EP4144933A1 - Panel for covering a surface - Google Patents

Abstract

The invention relates to a panel (10a, 10b) for cladding a surface, with a panel core which consists of a flat panel surface (12), a flat panel undersurface (14) spaced from this and parallel to this, and four panels each connecting the panel surface to the panel undersurface Panel side surfaces is enclosed, wherein mutually complementary coupling elements (16, 18) in the form of an upper coupling element (16) and a lower Koppelelemenst (18) are arranged on two opposite panel side surfaces, which are designed such that they a coupling of a first such panel ( 10a) with a second such panel (10b) by means of a relative movement of the upper coupling element (16) of the first panel (10a) towards the lower coupling element (18) of the second panel (10b), with a first coupling section of the coupling elements (16, 18), a second coupling section of the coupling elements (16, 18) and a third coupling section of the coupling elements (16, 18) are provided and the upper coupling element (16) has a locking receptacle (28) adjoining the latching element (24) and the lower coupling element (18) has a locking element adjoining the locking receptacle (26) at its distal end (30) which engages in the locking receptacle (28) when two panels (10a, 10b) are in the coupled state, so that the locking receptacle (28) together with the locking element (30) form the third coupling section of the coupling elements (16, 18). According to the invention, the surfaces (32, 34) of the locking receptacle (28) or of the locking element (30) which face one another when two panels (10a, 10b) are in the coupled state have corrugated structures which are complementary to one another. In this way, a panel (10a, 10b) for cladding a surface is provided which has particularly high fluid resistance.

Description

The invention relates to a panel for cladding a surface, in particular a floor panel for cladding a floor area of a building space, with a panel core which consists of a flat panel surface, a flat panel undersurface spaced from this and parallel to it and four panel side surfaces connecting the panel surface to the panel undersurface is enclosed, with mutually complementary coupling elements in the form of an upper coupling element and a lower coupling element being arranged on two opposite panel side surfaces, which are configured in such a way that they enable a coupling of a first such panel to a second such panel by means of a relative movement of the upper coupling element of the first Allow panels to the lower coupling element of the second panel out, the upper coupling element has a wedge-shaped projection at its distal end and the lower coupling element aufwei a counter surface st, which rests against the wedge-shaped projection in the coupled state of two panels, so that the wedge-shaped projection together with the mating surface form a first coupling section of the coupling elements, the upper coupling element has a latching element adjoining the wedge-shaped projection and the lower coupling element has a latching element adjoining the mating surface Has a locking receptacle into which the locking element is locked when two panels are in the coupled state, so that the locking element together with the locking receptacle form a second coupling section of the coupling elements, the upper coupling element has a locking receptacle adjoining the locking element and the lower coupling element has a locking receptacle at its distal end the locking receptacle has subsequent locking element, which engages in the coupled state of two panels in the locking receptacle, so that the locking receptacle together with the locking element a third coupling portion form the coupling elements. Such a panel is from the U.S. 10,000,935 B2 known.

Such a panel thus always has a lower coupling element and an upper coupling element, with the terms "lower" and "upper" referring to the fact that when the panels are being assembled, an upper coupling element of a panel to be assembled is attached to a lower coupling element of an already assembled and on the panel lying on the ground is pressed on. In order to form the first coupling section, the wedge-shaped projection of the upper coupling element is pressed onto a mating surface of the lower coupling element which runs obliquely to the ground. In order to form the second coupling section, the lower coupling element is spread open in the area of the locking receptacle by the penetrating locking element of the upper coupling element. In order to form the third coupling section, the upper coupling element is spread open in the region of the locking receptacle by the penetrating locking element of the lower coupling element.

Due to the relatively large contact surface between the upper coupling element and the lower coupling element, a high fluid resistance of a composite of such panels is already achieved. “Fluid strength” is understood to mean the ability of a composite of the panels to resist the passage of fluid, such as water, from the top of the panels and between adjacent panels to the bottom of the panels and, in the best case, to prevent this entirely. However, it has been shown that complete fluid resistance of such a composite panel cannot be achieved in all situations.

Proceeding from this, it is the object of the invention to provide a panel for cladding a surface which has a particularly high fluid resistance.

