EP0017005A1 - Hollow-block building element - Google Patents

Abstract

1. Hollow construction block element, particularly for slope stabilization, with longitudinal and transverse walls surrounding at least one recess constructed as a through-hole, said walls having a constant horizontal cross-section over their height, so that the longitudinal and transverse walls pass in undercut-free and massive manner between two horizontal planes, characterized in that blocking bosses (2) project at the lower horizontal plane and are substantially arranged within the horizontal cross-section areas of the transverse walls (4, 5) located between the longitudinal walls (3), at least two bosses (2) being arranged on at least one transverse wall (4, 5) and their centres are essentially located on the vertical plane of symmetry of this transverse wall (4, 5), the inside width of said bosses being at least equal to the longitudinal wall thickness.

Description

The invention relates to a hollow block component, with a component body which encloses at least one recess on its upper side and has at least one cam which can be inserted into the recess of a similar component arranged underneath on its underside.

Such components usually consist of concrete, lightweight concrete, clay or the like and are used for the binder-free construction of buildings. The components are offset so that each of the cams of the components of a row surround the recesses of the components of an adjacent row, so that a stable, form-fitting connection is created. The designation top and bottom only serves the nomenclature, the components can of course Lich used in both arrangements, however, the arrangement of the cams on the underside is usually preferred. so that the building has a smooth top. The component body can be made more or less solid and in any case has on the side opposite the cams on the circumferentially closed recesses which are dimensioned at least so that they accommodate the cams. For reasons of weight saving, however, the component element is usually designed as a honing block, which may be ribbed in accordance with the structural requirements.

In a known hollow block component of the type described above (cf. DE-GM 78 07 968), the component body consists of a frame element, in the interior of which one or more hollow cylinders are arranged as a stiffening core. Cams and recesses are formed by the fact that the hollow cylinders are offset in height with respect to the frame element so that they protrude from the frame elements on the top and a space remains free on the underside within the frame element. These known hollow block components have proven their worth in the construction of garden walls, patio supports, fencing, etc. However, they can only be moved in a seamless connection, and in particular a lateral offset of rows lying one above the other cannot be carried out, so that only vertical walls can be erected. This makes these known hollow block components unsuitable for the construction of slope stabilizers, embankments, noise barriers, etc. For these applications, there must be the possibility of erecting a composite that is inclined relative to the vertical, and also, for landscaping reasons, the possibility of greening. To do this, it is necessary to move the individual components in such a way that the largest possible voids and gaps remain which are filled with soil and planted can. Despite this loosened construction, such a composite must of course have the required static stability. All of this is not possible with the known components described above.

For the erection of embankment fastenings, etc., concrete block elements are known (from practice) which consist of a frame which is closed on the circumference, open at the top and bottom and has a projection along one side. These components of another type are each moved to a stop on the protrusion of the component below them, so that an inclined relative to the vertical and relatively loose, suitable for greening arrangement. With these known concrete structural elements, an adaptation to different conditions is practically not possible, but above all there is no positive connection in the longitudinal direction of the composite, so that no satisfactory stability is achieved.

The invention has for its object to provide a hollow block component of the type described above, with the embankment ^fastenings etc. can be erected, which are characterized by a stable, form-fitting structure with a high proportion of voids and gaps. In particular, the possibility of adapting to different applications in a further area is sought.

This object is achieved in that each recess is assigned a cam set of at least two cams and that the distance between adjacent cams corresponds at least to the wall width of the recess. Preferably, four cams are assigned to each recess; under certain circumstances, an even larger number of cams per recess can also be expedient. In any case, it is recommended that the cams on the corners be with the limits of the rectangular plan of the component parallel to the rectangle (or square) arranged parallel sides, so that an overall largely regular structure of a component according to the invention results.

The arrangement of the cams according to the invention has the result that there are, as it were, incisions running parallel or perpendicular to the limits of the component, into which the walls of the recess of a component arranged below can engage, so that conversely one or more of the cams in the recess are fixed, while the other cams of the cam set in question lie outside the recess. The result is a displacement of the components in the longitudinal or transverse direction, whereby there is a clear positive connection. So that an extensive, continuous bond is created, the components naturally each have several, as a rule two recesses and two cam sets. Depending on their design and mutual spacing, there is the possibility of placing the components with more or less wide passages on the gap. Furthermore, the possibility of arranging the components laterally offset from one another creates the possibility of adapting to different slope inclinations, the high degree of static stability always being ensured by the interlocking between adjacent components; is.

