DE19960320A1 - Paving stone system - Google Patents

Abstract

The invention relates to a paving stone for use in a paving stone system having a lattice-shaped grid, the paving stone having spacers or cams on at least two opposite or adjacent sides. A paving stone system is proposed which has good drainage properties and in which thrust transmission from one paving stone (1) to an adjacent paving stone (1) is possible without risk of damage to the side flanks (29, 30) of the spacers (21).

Description

The invention relates to a paving stone according to the Preamble of claim 1.

Various are on paving stone surfaces Criteria / demands made.

One criterion for paving stones is an effective lateral one Gearing through which a firm anchoring of the Paving stones is reached among themselves, so this can withstand high loads. Such burdens occur, for example, by a braking or turning vehicle on. With such stones comes Often an all-round gearing is used, as they do for example from German utility model 94 09 076 U1 is known. Good drainage properties play a role here not matter.

Another criterion is good drainage properties a surface composed of paving stones. So will for example in EP 0 648 291 B1 a paving stone described with a neighboring stone through the front toothed abutting, stair-shaped spacers is. This paving stone allows thrust transmission the neighboring stone in one direction. Through the abutting spacers becomes larger Gap formed between the paving stones, which itself has a positive effect on the drainage properties because this increases the area on the water can seep away. With a strong shear load such  Paving stones are subject to increased teeth Risk of breakage and / or increased wear. That is, the Cams have to be made very large and stable around the To be able to withstand loads on their side surfaces. This in turn is material-intensive and therefore cost-intensive and means a reduction in the area on which water can seep away.

The invention has the task of a paving stone in one Propose paving stone system, which good one Has drainage properties and one Thrust transmission from a paving stone to one neighboring paving stone without the risk of damage the side flanks of the spacers is possible.

This task is based on a paving stone type mentioned in the introduction by the characteristic features of claim 1 solved.

The essence of the invention is a paving stone with a Cam group together with at least one cam or one another group of cams of a neighboring paving stone encloses at least one pocket or a pocket-shaped one Forms a space or a kind of half-pocket. By the Interaction of the cams becomes a functional unit formed, in which the cams with the front flanks only to be in abutting contact. With such a shock contact the properties of the stone material (especially concrete and Cement) optimally used, as these materials against pressure are very resistant. Direct shear and Frictional loads between two cams occur Functional units not in which the cams that Side surfaces of the paving stones and the filling material of the Bags work together like a serration. This Loads are avoided between diagonally opposite cams of a functional unit or two  interacting cam groups always form a space is. This space or bag is preferably made of sand, Split or a sand-split mixture filled so that water is in the bag can seep away. Diagonally opposite cams two cams belonging to a functional unit or Cam groups only act under with their side flanks Interposition of the filling material on each other. Here the filler distributes the thrust with which the side flank one cam acts on the diagonally opposite one Side flank of the other cam. Thus the acting Force on the entire area of the side flank of the second Distributed the cam and reduced the surface pressure.

The development of the invention according to subclaims 3 and 4 allows a cam group in a small space to accommodate without reducing stability as the cams designed smaller or larger according to their load are. A trapezoidal cross-section of the cam like it Proposes claim 5 means a more stable transition of Cam in the base of the paving stone. Will continue this facilitates the demolding of the paving stone.

The cross section of the pocket described in claim 6, the each between the opposite side surfaces of the Paving stones and four cams is formed Advantage that this when pushing two diagonally opposed cam does not go to zero. This ensures that what is in the bag Filling material through a slightly moving paving stone is compressed minimally and therefore its water permeable properties not by repeated strong compression loses.

The developments of the invention according to subclaims 8 to 10 show that the cam groups are flexible to the Paving stone size can be adjusted. So can  depending on the size of the stone and cam, the intensity of the Interlocking with neighboring stone adapted to needs become.