This object is solved by the subject matter of patent claim 1. Preferred developments of the invention are described in the dependent claims.

According to the invention a panel for cladding a surface is provided in this respect, in particular a floor panel for cladding a floor area of a building space, with a panel core of a flat panel surface, one of this spaced-apart and parallel to this flat panel undersurface and four panel side surfaces connecting the panel surface to the panel undersurface, wherein mutually complementary coupling elements in the form of an upper coupling element and a lower coupling element are arranged on two opposite panel side surfaces, which are designed in such a way that they have a enable a first such panel to be coupled to a second such panel by means of a relative movement of the upper coupling element of the first panel towards the lower coupling element of the second panel, the upper coupling element has a wedge-shaped projection at its distal end and the lower coupling element has a mating surface which in the coupled state of two panels rests against the wedge-shaped projection, so that the wedge-shaped projection together with the mating surface form a first coupling portion of the coupling elements, the upper Koppelel ement has a locking element adjoining the wedge-shaped projection and the lower coupling element has a locking receptacle adjoining the counter surface, into which the locking element is locked when two panels are coupled, so that the locking element together with the locking receptacle form a second coupling section of the coupling elements, the upper one Coupling element has a locking receptacle adjoining the locking element and the lower coupling element has at its distal end a locking element adjoining the locking receptacle, which engages in the locking receptacle when two panels are coupled, so that the locking receptacle together with the locking element form a third coupling section of the coupling elements, characterized in that the surfaces of the locking receptacle or of the locking element which face one another in the coupled state of two panels have a corrugated structure which is complementary to one another ures.

It is thus a significant aspect of the invention that the surface of the locking receptacle and the surface of the locking element each have a corrugated structure, these corrugated structures being complementary to one another. The fact that the corrugated structures are complementary to one another means that the shape of these corrugated surfaces is such that they lie flat against one another in the coupled state of two panels, which is achieved by the surface shapes of the locking receptacle of the locking element corresponding to one another. That's where the locking mount is has a trough, the locking element is provided with a crest, and vice versa. In this way, an interlocking of the two surfaces is practically achieved. This makes the interface between the latch receiver and the latch member larger than flat surfaces, ultimately making it more difficult for fluid to pass between the latch receiver and the latch member. In this way, an even higher fluid resistance of a composite panel consisting of such panels can be achieved.

In principle, completely different corrugated structures can be used in order to achieve the fluid resistance in question. According to a preferred development of the invention, however, it is provided that the corrugated structures in the locking receptacle and the locking element run perpendicularly to the panel side faces that have the mutually complementary coupling elements. It has been shown that particularly good resistance to fluids can be achieved in this way. Incidentally, the shape of the corrugated structures can follow various forms. According to a preferred development of the invention, however, it is provided that the wave structures in the locking receptacle and the locking element run sinusoidally.

As far as the number of wave crests and wave troughs is concerned, this can vary in principle. According to a preferred development of the invention, however, it is provided that the wave structures have at least four wave crests, preferably at least five wave crests, very preferably at least six wave crests. It has been shown that even such a small number of wave crests leads to a significant improvement in fluid resistance. Furthermore, it is preferred that the height difference between the wave crests and the wave troughs is between a maximum of 7% and a minimum of 1% of the total thickness of the panel given by the distance between the panel surface and the panel undersurface.

The invention allows the surfaces of the locking element and the surface of the locking receptacle as a whole, that is to say without taking the corrugation structure into account, both to be essentially planar. This means that the wave structures practically oscillate around a plane plane. Preferably, however, that the surfaces of the locking element is generally convex perpendicular to the panel side faces having the mutually complementary coupling elements and the surface of the locking receptacle is generally concave perpendicular to the panel side faces having the mutually complementary coupling elements. When it says here that surfaces are convex or concave overall, this means the shape of the surfaces without the wave structures. Of course, the wave structures mean that both surfaces repeatedly have convex or concave areas locally. Overall, however, the surface of the locking element according to the preferred development of the invention described here is curved outwards, i.e. in the locked state of two panels towards the surface of the locking receptacle, while the surface of the locking receptacle is correspondingly retracted so that it touches the surface of the locking element is adjusted.

