• 专利附录
  • 专利说明
  • 权利要求
  • 类似技术
  • 同族专利
  • 引用文献
  • 法律状态
  • 优先权
    • 专利摘要:
    The tile cladding system (1) includes a mounting plate (4) and a number of tile elements (2). Each tile element has a front side (7) adapted to face away from a building surface and a back side (8) adapted to be connected to a front side (5) of the mounting plate. The front side of the mounting plate and the back side of each tile element are provided with a number of protrusions (9) and/or indentations (10) in such a way that protrusions may fit into indentations in order to form a snap-fit or friction fit connection. The mounting plate is provided with a number of transverse grooves (11) extending in a transverse direction (T) and being mutually spaced in a longitudinal direction (L) of the mounting plate, and the transverse grooves have such a configuration that the mounting plate is able to bend.
    公开号:DK201770666A1
    申请号:DKP201770666
    申请日:2017-09-05
    公开日:2019-03-20
    发明作者:Munck Thomsen Lars
    申请人:Click'n Tile Aps;
    IPC主号:
    专利说明:

    TILE CLADDING SYSTEM AND METHOD FOR MOUNTING TILE ELEMENTS ON A BUILDING SURFACE
    The present invention relates to a tile cladding system for mounting tile elements on a building surface, including a mounting plate and a number of tile elements, the mounting plate having a longitudinal direction, a transverse direction, a front side adapted to carry the tile elements and a back side adapted to be attached on the building surface, each tile element having a front side adapted to face away from the building surface and a back side adapted to be connected to the front side of the mounting plate, the front side of the mounting plate being provided with a number of protrusions and/or indentations and the back side of each tile element being provided with a number of protrusions and/or indentations corresponding to respective protrusions and/or indentations of the mounting plate in such a way that protrusions may fit into indentations in order to form a snap-fit or friction fit connection.
    DE 40 26 472 A1 discloses a tile cladding system including a layer of artificial material bonded to the rear face of a tile. Within this artificial layer, cylindrically shaped recesses are formed. These recesses are matched by cylindrical extrusions formed on a layer of material which is fixed to the surface to be tiled. The tiles are attached by a push fitting when matching recesses to protrusions. The tiles can be removed without damage and re-used, and the system is suitable for wall, ceiling and floor tiling. However, the application of the material forming cylindrical extrusions on the surface to be tiled may be cumbersome.
    DE 10 2011 009 655 A1 discloses a similar tile cladding system.
    The object of the present invention is to provide a more versatile tile cladding system whereby the mounting of the tile elements on the building surface is facilitated.
    In view of this object, the mounting plate is provided with a number of transverse grooves extending in the transverse direction and being mutually
    DK 2017 70666 A1 spaced in the longitudinal direction, and the transverse grooves have such a configuration that the mounting plate is able to bend.
    In this way, the mounting plate may be supplied in rolled up form before it is attached to the building surface, thereby greatly improving the mounting procedure. Longer lengths of mounting plate may advantageously be attached to the building surface gradually, as the length of mounting plate is unrolled.
    Furthermore, the grooves of the mounting plate may compensate for possible irregularities of the building surface so that an even surface may nevertheless be formed by the front sides of the respective tile elements.
    In an embodiment, the transverse grooves are formed in the front side of the mounting plate. Thereby, the process of adhesion of the mounting plate to the building surface, as the length of mounting plate is unrolled, may be facilitated and may result in more accurate positioning, because bending of the mounting plate at the grooves will generally not change the length of the back side of the mounting plate in the longitudinal direction.
    In addition, the grooves in the front side of the mounting plate may serve to receive signal wires and/or power cables which may also easily be installed at a later stage, because some of the tile elements may even without special tools simply be removed and mounted again after arrangement of the wires and/or cables. The wires and/or cables may then be hidden by the tile elements.
    In an embodiment, the back side of the mounting plate is provided with a number of grooves. Thereby, the adhesion of the mounting plate to the building surface may be improved, partly because these grooves may serve as reservoirs for surplus adhesive, and partly because these grooves may increase the contact area of the adhesive arranged between the back side of the mounting plate and the building surface.
    The grooves in the back side of the mounting plate may be in the form of longitudinal grooves extending in the longitudinal direction. Thereby these
    DK 2017 70666 A1 grooves may be arranged transversely to the above-mentioned transverse grooves, and the combination of longitudinal and transverse grooves may impart flexibility to the mounting plate in both directions and thereby compensate even better for possible irregularities of the building surface so that an even surface may nevertheless be formed by the front sides of the respective tile elements.
