Building panels

Abstract

Flooring material including sheet-shaped floor elements with a mainly square or rectangular shape. The floor elements are provided with edges, a lower side and an upper decorative layer. The floor elements are intended to be joined by means of joining members. The floor elements are provided with male joining members on a first edge while a second edge of the floor elements are provided with a female joining member. The male joining member is provided with a tongue and a lower side groove while the female joining member is provided with a groove and a cheek, the cheek being provided with a lip. The floor elements are provided with a male vertical assembly joining member on a third edge while a fourth, opposite, edge is provided with female vertical assembly joining member.

Description

BACKGROUND

1. Field of the Invention

The present invention relates to a flooring material comprising sheet-shaped floor elements which are joined by means of joining members.

2. Background

Prefabricated floor boards provided with tongue and groove at the edges are quite common nowadays. These can be installed by the average handy man as they are very easy to install. Such floors can, for example. be constituted of solid wood, or of wood particles consolidated by use of a binder including fibre board, such as high or medium density fibre board (HDF or MDF), particle board, chip board, oriented strand board (OSB) or any other construction comprising particles of wood bonded together with a binder. These are most often provided with a surface layer such as lacquer, or some kind of laminate. The boards are most often installed by being glued via tongue and groove. The most common types of longue and groove are however burdened with the disadvantage to form gaps of varying width between the floor boards in cases where the installer hasn't been thorough enough. Dirt will easily collect in such gaps. Moisture will furthermore enter the gaps which will cause the core to expand in cases where it is made of wood, fibre board or particle board, which usually is the case. The expansion will cause the surface layer to rise closest to the edges of the joint which radically reduces the useful life of the floor since the surface layer will be exposed to an exceptional wear. Different types of tensioning devices, forcing the floor boards together during installation can be used to avoid such gaps. This operation is however more or less awkward. It is therefore desirable to achieve a joint which is self-guiding and thereby automatically finds the correct position. Such a joint would also be possible to utilize in floors where no glue is to be used.

Such a joint is known through WO 94/26999 (herein incorporated by reference in its entirety) which deals with a system to join two floor boards. The floor boards are provided with a locking device at the rear sides. In one embodiment the floor boards are provided with profiles on the lower side at a first long side and short side: These profiles, which extends outside the floor board itself, is provided with an upwards directed lip which fits into grooves on the lower side of a corresponding floor board. These grooves are arranged on the second short side and long side of this floor board. The floor boards are furthermore provided with a traditional tongue and groove on the edges. The intentions are that the profiles shall bend downwards and then to snap back into the groove when assembled. The profiles are integrated with the floor boards through folding or alternatively, through gluing.

According to WO 94/26999, the floor boards may be joined by turning or prizing it into position with the long side edge as a pivot point. It is then necessary to slide the floor board longitudinally so that it snaps into the floor board previously installed in the same row. A play is essential in order to achieve that. This play seems to be marked Δ in the figures. A tolerance of ±2 mm is mentioned in the application. Such a play will naturally cause undesired gaps between the floor boards. Dirt and moisture can penetrate into these gaps.

It is also known through WO 97/47834 (herein incorporated by reference in its entirety) to manufacture a joint where the floor boards are joined by turning or prizing it into position with the long side edge as a pivot point. According to this invention a traditional tongue has been provided with heel on the lower side. The heel has a counterpart in a recess in the groove of the opposite side of the floor board. The lower cheek of the groove will be bent away during the assembly and will then snap back when the floor board is in the correct position. The snap-joining parts, i.e. the tongue and groove, is in opposite to the invention according to WO 94/26999 above, where they are constituted by separate parts, seems to be manufactured monolithically from the core of the floor board. WO 97/47834 does also show how the tongue and groove with heels and recesses according to the invention is tooled by means of cutting machining. This invention does also have the disadvantage that the best mode of joining floor boards includes longitudinal sliding for joining the short sides of the floor boards, which also here will require a play which will cause unwanted gaps between the floor boards. Dirt and moisture can penetrate into these gaps.

