The invention relates to a fastening system for panels, with retaining profiles arranged at the narrow sides of the panels, in particular for floor panels, wherein mutually opposite retaining profiles of a panel match each other in such a way that similar panels can be fastened to one another, wherein at least one pair of oppositely disposed retaining profiles has complementary hook elements that can be hooked one into the other and that the hook elements have hook projections with retaining surfaces by which the panels, in the assembled condition, are held against each other in such a way that there is a gap-free floor surface.
A fastening system of the general kind set forth is known from EP 0 715 037 A1.
In a flat assembly comprising a very large number of individual panels, a problem, which arises, is that of re-engaging a hook connection once it has come undone because the hook element that is associated with the base cannot be urged upwardly as it is not accessible.
The durability of the connection, particularly in the direction of the perpendicular joining movement, is therefore completely inadequate.
Therefore, the object of the invention is to provide a fastening system that is of a simple design configuration and is more durable than the known fastening system.
In accordance with the invention that object is attained in that the retaining surfaces of the hook projections are inclined, such that the hook projections decrease from their free ends towards the legs and the retaining surfaces of the complementary hook projections bear against each other at least in a region-wise manner.
This measure ensures that the retaining surfaces of the hook projections engage behind each other in such a way that they can be hooked into each other only by elastic. deformation. Release of the connection in a direction perpendicular to the plane in which the panels are laid is resisted by the retaining surfaces engaging behind each other.
In a simple manner, a first retaining profile of a panel is provided with a hook element formed from a leg that projects approximately perpendicularly from the narrow side and is arranged at the top side of the panel, wherein arranged at the free end of the leg is a hook projection that faces towards the underside of the panel. The rear retaining profile of the panel is provided with a hook element formed from a leg that projects from the narrow side and is arranged at the underside of the panel, wherein arranged at the free end of said leg is a hook projection that faces towards the top side of the panel.
The top side of the panel forms a transition into the leg from the region involving the thickness of the complete panel, with a step in respect of the thickness of the panel. The leg is approximately of a thickness that corresponds to a third of the thickness of the panel. The same applies to the underside of the panel. In opposite relationship to the hook element of the top side, the leg at the underside forms a transition into the leg from the region of the complete thickness of the panel, with a step in respect of the panel thickness, the leg also being of a thickness that is about a third the thickness of the panel. The legs and the hook projections are substantially more massive than the undercut configuration of the known groove-and-tongue connection. That therefore involves an improvement in the strength and durability of the fastening system according to the invention.
Advantageously the hook projection of the leg at the underside bears, in the assembled condition of a panel, against the leg at the top side of a second panel. In addition, clearance is provided between the hook projection of the leg at the top side of the second panel and the leg at the underside of the first panel.
It will be appreciated that this can also be reversed so that clearance can be provided between the hook projection of the leg at the underside of the first panel and the leg at the top side of the second panel. What is important is that a pair of leg/hook projection, in the assembled condition, always bear clearly against each other, and the other leg/hook projection pair has clearance therebetween. If the fastening system were so designed that both leg/hook projection pairs always bear against each other, then tolerances in manufacture of the retaining profiles mean that well-defined contact therebetween would not be achieved and sometimes one leg/hook projection pair and sometimes another leg/hook projection pair would bear against each other.
A development of the fastening system provides that the retaining surfaces of the hook projections engage behind each other in such a way that complementary hook projections can be hooked one into the other only by elastic deformation. The panels are thus arrested perpendicularly to the plane of laying thereof.
It is possible in that way to ensure that the retaining elements cannot be moved away from each other for example due to an uneven base, when subjected to a loading. When a panel is subjected to a loading, the connected panel is moved with the loaded panel in the same direction. The joint remains together.
A further advantage is achieved if the end of the hook projection at the top side of the one panel in the assembled condition bears, at least in the region of the top side of the panel, against the second panel and clearance is provided between the hook projection at the underside of the second panel and the end of the first panel. That measure again serves to provide that there is always a clear condition of contact between two connected panels, by virtue of the structural configuration involved.
An alternative embodiment provides that at least one of the ends of a hook element of a panel has at its free end a projecting detent or latching element that, in the assembled condition, engages into an undercut recess of the hook element of the other panel.
