MECHANICAL LOCKING DEVICE FOR BUILDING PANELS

Abstract

A set of building panels such as floor panels, including similar or essentially identical building panels. Each building panel having a first mechanical locking device configured to horizontally and vertically lock a first edge of a building panel to a second edge of an adjacent building panel, where the first edge and the second edge preferably are the long edges of the building panels, and a second mechanical locking device configured to horizontally and vertically lock a third edge of a building panel to a fourth edge of an adjacent building panel, where the third edge and the fourth edge preferably are the short edges of the building panels. Each mechanical locking device includes a locking strip including a locking element configured to cooperate with a locking groove. Each locking element has an impact surface and each locking groove comprises an impact surface.

Description

CROSS REFERENCE TO RELATED APPLICATIONS

The present application claims the benefit of Swedish Application No. 2351187-6, filed on Oct. 13, 2023, and of Swedish Application No. 2351308-8, filed on Nov. 16, 2023. The entire contents of each of Swedish Application No. 2351187-6 and Swedish Application No. 2351308-8 are hereby incorporated herein by reference in their entirety.

TECHNICAL FIELD

The present application relates to the field of building panels, such as floor panels, wall panels, furniture components, or similar. More specifically, the present application relates to the field of mechanical locking devices for such building panels.

TECHNICAL BACKGROUND

Building panels, such as floor panels, may typically comprise a mechanical locking device for assembling the building panel with similar or essentially identical building panels such that said building panels are locked together in the assembled position. The mechanical locking device may lock adjacent building panels in a horizontal and/or vertical direction.

For applications or material choices, such as for a Luxury Vinyl Tile (LVT tile), a Stone Plastic (Polymer) Composite panel or Solid Polymer Core panel (SPC panel), or an Expanded Polymer Core panel (EPC panel), also known as Water Proof Core panel or Wood Plastic Composite panel (WPC panel), it may be advantageous to utilize a mechanical locking device which is formed in one piece with the floor panel. Such locking systems are described in the disclosure WO 2021/20661 or WO 2023/106988 and may provide strong locking of the panels and a fast and easy installation of them.

It has been found that a mechanical locking device used for this type of installation and for this type of building panels, and others, may be improved when it comes to, e.g., withstanding vertical pressure. Accordingly, there is room for improvement in the technical field.

U.S. Pat. No. 20,170,254096 A1 discloses a panel having a long edge locking system forming a slide lock system on the long edges. The three set of cooperative locking surface are configured to provide a strong press fit between the locking element and the locking groove. Thereby, the panels can be tightly secured to each other such that displacement along the long edges is prevented.

U.S. Pat. No. 20,170,067261 A1 discloses a panel having a complementary locking means of a second pair of edges which are to be joined to each other by a downward, vertical movement. The locking means comprises in one example a lower latching means comprising a female latching element and a male latching element.

SUMMARY

An object of embodiments of the present invention is to provide improvements over known art.

In a first aspect of the present invention there is provided a set of building panels, such as floor panels, comprising similar or essentially identical building panels wherein each building panel comprises a first mechanical locking device configured to horizontally and vertically lock a first edge of a building panel to a second edge of an adjacent building panel, where the first edge and the second edge preferably are the long edges of said building panels, and a second mechanical locking device configured to horizontally and vertically lock a third edge of a building panel to a fourth edge of an adjacent building panel, where the third edge and the fourth edge preferably are the short edges of said building panels. Each mechanical locking device comprises, at one of the first edge or second edge, and at one of the third edge or fourth edge, a locking strip extending from respective edge in a direction away from said edge, where each locking strip comprises, at its outermost portion, a locking element extending in a direction perpendicular to the extension of the locking strip. Each locking element is configured to cooperate with a locking groove arranged in the other of the first edge or second edge, and in the other of the third edge or fourth edge, such that adjacent building panels are locked in a horizontal direction in an assembled position. Each locking element comprises an impact surface extending from an outer surface of the locking element towards a back surface of the building panel, at an acute angle in relation to the horizontal plane. Each locking groove comprises an impact surface extending from an inner surface of the locking groove towards the back surface of the building panel, at an acute angle in relation to the horizontal plane and configured to cooperate with the impact surface of the locking element in an assembled position, when a force, acting, at least partially, in a vertical direction, is applied to at least one of the building panels.

