EP1193346A1 - Artificial stone paving element with an elongated-rectangular base form and peripheral teeth - Google Patents

Abstract

Floor covering element (2) made of synthetic stone has a rectangular shape with interlocking elements along the periphery. On one long side there is a first interlocking section (6.1), an intermediate angled section (8.1) leading outward, a second interlocking section (6.2), and an end angled section (10.1) leading inward. The second interlocking section corresponds to the first interlocking section rotated by 180 degrees and shifted outward. On a second long side there is a third interlocking section (6.3), an intermediate angled section (8.2) leading outward, a fourth interlocking section (6.4), and an end angled section (10.2) leading inward. The fourth interlocking section corresponds to the third interlocking section rotated by 180 degrees and shifted outward. On a first short side there is a fifth interlocking section (6.5) leading from the first to the third interlocking section. On a second short side there is a sixth interlocking section (6.6) leading from one end angled section to the other. The second, fourth and sixth interlocking sections are identical and coincide with each other when rotated by 90 degrees or 180 degrees about a virtual first axis of rotation protruding from the top surface of the floor covering element. The first, third and fifth interlocking sections are identical and coincide with each other when rotated by 90 degrees or 180 degrees about a virtual second axis of rotation protruding from the top surface of the floor covering element.

Description

(a) an einer ersten Längsseite des Bodenbelagelements folgen ein erster Verzahnungsabschnitt, ein weiter nach außen führender Zwischen-Schrägabschnitt, ein zweiter Verzahnungsabschnitt, und ein weiter nach innen führender End-Schrägabschnitt aufeinander, wobei der zweite Verzahnungsabschnitt dem ersten Verzahnungsabschnitt, um 180° gedreht und nach außen verschoben, entspricht;

(b) an einer zweiten Längsseite des Bodenbelagelements folgen ein dritter Verzahnungsabschnitt, ein weiter nach außen führender Zwischen-Schrägabschnitt, ein vierter Verzahnungsabschnitt und ein weiter nach innen führender End-Schrägabschnitt aufeinander, wobei der vierte Verzahnungsabschnitt dem dritten Verzahnungsabschnitt um 180° gedreht und nach außen verschoben, entspricht;

(c) an einer ersten Querseite des Bodenbelagelements befindet sich ein fünfter Verzahnungsabschnitt, der von dem ersten zu dem dritten Verzahnungsabschnitt führt;

(d) an einer zweiten Querseite des Bodenbelagelements befindet sich ein sechster Verzahnungsabschnitt, der von dem einen End-Schrägabschnitt zu dem anderen End-Schrägabschnitt führt;

(e) der zweite Verzahnungsabschnitt, der vierte Verzahnungsabschnitt und der sechste Verzahnungsabschnitt sind gleich und durch Drehung um 90° oder 180° um eine virtuelle, erste Drehachse, die von der Draufsichtsfläche des Bodenbelagelements aufragt, miteinander zur Deckung bringbar;

(f) der erste Verzahnungsabschnitt, der dritte Verzahnungsabschnitt und der fünfte Verzahnungsabschnitt sind gleich und durch Drehung um 90° oder 180° um eine virtuelle, zweite Drehachse, die von der Draufsichtsfläche des Bodenbelagelements aufragt, miteinander zur Deckung bringbar.

The invention relates to a flooring element made of artificial stone material with a basic shape, which - roughly speaking - is oblong-rectangular, and with teeth on the circumference, characterized by the following features in combination:

(a) on a first longitudinal side of the floor covering element, a first toothed section, a further outwardly extending intermediate bevel section, a second toothed section, and a further inwardly directed end beveled section follow one another, the second toothed section rotating the first toothed section by 180 ° and moved outward, corresponds to;

(b) on a second longitudinal side of the floor covering element are followed by a third toothed section, a further outwardly extending intermediate bevel section, a fourth toothed section and a further inwardly directed end beveled section, the fourth toothed section being rotated by 180 ° and after the third toothed section shifted outside, corresponds;

(c) on a first transverse side of the floor covering element there is a fifth toothed section which leads from the first to the third toothed section;

(d) on a second transverse side of the floor covering element there is a sixth toothed section which leads from one end inclined section to the other end inclined section;

(e) the second toothed section, the fourth toothed section and the sixth toothed section are identical and can be brought into register with one another by rotation through 90 ° or 180 ° about a virtual, first axis of rotation, which projects from the top view surface of the floor covering element;

(f) the first toothed section, the third toothed section and the fifth toothed section are identical and can be brought into register with one another by rotation through 90 ° or 180 ° about a virtual, second axis of rotation which protrudes from the top view surface of the floor covering element.