For reasons of weight and cost, the components according to the invention are generally not made solid but with more or less pronounced openings, which at the same time form the recesses for receiving the cams. In principle, various embodiments are possible for this. In view of the fact that the execution of undercuts is technically complicated and complex, it is advisable to form the recesses by chambers which penetrate the component with a substantially uniform cross section and are open at the top and bottom, so that a component body constructed from longitudinal, transverse and chamber partitions results. The longitudinal direction of the component is defined as the direction in which the chambers are arranged next to one another. Starting from such a component, the invention provides in a particularly preferred embodiment that the cams of each set of cams are arranged on the transverse or chamber partition walls delimiting one of the chambers. The initially existing problem that the cams sitting on the walls delimiting a chamber obviously cannot be inserted into this chamber is solved by the arrangement of the cams in the form of cam sets and the mutually offset arrangement of the components.

It is advisable to limit the longitudinal, transverse and chamber partition walls with parallel surfaces and with the same width. The width of the cams preferably corresponds to the width of the walls. The cams themselves can largely be of any design, a design with a circular or square layout having proven particularly useful. It is advisable to have the cams taper conically or pyramid-shaped towards their free ends. This makes it easier to demold without flaking, and the components can be joined together to form a bond in a particularly simple manner.

In any case, the cams sit at a greater or lesser distance from the longitudinal walls on the transverse or chamber partitions, and preferably in rows parallel to the longitudinal extension of the component. This creates the possibility, which may be advantageous, that the cams, each arranged on a common transverse or chamber partition, in other words, to arrange the rows of cams at different distances from the next longitudinal wall, which results in an asymmetrical structure of the component when viewed from above. This results in the possibility of realizing different lateral misalignments depending on the arrangement of the components by abutting the cams.

The dimensions of the chambers and walls are important to ensure that there are optimal possibilities when producing a composite from the components according to the invention. First of all, it is recommended that the inside width of the chambers measured in the longitudinal direction of the component corresponds to at least twice the width of the transverse or chamber partition walls. It is assumed that the width of the cams corresponds essentially to the width of the respective wall, otherwise the clear width of the chambers can also be correspondingly smaller. This also applies accordingly to the following design recommendations. In any case, it is achieved with this design that a gapless assembly can also be established in the longitudinal direction.

In a preferred embodiment, the inside width of the chambers measured in the transverse direction of the component is at least twice the width of the transverse or chamber dividing walls greater than the inside width of the chambers measured in the longitudinal direction. This creates the important possibility of joining the components to one another in a direction perpendicular to one another.

A particularly advantageous embodiment of the invention is characterized by at least three chambers, namely two side chambers and at least one middle chamber arranged between the side chambers. The measured in the longitudinal direction of the component Clear width of the middle chamber at least, preferably even more or less exactly twice the width of the transverse or chamber dividing walls greater than the clear width of the side chambers measured in the longitudinal direction. In the preferred case, in which this dimensioning ratio is more or less exactly adhered to, a structure is obtained in which, measured in the longitudinal direction in each case, the clear width of the central chamber corresponds to the width of the side chambers measured over the walls. For example, in the three-chamber element to be preferred, the inside width of the central chamber thus corresponds essentially to one third of the total length of the component. In general, but in particular in the case of the last-mentioned embodiment, a length-to-width ratio of 2: 1 is recommended for the layout of the entire component.

With the components explained above, all the combinations that come into consideration in practice can be built: closed or on a gap, flat, curved or with corners, vertical or inclined. However, there are still protrusions when cornering. In order for the components of different layers to be flush with one another at a corner, the invention provides special corner elements which are characterized in that the cams arranged on one of the transverse walls are at a distance of one wall width from the free outer side of the transverse wall and from the free outer sides of the adjacent ones Longitudinal walls each have a distance corresponding to twice a wall width. The length of these corner elements preferably corresponds to half of a normal element in the composite, for example half the length of the three-chamber element explained above. It has also proven to be advantageous to design these corner elements as a single-chamber element, ie without inner chamber partition walls.

