NL8400762A - COMBINATION STONE. - Google Patents

Description

* VO 6096

Combination stone.

The invention relates to a combination brick, in particular a combinatis paving stone, preferably with the basic shape of a quadrilateral, with base surfaces running parallel or substantially parallel, and side surfaces extending between them, optionally bulging.

The known combination stones, such as those described for example in German Auslegeschrift 16 58 485 or in German Gebrauchsmuster 80 07 289, have in their side surfaces which are perpendicular to the base surfaces, i.e. rideable and ground-facing planes, recesses of such a shape that they interact with corresponding associated projections of adjacent combination stones, thus avoiding displacement parallel to the surfaces.

The known combina-15 bricks, which have a simple geometric shape, have the drawback, however, that they are hardly suitable for large loads, since pits are then formed, particularly in the areas where a load transfer frequently takes place, which form undesirable irregularities. and water collecting places and the like. Therefore, the known ones are preferably in their basic form a quadrilateral such as, for example, a rectangle or a square combination stones for parking spaces or the like, only if the substrate has been formed accordingly, so through this the loading and distribution thereof take place.

The object of the present invention is to design a combination stone of the above-mentioned type in such a way that, in particular, it is possible to absorb large loads, whereby the load distribution can ever take place on the stone itself, so that to a large extent, independent of the substrate is ensured that the surfaces covered with the combi-30 do not show floors, floors or the like, even after frequent loading.

This problem is solved according to the invention in that at least two opposite side surfaces of the combination stone have a stepped geometry by abutting surface parts, in which common sides of the abutting 8400762 * 2 -2- parts run parallel or nearly parallel to the base planes. As a result of the leather according to the invention a combination stone is obtained which has a toothing recessed in two side surfaces, which preferably form the end faces, so that in the case of stones applied in bonded form, a uniform load distribution from a point can then take place, on which a pressure is exerted.

In other words, the stepped geometry prevents the bricks from being perpendicular to the base surfaces, that is to say with respect to the top or top. ground plane, may shift. Moreover, lateral shifting is also prevented when the individual stones are arranged in opposition to one another. Preferably becomes one. stepped geometry in the end faces is proposed, so a sawtooth or stepped structure can also be chosen, without the advantages obtained according to the invention having to be given up. The geometry of one end face is of course adapted to the geometry of the other end face in such a way that they complement each other in shape in order to be able to relate the stone.

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The surface parts which cause the step-like geometry preferably enclose the same or substantially the same angle with each other. Furthermore, the outer parts must be designed as the same size or almost the same size, the interior of these enclosed parts being able to be chosen as a large area. Such a geometry has shown that particularly good loading and distribution thereof is ensured. If, as noted, the stepped geometry is preferably formed by three parts, so that an S-shape is formed in side view, the side surfaces having the teeth can of course comprise more than three mutually angled surface parts, but it must be ensured that for a uniform load distribution at least one of the common inner and / or inner parts formed by abutting parts. exteriors run parallel or nearly parallel to the base surfaces.

According to the invention, the combination stone preferably has to have a substantially quadrangular shape, however, the base surfaces do not correspond entirely when projected along their perpendiculars. That is, the top and bottom base planes are mutually offset in the longitudinal direction of the stone.

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In order to provide a simple geometry with a high efficiency, the stone according to the invention is preferably designed in such a way that two congruent parts are formed during a cutting along a center axis.

Finally, an embodiment of a combination stone can be particularly mentioned, in which the stepped geometry is formed by three surface parts, the outer surface parts being of equal or almost equal design and smaller than the middle surface part. In addition, the plane ratio between the inner surface part and the respective outer part is about 5 to 4. Furthermore, the angle which the surface parts make with each other is preferably chosen at 110 °.

The protrusions, respectively protrusions, of one side surface and the associated protrusions, respectively protrusions vs in the other side surfaces, preferably lie on a parallel or sufficiently parallel line to the base surfaces. The distance between the corresponding protrusions or protuberances is approximately 200 mm, the height of the stone being 110 mm and the depth 140 mm. A suitable geometry results in an optimum stone in form and shape, in which the pressures acting on it are evenly distributed over the adjacent stones.

According to a very efficient embodiment of the invention, the manufacture of the combination stone takes place in deviation from the known in that the molding is effected on the side surfaces which do not have the step-like geometry due to pressure loading. This provides in particular the advantage that the base surfaces are generally smooth, so that a very flat surface is available in comparison with the existing combination stones, so that even ceramic materials can be used for making the combination stones. Preferably, however, heavy concrete is mentioned as the basic material.

