DE20120836U1 - Roof balcony, terrace, loggia or the like. - Google Patents

Description

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LEINE & WAGNER

PATENT ATTORNEYS ■ EUROPEAN PATENT & TRADEMARK ATTORNEYS

Dipl.-Ing. Sigurd Leine Dipl.-Ing. Carsten Wagner

Burckhardtstraße 1 D-30163 Hanover

Telephone (0511) 62 30 Fax (0511) 62 21

Fiber-reinforced plastics
GmbH Dessau

Our sign date

556/002 21.12.2001 cw / Ii

Roof balcony, terrace, loggia or similar

The invention relates to a roof balcony, a roof terrace, a roof loggia or the like of the type mentioned in the preamble of claim 1.

EP 0 744 505 A1 discloses a roof balcony of the type in question, which has a floor element and at least four wall elements, the weather-side surfaces of the floor element and the wall elements being designed as a one-piece weather shell made of plastic, and at least in the area of the wall elements, a room-side shell made of individual, possibly load-bearing panels made of fiber-reinforced, inorganic and/or organic material is provided, spaced from the weather shell by hollow plastic profiles. The floor element here consists of a glass-fiber-reinforced polyester. The roof balcony known from the publication is designed as a prefabricated component. In this way, not only is a considerable reduction in costs and time saved during assembly, but also a consistently high structural quality of the roof balcony or the like is achieved.

The invention is based on the object of specifying a roof balcony or the like of the type mentioned in the preamble of claim 1, in which the stability of the floor element is improved.

This problem is solved by the teaching set out in claim 1.

According to the invention, the floor element is at least partially formed by a multi-layered plastic plate. In this way, the stability of the floor element is significantly increased, so that the floor element can be designed with a larger surface area compared to the prior art. The floor element according to the invention can therefore also be used, for example, for large roof terraces.

In the roof balcony known from the prior art, the floor element is supported on a substructure via supports. Due to the higher stability of the floor element according to the invention, the distance between the supports can be increased in the roof balcony according to the invention or the like. In this way, the construction of the roof balcony according to the invention is simpler and therefore more cost-effective. Due to the larger distance between the supports, structural unevenness can be better compensated or bridged.

A further advantage of the roof balcony or the like according to the invention is that it is simple and therefore inexpensive to manufacture.

The teaching according to the invention is particularly applicable to roof balconies, terraces, loggias or the like.

In principle, it is sufficient if the plate, which at least partially forms the floor element, is made up of two layers. A particularly advantageous development of the teaching according to the invention provides that the plate is made up of three layers and has a core layer accommodated between two cover layers. This embodiment results in particularly high stability and at the same time is cost-effective to manufacture.

In order to further increase the stability of the panel, it is advisable for the cover layers to be made of a fibre-reinforced plastic, in particular glass fibre-reinforced plastic.

The plastic can be selected within wide limits. An advantageous further development provides that the plastic is a stabilized polyester resin.

Such polyester resins are highly stable when cured and are easy to process.

The core layer of the floor element according to the invention can consist of any suitable plastic. The plastic is expediently a polyurethane foam. This results in particularly high stability and easy processing.

The plastic of the core layer preferably has a density of at least 55 kg/ ^cm1 .

An extremely advantageous development of the teaching according to the invention provides that the cover layers are connected to one another by connecting elements which extend through the core layer. In this way, the compressive strength of the floor element according to the invention is further increased.

In the aforementioned embodiment, the connecting elements are preferably designed in a column-like manner, as provided for in a further development.

In principle, the connecting elements can be formed by separate components. In order to simplify production and thus make it cost-effective, it is advantageous for the connecting elements to be molded into the core layer and/or molded onto the cover layers.

A particularly simple production is achieved by the fact that the connecting elements are made of the same

material as the cover layers. In this embodiment, for example, through holes can be provided in the core layer, into which the material of the cover layers penetrates when the cover layers are applied and forms the connecting elements after hardening.

