Floor element for forming a floor covering and floor covering
阅读说明:本技术 用于形成地板覆盖物的地板元件和地板覆盖物 (Floor element for forming a floor covering and floor covering ) 是由 拉胡尔·保特基 洛朗·梅尔斯曼 克劳迪奥·贝内文蒂 克劳迪奥·卡塞利 于 2018-05-14 设计创作,主要内容包括:一种用于形成地板覆盖物的地板元件(1),其中,所述地板元件(1)包括由陶瓷材料制成的装饰层(3)和布置在所述装饰层(3)下方的支撑层(14),其中,所述支撑层(14)包括设置有联接元件(16、17、31、35)的边缘(15),所述联接元件被构造成实现与相邻地板元件(1)的联接元件(16、17、31、35)的机械联接,并且其中,所述地板元件(1)包括布置在所述装饰层(3)和所述支撑层(14)之间的增强层(11)。(A flooring element (1) for forming a floor covering, wherein the flooring element (1) comprises a decorative layer (3) made of a ceramic material and a supporting layer (14) arranged below the decorative layer (3), wherein the supporting layer (14) comprises an edge (15) provided with coupling elements (16, 17, 31, 35) configured to enable mechanical coupling with coupling elements (16, 17, 31, 35) of an adjacent flooring element (1), and wherein the flooring element (1) comprises a reinforcement layer (11) arranged between the decorative layer (3) and the supporting layer (14).)
1. A floor element for forming a floor covering, wherein the floor element (1) comprises: a decorative layer (3) made of a ceramic material; and a supporting layer (14) arranged below the decorative layer (3), wherein the supporting layer (14) comprises a coupling edge (15) provided with coupling elements (16, 17, 31, 35) configured to enable a mechanical coupling with coupling elements (16, 17, 31, 35) of an adjacent flooring element (1), and wherein the flooring element (1) comprises a reinforcement layer (11) arranged between the decorative layer (3) and the supporting layer (14).
2. Floor element according to claim 1, wherein the reinforcement layer (11) comprises a layer of glass fibres, such as a glass fibre mat.
3. Floor element according to claim 1, wherein the reinforcement layer (11) comprises a metal sheet, preferably having a coefficient of thermal expansion which is higher than the coefficient of thermal expansion of the decorative layer (3).
4. Flooring element according to any one of the preceding claims, wherein the flooring element comprises an intermediate layer (13) arranged between the reinforcement layer (11) and the supporting layer (3).
5. Floor element according to claim 4, wherein the intermediate layer (11) is made of the same material as the decorative layer (3) and/or has the same thickness (A) as the decorative layer (3).
6. Floor element according to any of the preceding claims, wherein the decorative layer (3) has a thickness (A) of between 4 and 15 mm.
7. The flooring element of any one of the preceding claims, wherein the thickness of the flooring element is 13mm or less.
8. Floor element according to any of the preceding claims, wherein the decorative layer (3) is made of a brittle material and/or is made of natural stone, glass or concrete, but not of a ceramic material.
9. Flooring element according to any one of the preceding claims, wherein the supporting layer (14) is made of a polymeric material, preferably PVC.
10. Flooring element according to any one of claims 1-8, wherein the supporting layer (14) is made of fibre cement.
11. The floor element according to any of the preceding claims, wherein the coupling element (16, 17, 31, 35) is configured to be coupled by means of a translational downward movement (G) of the floor element (1) relative to an adjacent floor element (1).
12. Floor element according to any of the preceding claims, wherein the coupling element (16, 17, 31, 35) comprises at least one male part (16) and at least one female part (17).
13. The floor element according to claim 12, wherein the male part (16) is in the shape of a tongue (52) and the female part (17) is in the shape of a groove (17), or wherein the male and female parts (16, 17) in top view are dovetail shaped.
14. The floor element according to any of the preceding claims, wherein in the coupled condition of two of said adjacent floor elements (1) locking surfaces (21, 22, 27) are formed which limit the mutual movement of said floor elements (1) in vertical and/or horizontal directions (X, Y, Z).
15. Floor element according to claim 14, wherein in the coupled condition of two of said neighbouring floor elements (1) a first locking surface (21) is formed for limiting the mutual movement of the floor elements (1) in the horizontal direction (X) along the coupling edge (15), and a second locking surface (22) is formed for limiting the mutual movement of the floor elements (1) in a direction (Y) substantially horizontal and perpendicular to the coupling edge (15), and a third locking surface (27) is formed for limiting the mutual movement of the floor elements (1) in a substantially vertical direction (Z).
16. Floor element according to claim 15, wherein the locking surface (21, 22, 27) comprises a portion on a resilient arm (50, 51).
17. The flooring element according to any of the preceding claims, wherein the decorative layer (3) is fitted on the supporting layer (14) with an intermediate distance (8) between the decorative layer (3) in the coupled state of the two flooring elements (1).
18. A floor covering comprising a plurality of adjacent floor elements (1), wherein each floor element (1) comprises a decorative layer (3) of a ceramic material and a supporting layer (14) arranged below the decorative layer (14), wherein the floor covering (2) comprises a combination of the following features:
-at least one flooring element (1) comprises a reinforcement layer (11) between the decorative layer (3) and the supporting layer (14);
-the floor element (1) comprises coupling means (16, 17, 31, 35) configured to enable coupling with coupling elements (16, 17, 31, 35) of adjacent floor elements (1);
-the floor covering (2) comprises mortar (10) filling an intermediate distance (8) separating the decorative layer (3) of the floor element (1).
Technical Field
The present invention relates to a floor element for forming a floor covering and a floor covering.
More particularly, the invention relates to a floor element for forming a floor covering, wherein the floor element comprises a decorative layer made of a brittle material, such as natural stone, glass, or a sintered ceramic material, such as porcelain, ceramic, or the like. The decorative layer may be, for example, a tile.
Background
Traditionally, tiles are assembled by being placed side by side on a surface such as a floor or wall. Typically, the tiles are affixed to the surface using an adhesive. The joints between the tiles are grouted. In this way, the tiles are bonded to a rigid surface, such as a concrete subfloor, thereby increasing their impact strength. In the flooring-fitted rooms and at the quarters below the respective rooms, the adhesion to the sub-floor and therefore to the residential structure also results in a high attenuation of the walking sound. The tile surface is water-tight and hygienic, since it can be cleaned in a very wet manner. However, the step of assembling the tiles with adhesive is laborious and represents a large part of the labor involved in typical floor covering assembly. Moreover, this assembly technique requires a high level of expertise to obtain a good and level floor covering. Consequently, professional assembly of tiles is often very expensive due to the time and labor involved in assembly.