According to a preferred development of the invention, it is provided that the surfaces of the locking element and the surface of the locking receptacle run perpendicularly to the side surfaces of the panel, which have the mutually complementary coupling elements, apart from the corrugated structures, in the shape of a segment of a circle, with the radius of the surface of the locking element and the surface of the locking receptacle being in range from 85% to 95% of the total thickness of the panel given by the distance between the panel surface and the panel undersurface. It has been found that within these values there is an advantageous and even distribution of forces. Due to the resulting flat arc shape, the coupling elements are advantageously protected against static friction and thus against the risk of breakage.

According to a preferred development of the invention, it is provided that a tangent to the center of the circular segment shape of the surface of the locking element and/or a tangent to the center of the circular segment shape of the surface of the locking receptacle has a respective arc angle α of at most 45°, preferably of includes a maximum of 35°, particularly preferably a maximum of 25°. In this way, high vertical forces can be absorbed horizontally evenly distributed by the locking element of the lower coupling element become. At the same time there is sufficient inclination to form the third coupling section. This protects the components and secures the panels.

According to a preferred development of the invention, it is provided that the latching element has a latching projection and the latching receptacle has a latching abutment, which interact with one another when two panels are in the coupled state. Such an embodiment permits a reliable, form-fitting second coupling section, the interaction of the latching projection and the latching abutment not subjecting the panel to any component-damaging stress.

According to a preferred development of the invention, it is provided that the locking element has a locking projection and the locking receptacle has a locking abutment, which interact with one another when two panels are in the coupled state. Such an embodiment permits a reliable, form-fitting third coupling section, with the interaction of the locking projection and the locking abutment not subjecting the panel to any component-damaging stress.

According to a preferred development of the invention, it is provided that the material thickness of the lower coupling element between the panel undersurface and the latching receptacle is less than the material thickness of the upper coupling element between the panel surface and the locking receptacle. This means a dimensioning according to which the coupling elements, when two panels are joined together, are spread apart less stressful than previously known panels due to an adapted dimensioning and thus tend towards material failure or breakage with a reduced risk.

It has been found that the assembly loads on the lower coupling element can generally be better balanced than the assembly loads on the upper coupling element. One of the reasons for this is that the lower coupling element rests on the surface to be clad during the assembly of the upper coupling element. The forces acting on the lower coupling element can thus be directly and evenly counteracted by the ground and are therefore less damaging to individual components of the lower coupling element. In contrast, forces acting on the upper coupling element during the joining of two panels have no such possibility of force distribution, so that the upper coupling element tends to materially fail. Such a material failure or a fracture usually occurs in areas with high loads and the smallest possible material thickness. The lower coupling element has the smallest material thickness between the panel lower surface and the snap-in receptacle. The upper coupling element has the smallest material thickness between the panel surface and the locking receptacle. In the following, material thickness means a minimum or maximum material thickness in this respective area. If the formulation material thickness is used, this applies to this definition or arrangement.

Under the aspects mentioned above, according to a preferred development of the invention, it is provided that the material thickness of the lower coupling element between the panel lower surface and the snap-in receptacle is at least 62%, preferably at least 67% and particularly preferably at least 72% of the material thickness of the upper coupling element between the panel surface and the locking recording is. Furthermore, it is preferred that the material thickness of the lower coupling element between the panel undersurface and the locking receptacle is at most 82%, at most 77% and particularly preferably at most 72% of the material thickness of the upper coupling element between the panel surface and the locking receptacle. It is also preferable that the material thickness of the upper coupling element between the panel surface and the locking receptacle is at least 34%, preferably at least 39%, particularly preferably at least 44% of the total thickness of the panel given by the distance between the panel surface and the panel undersurface.

Furthermore, it is preferred that the material thickness of the upper coupling element between the panel surface and the locking receptacle is at most 54%, preferably at most 49%, particularly preferably at most 44% of the total thickness of the panel given by the distance between the panel surface and the panel undersurface. It is preferably the case that the material thickness of the lower coupling element between the lower surface of the panel and the snap-in receptacle is at least 24%, preferably at least 29%, particularly preferably at least 34% of the total thickness of the panel given by the distance between the panel surface and the panel undersurface. Furthermore, it is preferred that the material thickness of the lower coupling element between the panel undersurface and the snap-in receptacle is at most 44%, preferably at most 39%, particularly preferably at most 34% of the total thickness of the panel given by the distance between the panel surface and the panel undersurface.