As explained, the aspect of cost and weight savings is of considerable importance. In this regard, there is the advantageous possibility of providing recesses in the longitudinal, transverse and / or chamber partition walls in the area between the cams and thus tapering these walls to reduce weight, insofar as the static conditions permit this. It is particularly important that the walls do not have to be made over their entire length with the thickness specified by the cams.

• Figur 1 ein Hohlblock-Bauelement in Aufsicht,
• Figur 2 das in Figur 1 dargestellte Hohlblock-Bauelement im Schnitt 11 - 11,
• Figur 3 ein als Eckelement vorgesehenes Hohlblock-Bauelement,
• Figuren verschiedene aus den Hohlblock-Bauelementen errichtete 4, 5 und 6 Verbünde.

The invention is explained in more detail below on the basis of a drawing which merely shows exemplary embodiments. Show it

• FIG. 1 shows a hollow block component in supervision,
• FIG. 2 shows the hollow block component shown in FIG. 1 in section 11-11,
• FIG. 3 shows a hollow block component provided as a corner element,
• Figures various 4, 5 and 6 assemblies constructed from the hollow block components.

FIG. 1 shows a top view of a hollow block component, specifically on the underside. This is not important, however, because the components according to the invention can also be used in an arrangement which is reversed with respect to the top and bottom.

The component shown, made of concrete, consists essentially of a component body 1, on the underside of which projecting cams 2 are formed, which are highlighted in Figure 1 by hatching. The component body 1 has a rectangular plan and is made up of two longitudinal walls 3, which are connected by perpendicular, outer transverse walls 4 and internal chamber partition walls 5. These walls enclose the building element, which penetrates the component and is open at the top and bottom, namely an outer side chamber 6 and a middle chamber 7 located between them. It is therefore a three-chamber element. The chambers 6, 7 thus form recesses into which the cams can enclose a similar component arranged underneath.

As the figures make clear, each of the chambers 6, 7 is assigned a set of cams of a total of four cams 2. The cams 2 are arranged on the transverse or chamber partition walls 4, 5 delimiting the chambers 6, 7. In any case, the distances (which will be dealt with in detail below) between adjacent cams 2 are dimensioned such that they correspond at least to the width of the walls 3, 4, 5.

In the embodiment shown in FIGS. 1, 2, the cams 2 have a square outline, the width of the cams 2 corresponding to the width d of the transverse or chamber dividing walls 4, 5 in the area of the cams 2. In the figures it cannot be seen that the cams 2 taper slightly pyramid-shaped towards their free end, so that they can be easily removed during manufacture and without flaking. In the area between the cams 2, the walls 3, 4, have cutouts 8 which bring about a tapering of the walls in order to save weight.

Figure 1 shows that the cams 2 are each arranged at the corners of a rectangle, the sides of which are parallel to the Grundrißbe boundaries of the component body 1 extend. The cams 2 are recognizably arranged in rows of cams parallel to the longitudinal extent of the component, which in the illustrated embodiment each have the same distances from the respectively adjacent longitudinal wall 3. The figures do not show the possibility that these distances from the adjacent longitudinal walls 3 can also be different.

In order to achieve optimal results when assembling groups with the components shown, it is advisable to comply with certain design rules, which are explained below. First, the longitudinal, transverse and chamber dividing walls 3, 4, 5, which are delimited in parallel, have the same width d among themselves. Of course, this only applies with the exception of the recesses 8 explained, that is to say in the vicinity of the cams 2. The length-to-width ratio of the component layout is 2: 1. The clear width a of the side chambers 6 measured in the longitudinal direction of the component is approximately the same twice the width d of the walls 3, 4, 5, while the measured inside width c of the middle chamber is twice the width d of the walls 3, 4, 5 than the inside width a of the side chambers 6 Clearance c of the central chamber is essentially one third of the total length of the component. The inside width b of the chambers 6, 7 measured in the transverse direction of the component is correspondingly larger by twice the width d of the walls 3, 4, 5 than the inside width a of the side chambers 6 measured in the longitudinal direction.