The force acting, at least partially in the vertical direction, may be a force resulting from a load applied on the building panel in the assembled position. The force may act on the at least one building panel in the assembled position during conventional use, for example when being installed in a room.

The force may be applied on a front surface of at least one the building panels, opposite the back surface of at least one of the building panels. Each first mechanical locking device and each second mechanical locking device may comprise, at one of the first edge or second edge, and at one of the third edge or fourth edge, the locking strip extending from respective edge in a direction away from said edge.

Each first mechanical locking device and each second mechanical locking device may comprise the locking groove arranged in the other of the first edge or second edge, and in the other of the third edge or fourth edge.

At least the cooperating impact surfaces of respective locking element and locking groove are beneficial as they improve the stability and strength of the mechanical locking device, such as the vertical locking strength of the mechanical locking device.

The impact surfaces may also be referred to as support surfaces in the entirety of the present disclosure.

The impact surfaces, or support surfaces, are configured to cooperate with a corresponding impact surface, or support surface, when a force, acting, at least partially, in a vertical direction, is applied to at least one of the building panels in the assembled position. The impact surfaces, or support surfaces, may be configured to provide support during an impact, i.e., a force, acting, at least partially, in a vertical direction, applied to at least one of the building panels. The two impact surfaces may be configured to cooperate with each other, such as being in contact with each other, and support each other, when a force, acting, at least partially, in a vertical direction, is applied to any one of the building panels in the assembled position.

The building panels may be assembled together by means of a pivoting motion.

The building panels may be assembled by a pivoting motion pivoting about an upper portion of the edge of the adjacent building panel.

In an alternative assembling two adjacent building panels may be snapped together. A snapping assembly is achieved by a more horizontal displacement of the building panels being assembled, compared to a pivoting assembly, by pushing on one or both building panels towards each other. A snapping assembly, as well as a pivoting assembly may be suitable for every thickness of a building panel, i.e., for building panels with a thickness between 2 and 20 mm.

The first mechanical locking device and the second mechanical locking device may be configured to be assembled together by means of a pivoting motion, or by a snapping assembly by an essentially horizontal displacement of the building panel being assembled to an adjacent building panel.

The first mechanical locking device and the second mechanical locking device may be configured to be assembled together by means of a pivoting motion of the building panel pivoting about an upper portion of the edge of the adjacent building panel.

In an embodiment, the impact surface of the locking element may be arranged at the acute angle of between and in relation to the horizontal plane. The impact surface of the locking groove may be arranged at the acute angle of between 40° and 70° in relation to the horizontal plane.

Further, the impact surface of the locking element may be essentially parallel to the impact surface of the locking groove, but the impact surface of the locking element may in an alternative embodiment be non-parallel to the impact surface of the locking groove.

For example, the impact surface of the locking element may be arranged at an angle relative to the impact surface of the locking groove, such as 1-20°, such as 1-10°, for example, 1-5°.

The building panel may have a thickness of between 2 and 20 mm, or between 3 and 10 mm, or between 3 and 8 mm.

In an embodiment where the building panel has a thickness of between 3 and 4.5 mm, the impact surface of the locking element may be arranged at the acute angle of between 40° and 60° in relation to the horizontal plane.

In another embodiment where the building panel has a thickness of 4.5 mm or more, e.g., 5 mm or 8 mm, the impact surface of the locking element may be arranged at the acute angle of between 40° and 70° in relation to the horizontal plane.

The locking element may further comprise a locking surface configured to cooperate with a locking surface of the locking groove in which the locking element is arranged in an assembled position. The locking surface of the locking element and the locking surface of the locking groove may be essentially parallel.

In an embodiment, the locking surface of the locking element may be arranged at an acute angle of between 40° and 60°, preferably about 50°, in relation to the horizontal plane.

The mechanical locking device may further comprise, at one of the first edge or second edge, and at one of the third edge or fourth edge, an upper locking tongue extending from respective edge in a direction away from said edge, and configured to be received in and cooperate with an upper tongue groove arranged in the other of the first edge or second edge, and in the other of the third edge or fourth edge. The advantage with the upper locking tongue and the cooperating upper tongue groove is that they together are able to create a tight seal in the upper edge portions of the assembled building panels which may prevent liquid, such as water, to penetrate the mechanical locking device and in turn damage the edges of the building panel.