SUMMARY OF THE INVENTION

It is, through the present invention, made possible to solve the above mentioned problems whereby a floor element which can be assembled without having to be slid along already assembled floor elements has been achieved. Accordingly, the invention relates to a flooring material comprising sheet-shaped floor elements with a mainly square or rectangular shape. The floor elements are provided with edges, a lower side and an upper decorative layer. The floor elements are intended to be joined by means of joining members. The invention is characterized in that;

• • a) The floor elements are provided with male joining members on a first edge while a second, opposite, edge of the floor elements are provided with a female joining member. The male joining member is provided with a tongue and a lower side groove. The female joining member is provided with a groove and a cheek, the cheek being provided with a lip. The floor elements are intended to mainly be joined together by tilting the floor element to be joined with an already installed floor element or a row of already installed floor elements, with the male joining member of the floor element angled downwards and that the first edge is allowed to be mainly parallel to the second edge of the already installed floor element or elements. The tongue of the tilted floor element is then inserted into the groove of the female joining member of the already installed floor element or elements. The tilted floor element is then turned downwards, with its lower edge as a pivot axis, so that the lip eventually snaps into the lower side groove where the decorative upper layer of the floor elements are mainly parallel.
  • b) The floor elements are moreover provided with a male vertical assembly joining member on a third edge while a fourth edge is provided with female vertical assembly joining member. The fourth edge is arranged on a side opposite to the third edge.
  • c) The floor elements are alternatively provided with a male vertical assembly joining member on a third edge, while a fourth edge also is provided with male vertical assembly joining member. The fourth edge is arranged on a side opposite to the third edge. Adjacent male vertical assembly joining members are thereby joined by means of a separate vertical assembly joining profile. Two adjacent edges of a floor element can hereby be joined with a floor element adjacent to the first edge and a floor element adjacent to the third or fourth edge at the same time, and in the same turning motion.

The force needed to overcome the static friction along the joint between two completely assembled male and female joining members is preferably larger than 10N per meter of joint length, suitably larger than 100N per meter of joint length.

According to one embodiment of the invention, the floor elements are provided with male vertical assembly joining members on a third edge and provided with female vertical assembly joining members on a fourth edge. The male vertical assembly joining members are provided with mainly vertical lower cheek surfaces arranged parallel to the closest edge. The lower cheek surfaces are intended to interact with mainly vertical upper cheek surfaces arranged on the female vertical assembly joining members so that two joined adjacent floor elements are locked against each other in a horizontal direction. The male and female vertical assembly joining members are provided with one or more snapping hooks with matching under cuts which by being provided with mainly horizontal locking surfaces limits the vertical movement between two joined adjacent floor elements.

The floor elements may alternatively be provided with male vertical assembly joining members on both a third and a fourth edge. These edges are then snap joined by means of a vertical assembly profile which on both sides of a longitudinal symmetry line is designed as a female vertical assembly joining member according to the description above. Two joined adjacent floor elements are locked to each other in a horizontal direction via the vertical assembly profile while, at the same time, vertical movement between two joined adjacent floor elements is limited.

The joint between a third and a fourth edge of two joined floor elements preferably comprises contact surfaces which are constituted by the horizontal locking surfaces of the under cuts and hooks, the mainly vertical upper cheek surfaces and lower cheek surfaces as well as upper mating surfaces.

The joint between two joined floor elements suitably also comprises cavities.

According to one embodiment of the invention the snapping hook is constituted by a separate spring part which is placed in a cavity. Alternatively the undercut is constituted by a separate spring part which is placed in a cavity. The spring part is suitably constituted by an extruded thermoplastic profile, a profile of thermosetting resin or an extruded metal profile.