The lattice-shaped grid, which according to subclaim 11 same distance between the two planes that is through the end faces of the different cams are defined ensures that the large cams each in the Area of the opposite paving stone and with the big cams of the opposite paving stone one Form loose toothing. According to sub-claim 13 always butt contact between neighboring paving stones, see above that a parallel alignment of the paving stones to each other is guaranteed. The further development of the invention Subclaim 14 allows paved within a Area to lay areas that are made of paving stones other paving stone system exist. This also exists at the transitions from one stone system to another Stone system an inventive connection between the Paving stones. This ensures that the individual paving stone fields not freely against each other can move.

Further details of the invention are shown in the drawings based on schematically illustrated embodiments described.

Here show:

Fig. 1 is a plan view of a rectangular paving stone with cams and four cams,

Fig. 2 is a further top view of the rectangular parallelepiped block with cams and four cams,

Fig. 3 is a side view of the cuboidal paving stone with cams and four cams,

Fig. 4 shows a detail of the cuboidal paving stone shown in FIG. 2,

Fig. 5 is a plan view of a rectangular paving stone with cams and three cams,

Fig. 6 is a plan view of a square paving stone with cam groups of six cams,

Fig. 7 is a side view of a square paving stone with cams and three cams,

Fig. 8 is a plan view of a further square paving stone with cams and two cams,

Fig. 9 is a plan view of a square paving stone of another paving stone system with individual cams,

An enlarged view of a pocket formed by two groups of cams each with two cams Fig. 10,

Fig. 11 is a plan view of the laid paving stone bond cuboidal paving stones with cams and three cams,

Fig. 12 is another plan view of the laid paving stone bond cuboidal paving stones with cams and three cams,

Fig. 13 is a plan view of a paving stone bond of cuboidal paving stones with cam groups of four cam and integrated in the paving stone system external to the system square paving stone with individual cams,

Fig. 14 is a plan view of two cooperating cuboidal paving stones with cams and four cams,

Fig. 15 is a plan view of a paving stone bond of square paving stones with cam groups of six cam and integrated in the paving stone system external to the system paving stone with individual cams.

In Fig. 1 a plan view of a paving stone 1 is shown, which is designed as a rectangular stone 2 . The paving stone 1 is assigned to a grid 4 of a paving stone system 5 (see, for example, FIGS. 11, 13). The paving stone 1 is essentially delimited by side surfaces 6 , 7 , 8 , 9 , a usable surface 10 and a contact surface 11 . Two diagonals 12 , 13 , which intersect at an intersection 14 , run on the usable area 10 . Furthermore, cam groups 20 are arranged on the side surfaces 6 , 7 , 8 , 9 point-symmetrically to the intersection 14 . The cam groups 20 consist of cams 21, more precisely large cams 22 , 24 and small cams 23 , 25 . The cams 21 have an end-side front flank 28 , side flanks 29 , 30 and a top flank 31 . Furthermore, half pockets 33 are arranged between the cams 21 . The large cams 22 , 24 have a cam depth t1. The small cams 23 , 25 have a cam depth t2.

FIG. 2 shows a further top view of the rectangular rectangular block 2 shown in FIG. 1. The rectangular block has a first width B1, which represents the distance between the side surfaces 6 , 7 , and a second width B2, which represents the distance between the front flanks 28 of two large cams 22 , 24 arranged on the side surfaces 6 , 7 . Furthermore, the rectangular block 2 has a first length L1, which represents the distance between the side surfaces 8 , 9 , and a second length L2, which represents the distance between the front flanks 28 of two large cams 22 , 24 arranged on the side surfaces 8 , 9 . In FIG. 2 it can also be seen that the cam groups 20 are arranged point-symmetrically to the intersection 14 of the diagonals 12 , 13 on the side surfaces 6 , 7 , 8 , 9 of the rectangular block 2 . The grid 4 has a grid length R _L and a remaining width R _B.

