11) in the side wall of the sleeve (8), this to guide the sliding movement of the guide element (2) in the sleeve ( 8).

The guide element (2) is spring-loaded in the sleeve (8) by means of a spring (7). This spring (7) is arranged around a rod (13), which is arranged at the top of the guide element (2). The spring (7) here extends between the top of the guide element (2) and a closing plate (14) at the top of the tube (8). An opening (15) is provided in the closing plate (14), through which the rod (13) is slidably arranged.

Together with gravity, the spring (7) exerts a downward force on the guide element (2), which drives the guide element (2) towards the guide rail (1). When the sliding door leaf is displaced relative to the guide rail (1), the guide element (2) thus always remains in contact with the guide rail (1). In the figures 1 and 3-4 for the first embodiment the guide element (2) is shown in different positions relative to the sleeve (8) in which it is telescopically arranged. In each position the guide element (2) is partially located in the sleeve (8) and thus when the sleeve (8) is arranged in the hollow profile (3), in this hollow profile (3).

This guide element (2) is rigid and wheelless, so that it can also absorb heavy transverse forces. For this purpose, this can be made, for example, from a POM copolymer with optimum sliding characteristics via, for example, injection molding.

Claims (14)

CONCLUSIONS A guide system for a sliding door device for guiding a sliding door leaf of this sliding door device on its underside, said sliding door leaf comprising a hollow profile (3), the cavity of which at one end of this profile (3) opens into the lower edge of the sliding door leaf, comprising - a guide rail (1) for positioning under the sliding door leaf; - and a guide element (2), which is telescopically attachable at the bottom of the hollow profile (3), in such a way that a downward force acts on this guide element (2), which guides the guide element (2) towards the guide rail (1) floats, so that in the mounted state of the guide system, when the sliding door leaf is displaced relative to the guide rail (1), the guide element (2) remains in contact with the guide rail (1); characterized in that the guide element (2) is wheelless and rigid and always extends partially in the hollow profile (3) when it is arranged telescopically in the hollow profile (3) and is in contact with the guide rail (1). Guiding system according to claim 1, characterized in that the guiding system comprises a spring (7) which exerts a spring force on the guide element (2), so that this spring force forms part of said downward force. Guiding system according to one of the preceding claims, characterized in that the guide rail (1) comprises a hook element for hooking into a lateral recess of the guide element (2) such that when an upward force acts on the guide element, hooked hook element engages the guide element (2) and exerts a downward restraining force on the guide element (2), this downward restraining force forming part of said downward force. Guiding system according to claim 1, characterized in that the gravitational force acting on the guiding element (2) forms said downward force. Guiding system according to one of the preceding claims, characterized in that the guide element (2) has a slot (4) at the bottom and that the guide rail (1) has an upright rib (6) for engaging in said slot (4) to engage for guiding the guide element (2). Guiding system according to claim 5, characterized in that said slot (4) comprises a convex bottom (5). Guiding system according to one of the preceding claims, characterized in that the guiding element (2) is convex on its underside. Guiding system according to one of the preceding claims, characterized in that each side wall of the guiding element (2), which is provided to contact the guiding rail (1) in the assembled state of the guiding system, is convex. Guide element according to one of claims 6, 7 or 8, characterized in that the outer surface of the guide element (2) is convex at the places provided for contacting the guide rail (1) in the mounted state of the guide system executed. Guide system according to one of the preceding claims, characterized in that the guide element (2) is mainly made of plastic. Guide system according to one of the preceding claims, characterized in that the guide element (2) is mainly made of polyoxymethylene copolymer. A sliding door device comprising - a sliding door leaf, which comprises a hollow profile (3), the cavity of which at one end of this profile (3) opens into the lower edge of the sliding door leaf; - a guide rail (1) which is arranged under the sliding door leaf; - and a guide element (2) telescopically arranged at the bottom of the hollow profile (3) such that a downward force acts on this guide element (2), which drives the guide element (2) towards the guide rail (1), in order to moving the sliding door leaf relative to the guide rail (1), keeping the guide element (2) in contact with the guide rail (1); characterized in that the guide element (2) is wheel-less and rigid and always extends partially in the hollow profile (3) when this guide element is telescopically arranged in the hollow profile (3) and is in contact with the guide rail (1) . Sliding door device according to claim 12, characterized in that the hollow profile (3) extends on a lateral side of the sliding door leaf. A sliding door device according to claim 12 or 13, characterized in that said sliding door device comprises a guide system according to one of claims 1 to 9, wherein said guide rail and said guide element of this sliding door device form part of this guide system.