The vertical assembly joining profiles are suitably shaped as extended profiles which suitably are manufactured through extrusion which is a well known and rational method. The vertical assembly joining profiles are suitably shaped as extended lengths or rolls which can be cut to the desired length. The length of the vertical assembly joining profiles considerably exceeds the length of a floor element, before being cut. The lateral joints of the floor will only need shorter pieces of vertical assembly joining profiles which are positioned as each new floor board is introduced to a row. Vertical assembly joining profiles according to the present invention may be manufactured of a number of different materials and manufacturing methods. Among the most suited can, however, be mentioned injection moulding and extrusion. Suitable materials are thermoplastic materials such as polyolefins, polystyrene, polyvinyl chloride or acrylnitrile-butadiene-styrene copolymer. These may suitably be filled with, for example, wood powder or lime in order to increase the rigidity but also to increase the adhesion when glue is used. It is also possible to mill a vertical assembly joining profile from a material such as wood, fibre board or particle board.

The flooring material including the floor boards and joining profiles above is most suited when installing floors where it isn't desired to use glue. It is, however, possible to use glue or twin-faced adhesive tape in order to make the installation irreversibly permanent. The glue or tape is then suitably applied on, or in connection to, possible cavities or faces below the upper mating surfaces.

BRIEF DESCRIPTION OF THE DRAWINGS

The invention is described further in connection to enclosed figures showing different embodiments of a flooring material whereby,

FIG. 1 shows, in cross-section, a first and a second edge 2^I and 2^II respectively, during joining

FIG. 2 shows, in cross-section, a second embodiment of a first and a second edge 2^I and 2^II respectively, during joining.

FIG. 3 shows, in cross-section, a third embodiment of a first and a second edge 2^I and 2^II respectively, during joining.

FIG. 4 shows, in cross-section, a fourth embodiment of a first and a second edge 2^I and 2^II respectively, during joining.

FIG. 5 shows, in cross-section, a third and a fourth edge 2^I and 2^IV respectively, during joining.

FIG. 6 shows, in cross-section, a second embodiment of a third and a fourth edge 2^III and 2^IV respectively, during joining.

FIG. 7 shows, in cross-section, a third embodiment of a third and a fourth edge ^2III and 2^IV respectively, during joining.

FIG. 8 shows, in cross-section, a fourth embodiment of a third and a fourth edge 2^III and 2^IV respectively and a vertical assembly joining profile 30, during joining.

FIG. 9 shows, in cross-section, a first and a second edge 2^I and 2^II respectively, during joining.

FIG. 10 shows, in cross-section, a second embodiment of a first and a second edge 2^I and 2^II respectively, during joining.

FIG. 11 shows, in cross-section, a third embodiment of a first and a second edge 2^I and 2^II respectively, during joining.

FIG. 12 shows, in cross-section, a fourth embodiment of a first and a second edge 2^I and 2^II respectively, during joining.

FIG. 13 shows, in cross-section, a third and a fourth edge 2^III and 2^IV respectively, during joining.

FIG. 14 shows, in cross-section, a second embodiment of a third and a fourth edge 2^III and 2^IV respectively, during joining.

FIG. 15 shows, in cross-section, a third embodiment of a third and a fourth edge 2^III and 2^IV respectively, during joining.

FIG. 16 shows, in cross-section, a fourth embodiment of a third and a fourth edge 2^III and 2^IV respectively and a vertical assembly joining profile 30, during joining.

FIG. 17 shows, in cross-section, a fifth embodiment, having a spring part disposed in a cavity.