Flooring elements of the class that one with oblong-rectangular Basic shape (often also: essentially twice as long as wide; however, this characterization would apply to the invention Flooring element problematic) are large Number known. Different basic forms are to be distinguished from this, e.g. square, octagonal, hexagonal. Typical for flooring elements with an elongated rectangular basic shape is that they usually (if the Geometry of the gear is aligned) in several different types of installation to form associations from mutually anchored Have the flooring elements laid. The extent of mutual Anchoring here is entirely due to the geometry of the teeth especially the extent to which protrusions over one Project "neutral line" and jump back compared to Jump back "neutral line", determined.

The flooring element according to the invention is technically distinguished advantageous in that the points of view of the diversity of possible laying pattern, the interlocking between side by side installed flooring elements and - in the case of oblong-rectangular Basic form of unusual - lateral chipping of the laying joint when Progress by essentially half each Floor covering element length for an optimal overall concept are fused. As a result, with the Floor covering element according to the invention created floor covering associations that high load bearing capacity (or in other words: thanks to high security against unwanted shifting of flooring elements under the effect of loads) and by simple, convenient Mark layability. Also the lively, appealing look of the association is a positive point of view.

Since the second in the flooring element according to the invention Tooth section "further out" (i.e. in the transverse direction of the Flooring element moved further out) than the first Gear section is located, and since the same for the relation between the fourth tooth section and the third Tooth section applies, the one already mentioned above arises Lateral "jumping" of the laying joint, each time you look at one moved about half the length of the floor covering along the laying joint. This lateral "jumping" increases the bond effect of the Flooring elements in the association or the load bearing capacity of the Association very significantly.

In the claims and in the description of the present Patent specifications are statements about geometric in many places Conditions, e.g. "Lead", "Return", "Tooth formed from a line of contiguous, rectilinear sections ". All such statements refer to a view of the flooring element in plan view, i.e. view from above onto the useful side or top of the floor covering element, as if this had been laid on a mat, unless expressly so something else is stated at the point in question. Preferably the floor covering element according to the invention is a Flooring element that is used for the creation of flooring "in Outdoor area "or for the use of outdoor areas is. As a particularly preferred area of application of the invention Floor covering element, traffic areas, especially those in Outdoors, such as Areas for motor vehicle traffic, areas for Bicycle traffic, areas for pedestrian traffic. Particularly typical and squares, courtyards, driveways, paths, streets, Pedestrian zones, loading zones, terraces, parking areas for vehicles, Gas stations, commercial areas, industrial areas Areas, workshops, container spaces.

In most cases, the "artificial stone material" is concrete. As brick-like materials are another preferred option called. In general, all materials are also considered those aggregates or fillers in time-hardening Binders (e.g. also plastic) are stored, in particular Polymer concrete.

The introductory paragraph spoke of virtual axes of rotation; these preferably protrude at right angles from the useful side of the Flooring element on. With the statement "rotation by 90 ° or 180 °" are both clockwise and counterclockwise rotations Clockwise required as related to the below Embodiments will be even clearer.

All of the toothing sections mentioned preferably each have at least one lead and one lead back from one straight line connecting their end points. Most notably it is preferred if in each case only one projection and only one Return, i.e. not several projections and not several Returns are provided. This yields an optimal one Compromise between good anchoring effect of the gearing and Avoid dividing the anchorage effect among numerous Projections and recesses, which are then inevitably right for everyone are small, which reduces the anchoring effect. It is also possible, only one protrusion or only one per tooth section To provide return.