    In an embodiment, the mounting plate has two opposed edge areas extending in the longitudinal direction at either side of a central area of the mounting plate, and a general material thickness of the mounting plate in each of said opposed edge areas is smaller than a general material thickness of the mounting plate in the central area. Thereby, two adjacent mounting plates may be arranged with overlapping edge areas and an even surface may nevertheless be formed by the front sides of the respective tile elements mounted thereon. The overlapping edge areas may avoid or minimise leakage of water and/or dirt to the underlying building surface.
    In an embodiment, a first of said opposed edge areas is provided with some of said protrusions and/or indentations and a second of said opposed edge areas is not provided with protrusions and/or indentations. Thereby, a broader overlap between adjacent mounting plates may be obtained with a better sealing effect as a result.
    In an embodiment, the tile cladding system includes a fixation tool having at least two, preferably four, protrusions and/or indentations corresponding to respective protrusions and/or indentations of the mounting plate and so that the fixation tool may form a fitting connection with two adjacent mounting plates at the same time. Thereby, the fixation tool may define the correct relative mounting position between said two mounting plates and thereby vastly facilitate the mounting process of the mounting plate on the building surface. Furthermore, a more precise mounting of the entire tile cladding system may be ensured so that an even surface may be formed by the front sides of the respective tile elements.
    DK 2017 70666 A1
    In an alternative embodiment, the fixation tool is formed as a very thin plate compared to the thickness of the edges areas, and/or corresponding recesses are formed at the edges of the mounting plates in order to take up the fixation tool. Thereby, the fixation tool may be left in place when mounting the tile elements on the mounting plates.
    In a further alternative embodiment, the fixation tool is integrated as a part of the mounting plates, possibly in the form of a flap extending from one of the opposed edges areas of each mounting plate. In this case, the fixation tool should be left in place when mounting the tile elements on the mounting plates and therefore be formed thin with corresponding recess as mentioned above.
    In an embodiment, the front side of the mounting plate is provided with a number of protrusions, preferably in the form of at least substantially cylindrical studs, the front side of the mounting plate has no indentations, the back side of each tile element is provided with a number of indentations, preferably in the form of at least substantially cylindrical holes corresponding to respective protrusions of the mounting plate, and the back side of each tile element has no protrusions. Thereby the mounting plate may be configured relatively thin, because the protrusions will extend into the indentations of the tile elements.
    The present invention further relates to a method of mounting tile elements on a building surface by means of a mounting plate having a longitudinal direction and a transverse direction, whereby a back side of the mounting plate is attached on the building surface, preferably by gluing, and whereby a back side of each tile element is connected to a front side of the mounting plate by fitting protrusions on the front side of the mounting plate and/or on the back side of each tile element into corresponding indentations on the front side of the mounting plate and/or on the back side of each tile element, thereby forming a snap-fit or friction fit connection between the respective tile elements and the mounting plate.
    DK 2017 70666 A1
    The method is characterised in that the mounting plate is provided with a number of transverse grooves extending in the transverse direction and being mutually spaced in the longitudinal direction, in that, before attaching the mounting plate to the building surface, the mounting plate is supplied in rolled up form, and in that, upon attachment of the mounting plate on the building surface, the cross-sectional area of the transverse grooves generally changes.
    In this way the mounting procedure may be greatly improved. Longer lengths of mounting plate may advantageously be attached to the building surface gradually, as the length of mounting plate is unrolled.
    Furthermore, the grooves of the mounting plate may compensate for possible irregularities of the building surface so that an even surface may nevertheless be formed by the front sides of the respective tile elements.
    In an embodiment, upon attachment of the mounting plate on the building surface, the cross-sectional area of the transverse grooves generally increases. Thereby, the process of adhesion of the mounting plate to the building surface, as the length of mounting plate is unrolled, may be facilitated and may result in more accurate positioning, because bending of the mounting plate at the grooves will generally not change the length of the back side of the mounting plate in the longitudinal direction.
    In an embodiment, a first length of mounting plate is attached to the building surface, whereby, subsequently, a second length of mounting plate is attached to the building surface so that an edge area of the second length of mounting plate overlaps an edge area of the first length of mounting plate. Thereby, an even surface may nevertheless be formed by the front sides of the respective tile elements mounted thereon. The overlapping edge areas may avoid or minimise leakage of water and/or dirt to the underlying building surface.