DETAILED DESCRIPTION OF THE INVENTION

FIG. 1 shows, in cross-section, a first and a second edge 2^I and 2^II respectively, during assembly. The figure shows pans of a flooring material comprising sheet-shaped floor elements 1 with a mainly square or rectangular shape. The floor elements 1 are provided with edges 2, a lower side 5 and an upper decorative layer 3. The floor elements 1 are intended to be joined by means of joining members 10. Such floors floor elements, for example, be constituted of solid wood, fibre board, such as medium density fibre board (MDF), particle board, chip board, or any other construction comprising pieces or particles of wood, including combinations of plastic elements and the particles or pieces of wood. The floor elements 1 are provided with male joining members 101 on a first edge 2^I while a second edge 2^II of the floor elements 1 are provided with a female joining member 10^II. The second edge 2^II is arranged on a side opposite to the first edge 2^I. The male joining member 10^I is provided with a tongue 11 and a lower side 5 groove 12. The female joining member 10^II is provided with a groove 13 and a cheek 14, the cheek 14 being provided with a lip 15. The floor elements 1 are intended to mainly be joined together by tilting the floor element 1 to be joined with an already installed floor element 1 or a row of already installed floor elements 1, with the male joining member 10^I of the floor element 1 angled downwards and that the first edge 21 is allowed to be mainly parallel to the second edge 2^II of the already installed floor element 1 or elements 1. The tongue 11 of the tilted floor element 1 is then inserted into the groove 13 of the female joining member 10^II of the already installed floor element 1 or elements 1, whereby the tilted floor element 1 is turned downwards, with its lower edge as a pivot axis, so that the lip 15 eventually falls into the lower side 5 groove 12 where the decorative upper layer 3 of the floor elements 1 are mainly parallel.

The embodiment shown in FIG. 1 corresponds mainly with the one shown in FIG. 1. The lip 15 and lower side 5 groove 12 are, however, provided with a cam 16 and a cam groove 17 which provides a snap action locking.

The embodiment shown in FIG. 3 corresponds mainly with the one shown in FIGS. 1 and 2 above. The lip 15 and lower side 5 groove 12 are, however, provided with a cam 16 and a cam groove 17 which provides a snap action locking.

The embodiment shown in FIG. 4 corresponds mainly with the one shown in FIG. 1 above. The lip 15 and cheek 14 is however shaped as a thin resilient section which provides a snap action locking.

FIG. 5 shows, in cross-section, a third and a fourth edge 2^II and 2^IV respectively, of a floor element 1 according to any of the FIGS. 1 to 4. The floor elements 1 are provided with a male vertical assembly joining member 10^III on a third edge 2^III while a fourth edge 2^IV is provided with a female vertical assembly joining member 10^IV. The fourth edge 2^IV is placed on a side opposite to the third edge 2^III. The male vertical assembly joining members 10^III are provided with mainly vertical lower cheek surfaces 21 arranged parallel to the closest edge 2. The lower cheek surfaces 21 are intended to interact with mainly vertical upper cheek surfaces 22 arranged on the female vertical assembly joining members 10^IV so that two joined adjacent floor elements 1 are locked against each other in a horizontal direction. The male vertical assembly joining members 10^III are moreover provided with two snapping hooks 23 while the female vertical assembly joining members 10^IV are provided with matching under cuts 24, which by being provided with mainly horizontal locking surfaces limits the vertical movement between two joined adjacent floor elements 1.

The joint between a third and a fourth edge 2^III and 2^IV respectively of two joined floor elements 1 further comprises contact surfaces which are constituted by the horizontal locking surfaces of the under cuts 24 and hooks 23, the mainly vertical upper cheek surfaces 22 lower cheek surfaces as well as upper mating surfaces 25. The joint between two joined floor elements 1 also comprises cavities 6.

The embodiment shown in FIG. 6 corresponds in the main with the one shown in FIG. 5. The male vertical assembly joining members 10^III are, however, provided with only one snapping hook 23 while the female vertical assembly joining members 10^IV are provided with a matching undercut 24, which by being provided with mainly horizontal locking surfaces limits vertical movement between to joined adjacent floor boards 1.

The embodiment shown in FIG. 7 corresponds in the main with the one shown in FIG. 6. The snapping hook 23 on the male vertical assembly joining member 10^III is, however, moved somewhat, inwards in the floor element 1 whereby a guiding angle is formed above the undercut 24 of the female vertical joining member 10^IV.

The embodiment shown in FIG. 8 corresponds mainly with the one shown in FIG. 7. Both the third and the fourth edges 2^III and 2^IV respectively are, however, provided with male vertical assembly joining members 10^III. A vertical assembly joining profile 30, provided with a female vertical assembly joining profile 10^IV on both sides of a vertical symmetry line, is used for joining the two floor elements 1. The female vertical assembly joining members 10^IV of the vertical assembly joining profile 30 are equipped similar to the female vertical assembly joining members 10^IV in FIG. 7 above.