In the flooring element according to the invention it can be provided that the first, the third and the fifth tooth section respectively consistently outside of a straight connecting line of its end points runs and that the second, fourth and sixth Gear section continuously within a straight line Connection line of its end points runs. You can also "reverse" provide that the first, third and fifth gear section each continuously within a straight connecting line Endpoints runs and that the second, fourth and sixth Gear section continuously outside a straight line Connection line of its end points runs. The way of expression "always runs outside the relevant baseline" does not necessarily mean that it is only a head start; much more, even this interlocking could have a head start and a lead Have a return to a "neutral line" or even several. Analogously, the statement means "continuously within the concerned baseline "does not necessarily mean that it is a single return acts; rather, the Gearing a lead and a return compared to one Show "neutral line", or even several.

Preferably, the intermediate sloping sections and the end sloping sections unoccupied by gearing. Preferably the run Between sloping sections and the end sloping sections each under an angle of 45 ° relative to the central longitudinal axis of the Flooring element (be it that these inclined sections of gearing are unoccupied, be it that these inclined sections are geared are, in which case the angle specification is the specification of a general course is).

The straight connecting line of the end points is preferably at mentioned tooth sections each longer than the straight Connection line of the end points at the intermediate sloping sections and the end sloping sections. It is preferably straight Connection line of the end points at the named Gear sections at least 1.5 times as long, stronger preferably at least 2.0 times as long, most preferably at least 2.5 times as long as the straight connecting line of the End points at the intermediate bevel sections and the end bevel sections. These statements represent for the Gear sections have plenty of gear length available while the - preferably not toothed - Oblique sections are kept comparatively short. Also receives an embodiment in which the width difference between that of the first, third and fifth gear section limited part of the flooring element and that of the second, fourth and sixth gear section limited, other part of Flooring element is not excessively large. This leads to one optimal compromise between good load capacity because of the lateral "jumping" of the installation joints and avoidance Excessively small parts of the flooring element, which in itself Pushing too little into the covered surface may be too little Would oppose.

According to a particularly preferred development of the invention neither the first and the third tooth section nor the second and the fourth toothed section is a mirror image of one another. With this Training can be an undesirably large cross-sectional weakening the flooring element and thus an undesirable increase in Avoid risk of breakage of the relevant flooring element. To the non-existence of mirrored pairs of Gear sections occur when the one in question Gear section, viewed on its own, not in itself mirror-symmetrical to an axis of symmetry which is perpendicular to the straight connecting line of the relevant endpoints and this Connection line is halved.

Preferably, neither the first and the third gear section can be brought to cover by parallel displacement, the second and the fourth tooth section by parallel displacement to the cover brought. In the previously known floor covering elements with oblong rectangular Basic form can be seen either as mirror image opposite pair of gears or, more rarely, opposing pairs covered by parallel shift to cover are feasible. The latter version arises when the toothing in question, considered in itself, point symmetrical to Halving point of the straight connecting line concerned End points of the gearing is. On the other hand, Training according to the invention the opposite way, the geometry "Pairs of gear sections are due to parallel displacement To avoid cover. "Surprisingly, one creates nevertheless a flooring element that - with only one exception - to the Maximum number of laying options.

The toothing sections mentioned are preferably each one Line drawing of straight, angularly connecting pieces, particularly preferred of at least three of these pieces, very particularly preferably from exactly three or exactly four of these pieces. In particular the latter two versions lead to toothed sections, which, on the one hand, have a good gear effect, but, on the other hand, do not split up too many anchors. An embodiment in which the respective one is most preferred Gear section begins with a short, first piece, then a longer second piece and a longer third piece follow, and then a fourth piece concludes. From the geometrical Relationships mentioned in the introductory paragraph the result is that in this case the first and fourth pieces have the same length and the second and third pieces are the same length. Besides, is preferred if the by the second, fourth and sixth Gear section formed each projection over the straight Connection line of the endpoints of the corresponding Gear section smaller than the respective area through which mentioned toothing sections compared to the mentioned Connecting line formed recess; the first, third and fifth toothing section reversed, i.e. each larger area and smaller area recess.