Finally, according to a preferred development of the invention, the panel consists of at least one carrier or core on or to which different functional layers are applied or attached, such as decorative layers, wear protection layers and/or counteracting layers. The described coupling elements according to the invention are essentially formed in the carrier or core. The carrier or core of a panel according to the invention can be provided, for example, a carrier based on a natural material, a plastic, a wood-plastic composite material (WPC), a mineral-plastic composite material (MPC, SPC). Layered structures made from several of the materials mentioned can also be used, for example plasterboard or wood-plastic layered boards.

For example, the carrier plate can be made of a thermoplastic, elastomeric or duroplastic material. Also panels made of minerals such as natural and artificial stone panels, concrete panels, gypsum fiber panels, so-called WPC panels (made of a mixture of plastic and wood), so-called MPC or SPC panels (made of a mixture of plastic and mineral or stone flour), as well as Boards made from natural raw materials such as cork and wood can be used as carriers according to the invention. Panels made from biomass as a natural material such as straw, corn stalks, bamboo, leaves, algae extracts, hemp, oil palm fibers can also be used according to the invention. Furthermore, recycled materials made from the materials mentioned can be used within the scope of the method according to the invention. In addition, the panels can be made from the natural material cellulose, such as paper or cardboard.

In addition to solid wood materials, wood-based materials within the meaning of the invention are also materials such as cross laminated timber, glued laminated timber, block laminated timber, veneer plywood, laminated veneer lumber, strip veneer lumber and flexible plywood. In addition, wood-based materials within the meaning of the invention also include chipboard materials such as chipboard, extruded boards, coarse chipboard (Oriented Structural Board, OSB) and chipboard as well as wood fiber materials such as wood fiber insulation boards (HFD), medium-hard and hard fiberboard (MB, HFH), and in particular medium-density Understanding Fiberboard (MDF) and High Density Fiberboard (HDF). Modern wood-based materials such as wood-polymer materials (Wood Plastic Composite, WPC), sandwich panels made of a light core material such as foam, rigid foam or paper honeycomb and a layer of wood applied thereto, as well as chipboard bonded with minerals, for example with cement, form wood-based materials within the meaning of the invention. Cork is also a wood-based material within the meaning of the invention.

For the purposes of the invention, the term fiber materials is to be understood as meaning materials such as paper and nonwovens based on vegetable, animal, mineral or artificial fibers, as well as cardboard. Examples are fiber materials made from plant fibers, in addition to paper and fleece made from cellulose fibers, panels made from biomass such as straw, corn stalks, bamboo, leaves, algae extracts, hemp, cotton or oil palm fibers. Examples of animal fiber materials are keratin-based materials such as wool or horsehair. Mineral fiber materials are examples of mineral wool or glass wool.

Furthermore, the carrier can be a plastic-based carrier, that is to say it can have or consist of a plastic. Examples of thermoplastics are polyvinyl chloride, polyolefins (e.g. polyethylene (PE), polypropylene (PP), polyamides (PA), polyurethanes (PU), polystyrene (PS), acrylonitrile butadiene styrene (ABS), polymethyl methacrylate (PMMA), polycarbonate). (PC), polyethylene terephthalate (PET), polyether ether ketone (PEEK) or mixtures or copolymers of these. The plastics can contain the usual fillers, for example talc, calcium carbonate (chalk), aluminum oxide, silica gel, quartz flour, wood flour, gypsum. They can also be be colored in a known manner In particular, it can be provided that the carrier material has a flame retardant and/or an antistatic additive.

Thermoplastics in particular also offer the advantage that the products made from them can be recycled very easily. Recycled materials from other sources can also be used. This results in a further possibility of reducing the production costs.

