DE3528323A1 - Interlocking paving stone - Google Patents

Abstract

The interlocking paving stone has four long stone sides (1 to 4) and one extremely short stone side (5) which are all designed as cylindrical surfaces, preferably circular cylinders. Each of the stone sides is congruent in a mirror-inverted manner with the respectively opposite stone side (1-3, 2-4, 5-1). The interlocking paving stone represents an irregular pentagon which, because of the relative shortness of the stone side (5), has an approximately square appearance. In the interlocking paving, the interlocking paving stones bear against one another on all sides with the long cylindrical stone sides (1 to 4); this mutual contact is geometrically perfect and each paving stone is anchored non-displaceably in the paving. Only on the short stone side (5) is, in many parameter constellations, a small open triangle formed, the height of which constitutes on average about 5% of the stone diameter and is of no significance for the strength of the interlocking paving. By means of variations in the length of the cylinder radius (R) and in the relative length of the individual cross-legs (a, b, c, d) of an imaginary basic cross (6) which is responsible for defining the parameters, an extensive range of attractive stone contours is created, which all guarantee a particularly high strength in the interlocking paving. <IMAGE>

Description

The present invention is on a composite paving stone related, which on the one hand in the network a recently much in demand, old-fashioned "rustic" contour which is reminiscent of natural stone pavement, and on the other hand is more generally usable by being in the composite Endures higher traffic pressures without the network loosens up.

For this purpose, the stones of a pavement bond firmly to anchor to each other, it is known to use composite paving stones to be provided with curved stone flanks. In BE-PS 5 54 294 INNOCENSO is a stone with sinusoidal described convex and concave stone flanks. Similar proposals are in DE-PS 8 12 675 TRIEF and 11 16 695 SCHÜLLER as well as in the US PS 8 88 530 PUGH published. All of these inventions point share the same drawbacks: it's hard to lay them so that the curved flanks are sufficient lie exactly next to each other. Another, for that practical laying of these stones is a significant disadvantage are the sharp corners that are formed all over there where two concave stone flanks intersect, and the sharper the stronger and more effective it is Is curvature. Such sharp edges are on the one hand break off slightly during transport and installation can also pose a risk of injury to the construction workers.  

The paving stones known from the cited publications have therefore not prevailed on the market can. In contrast, paving stones have prevailed with zigzag long and end sides, mostly in the Basic contour of an elongated square. These cobblestones are only for small and medium loads suitable. They are linked in several short ones Jagged or notches supported against each other; their static resistance to lateral displacement Pressure component is less than the resistance in a composite of paving stones with convex-concave Flanks. In addition, the composite image is restless and does not appeal to everyone. For roads with higher pressure load is almost exclusively today Total coverings brought forward.

The present invention has for its object a composite paving stone with congruent cylindrical stone flanks to create with a practically geometrically complete system on the flanks of the neighboring stones in the pavement and consequently with an immovable anchoring of the composite paving stone in the pavement. Each stone flank may only have a cylindrical surface - convex or concave and must not have any sharp corners with the abutting flanks form. Furthermore, the composite paving stone should be in the paving composite have an essentially square-like contour and in association the "old-fashioned" desired today Show contour image.

This invention task is with the in the claims technical means described solved.  

Embodiment

In the following, some exemplary embodiments will be described with reference to drawings illustrated and explained the invention. Show it:

Fig. 1 c a composite paving stone according to the invention with an isosceles base cross and cylinder radius equal to the cross width of a +, in a plan view,

Fig. 2 shows the paving stone Fig. 1 in a composite same paving stones, on a somewhat smaller scale,

Fig. 3 is a composite paving stone according to the invention with a non-isosceles basic cross ratio of the cross leg a: c = d: b = 0.83, R = a + c,

Fig. 4 is a composite paving stone with cross legs ratio a: b = c: d = 1,2, R = a + c,

Figure 5 is a composite paving stone with cross legs ratio a:. C = b: d = 1.67 and R = a + c,

Fig. 6 is a composite paving stone with cross legs ratio a: b = c = d = 0.6, R = a + c,

Fig. 7 is a composite paving stone with cross legs ratio a: c = 0.6 and b: d = 1.67, R = a + c,

Fig. 8 is a composite paving stone with cross legs ratio a = b = c = d and R = 0.7 (a + c),

Fig. 9 is a composite paving stone a = b = c 1,5, R = a,

Fig. 10 is a composite paving stone with cross legs ratio c = 3, b = d = 2.7 a, R = 4 _1,3,5 a, R _2,4 6 = a,

Fig. 11 is a composite paving stone with cross leg ratio a = b = c = d, R _1,3,5 = 1.2 a , R _2.4 = 2.4 a and

Fig. 12 is a composite paving stone with cross legs ratio b = 1.33 A, c = 1.67 a, d = 2 a, R 2 b _1,3,5 =, R _2,4 4 = b.