FIG. 3 shows a side view of the side surface 9 of the rectangular block 2 shown in FIGS. 1 and 2 . The rectangular block 2 has a height H ₁ between the usable surface 10 and the contact surface 11 . The cams 21 extend essentially over a height H ₂ , which corresponds approximately to 9/10 the height H ₁ . The usable area 10 merges into the side areas 6 , 7 , 8 , 9 via a phase 34 , the phase 34 extending approximately at an angle α of 40 ° to the usable area 10 . The cover surfaces 31 of the cams 21 run approximately parallel to the phase 34 .

FIG. 4 shows a detailed view of the rectangular block 2 shown in FIG. 2 . The large cam 22 shown on the side surface 7 has a depth t1 and a front flank width b1. The small cam 23 shown on the side surface 7 has the depth t2 and a front flank width b2. The side flanks 29 , 30 of the cams 21 run at an angle β = 15 ° to a bisector 32 .

Fig. 5 shows a top view of another rectangle Stein 2. The rectangular block 2 has two cam groups 20 with three cams 21 on each of the side surfaces 6 , 7 . A first cam group 20 a has two large cams 22 , 24 and a small cam 23 and a second cam group 20 b has two small cams 23 , 25 and a large cam 24 . 35 formed cams 21 are arranged as a single cam at the side surfaces 8,. 9 The individual cams 35 have a depth t3 and a front flank width b3. The following generally applies in paving stone system 5 : t3 = t1-t2. The cams 21 are also arranged on the rectangular block 2 in a point-symmetrical manner to an intersection 14 of diagonals 12 , 13 .

Fig. 6 shows a plan view of a paving stone 1 , which is designed as a square stone 3 . The square stone 3 has cam groups 20 on side faces 6 , 7 , 8 , 9 , which are composed of six cams 21 . The cam group 20 consists of three large cams 22 , 24 , 26 and three small cams 23 , 25 , 27 . The large cams 22 , 24 , 26 are arranged alternately with the small cams 23 , 25 , 27 on the side surfaces 6 , 7 , 8 , 9 . Two diagonals 12 , 13 running on a usable area 10 of the square stone 3 intersect at an intersection 14 . At this intersection 14 , the cam groups 20 are arranged point-symmetrically. The large cams 22 , 24 , 26 of the square stone 3 have a depth t1. The small cams 23 , 25 , 27 of the square stone 3 have a depth t2.

Fig. 7 shows a side view of another as a square stone 3 formed paving stone 1. This square block 3 has two cam groups 20 , each with three cams 21 , on side surfaces 6 , 7 , 8 , 9 . Here, a cam group 20 a with a small cam 23 seated between two large cams 22 , 24 and a cam group 20 b with a large cam 24 seated between two small cams 23 , 25 are arranged alternately on the square block 3 . The square stone 3 has a phase 34 delimiting a usable area 10 , which extends at an angle α of approximately 40 ° to the usable area 10 .

Fig. 8 shows a top view of another formed as a square stone 3 paving brick 1. The square stone 3 has two cam groups 20 on each of the side surfaces 6 , 7 , 8 , 9, each of which is composed of two cams 21 . The cam group 20 consists of a large cam 22 and a small cam 23 . Two diagonals 12 , 13 , which connect the corners 15 of the square stone 3 , intersect at an intersection 14 , to which the cam groups 20 are arranged point-symmetrically. The basic rule for the ashlars 3 is that the grid width R _B corresponds to the grid length R _L and the width B1 corresponds to the length L1.

Fig. 9 shows in plan view a square paving stone paving stone 100 of another system 104 with each cam 101. The cams 101 are arranged symmetrically about a center point 102 and have a depth t3. The paving stone 100 has a width B1 and a length L1. Furthermore, it has a grid 103 with a grid width R _B with a grid length R _L. The cams 101 are halved by the grid 103 . A square paving stone 100 similar to this stone, which instead of four cams on each side has five cams on each side, is shown in FIGS. 13 and 15 in a paving stone system 5 , which is partially composed of paving stones 1 according to the invention.