The carrier material or the material from which the carrier is formed can, for example, be a matrix material and a solid material, the matrix material in an amount, based on the carrier material, of ≥ 25 wt .-% to ≤ 55 wt .-%, in particular from ≥ 35% by weight to ≤ 45% by weight, and the solid material is present in an amount, based on the carrier material, of ≥ 45% by weight to ≤ 75% by weight, in particular ≥ 55% by weight to ≦65% by weight, and wherein the matrix material and the solid material together, based on the carrier material, are present in an amount of ≧95% by weight, in particular ≧99% by weight, and the solid material at least 50 wt. %, in particular at least 80 wt. %, in particular at least 95 wt 50% by weight, in particular e is formed to an extent of at least 80% by weight, in particular at least 95% by weight, based on the matrix material, by a plastic composition consisting of a homopolymer and at least one first copolymer and one second copolymer.

Layered silicate powder is understood to mean, in a manner known per se, a powder made from a layered silicate. Layered silicate is known to refer to minerals from the silicate group, the silicate anions of which are usually arranged in layers. For example, phyllosilicates are understood to mean minerals from the mica group, the chlorite group, the kaolinite group and the serpentine group.

The solid material can thus advantageously be formed at least largely from the mineral substance layered silicate, with this substance being able to be used in powder form or being present in the carrier material in the form of particles. In principle, the solid material can consist of a powdered solid.

Layered silicates offer the advantage that they can allow the production of a carrier with good mechanical properties and, at the same time, can be easily processed into corresponding powders due to their layered structure.

The invention is explained in more detail below using a preferred exemplary embodiment with reference to the drawings.

• Fig. 1 schematisch eine Schnittansicht der Kopplungselemente zweier Paneele gemäß einem bevorzugten Ausführungsbeispiel der Erfindung in ungekoppeltem Zustand und
• Fig. 2 schematisch eine Schnittansicht der Kopplungselemente der in Fig. 1 gezeigten Paneele in gekoppeltem Zustand.

Show in the drawings

• 1 schematically a sectional view of the coupling elements of two panels according to a preferred embodiment of the invention in the uncoupled state and
• 2 schematically a sectional view of the coupling elements in 1 Panels shown in coupled condition.

Out of 1 two panels 10a, 10b can be seen in a schematic sectional view, which are provided for cladding a surface. Specifically, the preferred exemplary embodiment of the invention shown here involves two floor panels for cladding a floor area of a building room. 1 shows the panels 10a, 10b in the uncoupled state, ie separated from one another. The panels 10a, 10b shown here have thermoplastic polymers as the base material. Alternatively, they can have HDF or MDF carriers.

The two panels 10a, 10b each have a panel core which is enclosed by a flat panel surface 12, a flat panel bottom surface 14 spaced from this and parallel to this flat panel bottom surface and four panel side surfaces connecting the panel surface 12 to the panel bottom surface 14. How out 1 As can be seen, mutually complementary coupling elements 16, 18 in the form of an upper coupling element 16 and a lower coupling element 18 are arranged on two opposite panel side surfaces, which are configured in such a way that they allow a first such panel 10a to be coupled to a second such panel 10b by means of a relative movement of the upper coupling element 16 of the first panel 10a to the lower coupling element 18 of the second panel 10b.

The panels 10a, 10b each have three coupling sections on their coupling elements 16, 18, as follows:
The upper coupling element 16 has a wedge-shaped projection 20 at its distal end, and the lower coupling element 18 has a mating surface 22 which rests against the wedge-shaped projection 20 in the coupled state of two panels 10a, 10b, so that the wedge-shaped projection 20 together with of the mating surface 22 form the first coupling section of the coupling elements 16, 18.

In addition, the upper coupling element 16 has a latching element 24 adjoining the wedge-shaped projection 20, and the lower coupling element 18 has a latching receptacle 26 adjoining the mating surface 22, into which the latching element 24 is latched when two panels 10a, 10b are coupled, see above that the locking element 24 together with the locking receptacle 26 form the second coupling section of the coupling elements 16, 18.

Finally, it also applies that the upper coupling element 16 has a locking receptacle 28 adjoining the locking element 24, and the lower coupling element 18 has at its distal end a locking element 30 adjoining the locking receptacle 26, which in the coupled state of two panels 10a, 10b in the locking receptacle 28 engages, so that the locking receptacle 28 together with the locking element 30 form the third coupling section of the coupling elements 16, 18.

