HU227063B1 - Moulded brick building set - Google Patents

Abstract

A moulded brick building set is inserted in a pavement. In order to provide various laying possibilities with bricks of various sizes, the moulded bricks have on their side walls mutually adapted spacers which mesh with each other.

Description

The present invention relates to a form stone building kit according to the preamble of claim 1.

Shaped stones, and in particular paving stones, are known in many embodiments. They are used to create gardens, roads and walkable surfaces. Such paving stones may have flat side surfaces with parallel axes on their sides where the paving stones can be laid with or without a joint. These stones are provided with side teeth and locking joints to prevent lateral slipping of the laid stones. In this connection, the form-locking joints may be made flat (DE 31 16 540 C2; US 34 94 266) or interlocking tooth elements (DE 92 01 491 U1; EP 00 60 961 B1). According to the prior art, the tooth or joint extends substantially over the entire sidewall, so that no joints, crevices or other intermediate spaces between adjacent stones are at all. However, a tooth can also be formed in a form-locking manner by means of spacers on the side walls, as described, for example, in DE 37 43 035 A1. The spacers provide intermediate spaces or joints between the paved stones, which allow for a secure wedge between the stones and a toothed connection and better drainage between the paved surfaces. In this context, the application of such stone systems clearly recognizes the desire to avoid, as far as possible, the adhesion of surfaces, that is to say, the rainwater should run off the entire casing or leak. This can be accomplished with spacers and intermediate spaces.

The disadvantage of the known paving stone systems is that, due to the most often unbroken teeth or the surface design of the sidewalls with a toothed surface, the joint construction with the possibility of trouble-free drainage is not achieved. If the known paving stones have only individual spacers on their side walls as tooth elements and joint forming tools, they cannot be used in a form stone building kit. Further, it is disadvantageous for known paving stones that the corner sections of the stones are subjected to a higher, possibly destructive load.

From the printed specification DE-U-9 208 769, a form stone is known which is also provided with spacers spaced off relative to one another at the side edges of the paving stone. However, these spacers do not form a tooth but serve to create a smooth side joint.

It is an object of the present invention to provide a form stone building kit that provides equal sized joints and trouble-free water leakage throughout the casing while maintaining mutual anchorage in the event of lateral displacement forces. In addition, diversity of design options must be ensured. Another object of the invention is to reduce the load on the sensitive corner sections of the stones.

The object is solved by starting from the paving stone according to the scope of claim 1 with the features in the characteristic part of claim 1.

The present invention provides various shaped stones, and in particular paving stones, which are suitable for insertion into a paving joint in a building kit, i.e. for insertion into a grid in the form of a surface covering. In addition, they have side spacers that allow joint construction and thus provide trouble-free drainage of the surface. The spacers are located on the sidewalls of the paving stones in such a way that they provide a lateral, shape-locking engagement of adjacent impact surfaces, whereby the spacers are arranged to conserve the corner sections of the form stone.

The invention further provides a set of form stone building blocks consisting of paving stones of various sizes. Therefore, the lateral spacers must be designed and aligned with each other to provide reliable lateral anchoring or tooth engagement for each stone size, i.e., to provide a near-tilt toothed coupling for each adjacent side surface. Special gaps between individual spacers allow for optimum drainage effect while simultaneously protecting the particularly stressed corner sections of the stones when in place or during placement.

The invention will be further described with reference to the following exemplary embodiment and the accompanying drawings. In the drawing it is

Fig. 1 is a top plan view, schematically depicting, a first embodiment of a form stone building kit; the

Figure 2 is a perspective perspective view of the shape stones of Figure 1; the

Figure 3 is a top plan view, schematically illustrated, of an enlarged building set compared to Figure 1; the

Figure 4 is a perspective view of the additional building blocks shown in Figure 3.

As shown in Figure 1, the form stone building set consists of rectangular and square individual 1-12 stones. The

According to the horizontal and vertical guide lines 13 and 13 'shown in Fig. 1, each of the paving stones 1-12 consists of square segments 14 having one or more edge lengths li.