To further increase the compressive strength of the floor element, it is advisable that the height of the connecting elements is at least four times their diameter.

Another development of the teaching according to the invention provides that the top of the plate is provided with a further layer. This further layer can be non-slip and/or colored and/or patterned, as provided for in one development. In this embodiment, the floor element according to the invention can be designed to be non-slip and/or visually particularly attractive.

The material of the additional layer can be selected within wide limits according to the respective requirements. A practical embodiment provides that the additional layer consists of a filled polyurethane resin. Such polyurethane resins form a particularly resistant surface after hardening.

In principle, the floor element of the roof balcony according to the invention can be designed as a separate component which is connected on site during assembly of the roof balcony according to the invention, for example, to wall elements. A particularly advantageous further development of the teaching according to the invention provides that wall elements are provided and that at least the weather-side surfaces of the floor element and the wall elements form a one-piece weather shell made of plastic. In this embodiment, the weather shell is

prefabricated in one piece, so that the assembly of the roof balcony according to the invention is facilitated. In particular, the roof balcony according to the invention can be designed as a prefabricated component.

In a roof balcony according to the invention that is designed as a prefabricated component, it is expedient for the weather shell to be supported by supports on a shell on the room side. In this embodiment, the weather shell and the shell on the room side can be firmly connected to one another via the supports, so that the degree of prefabrication of the roof balcony according to the invention is further increased.

A floor element according to the invention is specified in claim 17. Advantageous and expedient further developments of the floor element according to the invention are specified in subclaims 18 to 32.

The invention is further based on the object of specifying a roof balcony or the like of the type mentioned in the preamble of claim 33, the assembly of which is further simplified.

This problem is solved by the teaching set out in claim 33.

The teaching of claim 33 is based on the fact that a roof balcony generally requires a slight _gradient of, for example, 1% to promote the drainage of water, for example to a drain. The basic idea of the teaching according to the invention is to design the supports with which the floor element is supported on the substructure, for example a room-side shell, in such a way that the required gradient is achieved when connecting the floor element to the supports without any further measures. For this purpose, the supports are designed or arranged according to the invention in such a way that the floor element is in a

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The drainage direction is arranged at an incline.

In this way, additional measures for creating a slope of the floor element are no longer necessary, so that the assembly of the roof balcony according to the invention is further simplified and thus more cost-effective.

A particularly advantageous embodiment of the basic idea of the invention is that the supports extend in the drainage direction and have a height that decreases in the drainage direction. In this embodiment, a cross-section of the supports that tapers in the drainage direction ensures that when the floor element is placed on the supports, the desired gradient, which can be selected within wide limits, is achieved without additional measures.

Another embodiment of the basic idea of the invention provides that the supports extend transversely to the direction of flow and that successive supports in the direction of flow have a height that decreases in the direction of flow. In this embodiment, supports with a constant cross-section over their length can be used. The desired gradient is achieved in this embodiment by using supports of different heights, namely those that decrease in the direction of flow.

In order to reduce the weight of the roof balcony according to the invention and to make its production more cost-effective, it is expedient for the supports to be hollow profiles, in particular hollow plastic profiles.

0 In order to increase the stability of the supports in the above-mentioned embodiment, it is advantageous that at least some of the hollow profiles have a reinforcing insert.

In order to use the roof balcony or similar according to the invention

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In order to form the roof balcony as a prefabricated component as possible, an advantageous further development provides that the substructure is designed as a shell on the room side and that the floor element is firmly connected to the shell on the room side via the supports. In this embodiment, the degree of prefabrication of the roof balcony according to the invention is increased and assembly is thus made considerably easier.

An advantageous further development of the aforementioned embodiment provides that the supports are made of plastic and are laminated into the floor element and the room-side shell or are laminated to the floor element and the room-side shell.

The invention is explained in more detail below with reference to the accompanying drawings, in which an embodiment of the invention is shown which is designed as a loggia.