How further from 1 As can be seen, it applies to both panels 10a, 10b that the latching element 24 has a latching projection 42 and the latching receptacle 26 has a latching abutment 44. Out of 2 It can be seen that the latching projection 42 and the latching abutment 44 interact with one another in the coupled state of two panels 10a, 10b in order to ensure a firm connection of the panels 10a, 10b with one another. In addition, the locking element 30 has a locking projection 46 and the locking receptacle 28 have a locking abutment 48, which, as also from 2 can be seen, interact with each other in the coupled state of two panels 10a, 10b.

It is now essential that the surfaces 32, 34 of the locking receptacle 28 or of the locking element 30 which face one another in the coupled state of two panels 10a, 10b have corrugated structures which are complementary to one another. Out of 1 it can be seen that the corrugated structures in the locking receptacle 28 and the locking element 30 run perpendicular to the panel side surfaces having the mutually complementary coupling elements 16, 18 and that the corrugated structures in the locking receptacle 28 and the locking element 30 run sinusoidally.

Besides, the 1 and 2 It can be seen that the surface 32 of the locking element 30 runs convex overall in a direction perpendicular to the panel side surfaces having the mutually complementary coupling elements 16, 18 and the surface 34 of the locking receptacle 28 runs in a direction perpendicular to the panel side surfaces having the mutually complementary coupling elements 16, 18 overall concave.

The figures also show that the surface 32 of the locking element 30 and the surface 34 of the locking receptacle 28 run perpendicular to the panel side surfaces having the mutually complementary coupling elements 16, 18, apart from the corrugated structures, in the shape of a circular segment. The radius R of the surface 32 of the locking element 30 and the surface 34 of the locking receptacle 28 is in the range of 85% to 95% of the total thickness G of the panel 10a, 10b given by the distance between the panel surface 12 and the panel undersurface 14.

It should also be mentioned that in the case of panels 10a, 10b, a tangent to the center of the circular segment shape of the surface 32 of the locking element 30 and a tangent to the center of the circular segment shape of the surface 34 of the locking receptacle 28 relative to the panel surface 12 and the panel undersurface 14 have a respective arc angle α of includes a maximum of 45°. In this way, high vertical forces horizontally evenly distributed by the locking element of the lower coupling element 18 are received.

In addition, the material thickness UM of the lower coupling element 18 between the panel undersurface 14 and the latching receptacle 26 is less than the material thickness OM of the upper coupling element 16 between the panel surface 12 and the locking receptacle 28, which leads to the advantages in terms of breakage resistance detailed above .

Reference List

10a, 10b

panels

12

panel surface

14

panel undersurface

16

upper coupling element

18

lower coupling element

20

wedge-shaped projection

22

counter surface

24

locking element

26

snap-in mount

28

locking receptacle

30

locking element

32

surface of the locking element

34

surface of the locking seat

42

locking projection

44

detent abutment

46

locking tab

48

locking abutment

G

overall thickness

OM

Material thickness of the upper coupling element

AROUND

Material thickness of the lower coupling element

a

arc angle

R

radius

Claims (15)