    A number of tile elements may be connected to both the first and the second length of mounting plate, so that said number of tile elements thereby bridge said first and second length of mounting plate. Possible irregularities of the
    DK 2017 70666 A1 building surface may be even better hidden by said bridging tile elements as sudden steps between adjacent tile elements at the edges of the mounting plates may be avoided.
    In an embodiment, before finally fixing the second length of mounting plate to the building surface, a fixation tool is brought into fitting engagement with protrusions and/or indentations on both said first and second length of mounting plate, thereby positioning the second length of mounting plate in relation to the first length of mounting plate. Thereby, the advantages mentioned above may be obtained.
    Preferably, the fixation tool is removed from said first and second length of mounting plate before the attachment of tile elements on said first and second length of mounting plate is finished. Thereby, the fixation tool may be reused for the positioning of subsequent mounting plates. Furthermore, the fixation tool may not interfere with the subsequently mounted tile elements.
    According to some (further) embodiments or aspects of a tile cladding system as disclosed herein and/or a method of mounting tile elements as disclosed herein, the material of the mounting plate may also be flexible and/or elastic in itself so that the mounting plate is able to bend, at least to some extent, even without the transverse grooves formed therein.
    According to some (further) embodiments or aspects of a tile cladding system as disclosed herein and/or a method of mounting tile elements as disclosed herein, the mounting plate may be perforated or consist of or comprise a web, net, etc.
    The invention will now be explained in more detail below by means of examples of embodiments with reference to the very schematic drawing, in which
    Fig. 1 is a perspective view of a mounting plate of the tile cladding system according to the invention;
    DK 2017 70666 A1
    Fig. 2 is a partial cross-sectional view along the line II-II of Fig. 1 on a larger scale;
    Fig. 3 is a plan view illustrating the back side of a tile element of the tile cladding system according to the invention, on a larger scale relative to Fig. 1; and
    Fig. 4 is a plan view illustrating a fixation tool of an embodiment of the tile cladding system according to the invention, on a larger scale relative to Fig. 1.
    Figs. 1 and 2 illustrate an embodiment of a tile cladding system 1 according to the present invention for mounting tile elements 2 on a not shown building surface in the form of a wall, floor, ceiling or the like. The tile cladding system 1 includes a mounting plate 4 and a number of tile elements 2. The mounting plate 4 is illustrated in Fig. 1 during unrolling, and Fig. 2 illustrates in part a cross-sectional view along the line II-II in Fig. 1. Only the upper part of the mounting plate seen in Fig. 1 is illustrated in the cross-sectional view of Fig.
    2. The mounting plate 4 may be cut in suitable length in order to fit the relevant building surface, and the mounting plate 4 is preferably adhered to the building surface by means of a suitable adhesive, however, any suitable fastening means may be used, such as for example screws, nails or the like.
    The mounting plate 4 has a longitudinal direction L, a transverse direction T, a front side 5 adapted to carry the tile elements 2 and a back side 6 adapted to be attached on the building surface. Each tile element 2 has a front side 7 adapted to face away from the building surface, typically into the interior of a room of a building, and a back side 8 adapted to be connected to the front side 5 of the mounting plate 4. Typically, the tile elements 2 may have a rectangular periphery, but in fact the periphery could have any suitable form, and tile elements with different forms of periphery may be combined on the same mounting plate 10. The front side 5 of the mounting plate 4 is provided with a number of protrusions 9 in the form of at least substantially cylindrical studs, and the back side 8 of each tile element 2 is provided with a number of indentations 10 in the form of at least substantially cylindrical holes corresponding to respective protrusions 9 of the mounting plate 4 in such a way
    DK 2017 70666 A1 that protrusions 9 may fit into indentations 10 in order to form a snap-fit or friction fit connection. Although in the embodiment shown, the protrusions 9 are illustrated as cylindrical studs and the indentations 10 are illustrated as cylindrical holes, these elements may have any suitable form in order to provide a snap-fit or friction fit connection. For instance, the protrusions 9 could have the form of tongues and the indentations 10 could have the form of corresponding grooves. It should be mentioned that although Fig. 1 illustrates only some of the protrusions 9 in the form of at least substantially cylindrical studs on the mounting plate 4, typically, the protrusions 9 will be distributed at least substantially regularly over the entire front side 5 of the mounting plate 4, possibly apart from an area along one or more edges as explained below. Likewise, it should be mentioned that although Fig. 1 illustrates only some of the transverse grooves 11, typically, the transverse grooves 11 will be distributed at least substantially regularly over the entire front side 5 of the mounting plate 4.