Fig. 1 shows a rectangular foundation stone 1 with a shorter side wall Ι ₂ = 2χ | · | and its long side 16 has a length of l ₃ = 3xl ₁ . The plan view of the foundation stone 1 shown in Figure 1 is thus made up of six square segments 14.

Fig. 1 further illustrates a 1/2 stone with a reference mark 2 which covers the surface of the base stone 1 and is formed by a longitudinal section bisecting the shorter side wall 15 of the base stone 1 along the horizontal guide line 13 '. The reference sign 2 half-stones thus identical longer length l ₃ has sidewalls 16 and shorter sidewalls 17 of length li.

The foundation stone one one with 3 other reference numerals 1/3 stone is assigned to that top view shown in Figure 1 includes two rectangular segment 14 surface includes _I2 = 2XL _one length longer than 15 sides and length of the short side wall 17.

HU 227 063 Β1

If we divide the 1/3-stone of reference 3, a 1/6-stone of 4 is obtained in the form of a smaller square stone of side length.

The corresponding sidewall is again represented by the symbol 17.

While 2-4 stone shapes to correspond to the parent material 1 less with embodiments as long by 5 reference sign 1 1/2 stone this shape is enlarged, the surface is made up of nine squares 14 segments and provides L ₃ side length of square contours. Its surface consists of the joining of the foundation stone 1 and the 1/2 stone with the reference numeral 2. The side walls 16 are 1 _{3 in the} case of 1/2-stone, corresponding to the longer side wall 16 of the foundation stone 1, shown as a side edge.

If doubling of the parent material surface 1, the rectangular shaped clear double-6 recovered length l _3, and l is shorter sidewalls 16 ₄ = ₂ = 4xl 2XL _one long side wall 18. The double stone 6 therefore consists of twelve square 14 segments.

The development of the paving stone building kit of Figure 1 is illustrated in Figure 3. While illustrated square formaköként 5 reference sign 1 1/2, followed l _three edge length 16 side wall, i.e. in the main stone one long side wall is plotted, while in Figure 3 a normal square 7 followed converted _I2 élhosszúsággal, i.e., the parent material 1 less than 15 sidewall Who. As a result, its surface consists of four square 14 segments.

By doubling the square stone 7 with an edge length l ₂ , a second rectangular double stone 8 is obtained, the shorter side wall 15 having a shorter side length l ₂ and the longer side wall 18 having a length l ₄ = 2x l ₂ . The longer sidewall 18 corresponds to the same sidewall 18 of the first 6 double stones.

Quadrupling the top view surface of the small square stone 7 and doubling the surface of the second double stone 8 results in a large square stone or quadruple stone 9 having a side length 2x _{4 2} = ₄ x _{1 1} .

In addition to the stone shapes 1-9, as shown in Fig. 3, a corner stone 10 is constructed, which in plan view consists of two small square 7 stones of edge length 1 ₂ touching each other in a corner 21, complemented by a diagonal cut square stone 7 we produce. As a result of the cut-off diagonal 19 'of the square stone 7 ₅ = V ₂ x 12 ₂ , an oblique running sidewall 19 is formed in the corner stone 10. As a result, the corner stone can be made up of two square cubes 7 and a diagonal section of a square stone 7, i.e. the diagonal segment 20 depicted as a "diagonal element", with corresponding additional spacers.

The paving stone system is further supplemented with a

3, which in principle corresponds to the corner stone 10, but with two diagonal segments 20 mirrored at the corner, so that two diagonal segments 20 ', 20' are formed. For the sake of understanding, here we have marked the additional 19 ”diagonal in the 10 corner stones. Again, this diagonal stone 11 is composed of two square stones 7 and two separate diagonal segments 20 ', 20'.

Each of the molds 1-11 has spaced spacers 22 on the outer wall 15-19 of the same concept.