Fig. 10 shows the interaction of the cam group 20 of the paving stone 1, with a cam group 20 'of an adjacent paving stone 1'. FIG. 10 shows the interaction of the two cam groups 20 , 20 ', which consist of a large cam 22 , 22 ' and a small cam 23 , 23 '. The interaction of cam groups 20 , 20 'consisting of three or more cams 21 , 21 ' behaves analogously to this illustration. By the half-pockets 33 , 33 'which are formed between the cams 21 , 21 ' of the cam groups 20 , 20 ', a pocket 36 is formed, which through the side flank 29 of the small cam 23 , the side surface 6 of the paving stone 1 , the side flank 30 of the large cam 22 , the front flank 28 of the large cam 22 , the side flank 29 'of the small cam 23 ', the side surface 7 'of the paving stone 1 ', the side flank 30 'of the large cam 22 ' and the front flank 28 'of the large cam 22 'is delimited. In cross section, the pocket 36 consists of two trapezoids 37 , 37 'and a parallelogram 38 . Here, the parallelogram 38 is arranged between the base sides 39 , 39 'of the trapezoids 37 , 37 ', so that the cross section is given an S-like appearance. The front flank 28 of the large cam 22 touches the front flank 28 'of the small cam 23 ' in a plane E1. The front flank 28 of the small cam 23 touches the front flank 28 'of the large cam 22 ' in a plane E2. The grid 4 runs parallel and at the same distance a to the planes E1, E2. The parallelogram 38 is divided by the grid 4 b into two equal Teilparallelogramme 38 a, 38th The pocket 36 , which is formed between the cams 21 , 21 ', is filled with a filler 39 up to approximately the top surfaces 31 , 31 '. The filling material 39 preferably consists of split 40 a or a sand split mixture 40 b. An impact load in the direction of the arrow x is transmitted from the paving stone 1 'via the front flanks 28 ' of the cams 21 'to the front flanks 28 of the cams 21 of the paving stone 1 . A in the direction of arrow y on the paving stone 1 'acting thrust force from the large cam 22' transmitted through the filling material 39 on the large cam 22nd The side flanks 30 ', 30 of the cams 22 ', 22 do not come into contact here. The pressure emanating from the paving stone 1 'is evenly distributed by the filler 39 to the side flank 30 of the cam 22 . A movement of the paving stone 1 in the direction of arrow y causes a reduction in a cross-sectional area 41 or a volume 42 of the pocket 36 . Through the movement of the paving stone 1 in the direction of arrow y, the cross-sectional area 41 of the pocket 36 is reduced by a maximum of a cross-sectional area 43 marked by the parallelogram 38 . In the extreme case, the cross-sectional area 'is defined when the large cam 22' 41 of the bag 36 only through the trapezes 37, 37 is applied to a shift in the direction of arrow Y with its side edge 30 'to the side edge 30 of the large cam 22nd Since only about 20% of the filler material 39 is subject to compression at shear loads in the direction of the arrow y, the filler material 39 is only slightly compressed so that the compression has no negative influence on the water permeability of the filler material.

Fig. 11 shows a plan view of the laid paving stone system 5 paving stones 1. Here paving stones 1 are used, which are designed as rectangular stones 2 , each with two cam groups 20 on the opposite side surfaces 6 , 7 (see also FIG. 5). The paving stone system 5 shown in Fig. 11 consists of three transverse rectangular stones 2 a, 2 b, 2 c and an upright rectangular stone 2 d. The rectangular blocks 2 have a grid width R _B and a grid length R _L. The grid 4 of the vertically laid rectangular stone 2 d coincides with the grid 4 of the horizontally laid rectangular stones 2 a, 2 b, 2 c, then again when a field, not shown, is laid on the rectangular stone 2 d, which consists of three horizontal rows with 5 vertically laid rectangular stones 2 each. The arrangement of the cam 21 to the rectangular stones 2 is ensured that between horizontally and laid edgewise rectangular stones 2 never single cam 35 with large cams 22, 24 in abutting contact, occur.

