RU2153553C2 - Concrete paving block - Google Patents

Abstract

FIELD: paving blocks. SUBSTANCE: paving block, particularly, made of concrete for pavements has external contour, preferably, in the form of hexagon whose side surfaces in position of placement may at least in separate zones rest on one another. Each side surface of hexagonal stone has supporting profiling which runs vertically through at least one part of height of corresponding side surfaces and at least one profile tooth and one receiving hollow with cross-section corresponding to tooth profile. Novelty consists in fact that profile teeth in zone of stone side surface have length extending over one part of height of side surface and in placed position of pavement stones form at least one groove running over perimeter for reception of sealing material. EFFECT: improved stability of binding and sealing from harmful substances in zone of gaps between stones. 21 cl, 41 dwg

Description

 The invention relates to paving stones made of concrete, in particular for paving, according to the restrictive part of paragraph 1 of the claims.

 From US patent US-A-5,267,810 known paving stones having a hexagonal shape in plan, the corresponding side surfaces of the paving stones provided with support profiling. When laying in the appropriate gap between the cobblestones stacked side by side, only sand is introduced, as a result of which, at high loads, undesirable stones can be displaced and harmful substances get into the soil under the cobblestones.

 From the German patent DE-A-330325, a hexagonal block stone is known, which has protrusions on the lateral surfaces, which, after laying, form an increased water permeability gap. In this regard, paving becomes less resistant to load and both surface water and harmful substances can penetrate through the gap under the paving stones.

 The basis of the invention is the task of creating the paving of the named type of concrete, in which, with increased load in the laid state, a reliable tight connection is possible.

 Based on the cobblestone according to the restrictive part of paragraph 1 of the claims, the invention solves this problem by the features of the distinctive part of paragraph 1. With respect to other significant forms of implementation, reference is made to paragraphs 2-21 of the claims.

 Paving stones according to the invention are provided in the area of the side walls with horizontally extending grooves which, in the laid state of several paving stones, are located between adjacent zones of the side walls in such a way that sealing material can be inserted in a certain position in this position in certain areas, with the help of which it becomes possible complete sealing of joints in paving stones.

 In this case, the groove forming the receiving cavity is simultaneously lowered relative to the serving surface of the bridge upper side of the paving stones in the horizontal direction so that, for example, displacement caused by increased loads in the area of the stone edges or damage caused by objects penetrating into the gap zone are limited respectively to the upper gap zone laying, and the receiving cavities or the sealing material inside them are protected in any case so that a dense shelter of the earth from unforeseen is achieved leaks, e.g. oils, etc.

 In this case, the shaped grooves forming the cavities can have any cross section, and especially when executed in the form of a trapezoid or a rectangle, the cost of manufacturing paving stones, for example, by simple molding by molding, can be insignificant. Similarly, the vertical height position of the corresponding groove on the side wall, the size of the groove and the number of shaped grooves on one side wall can vary significantly so that in addition to paving density requirements that vary depending on the customer, the corresponding pavers can be made with different structural forms and stacked on the pavement with the appropriate styling appearance.

 In a suitable embodiment, the sealing material, made, for example, in the form of an elastic or plastic deformable plastic tape, can be inserted into the receiving cavity when laying pavers. Due to the elastic properties of the sealing material, its sealing effect is also maintained at high loads acting on the pavement, since damage to the sealing material is largely eliminated, including with a slight vertical displacement of stones or penetrating foreign objects.

 The hexagonal cobblestones described above have, in a further embodiment, tight-fitting elements embedded, in particular, into molded stone bodies, which, when laying several stones, form opposite protruding zones in the area of the side walls. These protruding zones are directed into the stacking gap and can then be bonded in such a way that a liquid impervious zone is reliably created.

 Thus, with the help of pavers formed according to the invention and with appropriate laying, such an engagement of adjacent side surfaces is achieved that local overloads are excluded, in particular under braking and pulling loads from the vehicle to the upper side of the pavers. By distributing the pressure across the plane to several hexagonal stones, mutually resting in the area of the profile teeth, unwanted displacements in the paving stone are reliably eliminated, and thereby reliable compaction of the pavement surface from uncontrolled leakage is achieved.

 In a preferred embodiment, the profile teeth have such a shortened length compared to the height of the hexagonal stone that when paving stones are laid between adjacent side surfaces in separate zones, a laying chute arises to ensure the most reliable and remaining uniform dense laying and good sealing, for example, by means of mass filling joints.