In an embodiment, the height of the upper locking tongue may be greater than the height of the upper tongue groove in order to create the tight seal between the adjacent building panels. The difference between the height of the locking tongue and the height of the tongue groove may be in the range of 0.01 to 0.2 mm, preferably 0.01 to 0.1 mm, even more preferably 0.01 or 0.05 mm.

In an embodiment, the first mechanical locking device and the second mechanical locking device are the same type of locking device.

In an embodiment, the first mechanical locking device and the second mechanical locking device are configured to lock the building panel to an adjacent building panel in a similar manner.

In an embodiment, the first mechanical locking device and the second mechanical locking device are substantially identical.

The building panel may comprise at least a substrate and a surface layer arranged on the substrate. In an embodiment, the building panel may further comprise a backing layer arranged opposite the surface layer, on the other side of the substrate.

In an embodiment the substrate is a single-layered substrate. At least the impact surface of the locking element and the impact surface of the locking groove may be arranged in the substrate. In an embodiment, the impact surface of the locking element, the locking element, the locking strip, the locking groove and the impact support of the locking groove may be arranged in the substrate. In another embodiment, all features of the mechanical locking device may be arranged in the substrate.

In another embodiment the substrate is a multi-layered substrate. At least the impact surface of the locking element and the impact surface of the locking groove may be arranged in the substrate. In an embodiment, the impact surface of the locking element, the locking element, the locking strip, the locking groove and the impact support of the locking groove may be arranged in the substrate. In another embodiment, all features of the mechanical locking device may be arranged in the substrate.

At least the substrate of the building panel may comprise a polymer-based material. The polymer-based material may be a thermoplastic material. Preferably a substrate made of a thermoplastic-based material may comprise 10-50 wt. %, more preferably 20-40 wt. %, of the thermoplastic material. In some embodiments, the thermoplastic material may be PVC. In some embodiments, the thermoplastic material may be polyvinyl chloride (PVC), polyester, polyethylene (PE), polypropylene (PP), polystyrene (PS), thermoplastic polyurethane (TPU), or polyethylene terephthalate (PET), polyacrylate, methacrylate, polycarbonate (PC), polyvinyl butyral (PVB), polybutylene terephthalate (PBT), or a combination thereof. In some embodiments, the thermoplastic material may be a bioplastic material.

The substrate may further comprise a filler, which may be an inorganic filler or an organic filler. An inorganic filler may be a mineral material, for example calcium carbonate (CaCO₃), limestone, such as chalk, talc, fly ash, barium sulphate (BaSO₄), magnesium oxide (MgO), magnesium chloride, e.g., MgCl₂ and/or magnesium sulphate, e.g., MgSO₄, or a stone material, such as stone powder. An organic filler may be for example a wood material, such as wood fibres or dust, a bamboo material or rice husks. The substrate may comprise 40-90 wt. % filler, or 50-80 wt. % filler.

In an embodiment, the set of building panels may be resilient building panels where the substrate comprising a polymer material, such as a thermoplastic material. The substrate of the building panel may comprise a thermoplastic material, preferably polyvinyl chloride, PVC, and an inorganic filler. In preferred embodiments, the substrate may comprise 20-40 wt. % of the thermoplastic material, such as PVC, and 50-80 wt. % of a filler. The substrate of the building panel may further comprise a thermosetting resin, preferably comprising polyurethane, PU, an epoxy resin, or a melamine-formaldehyde resin.

The substrate may further comprise a plasticizer. A degree of plasticizer in the substrate may be less than 5 wt. %, preferably less than 3 wt. % or less than 1 wt. %.

The substrate and/or the building panel may have a modulus of elasticity of 1-10 GPa, such as 2-8 GPa, preferably determined in accordance with ISO 178: 2010/A1:2013.

The substrate may be dense by not being foamed. In some embodiments, however, the substrate may be foamed. Preferably, the foaming may be incorporated in the thermoplastic material by means of a blowing agent or foaming agent. Generally herein, the substrate may, for example, be extruded.