Fig. 12 shows a further plan view of the laid paving stone system 5 square bricks 2. In the illustrated rectangular stones 2 is described in Fig. 5 square stone 2. In Fig. 12, a transverse rectangular stone 2 a and upright rectangular stones 2 d, 2 e is shown. The upright rectangular stone 2 e is a rectangular stone 2 , which is a mirror image of the rectangular stones 2 a, 2 d. Such rectangular blocks 2 e make it possible to offset the rectangular blocks 2 with an odd number of cams 21 per cam group 20 .

FIG. 13 shows a top view of a paving stone system 5 comprising rectangular stones 2 with cam groups 20 , each with 4 cams 21 and a non-system square paving stone 100 integrated into the paving stone system 5 . The non-system paving stone 100 has cams 101 which are arranged symmetrically about a center 102 . The rectangular blocks 2 shown in FIG. 13 correspond to the rectangular block 2 already described in FIG. 1.

In principle, it applies to all paving stones 1 that in the paving stone system 5 either either large cams 22 , 24 , 26 with small cams 23 , 25 , 27 and / or small cams 23 , 25 , 27 with individual cams 35 and / or large cams 22 , 24 , 26 make butt contact with side surfaces 6 , 7 , 8 , 9 . This is ensured for the paving stones 1 in that the cam groups 20 are arranged point-symmetrically to the intersection 14 . With regard to the butt contact of small cams 23 , 25 , 27 to the cams 101 of the non-system paving stone 100 , the interaction is achieved by a special arrangement of the cams 21 on the paving stone 1 . The small cams 23 , 25 are assigned to the cams 101 , and the large cams 22 , 24 are in contact with a side surface 105 of the paving stone 100 . The cams 101 are thus divided by the grid 4 , 103 parallel to the side surface 105 . The small cams 23 , 25 are arranged at a distance f from one another within the individual cam groups 20 . The cams 101 of the paving stone 100 are also arranged at this distance f. Furthermore, the small cam 25 of a first cam group 20 a is arranged at a distance g from the small cam 23 of a second cam group 20 b. For the distance g, g = 2f. The distance of the small cam 23 of the first cam group 20 a to the grid 4 corresponds to h. The distance of the small cam 25 of the second cam group 20 b to the grid 4 corresponds to i. Here h + i = g = 2f. For the side surfaces 8 , 9 , on each of which a cam group 20 is arranged, it applies that f is the distance between the small cams 23 , 25 . Here, the small cam 25 is arranged at a distance i from the grid 4 and the small cam 23 at a distance h from the grid 4 . Again h + i = 2f. This arrangement ensures that small cams 23 , 25 are arranged on the grid 4 at a distance f or a multiple of the distance f. With regard to the grid 4 with grid width R _B and grid length R _L : R _L = i + f + g + f + h and R _B = i + f + h. For the paving stones 100 it applies that within a paving stone system 5 made of paving stones 1 a field must be laid out of so many paving stones 100 that the smallest common multiple with the grid 4 of the paving stone system 5 is achieved by the grid 103 of the paving stones 100 .

Furthermore, a paving stone 1 'is shown in which two adjacent side surfaces 7 , 8 are provided with cam groups 20 and two further adjacent side surfaces 6 , 9 have cams 21 designed as individual cams 35 . According to an embodiment variant, not shown, it is provided that the paving stone systems 5 , 103 have the same grid dimensions, so that the paving stones 1 , 100 can be laid alternately. Such a match is realized in the paving stones 1 , 100 shown in FIGS. 6 and 9.

Fig. 14 shows a plan view of two co-operating rectangular bricks 2 with the cam 20 groups with four cams 21. The rectangular block 2 forms a toothing 44 with the adjacent rectangular block 2 'through the cam groups 20 , 20 ' and the pockets 36 . The toothing 44 is achieved in that the pockets 36 a, 36 b, 36 c pass from one cam group 20 into an adjacent cam group 20 '. When the rectangular stone 2 moves in the direction of the arrow x, the thrust is transferred from the large cam 22 , 24 via the filler material 39 stored in the pockets 36 a, 36 c to the large cams 22 ', 24 ' in a manner which protects the edges. During a movement of the rectangular stone 2 in the direction of arrow X 'of the thrust of the large cam 24 via the b in the pocket 36 mounted filling material 39 on the large cam 24' transmitted.