This structure has been found to be particularly good to handle because the retaining profiles can be latched one into the other under light pressure and with elastic deformation. In addition, the hook elements enjoy good resistance to wear, which is advantageous in terms of multiple laying. The resistance to wear is good for the reason that different arresting functions are performed by different hook element regions and the loading on the hook element thus occurs in a distributed fashion. The panels are arrested for example by the detent element and the recess, perpendicularly to the plane in which the panels are laid. In contrast, the arresting action for the panels to prevent then from being pulled apart in the longitudinal direction thereof is afforded by the retaining surfaces of the hook projections.
In a simple manner the projecting detent element of the first panel is in the form of a bead that extends over the entire length of the narrow side and the undercut recess of the second panel is in the form of an elongate channel that receives the bead in the assembled condition. To form the joint, the bead and the channel have to be fitted one into the other with elastic deformation of the hook elements.
This embodiment of the fastening system is particularly suitable for multiple laying, when no glueing is effected, by virtue of its resistance to wear. It is also inexpensive to manufacture.
In the region of the joint a clearance gap can be tolerated between the panels at the underside of the panels that are laid on a support base, for example a floor finishing layer.
A further improvement provides that the regions provided with clearance in the assembled condition of two panels form adhesive pockets.
Besides use of the proposed fastening system for adhesive-free laying of floor panels, it is particularly suitable for making a joint with adhesive.
For that purpose those locations of the retaining profiles, which have to be provided with adhesive, are identified for example in instructions for use or by markings on the retaining profile itself. In that way, the user can apply adhesive very accurately where adhesive pockets occur in the assembled condition of two panels.
In the predominant situations of use of the floor panels, the glued form of laying same is considered to be the most appropriate fashion of laying the panels. That is because the durability of the panels is markedly improved. Securing the retaining profiles by adhesive provides that dirt and moisture are virtually prevented from penetrating into the joints. The absorption of moisture and swelling of the panels in the joint region of the retaining profiles is minimized thereby.
It will be appreciated that there can be situations of use for which adhesive-free laying is to be preferred. For example, when a floor covering when laid has to be frequently taken up again and re-laid, for example when dealing with floors in setting up fairs and exhibitions.
An embodiment that is simple and durable has been found to be a structure in which the retaining profiles of the long narrow sides are in the form of complementary positively engaging profiles, wherein the positively engaging profile of one panel forms a common hinge with the complementary positively engaging profile of a second panel in the laid condition and the hinge is to be assembled by a rotary joining movement of the panels. By virtue of that pivotability between the long narrow sides, that connecting location between the panels is protected from severe material damage and breakage of the retaining profiles.
By virtue of the presence of the hinge, the panels can be bent upwardly and downwardly at the connecting location. If, for example, a panel is resting on a support base with a raised portion so that when a loading is applied a narrow side of the panel is pressed on to the support base and the oppositely disposed narrow side rocks upwardly, then a second panel, which is fastened to the upwardly moving narrow side, is also moved upwardly. The flexural forces that are operative in that situation however do not damage the narrow cross-sections of the positively engaging profiles. Instead, a pivotal movement takes place. This structure takes account of the principle of ‘matched deformability’. That principle is based on the realization that very stiff and accordingly allegedly stable connecting locations give rise to high levels of notch stresses and easily fail as a result. In order to avoid this, components are to be designed in such a way that they have ‘matched deformability’ or flexibility that is suitably adapted to the purpose of use, and in that way notch stresses can be reduced.
A floor laid with the proposed fastening system has a flexibility that is adapted to irregular rough or corrugated base surfaces. This measure therefore enhances the durability of the panels. The fastening system is therefore particularly well suited for panels for renovating irregular floor surfaces in old buildings.
Even in the case of a flat base, panels can suffer from an alternate flexing effect, more specifically if a soft underlay, for example a sheet for deadening the sound of footsteps, or the like, is laid on the base. At a loaded location, the underlay is depressed and the panels flex at their connecting locations. The fastening system is also better suited for this kind of panel laying than the known fastening systems.
A further advantage is that panels with the fastening system according to the invention are better suited to multiple laying than panels with the known fastening system because the panels with the fastening system according to the invention, even after a long period of use on an irregular base, do not have any early signs of damage to the positively engaging profiles The positively engaging profiles are stable in respect of shape and durable. They can be used for a substantially longer time and can be re-laid more frequently because of their service cycle.
