DE907120C - Process for the production of a double-shell cavity wall and hollow blocks for this purpose - Google Patents

Description

Process for the production of a double-shell cavity wall and hollow blocks The invention relates to a method for producing a double-shell Hollow wall and hollow blocks for this.

When building walls or walls for apartments, it is common to use empty ones Arrange spaces between the components to create good insulation. The invention avoids this in that the wall itself is designed as an insulating body will. This is achieved in that the thickness corresponds to the wall thickness and prefabricated hollow blocks forming the wall shells with their longitudinal side walls with two intersecting directions or only one direction, partially continuous cavities in the dressing are offset in such a way that the finished Cavity wall contains a network of communicating channels, which optionally restricted or interrupted at certain points to restrict air circulation will.

The hollow blocks are laid in mortar, and the perpendicular and channels running horizontally or inclined, the lengthways constant or can also be conical, have different cross-sectional shapes.

The partitions of these channels are on the one hand by the longitudinal side walls the hollow blocks formed, as already mentioned, and on the other hand from cross-connecting parts the long side walls.

The arrangement of openings at the top and bottom of the so educated Wall or wall gives you natural air circulation in the sewer network. By appropriate heating or cooling of the air one can also cause the effect of an air conditioning system. The channels can also be in certain Cases are used to lay electrical or other lines.

The weaker inner wall of the prefabricated hollow blocks can made of less resistant building material than the stronger, den supporting part forming the same outer wall. One becomes such a block of great size Preserved resilience while maintaining future interior furnishings of the apartment, as the attachment of furnishings to the interior walls is relieved.

In detail, various embodiments of the subject invention are presented described in accordance with the drawings. Fig. I shows a hollow block in isometric Representation, Fig.2 a side view of the hollow block according to Fig. I, Fig. 3 a isometric illustration of a further embodiment of a hollow block according to Fig. I, Fig. 4 a side view of the hollow block according to Fig. 3, Fig. 5 an isometric Representation of a further variant of a hollow block according to Fig. 3, Fig. 6 a corresponding further example in isometric representation, Fig. 7 shows a partial plan of the assembly of two hollow blocks according to Figs. I and 2, Fig. 8 is a cross-section showing a modification of the course of the vertical and horizontal Channels shows, Fig. G a schematic longitudinal section through a wall part made of hollow blocks according to fig. i, fig. io the same as fig. g, but with hollow blocks according to Fig 3. Fig. I i the same as Fig. G, but with hollow blocks according to Fig. 5, Fig. I2 the same as Fig. G, but with hollow blocks as shown in Fig. 6.

The invention is not limited to these exemplary embodiments.

Channels i (Fig. I) lead to the upper surfaces li and the lower surfaces 12 of the hollow block. These channels i intersect channels 2 which run transversely to the channels i and lead to locations 4 of the side surfaces. The channels i and 2 are connected to one another at the intersections 15. An offset 3 is arranged inwardly on the side surfaces in order to prevent the bonding mortar from penetrating into the channels 2. In order to prevent the penetration of the connection mortar into the vertical channels, grooves io can possibly be provided on the upper surfaces ii (Fig. 2). To achieve a solid part 13, which forms the outer, load-bearing wall shell, and a weaker part 16, which represents the inner wall shell or wall cladding, the channels i and 2 are arranged laterally to the axis xx. If the load is to be absorbed evenly by both wall shells, channels i and 2 are arranged in axis xx.

In the embodiment of Fig. 3, two channels 18 are larger Dimensions available that lead to the upper surfaces ig and into a transverse channel 2o. The channel 2o, which leads to the side surfaces 21 and extends to the lower surface 25, is also of larger size than the channels according to Fig. i and 2. Fig. 4 leaves particularly recognize that the channel 2o, as indicated in Fig. 3, the shape has a deep groove and cuts through the block of length nath.

A modified embodiment of the hollow block according to Fig. 3 Figure 5 illustrates Figure 5, showing that a channel 22 does not extend to the side surface 27 needs to lead. In this case it only extends to the lower surface 26 and forms the connecting link between the channels 22. In this embodiment dislocations are not absolutely necessary on the side surfaces.

Fig. 6 shows a further embodiment according to Figs. 3 and 5, in which the partition that separates the various channels from one another has been omitted. This embodiment then results in a continuous channel 28 which leads from the upper surface 2g to the lower surface 30.

In Fig. 7 is shown in plan view, such. B. two hollow blocks according to Fig. i and 2 are arranged side by side. The parts 4 of the side surfaces touch each other. The channels 2 of each block are continuations of one another. the Recessed parts 3 of the side surfaces of each block form one at the butt joint Receiving space g for the bonding mortar. Projecting retaining strips 8 can the perpendicular outer edges of the parts 3 of the side surfaces be provided to a Prevent the mortar from flowing out.

Another general design in which the vertical channels are not arranged in the same stone plane as the horizontal channels shown in Fig. 8. In this embodiment, the vertical channels 32 are with the horizontal channels 33 at points 34 in connection with one another.