Further details, advantages and features of the invention follow from the description of exemplary embodiments shown in the drawing. In the drawing: Fig. 1 shows a road surface made up of combination stones, Fig. 2 shows a composite combination stone, 8400782 3 t -4-Fig. 3 and 4 show different embodiments of combination stones in side view, Fig. 5 shows a preferred embodiment of a Figure 6 is a side view of the combination stone, and Figure 6 is a perspective view of the combination stone according to Figure 5.

In Fig. 1 a part of a pavement 10, which is shown, is shown. combination stones 12 according to the invention have been assembled, which may have a shape, as will be further detailed with regard to FIGS. 2 to 5. The combination stones 12 are thereby mutually opposed, i.e. the combination stones in successive rows 14, respectively. 16 are mutually displaced by a half edge length 18 of the combination stone. Naturally, the combination stones can also be arranged in a different shape.

However, the resistance has the advantage that the structure of the side surfaces to be discussed, which must substantially ensure a displacement of the combination stones 12 perpendicular to the paving surface, also prevents lateral displacement.

Fig. 2 shows two combination bricks 20 according to the invention 20, which are not mutually opposed for the sake of simplicity. The combination stone 20 has a substantially quadrangular shape, the end faces 20 and 24 respectively having a stepped geometry. This geometry is obtained in that the end faces 22 and 20, respectively. 24 from three corner parts 26, 25, 28, 30, respectively enclosing each other. 32, 34 and 36 have been made. The shape of the end faces 24 and 26 is chosen in such a way that they complement each other so as to enable a connection. As can be seen from Figs. 2 to 5, the preferably stepped geometry of the end faces 24 and 26 is chosen such that the common edges 38, 40, 30 and 30, respectively. 42 and 44 of abutting parts 26, 28, respectively. 28, 30, respectively. 32, 34, respectively. 34, 36 parallel or almost parallel to the pavement 10, i.e. to the base surfaces 46, respectively. 48 expired. This gives rise to the advantage that, on the basis of the given toothing, the effect of the pressure on a combination stone is distributed over the adjacent stones 35, so that the danger is eliminated to a great extent that with frequently strong loads, such as, for example, in a parking lot 8400762 - 5- for trucks or the like, the paved paving forms unevenness, in particular floors.

Special shapes of the combination stones displaying the stepped geometry are shown in Figures 3, 4 and 5. The combination stone 50 according to Fig. 3 has a stepped geometry in the side surfaces 52 and 54, which is determined by the fact that the central surface part 56, respectively. 58 encloses an angle relative to the centerline 61 of the combination stone 50. In analogy to a staircase, therefore, the second part to be designated 56 includes an angle with the horizontal.

The adjacent surface parts 60, 62, respectively. 64, 66 with respect to their direction relative to the surrounding parts 56, respectively. 58 is chosen such that the same angle is always enclosed. That is, the angle ot and S is chosen to be the same size. It has been found that the angle α equal to angle β is approximately 110 °. In the exemplary embodiment according to Fig. 3, if the surface parts are chosen to be the same size, other dimensions can also be chosen, as has been explained in connection with Figs. 4 and 5. Furthermore, it can be seen from Fig. 3 that the projection of the base surfaces along hm does not completely cover each other vertically.

In Fig. 4 a combination stone 68 is shown, the side surfaces of which are a step 70, respectively. 72, the step of which extends parallel to the surface of the combination stone 68. At the same time, in this exemplary embodiment, the middle surface part 74, respectively. 76 located on the centerline 78. Of course, the parts 74 and 76 can also be oriented symmetrically with respect to the centerline 78.

Figs. 5 and 6 show a particularly advantageous embodiment of a combination stone 80 according to the invention, the stepped geometry of which in the side surfaces 82, respectively. 84 through three planar sections 86, 88, 90, respectively. 92, 94 and 96 is formed. The 30 outer surface parts 36, 90, respectively. 92, 96 are chosen smaller than the mid-plane parts 88, respectively. 92. Preferably, the area ratio is about 5 to 4, that is, the interior area portion 88, respectively. 94 is approximately 25% larger than the respective outer surface part 36, respectively. 90, resp.

92, resp. 96. Furthermore, a particularly good pressure distribution is then obtained over the 35 bricks 80 connected, when the surface parts 86, 88, resp. 88, 90, respectively. 92, 94, respectively. 94, 96 an angle γ of approx. 110 ° in 8400782 - * ψ -δε lutes. Finally, the protuberance 98 on the front side 82 with the associated protuberance 102 on the front side 84, respectively, the protuberance 100 on the front side 82 and the protuberance 104 on the front side 84, respectively, on a parallel or substantially parallel to the base surfaces 5, 106, respectively. 108 running straight 110, respectively. 112 located. The distance between the corresponding protuberances and protrusions 98, 102, respectively.