To replace existing floor coverings made of ceramic tiles, it is often necessary to break the tiles, resurface the surface by removing the remaining adhesive, and then fit a new floor covering. Thus, removing floor coverings made of tiles is a laborious and time-consuming operation. This operation also becomes difficult if the aim of the repair is to replace only one or a few damaged tiles, since replacing one tile preferably should not damage the adjacent tile.
In recent years, manufacturers have attempted to produce "do-it-yourself" tiling solutions that are easy to assemble. Some examples of these attempts are shown in WO 2004/097141 and WO 2008/097860. The floor elements disclosed in those documents can be laid on a surface and mechanically joined together to form a floor covering without the use of adhesives, thereby reducing labor and time in the assembly phase. Such floor coverings are known as floating floor coverings. In particular, in these documents, tiles or natural stone slabs are fixed to a supporting layer comprising coupling elements configured to effect coupling with coupling elements of adjacent flooring elements, so as to form a floor covering.
On the other hand, since such floor elements are not bonded to a common rigid surface, the impact strength and thus the fatigue strength are significantly reduced. The floating mounting may also generate a large walking noise. The joints between the tiles of WO 2008/097860 may be prone to water penetration, particularly during wet cleaning. According to some embodiments of WO 2004/097141, mortar may be applied between adjacent floor elements to obtain a joint, which may result in watertightness of the respective joint.
To improve the impact resistance of the tile, US 2014/349084 proposes a tile with a composite structure. In the composite tile, a reinforcing layer is disposed between two ceramic layers or between a ceramic layer and a polymer laminate. As an example of the reinforcing layer, a glass fiber layer may be cited. However, the assembly of the tile is still cumbersome. It is desirable to bond to the underlying subfloor, for example, via the sub-floor with a pressure sensitive adhesive or a tacky quick-loop fabric, so that the tile is made substantially solid with the subfloor to improve impact strength. Moreover, precise positioning of the tiles is difficult.
WO 2010/072704 proposes a different type of reinforcement layer, namely a steel plate. The steel plate is adhered to the back of the tile or plate. Also here, however, assembly is difficult. Assembly is accomplished by simply resting the tiles on the subfloor, so it is difficult to precisely position the tiles, and floor coverings can result in poor surface flatness and noisy and permeable floor coverings.
Disclosure of Invention
The present invention is directed, in a first aspect, to an alternative flooring element, according to some preferred embodiments thereof, which is directed to solving one or more of the problems set forth in the prior art.
Thus, according to a first independent aspect thereof, the present invention relates to a flooring element for forming a floor covering, wherein the flooring element comprises a decorative layer made of a ceramic material and a supporting layer arranged below the decorative layer, wherein the supporting layer comprises an edge provided with coupling elements configured to enable mechanical coupling with coupling elements of adjacent flooring elements, and wherein the flooring element comprises a reinforcement layer arranged between the decorative layer and the supporting layer. The inventors have found that with this solution the impact resistance of the floor elements, in particular of the ceramic decor layer, is greatly increased, so that even in the case of mechanical locking between such floor elements the impact strength of conventional elements assembled by means of an adhesive can be reached or even exceeded. In fact, the reinforcement layer substantially improves the rigidity of the decorative layer, thus forming a barrier to the propagation of cracks in the decorative layer itself. Furthermore, in the case of surface cracks of the decorative layer, the reinforcing layer keeps the decorative layer coherent itself and is preferably compacted, thereby masking the visual appearance of the surface cracks.
The impact strength of the floor can be determined by means of a steel ball impact test. According to this test, the impact strength is measured by dropping a steel ball onto the floor element from a certain height, and if the floor element is not broken, the height is increased until the height is reached at which the steel ball breaks the floor element. The steel ball weighed 225.5 grams and had a diameter of 38.1 millimeters (1.5 inches). The impact strength is expressed as the maximum achievable height at which the steel ball will not break the floor element when it is landed on the floor element. The higher the drop height, the higher the impact strength. Impact strength can be expressed in newton meters (Nm), i.e. the energy of a steel ball when hitting the surface of a floor element. The inventors have found that conventional floorings, for example floorings made of porcelain flooring elements with a thickness of about 10mm directly bonded to a subfloor, generally exhibit an impact strength of between 1.68Nm and 2.25Nm (corresponding to a drop from a height of 762mm to 1016 mm), whereas known floating floorings exhibit an impact strength of generally below 1.12Nm (corresponding to a drop of balls from a height of less than 508 mm). The inventors have found that with this solution impact strengths of more than 1.91Nm (corresponding to steel balls falling from a height of more than 863 mm) can be achieved.
The fatigue strength of the floor is determined by means of the so-called robinson test according to ASTM C627. According to this test, a three-wheeled cart was rotated about its center on top of the tile floor sample block. Above each wheel is a bar along which weights can be stacked. A powered motor drives the assembly and the cart rotates at a speed of 15 revolutions per minute. The test was run according to a loading schedule with 14 different cycles. The plan specifies for each cycle the type of wheel to be used (soft rubber, hard rubber or steel), the weight to be accumulated above each wheel and the number of cart revolutions to be performed. After each cycle was completed, the sample floor panels were visually inspected. The test results determined whether the floor was acceptable based on the number of cycles passed without failure and indicated that the floor would be able to achieve the following service levels:
samples that completed
samples that completed all 14 cycles without failure were designated as "overweight" commercial ratings.
The inventors have found that the robinson test can pass a minimum of 6 cycles (light commercial) due to the use of the reinforcement layer.
According to a most preferred embodiment of the invention, the decorative layer comprises a ceramic body, for example made of porcelain, earthenware, pottery or other sintered ceramic powder. Preferably, the decorative layer is a tile or a plate. By "tile", the element is meant to have a body consisting of a baked mineral (such as clay) and preferably a baked decorated top surface, preferably based on glaze.
It is noted, however, that this first aspect may be advantageously applied to decorative layers made of any kind of brittle material, such as natural stone, concrete, glass or glass-ceramic materials. By brittle material is meant a material that fractures without significant plastic deformation. In particular, for the scope of said patent application, the term "brittle material" means a material which itself (if not bonded to a support layer and without reinforcing elements) has an impact strength according to the ball impact test of less than 1.68 (corresponding to a ball falling from a height of less than 762 mm).
The decoration of the decorative layer may provide various textures, designs and colors. In a preferred embodiment, the decoration simulates a natural product, such as natural stone or wood. Preferably, the decoration is at least partially formed by printing. Although screen printing, rotogravure printing, flexography printing or offset printing are not excluded, printing is preferably achieved by means of digital printing such as inkjet printing. According to one variant, the decoration is formed at least partially by a homogeneously coloured base material or a mixture of coloured base materials.
