DE20010281U1 - Wall element for buildings - Google Patents

Description

Wall element for buildings

The present invention relates to a prefabricated wall element for buildings according to claim 1.

Prefabricated wall elements, in particular external walls of prefabricated houses or similar buildings, are known from the general state of the art. These consist of several surface elements and an external cladding with a thermal insulation plaster system. Such wall elements comprise a base body made of expanded clay onto which the thermal insulation plaster system is applied.

Such prefabricated wall elements have the disadvantage that they are relatively heavy and require a considerable wall thickness to achieve a certain K-value.

The object of the present invention is to create a prefabricated wall element which is considerably lighter than known prefabricated wall elements and which achieves a predetermined K-value even with a considerably lower wall thickness than conventional wall elements or has a considerably lower K-value than conventional wall elements with the same thickness.

The problem is solved by the features of claim 1.

By forming a base shell and a support frame attached to it, which defines at least one field in the wall plane, into which an insulation element is fitted, the weight of the prefabricated wall element is reduced by around 33% compared to a standard wall made of expanded clay with the same wall thickness. Furthermore, the K value is significantly reduced with the same wall thickness.

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Further advantages result from the features of subclaims 2 to 6.

An embodiment of the present invention is described in more detail below with reference to the drawings.

Hm2001bnew

Fig. 1 is a schematic perspective view of a wall element according to the present invention, partially cut away;

Fig. 2 shows a schematic, perspective system section through the wall element from Fig. 1;

Fig. 3 is a schematic perspective top view of a horizontal inner grid shell

with lattice girders for a wall element from Fig. 1; and Fig. 4 is a bar diagram showing different building materials depending on

their K-value and the respective wall thickness. 10

In Fig. 1 and 2, a wall element 100 is shown which is a composite part made of several elements. The wall element 100 essentially comprises a base shell 1, e.g. made of lightweight concrete. The base shell 1 faces the viewer with an outer surface 1.1 of the base shell and in the present embodiment has a thickness of 10 cm. A framework 2 is attached to the base shell 1, which also consists of e.g. lightweight concrete. Other lightweight materials are also conceivable for both the base shell 1 and the framework 2 in other designs.

In the present embodiment, the framework 2 has a plurality of parallel, load-bearing supports 2.1 which, when the wall element 100 is assembled, run essentially vertically and are connected to one another via an upper cross member 2.2 and a lower cross member 2.3. The cross members 2.2 and 2.3 preferably also run parallel to one another. The load-bearing supports 2.1 and 2.2 as well as the cross members 2.2 and 2.3 each enclose a field 2.4. The framework 2 has the function of supporting load transfer and stiffening of the wall element 100. The size of the fields, i.e. the distance between the load-bearing supports 2.1 and the cross members 2.2 and 2.3, can be determined as required. In the present embodiment, the fields have a dimension of 2.44 cm x 100 cm. Depending on the selected size of the wall element 100, one or more fields 2.4 are located next to each other. In other embodiments, it is also conceivable to vary the geometric shape of the fields 2.4. In individual cases, it can be provided that the supporting supports 2.1 are not parallel to each other and do not form a right angle with the respective cross beams 2.2 and 2.3, as is the case in the embodiment shown in Fig. 1. In principle,

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zip it is also possible for the fields 2.4 to be triangular, polygonal or round, for example. The framework 2 is preferably made in one piece.

The framework 2 or the load-bearing supports 2.1 and the cross beams 2.2 and 2.3 form a common frame outer surface 2.5, which preferably lies in one plane.

An insulating element 2 is inserted into each field 2.4 of the framework 2. In the present embodiment, the insulating element 3 is a thermal insulation panel of thermal conductivity group 030 with dimensions of 2.44 cm x 100 cm and a thickness of 10 cm and is fitted exactly into each field 2.4 of the framework 2. The unit thus formed forms the basic structure for the wall element 100 according to the invention. The formation of the fields 2.4 results in an enormous weight saving of approx. 33% and the insertion of insulating elements 3 achieves a better K value. To complete and perfect this basic structure, a thermal insulation panel 4 is applied to the outer surface 2.5 of the framework 2 and an insulating element outer surface 3.1, which also takes on the function of a plaster base. Preferably, the thermal insulation panel 4 has a thickness of 10 cm and is flush with the outer edges of the frame element 2.