Each spacer 22 of FIG. 1 has a trapezoidal cross-sectional view in plan view, with a base plate 23 resting on the respective sidewall, which is _{16 in} length. All 22 spacers h- | The height of the trapezoid is given, for example, at the foundation stone 1 and it essentially defines the joint width of the adjacent shaped stones. 1, the outer trapezoidal sides 24 of the spacers 22 generally touch the respective opposite side walls 15-19 of the adjacent stone.

According to the foundation stone 1, the spacers 22 are arranged in such a way that starting from each corner 25 of the respective form stones 1-12, a small gap 26 is formed from the corner 25 towards the first side wall (e.g. 16 for the foundation stone 1) and the other side wall. (for example 15 for the foundation stone 1), a large slot 27 having a width "b" is formed before the first spacers 28 and 29, respectively. The distance or slit width "a" is then selected to be approximately the same as the uniform width "c" of the spacer 22 of the form stones 1-11, whereby the width "c" corresponds to the base length _{6 of} the trapezoid shown.

The width "b" of the larger slot 27 and the distance are chosen as twice the value of the width "a", i.e. bs2as2c. By this measure all corners of the form stones are kept at a sufficient distance from the spacers. As a result, there are no loads, heel pressures, that is, the compressive forces acting on the heel section, which avoids injury during placement and load in the lowered position. Furthermore, the slots 26, 27 provide sufficient space at least in the corner section of the stones for good drainage, which may also be facilitated by slots in the middle section of the side surfaces of the stones. Each of the form sections 1 to 11 has an appropriate arrangement of spacers 28, 29 on the corner sections.

If the aforementioned arrangement of spacers 28, 29 is reduced by the corresponding slots 26, 27 to the stone 1/6 of Fig. 1, there will always be only one spacer on each sidewall 17 for an edge shape β. The significance of the spacers 28, 29 is thus consistent with which corner is involved. The same applies to the corner sections of the short side walls 17 for the shape stones 2 and 3.

In the case of the side walls 1, ₂ , 1, ₃ , ₄ , ₄ , 15, 16, 18 shown in Fig. 1, additional spacers are provided on the side walls for producing a tooth-shaped tooth between the shaped stones. In addition, each of the conceivable square segments 14 of side U has a spacer 29, 29 'at distance b or

EN 227 063 Β1 from the 25 corners of the stone or one of the 30 corners of the respective square segment 14 and this spacer has a length "c" in the sidewall section of length β. This smaller square segment 14 has a smaller gap at the other corner with a distance "a". In this connection, reference is made to the 5 stone. Consequently, if there is only one spacer on the outer surface of a square segment 14, the edge length is determined by the dimensions a + c + b, where "a" is the small slot, "b" is the large slot, and "c" 'indicates the spacing width. This is shown in Fig. 1 in the case of foundation stone 1 on the upper side wall 16.

As in Figure 1 the longer l ₂ l _four side walls show the current 25 from corner to the shorter, in "a" from 28 spacers followed by a further 32 spacing the rectangular segments belonging to it, starting at the adjacent rectangular segments 31 corners and " c ”width. For such a segment I · long, square 14 ', starting from the corner 25 of the form stone, the order is the distance "a" plus the width "c" of the first spacer 28 plus a slot "33" of width adjacent to a spacer is defined by the width "c" of the second spacer 32.

For each sidewall 15-18, after the first spacer 28 from the corner 25, there is always a second spacer 32 in the respective square segment 14 at distance "a". The next square segment has a lateral spacing 29 and 29 ', respectively, for the side wall l _{2 of} length 15. This corresponds to the arrangement of the base length l _{2 for the form} stones 1, 2, 3.

If the sidewalls of form stones 1 and 2 are increased from length l _{2 to} length l ₃ , an additional segment of length β is inserted to extend length l ₂ 'with the additional spacer 29'. If this spacer 29 'is at a distance "b" from the corner section 25, then it will coincide with spacer 29.