The decorative layer may comprise a background coating at least partially covering its upper surface and adapted to receive an ornament on top thereof, e.g. adapted to receive a print on top thereof. The background coating may be white, beige, brown or any color suitable for receiving a decoration on top thereof. In case the decorative layer is made of a ceramic material, the background layer preferably comprises at least a glaze covering the upper surface of the ceramic body.
The decorative layer may also include a protective coating at least partially covering an upper surface thereof and adapted to be placed over the upholstery. The protective coating may be transparent or translucent. It is clear that a protective coating can be used in combination with a background coating. In the case of a decorative layer made of a ceramic material, the protective layer is preferably a glaze.
Preferably, the thickness of the decorative layer is between 4 and 15mm, such as 6mm, preferably above 7mm, such as 10 mm. The inventors have found that by adding a reinforcement layer, a thinner decorative layer can achieve satisfactory fatigue performance.
It is clear that the decorative layer can be made in any shape, for example square, rectangular or hexagonal. In this preferred embodiment, the floor element is rectangular and oblong and is preferably provided with a wood grain print depicting wood grain lines extending in the longitudinal direction of the rectangular decor layer as a whole. Preferably, the supporting layer has a shape substantially corresponding to the decorative layer, however, preferably, the one or more portions extend beyond the decorative layer and the one or more recesses extend below the decorative layer. The support layer is preferably an adhesive element, wherein the support layer preferably covers a substantial part, i.e. at least 50%, of the lower surface of the decorative layer. Preferably, the support layer covers 80% or more of the lower surface of the decorative layer. According to a variant, the supporting layer comprises a plurality of separate adjacent supporting layer portions, in which case said plurality of supporting layer portions preferably covers at least 50% of the lower surface, or even 80% or more of the lower surface thereof.
According to a first aspect of the invention, the flooring element comprises a reinforcement layer arranged between the decorative layer and the supporting layer. Such an enhancement layer may be implemented according to a number of possibilities, two preferred possibilities being described herein below.
According to a first possibility, the reinforcement layer comprises a layer of glass fibers, such as a glass fiber mat, a glass fiber fleece or a glass fiber cloth. In combination with or instead of glass fibres, the reinforcement layer may comprise carbon fibres, polymer fibres, such as aramid or polyamide fibres, or ceramic fibres, such as boron or silicate fibres. The reinforcing layer may comprise woven or non-woven fibers, for example, having fibers arranged in different orientations. The reinforcing layer may also comprise a plurality of fibrous layers overlapping each other, for example with fibres arranged in different orientations in each layer. The fibrous layer provides a rigid reinforcement layer, increasing the rigidity of the decorative layer, limiting the propagation of cracks in the decorative layer itself.
According to a second possibility, the reinforcement layer comprises a metal plate, for example a steel plate. Preferably, the metal plate is configured to establish a compressed state in the decorative layer. Thus, since the decorative layer is in a compressed state, the impact resistance is greatly improved since the compression retards the propagation of cracks and helps to mask the visual effect of surface cracks. To achieve this, the metal sheet is first stretched, for example by means of mechanical or thermal stretching, and then bonded to the decorative layer while the metal sheet is in the stretched state. Subsequently, the stretching is released by interrupting the mechanical stretching or by cooling the metal sheet itself, so that a state of compression is established in the decorative layer.
According to a preferred embodiment the coefficient of thermal expansion of the metal plate is higher than the coefficient of thermal expansion of the decorative layer. With this solution, the reinforcement layer is heated to a stretched state, then bonded to the decorative layer while the reinforcement layer is still in the stretched state, and then cooled to retract and place the decorative layer in a compressed state.
In a preferred embodiment, the metal sheet is a steel sheet, preferably having a thickness of between 0.1 and 1mm, for example 0.2 mm.
The inventors have found that an impact resistance of about 3.09Nm (equivalent to a ball falling from a height of 1397 mm) and extra-heavy commercial robinson test results can be achieved according to an embodiment of the second possibility. With this solution, tiles with standard thickness can be used for floating floor coverings.
The inventors have found that surprisingly good results can be obtained with such a metal sheet even with a relatively thin ceramic decorative layer. For example, the decorative layer may be less than 15mm, more preferably less than 12 mm. However, the thickness of the decorative layer is preferably at least 7 mm. With such thickness values, excellent impact resistance can be obtained even with a mechanical connection between the floor elements. For example, an impact resistance of about 3.09Nm (equivalent to a ball falling from a height of 1397 mm) and extra-heavy commercial Robinson test results can be obtained. A further advantage is that for the decorative layer, tiles of standard thickness can be used, for example tiles of 10mm thickness. Furthermore, no additional layers are required to achieve good impact resistance. For example, no intermediate layers are required, except for non-structural layers such as adhesive layers between the decorative layer and the metal sheet and/or between the metal sheet and the support layer. Thus, the total thickness of the floor element may be limited. In a preferred construction, the decorative layer is bonded directly to the metal plate and the metal plate is bonded directly to the support layer.
In general, the reinforcement layer is preferably made of a material exhibiting a young's modulus higher than that of the decorative layer (e.g., twice or three times the young's modulus of the decorative layer). In this way, a reinforcement layer is provided which increases the rigidity of the decorative layer to define a barrier to crack propagation.
Preferably, the reinforcement layer is bonded to the decorative layer and/or the support layer by means of an adhesive layer (e.g. glue). Preferably, the reinforcement layer is bonded directly to at least the lower surface of the decorative layer.
It is noted that the reinforcement layer does not have to be arranged directly between the decorative layer and the supporting layer. In other words, one or more further intermediate layers may be provided together with the reinforcement layer between the decorative layer and the reinforcement layer and/or between the reinforcement layer and the support layer.
For example, the flooring element may comprise an intermediate layer arranged between the reinforcement layer and the supporting layer or between the reinforcement layer and the decorative layer. Preferably, the intermediate layer is disposed between the reinforcing layer and the support layer. The inventors have found that by arranging such an intermediate layer in combination with a reinforcement layer, the reinforcement effect is enhanced, thereby further improving the impact and fatigue strength of the floor element. The inventors have also found that the use of an intermediate layer in combination with a reinforcing layer can reduce the thickness of the decorative layer.
For example, it has surprisingly been found that the impact resistance of a thin tile (such as a tile having a thickness of 6mm or less) can be significantly enhanced by laminating a reinforcing layer (such as a glass fibre layer) on the back of the tile and laminating an intermediate layer (such as a second tile, which preferably has the same or about the same thickness as the decorative layer) to the reinforcing layer.