In Fig. 15 a plan view is shown on a paving stone system 5 of square stones. 3 Furthermore, a non-system paving stone 100 from a paving stone system 104 is shown, which is integrated into the paving stone system 5 . The square stones 3 shown in FIG. 15 correspond to the square stone 3 described in FIG. 6. The distances f between the small cams 23 , 25 , 27 correspond to the distances f which the cams 101 have from one another or a multiple thereof. FIG. 15 also shows a free area 45 , which is left free between square stones 3 for creating a marking or a larger green area. The square stones 3 , which generate the free area 45 , can be attached to the existing paving stone system 5 without machining if the free area has a width B _F which corresponds to an integer multiple of the distance f.

The invention is not shown or described on Embodiments limited. Rather, it encompasses Developments of the invention in the context of Property rights claims.

In particular, 5 paving stones 1 with the following dimensions are provided in the paving stone system:

The paving stones 1 , 101 shown in FIGS. 6 and 9 can be combined with one another as desired due to their identical grid dimensions R _B , R _L , although they belong to different paving stone systems 5 , 104 . Due to the laying play that is required to compensate for bulges of the paving stones and embedding of filler material between the abutting surfaces, the position of the grid preferably shifts by about 1 mm in the direction of the adjacent brick, so that the grid dimensions given in the table above are available.

According to an embodiment variant, not shown, are also Paving stones provided, the six- or are octagonal.  

Reference list

1

Paving stone

2nd

Rectangular stone

3rd

Square stone

4th

Grid

5

Paving stone system

6-9

Side surface

10th

Usable area

11

Contact surface

12th

diagonal

13

diagonal

14

Intersection

15

corner

20th

Cam group

20th

a first cam group

20th

b second cam group

21

cam

22

big cam

23

small cam

24th

big cam

25th

small cam

26

big cam

27

small cam

28

front flank

29

Side flank

30th

Side flank

31

Top surface

32

bisector

33

Half pocket

34

phase

35

Single cam

36

bag

36

a bag

36

b bag

36

c pocket

37

Trapezoid

38

parallelogram

38

a Partial parallelogram

38

b Partial parallelogram

39

filling material

40

a split

40

b Sand split mixture

41

Cross sectional area

42

volume

43

Cross sectional area

44

Gearing

45

Open space

100

Paving stone

101

cam

102

Focus

103

Grid

104

Paving stone system

105

Side surface

Claims (14)