 In the following embodiment, the paving stones have undercuts in the supporting profiling zone, due to which, using geometric closure of the interacting side surfaces, dense paving stones are achieved. Due to this, when braking and pulling away from the vehicles, loads occurring on the upper side of the paving stones, for example, shear and rotation moments in the horizontal and / or vertical direction, are transmitted through joints with geometric locking of the paving stones on the formed paving surface in such a way that overloads are reduced on individual cobblestones.

 By distributing pressure on several paving stones made, in particular, in the form of hexagonal stones, which in turn have an opposing support with a geometric closure with the help of several profile teeth equipped with undercuts, unwanted displacements in the paving stone laying plane can be reliably eliminated, including at increased loads, the formation of a gap is prevented when individual cobblestones are displaced, and thus an uncontrolled penetration of harmful substances such as oils, etc. into the ground under cover.

 Other details and advantages of the invention are presented in the following description and drawings, which clearly illustrate several examples of the pavers according to the invention.

In FIG. 1 shows a top view of the pavers according to the invention in a first embodiment,
FIG. 2 is a side view of a partial sectional view of pavers along line II-II of FIG. 1,
FIG. 3 is a top view of the pavers in a second embodiment;
FIG. 4 is a side view of a partial section through the pavers of FIG. 3 along line IV-IV shown in FIG. 3
FIG. 5 is a top view of several cobblestones of FIG. 1 stowed
FIG. 6 is a top view of several cobblestones of FIG. 3 stowed,
FIG. 7 is a top view of the pavers, similar to FIG. 1, in another embodiment,
FIG. 8 is a top view of the pavers, similar to FIG. 3, in another embodiment,
FIG. 9 is a partial section through two cobblestones when laid along line IX-IX of FIG. 5,
FIG. 10 is a partial sectional view of two cobblestones in a stacked state along line XX shown in FIG. 6
FIG. 11-22 - in each FIG. a top view of the pavers according to the invention in a suitable hexagonal shape, with different contours of the proposed profile teeth,
FIG. 23 - several cuts of pavers having profile teeth of various lengths,
FIG. 24-25 - in each FIG. top view of pavers with irregular hexagonal shape,
FIG. 26 is a schematic representation of pavers, similar to FIG. 2, with different shapes of chamfers,
FIG. 27 is a schematic representation of pavers, similar to FIG. 4, with various shapes of chamfers,
FIG. 28 is a top view of paving stones according to the invention with undercuts in a second embodiment;
FIG. 29 is a plan view of several cobblestones of FIG. 28 when stowed
FIG. 30 is a top view of paving stones with undercuts in a second embodiment;
- FIG. 31 is a plan view of several cobblestones of FIG. 30 when stowed
- FIG. 32 is an enlarged image of a section of two paving stones in a laid state with a corresponding groove on a side wall forming a common receiving cavity,
- FIG. 33 is an image similar to FIG. 32 of paving stones with a support protrusion from the side of the sole on their lateral surfaces,
- FIG. 34 is a top view of two hexagonal paving stones in a laid state with supporting profiling made by a groove-protrusion connection,
FIG. 35 is a corresponding single image, similar to FIG. 33, with a support protrusion from the side of the sole on the paving stones,
FIG. 36 is a sectional view taken along line IV-IV of FIG. 34, with paving stones having a horizontal molded groove in the region of the vertical groove-protrusion connection,
FIG. 37 is a cross-sectional image with additional material stacked in a groove, similar to FIG. 32 or FIG. 36,
FIG. 38 is a partial sectional view similar to FIG. 9, with sealing and connecting elements built into the paving stones,
FIG. 39 is a partial sectional view, similar to FIG. 10, with tight fit elements, in a second embodiment,
FIG. 40 and 41, respectively, partial sections, similarly to FIG. 32 of both forms of execution of the elements of the tight connection in the laid state.

 In FIG. 1, a cobblestone according to the invention, made in the form of a hexagonal stone 1, is presented in a plan view, and its regular hexagonal plan view is represented by the corresponding side surfaces 2 of the same length. These side surfaces 2 of the pavers 1, resting on one another in the laid state (Fig. 5, Fig. 6), have support profiling 3, by which a preferred increase in the stability of the pavers in the laid state is achieved.

 In a suitable embodiment, on a hexagonal stone 1, in the area of each of the side surfaces 2, corresponding trapezoidal shaped teeth 4, 4 'are formed as supporting profiling, and a corresponding receiving cavity 5 is formed between these profile teeth 4, 4'.