Two adjacent edges 2 of a floor element 1 can at the same time, and in the same turning motion, be joined with a floor element 1 adjacent to the first edge 21 and a floor element 1 adjacent to the third or fourth edge 2^III and 2^IV respectively, when assembling floor elements 1 according to the above described embodiments.

The floor elements 1 according to the present invention most often comprises a core. The core is most often comprised of particles or fibre of wood bonded with resin or glue. It is advantageous to coat the surface closest to the joint in cases where the floor will be exposed to high levels of moisture since the cellulose based material is sensitive to moisture. This coating may suitably incorporate resin, wax or some kind of lacquer. It is not necessary to coal the joint when it is to be glued since the glue itself will protect from moisture penetration. The upper decorative layer 3 is constituted of a decorative paper impregnated with melamine-formaldehyde resin. One or more so called overlay sheets of a-cellulose, impregnated with melamineformaldehyde resin may possibly be placed on top of the decorative layer. The abrasion resistance may be improved by sprinkling one or more of the sheets with hard panicles of for example α-aluminium oxide, silicon carbide or silicon oxide. The lower side 5 may suitably be coated with lacquer or a layer of paper and resin.

FIGS. 9-16 demonstrate the improvement of the radially projected dimension of the length (L) of the groove or undercut and the horizontal rotated radially projected height (L) of the lip or upper cheek surface of the boards of the invention. With respect to FIGS. 9-12, the radially projected dimension, indicated at α, corresponds to the length of the groove 13, while β indicates the horizontal rotated length of lip 15. Additionally, γ indicates the length of the tongue 11, while δ is the horizontal rotated length of the locking groove 12. Because α is greater than γ, and β is greater than δ, adjacent floor elements cannot be assembled horizontally. In other words, because tongue 11 (as well as groove 13) is greater than lip 15 (as well as locking groove 12), the floor elements depicted in these figures can only be assembled by rotating or turning one of the floor elements. Generally, in each of these figures, α is substantially equal to γ and β is substantially equal to δ. This “substantially equal” relationship provides for a close fitting, while limiting movement of adjacent panels once assembled. For example, the difference in dimensions may be from 0.005-5%, or from 0.02-0.5 mm.

In contrast, the floor elements shown in FIGS. 13-16 may be assembled through horizontal motion. Specifically, ε is the length of the undercut 24, while ζ corresponds to the horizontal rotated length of the upper cheek surface 22. Additionally, η indicates the length of the snapping hooks 23, while the horizontal rotated length of the lower cheek surface 21 is specified by θ.

Because ε is less than η and ζ is less than θ, the floor elements can only be assembled through horizontal movement. That is to say, due to the particular dimensions of the undercuts 24, upper cheek surface 22, snapping hooks 23 and lower cheek surface 21, the floor panels of the invention may be joined through substantially vertical movement of one panel with respect to a second panel.

The dimensions ε and η may also be related to the thickness of the floor element itself. For example, the ratio between ε and the thickness (or η and the surface) may be in the range of about 0.025 to 0.2, typically, about 0.05 to about 0.1, and more typically, about 0.07 to 0.09. That is to say, when the thickness is 8 mm, as is common in conventional boards, ε or η would be from 0.2 to 1.5 mm. Additionally, α (or γ) can be at least 2 times greater than β (or δ), while ε (or η) is at least 2 times ζ (or θ).

Moreover, all dimension lines of FIGS. 9-16 are intended to indicate the area taken up by the inserted part as the recesses, such as, the groove 13 and need not be deeper than the tongue 11. Although in some cases, the recesses are deeper than the length of the tongue 11. With particular reference to FIG. 9, β effectively is zero, meaning that there is no undercut when pivoting the panel.

FIG. 17 shows an embodiment of the invention, wherein the snapping hooks 23 include a spring part 32, positioned in a cavity 34 on an edge 2.