    Furthermore, according to the present invention, the mounting plate 4 is provided with a number of transverse grooves 11 extending in the transverse direction T and being mutually spaced in the longitudinal direction L, as illustrated in Fig. 1. The transverse grooves 11 have such a configuration that the mounting plate 4 is able to bend, that is, the deepness and width of the transverse grooves 11 are adapted to a general material thickness tx in a central area 15 of the mounting plate 4 and to the material properties of the mounting plate 4 in such a way that the mounting plate 4 may bend and can be rolled up 3, for instance as illustrated in Fig. 1. The mounting plate 4 may be formed of any suitable material or combination of materials, however, it is preferred that the mounting plate 4 and the protrusions 9 formed thereon is formed as an integrated plastic moulding. Although the mounting plate 4 is bendable as a result of the transverse grooves 11, the material of the mounting plate 4 may also be flexible and/or elastic in itself so that the mounting plate 4 would be able to bend, at least to some extent, even without the transverse grooves 11 formed therein. In particular, it is preferred that the mounting plate 4 is suitable as a moisture/vapour barrier in order to avoid that water leaks into the underlying building surface. Likewise, the tile elements 2 may be formed of any suitable material or combination of materials
    DK 2017 70666 A1 and may have different functions apart from defining the aesthetic appearance of the surface formed by the tile elements. For instance, some tile elements could form a mirror.
    Preferably, the transverse grooves 11 are formed in the front side 5 of the mounting plate 4. Thereby, the process of adhesion of the mounting plate 4 to the building surface, as the length of mounting plate 4 is unrolled, see Fig. 1, may be facilitated and may result in more accurate positioning. This is because bending of the mounting plate 4 at the transverse grooves 11 will generally not change the length of the back side 6 of the mounting plate 4 in the longitudinal direction L. On the other hand, if the transverse grooves 11 are formed in the back side 6, the length of the back side 6 will be reduced during unrolling of the mounting plate 4 onto the building surface, thereby resulting in a contact force between the mounting plate 4 and the building surface in the longitudinal direction during application. This may result in a less precise positioning of the mounting plate 4.
    In addition, the transverse grooves 11 in the front side 5 of the mounting plate 4 may serve to receive not shown signal wires and/or power cables which may also easily be installed at a later stage, because some of the tile elements 2 may even without special tools simply be removed and mounted again after arrangement of the wires and/or cables. The wires and/or cables may then be hidden by the tile elements 2.
    It is understood that although the transverse grooves 11 enables the mounting plates 4 to be provided in rolled-up form and may be unrolled during mounting on the building surface, the mounting plates 4 may also be provided in their plane form, for instance in a stack. The transverse grooves 11 may still serve for the different purposes mentioned above, such as to provide flexibility and to receive wires and cables. In this case, flexibility of the mounting plates may still be an advantage during attachment to the building surface.
    In the embodiment illustrated, the back side 6 of the mounting plate 4 is provided with a number of longitudinal grooves 12 extending in the longitudinal direction L. Thereby, the adhesion of the mounting plate 4 to the building surDK 2017 70666 A1 face may be improved, partly because these longitudinal grooves 12 may serve as reservoirs for surplus adhesive, and partly because these longitudinal grooves 12 may increase the contact area of the adhesive arranged between the back side 6 of the mounting plate 4 and the building surface.
    The longitudinal grooves 12 are in the embodiment illustrated arranged at right angles to the above-mentioned transverse grooves 11, and the combination of longitudinal and transverse grooves 11, 12 may impart flexibility to the mounting plate 4 in both directions and thereby compensate even better for possible irregularities of the building surface so that an even surface may nevertheless be formed by the front sides 7 of the respective tile elements 2. Of course, increased flexibility of the mounting plate 4 may likewise be achieved by arranging the longitudinal grooves 12 at other suitable angles, such as for instance 70 degrees, with respect to the transverse grooves 11.