The substrate and/or the building panel may be formed of one or several layers. For example, the substrate may be included in an AB, ABA or ABC layer arrangement comprising two or three layers. Here, the same letter (A) and different letters (A, B or C) refer to the layers having substantially the same material composition and different material compositions, respectively. For example, at least two layers may be attached, such as laminated, to each other or at least two layers may be bonding layers bonded to each other by an adhesive. In some examples, at least two layers may be coextruded.

In alternative embodiment the substrate may instead comprise, or may be, a wood-based substrate, such as an HDF board, an MDF board, a particle board or a plywood board.

In other alternative embodiments the substrate may instead comprise a polyurethane, PUR, thermoset and, optionally, MgO.

The surface layer of the building panel may comprise a decorative layer. Such a decorative layer may be a decorative foil comprising a thermoplastic material. The thermoplastic material of the decorative layer may be or comprise PVC, polyester, PP, PE, PS, PU, PET, polyacrylate, methacrylate, polycarbonate, polyvinyl butyral, polybutylene terephthalate, or a combination thereof. The decorative foil may preferably be printed, for example by direct printing, rotogravure, or digital printing. The decorative layer may be a single or multi layered decorative layer.

In other embodiments the decorative layer may be a printed sheet, or a printed sheet in combination with a primer, e.g., a paper sheet. The decorative layer may further be a printed decor which is printed directly on the substrate.

In other embodiments the decorative layer may be the surface layer, e.g., when the surface layer is a wood based layer, such as a wood veneer of varying thicknesses, or an impregnated or unimpregnated paper sheet with or without a decorative print.

In yet another embodiment the surface layer may be formed by a powder layer comprising, e.g., wood fibres, a thermosetting binder, pigment, etc. The surface layer of the building panels may further comprise a wear layer such as a film, foil or a lacquer. The wear layer may be a single or multi layered wear layer. The wear layer may comprise thermoplastic material. The thermoplastic material may be PVC, polyester, PP, PE, PS, PU, PET, polyacrylate, methacrylate, polycarbonate, polyvinyl butyral, polybutylene terephthalate, or a combination thereof. The wear layer may further comprise wear resistant particles, such as aluminium oxide particles or similar.

The building panel may further comprise a backing layer. Such a backing layer may be configured to balance the building panel. The backing layer may be a paper sheet, a wood veneer, a powder layer or any other suitable backing layer.

BRIEF DESCRIPTION OF THE DRAWINGS

Embodiments of the invention will be described in the following: reference being made to the appended drawings which illustrate non-limiting embodiments of how the inventive concept can be reduced into practice.

FIG. 1 schematically illustrate a building panel according to an embodiment of the inventive concept,

FIG. 2A-2C illustrate an assembly of a plurality of similar or essentially identical building panels,

FIG. 2D illustrates the building panels in FIG. 2A-2C in the assembled position,

FIG. 3A illustrates a cross section of an edge of the building panel including a first connecting means of a mechanical locking device according to an embodiment of the inventive concept,

FIG. 3B illustrates a cross section of an edge, opposite the edge in FIG. 3A, of the building panel including a second connecting means of the mechanical locking device,

FIG. 4A-4C illustrate an assembly of two adjacent building panels including a mechanical locking device according to an embodiment of the present inventive concept,

FIG. 5A illustrates two adjacent building panels including a mechanical locking device according to an embodiment of the present inventive concept, in an assembled position,

FIG. 5B is a detailed view of FIG. 5A,

FIG. 5C is a detailed view of FIG. 5A,

FIG. 6 illustrates two adjacent building panels including a mechanical locking device according to an embodiment of the present inventive concept, in an assembled position,

FIG. 7 illustrates two adjacent building panels including a mechanical locking device according to another embodiment of the present inventive concept, in an assembled position,

FIG. 8 illustrates two adjacent building panels including a mechanical locking device according to yet another embodiment of the present inventive concept, in an assembled position,

FIG. 9 illustrates two adjacent building panels including a mechanical locking device according to an embodiment of the present inventive concept, in an assembled position,

FIG. 10 illustrates two adjacent building panels including a mechanical locking device according to another embodiment of the present inventive concept, in an assembled position,

FIG. 11 illustrates two adjacent building panels including a mechanical locking device according to yet another embodiment of the present inventive concept, in an assembled position,