It shows:

Fig. 1 is a partial perspective view of a loggia according to the invention in the installed state,
;; Fig. 2 a highly schematic sectional view

of a floor element according to the invention, Fig. 3 is a perspective view not to scale 5 of a roof loggia according to

Fig. 1 used carrier and

Fig. 4 is a highly schematic perspective partial view of a floor element according to the invention.
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Fig. 1 shows an embodiment of a loggia 2 according to the invention in the installed state. The loggia 2 is designed as a prefabricated component and has a floor element 4, which is described below with reference to Fig. 2

is formed by a multi-layered plastic plate, as explained in more detail. The floor element 4 in this embodiment is trough-shaped and formed in one piece with wall elements, of which only a ridge-side wall element 6 and a verge-side wall element 8 can be seen in the drawing. In this embodiment, the floor element 4 forms a one-piece weather shell with the wall elements 6, 8 and the other wall elements not shown. If necessary according to the respective requirements, the floor element 4 and the wall elements 6, 8 can also be formed separately. The loggia 2 according to the invention in this embodiment is designed with two shells and has a room-side shell 10 which consists of panels 12, for example chipboard or the like, which are laminated with a vapor barrier film 14 on the side facing the floor element 4. The floor element 4 is supported on the room-side shell 10 via U-shaped or hat-shaped supports in cross-section, whereby in Fig. 1 only one support is provided with the reference number 16. In this embodiment, the supports 16 are formed by plastic hollow profiles which are laminated to the underside of the floor element 4 and the top of the room-side shell 10, so that the floor element 4 is firmly connected to the room-side shell 10 and in this way the loggia 2 is designed as a pre-assembled prefabricated component which is assembled as a whole on site at a construction site.

0 The supports 16 are designed according to the invention in such a way that the floor element 4 is arranged inclined in a direction symbolized by an arrow 18 in Fig. 1, in the embodiment towards the ridge-side end of the floor element 4. In this way

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A gradient is formed which ensures that water collecting on the floor element 4 flows towards the eaves-side end of the floor element 4, where a drainage opening 20 is provided which is connected to a drainage pipe 22. In this exemplary embodiment, the supports 16 extend in the drainage direction 18 and have a height which decreases in their longitudinal direction, i.e. in the drainage direction, so that when the floor element 4 is placed on the supports 16, a gradient is formed in the desired manner towards the eaves-side end of the floor element 4. The gradient can be selected according to the respective requirements, whereby a slight gradient of, for example, 1% is sufficient. The supports 16 can be provided with a reinforcing insert 23 if necessary.

As an alternative to the use of supports 16 with a height that decreases in the direction of flow, supports with a constant height along their longitudinal direction can also be used, wherein the supports then extend transversely to the direction of flow 18 and successive supports in the direction of flow 18 have a height that decreases in the direction of flow 18.

Fig. 2 shows a section through the floor element 2, which in this embodiment is formed by a three-layer plate in which a core layer 28 is accommodated between two cover layers 24, 26. In this embodiment, the cover layers 24, 26 consist of a stabilized polyester resin which is reinforced with glass fibers 30. The core layer 28 consists of a polyurethane foam with a bulk density of at least 55 kg/cm ³ .

In this embodiment, the cover layers 24, 26 are connected to each other by column-like connecting elements, of which only

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a connecting element is provided with the reference number 32. In this embodiment, the connecting elements 32 are formed into the core layer 28 and molded onto the cover layers 24, 26 and consist of the same material as the cover layers 24, 26. The cover layers 24, 26 and the connecting elements 32 can be produced, for example, in such a way that a plate provided with through holes 34 is used as the core layer 28 and a glass fiber reinforced, stabilized polyester resin is applied to this plate, which penetrates into the through holes 34 and thus connects the cover layers 24, 26 formed on both sides of the core layer 28 to one another.

Due to the multi-layer structure of the floor element 4, it has a particularly high level of stability. The stability, in particular the compressive strength of the floor element 4, is increased even further by the connecting elements 32, since the cover layers 24, 26 are supported on one another in the area of the connecting elements 32, so that the compressive load on the core layer 28 is reduced.