Each of the opposite sides of each of the molds 1-6 is formed diagonally-symmetrically, i.e. the respective side walls 15-18 are rotated counterclockwise or counterclockwise. Thereby basically repeated l _2, l ₂ 'away from the 28, 29, spacers 32 and a possible additional auxiliary, l ₁ a square segment 14 laying! pattern.

The respective widths of the spacers and the gaps between them correspond to a single or multiple of the respective dimensions, so as to allow trouble-free interlocking tooth engagement when the stones are slid into one another. In addition, in the case of shaped stones of lengths ₃ and 1 ₄ , gaps are formed not only in the corner section but also in the middle section of the stone for better drainage. This results from the spacers 29 'arranged individually in the respective square segments.

The spacers principle 15 sidewalls _I2 longitudinal section depicts a consequence of working examples in which case two 28, 32 spacing is a square 14 'segment, and a third spacer 29 is disposed in this 15 side wall of the next segment. The two spacers 28, 32 cooperate with the spacer 29 of the adjacent paving stone when the stones are joined, i.e. the spacer 29 penetrates into the gap 33 between the spacers 28, 32.

If the sidewall length l _{2 is} increased one or more times the length section β according to the length dimensions l ₃ and l ₄ , additional spacers 29 ', 32' are provided on each side wall 16, 18, which are also in raster size corresponding to raster lines away.

Accordingly, as shown in Fig. 1 for form stone 1, the longer side wall 16 of length 1 _{3 is made up of} a length section 1 ₂ 'plus a length section, where the length section ₁₂ ' is the short side wall 15 Represents the movement of its ₂ longitudinal sections counterclockwise. The two spacers 28, 32 of the sidewall 15 thus become the corresponding spacers 28, 32 at ₁₂ '. The sidewall 16 thus consists of the sidewall 15 of the shorter sidewall of the form stone and, consequently, the sidewall 17 of the form stones 2-4.

The opposite side walls of each of the form stones 1-9 are arranged diagonally-symmetrically, i.e. they are always placed in the same direction of rotation on the stone.

In the same six stone increased the longer side wall 17 l ₂ doubles so that the three side walls 15 28, 32, 29 spacing of the pattern doubled. This is illustrated in the _I2 'plotting. Consequently, if the length l ₂ sidewalls 15 are placed one behind the other two, is obtained by the side wall 18 of length L _4.

The arrangement of the spacers described above continues with the additional shape versions shown in Figure 3. The paving stones 7, 8 and 9 also have a characteristic arrangement of two spacers 28, 29 starting from each corner 25, which seal one or more spacers between them. This is illustrated in Figure 3 in a specific order.

The respective inclined surfaces 19 of the form stones 10, 11 also have two spacers 28 ', 29' spaced apart from the corner section and spaced a 'and b' from the respective corner 25 '.

In addition, there is again a proper arrangement of the distances a ', b' and c '. The oblique surfaces 19 of the stones 10, 11 correspond to the diagonal 19 'of the square stone 7, so that the arrangement and dimensions of the oblique surface 19 and the diagonal 19' are derived from the equation Ι ₅ = λ / 2 * Ι ₂ . The dimensions of the spacers 28 ', 29' and 32 'are similarly derived from this calculation rule, i.e. cc * V2, aa * V2 and bb * V2.

2 and 4 are perspective views of the individual shapes. Identical parts are denoted by the same reference numerals. Similarly, the sidewalls 15-19 are depicted with appropriate spacers.

HU 227 063 Β1

According to the representation of the base stone 1 in Figure 2, this stone is of height H. The spacers 22 extend from the base surface 34 to a height h ₂ which does not extend to the upper surface 35 of the respective mold stone but ends at a distance "d" from the upper surface 35. Thus, the tooth-like spacers are not visible when the stones are laid.

As mentioned, the opposite sides of each form stone are formed identically, wherein the spacers are arranged in a circumferential direction of rotation, i.e. diagonally.