In the schematic longitudinal section g through a wall part made of hollow blocks according to Fig. I, the coherent network resulting from the channels i and 2 is shown. The channels are connected to one another at the many intersection points 15. The hollow blocks are offset horizontally in the association that the vertical channels each coincide. A continuation of the horizontal channels is given by the surfaces 4 meeting at the butt joints. As indicated at 43, individual duct parts can be covered in order to reduce or eliminate the air circulation.

Hollow blocks according to Fig. 3 are used in the wall part according to Fig. 10. The result is a coherent network of channels 18 and 2o, which are located in the Cut points 35, only the channel cross-sections are larger than at Fig 9.

In Fig. I i is the production of a wall or wall from hollow blocks shown in Fig. 5. The arrow lines 36 and 37 indicate the axes of the horizontal and perpendicular channels which intersect at points 38. You can see that this Channel system based on the shape of the letter H.

According to Fig. 12 hollow blocks according to Fig. 6 are laid so that in the staggered superposed channels 28 vertical and inclined channel axes 40, 41 result, which intersect at points d2. 43 are locking points again of the channels.

As already mentioned, the ignere wall of the hollow blocks can be made from less resistant material, e.g. B. lightweight concrete, made as the outer wall be the z. B. consists of heavy concrete. This makes the attachment of equipment relieved in the apartment. Furthermore, some of the through channels can both are in connection with the surrounding building spaces as well as with the outside air, so that they can form part of the piping system of a heating or air conditioning system.

Claims (7)

PATENT CLAIMS: i. Process for the production of a double-shell cavity wall, characterized in that prefabricated hollow blocks, which correspond in their thickness to the wall thickness and which form the wall shells with their longitudinal side walls, are offset with partially continuous cavities in the association that extend in two intersecting directions or only in one direction, that the finished cavity wall contains a network of interconnected channels, which may be narrowed or interrupted at certain points to restrict the air circulation. 2. hollow block for performing the method according to claim i, characterized characterized in that it is a network of cavities intersecting in any direction contains any form that are related to each other and all of which or only a few penetrate the stone in all its extent. 3. Hollow block according to claim 2, characterized in that it has one or more in horizontal and vertically extending cavities containing each other in Connect and end either directly or in the bearing and abutment surfaces merge into groove-like cavities at these points, which have at least one Pass through the storage or abutment area. 4. hollow block according to claim 2 or 3, characterized characterized in that it has several superimposed horizontal cavities (2, 33) and a plurality of juxtaposed vertical cavities (i, 32) contains, - the all up to the abutment surfaces (4,21) or the bearing surfaces (i, 12, 24, 26) of the Go through the stone (fig. I, 2 and 8). 5. hollow block according to claim 2 or 3, characterized in that it has one or more vertical or horizontal Directional, adjacent cavities, which are in groove-like, end over at least one bearing or abutment surface extending depressions. 6. hollow block according to claim 5, characterized in that the groove-like recess (2o) is closed at the ends by the end walls (27) of the stone (Fig. 5). 7. hollow block according to one of claims 2 to 6, characterized in that the longitudinal axes of the cavities are preferably in one plane (Fig.2 and 4). B. hollow block for carrying out the method according to claim i, characterized in that it contains only one continuous cavity (28) of stone height and a length corresponding approximately to the stone length (Fig. 6). 9. Hollow block according to one of claims: 2 to 8, characterized in that its cavities or its cavity, depending on the thickness of the wall to be created, lie in the longitudinal center plane of the stone or in a plane parallel to it, to the outside. ok Hollow block according to one of Claims 2 to 9, characterized in that its cavities or its cavity have any cross-section and, in the case of several cavities, the cross-sections are the same or different among themselves. i i. Hollow block according to one of Claims 2 to 10, characterized in that the cross-section of its continuous cavities or some of them or of its cavity is more or less reduced in length. 12. Hollow block according to one of claims 2 to ii, characterized in that the continuous cavities or some of them or the continuous cavity taper in cross section to the extent or have such rough walls that the circulation of air in the cavities is prevented or made difficult. 13. Hollow block according to one of claims 2 to 12, characterized in that the openings of the continuous cavities or the continuous cavity in the stone walls are of any shape and, in the case of several cavities, of any number. 14. Hollow block according to one of claims 2 to 13, characterized in that it is provided on its abutment surfaces and / or on its upper bearing surface with grooves (3, 10) which receive the binding mortar and when the stones are bricked. Their upstanding sides prevent mortar from penetrating into the continuous cavities of the stones. 15. Hollow block according to one of claims 2 to 14, characterized in that it is made continuously from a single building material. 16. Hollow block according to one of claims 2 to 14, characterized in that it is in its one z. B. in the case of outer walls, the outer wall shell forming part consists of a harder building material than in its other part. 17. According to the method according to claim i produced hollow wall of hollow blocks according to one of claims 2 to 16, characterized in that it contains a network of interconnected, possibly interrupted at certain points channels, which optionally have the same or different cross sections and the cross-section of which is the same or different for each individual channel. 18. Cavity wall according to claim 17, characterized in that some of their continuous channels are in communication with both the surrounding building spaces and with the outside air, so that they can form parts of the pipe system of a heating or air conditioning system. i9. Cavity wall according to claim 17 or 18 as an outer wall, characterized in that its outer wall shell is made of harder building material, e.g. B. heavy concrete, and its inner wall shell made of lighter building material, z. B. lightweight concrete.