The intermediate layer may be made of the same or similar material as the decorative layer. For example, in a preferred embodiment, the intermediate layer is made of a ceramic body or another brittle material (such as one of the materials listed at the beginning of the present application). The inventors have found that an intermediate layer made of the same material as the decorative layer is sufficient to exceed the standard strength of conventional floorings.
It is possible that the intermediate layer is made of a material of lower quality than the decorative layer, for example, the intermediate layer is essentially made of a non-decorative ceramic plate, a non-smooth natural stone, a recycled ceramic plate or a ceramic plate made of a mixture of raw materials (including a large amount of waste or scrap, such as household, demolition, industrial or waste).
Preferably, the intermediate layer has the same thickness as the decorative layer. It is clear that the thickness of the intermediate layer can be greater or less than the thickness of the decorative layer.
Preferably, the reinforcing layer and, if present, the intermediate layer have substantially or exactly the same shape and horizontal dimensions as the decorative layer. Furthermore, the decorative layer overlaps the reinforcing layer and, if appropriate, the intermediate layer in order to cover and conceal the reinforcing layer.
The intermediate layer may be bonded to the reinforcing layer by means of an adhesive layer, such as glue, and to the support layer or the decorative layer.
The glue used to bond the various elements of the flooring element together may be an epoxy glue, a hot melt glue or a polyurethane based glue.
The inventors have found that it is particularly advantageous to use an intermediate layer if a glass fibre layer is used as the reinforcing layer. Very good results in terms of the impact resistance of the mechanically joined floor element are obtained if a glass fibre layer is provided between two tiles. The inventors have found that with this solution an impact resistance of 3.37Nm (equivalent to a ball falling from 1524 mm) can be achieved. This is also true when both the decorative layer and the intermediate layer have a thickness of 6mm or less. Thus, with this solution it is possible to use thin tiles as floating floor covering, while having extremely high impact and/or fatigue strength values. In one preferred construction, the fiberglass layer is bonded directly to the ceramic decorative layer and to the ceramic intermediate layer, and the intermediate layer is bonded directly to the support layer. Direct bonding can be carried out by means of adhesives or glues.
According to a preferred embodiment of the invention, the supporting layer is made of a material different from the material of the decorative layer. More particularly, the supporting layer is preferably made of a material suitable for being provided with coupling elements and/or of a waterproof material and/or of a compressible material.
In a first possibility, the support layer is made of a polymeric material. Polymeric materials have good mechanical properties while having relatively low cost and low weight, and further, they provide an impermeable and sound-reducing support layer.
Preferably, the support layer is made of a thermoplastic polymeric material, preferably having a glass transition temperature (Tg) lower than 100 ℃, for example PVC (polyvinyl chloride) or polyurethane, more particularly thermoplastic polyurethane. Forming the support layer from a material having a relatively low glass transition temperature results in the support layer being susceptible to compression at room temperature. Compression is desirable in many respects. For example, possible thermal expansion of the supporting layer can be partially or completely suppressed by a more rigid or harder decorative layer and/or reinforcing elements that hold the material of the supporting layer in its original dimensions. Compression is also interesting for the design of the coupling element and allows a certain adaptation to the unevenness of the sub-floor, which in turn prevents air spaces between the supporting layer and the sub-floor, which would amplify walking noise.
In a preferred embodiment, the support layer is made of rigid or flexible PVC, wherein the rigid PVC comprises an amount of plasticizer of less than 15phr and the flexible PVC comprises an amount of plasticizer of 15phr or more, preferably more than 20 or more than 25 phr. The support layer may also comprise a substantial amount of filler material, such as chalk, for example more than 30 wt% or more than 60 wt% of such filler material. The filler increases the weight of the supporting layer and makes the supporting layer very effective in eliminating the transmission of walking sounds to lower places. Rigid PVC provides a support layer with good dimensional stability when exposed to temperature changes. In other words, the expansion of the supporting layer is limited when exposed to high temperatures, thereby providing good floor stability. The support layer made of flexible PVC has a lower dimensional stability but is more compressible, so its tendency to expand will be at least to some extent inhibited by the decorative layer and/or the reinforcing element.
According to a variant, the support layer, made of flexible PVC or of any other material (whether thermoplastic or not), can be designed to compensate for dimensional variations due to temperature variations. For example, the supporting layer may be formed by a plurality of separate elements (e.g., strips), or may include grooves that separate adjacent portions of the supporting layer, thereby allowing expansion of the portions without affecting the overall stability of the floorboard.
In a second possibility, the support layer is made of fiber cement. The inventors have found that with this solution the floor element has a high impact strength and fatigue strength and a high thermal stability, so that the floor element does not expand or contract significantly when exposed to temperature changes.
Furthermore, the thickness of the support layer is preferably between 2 and 7mm, preferably 6mm, more preferably about 3 or less. For example, a preferred embodiment of the invention provides a support layer made of PVC with a thickness of 3mm, thus representing a good solution in terms of thermal stability, noise reduction, low weight and low cost. An alternative embodiment provides a support layer made of fiber cement with a thickness of 6mm, providing very good thermal stability.
Thus, the thickness of the floor element is less than 20mm, preferably 18mm or less, more preferably 13mm or less. In this way the resulting floor element is relatively thin, thereby reducing the environmental impact of the floor, especially in the case of renovation of existing floors. Furthermore, in this way the weight of the floor element is limited, thereby making packaging, transport and assembly easier.
As mentioned before, the supporting layer comprises a rim with coupling elements. The coupling element is configured to effect a mechanical coupling with the coupling element of an adjacent floor element. Under "mechanical coupling" coupling is understood to allow adjacent floor elements to be coupled without glue or the like. The mechanical coupling can be achieved by means of a profiled edge profile comprising coupling elements, mainly male and female parts, cooperating with each other.
The coupling element preferably comprises at least one male part and at least one female part, wherein in the connected state of two such floor elements such male and female parts have been engaged with each other. The male and female parts are preferably formed at least partially in the support layer. For example, the male part and/or the female part may be integrally formed in the support layer.
Preferably, the at least one male part is located at a first edge of the floor element and the at least one female part is located at a second, opposite edge of the floor element. Preferably, the male part projects outwardly from its respective edge in a horizontal direction so as to form a protrusion at said edge, and the female part preferably extends inwardly from its respective edge in a horizontal direction so as to form a recess at said edge. The male part and the female part engage each other in the connected state of two similar floor elements to establish a mechanical coupling between the respective edges, preferably creating a locking between the edges in at least all horizontal directions in the plane of the assembled floor elements. According to a particular embodiment, the engagement of the male part and the female part creates a locking between the respective edges at least in a vertical direction perpendicular to the plane of the assembled floor element.