The alternatives mentioned are also a preferred alternative Gear sections each have a curved line. The Curvature of the line can gradually or in its course to change by leaps and bounds. Transitions from curvature in the Clockwise to counterclockwise curvature and vice versa. According to a further, preferred alternative, the ones mentioned are Gear sections each have a line train with at least one rectilinear piece and with at least one curved piece.

It is preferred if each toothed section is exactly one Turning point of its course. A turning point is when one at one point as it progresses along the toothing section from "change of direction clockwise" to "change of direction counterclockwise "and vice versa.

The floor covering element is preferably provided with spacing projections on the circumference provided, the spacer projections at the Consideration of the entire description so far (and in the Claims 1 to 14) addressed geometric relationships to be disregarded. The latter half sentence means however not that there are not versions in which even at Taking into account the spacing projections, the geometric conditions would still exist. The Spacer projections can be a size in particular Definition of narrow joints with a maximum width of 5 mm have between adjacent flooring elements, whereby the laying of the flooring elements is simplified. This "narrow" joints, which in most cases are 3 to 5 mm wide those joints that are normally used as laying joints between the Flooring elements are present in the flooring and normally be filled with sand after laying the flooring elements. If the flooring elements these "small" spacing protrusions have, the publisher when laying easier by Toasting the spacer tabs work. On the other hand, you can the spacing protrusions in particular a size for fixing of wide joints with a width of at least 8 mm between have adjacent flooring elements, which powerful water penetration joints are formed. If those "Larger" spacer projections are provided relatively wide joints between adjacent flooring elements. These joints are usually also made with sand or grit filled up, through these "wide" joints can rainwater much more effective than with the "narrow joints in normal width" flow into the ground between the flooring elements so that the occupied area is no longer connected to a drainage system must be connected and an amount for the desired enrichment of the groundwater is provided. Both in the "smaller" Spacer projections as well as the "larger" spacer projections can either be trained so that the projections of a considered flooring element with locations of the neighboring Flooring elements come into contact that are not there Projection are provided, or you can train so that the Projections in places with the adjacent Flooring elements come into contact, where the latter also one Have a head start; in this case, the projections hit each other in pairs against each other. It is understood that in this case the Projections a "projection measure" over the others Flooring element contour have about half the desired Joint width corresponds; in the first case described, "Projection size" of the projections in approximately the desired joint width correspond.

The floor covering element is preferably provided with recesses on the circumference provided to create efficient water passage openings, the recesses when considering the in the previous Description (and in claims 1 to 14) addressed geometrical relationships are disregarded. The last half sentence does not mean, however, that there are no designs where even if the recesses are taken into account geometrical relationships would exist. For this powerful Water passage openings and the thereby achieved The water drainage capacity of the flooring applies analogously to what was previously in the Connection with the water penetration joints has been carried out.

The floor covering element according to the invention can be a on its top Have dummy joints, the course of the fifth tooth section after rotation through 180 ° around the virtual, second axis of rotation and from one end point of the first gear section to one End point of the third gear section leads.

It is emphasized that the term "toothing" is merely the function of the positive interlocking or mutual anchoring when installed between two adjacent flooring elements to express. In particular, it shouldn't be anything in Direction sharpness, angularity or angular course of pieces the interlocking be expressed; also a rounded one Course e.g. according to a sine line is of course one Toothing in the sense of the invention.

Fig. 1

eine Draufsicht auf ein Bodenbelagelement;

Fig. 2

eine Draufsicht auf ein abgewandeltes Bodenbelagelement;

Fig. 3

einen Ausschnitt aus einem Bodenbelag, bei dem mehrere Bodenbelagelemente von Fig. 1 verlegt sind;

Fig. 4

einen Ausschnitt aus einem anderen Bodenbelag, bei dem mehrere Bodenbelagelemente von Fig. 1 verlegt sind.

The invention is explained in more detail below with reference to exemplary embodiments illustrated in the drawings. It shows:

Fig. 1

a plan view of a flooring element;

Fig. 2

a plan view of a modified flooring element;

Fig. 3

a section of a floor covering in which several floor covering elements of FIG. 1 are laid;

Fig. 4

a section of another floor covering, in which several floor covering elements of Fig. 1 are laid.