In a simple embodiment, the hinge is formed from an opening in the narrow side of the first panel and a matching projection on the complementary narrow side of the second panel. The positively engaging profiles are preferably of such a design that a loading at the top side of the floor panels in the laid condition is transmitted from the top wall of the opening in a first panel to the projection of the second panel and from the projection of the second panel to the wall at the underside of the first panel. In the laid condition, the walls of the opening in the first panel are in contact with the top side and the underside of the projection of the second panel. The top wall of the opening however is in contact with the projection of the second panel only in a short region at the free end of the upper wall of the opening. In that way the structure permits a hinge movement between the panel with the opening and the panel with the projection, with slight elastic deformation of the walls of the opening. In that way the stiffness of the connection is best matched to an irregular base, which inevitably results in a bending movement between panels that are fastened to each other.
In a simple structure, the hinge is formed from a concave curvature in the inward wall of the opening that is towards the base, and a convex curvature at the underside of the projection, that is towards the base. In addition, the top side of the projection of a panel, which is remote from the base, has an inclined removal of material that extends to the free end of the projection. The thickness of the projection is increasingly reduced towards the free end by the removal of material. A free space for movement is afforded for the common hinge by the removal of material.
In order to take up laid panels again, desirably firstly a row of panels disposed in mutually juxtaposed relationship are lifted in such a way that they rotate inclinedly upwardly in the hinge. The projections are then pulled in an inclined direction out of the openings and the hinge is taken apart. The panels are then only joined at the short narrow sides. It is recommended that the interengaged hook elements of the short narrow sides should be pulled apart in their longitudinal extent, in order in that way in the disconnection procedure to avoid deformation of the hook elements, such as to cause material fatigue.
Advantageously the convex curvature of the projection and the concave curvature of the opening substantially form a portion of a circle, wherein the centre point of the portion of the circle is on or beneath the top side of the projection, in the laid condition. In the latter case, the centre point of the circle is within the cross-section of the projection.
This simple design configuration affords a hinge in which the convex curvature of the projection is similar to a hinge ball and the concave curvature of the recess is similar to a hinge socket, in which respect as will be appreciated, unlike a ball-and-socket joint, no spherical movement but only a straightforward rotational movement is possible.
In an advantageous development, the furthest projecting point of the convex curvature of the projection of a panel is so arranged that it is somewhat below the upper edge of the panel. That means that the projection is of a cross-section that is relatively large in comparison with the overall thickness of the panel. In addition, the concave curvature of the opening affords a sufficiently large undercut configuration for the convex curvature of the projection so that they can scarcely be moved away from each other by virtue of the tensile forces acting in the plane in which the panels are laid.
The hinge properties of two interconnected panels can be further improved if the wall of the opening of a panel, which is towards the base, has on its inside an inclined removal of material which extends to the free end of the wall and the wall thickness of said wall is increasingly thinner towards the free end. In that case, a free space for movement for the common hinge is provided by the removal of material, in the laid condition of two panels.
With that improvement, the amount of elastic deformability of the walls of the opening is further reduced, during flexing of the laid panels in an upward direction.
It is also desirable if the opening of a panel can be enlarged for connection to the projection of a further panel by resilient deformation of its lower wall and the resilient deformation of the lower wall, which occurs during the joining operation, is reversed again in the finished joined condition of two panels. In that way the positively engaging profiles are elastically deformed only for the joining operation and during a pivotal hinge movement and are not subjected to any elastic stressing when they are not loaded.
Preferably, the positively engaging profiles are formed integrally at the narrow sides of the panels. The panels can be produced very easily and with a low level of waste.
It has been found that the strength of modern carrier materials such as for example medium density fibreboard (MDF) or high density fibreboard (HDF) that are provided with a wear-resistant working layer are particularly suitable for use of the fastening system proposed. Those materials are simple to machine and achieve adequate surface quality, for example by a cutting machining operation. In addition, those materials enjoy high stability in respect of shape of the milled profiles. Even after having been laid a plurality of times the retaining profiles are still so good in terms of shape that a secure joint is possible, even on an uneven base.
A further advantage is afforded if, in the laid condition of the panels, the free spaces for movement for the common hinges are provided with a filler that hardens in soft-elastic form. That filler preferably closes all joints and in particular the joint at the top side, in such a way that no moisture and no dirt can penetrate. Upon a hinge movement of the interconnected panels, the soft-elastic filler is squeezed or stretched, depending on the direction of rotation of the hinge movement. In that situation, it always adheres to the contact surfaces of the narrow sides of the panels and returns to its initial shape upon return of the hinge movement. The filler contributes to the return movement of the hinge, by virtue of the elastic internal deformation of the filler.