The three chamber element described above with reference to FIGS. 1 and 2 is intended for use in extensive flat areas of a composite. FIG. 3 shows another embodiment that is used specifically as a corner element and offers the possibility of using corners flush exterior surfaces. The corner element 9 shown in FIG. 3 is designed as a single-chamber element with two parallel longitudinal walls 3 and two transverse walls 4 perpendicular thereto. On e ner of the transverse walls 4, the cams in FIGS. 1, 2 are arranged accordingly. In contrast, on the other, the outside of a corner forming transverse wall 10, which is twice the width of the other transverse wall, the cams 2 are arranged so that they have a distance from a wall width b relative to the free outside of this transverse wall 10. In addition, the cams 2 are arranged here so that there is a distance corresponding to twice a wall width b relative to the Außenensei th of the adjacent longitudinal walls 3 j. The floor plan width of the corner element 9 corresponds to the width of the three-chamber element according to FIGS. 1, 2, while the length of the corner element only corresponds to half the length of the three-chamber element. 3 shows that the cams 2 can also be designed with a circular cross section, the cam diameter corresponding to the wall width d.

Figures 4, 5 and 6 show different options for the establishment of networks with the components described. Two component layers are shown, the lower one being drawn out and the upper one shown in dashed lines.

Figure 4 shows a closed, gapless composite. The upper layer is offset from the lower, so that the resulting composite is inclined relative to the vertical, for example, according to the inclination of an embankment to be fastened. A component 11 of the upper layer is arranged perpendicular to the other components and is used for anchoring in relation to the slope (not shown). _M an recognizes without further explanation how the cams 2 each enclose in the chambers 6, 7 and thereby the walls 3, 4 and 5 in a form-fitting manner lock in.

FIG. 5 accordingly shows a flat composite in which the components are set to a gap.

FIG. 6 shows the execution of a corner. It can be seen how, due to the special design of the corner elements 9, the outer surfaces of the structural elements lie flush with one another.

Claims (12)

1. Hollow block component, with a component body which encloses at least one recess on its upper side and has at least one cam which can be inserted into the recess of an identical component arranged below it, characterized in that each recess (6, 7) has a set of cams is assigned by at least two cams (2) and that the distance between adjacent cams (2) corresponds to at least the wall width (d) of the recess (6, 7). 2. Component according to claim 1, characterized in that each recess (6, 7) four cams (2) are assigned. 3. Component according to claim 1 or 2, characterized in that the cams (2) are arranged at the corners of a rectangle with parallel to the limits of the rectangular plan of the component arranged sides. 4. Component according to one of claims 1 to 3 in the embodiment with the component penetrating, open at the top and bottom and the recesses forming chambers, the component element consists of longitudinal, transverse and chamber partitions, characterized in that the cams (2) each cam set is arranged on the transverse or chamber partition walls (4, 5) delimiting one of the chambers (6, 7). 5. The component according to claim 4, characterized in that the longitudinal, transverse and chamber partition walls (3, 4, 5) are limited in parallel area and have the same width (d). 6. The component according to claim 4 or 5, characterized in that the width of the cams corresponds to the width (d) of the transverse or chamber partition walls (4, 5). 7. Component according to one of claims 1 to 6, characterized in - that the cams (2) taper conically or pyramid-shaped to their free end. 8. Component according to one of claims 1 to 7, characterized in that the cams (2) are arranged in parallel to the longitudinal extent of the component rows of cams and that the rows of cams are arranged at different distances from the respective next longitudinal wall (3). 9. Component according to one of claims 4 to 8, characterized in that the inside width measured in the longitudinal direction of the component (a, c) of the chambers (6, 7) at least twice the width (d) of the transverse or chamber partition walls ( 4, 5). 10. The component according to one of claims 4 to 9, characterized in that the inside width measured in the transverse direction of the component (d) of the chambers (6, 7) is at least twice the width (d) of the transverse or chamber partition walls (4, 5) larger than the inside width (a) of the chambers measured in the longitudinal direction. 11. The component according to one of claims 4 to 10, characterized by at least three chambers, namely two side chambers (6) and at least one central chamber (7) arranged between the side chambers (6), the clear width (c) measured in the longitudinal direction of the component the central chamber (7) is at least twice the width (d) of the transverse or chamber partition walls (4, 5) larger than the clear width (a) of the side chambers (6) measured in the longitudinal direction. 12. Component according to one of claims 4 to 11, as a Eckel element, characterized in that the cams (2) arranged on one of the transverse walls (10) with respect to the free outside of the transverse wall (10) are at a distance from a wall width (d) and in relation to the free outer sides of the adjacent longitudinal walls (3) each have a distance corresponding to twice a wall width (d).

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