 In this case, the profile teeth 4, 4 ', vertically directed in the laid state (Fig. 5, Fig. 6), are evenly distributed, each along the corresponding side surface 2, the latter, in particular, having two profile teeth 4, 4', for which are two receiving cavity 5.

 Hexagonal stone 1 can be laid in a connected paving in any laying position, rotated around the middle vertical axis 6. To this end, each of the side surfaces 2, in an expedient embodiment, has a first profile tooth 4, starting directly at one of the vertices 8 of the hexagonal stone 1 and located after behind it in a clockwise direction the corresponding second profile tooth 4 '. In this case, the same distance remains between the profile teeth 4, 4 'A. It is also possible to arrange the profile meshing with a mirror image and the profile teeth 4, 4', starting on top 8 after each other counterclockwise.

 In a sectional view according to FIG. 2, it is specified that the profile teeth 4, 4 'have a length extension corresponding to the height H of the hexagonal stone 1. In the second embodiment according to FIG. 3 and FIG. 4, the hexagonal stone 1 may be provided with profile teeth 14, 14 ', which respectively end below the surface 9, which is the working surface of the hexagonal stone 1. Thus, the profile tooth 14, 14' has a length H 'extending to a portion of the height H of the side surfaces 2, 2 ', which in the laid state (Fig. 9, 10) can close the profile teeth 14, 14' in such a way that paving in the area of surface 9 represents only the shape of a regular hexagon.

 In FIG. 2, it is explained that the profile tooth 4, 4 ′ has a chamfer 10 in the transition zone to the outer side 9 of the hexagonal stone 1. In a suitable embodiment, the transition zone of the side surfaces 2, 2 ′ related to the zone of the receiving cavity 5, 5 ′ can also have chamfer 10.

 In FIG. 4, a profile tooth 4, 4 ', having a height H' in the region of its upper side in the laid state, is made with a bevel 11, which in the connected state (Fig. 6) forms a groove 12, ribbed from the bottom.

 In the stacked state according to FIG. 5, the corresponding upper sides 9 of the hexagonal stones 1 abutting against each other form a substantially flat working surface, which forms a joint 13, exclusively in the area of the upper chamfers 10.

 The paving stones shown in FIG. 7 and FIG. 8 are possible altered forms of the above-described hexagonal stone 1, and any increase in the cobblestone 1 or 1 ″ according to FIG. 7 and 8 as the main element having a support profiling 3 and the correct location in the area of the side surfaces, which can also be made either triangular or in the shape of a quadrangle or polygon.

 Sectional views according to FIG. 9 and FIG. 10 explain both the interconnected positions of each pair of profile teeth 4, 4 'and 14, 14', and the different execution of the joint 13 and the laying chute 12, which can be closed with sealing material during the installation of the pavers, which is achieved between the stones by a uniform butt gap (for example 10-15 mm) reliable seal, which in the area of the upper side 9 is not significantly affected by high loads.

 In FIG. 11-22, as examples, other forms of execution of the hexagonal stone 1 are shown, with each contour of the profile teeth 4, 4 'or 14, 14' being explained in a different geometric shape. Moreover, the possible triangular contour of the profile teeth 4, 4 'or 14, 14' is also not shown. The embodiments of FIG. 17-22 show the contours that in the area of the respective lateral sides 2 are provided with only one profile tooth 4 or 14 'and one receiving cavity 5.

 In FIG. 23 a) - 1) the geometrical design of the profile teeth 4, 4 'or 14, 14' is mainly unchanged, however, they have different lengths L, L ', as a result of which the hexagonal stones 1 should be laid for the most part with a predetermined position (in the drawing not submitted).

 In FIG. 24 and FIG. 25, the hexagonal stone 1 is made with different lateral lengths B and B '' and thereby clearly illustrates, by way of example, other permissible contour changes that do not affect the performance of the profile teeth 4, 4 'or 14, 14' and their associated position when laying and only change the visual perception of the pavement.

 In FIG. 26 and 27 are schematically shown in the corresponding examples from a) to c) and from a) to e) different execution of the chamfers 10, 10 'and bevels 11 in the area of the side surface 2 or profile teeth 4, 4' and 14, 14 '(similarly Fig. 2-4), and the execution form of each bevel is indicated by the letter S, and the designation R refers to the execution of the radius.

 In FIG. 28, a block stone 101 having a main contour in the form of a hexagon, but in a modified embodiment, is shown, the block stone 101 having corresponding support profiling on the side surfaces 102, which are made with the same edge length B. It is also permissible to make cobblestone with different lengths of edges and / or a different number of angles so that it is possible to create different laying structures using various polygonal contours.