    As illustrated in the embodiment shown in Fig. 1, the mounting plate 4 has two opposed edge areas 13, 14 extending in the longitudinal direction L at either side of the central area 15 of the mounting plate 4. A general material thickness t2 of the mounting plate 4 in each of said opposed edge areas 13, is smaller than, e.g. about half of, a general material thickness ti of the mounting plate 4 in the central area 15. Thereby, two adjacent mounting plates 4 may be arranged with overlapping edge areas 13, 14 and an even surface may nevertheless be formed by the front sides 7 of the respective tile elements 2 mounted thereon. The overlapping edge areas 13, 14 may avoid or minimise leakage of water and/or dirt to the underlying building surface.
    In an embodiment, the mounting plate 4 has a width in its transverse direction T of approximately 50 centimetres; however, any suitable width is possible. The general material thickness t1 of the mounting plate 4 in the central area 15 may for instance be about 1.5 to about 2.5 millimetres, be about 1.8 to about 2.2 millimetres, or be approximately 2 millimetres and the general material thickness t2 of the mounting plate 4 in each of said opposed edge areas 13 may for instance be about 0.8 to about 1.2 millimetres, be about 0.9 to about 1.1 millimetres, or be approximately 1 millimetres. However, any suitable dimensions are possible.
    DK 2017 70666 A1
    In a not shown embodiment, a first of said opposed edge areas 13, 14 is provided with some of said protrusions 9 and/or indentations and a second of said opposed edge areas 13, 14 is not provided with protrusions and/or indentations. Thereby, a broader overlap between adjacent mounting plates 4 may be obtained with a better sealing effect as a result.
    In the embodiment illustrated in the figures, the tile cladding system 1 includes a fixation tool 16 illustrated in Fig. 4 and having four at least substantially cylindrical indentations 17 corresponding to respective protrusions 9 of the mounting plate 4. Thereby, the fixation tool 16 may form a fitting connection with two adjacent mounting plates 4 at the same time and define the correct relative mounting position between said two mounting plates 4. Thereby, the mounting process of the mounting plate on the building surface may be vastly facilitated. Furthermore, a more precise mounting of the entire tile cladding system 1 may be ensured so that an even surface may be formed by the front sides 7 of the respective tile elements 2.
    In an alternative not shown embodiment, the fixation tool 16 is formed as a very thin plate compared to the thickness of the edges areas 13, 14, and/or corresponding recesses are formed at the edges of the mounting plates 4 in order to take up the fixation tool 16. Thereby, the fixation tool 16 may be left in place when mounting the tile elements 2 on the mounting plates 4.
    In a further alternative not shown embodiment, the fixation tool 16 is integrated as a part of the mounting plates 4, possibly in the form of one or more flaps extending from one of the opposed edges areas 13, 14 of each mounting plate 4. Said one or more flaps may also be an integrated part of the opposed edges areas 13, 14. In these embodiments, the fixation tool or tools 16 may be left in place when mounting the tile elements 2 on the mounting plates 4 and may therefore be formed thin with corresponding recess or recesses as mentioned above. Thereby, a separate fixation tool is not necessary.
    In an illustrated method according to the invention, a back side 6 of the mounting plate 4 is attached on the building surface, preferably by gluing,
    DK 2017 70666 A1 and a back side 8 of each tile element 2 is connected to a front side 5 of the mounting plate 4 by fitting protrusions 9 on the front side 5 of the mounting plate 4 into corresponding indentations 10 on the back side 8 of each tile element 2, thereby forming a snap-fit or friction fit connection between the respective tile elements 2 and the mounting plate 4. Before attaching the mounting plate 4 to the building surface, the mounting plate 4 is supplied in rolled up form 3, and, upon attachment of the mounting plate 4 on the building surface, the cross-sectional area of the transverse grooves 11 generally changes.
    In the illustrated method, wherein the transverse grooves 11 are formed on the front side 5 of mounting plate 4, the cross-sectional area of the transverse grooves 11 generally increases upon unrolling of the mounting plate 4. Thereby, the process of adhesion of the mounting plate 4 to the building surface, as the length of mounting plate 4 is unrolled, may be facilitated and may result in more accurate positioning, because bending of the mounting plate 4 at the transverse grooves 11 will generally not change the length of the back side 6 of the mounting plate 4 in the longitudinal direction L.
    In an embodiment of the method according to the invention, a first length of mounting plate 4 is attached to the building surface, whereby, subsequently, a second length of mounting plate 4 is attached to the building surface so that an edge area 14 of the second length of mounting plate 4 overlaps an edge area 13 of the first length of mounting plate 4. Thereby, an even surface may nevertheless be formed by the front sides 7 of the respective tile elements 2 mounted thereon. The overlapping edge areas 13, 14 may avoid or minimise leakage of water and/or dirt to the underlying building surface.