In this embodiment, a further layer 36 is applied to the top of the upper cover layer 24, which can be, for example, non-slip and/or colored and/or patterned. In this way, the floor element 4 is designed to be non-slip and/or visually appealing. In this embodiment, the further layer 36 consists of a filled polyurethane resin.

Fig. 3 shows a perspective view (not to scale) of a support 16 used in the loggia 2 according to Fig. 1. As can be seen from Fig. 3, the support 16 has a longitudinally extending

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The support 16 has a height that decreases in the direction of flow 18, so that the support 16 is essentially wedge-shaped. For illustration purposes, the height difference between the ridge-side end 38 and the eaves-side end 40 of the support 16 is exaggerated. This height difference is dimensioned such that a gradient of, for example, 1%, is achieved in accordance with the respective requirements. In this embodiment, the support 16 is formed by an essentially U-shaped hollow plastic profile, with the legs 42, 44 of the hollow plastic profile having bevels 46, 48 on which the floor element 4 is supported in the assembly position (see Fig. 1).

Fig. 4 shows the floor element 14, which is supported on the room-side shell 10 via the supports 16.

As can be seen from Fig. 4, due to the design of the supports 16 with a height that decreases in the drainage direction 18, a gradient is formed in the desired manner, so that water collecting on the floor element 4, for example rainwater, flows in the drainage direction 18 to the eaves-side end of the floor element 4 and can be drained off via the drainage opening 20 and the drainage pipe 22, for example to a gutter. In this way, water is prevented from standing on the floor element 4.

Due to the inventive design of the floor element 4 as a multi-layer plate, the stability of the floor element 4 is significantly increased, so that the floor element can be designed to be particularly large and can also be used, for example, for large terraces or the like. Due to the increased stability of the floor element 4, the lateral distance between the supports 16 can be larger than in the prior art. In addition, structural

- 12 technical irregularities can be more easily compensated.

Claims (39)