 Moreover, on the side surfaces 102, 102 'of the cobblestone 101, corresponding groove elements 103 and a protrusion element 104 are provided, alternating in the direction of the periphery, similarly to the embodiment shown in FIG. 1-28, due to which when laying (Fig. 29, Fig. 31) an effective support profiling is formed for several hexagonal paving stones 101.

 According to this embodiment, in the cobblestone stone 101, there is provided support profiling in the region of the groove-protrusion elements 103, 104 with corresponding undercuts 105, 106, which allow, at low cost, to improve the stability of the connection of the cobblestone stones 101 in the laid state (Fig. 29).

 As shown in FIG. 28 and 30, individually in a plan view of the cobblestones 101 and 101 ', it is seen that the undercuts 105, 106 or 105', 106 'pass vertically (i.e. perpendicular to the plane of the drawing) through the respective side surfaces 102, 102'. In an expedient form of execution and to reduce manufacturing costs, in each of the side surfaces 102, 102 ′ only one corresponding groove element 103 and one protrusion element 104 are provided, moreover, the arrangement of several of the same supporting profiling with undercuts 105, 106 or 105 'is also possible, 106 '.

 For a more complete geometric closure in a stable state, groove elements 104 and protrusion elements 103 in the area of undercuts 105, 106 are made with a cross section that is additional and provides simple vertical fixation when laying paving stones 101, with individual images in FIG. 28 and 30 illustrate a preferred embodiment in which the groove elements 104 and the protrusion elements 103 in the area of the undercuts 105, 106 have a pointed triangular shape. In this case, a rectangular or arc contour of the undercuts is also possible.

 In a second embodiment of the pavers 101 of FIG. 30, the contour of the fit of the undercuts 105 ', 106' is made with additional support radii 107, 108 in such a way that manufacturing and laying of paving stones 101 'are simplified.

In a further acceptable form of execution, the undercuts can be made with a length that extends only in separate sections along the height of the side surfaces 102, 102 '(not shown in the drawing) in such a way that, if necessary, the paving stones engage with each other when laying at an angle of 180 ^o . It is also conceivable to provide an undercut at least zonally in the support profiling extending horizontally in the respective lateral surfaces in such a way that the horizontal stability of the pavers can improve the stability in the laid state and the impermeability of the pavement surface.

 In FIG. 32, in an enlarged section, two cobblestones 201, 201 ′ which are in a laid state are clearly illustrated, and when taken together with a plan view according to FIG. 34, a polygonal outer contour (here: a regular hexagon) of paving stones 201, 201 ′ is clearly shown. Two adjacent cobblestones 201, 201 'for paving (not shown) in the area of their lateral sides 203, directed towards each other and perpendicular to the upper surface 202, rest on each other and form a laying gap 204 in the common support zone .

 Cobblestones 201, 201 ′ in this embodiment in the area of the side surfaces 203 are respectively provided with only one groove 205, 205 ′ (FIG. 32, FIG. 33) so that several paving stones 201, 201 ′ (FIG. 34) in the laid state form a predominantly closed receiving cavity 206, 206 ', passing in all side surfaces 203.

 In an expedient embodiment, an elastic sealing material 207 is laid in the receiving cavity 206, 206 '(Fig. 37), with which the receiving cavity 206, 206' is respectively filled at least in sections. In this preferred embodiment, the sealing material 207 may have oblique corrugations 208, which in addition to the known jointing material 209 for filling the joint, for example an adhesive containing bitumen and the like, contributes to an increase in impermeability.

 In the receiving cavities 206 or 206 'shown in FIG. 32 - FIG. 37, grooves 205, 205 ′ are formed so that the corresponding paving stones 201, 201 ′ in a laid state form a predominantly horizontally extending receiving cavity 206, 206 ′. It is also acceptable that the grooves are made with a contour in the shape of a meander (not shown in the drawing) and the corresponding side walls of the groove 211 and / or the bottom 212 of the groove (Fig. 33) have such a profile that various cross-sectional shapes of the receiving cavities arise and they can take for example, a correspondingly formed sealing material 207 so that a quick laying of paving stones 201, 201 ′ is possible without additional auxiliary means.