The thickness of the thermal insulation panels 4 can be varied depending on the thickness of the entire wall element 100 and can be, for example, 12 cm or 15 cm or other values.

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A fabric coating with finishing plaster 5 is applied to the thermal insulation board 4.

In the following table, the wall element 100 is shown in three different thicknesses with the corresponding achieved K values, specifying the basic designations for the building elements described above. The different thicknesses result from the variation in the thicknesses of the thermal insulation panels 4 described above.

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lim2001bnew

Pos. Wandl Wall 2 Wall 3 1 10 centimeters 10 centimeters 10 centimeters 2 10 centimeters 10 centimeters 10 centimeters 3 10 centimeters 10 centimeters 10 centimeters 4 10 centimeters 12cm 15cm 5 learn 1 cm 1 cm Total 31cm 33cm 36cm K-W 0.1689 0.1541 0.1361

A ceiling support 6 is formed in the upper area of the base shell 1 or the upper cross beam 2.2 of the framework 2. The ceiling support 6 is formed by a lightweight concrete edge. In the present embodiment, the first 15 cm on the inside are used to support and cast a ceiling structure and thus also as a ring beam. The remaining 5 cm are concreted in the thickness of the ceiling.

Fig. 3 shows a schematic representation of the base shell 1 with its outer surface 1.1 of the base shell. A lattice girder 7 has been inserted into the outer surface 1.1 of the base shell, which serves to anchor the framework 2. In a subsequent step, the insulation panels 3 are inserted into the areas enclosed by the lattice girder 7 and, if necessary, glued and/or anchored to the outer surface 1.1 of the base shell. The remaining free spaces on the base shell 1 in the area of the lattice girders 7, which in the present embodiment have a width of approximately 10 cm, are then filled with lightweight concrete wet-on-wet, so that the load-bearing supports 2.1 and the cross beams 2.2 and 2.3 are formed around the insulation elements 3 and anchored to the base shell 1 via the lattice girders 7. The thermal insulation board 4 is then glued and doweled seamlessly and over the entire surface of the frame outer surface 2.5 and the insulation element outer surface 3.1. Finally, the fabric filler with finishing plaster 5 is applied to the thermal insulation board outer surface 4.1.

By installing lattice girders in a base shell in such a way that at least one field is delimited on the base shell and by applying an insulation panel in the field and then pouring a free space formed by the lattice girders with lightweight concrete, a framework of frame elements and an optimal fit of each insulation element into this frame structure is ensured.

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Claims (6)

1. Prefabricated wall element for buildings, characterized by , - an inner base shell ( 1 ) which has a base shell outer surface ( 1.1 ), - a framework ( 2 ) firmly connected to the outer surface ( 1.1 ) of the base shell, which comprises individual frame elements ( 2.1 , 2.2 , 2.3 ) which delimit a field ( 2.4 ) on the outer surface ( 1.1 ) of the base shell, and - an insulating element ( 3 ) fitted into the field ( 2.4 ). 2. Prefabricated wall element according to claim 1, characterized in that the frame elements ( 2.1 , 2.2 , 2.3 ) of the framework ( 2 ) form a common frame outer surface ( 2.5 ) in a common plane, to which a thermal insulation panel ( 4 ) is firmly attached. 3. Prefabricated wall element according to claim 2, characterized in that the frame outer surface ( 2.5 ) is flush with an insulation element outer surface ( 4.1 ) and the thermal insulation panel ( 5 ) is supported on the insulation element outer surface ( 4.1 ). 4. Prefabricated wall element according to one of claims 1 to 3, characterized in that a top coat of plaster ( 5 ) is applied to an outer surface ( 4.1 ) of the thermal insulation panel. 5. Prefabricated wall element according to one of the preceding claims, characterized in that the framework ( 2 ) defines a plurality of fields ( 2.4 ). 6. Prefabricated wall element according to one of the preceding claims, characterized in that a ceiling support ( 6 ) is formed on an upper edge of the base shell ( 1 ) and the framework ( 2 ).