The floor covering element 2 shown in FIG. 1 has - roughly speaking - an elongated rectangular basic shape and a longitudinal central axis 4. The Outline of the flooring element 2 consists of a total of six Gear sections 6.1, 6.2, 6.3, 6.4, 6.5, 6.6, two intermediate bevel sections 8.1 and 8.2, and two end sloping sections 10.1 and 10.2. If you look at the bottom left corner 12 of the flooring element 2 begins and progresses upwards in Fig. 1, is first a first Gear section 6.1 available. This is followed by obliquely on the top left intermediate sloping section 8.1, the under runs at an angle of 45 ° to the longitudinal central axis 4. If you do that first toothing section 6.1 about a virtual axis of rotation, the rises vertically from the plane of the drawing and z. B. on in Fig. 1st upper end point of the first toothed section 6.1 is around Rotates 180 ° and then to the left and outside and a little upwards in Fig. 1 shifts, one obtains a second toothed section 6.2, which is to the upper end of the intermediate inclined section 8.1 in FIG. 1 followed. If you take the first gear section 6.1 by a virtual axis of rotation, z. B. at the end in Fig. 1 12 of the first toothed section 6.1 is located 90 ° clockwise rotates, you get a fifth tooth section 6.5, which Flooring element 2 completes below in Fig. 1. If you have the fifth Gear section 6.5 around a virtual axis of rotation that is perpendicular from the drawing level rises and z. B. on the right in Fig. 1 End point of the fifth tooth section 6.5 is located at 90 ° in Turning clockwise, a third gear section 6.3 is obtained. You can also choose one for the last two rotations virtual axis of rotation 14 in the middle of the lower part of FIG Introduce flooring element 2.

1 includes the second toothed section 6.2 End oblique section 10.1, which leads obliquely to the top right in FIG. 1 and at an angle of 45 ° relative to the longitudinal central axis 4 runs. In the middle of the upper part of the floor covering element in FIG. 1 2 is a virtual axis of rotation that is perpendicular to the plane of the drawing towers, drawn. A rotation of the second gear section 90 ° clockwise around the axis of rotation 16 results in a sixth Toothing section 6.6, which is the floor covering element at the top in FIG. 1 concludes. A rotation of the sixth toothed section 6.6 by 90 ° clockwise around the axis of rotation 16 or a rotation of the second toothed section 6.2 by 180 ° about the axis of rotation 16 a fourth tooth section 6.4. Between the third Gear section 6.3 and the fourth gear section 6.4 there is an intermediate sloping section 8.2, which is in Fig. 1 from the left bottom to top right at an angle of 45 ° to the Longitudinal central axis 4 runs. Between the fourth tooth section and the sixth toothed section is an end inclined section 10.2 the one in Fig. 1 from bottom right to top left extends at an angle of 45 ° to the longitudinal central axis 4.

There is one for each of the six gear sections 6.1 to 6.6 straight connecting line 18 between the relevant two end points drawn in broken lines.

It can be seen that the first gear section 6.1, the third Gear section 6.3 and the fifth gear section 6.5 are the same and by rotation through 90 ° or 180 ° around the axis of rotation 14 are congruent with each other. It can also be seen that the second Gear section 6.2, the fourth gear section 6.4 and the sixth toothed section 6.6 by rotation through 90 ° or through 180 ° are coincident with each other about the axis of rotation 16.

If you pick out the first toothed section 6.1, there is this consists of a line train of angularly adjoining, straight-line pieces, namely - progressing clockwise - one first, short piece 20.1, a second, much longer piece 20.2, a third, long piece 20.3 and a fourth, short piece 20.4. The first piece 20.1 and the fourth piece 20.4 are the same length, and the second piece 20.2 and the third piece 20.3 are of equal length. All four pieces 20.1 to 20.4 run under different sizes Angles relative to the longitudinal central axis 4, the fourth piece 20.4 has the smallest angle, the second piece 20.2 the next largest Angle, the third piece 20.3 has the next larger angle, and the first piece 20.1 has the largest angle.