The coupling element is preferably configured to allow coupling by means of movement of one floor element relative to another adjacent floor element. Such movement may be a translational movement in a downward (e.g. vertical) direction, a translational movement in a horizontal direction (e.g. perpendicular to the edge) or a tilting movement about a horizontal axis parallel to the edge. It is clear that a corresponding movement then preferably results in the above-mentioned male and female parts of adjacent floor elements engaging each other.
Preferably, the coupling element is configured such that the floor element can be disassembled by means of an upward (e.g. vertical) translational movement. In order to allow a smooth detachment, the coupling element is preferably at least partially or completely integrally provided in a support layer made of a flexible material (for example made of a thermoplastic material with a Tg below 100 ℃), preferably made of soft PVC. Such a material will provide sufficient flexibility for the coupling elements to become uncoupled even if some part of the coupling elements is underneath one or more adjacent floor elements. By this solution, individual floor elements of the floor can be removed from the floor covering for replacement without having to remove adjacent floor elements, so that the floor elements are easier to replace by the preferred embodiment of the invention.
As used herein, the terms "horizontal" and "vertical" are expressed substantially in relation to a floor covering that fits over a surface that is considered horizontal in its ordinary sense. Thus, when used in relation to a single floor element, which is a substantially flat element provided with a main plane, the terms "horizontal" and "vertical" should be considered equivalent to the terms "parallel with respect to the main plane of the floor element/fitted floor element" and "perpendicular with respect to the main plane of the floor element/fitted floor element", respectively.
In general, the coupling element may be constructed in various ways. In the following, two general possibilities for their construction are described, without excluding any other possibilities that also fall within the scope of the invention.
In a first general possibility for constructing the coupling element, the male part and the female part extend over a limited length portion of the relative edge, wherein this limited length is less than the entire length of the relative edge itself, preferably less than half the length of the relative edge. According to this possibility, the edge preferably comprises a section devoid of the male part and the female part. Alternatively, the male and female elements may alternate along the edge. Preferably, at said edges, the decorative layer is supported by the supporting layer at least over 30% of the length of the relevant edge. In this way, the risk of the brittle material failing in the packaging or at the time of assembly is reduced. According to a first possibility at hand, each edge may comprise one or more male parts and/or one or more female parts. Preferably, the male part and the female part are arranged along such edges, so that at the option of the fitter the floor element can be fitted in several patterns, such as a regular flank pattern, a herringbone pattern and/or an offset pattern, such as a half offset pattern or a third offset pattern. Preferably, the male part and/or the female part are arranged on the same edge symmetrically, mirror-symmetrically or parallel-symmetrically with respect to the midpoint of said edge. In case of assembly in a half-half pattern, the male and/or female parts are preferably arranged in the same way along both halves of the respective edge. In case of fitting in a one-third offset pattern, the male and/or female parts are preferably arranged in the same way along all three thirds of the respective edge. As mentioned above, in an alternative embodiment, the male and female elements alternate with each other on the same edge.
According to a first possibility, the geometry for the coupling parts comprises mating male and female parts, which are dovetail-shaped in plan view, or male and female parts similar to the connection of a jigsaw puzzle in plan view.
In a second general possibility for constructing the coupling part, the male part and the female part may be provided along substantially the entire length of the relevant edge, for example, substantially defining the relevant edge. For example, according to this embodiment, the male and female parts may be shaped as a tongue and groove extending substantially the entire length of the associated mutually opposing edges.
Preferably, the floor element comprises a male part and/or a female part having a common geometry on all edges thereof, thereby allowing several assembly solutions. It is clear that the floor element can comprise male parts and/or female parts with different geometries on the same edge or on different edges according to different embodiments of the invention. For example, the floor element may comprise male parts and/or female parts having different shapes or different sizes on different edges. For example, a rectangular floor element may comprise a first male and/or female part having a first shape on a long edge and a second male and/or female part having a second shape on a short edge. By this solution, the floor elements can only be assembled according to a specifically selected pattern, thereby obtaining a specifically selected visual effect of the floor and minimizing the occurrence of assembly errors.
In the coupled condition of two of said adjacent floor elements, said coupling elements cooperate and preferably form locking surfaces limiting the mutual movement of said floor elements in the vertical and/or horizontal direction.
For example, the locking surface may comprise a first locking surface adapted to limit mutual movement of the floor elements along the coupling edge. By this solution, once the floor elements are coupled, they cannot be made to slide relative to each other, thereby making the fitting of the floor covering easier. This is especially true when a pattern in the floor covering is desired, such as a checkerboard pattern or a semi-offset pattern. Preventing or limiting mutual movement of the floor elements alongside one another at a first pair of edges is also important in the assembled floor covering, as this may help to maintain a connection between a second pair of edges (e.g. perpendicular to the first pair of edges) of adjacent floor elements.
According to a preferred embodiment, said first locking surface is formed by the engagement of a male part to a female part. According to this example, the first locking surfaces are preferably formed at least by surfaces delimiting the male part and the female part in the horizontal direction along the coupling edge, or in other words, the first locking surfaces are preferably formed at least such that they or their extensions intersect the coupling edge.
Preferably, in the coupled condition of two adjacent floor elements, a second locking surface is formed which limits the mutual movement of the floor elements in a direction perpendicular to the coupling edge and in a substantially horizontal plane. Preferably, the second locking surface is formed by the engagement of the male part to the female part. Preferably, the second locking surface is formed at least by surfaces delimiting the male part and the female part in a horizontal direction perpendicular to the respective edges. This second locking surface may be formed according to a number of possibilities, of which three possibilities are described in detail below.
In a first possibility for constructing the second locking surface, the second locking surface coincides with the first locking surface, in which case these surfaces have a normal oriented at an angle to the direction of the respective edge, wherein this angle is smaller than 90 °, preferably between 20 ° and 70 °. In particular, according to this preferred embodiment of the invention, the first locking surface and the second locking surface are formed by the engagement of the male part to the female part and are both formed by surfaces delimiting the male part and the female part in a direction along the coupling edge, or in other words, said first and second locking surfaces are formed at least by surfaces which intersect said coupling edge by themselves or by their extension. According to this preferred example, the male and female parts may have a profile that tapers towards their associated edges, as seen in a top plan view. For example, the male and female parts may be dovetail-shaped as seen in top plan view, or may show two opposite sides when viewed in the direction of the edges (which are planar and/or curved) and converge towards each other towards the relevant edge. In this way, in the coupled state of the male part and the female part, the first and second locking surfaces are formed on the tapered or converging sides. It is clear that according to such an embodiment, the male part may be shaped as a dovetail-shaped protrusion on the relevant edge, while the female part may be shaped as a matching recess on the opposite edge of the floor element.