Perspective representation of the shape stones 7-11 a

Figure 4 corresponds to that of Figure 3. Again, like parts are identified by the same reference numerals.

As shown in particular in FIG. 3, all molds 1-11 can be placed in a predefined raster system where the side walls can be guided into each other in a form-fitting manner. Thus, a large number of placement shapes are possible. The raster value for the overlapping spacers is R = nxl ₁ + 2x1 / 2h, where n = 1-4 and Ιη is the height of the spacer 22.

The invention is not limited to the embodiments described and illustrated. It includes many other additions and modifications within the scope of the claims. Thus, as indicated, individual stones can be disintegrated into pieces of stone, such as by diagonal cutting the square stone 7 into diagonal members 20, 20 ', 20' which again have suitable spacers on each side. According to the calculation rule I ₅ = I ₂ xV ₂ , the corresponding dimensions on the diagonal surface 19 are enlarged.

Furthermore, it would be possible to develop a square 12 complementary stone (Hypotenus stone) l ₅ = V2x | ₂ laterally for lateral continuation of the inclined surface 19 as indicated in FIG.

Finally, a small 4 square stone can be developed, or so

The side walls 17 of the form stones 2 shown in Figures 1 or 3 a

2, the special stones 2 ', 3', 4 'may be formed as sidewalls 17', starting with an additional spacer 36, 36 'in the corner section to provide a flat or two-point abutment surface for machine deposition, thereby prevent tilting.

Claims (19)