    Possibly, a number of tile elements 2 are connected to both the first and the second length of mounting plate 4, said number of tile elements 2 thereby bridging said first and second length of mounting plate 4. Possible irregularities of the building surface may be even better hidden by said bridging tile elements 2 as sudden steps between adjacent tile elements 2 at the edges of the mounting plates 4 may be avoided.
    DK 2017 70666 A1
    In an embodiment of the method according to the invention, before finally fixing the second length of mounting plate 4 to the building surface, the fixation tool 16 is brought into fitting engagement with protrusions 9 on both said first and second length of mounting plate 4, thereby positioning the second length of mounting plate 4 in relation to the first length of mounting plate 4. Preferably, the fixation tool 16 is removed from said first and second length of mounting plate 4 before the attachment of tile elements 2 on said first and second length of mounting plate 4 is finished. Thereby, the fixation tool 16 may be reused for the positioning of subsequent mounting plates 4. Further10 more, the fixation tool 16 may not interfere with the subsequently mounted tile elements 2.
    The mounting plates 4 may be arranged with their longitudinal direction L in any suitable direction, for instance, if the relevant building surface is a wall, the longitudinal direction L of the mounting plates 4 may be arranged in horizontal or vertical direction of the surface of the building.
    DK 2017 70666 A1
    List of reference numbers
    L longitudinal direction
    T transverse direction t1 general material thickness in central area t2 general material thickness in opposed edge areas tile cladding system tile elements rolled-up mounting plate mounting plate front side of mounting plate back side of mounting plate front side of tile element back side of tile element protrusions indentations transverse grooves longitudinal grooves
    13, 14 opposed edge areas of mounting plate central area of mounting plate fixation tool indentations of fixation tool
    权利要求:
    Claims (11)
    [1] Claims
    1. A tile cladding system (1) for mounting tile elements (2) on a building surface, including a mounting plate (4) and a number of tile elements (2), the mounting plate (4) having a longitudinal direction (L), a transverse direction (T), a front side (5) adapted to carry the tile elements (2) and a back side (6) adapted to be attached on the building surface, each tile element (2) having a front side (7) adapted to face away from the building surface and a back side (8) adapted to be connected to the front side (5) of the mounting plate (4), the front side (5) of the mounting plate (4) being provided with a number of protrusions (9) and/or indentations and the back side (8) of each tile element (2) being provided with a number of protrusions and/or indentations (10) corresponding to respective protrusions (9) and/or indentations of the mounting plate (4) in such a way that protrusions (9) may fit into indentations (10) in order to form a snap-fit or friction fit connection, characterised in that the mounting plate (4) is provided with a number of transverse grooves (11) extending in the transverse direction (T) and being mutually spaced in the longitudinal direction (L), and in that the transverse grooves (11) have such a configuration that the mounting plate (4) is able to bend.
    [2] 2. A tile cladding system according to claim 1, wherein the transverse grooves (11) are formed in the front side (5) of the mounting plate (4).
    [3] 3. A tile cladding system according to claim 1 or 2, wherein the back side (6) of the mounting plate (4) is provided with a number of grooves, preferably in the form of longitudinal grooves (12) extending in the longitudinal direction (L).
    [4] 4. A tile cladding system according to any one of the preceding claims, wherein the mounting plate (4) has two opposed edge areas (13, 14) extending in the longitudinal direction (L) at either side of a central area (15) of the mounting plate (4), and wherein a general material thickness (t2) of the mounting plate (4) in each of said opposed edge areas (13, 14) is smaller than a general material thickness (t1) of the mounting plate (4) in the central area (15).
    DK 2017 70666 A1
    [5] 5. A tile cladding system according to claim 4, wherein a first of said opposed edge areas (13, 14) is provided with some of said protrusions (9) and/or indentations and a second of said opposed edge areas (13, 14) is not provided with protrusions and/or indentations.
    [6] 6. A tile cladding system according to any one of the preceding claims, wherein the tile cladding system (1) includes a fixation tool (16) having at least two, preferably four, protrusions and/or indentations (17) corresponding to respective protrusions (9) and/or indentations of the mounting plate (4) and so that the fixation tool (16) may form a fitting connection with two adjacent mounting plates (4) at the same time.