It is easy to imagine that the line from the four pieces 20.1 to 20.4 could alternatively be replaced by a continuously curved one Line course, which the course of the line course from the four pieces 20.1 to 20.4 reproduces and the curvature changes in its course Has. Furthermore, alternatively, it is easy to imagine that only the "Kinks" of the drawn line from the pieces 20.1 to 20.4 rounds off and there are straight parts between the roundings leaves. Then you have a line of several straight-line pieces and several curved pieces in front of it.

From the foregoing description it also follows that the drawn line has only one turning point, namely on the third piece 20.3.

It can be seen that through the pieces 20.1 to 20.4 a projection 22 opposite the associated straight connecting line 18 and a Recess 24 formed against the straight connecting line 18 have been. The recess 24 has a fairly small area. The Projection 22 has a very much larger area.

The third gear section 6.3 and the fifth gear section 6.5 are made up of four pieces, if you look at each other again clockwise along the toothed sections 6.3 and 6.5 moves. Everywhere there is a smaller recess 24 and a distinct area larger projection 22. As already described, is the second toothed section 6.2 by 180 ° rotation of the first Gear section 6.1 and subsequent parallel displacement after left-top arose, as did the fourth tooth section 6.4 the third toothed section 6.3 after rotation through 180 ° and Parallel shift to the top right. As a result, you have each also four pieces 26.1 to 26.4, but now is through everyone Gear section 6.2, 6.4, 6.6 a small projection 28 and a clearly larger recess 30 is formed.

It can also be seen that the first toothed section 6.1, the third Gear section 6.3 and the fifth gear section 6.5 all complementary to the second toothed section 6.2, the fourth Gear section 6.4 and the sixth gear section 6.6 are. As a result, another flooring element 2 with each any gear section 6.1 or 6.3 or 6.5 on each any of the toothed sections 6.2 or 6.4 or 6.6 - if necessary after appropriate rotation - can be created. These relationships will be even clearer with reference to Figures 3 and 4.

The modified floor covering element 2 shown in FIG. 2 has the same geometric relationships as that drawn in Fig. 1. However, the floor covering element 2 of FIG. 2 additionally has one Scheinfuge 32 at the transition from the top in Fig. 2 Floor covering element part and the lower floor covering element part in FIG. 2. The course of the dummy joint 32 is an angular line contiguous, straight pieces, and the course of the False joint 32 arises when the first toothed section 6.1 by 90 ° clockwise or the second toothed section 6.2 90 ° counterclockwise or the third gear section 6.3 rotates by 180 ° about the axis of rotation 14. You can also use the equivalent second tooth section by 90 ° clockwise or the fourth Gear section by 90 ° counterclockwise or sixth toothed section 6.6 by 180 ° around the axis of rotation 16 rotate. The dummy joint 32 is a groove in the top view of the Flooring element, which to a relatively shallow depth from above goes into the flooring element 2.

In Fig. 2, the possibility is also shown, recesses 34 on To provide the circumference of the flooring element 2, in the example shown rectangular recesses 34. The recesses 34 are at each of the toothing sections 6.1 to 6.6 to the right of the center. If several flooring elements 2 are laid next to each other, are each a recess 34 of a first flooring element and one Recess 34 of a second flooring element facing each other and together form a powerful water passage opening.

There is also the possibility of small, top view semicircular spacer projections 36, and for the longer pieces 20.2 and 20.3 to the right of the center (Analogously for the longer pieces of all toothing sections 6.1 to 6.6) and in the intermediate sloping sections 8.1 and 8.2 and in the End sloping sections 10.1 and 10.2 each to the right of the center. On this way there are two contact points in the finished association Spacer tabs 36 per "long piece" each Gear section and per inclined section.

Finally, on the left in Fig. 2 long side of the Flooring element, approximately in the middle, the possibility drawn that instead of the "small" spacing projections 36 larger ones Provide spacing projections 38, rectangular in plan view can, e.g. B. each in the middle of the long piece of Gear section and / or the respective inclined section. In in this case come the "large" spacer protrusions 38 in pairs for mutual investment. The spacer protrusions 38 have - measured perpendicular to the contour of the Flooring element 2 - a dimension that between adjacent installed flooring elements 2 powerful water penetration joints be formed.