 According to the embodiment of FIG. 32 - Fig. 37, in the corresponding lateral surfaces 203 of the cobblestones 201, 201 ', instead of the separate groove 205, 205' shown in the drawing, there can also be several parallel grooves (not shown in the drawing) so that at a low cost it is possible to lay the sealing material 207 at different heights of the side surfaces 203 or at the same time use several receiving cavities as sealing zones.

 In an expedient form of execution, the grooves 205, 205 'are located on the corresponding side surface 203 of the adjacent block stones 201, 201' at the same height (Fig. 32, Fig. 33), due to which a significantly larger receiving cavity 206, 206 'is formed on both sides.

 In the embodiment of the paving stones 201, 201 ′, according to FIG. 33, corresponding lateral surfaces 203 ′ are provided below the corresponding grooves 205, 205 ′ with a forwardly shaped protrusion 214, 214 ′ relative to the upper zone 203 ″ of the side surface so that In the presently laid state, the lower shaped protrusions 214, 214 'are adjacent to each other and, near the upper surface 202 of the stones 201, 201', form an upper expanding gap zone 204 ', the width B of which allows additional packing of the sealing material 207.

 Cobblestones 201, 201 ′ shown in FIG. 34 have, in the area of their side surfaces 203, supporting profiling 215 extending in the vertical direction and intersecting at least in certain sections with the corresponding groove 205, 205 ', which, when laid, of several paving stones 201, 201', is additional to each other and located in stable support interaction, the gear elements are a groove-protrusion 216, 217. Due to this implementation of the support profiling 215 and the grooves 205, 205 'extending around the periphery, it is possible to obtain paving stones in which combi are available at low cost Support profiling and a clearance 204, 204 ', which are protected against the penetration of harmful substances, result in particularly high resistance to stress.

 FIG. 35 and FIG. 36 explain in a corresponding right image the possible implementation of the receiving cavities 206 'with, respectively, only one-sided, located, for example, in the area of the support projection protrusion element 217 21 of the recess 205 ", and one-sided arrangement of this type of receiving cavity 206' may be provided, in particular for the indicated paving stones laying area (not shown in the drawing) and joint laying of extreme stones having corresponding flat side surfaces and the above stones with grooves.

 In FIG. 38-41 illustrate clearly other possible forms of execution of cobblestone 1 or 201, according to the invention, presented in section, improving the impermeability of the working surface, each of which is equipped with an element 300 tight connection built into the body of the stone with a geometric closure, which, for example, is cast simultaneously with the manufacture of concrete stone.

 In the embodiment of FIG. 38, the tight-fitting element 300 is formed as a frame element 301, covering the side surface 2 of the cobblestone 1 from the edge side, the fastening elements 302 of which are cast during the manufacture of the cobblestone 1 and thereby connect the frame element 301 in the form of a counter hook to the main body stone. In the laid state of both cobblestones 1 shown in the drawing, the respective frame elements 301 are directly adjacent to each other and connected in the upper area of the laying groove 312 by means of, for example, an adhesive or weld joint 312 so that the joint 13 is impervious to liquid.

 In FIG. 39-41, further embodiments of the tight fitting element 300, which according to FIG. 39 and FIG. 40 is made in the form of a tape profile element 314, fixed in the body of the stone using the elements of the counter hook 202 '. The tape profile elements 314, in the stacked state shown in the drawing, are connected in the area of the connecting seams 312 'in such a way that the cavity zones having the expansion are also closed from the liquid. Presented in FIG. 41, an embodiment illustrates a frame member 301 similar to the embodiment of FIG. 38, in combination with the receiving cavity 206 of FIG. 40.

 In a suitable embodiment, the frame element 301, as well as the tape profile element 314, are made of thermoplastic artificial material so that the corresponding connecting seam 312 'in the laid state can be obtained using a simple heating element.

Using the above-described hexagonal contour, a paving stone is obtained which, due to its lateral surfaces, when laying on a plane at a uniform angle of 120 ^°, has a stabilizing effect on adjacent stones, while at the same time increased resistance to fracture of individual stones and reliable sealing in the area of the laying joint are achieved.