    [7] 7. A method of mounting tile elements (1) on a building surface by means of a mounting plate (4) having a longitudinal direction (T) and a transverse direction (T), whereby a back side (6) of the mounting plate (4) is attached on the building surface, preferably by gluing, and whereby a back side (8) of each tile element (2) is connected to a front side (5) of the mounting plate (4) by fitting protrusions (9) on the front side (5) of the mounting plate (4) and/or on the back side (8) of each tile element (2) into corresponding indentations (10) on the front side (5) of the mounting plate (4) and/or on the back side (8) of each tile element (2), thereby forming a snap-fit or friction fit connection between the respective tile elements (2) and the mounting plate (4), characterised in that the mounting plate (4) is provided with a number of transverse grooves (11) extending in the transverse direction (T) and being mutually spaced in the longitudinal direction (L), in that, before attaching the mounting plate (4) to the building surface, the mounting plate (4) is supplied in rolled up form (3), and in that, upon attachment of the mounting plate (4) on the building surface, the cross-sectional area of the transverse grooves (11) generally changes.
    [8] 8. A method of mounting according to claim 7, whereby, upon attachment of the mounting plate (4) on the building surface, the cross-sectional area of the transverse grooves (11) generally increases.
    DK 2017 70666 A1
    [9] 9. A method of mounting according to claim 7 or 8, whereby a first length of mounting plate (4) is attached to the building surface, whereby, subsequently, a second length of mounting plate (4) is attached to the building surface so that an edge area (14) of the second length of mounting plate (4) overlaps an
    5 edge area (13) of the first length of mounting plate (4), and whereby, possibly, a number of tile elements (2) are connected to both the first and the second length of mounting plate (4), said number of tile elements (2) thereby bridging said first and second length of mounting plate (4).
    [10] 10 10. A method of mounting according to claim 9, whereby, before finally fixing the second length of mounting plate (4) to the building surface, a fixation tool (16) is brought into fitting engagement with protrusions (9) and/or indentations on both said first and second length of mounting plate (4), thereby positioning the second length of mounting plate (4) in relation to the first length
    [11] 15 of mounting plate (4), and whereby, preferably, the fixation tool (16) is removed from said first and second length of mounting plate (4) before the attachment of tile elements (2) on said first and second length of mounting plate (4) is finished.
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    DK179733B1|2019-04-29|
    US20220003002A1|2022-01-06|
    WO2019048467A1|2019-03-14|
    EP3679204A1|2020-07-15|
    引用文献:
    公开号 | 申请日 | 公开日 | 申请人 | 专利标题
    US750954A|1904-02-02|Floor-tiling |
    DE593150C|1934-02-21|Hubert Stueken|Wall covering made of hard stone|
    US1854772A|1930-02-24|1932-04-19|Stuken Hubert|Wall tile covering|
    US4890433A|1987-12-15|1990-01-02|Motokatsu Funaki|Tile mounting plate and tiled wall structure|
    GB9118203D0|1991-08-23|1991-10-09|Wynne Charles H|Surface coverings|
    US6543196B1|2001-08-17|2003-04-08|Manual A. Gonzales|Flooring device|
    DE102008026169A1|2008-05-31|2009-12-03|Thomas Hugo Schneegans|Electrified module building board system for use at e.g. ceiling, of building for supplying current to lamp, has module fields provided at bases of individual chambers with reinforced bracing surfaces, and comprising bolt fastening holes|
    法律状态:
    2019-03-20| PAT| Application published|Effective date: 20190306 |
    2019-04-29| PME| Patent granted|Effective date: 20190429 |
    优先权:
    申请号 | 申请日 | 专利标题
    DKPA201770666A|DK179733B1|2017-09-05|2017-09-05|TILE COVERING SYSTEM AND PROCEDURE FOR FITTING TILE ELEMENTS ON A BUILDING SURFACE|DKPA201770666A| DK179733B1|2017-09-05|2017-09-05|TILE COVERING SYSTEM AND PROCEDURE FOR FITTING TILE ELEMENTS ON A BUILDING SURFACE|
    EP18768826.2A| EP3679204A1|2017-09-05|2018-09-05|Tile cladding system and method for mounting tile elements on a building surface|
    PCT/EP2018/073850| WO2019048467A1|2017-09-05|2018-09-05|Tile cladding system and method for mounting tile elements on a building surface|
    US17/280,819| US20220003002A1|2017-09-05|2018-09-05|Tile cladding system and method for mounting tile elements on a building surface|
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