List of reference numbers

1, 2 convex stone flanks or convex cylinder jacket surfaces
3, 4 concave stone flanks or concave cylinder surfaces
5 short concave stone flank or cylinder surface
6 basic cross
7 cylinder axis for determining the stone flank 5
8 head start
9 rounded corner at the projection 8
10 triangular opening on the stone flank 5
R cylinder radius of stone flanks 1 to 5
a, b, c, d legs of the base cross 6

The paving stone Fig. 1 and 2 represents a top view of an irregular pentagon with cylinder-shaped stone flanks 1 to 5. The cylinder axes of the four long stone flanks 1 to 4 are of the legs a, b, c, d of an imaginary base cross 6 or of their Extensions determined by the cylinder axis of the stone flank 1 in the cross leg c or - at radius R ≦ λτ a + c - in its extension, the cylinder axis of the stone flank 2 in the cross leg d or in its extension, the cylinder axis of the stone flank 3 in the extension of the cross leg c and that of the stone flank 4 in the extension of the cross leg d . The cylindrical surface of the very short stone flank 5 is determined by an axis 7 which is arranged on a line parallel to the cross legs b + d from the end point of the cross leg 3 at a distance b + d . The cylinder jacket 5 runs through the axis 7 and runs parallel to the congruent cylinder jacket 1 . The cylinder axis of the cylinder jacket 5 is located in a line parallel to the cross arms a + c at a distance R from the axis 7 .

In the exemplary embodiment, the sum of the mutually extending cross branches a + c and b + d are set to the same size, that is

a + c = b + d

The examples FIGS. 1 to 7 are all related to a radius R = a + c .

The disadvantageous overlap of the concave side flanks 3, 4 in the known paving stones does not come about here because the short stone flank 5 cuts them off beforehand. This gives rise to the projection 8 which is characteristic of the invention and which, if considered to be expedient, can be rounded off at the corner 9 .

As shown in FIG. 2, composite paving stones according to the invention lie geometrically precisely against one another everywhere except for a small triangle 10 . The height of this triangle is approx. 4-5% of the radius R , i.e. a full 5-6 mm for a normal stone diameter of 150 mm. This opening has no significance for the stability of the pavement composite. Of crucial importance is the fact that the individual paving stone is immovably wedged together because of the long uninterrupted cylindrical stone flanks. Even under very large lateral load components, the stone in the dressing cannot move.

In the composite paving stone shown in FIGS. 1 and 2, all of the cross legs a, b, c, d of the base cross 6 are of equal length, that is to say the base cross isosceles. The radius R is equal to a + c . With this parameter constellation, an optimal design has been achieved: the paving stone looks largely square when viewed, has no sharp corners and the short stone flank 5 , the inevitable concession to the approaching concave stone flanks 3, 4 is wide enough to be transported and to be safe to lay.

However, the stone can be designed differently by varying the length of the radius R and the individual cruciform legs a, b, c, d . As a result, as shown in FIGS. 3 to 9, interesting stone shapes are created which also produce interesting composite patterns.

For the sake of comparability, the sum of the vertical and the sum of the horizontal cross arms is the same in the examples FIGS. 1 to 8. Now you shorten it in this function

a + c = b + d

the cross-legs a and b in relation to the legs c and d , result accordingly With these leg ratios, the projection 8 becomes more pointed and the side flank 5 becomes shorter, cf. Fig. 3.

But if you lengthen the legs b and c in relation to a and d : the projection 8 becomes wider and the side flank 5 longer, cf. Fig. 4.

Such variations have limits, as shown in FIG. 5. Here, at a ratio of 1.5 between a and c or between b and d , the cylinder jacket surface 5 just barely reaches the cutting point of the two concave side flanks 3, 4 ; So there can be no stone flank 5 .

If c ≦ λτ a and d ≦ λτ b , there is a wide projection 8 , cf. Fig. 6. With c ≦ λτ a and b ≦ λτ d the projection 8 is again narrower, cf. Fig. 7.