Claims (21)

 1. Cobble stone, in particular concrete, with an external contour forming preferably a hexagon, the side surfaces (2, 102, 203) of which, facing the adjacent cobblestones laid on the base, are provided with support profiling (3, 103, 104, 215), which extends vertically through at least part of the height of the respective side surfaces (2, 102, 203), and has at least one profile tooth (4, 4 ', 14, 14 ', 104, 217) and one receiving cavity (5, 103, 105) with a cross section corresponding to tooth profile, and when laid, profile teeth (4, 4 ', 14, 14', 104, 217) of one paving stone (1, 101, 201) enter the corresponding receiving cavities (5, 103, 105) of the corresponding neighboring paving stone (1, 101, 201), characterized in that the profile teeth (14, 14 ') of the cobblestone (1, 101, 210) in the area of its side surfaces (2, 102, 203) are made with a length (H') extending along part of the height (H) of the side surface (2), and in the laid state of the paving stones (1, 101, 201), form at least one groove (12, 205, 205 ', 205' ') extending around the perimeter to receive the sealing material (207, 208, 209).  2. Cobblestone according to claim 1, characterized in that the profile teeth (14, 14 ') end below the upper side (9) of the cobblestone (1) serving as a working surface.  3. Cobblestone according to claim 1 or 2, characterized in that the profile teeth (14, 14 ') have an upper bevel (10, 11).  4. Cobblestone according to any one of claims 1 to 3, characterized in that the side surfaces (2) have a chamfer (10 ') between the profile teeth (4, 4') in the transition zone to the upper side (9) of the paving stone (1). )  5. Cobblestone according to any one of claims 1 to 4, characterized in that at least one profile tooth (4, 4 ') and one receiving cavity (5) are located on each side surface (2) at a distance from the vertical edges ( 8) side surface (2).  6. Cobblestone according to any one of claims 1 to 5, characterized in that the profile teeth (4, 4 ', 14, 14', 104, 217) are made trapezoidal.  7. Cobblestone according to any one of paragraphs. 1 - 6, characterized in that each side surface (2, 102, 203) is equipped with several profile teeth (4, 4 ', 14, 14', 104, 217) and several receiving cavities (5, 103, 205).  8. Cobblestone according to any one of paragraphs. 1 - 7, characterized in that each side surface (2) has a first profile tooth (4, 14), starting directly from the corner (8), mainly hexagonal block stone (1), and located at a certain distance from it counterclockwise second profile tooth (4 ', 14').  9. Cobblestone according to claim 8, characterized in that the profile teeth (4, 4 ', 14, 14') of each side surface (2) have the same distance (A).  10. Cobblestone according to any one of claims 1 to 9, characterized in that the profile teeth (4, 4 ') have a length corresponding to the height (H) of the paving stone (1).  11. Cobblestone according to any one of claims 1 to 10, characterized in that in the area of its lateral surfaces (2, 102, 203) it is equipped with an element (300) of a tight connection protruding outward from each side surface (2, 102, 203 )  12. Cobblestone according to any one of claims 1 to 11, characterized in that the profile teeth (4, 4 ', 14, 14') and the receiving cavity (5, 103, 205) of the supporting profiling (103, 104) have at least at least one undercut zone (105, 106, 105 ', 106').  13. Cobblestone according to claim 12, characterized in that the undercut zone (105, 106, 105 ', 106') passes through the entire height of each side surface (102, 102 ').  14. Cobblestone according to claim 12 or 13, characterized in that the undercut zones (105, 106, 105 ', 106') have rounded transitions (107).  15. Cobblestone according to one of claims 1 to 14, characterized in that in each of the side surfaces (203) there are several grooves extending in parallel (205, 205 ', 205' ').  16. Cobblestone according to any one of claims 1 to 15, characterized in that the grooves (205, 205 ', 205' ') in the laid state of the cobblestone (201, 201') extend predominantly horizontally and form a horizontal grip with a corresponding tooth cobblestone grooves.  17. Cobblestone according to any one of claims 1 to 16, characterized in that the groove (s) (205, 205 ', 205' ') is located (s) at the same height on each side surface of adjacent cobblestones (201 , 201 ').  18. Cobblestone according to any one of claims 1 to 17, characterized in that the groove (s) (205, 205 ', 205' ') in the longitudinal direction of the profile extends respectively in a straight line or in the shape of a meander.  19. Cobblestone according to any one of claims 1 to 18, characterized in that the corresponding side surfaces (203 ') have a shaped protrusion (214, 214') below the grooves (s) (205, 205 ', 205' ') relative to the upper side surface areas (203``).  20. Cobblestone according to any one of claims 1 to 19, characterized in that the element (300) of the tight connection is embedded in the paving stone (1, 101, 201) and adjacent elements (300) in the laid state of several paving stones can be connected to each other other in the respective areas (12, 13, 204, 206).  21. Cobblestone according to any one of claims 1 to 20, characterized in that the tight joint element (300) is made in the form of a plastic profile element.

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