In a second possibility for configuring the second locking surface, the second locking surface is different or separate from the first locking surface. According to a second possibility, the second locking surface can be formed at least by a surface delimiting the male part and the female part in a direction substantially perpendicular to the coupling edge. For example, according to the described embodiment, the male and female parts may be T-shaped in top plan view, with the head of the T forming the male part and engaging at the rear of the female part. According to another embodiment, the male part may be provided with one or more barbs which engage at the rear part of the female part. Alternatively, according to a third possibility, the second locking surface may be formed by a vertical protruding portion and a vertical recessed portion engaging behind each other. For example, in case the coupling part is substantially shaped as a tongue and a groove, the tongue may be provided with a downward protrusion and the groove may be provided with a recess cooperating therewith.
The coupling element may be configured such that in a coupled condition of two adjacent floor elements only one set of said first and/or second locking surfaces is formed for limiting a mutual movement of said floor elements in one substantially horizontal direction perpendicular to and/or along the coupling edge, although it is preferred that in said coupled condition at least two sets of said first and/or second locking surfaces are formed, wherein said sets limit a movement in mutually opposite horizontal directions perpendicular to and/or along the coupling edge. By this solution the coupling element is easily and conveniently shaped to limit movement in substantially all horizontal directions, thereby providing a firm lock between the tiles.
Furthermore, the coupling element preferably comprises a vertical locking element configured such that in the coupled state of two adjacent floor elements a third locking surface is formed, limiting the mutual movement of said floor elements in a substantially vertical direction. By this solution, the floor elements can be assembled smoothly without unacceptable height differences between adjacent floor elements. Furthermore, the floor elements are firmly coupled to each other to improve the fatigue properties of the floor covering. Furthermore, by limiting the relative movement of the floor elements, the effect of step noise, i.e. the noise generated per step, can be reduced.
Preferably, the vertical locking elements are provided along substantially the entire length of the coupling edge, although they may extend over only a limited portion of said coupling edge, for example only where a male or female part is present.
In particular, the third locking surface may be formed by at least an upwardly facing surface positioned on one of the joined floor elements and a downwardly facing surface on the other joined floor element cooperating therewith. In other words, the third locking surface is arranged on a surface or plane which is substantially horizontal or inclined with respect to the horizontal plane and forms an angle with the horizontal plane which is smaller than 90 °, preferably smaller than 70 °, more preferably smaller than 50 °, such as 15 ° or smaller, or 0 °, in other words horizontal.
The third locking surface may be constructed according to several different possibilities, three of which are briefly described herein below.
According to a first possibility, the vertical locking element comprises a hook-shaped element having a first portion extending from its respective edge in a substantially horizontal direction and a second portion extending downwards from the first portion in a substantially vertical direction. The hook-shaped element further comprises a protruding portion placed on the second portion, the protruding portion being shaped to define at least one upwardly facing surface adapted to cooperate, in use, with a downwardly facing surface provided on an adjacent floor element, thereby forming said third locking surface. For example, the downwardly facing surface is provided in the form of a chamfered lower edge of the support layer, such that it defines an abutment surface for the protruding part of the hook-shaped element.
The hook-shaped element may be positioned at least partially on the male part, on the female part or on a section next to an edge of the male part or female part, or may be provided on the male part or female part and on the section next to the male part or female part. Preferably, the hook-shaped element is arranged on a section next to the edge of the male part or the female part, preferably on a side of the male part substantially parallel to the coupling edge.
According to a second possibility, the male part protrudes outwardly beyond the upper edge of the decorative layer, while the female part extends inwardly beyond the upper edge of the decorative layer, thereby forming an undercut below the decorative layer, so that a third locking surface may be formed at least by the top surface of the male part and the upper surface of the undercut formed by the female part, preferably the bottom surface of the decorative layer delimiting the undercut in an upward direction.
According to a third possibility, the third locking surface may be formed by at least the mating surface on the bottom of the male part and the part of the female part that mates therewith, for example the upwardly facing surface of the female part. This third possibility can be achieved by means of an embodiment which also exhibits the features of the first possibility, wherein a hook-shaped portion is available at the female part, and wherein the second portion of the hook forms the upwardly facing surface.
In a preferred embodiment, the vertical locking elements are such that in the coupled condition of two floor elements two sets of third locking surfaces are formed, wherein the sets restrict movement in mutually opposite vertical directions, although it is possible to form only one set of third locking surfaces restricting movement in only one vertical direction. In this way, relative movement of the floor elements in the vertical direction is substantially prevented. Furthermore, in this way a good vertical relationship is obtained between adjacent floor elements. This solution may further lead to a reduction of step noise. In a preferred embodiment, the two sets of third locking surfaces lie in planes which are inclined, preferably orthogonal, to each other.
The two sets of third locking surfaces can be obtained in many different ways, the first and second possibilities being described herein below.
According to a first possibility, the third set of locking surfaces limiting the movement in vertical directions opposite to each other are arranged in sequence, preferably alternately one after the other in the direction along the coupling edge. In other words, a third set of locking surfaces limiting the movement in vertical directions opposite to each other is available on the subsequent portion of the coupling edge. It is not excluded that such portions may partially overlap. For example, the first edge is provided with a hook-shaped element on the male part and has a chamfered lower edge on a section next to the edge of the male part, while the opposite second edge is provided with a hook-shaped element on a section next to the edge of the female part and the female part is provided with a chamfered lower edge, so that in a coupled state of the floor element with an adjacent similar floor element, two sets of third locking surfaces are formed along the same coupling edge. By this solution, a very simple design of the vertical locking element can be used, allowing to reduce the thickness of the support element. The inventors have found that with this solution the lower support element may exhibit a thickness of between 2 and 4mm, for example a thickness of 3mm or less.
Preferably, the first set of third locking surfaces is located on a first line parallel to the coupling edge and the second set of third locking surfaces is located on a second line parallel to the coupling edge, and the first and second lines are different in a horizontal plane. For example, a first set of third locking surfaces is formed by the engagement of the male part with the female part, while a second set of third locking surfaces is formed by the engagement of sections of the edge alongside the male part with sections of the edge immediately adjacent to the female part. With this solution the floor element can easily be manufactured with two sets of third locking surfaces. In fact, on a single floor element, the upwardly facing surfaces of the first group can be manufactured by means of a specific process different from the process of manufacturing the facing surfaces of the other group. For example, on a first edge of a floor element, two different milling processes can be used, wherein these milling processes can be carried out simultaneously and act on different parallel lines in order to produce hook-shaped elements and chamfered edges.
