DE3810031A1 - SLOPE BLOCK - Google Patents

Abstract

In a retaining building block with an essentially frame-shaped type of construction for erecting plantable retaining structures, the front longitudinal wall (1) is designed roughly like a shield, the same projecting roughly by approximately the wall thickness at the top and in the longitudinal direction beyond the frame outlines. <IMAGE>

Description

The invention relates to a slope block with essentially rah menike design for the erection of embankment structures and is mainly characterized in that the front longitudinal wall is approximately shield is formed like, the same on the top and in the longitudinal direction projection protrudes by about the wall thickness and the this gives projections on the visible side round corners and edges exhibit.

Another important characteristic of the invention relates to the cross section formation of the rear wall and he two transverse walls, which are conical provides the inside of the walls, which increases downwards, or in lower area is more developed.  

They are already embankment blocks with an essentially frame-like structure kind known. So, among other things, the name used in German "System Heinzmann" was the name of the stone from which the invention is based. This stone consists of a frame of smooth sharp-edged walls, whereby the two transverse walls have a step falling backwards, which as Approach for stones to be put on. The stones are lattice-shaped built up and filled with soil. The resulting Gaps between the stones release an earth embankment and can be to be planted.

In the known system, these gaps are completely open on the front The embankment is supported only by the front wall of the stone. The Plants are relatively unprotected from wind, weather and sunlight exposed and rub when moving on the existing sharp edges the stones.

The invention aims to improve the function of such stones and to find an overall aesthetic solution from a technical-ecological point of view. It achieves this through the Formation of the front wall ( 1 ), which is characterized in that it is approximately shield-like and has top and longitudinal projections ( 2 ) that go about the wall thickness beyond the outer limits of the frame and visible side curves ( 3 ) at corners and Own edges.

It is thereby achieved that the earth embankments in the gaps an embankment wall advantageously from the lateral projections ( 2 ) of the front wall ( 1 ) of the erfgem. Stones are supported. Furthermore, these side projections create niches ( 7 ) instead of open gaps, which are suitable for planting. Provide protection from wind, weather and excessive sunlight.

The result. Curves on the corners and edges of the front wall are planted friendly and prevent injury to plants as a result of chafing. With the Stones also become an aesthetic picture of embankments buildings reached.

Another object of the invention is the formation of the stones in the rear look at an economical production. Stones with top Projections and curves are usually only in dismantled hand shapes or using tilting machines.

However, the most economical way of producing such stones is with stationary systems using the Rütten-Press process. In order to To be able to produce stones in this process, it is necessary to solve the problem of the volume distribution of the building material in the mold box during compaction. This problem can be solved. be solved advantageously. When filling the mold box with the undensified building material, such as. B. concrete or the like., The upper edges of the - undensified - stone lie in one plane, namely in the plane of the top of the mold box. Now it is necessary - taking into account uniform compression - to lower the upper edges of the transverse walls ( 5 ) and the rear wall (4) approximately by wall thickness compared to the upper edge of the front wall ( 1 ). This is accomplished. achieved by the training of the Koni described above. The rear wall and transverse walls are more voluminous in the lower area ( 6 ). The press ram can push lumen down during the compaction process, in the rear wall and transverse walls to a greater extent, because in the lower area here. more volume can be taken.

The conical design of the rear wall and the transverse walls, especially in the lower area on the inside of the wall, has another technical advantage. In the case of embankment structures, it is important that the supported soil on or in the embankment stones is secured against slipping. This requirement is met by the Stone not only achieved by the projections ( 2 ), but also by the taper of the rear wall and the transverse walls in the lower area of the inner sides.

Experience Stones can preferably be made with the outside dimensions l = 46 cm, b (wall thickness) = 50 cm and h (construction height) = 16.5 cm. This gives them a mass of approx. 42 kg per stone and are very handy to use. However, other dimensions can also be chosen in the sense of the invention.

The invention is illustrated, for example, with reference to drawings. In this the individual figures mean:

Fig. 1 oblique view of a erfgem. trained module,

Fig. 2 cross section through a erfgem. Stone,

Fig. 3 longitudinal section through a erfgem. Stone,

Fig. 4 plan section of an embankment.

Description of the figures

Fig. 1 The oblique view shows a erfgem. trained embankment block with approximately frame-shaped design. The front longitudinal wall ( 1 ) is approximately shield-like. It jumps on the top and in the longitudinal direction by about the wall thickness over the outer frame boundaries, the projections ( 2 ) having rounded corners ( 3 ) at corners and edges. The rear wall ( 4 ) and both transverse walls ( 5 ) together with the front wall form an approximately rectangular to square frame. The corners formed by the four walls are rounded on both the outside and the inside.

Fig. 2 This cross section through a erfgem. Stone (= cross section to the slope wall) shows the profile of the front wall ( 1 ) and the rear wall ( 4 ). On the front wall, a projection ( 2 ) and the curve ( 3 ) of the longitudinal edge formed on the visible side can be seen. The back wall clearly shows the required profile. Taper, which is reinforced in the lower area ( 6 ) on the inside of the wall.

Fig. 3 in this figure is the gem. Stone shown in a longitudinal section (= section parallel to the slope wall level). The two transverse walls ( 5 ) appear in profile, the front wall ( 1 ) can be seen in the rear view. The cuts through the transverse walls show this. trained profile with taper, which is stronger on the inside in the lower region ( 6 ). Outside the transverse walls, the cracks ( 2 ) appear in the front wall in the longitudinal direction. The upper corners of the front wall are marked by curves ( 3 ).

Fig. 4 The floor plan section of a slope wall shows two erfgem next to each other. Stones in a row and set back in between (drawn in broken lines) a stone in the row above. It illustrates how the projections ( 2 ) of the front walls reduce the opening of the vacant space and thus form a protected niche ( 7 ).

Claims (3)

1. embankment block with a substantially frame-like construction for the erection of embankment works, characterized in that the front longitudinal wall ( 1 ) is formed approximately in the manner of a shield, the same projecting on the upper side and in the longitudinal direction over the frame outlines by approximately the wall thickness and the projections ( 2 ) have roundings on the visible side ( 3 ) at corners and edges. 2. embankment block according to claim 1, characterized in that the rear wall ( 4 ) and the two transverse walls ( 5 ) have a conical cross-section, wherein the conicity increases on the inside of the walls downwards, or stronger in the lower region ( 6 ) is trained. 3. Embankment structure made of embankment stones acc. Claim 1 or Claim 2, characterized in that the gaps between two stones of a row are narrowed by the projections ( 2 ) at the ends of the front walls ( 1 ) and protective niches ( 7 ) are thereby provided.