FIG. 12 illustrates two adjacent building panels including a mechanical locking device according to an embodiment of the present inventive concept, in an assembled position,

FIG. 13 illustrates two adjacent building panels including a mechanical locking device according to an embodiment of the present inventive concept, in an assembled position,

FIG. 14 illustrates two adjacent building panels including a mechanical locking device according to another embodiment of the present inventive concept, in an assembled position,

FIG. 15 illustrates two adjacent building panels including a mechanical locking device according to yet another embodiment of the present inventive concept, in an assembled position,

FIG. 16 illustrates two adjacent building panels including a mechanical locking device according to an embodiment of the present inventive concept, in an assembled position,

FIG. 17 illustrates two adjacent building panels including a mechanical locking device according to another embodiment of the present inventive concept, in an assembled position,

FIG. 18 illustrates two adjacent building panels including a mechanical locking device according to yet another embodiment of the present inventive concept, in an assembled position,

FIGS. 19A-19D illustrated an alternative assembly of two adjacent building panels according to an embodiment of the present inventive concept,

FIGS. 20A-20B are illustrations of a test set up used in one of the tests.

FIGS. 21A-21C are photographs of a first test performed on two assembled building panels, and

FIGS. 22A-22C are photographs of a third test performed on two assembled building panels.

DETAILED DESCRIPTION OF EMBODIMENTS

Specific embodiments of the invention will now be described with reference to the accompanying drawings. This invention may, however, be embodied in many different forms and should not be construed as limited to the embodiments set forth herein; rather, these embodiments are provided so that this disclosure will be thorough and complete, and will fully convey the scope of the invention to those skilled in the art. The terminology used in the detailed description of the embodiments illustrated in the accompanying drawings is not intended to be limiting of the invention. In the drawings, like numbers refer to like elements. Generally, in this disclosure, terms like “below” or “lower” typically implies closer to the back surface of the panel or a plane thereof, whereas “above” or “upper” implies closer to the front surface or a plane thereof. Further, the thickness direction of the panel is defined as the vertical direction when the panel lays flat on a surface. The horizontal and vertical directions are the applicable definition when the building panel is laid flat on, e.g., a floor. Instead of horizontal and vertical directions, the description will also refer to a direction parallel with extension of the front surface of the building panel and a direction perpendicular to the extension of the front surface of the building panel. When a building panel is lays flat on, e.g., a floor, the horizontal direction is the same as the direction parallel with the extension of the front surface of the building panel and the vertical direction is the same as the direction perpendicular to the extension of the front surface of the building panel.

By “horizontal plane” is meant a plane, which extends parallel to the outer main surface of the surface layer, or in examples wherein no surface layer is provided, a plane, which extends parallel to an upper surface of the substrate. Immediately juxta-posed upper parts of two adjacent joint edges of two joined building panels together define a “vertical plane”, perpendicular to the horizontal plane.

With reference to the drawings, a building panel 1 is illustrated in FIG. 1. The building panel 1 may for example be a floor panel, a wall panel, a ceiling panel, a furniture element, or similar. When the building panel 1 is assembled into a larger unit, such as floor panels into a floor, similar or essentially identical building panels are used. Thus, every building panel 1 includes the similar or essentially identical components arranged at the same location.

The building panel 1 includes four side edges 2a-2d, a front surface 6a and a back surface 6b. The building panel 1, as illustrated, further includes a substrate 7 and a surface layer 8 arranged on one side of the substrate 7. The surface layer 8 may preferably be a decorative surface layer. The surface layer 8 is configured to face a user in an installed position. The surface layer 8 is an optional layer. If no surface layer 8 is present it is possible, if desirable, to provide the substrate 7 with a decorative feature, e.g., a print or the like.

In an embodiment the surface layer 8 may comprise a decorative layer. The decorative layer may be a colored powder layer, a paper sheet, a polymer-based sheet, a wood-based sheet, a wood veneer, a cork-based sheet or a fabric, woven or non-woven. Such layer may further be printed.

Further, the surface layer 8 may comprise a wear layer, such as a wear resistant foil, a wear layer having wear resistant particles and/or a lacquered layer and/or coating layer.