According to a second possibility, the two sets of third locking surfaces can be arranged one after the other in a substantially vertical direction, or in other words present in one and the same cross section taken along the respective edge. For example, the male part is in the form of a tongue and the female part is in the form of a groove, and the two sets of third locking surfaces are formed at least by a bottom surface of the tongue cooperating with an upwardly facing surface of the groove and an upper surface of the tongue and cooperating with a downwardly facing surface of the groove, respectively. Alternatively, according to said second possibility, the hook-shaped elements are arranged below the upper edge of the floor element, so that a C-shaped recess is formed between the protruding portion and the upper edge of the hook-shaped elements (e.g. between the protruding portion of the hook-shaped elements and the lower surface of the decorative layer), so that in the coupled state the chamfered edges of adjacent floor elements are at least partially inserted into the C-shaped recess, thereby forming two sets of third locking surfaces. In particular, the first set of third locking surfaces is formed by the protruding portions of the hook-shaped elements cooperating with the chamfered edges, while the second set of third locking surfaces is formed by the upper surface of the supporting layer provided with the chamfered edges and the upper surface of the C-shaped recess (e.g. the lower surface of the decorative layer).
The first, second and/or third locking surfaces may comprise portions on the resilient arms. Such resilient arms may be adapted to flex when floor elements are coupled together. In a special embodiment, the resilient arm maintains the bent position in the coupled state. In the latter case, the resilient arms may exert a reaction force which forces the floor elements towards each other, thereby limiting the relative movement of the floor elements in the vertical direction and/or in one or more horizontal directions. The spring arm can be arranged both on the male part and on the female part and on the edge section next to the male part and the female part. By means of the resilient arms, the floor elements can be coupled more easily and/or can be coupled firmly to each other to improve the fatigue properties of the entire floor. Furthermore, the resilient arms may bend after thermal expansion of the associated coupling elements of adjacent floor elements, thereby allowing thermal expansion of the floor elements without affecting the stability of the floor.
Preferably, the first and/or second locking surface comprises a portion on the first resilient arm and the third locking surface comprises a portion on the second resilient arm. According to one embodiment, the first resilient arm extends substantially in a horizontal plane and is adapted to bend in said horizontal plane. The first resilient arm may delimit the male part and/or the female part in a direction along the coupling edge. For example, in a preferred embodiment, the female part comprises two first resilient arms delimiting, in two mutually opposite horizontal directions along respective edges, a recess forming the actual female part itself. Preferably, the second resilient arm extends in a substantially vertical direction and is adapted to bend in a substantially horizontal direction. For example, the second elastic arm at least partially delimits said coupling element in a direction substantially perpendicular to the relative edge. In a preferred example, the hook-shaped element, and more particularly the second portion of the hook-shaped element, substantially defines such second resilient arm. It is of course not excluded that the first and/or second locking surface comprises portions on the same resilient arm.
Preferably, in the coupled condition of two of said floor elements, there is an intermediate distance between the respective upper edges of adjacent floor elements. Preferably, the decorative layer is fitted on the supporting layer in the following manner: when the floor elements are in the coupled condition, said intermediate distance is present between the edges of adjacent decorative layers, while the edges of the underlying supporting layer are coupled to each other by means of the available coupling elements. By this solution, minor dimensional variations of the decorative layers of adjacent tiles can be tolerated. In case the decorative layer is formed by one or more tiles, unrefined tiles may be chosen. Even if a rectification tile is selected, the intermediate distance is preferably at least 1.5 mm. Generally, for a brittle decorative layer, it is desirable to prevent direct contact between the edges of the decorative layer of adjacent floor elements to minimize the risk of breaking the edge portions upon assembly or upon use of the floor covering. Preventing direct contact between the edges of the decorative layer also prevents squeaking while walking on the floor. Additionally, some decorative layers and/or support layers may expand or contract due to thermal changes. The available intermediate distance prevents such expansion and contraction from affecting the stability of the floor.
The intermediate distance or gap between the decorative layers of adjacent floor elements can be further accomplished in several possible ways.
According to a first possibility, the intermediate distance between the floor elements may be filled with mortar, thereby providing an impermeable floor covering. Preferably, a polymeric grout is used.
In a second possibility, the decorative layer may be at least partially, preferably completely, surrounded by the gasket, such that in the coupled state of two adjacent floor elements the gasket is compressed by the decorative layer of the adjacent floor elements, thereby forming a substantially watertight connection between the floor elements.
It is noted that the characteristic feature of the floor element comprising a coupling element, in that in the coupled state of the floor element with an adjacent floor element a first, a second and a third locking surface for limiting the relative movement of the floor elements are formed, forms an inventive idea independent of the presence or absence of the decorative layer, in particular independent of the material constituting the decorative layer. Thus, according to a second independent aspect of the invention, the invention provides a floor element for forming a floor covering, wherein the floor element comprises an edge provided with coupling elements adapted to cooperate with coupling elements of adjacent similar floor elements in the floor covering, wherein the coupling elements comprise at least one male part and at least one female part, wherein, in a coupled condition of two of the adjacent floor elements, a first locking surface for limiting a mutual movement of the floor elements along the coupling edges, and a second locking surface for limiting a mutual movement of the floor elements in a substantially horizontal direction and a direction perpendicular to the coupling edges, and a third locking surface for limiting a mutual movement of the floor elements in a substantially vertical direction are formed, wherein, in the coupled condition two sets of third locking surfaces are formed, wherein said sets restrict movement in mutually opposite vertical directions. The inventors have found that with this solution the floor elements can be firmly coupled to each other, thereby forming a floor covering with good fatigue properties. Furthermore, by preventing relative movement of the floor elements, the effect of step noise, i.e. the noise generated per step, can be reduced.
It is clear that, as mentioned in the first aspect, the coupling element and the first, second and third locking surfaces are preferably formed according to a preferred embodiment of the first aspect of the invention, although the flooring element does not necessarily have to be provided with a decor layer and/or a supporting layer.
According to a third independent aspect of the present invention, there is provided a floor covering comprising a plurality of adjacent floor elements, wherein each floor element comprises a decorative layer of a ceramic material and a supporting layer arranged below the decorative layer, wherein the floor covering comprises a combination of the following features: at least one flooring element comprises a reinforcing layer between the decorative layer and the supporting layer; the floor element comprises a coupling device configured to enable coupling with a coupling element of an adjacent floor element; the floor covering comprises mortar which fills the intermediate distance separating the decor layers of the floor elements. Preferably, the flooring elements are separate from the secondary surface, e.g. the sub-floor, i.e. they are not bonded to the secondary surface by means of an adhesive or mechanical means. By this solution a floor covering is provided consisting of floor elements which are assembled without the use of adhesives, which exhibit satisfactory impact and fatigue strength and which are completely impermeable. By means of a third aspect, the inventors finally provide a solution to the long felt need in the art of ceramic flooring. They provide tile flooring that is easy to assemble and has good impact strength and water resistance. It is clear that the floor element of the first aspect and preferred embodiments thereof can be used to form a floor covering according to the third aspect of the invention.