The invention is described in greater detail hereinafter with reference to the Figures and illustrated by way of example in a drawing in which:
Referring to
The hook projection 5f of the second panel 5 with the leg 5e at the underside bears, in the assembled condition of the first panel 4, against the leg 4e at the top side of the second panel 5. For the purposes of affording well-defined contact, clearance L1 is provided between the hook. projection 4f of the leg 4e at the top side of the first panel 4 and the leg 5e at the underside of the second panel 5 in the present embodiment.
As shown in
The retaining surfaces 4g and 5g, which bear against each other, of the co-operating panels 4 and 5, therefore bear snugly against each other in a region-wise manner. The resulting intermediate spaces can advantageously serve as adhesive pockets 12a and 12b.
Clearance L2 is further provided between the end 5h of the hook projection 5f at the lower side of the second panel 5 and the inside surface 13 of the first panel 4. That resulting intermediate space can also serve as an adhesive pocket 12c. The same applies in regard to the end 14 of the hook projection 4f at the top side of the first panel 4 that, in the assembled condition, bears against the second panel 5 at least in the region of the top sides 16 and 9 of the panels. In the present embodiment, an intermediate space, which is also in the form of an adhesive pocket 12d, is enlarged beneath the top sides 16 and 9 of the panels towards the interior of the joint.
A second embodiment of a fastening system 2 is shown in
The hook projection 4f′ of the first panel 4′ with the leg 4e at the top side bears, in the assembled condition of the second panel 5′, against the leg 5e at the underside of the second panel 5′. For the purposes of affording well-defined contact, clearance L1′ is provided between the hook projection 5f′ of the leg 5e at the underside of the second panel 5′ and the leg 4e at the top side of the first panel 4′.
As shown in
The retaining surfaces 4g and 5g, which bear against each other, of the co-operating panels 4′ and 5′, therefore bear snugly against each other in a region-wise manner. The resulting intermediate spaces can advantageously serve as adhesive pockets 12e and 12f.
Clearance L2 is provided between the end 5h of the hook projection 5f at the lower side of the second panel 5′ and the in side surface 13 of the first panel 4′. That resulting intermediate space can also serve as an adhesive pocket 12g. The same applies in regard to the end 14 of the hook projection 4f′ at the top side of the first panel 4′ that, in the assembled condition, bears against the second panel 5′ at least in the region of the top sides 16 and 9 of the panels. In this embodiment, an intermediate space, which is also in the form of an adhesive pocket 12h, is enlarged beneath the top sides 16 and 9 of the panels towards the interior of the joint. The arrangement once again involves well-defined contact between the hook projections 4f′ and 5f′ and a gap-free surface for the floor covering 1.
Finally,
The positively engaging profiles 42 and 43 in
One of the positively engaging profiles 42 is provided with a projection 44 that protrudes from a narrow side. The underside of the projection 44, which, in the laid condition, is towards the base, has a cross-section with a convex curvature 45, for the purposes of affording a hinged connection. The convex curvature 45 is rotatably mounted in the complementary positively engaging profile 43. In the illustrated embodiment, the convex curvature 45 is in the form of a portion of a circle. The part 46 of the narrow side of the panel 40, which is arranged beneath the projection 44 and which in the laid condition is towards the base, is further back from the free end of the projection 44 than the part 47 of the narrow side, which is arranged above the projection 44. In the illustrated embodiment the part 46 of the narrow side, which is arranged beneath the projection 44, is set back approximately twice as far from the free end of the projection 44 as the part 47 of the narrow side, which is arranged above the projection 44. The reason for this is that the circular portion of the convex curvature 45 is relatively wide. In that way the furthest projecting point of the convex curvature 45 of the projection 44 is so arranged that it is somewhat beneath the top edge 48 of the panel 40.
The part 47 of the narrow side, which is arranged above the projection 44, projects at the top side of the panel 40 from the narrow side and forms a joint abutting surface 49. The part 47 of the narrow side is set back between that joint abutting surface 49 and the projection 44 of the panel 40. This ensures that the joint abutting surface 49 with the joint abutting surface 39 of the complementary panel 41 always forms a closed joint at the top side.
The top side of the projection 44, which is in opposite relationship to the convex curvature 45 of the projection 44, has a short straight portion 50 that in the laid condition, is also arranged parallel to the base U. From that short portion 50 towards the free end the top side of the projection 44 has an inclined removal of material 51 that extends to the free end of the projection 44.