PATENT CLAIMS Form stone building kit, in particular for insertion into paving stone, which is provided in a grid-shaped raster on the surface and on its side walls (15-19) with spacers (22, 28, 29), wherein at least one form stone (1-12) is a raster consisting of a plurality of segments (14) and having at least one of the spacers (22, 28, 29) on each side surface of the respective square segment (14) adjacent to an adjoining stone, and the form stone (1-12) on both sides of its corners (25). provided with a gap (26, 27) formed by at least one of the widths (c) or multiple of one of the spacers (22, 28, 29), characterized in that the spacers (22, 28) of adjacent shaped stones (1-12) , 29) and each side wall (15-19) of the form stone (1-12) in the direction of one of the corners (25) on the one hand, from a spacer (28) is formed by a larger slot (26) and a larger slot (27) having a width "b" from an additional spacer (29), whereby the width "a" is approximately one-fold and the width "b" is approximately twice as wide (27). 29, 29 ') the width "c". Form stone building set according to claim 1, characterized in that for more than one form stone (1-3, 5-11) having a square segment (14) of length β, each segment (14) lying at the corner (25) of the form stone the segment having one spacer (29) on one outer side and two spacers (22) on the other outer side (28, 32). The form stone building set according to claim 1 or 2, characterized in that one of the outer sides of a square segment (14) arranged outside the corner section of a form stone, facing towards the adjacent stone, has at least one spacer (29 '). with a small "a" slot and a large "b" slot relative to their respective corner points (30, 31). 4. Form stone building set according to any one of claims 1 to 4, characterized in that the outer side of an additional square segment (14) arranged outside the corner section of a shaped stone facing an adjacent stone has two spacers (28 ', 32'), one of which bordering the corner. 5. Form stone building set according to any one of claims 1 to 3, characterized in that on the opposite side walls (15, 19) of a form stone (1-12) the spacers (22) are arranged in the same arrangement, but transversely symmetrical or in the same direction of rotation. Form stone building set according to any one of the preceding claims, characterized in that it is provided with a rectangular foundation stone (1) which has a surface view of six square segments (14) of side length Ι-, where the side walls (15, 16) Ι ₃ = 3χ | · | l ₂ = 2x1 to ₁ , and wherein the shorter side wall (15) with three spacers (28, 29, 32) and the longer side wall (16) for the shorter side wall (15). 15) has an additional third length segment β with respect to it and is provided with an additional spacer (29 ') at a distance "b" from the corner (25). 7. Molded brick building set according to claim 6, characterized in that a half-stones (2) are provided, of which the longer side wall (16) of the foundation brick (1) Preparation of _3-length, the longer side wall (16) in an appropriate manner, the shorter side wall (17) and the foundation brick (1), a shorter side wall (15) l _2/2 half length and the foundation brick (1) is a square segment (14) β is formed in accordance with the length, wherein the shorter side wall is a (17) or two spacers (28, 29, 36). HU 227 063 Β1 8. Molded brick building set according to claim 6 or 7, characterized in that a further third-stone (3) is provided, which in each case a long side wall (15) of the foundation brick (1) _I2 length shorter sidewall ( 15) is suitably formed and at all times has a shorter side wall (17) provided with a spacer (22) at a distance "a" or "b" from the farthest one. Form stone building set according to one of Claims 1 to 3, 4 or 5, characterized in that it is provided with a first small square stone (4) having four side walls (17), one from the corner section (25). ) at all times "a" and (22) is arranged on spacers "b" distance, wherein the β side length corresponds to the molded brick (1) l _2/2 half-side length, or a square segment (14) β page length, and the stone ( 4) Preferably, an additional spacer (36, 36 ') is provided on the corner portion of each side wall (17). 10. Claims Molded brick building set according to any one, characterized in that a second large, there is provided (5) square brick having a side wall (16) corresponds to the foundation brick (1) Preparation of _3-length of the longer side wall (16); 11. Molded brick building set according to any preceding claim, characterized in that a further medium square brick provided with (7) having a side wall (15) of the foundation brick (1) Preparation of _2-length, shorter side wall (15) corresponds. 12. Molded brick building set according to any of the preceding claims, characterized in that it comprises a fourth square brick (9) having a L length of the sides _of length ₄ (18) of the foundation brick (1) L corresponding to the shorter side length of length ₂ twice (15). 13. Claims Molded brick building set according to any preceding claim that has a first rectangular double stone provided (6) having a longer side wall (18) of the foundation brick (1) the shorter side wall (15; 2XL ₂₎ corresponds to twice, and having a shorter The side wall (16) corresponds to the longer side wall (16) of the base stone (1) l ₃ . 14. Molded brick building set, characterized in that it has a further rectangular double stone with (8), the respective longer side wall (18) of the foundation brick (1) a short side wall (15, 2χ | ₂₎ according to claims corresponds to twice, and the respective shorter side wall (15) of which corresponds to a single l _{2 of} the short side wall (15) of the foundation stone (1). 15. Form stone building set according to any one of claims 1 to 3, characterized in that the foundation stone (1) is made up of two 1/2 stones (2) with spacers (22) on each side. 16. Form stone building set according to any one of claims 1 to 3, characterized in that it comprises a corner stone (10) made of _two square surfaces having a side length 1 _{2 of the} shorter side wall (15) of the base stone (1) in contact with one corner (21) and a connecting diagonal segment (20), wherein each outer surface (15) is formed with a tooth (28,29, 32) and the diagonal surface (19) is formed with a corresponding tooth (28 ', 29', 32 '). 17. Form stone building set according to any one of claims 1 to 3, characterized in that it has a diagonal stone (11) which is spatially or planarly two squares of a side length l ₂ corresponding to the shorter side wall (15) of the base stone (19 '). is formed of stone (7), wherein the bounding inclined surfaces (19) correspond to the length of the diagonals (19 ') of the square (7) and are preferably spatially aligned. 18. A 10-12. Form stone building set according to one of claims 1 to 3, characterized in that each square stone (5, 7, 9) and / or each rectangular stone (1, 2, 3, 6, 8) can be separated along at least one diagonal (19 '), where the diagonal oblique surface (19) is also provided with spacers (29 ', 29', 32 '). 19. Molded brick building set according to any of the preceding claims, characterized in that a further supplementary brick (12) (Hypotenus-stone) is associated with an oblique surface (19), matched to the respective oblique surface (19) l ₅ lateral edge lengths.