Panel (10a, 10b) for covering a surface, with a panel core which is enclosed by a flat panel surface (12), a flat panel undersurface (14) which is spaced apart from and parallel to this and four panel side surfaces which connect the panel surface (12) with the panel undersurface (14), wherein mutually complementary coupling elements (16, 18) in the form of an upper coupling element (16) and a lower coupling element (18) are arranged on two opposite panel side surfaces, which are designed in such a way that they enable a first such panel (10a) to be coupled to a second enable such a panel (10b) by means of a relative movement of the upper coupling element (16) of the first panel (10a) towards the lower coupling element (18) of the second panel (10b), the upper coupling element (16) has a wedge-shaped projection (20) at its distal end and the lower coupling element (18) has a mating surface (22) which rests against the wedge-shaped projection (20) when two panels (10a, 10b) are coupled , so that the wedge-shaped projection (20) together with the mating surface (22) form a first coupling section of the coupling elements (16, 18), the upper coupling element (16) has a latching element (24) adjoining the wedge-shaped projection (20) and the lower coupling element (18) has a latching receptacle (26) adjoining the counter surface (22), into which two panels (10a , 10b) the latching element (24) is engaged, so that the latching element (24) together with the latching receptacle (26) form a second coupling section of the coupling elements (16, 18), the upper coupling element (16) has a locking receptacle (28) adjoining the latching element (24) and the lower coupling element (18) has at its distal end a locking element (30) adjoining the locking receptacle (26), which in the coupled state of two panels (10a, 10b) engages in the locking receptacle (28), so that the locking receptacle (28) together with the locking element (30) form a third coupling section of the coupling elements (16, 18), characterized in that the surfaces (32, 34) of the locking receptacle (28) or of the locking element (30) which face one another when two panels (10a, 10b) are in the coupled state have corrugated structures which are complementary to one another. Panel (10a, 10b) according to Claim 1, characterized in that the corrugated structures in the locking receptacle (28) and the locking element (30) run perpendicularly to the panel side faces which have the mutually complementary coupling elements. Panel (10a, 10b) according to Claim 1 or 2, characterized in that the wave structures in the locking receptacle (28) and the locking element (30) are sinusoidal. Panel (10a, 10b) according to one of the preceding claims, characterized in that the wave structures have at least four wave crests. Panel (10a, 10b) according to one of the preceding claims, characterized in that the height difference between the wave crests and the wave troughs is between a maximum of 7% and a minimum of 1% of the total thickness ( G) of the panel (10a, 10b). Panel (10a, 10b) according to one of the preceding claims, characterized in that the surfaces (32) of the locking element (30) are generally convex perpendicular to the panel side surfaces having the mutually complementary coupling elements (16, 18) and the surface (34) of the The locking receptacle (28) extends concavely perpendicularly to the panel side surfaces having the mutually complementary coupling elements (16, 18). Panel (10a, 10b) according to any one of the preceding claims, characterized in that the surfaces (32) of the locking element (30) and the surface (34) of the locking receptacle (28) are perpendicular to those having the mutually complementary coupling elements (16, 18). Panel side surfaces, from the wave structures apart from, run in the shape of a segment of a circle, with the radius (R) of the surface (32) of the locking element (30) and the surface (34) of the locking receptacle (28) being in the range of 85% to 95% of that caused by the distance between the panel surface (12) and the Panel bottom surface (14) given total thickness (G) of the panel (10a, 10b). Panel (10a, 10b) according to one of the preceding claims, characterized in that a tangent to the center of the circular segment shape surfaces (32) of the locking element (30) and / or a tangent to the center of the circular segment shape of the surface (34) of the locking receptacle (28) encloses a respective arc angle (α) of at most 45° with respect to the panel surface (12) and the panel undersurface (14). Panel (10a, 10b) according to one of the preceding claims, characterized in that the latching element (24) has a latching projection (42) and the latching receptacle (26) has a latching abutment (44) which when two panels (10a, 10b) are coupled interact with each other. Panel (10a, 10b) according to one of the preceding claims, characterized in that the locking element (30) has a locking projection (46) and the locking receptacle (28) has a locking abutment (48) which, when two panels (10a, 10b) are in the coupled state interact with each other. Panel (10a, 10b) according to one of the preceding claims, characterized in that the material thickness (UM) of the lower coupling element (18) between the panel lower surface (14) and the latching receptacle (26) is less than the material thickness (OM) of the upper coupling element (16) between the panel surface (12) and the latch receptacle (28). Panel (10a, 10b) according to one of the preceding claims, characterized in that the material thickness (UM) of the lower coupling element (18) between the panel lower surface (14) and the latching receptacle (26) is at least 62% of the material thickness (OM) of the upper coupling element (16) between the panel surface (12) and the latch receptacle (28). Panel (10a, 10b) according to one of the preceding claims, characterized in that the material thickness (UM) of the lower coupling element (18) between the panel lower surface (14) and the latching receptacle (26) is at most 82% of the material thickness (OM) of the upper coupling element (16) between the panel surface (12) and the latch receptacle (28). Panel (10a, 10b) according to one of the preceding claims, characterized in that the material thickness (OM) of the upper coupling element (16) between the panel surface (12) and the locking receptacle (28) is at least 34% of the distance between the panel surface (12 ) of the panel bottom surface (14) given overall thickness (G) of the panel (10a, 10b). Panel (10a, 10b) according to one of the preceding claims, characterized in that the panel (10a, 10b) has at least partially thermoplastic styrene block copolymers as the base material.

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