As described and shown herein, one embodiment of the invention includes a system of surface elements used to form a surface. The surface element 1 has an upper surface 27 and a lower surface 28, a first edge 2^I and a second edge 2^II, opposite said first edge, joining the upper surface 27 to the lower surface 28. The first edge 2^I and second edge 2^II permit joining to adjacent surface elements by rotational movement, thereby limiting vertical movement therebetween. The surface element also has a third edge 2^III and a fourth edge 2^IV, opposite the third edge 2^III. The third edge 2^III and fourth edge 2^IV permit snap-action locking to an adjacent surface element by relative vertical movement to lock the surface element 1 to an adjacent surface element to limiting vertical movement therebetween. The third edge 2^III can have a plastic spring part 32 positioned in a cavity 34. The distal part of plastic spring part 32 terminates in a snapping hook. The fourth edge 2^IV can have a locking element 36, having a substantially perpendicular projection 38, which locking element 36 extends distally beyond the upper surface 27. Moreover, the upper surface 27 can include a decorative paper impregnated with a resin, hard particles to impart an abrasion resistance to the upper surface; and one or more sheets of alpha-cellulose, impregnated with a resin. The hard particles can be alpha-aluminum oxide, silicon carbide and/or silicon oxide.

Finally, the floor elements of this invention, preferably, comprise vertically-joined edges on at least two sides. For example, when the floor panel has a substantially rectangular shape, such vertically-joined edges may be found on two, three or all four sides. When the vertically-joined edges are located on less than all sides of the floor element, the remaining sides may include, for example, edges joined by rotating or horizontal movement or simple straight edges without a joining profile.

The invention is not limited by the embodiments shown since they can be varied within the scope if the invention.

Claims

1. A system of surface elements forming a surface comprising: a first surface element comprising: an upper surface;a lower surface;a first edge and a second edge, opposite said first edge, joining said upper surface to said lower surface; anda third edge and a fourth edge, opposite said third edge, joining said upper surface to said lower surface;wherein said third edge comprises a separate locking part positioned in a cavity of the third edge, said separate locking part being formed from at least one member selected from the group consisting of a thermoplastic, a thermosetting resin, and a metal;a second surface element, comprising an edge sized and shaped to join with said first edge of said first surface element through relative rotational movement, wherein said first edge of said first surface element and said edge of said second surface element lock said first surface element to said second surface element to limit relative vertical movement; anda third surface element, comprising an edge sized and shaped to join with said third edge of said first surface element only through relative vertical movement, wherein said third edge of said first surface element and said edge of said third surface element lock said first surface element to said third surface element to limit relative vertical movement, and wherein the locking part is disposed along a joint face between the third edge of the first surface element and the edge of the third surface element.

2. The system of claim 1, wherein the surface is a floor.

3. The system of claim 1, wherein the separate locking part comprises a spring part.

4. The system of claim 1, wherein the separate locking part is disposed between core portions of the first and second surface elements.

5. The system of claim 1, wherein the separate locking part comprises a thermoplastic.

6. The system of claim 1, wherein the separate locking part comprises a thermosetting resin.

7. The system of claim 1, wherein the separate locking part comprises metal.

8. A method of forming a surface comprising: providing a first surface element comprising: an upper surface;a lower surface;a first edge and a second edge, opposite said first edge, joining said upper surface to said lower surface; anda third edge and a fourth edge, opposite said third edge, joining said upper surface to said lower surface;providing a second surface element, comprising an edge sized and shaped to join with said first edge of said first surface element through relative rotational movement;joining said first edge of said first surface element to said edge of said second surface element through relative rotational movement;providing a third surface element, comprising an edge sized and shaped to join with said third edge of said first surface element through relative vertical movement;positioning a separate locking part in a cavity formed in the third edge of the first surface element, said separate locking part being formed from at least one member selected from the group consisting of a thermoplastic, a thermosetting resin, and a metal; andjoining said third edge of said first surface element to said edge of said third surface element only through relative vertical movement such that the locking part is disposed along a joint face between the third edge of the first surface element and the edge of the third surface element, wherein said separate locking part locks said first surface element to said third surface element to limit relative vertical movement.

