DE9007682U1 - Component for the construction industry - Google Patents

Description

31.504/70-Rl

Engineering office for structural scaffolding
Klaus Bürger & Partner
Terrassenstrasse 31, 1000 Berlin 38

Component for the construction industry

For the disposal of environmentally contaminated buildings or similar,
necessary to enclose the building to be disposed of, i.e. to enclose it with an auxiliary structure and to create a slight negative pressure in the space thus enclosed in order to
pollutants arising during building disposal

prevent it from escaping into the environment. Tarpaulins are used for such coverings, for example, which are easy and time-saving to install, but which have the disadvantage that their thermal insulation properties are inadequate, resulting in relatively large heat losses.

Furthermore, there are known building elements for the construction industry that are intended for hall roofs. If roof structures with a larger span are to be created using such known building elements, it is necessary to combine these building elements with a substructure in order to ensure sufficient static strength. However, such substructures require material expenditure and in particular assembly expenditure, which have an impact on the manufacturing costs of known roof structures. Furthermore, such substructures often impair the overall visual impression of the roof structure, which can be seen as a disadvantage in the case of roof structures for tennis or riding halls, for example.

The invention is based on the object of creating a construction element for the construction industry which is simple and inexpensive to manufacture, which is easy to assemble, and which is well suited as a construction element for roof structures - without being limited to this use - and which, when used in roof structures up to large spans, does not require a substructure.

This object is achieved according to the invention by a flat cover element with a square base and two stiffening elements, which are attached to two opposite first edge sections of the cover element and protrude from the cover element perpendicularly, parallel to each other and in the same direction, whereby each stiffening element has two

spaced-apart spacer elements have wall parts that are spaced-apart and run at least approximately parallel to one another, with one spacer element resting on the ceiling element and the second spacer element, which is spaced away from the ceiling element, having a channel designed to accommodate a tensioning element and running in the longitudinal direction of the second spacer element, and a cavity is defined in the corresponding stiffening element by the two spacer elements and the two wall elements. The two spaced-apart and parallel stiffening elements result in an excellent bending strength even in the case of a relatively thin-walled flat ceiling element, so that such construction elements are excellently suited for roof structures. Since the stiffening elements themselves are box-shaped due to the two spaced-apart spacers and the wall sections spaced apart by the spacers, the stiffening elements have excellent flexural rigidity despite being relatively light, so that structural elements designed in this way are easy to handle and require little effort. This means that structural elements of this kind are well suited for roof structures on buildings, whereby these buildings can be either permanent or temporary buildings. Temporary buildings are intended for example for so-called beer halls, marquees, buildings for enclosing buildings to be disposed of, etc. The design of the spacer element, which is remote from the flat cover element, of each of the two stiffening elements of the structural element according to the invention with a longitudinally extending groove, which is provided for receiving a clamping element, results in the advantage that a clamping element can be arranged in the groove of the corresponding spacer element in such a way that the corresponding clamping element in the

structural element and thus is not visible from any side in the roof construction made with such structural elements, for example. The tensioning elements, which can be steel rods, steel cables or the like, mechanically stiffen the construction, i.e. the assembly of a large number of structural elements according to the invention, particularly in roof constructions, in such a way that the otherwise usual substructures for meeting the static conditions can be dispensed with. The box-shaped design of the stiffening elements of each structural element has the advantage of a considerable reduction in weight with good mechanical strength, as well as the advantage that connecting elements can be arranged or pushed through in the cavities of neighboring structural elements, through which neighboring structural elements can be connected to one another.

It has proven to be advantageous if the channel used to accommodate a tensioning element is provided in the base area of the second spacer element facing away from the cover element and is formed in the middle area of the base area of the corresponding spacer element, and if a cover element is attached to the base area of the/each second spacer element so that the corresponding channel forms a channel. Such a channel in the base area of the second spacer element is easy to manufacture. By forming the channel in the middle area of the base area of the corresponding spacer element, symmetrical force relationships arise when the tensioning element located in the channel is tensioned, e.g. in the form of a tensioning cable. The cover element for covering the channel in the corresponding spacer element serves in particular to hold the corresponding tensioning element and to protect the tensioning element in the component according to the invention against contact and therefore against damage. This also creates a favorable visual impression because the clamping elements are not visible.

In the construction element according to the invention, the spacer elements can be made of squared timber and the wall parts of wooden panels. Of course, it would also be possible to use other materials for the spacer elements and the wall parts of each stiffening element. The construction elements of the last-mentioned type with spacer elements made of squared timber and wall parts made of wooden panels, however, have the advantage that they are easy to manufacture and easy to handle, so that such construction elements are particularly suitable for the manufacture of roof structures for buildings that are to be permanently erected or, in particular, for buildings that are to be erected temporarily.

If such building elements are intended for temporary buildings, which are intended, for example, to envelop buildings to be disposed of, it is advantageous if the building elements are covered with a light coating on the inside facing the building to be disposed of, in order to be able to quickly identify pollutants deposited on this inside and dispose of them if necessary.