Finally, the radius R can be extended or reduced. A radius longer than a + c produces a flatter stone, of course with a correspondingly weaker anchoring effect. With a radius R greater than ( a + 2 c ), the curvatures of the stone flanks are too flat for an effect according to the invention. A further increase in the radius leads to a boundary area in which the paving stone reaches the contour of a square (not shown, R = ∞).

If you shorten the radius to a value ≦ ωτ ( a + c ), the stone contour becomes rounder and the projection 8 longer, cf. Fig. 8, where R = 0.7 ( a + c ). The limit here is reached at R = a . If a = b = c = d , the stone flanks 1 and 2 form a single cylinder jacket. Another interesting example is the parameter constellation

a : c = b : d = 1.5
R = a

With this boundary constellation, the complete geometrical alignment of all flanks of a composite paving stone on the flanks of the neighboring stones has been achieved; the opening 10 has disappeared. The same geometrically complete system always occurs when the end of the cross leg d coincides with the zenith point 41 of the stone flank 4 . This constellation can produce very attractive stone contours, but in most (usable) cases it presupposes that the cylinder jacket pairs 1 - 3 (convex) and 2 - 4 (concave) differ from the exemplary embodiments in FIGS. 1 to 8 different radii. A composite paving stone with geometrically complete contact of all stone flanks, including the short stone flank 5 , on the flanks of adjacent stones in the paving compound is shown in FIG. 10.

Other parameter constellations also lead to a total or practically total placement of all the stone flanks on the stone flanks of the adjacent stones of a pavement network, as shown in FIG . Such stones are consistently short and wide, with radius R _1,3,5 ≦ ωτ R _2,4 . Figs. 10 to 12 show interlocking paving stones with different radii and different lengths of the cross legs. Fig. 12 shows a composite paving stone whose R _{2.4 is} twice as large as R _1.3.5 .

The embodiments of FIGS. 1 to 12 are all related to circular cylindrical stone flanks. However, the cylinder jacket surfaces 1 to 5 by other conic sections, z. B. ellipses and parabolas are shown; the axes of these conic sections then coincide with the cruciform axes a + c or b + d .

From the abundance of examples FIGS. 1 to 12, there is a wide range of design options, both in terms of anchoring effect and in terms of aesthetically attractive composite contours. The anchoring effect depends on the curvature of the cylinder surfaces; the shape and size of the projection 8 is also important for the anchoring. In addition, the lead has a pilot function in the laying.

Claims (5)

1. composite paving stone, the flanks of which are curved and alternately concave and convex in relation to the center of the stone , characterized in that the composite paving stone has the contour of an irregular pentagon with four long stone flanks ( 1 to 4 ) and a stone flank ( 5 ), which are designed as cylinder jacket surfaces in such a way that each stone flank is mirror-inverted congruent with the respective opposite stone flank ( 1 - 3, 2 - 4, 5 - 1 ), the cylinder axes of the stone flanks ( 1 to 5 ) from one of the zenith points ( 11, 21, 31, 41 ) of the four long stone flank curves ( 1 to 4 ) connecting imaginary right-angled basic cross ( 6 ) with cross legs ( a, b, c, d ) are determined by the cylinder axis of the stone flank ( 1 ) in the cross leg ( c ) or in its extension, the cylinder axis of the stone flank ( 2 ) in the cross leg ( d ) or in its extension, the cylinder axis of the stone flank e ( 3 ) in the extension of the cross leg ( d ) and the cylinder axis of the stone flank ( 4 ) in the extension of the cross leg ( b ), while the cylindrical surface of the short stone flank ( 5 ) is determined by an imaginary axis ( 7 ) that is arranged in a line parallel to the cross leg ( d ) at a distance ( b + d ) from the outer end point ( 31 ) of the cross leg ( c ) and through which the cylindrical surface of the stone surface ( 5 ) parallel and congruent with the cylinder surface ( 1 ) runs. 2. Composite paving stone according to claim 1, characterized in that the cylindrical jacket surfaces ( 1 to 5 ) are circular cylindrical. 3. composite paving stone according to claims 1 and 2, characterized in that each cylinder radius ( R ) is the same length or longer than the longest of the cross leg ( a to d ). 4. composite paving stone according to claims 1 and 2, characterized in that the cylinder radius ( R ) is smaller than the sum of the longest cross leg plus the length of two further cross leg. 5. composite paving stone according to claims 1 and 2, characterized in that the cylinder axis of the short stone flank ( 5 ) is arranged at a distance ( R ) from the axis ( 7 ), on a line parallel to the cross legs ( a + c ) extends.