It is emphasized that the dummy joint 32 and the recesses 34 and the spacer projections 36 and 38 are not necessarily common must be present (as drawn in Fig. 2), but that one either a dummy joint 32 or only recesses 34 or only spacing projections 36 or 38, or also Combinations of two of these features can be realized.

Fig. 3 shows a first example of how the flooring elements of Fig. 1 can misplace. The so-called runner's association is drawn. All Floor covering elements 2 have the sixth toothed section at the top in Fig. 3 (as drawn in Fig. 1) and are with their Longitudinal central axes 4 either in alignment or parallel to each other oriented. If you look at the leftmost in Fig. 3, in Fig. 3 viewed from the top leading laying series, then always closes a third gear section 6.3 to a sixth Gear section 6.6. If, on the other hand, the middle in Fig. 3 If you look at the laying series that leads from top to bottom, then they are Floor covering elements 2 of this series by about half Floor covering element length in the longitudinal direction compared to Floor covering elements 2 of the previously considered installation series offset. The relationship between the middle laying row and the in Fig. 3 far right, leading from top to bottom, third Installation series.

If you e.g. B. in Fig. 3, the flooring elements of the middle Installation row rotates by 180 ° (so that now with each floor covering element the third toothed section 6.3 points upwards in FIG. 3), then one sees immediately that between the leftmost, first row of laying and the middle laying row no longitudinal offset by about half Floor covering element length is present around the floor covering elements 2 to be able to mesh the middle laying row. This is a second possible laying pattern.

In Fig. 4, a third possible laying pattern is drawn, namely the so-called herringbone association. The herringbone is in the sloping herringbone row 40 on a third Toothing section of a flooring element 2 a second Toothing section of an adjacent floor covering element 2. Between the flooring elements 2 in this oblique herringbone row 40 there is a longitudinal offset of about half Flooring element length; the longitudinal central axes 4 of the Floor covering elements 2 are aligned parallel to one another; the Flooring elements are not rotated 180 ° against each other. In the next, neighboring, oblique herringbone row 42 are all Flooring elements at 90 ° to the longitudinal direction in the first considered herringbone row 40 rotated. The fourth Tooth section of each flooring element is a first Gear section of an adjacent flooring element 2 created. The fifth toothed sections of the flooring elements 2 of the second herringbone row 42 are each on a fourth Tooth section of the flooring elements 2 of the first Herringbone row 40.

In addition, so-called edge floor covering elements 44a, 44b, 44c and 44d shown. The edge flooring elements 44a and 44b have essentially half the size of a floor covering element 2; the Edge flooring elements 44c and 44d each have substantial the size of an entire flooring element 2. All edge flooring elements 44a to 44d have a straight line Boundary side.

In all drawing figures, the flooring elements 2 are drawn that their contours are perpendicular to the plane of the drawing. It it is pointed out that this need not necessarily be the case, e.g. B. could be below the useful side, which you can see in the drawing figures looks, a kind of step outwards or inwards. While the recesses 34 are usually from the top to the top at the very bottom, it is preferred to use the spacer protrusions 36 or 38 a bit below the level of the useful sides to end.

Usually both are visible in the drawing figures Usable area as well as when laying on the subfloor, typically a sand bed, placed underside - possibly with an exception a dummy joint 32 - flat surfaces. That is also not mandatory, one could e.g. B. provide creasing in the utility side or certain Lower or lower the surface areas a bit compared to the usable area Increase piece.

In most cases, flooring elements are formed with a chamfer Transition between the usable area and the outer outline, mostly in Form a small 45 ° bevel. The transition can be done analogously between the dummy joint 32 and the usable area of the flooring element do. These bevels are to increase clarity of the drawing figures not shown.