In order to achieve good heat and sound insulation in the construction element according to the invention with a relatively thin-walled cover element, it is advantageous if the cover element is formed by at least one multi-layer plate, whereby the/each plate has a central core layer and cover layers on the two main surfaces of the core layer. Such a laminate structure results in good mechanical stability properties even with relatively small wall thicknesses, which is particularly important for such construction elements when they are used for roof constructions or wall constructions. The heat and sound insulation properties are particularly guaranteed in such a construction element when the/each core layer is made of a plastic foam material and each cover layer is made of a

In order to be able to easily identify pollutants that settle on the building element, it is - as already mentioned - advantageous if at least the inside of the cover layer or metal sheet facing the building to be disposed of is provided with a light coating.

Preferably, bulkhead elements are attached to the two second edge sections of the cover element of the inventive structural element, which are perpendicular to the two first edge sections, and which protrude from the corresponding side edge section of the cover element perpendicularly, parallel to one another and in the same direction as the two associated stiffening elements, whereby each bulkhead element can have two recesses aligned with the two channels provided for receiving a tensioning element and two recesses aligned with the hollow spaces of the stiffening elements. By designing each structural element with two bulkhead elements spaced apart from one another and parallel to one another, the assembly of such structural elements along a straight row is significantly simplified without causing undesirable tilting or pivoting of neighboring structural elements. The bulkhead elements therefore serve to simplify the assembly of such structural elements. In addition, they serve to further stiffen a roof structure.

As already mentioned, each cavity of the box-shaped stiffening element is preferably designed to precisely accommodate a connecting element that connects adjacent components to one another. The connecting elements can be simply designed as a square disc or board and have a cross-sectional profile that corresponds to the clear cross-section of the cavity in the

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box-shaped stiffening element. The connecting elements for connecting adjacent structural elements are made of wood, for example.

In the construction element according to the invention, the/each flat cover element can be designed to be flat, and the two associated stiffening elements can have a rectangular main surface. With construction elements designed in this way, it is possible to create a straight-line flat structure by assembling several such construction elements, which can be used, for example, as a wall element or as a roof element.

In another construction element according to the invention, the/each flat cover element is designed to be angled in the shape of a gable, and the two associated stiffening elements have a symmetrical pentagonal main surface, with the two side walls spaced apart from one another being aligned perpendicularly to the associated gable walls. Such gable construction elements can be combined with the flat construction elements described above in order to create a roof structure with a gable.

In the case of a gable roof construction that exceeds a certain maximum span, the roof construction, which usually rests on support parts, can have a sub-tension. This sub-tension, which connects the support parts to one another, can be implemented using tension cables or tension rods. Such sub-tensions are visually insignificant and require significantly less material and assembly than conventional sub-structures, which are designed as half-timbered structures, for example.

The construction element according to the invention is therefore - as has already been mentioned several times - preferably suitable for a self-supporting roof construction of a building or as a wall and/or ceiling element for a room cell.

Further details, features and advantages emerge from the following description of an embodiment of the component according to the invention shown in the drawing as well as an example of use of components according to the invention. It shows:

Fig. 1 is a front view of a roof construction made of inventive components of different sizes, the roof construction being drawn in two parts for reasons of space, the connection of the two parts of the roof construction drawn one above the other being indicated by thin dash-dotted lines.

Fig. 2 a top view of the roof construction according to Fig. 1 in the direction of arrow II in Fig. 1, where, for reasons of space, the roof construction is also drawn in two parts, which are connected by a thin dash-dotted line,

Fig. 3 is a section through a component along the section line III-III in Fig. 2, and

Fig. 4 shows a section along the section line IV-IV in Fig. 2, whereby this section runs exactly between two adjacent components that collide.

Fig. 1 shows a roof construction made of components 10 of different lengths, with adjacent components 10 being connected by means of connecting elements 12. Each component 10 has - as can be clearly seen from Fig. 3 - a flat cover element 14, from the end sections 16 facing away from each other stiffening elements 18 protrude. Each stiffening element 18 has two spaced-apart spacer elements 20 and two wall parts 22, so that each stiffening element 18 is box-shaped. The spacer element 20 of each stiffening element 18, which is spaced away from the cover element 14, is formed with a groove 24, which is formed on the base surface 26 facing away from the cover element 14 in a middle section thereof. The base surface 26 of the spacer element 20, which is formed with the gutter 24 and is removed from the cover element, is provided with a cover element, so that the gutter 24 is closed off to form a channel. A tensioning element 30, which is indicated in Fig. 1 by a thin dash-dotted line, can be arranged in this channel, which extends through all the components 10. This tensioning element 30 can be a rope or rods connected to one another, with the tensioning element 30 being dimensioned in such a way that the desired strength of the roof construction is ensured.

In order to be able to arrange the individual components 10 in a line in a simple and time-saving manner, as indicated in Fig. 2, bulkhead elements 34 are provided on the two second edge sections 32 of the components 10 that are perpendicular to the first end sections 16, which protrude from the two spaced-apart second edge sections 32 in the same direction as the stiffening elements 18, as can be seen in Fig. 4. Each of the two bulkhead elements 34 of a component 10 has the two grooves 24

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aligned recesses 36 and; cutouts 38, whereby the last-mentioned recesses 38 are aligned with the cavities 40 which are delimited in the stiffening elements 18 by the two spacer elements 20 and the two wall parts 22.