1. paving stone for use in a lattice-shaped paving stone system, the paving stone having spacers or cams abutting one another on at least two opposite sides, characterized in that the paving stone ( 1 ) on at least two opposite or adjacent sides ( 6 , 7 , 8 , 9 ) is provided with at least one cam group ( 20 ) consisting of at least two different and spaced apart cams ( 21 ), a pocket-shaped intermediate space ( 33 ) being formed between the side flanks ( 29 , 30 ) of the cams ( 21 ). 2. Paving stone according to claim 1, characterized in that the cams ( 21 ) of a group of cams ( 20 ) have front flanks ( 28 ) on the front, via which the paving stone ( 1 ) with at least one cam ( 21 , 35 ) or a group of cams ( 20 ' ) of an adjacent paving stone ( 1 ') is in toothless butt contact, preferably the cam group ( 20 ) of a first paving stone ( 1 ) together with at least one cam ( 21 , 35 ) or a cam group ( 20 ') of a second paving stone ( 1 ') to form a toothing ( 44 ) forms at least one pocket ( 36 ). 3. Paving stone according to one of the preceding claims, characterized in that the cam group ( 20 ) of a paving stone ( 1 ) consists of at least one large cam ( 22 , 24 , 26 ) and at least one small cam ( 23 , 25 , 27 ), the have different depths (t1, t2) and / or different face widths (b1, b2) and form a half-pocket-shaped space ( 33 ) between them. 4. Paving stone according to one of the preceding claims, characterized in that the large cam ( 22 , 24 , 26 ) has approximately twice the end face width (b1) of the small cam ( 23 , 25 , 27 ) and preferably the large cam ( 22 , 24 , 26 ) has approximately 1.3 times to 1.5 times the depth (t1) of the small cam ( 23 , 25 , 27 ). 5. Paving stone according to one of the preceding claims, characterized in that the cams ( 21 ) of the paving stone ( 1 ) have a trapezoidal cross section. 6. Paving stone according to one of the preceding claims, characterized in that two cam groups ( 21 , 21 ') in contact form at least one pocket ( 36 ) which has a cross section ( 41 ) consisting of two trapezoids ( 37 ) and a parallelogram ( 38 ) is composed. 7. Paving stone according to one of the preceding claims, characterized in that the cam group ( 20 ) on a paving stone ( 1 ) consists of three cams ( 21 ), a small cam ( 23 , 25 , 27 ) in a first cam group ( 20 ). a large cam ( 22 , 24 , 26 ) is arranged between two small cams ( 23 , 25 , 27 ) between two large cams ( 22 , 24 , 26 ) and, in the case of a second cam group ( 20 ), and preferably the first cam group ( 20 ) a first paving stone ( 1 ) interacts functionally with the second cam group ( 20 ) of an adjacent paving stone ( 1 ') and thereby forms two pockets ( 36 ). 8. paving stone according to one of the preceding claims, characterized in that the cam group ( 20 ) on a paving stone ( 1 ) consists of two cams ( 21 ), wherein in a first cam group ( 20 ) a small cam ( 23 , 25 , 27 ) next to a large cam ( 22 , 24 , 26 ) and in the case of a second cam group ( 20 ) a large cam ( 22 , 24 , 26 ) is arranged next to a small cam ( 23 , 25 , 27 ), and the first cam group ( 20 ) a first paving stone ( 1 ) interacts functionally with the second cam group ( 20 ) of an adjacent paving stone ( 1 ') and forms a pocket ( 36 ). 9. Paving stone according to one of the preceding claims, characterized in that the cam groups ( 20 ) point-symmetrically to the intersection ( 14 ) of two on a usable surface ( 10 ) of the paving stone ( 1 ) extending diagonals ( 12 , 13 ) are arranged diametrically. 10. Paving stone according to one of the preceding claims, characterized in that the cam group ( 20 ) consists of four cams ( 21 ), wherein large and small cams ( 22 , 23 , 24 , 25 , 26 , 27 ) are arranged alternately. 11. Paving stone according to one of the preceding claims, characterized in that the front flanks ( 28 ) of the cams ( 21 ) of a cam group ( 20 ) lie on at least two mutually offset planes (E1, E2), the lattice-shaped grid ( 4 ) is equidistant between these levels (E1, E2). 12. Paving stone according to one of the preceding claims, characterized in that the paving stone ( 1 ) on two opposite side surfaces ( 6 , 7 , 8 , 9 ) at least one cam group ( 20 ) with cams of different depths (t1, t2) and on the others opposite side surfaces ( 6 , 7 , 8 , 9 ) has at least individual cams ( 21 , 35 ) of the same depth (t3), the cam depth of the individual cams ( 21 , 35 ) being the difference between the cam depths (t1, t2) of the cams ( 21 ) Cam groups ( 20 ) corresponds to (t3 = t1-t2). 13. Paving stone according to one of the preceding claims, characterized in that the cam group ( 20 ) of the paving stone ( 1 ) with a side surface ( 6 , 7 , 8 , 9 ) and with a single cam ( 35 ) or with several identical cams ( 35 ) of the adjacent paving stone ( 1 ') is in abutting contact. 14. Paving stone according to one of the preceding claims, characterized in that a shear connection can be established between the paving stone system ( 5 ) and a further paving stone system ( 104 ).