9. A system of surface elements forming a surface comprising: a first surface element comprising: an upper surface;a lower surface;a first edge and a second edge, opposite said first edge, joining said upper surface to said lower surface;a third edge and a fourth edge, opposite said third edge, joining said upper surface to said lower surface, said third edge comprising a first locking surface; anda second surface element, comprising an edge sized and shaped to join with said first edge of said first surface element through relative rotational movement, wherein said first edge of said first surface element and said edge of said second surface element lock said first surface element to said second surface element to limit relative vertical movement; anda third surface element, comprising an upper surface, a lower surface, and a second locking surface sized and shaped to join with said first locking surface of said third edge of said first surface element through relative vertical movement, wherein said first locking surface and said second locking surface lock said first surface element to said third surface element to limit relative vertical movement; anda separate locking part disposed between the first and second locking surfaces of the first and third surface elements, respectively, such that the separate locking part is disposed between upper and lower surfaces of each of the first and third surface elements.

10. The system of claim 9, wherein one of said first locking surface or said second locking surface comprises one or more snapping hooks; and wherein the other of said first locking surface or said second locking surface comprises one or more under cuts.

11. The system of claim 9, wherein said third edge comprises one or more cavity; and wherein the separate locking part is positioned in the cavity.

12. The system of claim 11, wherein said separate locking part is formed from at least one member selected from the group consisting of a thermoplastic, a thermosetting resin, and a metal.

13. The system of claim 9, wherein said edge of said third surface element comprises one or more cavity; and wherein said second locking surface comprises the separate locking part positioned in the cavity.

14. The system of claim 13, wherein said separate locking part is formed from at least one member selected from the group consisting of a thermoplastic, a thermosetting resin, and a metal.

15. A method of forming a surface comprising: providing a first surface element comprising: an upper surface;a lower surface;a first edge and a second edge, opposite said first edge, joining said upper surface to said lower surface;a third edge and a fourth edge, opposite said third edge, joining said upper surface to said lower surface, said third edge comprising a first locking surface; andproviding a second surface element, comprising an edge sized and shaped to join with said first edge of said first surface element through relative rotational movement;joining said first edge of said first surface element to said edge of said second surface element through relative rotational movement;providing a third surface element, comprising a second locking surface sized and shaped to join with said first locking surface of said third edge of said first surface element through relative vertical movement;providing a separate locking part disposed between the first and second locking surfaces of the first and third surface elements, respectively, such that the separate locking part is disposed between upper and lower surfaces of each of the first and third surface elementsjoining said third edge of said first surface element to said edge of said third surface element through relative vertical movement, wherein said first locking surface and said third locking surface lock said first surface element to said third surface element to limit relative vertical movement.

16. The method of claim 15, wherein one of said first locking surface or said second locking surface comprises one or more snapping hooks; wherein the other of said first locking surface or said second locking surface comprises one or more under cuts; andwherein joining said third edge of said first surface element to said edge of said third surface element comprises matingly engaging said one or more snapping hooks with said one or more under cuts.

17. The method of claim 15, wherein said third edge comprises one or more cavity; and wherein joining said third edge of said first surface element to said edge of said third surface element comprises:positioning the separate locking part in the cavity formed in the third edge; andjoining said third edge of said first surface element to said edge of said third surface element only through relative vertical movement, wherein said separate locking part locks said first surface element to said third surface element to limit relative vertical movement.

18. The method of claim 17, wherein said separate locking part being formed from at least one member selected from the group consisting of a thermoplastic, a thermosetting resin, and a metal.

19. The method of claim 15, wherein said edge of said third surface element comprises one or more cavity; and wherein joining said third edge of said first surface element to said edge of said third surface element comprises: positioning the separate locking part in the cavity formed in the edge of said third surface element; andjoining said third edge of said first surface element to said edge of said third surface element through relative vertical movement, wherein said separate locking part locks said first surface element to said third surface element to limit relative vertical movement.

20. The method of claim 19, wherein said separate locking part being formed from at least one member selected from the group consisting of a thermoplastic, a thermosetting resin, and a metal.