After the section according to Fig. 4 has been made through two adjacent, joined drilling elements 10, two connecting elements 12 can be seen in section from Fig. 4. It can also be seen from Figures 3 and 4 that the cover element 14 of the/each component 10 is designed in multiple layers, i.e. it has a central core layer 40 and cover layers 42 covering the core layer 40 on all sides.

From Fig. 1 it can also be seen that the roof construction is composed of a number of components 10, in which the cover element 14 is flat and in which the associated stiffening elements 14 are rectangular. These components are connected in the middle to a component 10 which has two symmetrical pentagonal stiffening elements 18 and a gable-shaped angled cover element 14. Only one of these two spacer elements 18 is visible in Fig. 1, because the second stiffening element 18 is exactly covered by the first stiffening element 18. The component 10 forming the gable is cut in the middle in Fig. 1 and drawn offset for reasons of space, with the thin dash-dotted line 44 indicating that the two parts of the roof construction drawn offset from one another belong together.

In the various figures, identical details are designated by the same reference numerals, so that it is unnecessary to describe all of these details in detail in connection with the individual figures.

Fig. 1 also shows that the roof structure rests on support parts 46, whereby the tensioning elements 30 are clamped and fixed with their ends that are at a distance from one another to the associated rear wall 48 of the support parts 46. If the span of the roof structure exceeds a certain amount, which can be 25 m, for example, a sub-tension 50 is provided between the opposing support parts 46, which, in the case of large spans, ensures the required static strength of the roof structure together with the tensioning elements 30. The dash-dotted line 52 in Fig. 1 indicates that the two partial lengths of the sub-tension 50, which are interrupted and drawn separately for reasons of space, belong together.

The support parts 46 rest on elements 54 drawn in sections, which can be, for example, support columns, scaffolding, walls, etc.

Claims (1)

31.504/70-Rl Engineering office for structural scaffolding Klaus Bürger & Partner
Terrassenstrasse 31, 1000 Berlin 38 Expectations 1. Component for the construction industry, characterized by a flat cover element (14) with a square base and two stiffening elements (18) which are attached to two opposite first edge sections (16) of the cover element (14) and protrude from the cover element (14) perpendicularly, parallel to one another and in the same direction, each stiffening element (18) having two wall parts (22) which are spaced apart from one another by spaced-apart spacer elements (20) and run at least approximately parallel to one another, • ■ · wherein one spacer element (20) rests against the cover element (14) and the second spacer element (20) remote from the cover element (14) has a groove (24) provided for receiving a clamping element (30) and running in the longitudinal direction of the corresponding spacer element (20), and a cavity (39) is defined in the corresponding stiffening element (18) by the two spacer elements (20) and the two wall parts (22). 2. Component according to claim 1,
characterized in that the groove (24) serving to receive a clamping element (30) is provided in the base surface (26) of the second spacer element (20) facing away from the cover element (14) and is formed in the central region of the base surface (26) of the corresponding spacer element (20), and that a cover element (28) is fastened to the base surface (26) of the/each second spacer element (20), so that the corresponding groove (24) forms a channel. 3. Construction element according to claim 1 or 2, characterized in that the spacer elements (20) consist of squared timber and the wall parts (22) of each stiffening element (18) consist of wooden panels. 4. Component according to claim 1 or 2, characterized in that the cover element (14) is formed by at least one multi-layer plate, wherein the/each plate has a central core layer (40) and cover layers (42) on the two main surfaces of the core layer (40). &Idigr;4 . Component according to claim 4, characterized in that the/each core layer (40) consists of a plastic foam material and each cover layer (42) consists of a metal sheet. 6. Component according to one of the preceding claims, characterized in that bulkhead elements (34) are attached to the two second edge sections (32) of the/each cover element (14) that are perpendicular to the two first edge sections (16), which bulkhead elements (34) protrude perpendicularly from the corresponding second edge section (32) of the cover element (14), parallel to one another and in the same direction as the two associated stiffening elements (18), each bulkhead element (34) having two recesses (36) that are aligned with the two grooves (24) provided for receiving a tensioning element (30) and two recesses (38) that are aligned with the cavities (39) of the stiffening elements (18). 7. Component according to one of the preceding claims, characterized in that the cavity (39) of the stiffening element (18) is provided for the precise reception of a connecting element (12) connecting adjacent components (10). 8. Component according to one of claims 1 to 7, characterized in. that the/each flat cover element (14) is flat and that the two associated stiffening elements (18) have a rectangular base area. 9. Construction element according to one of claims 1 to 7, characterized in that the/each flat cover element (14) is designed in a gable-shaped angled manner, and in that the two associated stiffening elements (18) have a symmetrical pentagonal base area, wherein the two side edges spaced apart from one another are aligned perpendicularly to the associated gable edges.