100, 104 is approximately 200 mm, the height of the combination stone being 110 mm. The length of the base planes 106, respectively. 108 is also about 200 mm, with the projection of the base 10 planes 106 and 108 perpendicular to each other along their perpendiculars. That is to say, the outer sides of the end faces 82, respectively. 84 are opposed to one another. A perspective view of a side view 80 of combination stations 80 of Figure 5 is shown in Figure 6. This figure also shows in particular the stepped geometry of the end faces 82, respectively. 84, which approximates the S shape.

As a further special feature of the invention, it should be noted that the described combination stones are formed horizontally. By lying it is to be understood that the pressure action when forming the combination stone is parallel to the center axis 61, 78, respectively. 114 expires. In other words, the shapes for making combination bricks are designed in such a way that the side surfaces which do not have the stepped geometry are determined by the mold bottom surfaces or by the mold punch. This gives the advantage that the shape of the stepped or tooth-shaped end faces can be chosen arbitrarily, without the danger of having to pay attention to undercuts. Furthermore, the base faces of the combination stones are as they are not directly with the shape punch. come into contact, particularly smooth, so that besides heavy concrete, for example ceramic materials can also be used for forming the combination stones.

Finally, it should also be noted that the combination stones preferably have a spatial shape, which split the combination stone into two congruent parts, 8400762, at a section along the center line (60, 78 and 114, respectively).

Claims (13)

1. Combination brick, in particular combination paving stone, preferably with the basic shape of a quadrilateral, with base surfaces parallel or substantially parallel, and side surfaces extending between them, which may have protrusions or protrusions, characterized in that at least two opposite side surfaces (22, 24; 56, 58? 82, 84) by abutting surfaces (26, 28, 30? 32, 34, 36? 56, 60, 62? 58, 64, 66; 86, 88, 90? 92 , 94, 96) have a stepped geometry, with common sides (38, 40, 42, 44) of abutting parts running parallel or substantially parallel to the base surfaces. Combination stands according to claim 1, characterized in that the end faces, 22, 24; 52, 54? 82, 84) of the combination stone (20; 50; 68-80) are stepped and complement each other in shape. Combination stone according to claim 1, characterized in that the stepped geometry is sawtooth-shaped. Combination stone according to claim 1, characterized in that the surface parts (26, 28, 30? 32, 34, 36? 56, 60, 62? 64, 68, 66? 86, 88, 90? 92, 94, 96) enclose the same or almost the same angle (α, Β, γ). Combination stone according to claim 3, characterized in that the angle (α, Β, γ) is preferably about 110 °. Combination brick according to claim 4, characterized in that the angle (α, Β, γ) is preferably about 55 °. Combination brick according to claim 1, characterized in that at least the outer parts (26, 30; 32, 36; 60, 62; 64, 66 - 86, 90 - 25 92, 96) are of the same size or substantially the same size flat. Combination stone according to claim 1, characterized in that the stepped geometry consists of three parts (26, 28, 30; 32, 34, 36? 60, 56, 62? 64, 58, 66; 86, 88, 90? 92 , 94, 96). Combination brick according to claim 1, characterized in that the combination brick (12, 20, 50, 68, 80) has substantially a quadrangular step with the end faces. 840075? * j τ »» -δ- ΙΟ. Combination stone according to claim 1, characterized in that the combination stone (12, 20, 50, 68, 80) can be split into two congruent parts according to its central axis (61, 78, 114). Combination stone according to claim 1, characterized in that the combination stone (12, 20, 50, 68, 80) is formed by action of pressure on the side surfaces which do not have the stepped geometry. Combination stone according to claim 7, characterized in that the middle surface part (88, 94) is approximately 1/4 or 1/5 larger than the respective outer surface part (86, 30, - 92, and 96, respectively). Combination stone according to claim 8, characterized in that the protrusion (90, 104) of the stepped geometry of one end face (82, 84 respectively) and the depression (100, 102, respectively) of the stepped geometry. the geometry of the other end face (84, and 82, respectively) to lie on a line (110, 112) parallel to or substantially parallel to the base surfaces (106, 108). Combination brick according to claim 13, characterized in that the distance between the indentation (.100, or 102) and the overlying projection (104, or 98) is approximately 200 mm. Combination stone according to claims 12 to 14, characterized in that the combination stone has a height of approximately 110 mm, a depth of approximately 140 mm and a length of approximately 200 mm with respect to its base surfaces (106, 108). . 8400762