1. Roof balcony, terrace, loggia or the like, with a floor element, characterized in that the floor element ( 4 ) is at least partially formed by a multi-layer plate made of plastic. 2. Roof balcony or the like according to claim 1, characterized in that the panel is constructed in three layers and has a core layer ( 28 ) accommodated between two cover layers ( 24 , 26 ). 3. Roof balcony or the like according to claim 2, characterized in that the cover layers ( 24 , 26 ) consist of a fiber-reinforced, in particular glass-fiber-reinforced plastic. 4. Roof balcony or the like according to claim 3, characterized in that the plastic is a stabilized polyester resin. 5. Roof balcony or the like according to claim 2, characterized in that the core layer ( 28 ) consists of a polyurethane foam. 6. Roof balcony or the like according to claim 2, characterized in that the plastic of the core layer ( 28 ) has a bulk density of at least 55 kg/cm ³ . 7. Roof balcony or the like according to claim 2, characterized in that the cover layers ( 24 , 26 ) are connected to one another by connecting elements ( 32 ) which extend through the core layer ( 28 ). 8. Roof balcony or the like according to claim 7, characterized in that the connecting elements ( 32 ) are column-shaped. 9. Roof balcony or the like according to claim 7, characterized in that the connecting elements ( 32 ) are molded into the core layer and/or molded onto the cover layers ( 24 , 26 ). 10. Roof balcony or the like according to claim 7, characterized in that the connecting elements ( 32 ) consist of the same material as the cover layers ( 24 , 26 ). 11. Roof balcony or the like according to claim 7, characterized in that the height of the connecting elements ( 32 ) corresponds to at least four times their diameter. 12. Roof balcony or the like according to claim 2, characterized in that the upper side of the plate is provided with a further layer ( 36 ). 13. Roof balcony or the like according to claim 12, characterized in that the further layer ( 36 ) is non-slip and/or colored and/or patterned. 14. Roof balcony or the like according to claim 12, characterized in that the further layer ( 36 ) consists of a filled polyurethane resin. 15. Roof balcony or the like according to claim 1, characterized in that wall elements ( 6 , 8 ) are provided and that at least the weather-side surfaces of the floor element ( 4 ) and the wall elements ( 6 , 8 ) form a one-piece weather shell made of plastic. 16. Roof balcony or the like according to claim 15, characterized in that the weather shell is supported by supports ( 16 ) on a room-side shell ( 10 ), preferably being firmly connected to the same. 17. Floor element for a roof balcony or the like, characterized in that the floor element ( 4 ) is at least partially formed by a multi-layer plate made of plastic. 18. Floor element according to claim 17, characterized in that the plate is constructed in three layers and has a core layer ( 28 ) accommodated between two cover layers ( 24 , 26 ). 19. Floor element according to claim 18, characterized in that the cover layers ( 24 , 26 ) consist of a fiber-reinforced, in particular glass-fiber-reinforced plastic. 20. Floor element according to claim 19, characterized in that the plastic is a stabilized polyester resin. 21. Floor element according to claim 18, characterized in that the core layer ( 28 ) consists of a polyurethane foam. 22. Floor element according to claim 18, characterized in that the plastic of the core layer ( 28 ) has a bulk density of at least 55 kg/cm ³ . 23. Floor element according to claim 17, characterized in that the cover layers ( 24 , 26 ) are connected to one another by connecting elements ( 32 ) which extend through the core layer ( 28 ). 24. Floor element according to claim 22, characterized in that the connecting elements ( 32 ) are column-shaped. 25. Floor element according to claim 23, characterized in that the connecting elements ( 32 ) are molded into the core layer ( 28 ) and/or molded onto the cover layers ( 24 , 26 ). 26. Floor element according to claim 23, characterized in that the connecting elements ( 32 ) consist of the same material as the cover layers ( 24 , 26 ). 27. Floor element according to claim 23, characterized in that the height of the connecting elements ( 32 ) corresponds to at least four times their diameter. 28. Floor element according to claim 17, characterized in that the upper side of the plate is provided with a further layer ( 36 ). 29. Floor element according to claim 28, characterized in that the further layer ( 36 ) is non-slip and/or colored and/or patterned. 30. Floor element according to claim 28, characterized in that the further layer ( 36 ) consists of a filled polyurethane resin. 31. Floor element according to claim 17, characterized in that wall elements ( 6 , 8 ) are provided and that at least the weather-side surfaces of the floor element ( 4 ) and the wall elements ( 6 , 8 ) form a one-piece weather shell made of plastic. 32. Floor element according to claim 31, characterized in that the weather shell is supported on a shell on the room side via supports ( 16 ). 33. Roof balcony, terrace, loggia or the like, with a floor element which is supported on a substructure via supports, characterized in that the supports ( 16 ) are designed or arranged such that the floor element is arranged inclined in a drainage direction. 34. Roof balcony or the like according to claim 33, characterized in that the supports ( 16 ) extend in the drainage direction ( 18 ) and have a height decreasing in the drainage direction. 35. Roof balcony or the like according to claim 33, characterized in that the supports extend transversely to the drainage direction ( 18 ) and that successive supports in the drainage direction ( 18 ) have a height decreasing in the drainage direction ( 18 ). 36. Roof balcony or the like according to claim 33, characterized in that the supports ( 16 ) are hollow profiles, in particular plastic hollow profiles. 37. Roof balcony or the like according to claim 36, characterized in that at least some of the hollow profiles have a reinforcement system. 38. Roof balcony or the like according to claim 33, characterized in that the substructure is designed as a room-side shell ( 10 ) and that the floor element ( 4 ) is firmly connected to the room-side shell ( 10 ) via the supports ( 16 ). 39. Roof balcony or the like according to claim 38, characterized in that the supports ( 16 ) consist of plastic and are laminated into the floor element ( 4 ) and into the room-side shell ( 10 ) or are laminated to the floor element ( 4 ) and the room-side shell ( 10 ).