Claims (17)

Flooring element made of artificial stone material with a basic shape, which - roughly speaking - is elongated-rectangular, and with serrations on the circumference,
characterized by the following features in combination: (a) on a first longitudinal side of the floor covering element, a first toothed section, a further outwardly extending intermediate bevel section, a second toothed section, and a further inwardly directed end beveled section follow one another, the second toothed section rotating the first toothed section by 180 ° and moved outward, corresponds to; (b) on a second longitudinal side of the floor covering element are followed by a third toothed section, a further outwardly extending intermediate bevel section, a fourth toothed section and a further inwardly directed end beveled section, the fourth toothed section being rotated by 180 ° and after the third toothed section shifted outside, corresponds; (c) on a first transverse side of the floor covering element there is a fifth toothed section which leads from the first to the third toothed section; (d) on a second transverse side of the floor covering element there is a sixth toothed section which leads from one end inclined section to the other end inclined section; (e) the second toothed section, the fourth toothed section and the sixth toothed section are identical and can be brought into register with one another by rotation through 90 ° or 180 ° about a virtual, first axis of rotation, which projects from the top view surface of the floor covering element; (f) the first toothed section, the third toothed section and the fifth toothed section are identical and can be brought into register with one another by rotation through 90 ° or 180 ° about a virtual, second axis of rotation which protrudes from the top view surface of the floor covering element. Floor covering element according to claim 1,
characterized in that all said toothing sections each have at least one projection and a recess against a straight connecting line of their end points. Floor covering element according to claim 1,
characterized in that the first, third and fifth toothed sections each run continuously outside a straight connecting line of its end points and in that the second, fourth and sixth toothed sections each run continuously within a straight connecting line of its end points. Floor covering element according to claim 1,
characterized in that the first, the third and the fifth tooth section each run continuously within a straight connecting line of its end points and in that the second, the fourth and the sixth tooth section each run continuously outside a straight connecting line of its end points. Floor covering element according to one of claims 1 to 4,
characterized in that the intermediate oblique sections and the end oblique sections are unoccupied by toothing. Floor covering element according to claim 5,
characterized in that the intermediate sloping sections and the end sloping sections each extend at an angle of 45 ° relative to the central longitudinal axis of the flooring element. Floor covering element according to one of claims 1 to 6,
characterized in that the straight connecting line of the end points in the said toothing sections is in each case longer than the straight connecting line of the end points in the intermediate inclined sections and the end inclined sections. Floor covering element according to claim 7,
characterized in that the straight connecting line of the end points in the said toothed sections is at least 1.5 times as long, preferably at least 2.0 times as long, most preferably at least 2.5 times as long as the straight connecting line of the end points at the intermediate bevel sections and the end bevel sections. Floor covering element according to one of claims 1 to 8,
characterized in that neither the first and the third toothing section nor the second and the fourth toothing section are mirror images of one another. Floor covering element according to one of claims 1 to 9,
characterized in that neither the first and the third toothing section nor the second and the fourth toothing section can be brought to congruence by parallel displacement. Floor covering element according to one of claims 1 to 10,
characterized in that the said toothed sections are each a line of angularly adjoining straight pieces. Floor covering element according to claim 11,
characterized in that the said toothing sections are each a line of at least three straight pieces which adjoin one another at an angle, preferably three of these pieces or four of these pieces. Floor covering element according to one of claims 1 to 10,
characterized in that the said toothed sections are each a curved line. Floor covering element according to one of claims 1 to 10,
characterized in that the said toothed sections are each a line with at least one straight piece and with at least one curved piece. Floor covering element according to one of claims 1 to 14,
characterized in that it is provided on the circumference with spacing projections, the spacing projections being disregarded when considering the geometric relationships mentioned in claims 1 to 14. Floor covering element according to one of claims 1 to 15,
characterized in that it is provided on the circumference with recesses for creating efficient water passage openings, the recesses being disregarded when considering the geometric conditions mentioned in claims 1 to 14. Floor covering element according to one of claims 1 to 16,
characterized in that it has a dummy joint on its upper side, the course of which corresponds to the fifth toothed section after rotation through 180 ° about the virtual, second axis of rotation and which leads from an end point of the first toothed section to an end point of the third toothed section.

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