According to a preferred aspect of the invention, the floor covering comprises a sub-layer arranged below the floor elements, which sub-layer is configured to act as a moisture barrier. By this solution, it is possible to prevent the formation of a mould under the floor element. In conjunction with this solution or as an alternative to this solution, the underlayment may be configured to act as a sound barrier, thereby reducing noise generated by footsteps on the floor.
Drawings
In order to better illustrate the characteristics of the invention, several preferred forms of embodiment are described below, by way of example without any limiting characteristics, with reference to the accompanying drawings, in which:
FIG. 1 illustrates an embodiment of a flooring element of the present invention;
FIG. 2 shows a perspective view of a floor covering formed by a plurality of floor elements according to FIG. 1;
fig. 3 shows a cross-section along the line III-III of fig. 1 on a larger scale;
fig. 4 shows a view of the region F4 shown in fig. 3 on a larger scale;
fig. 5 shows a floor element according to a variant of the invention in the same view as fig. 3;
fig. 6 shows a top plan view of the floor element of fig. 1 on a larger scale, wherein the decorative layer is represented by a dashed line;
fig. 7 shows the bottom view of fig. 6 on a larger scale;
FIGS. 8 to 11 show, on a larger scale, cross-sections along the lines VIII-VIII, IX-IX, X-X and XI-XI, respectively, shown in FIG. 6;
figures 12 and 13 show views, on a larger scale, of the regions F12 and F13 shown in figure 6;
FIG. 14 is a top view of the floor covering assembled from the floor elements of FIG. 1, wherein the decorative layer of the floor elements is shown in phantom;
FIGS. 15 and 16 show, on a larger scale, cross-sections along the lines XV-XV and XVI-XVI, respectively, of FIG. 14;
fig. 17 shows a view on a larger scale of the region F17 shown in fig. 14;
figure 18 shows, on a larger scale, a cross section along the line XV-XV of figure 14 during a coupling movement of the floor elements according to a variant of the invention;
figures 19 to 24 present, on a larger scale, views of the area indicated with F19 in figure 14 for variants of male and female parts;
FIG. 25 is a top view of a variation of the support layer;
figures 26 to 28 give views of the area indicated with F26 in figure 25 for variants of male and female parts;
fig. 29 is a top view of a floor element according to a variant;
FIG. 30 shows a cross-section along line XXX-XXX of FIG. 29 on a larger scale;
fig. 31 shows a cross-section of the coupled state of two floor elements according to fig. 29; and
fig. 32 shows a variant in a view similar to that of fig. 17.
Detailed Description
Fig. 1 shows a
Referring to fig. 1, 3 and 4, the
As can be seen from fig. 4, the
In the example shown in fig. 4, the
In the embodiment shown in fig. 1, 3 and 4, the
Referring to fig. 15 and 16, the floor covering 2 comprises an
As can be seen from fig. 3, the
By way of example, in the present embodiment, the
In the preferred embodiment shown in fig. 1, 3 and 4, the
Fig. 5 shows a different embodiment of the invention, wherein the
According to this alternative embodiment, the
The
Preferably, in the alternative embodiment of fig. 5, the
As can be seen for example from fig. 1 and 3, the
Referring now to fig. 6 and 7, the supporting
In this embodiment the
In the present embodiment, the
For example, the thickness C of the
As is clear from fig. 6 and 7, the
The
As is clear from fig. 3, 6 and 7, the
For example, in the preferred embodiment shown in fig. 6 and 7, and as shown in fig. 15 and 16, said
As shown in fig. 6, the
Furthermore, in the preferred embodiment shown in fig. 6 and 7, the
Fig. 12 and 13 show the
In the coupled condition of two of said neighbouring
In the present embodiment, with particular reference to fig. 14 and 17, the
Preferably, in said coupled condition of the
As shown in fig. 17, said first and second locking surfaces 21, 22 are formed by engaging the
Fig. 17 also shows that in the coupled state a
With particular reference to fig. 8 to 11, 15 and 16, the
In particular, said
In this embodiment, the
Fig. 18 shows an embodiment wherein the portion of the
In this embodiment, as is clear from the cross-sections of fig. 6 shown in fig. 6, 7 and 8 to 11, the hook-shaped
In this embodiment, the hook-shaped
In the embodiment shown in fig. 15 and 12, the
As can be seen from fig. 15, the first set of third locking surfaces 27 is formed by the upwardly facing
As can be seen in fig. 15, the two
Fig. 16 shows the cross section of fig. 14, wherein only one set 28 of third locking surfaces 27 is formed, which serve to limit the movement in only one vertical direction Z. The
Fig. 19 to 23 show different examples of
Fig. 25 and 26 to 28 show different embodiments, wherein the
The first
For example, fig. 25, 26 and 27 show an embodiment in which the
The
The
Fig. 29 to 31 show an alternative embodiment of the invention, in which the
Fig. 31 shows that in the coupled state of two
In this example, the
In this alternative embodiment, the two
In this embodiment, the
The invention is in no way limited to the embodiments described above, but such floors, floor coverings and floor elements can be realized according to different variants without departing from the scope of the invention.
Furthermore, as is clear from the content of the description, the invention relates to one or more of the following listed numbers from 1 to 50:
1. a
2. The
3. The
4. The
5. The
6. The
7. The
8. The
9. The
10. The
11. The
12. The
13. The
14. The
15. The
16. The
17.
18. The
19.
20. The
21.
22. The
23. The
24.
25.
26. The
27.
28.
29. The
30.
31.
32.
33. The
34. The
35. The
36. The
37. The
38.
39. The
40. The
41.
42.
43.
44. A floor covering 2 comprising a plurality of
at least one of the
the
the floor covering 2 comprises
45. The floor covering 2 of claim 44, wherein the floor covering 2 comprises a underlay layer below the
46. The floor covering 2 of any of
47. The floor covering 2 of any of claims 44 to 46, wherein the
48. The floor covering 2 of any of claims 44 to 47, wherein the
49. The floor covering 2 according to any of claims 44 to 48, wherein the
50. The floor covering 2 according to any of the claims 44 to 49, wherein the
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