The positively engaging profile 43, which is complementary to the above-discussed positively engaging profile 42, is discussed hereinafter with reference to the panel 41. The positively engaging profile 43 has an opening 52. It is substantially delimited by a lower wall 53 that, in the laid condition, is towards the base U and an upper wall 54. On the inside of the opening 52, the lower wall 53 is provided with a concave curvature 55. That enjoys the function of a bearing shell. The concave curvature 55 is also in the form of a portion of a circle. So that the relatively wide concave curvature 55 has space at the lower wall 53 of the opening 52, the lower wall 53 projects further from the narrow side of the panel 41 than the upper wall 54. At the free end of the lower wall 53, the concave curvature 55 forms an undercut configuration. In the finished laid condition of two panels 40 and 41 that undercut configuration has engaging behind it the projection 44 of the associated positively engaging profile 42 of the adjacent panel 40. The extent by which the projection 44 engages behind that undercut configuration, that is to say the difference between the thickest location of the free end of the lower wall 53 and the thickness of the lower wall 53 at the deepest point of the concave curvature 55, is such that there is a good compromise between hinged flexibility of the two panels 40 and 41 and a good hold to prevent the positively engaging profiles 42 and 43 from being pulled apart in the plane in which the panels are laid.
The fastening system of the state of the art shown in
The inside of the upper wall 54 of the opening 52 of the panel 41 is arranged in accordance with the illustrated embodiment parallel to the base U in the laid condition.
The lower wall 53 of the opening 52 of the panel 41, which is towards the base, has on its inside an inclined removal of material 56 which extends to the free end of the lower wall 53. By virtue of that arrangement, the wall thickness of the wall 53 becomes increasingly thinner to the free end of the wall 53. In the illustrated embodiment, the removal of material 56 adjoins the one end of the concave curvature 55.
As can be seen from
In the laid condition the short straight portion 50 of the top side of the projection 44 of the panel 40 is in contact with the inside of the upper wall 54 of the opening 52 of the panel 41. In addition, the convex curvature 45 of the projection 44 bears against the concave curvature 55 of the lower wall 53 of the recess 52 of the panel 41.
The lateral joint abutting surfaces 49 and 39, which are towards the top side, of two connected panels 40 and 41 always bear against each other in well-defined fashion. In practice, simultaneous exact contact of the convex curvature 45 of the projection 44 of the panel 40 against the concave curvature 55 of the opening 52 of the panel 41 is not possible. The result of manufacturing tolerances would be either that the joint abutting surfaces 49 and 39 bear exactly one against each other or the convex curvature 45 bears exactly against the concave curvature 55. In practice, the positively engaging profiles 42 and 43 are therefore so designed that the joint abutting surfaces 49 and 39 always bear exactly against each other and the convex curvature 45 and the concave curvature 55 cannot be moved sufficiently far one into the other for exact contact. As however, the manufacturing tolerances are of the order of magnitude of hundredths of a millimetre the convex curvature 45 and the concave curvature 55 also bear snugly virtually one against the other.
Panels 40 and 41 with the described complementary positively engaging profiles 42 and 43 can be fixed to each other in various ways. As shown in
A further kind of joint between the panels 40 and 41 is shown in
The latter kind of joint is preferably used for the short narrow sides of the panels 40 and 41 when they are provided with the same complementary positively engaging profiles 42 and 43 as the long narrow sides of the panels 40 and 41.
The damage that occurs early in the case of positively engaging profiles in accordance with the state of the art, due to breakage of the projection or the walls of the positively engaging profiles, is thus avoided.
A further advantage is afforded in terms of a hinge movement as indicated in
The filler 60 further provides that, in the bent condition of two panels 40 and 41, the filler 60 which is deformed in itself, by virtue of the inherent spring action thereof, is involved in returning the panels 40 and 41 to the plane in which they are laid.
Number | Date | Country | Kind |
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199 29 896.3 | Jun 1999 | DE | national |
299 11 462.7 | Jul 1999 | DE | national |
This is a Continuation of U.S. patent application Ser. No. 10/019,195 filed Jun. 3, 2002 which was a National Stage Entry of International Application No. PCT/DE99/03259 filed Oct. 19, 1999, which claimed the priority of two German Patent Applications Nos. 299 11 462.7 filed Jul. 2, 1999, and 199 29 896.3 filed Jun. 30, 1999, the priorities of all four Applications are claimed and all four Applications are incorporated herein by reference.
Number | Date | Country | |
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Parent | 10019195 | Jun 2002 | US |
Child | 12357543 | US | |
Parent | PCT/DE99/03259 | Oct 1999 | US |
Child | 10019195 | US |