The substrate 7 may be a single-layer substrate or a multi-layer substrate. A multi-layer substrate may include different layers to fulfil different features of the building panel, for example, layers with the purpose of providing the building panel with the desirable strength, hardness and/or balancing properties to name a few.

The substrate 7 may be a polymer-based substrate, comprising one of several polymer-based materials, a wood-based substrate, e.g., HDF or MDF, or a mineral-based substrate, e.g., MgO. The substrate 7 may further comprise one or several fillers and/or other additives.

The substrate 7 may comprise a thermoplastic material and a filler. For example, the thermoplastic material may be chosen from a group comprising polyvinyl chloride (PVC), polyethylene terephthalate (PET), polyvinyl butyral (PVB), polybutylene terephthalate (PBT), polyethylene (PE), polystyrene (PS), polypropylene (PP), polycarbonate (PC), polyvinyl acetate (PVAc), ethylene-vinyl acetate (EVA), polyacrylate methacrylate, polymethylmethacrylate (PMMA), acrylonitrile butadiene styrene (ABS), thermoplastic polyurethane (TPU), and/or a combination thereof. The filler may be an organic filler or inorganic filler. An organic filler may be fibres of wood, coconut or bamboo and rice husks. An inorganic filler may be calcium carbonate (CaCO3), barium sulphate (BaSO4), limestone, talc, fly ash, MgO, stone material and/or a combination thereof.

In an embodiment, the substrate 7 may comprise 10-40 wt. %, or 15-35 wt. %, of the thermoplastic material, such as PVC, and 50-80 wt. % of an inorganic filler.

A degree of plasticizer in the substrate 7 may be less than 5 wt. %, preferably less than 3 wt. % or less than 1 wt. % and may be in the range of 0.1-5 wt. %, 0.5-5 wt. %, or 0.5-3 wt. %. Generally herein, the substrate 7 may be dense or, alternatively, foamed. In any embodiment herein, the substrate 7 and/or the building panel 1 per se, may have a modulus of elasticity of 2-12 GPa, such as 4-9 GPa or 3-7 GPa.

The building panel 1 preferably has a thickness between 2 and 20 mm, or between 3 and 10 mm, or between 3 and 8 mm, or between 3 and 5 mm. In an embodiment the building panel 1 has a thickness of between 3.5 mm and 5 mm.

In order to lock adjacent building panels 1, 1′, 1″ together, each building panel 1 includes a first mechanical locking device 10 arranged along the first edge 2a and the opposite second edge 2b, where the first and second edge 2a, 2b preferably are the long edges of the building panel 1, and a second mechanical locking device 10′ arranged along the third edge 2c and the fourth edge 2d, where the third and fourth edge 2c, 2d preferably are the short edges of the building panel 1. Each mechanical locking device 10, 10′ is configured for horizontal and vertical locking of similar or essentially identical building panels in an assembled position by means of a pivoting motion and/or horizontal displacement.

The first mechanical locking device 10 includes at the first edge 2a connecting means 12a and at the second edge 2b connecting means 12b which are compatible with the connecting means 12a at the first edge 2a. The same goes for the second mechanical locking device 10′ which includes at the third edge 2c connecting means 12c which are compatible with connecting means 12d at the fourth edge 2d.

Illustrated in FIGS. 2A-2D is a possible assembly method of a set of building panels 1, 1′, 1″. There are, however, other possible ways of assembling such set.

In a first step, two building panels 1, 1′ are assembled along the third and fourth edge 2c, 2d, i.e., the short edges in the illustrated example. This is achieved by lifting the fourth edge 2d of the first building panel 1 and arranging the connecting means 12c of the opposite third edge 2c in the connecting means 12d of the fourth edge 2d of the second building panel 1′, such that the two connecting means 12c, 12d are able to cooperate to lock the two adjacent building panels 1, 1′. The fourth edge 2d of the first building panel 1 is then lowered down such that a pivoting motion around the cooperating connecting means 12c, 12d of the third and fourth edge 2c, 2d is achieved. During the pivoting motion and into the assembled position, where the two building panels 1, 1′ are arranged flush with each other, the cooperating connecting means 12c, 12d of each edge 2c, 2d locks the two adjacent edges 2c, 2d of the two building panels 1, 1′ together. The pivoting motion may pivot around an upper portion of the edge of the adjacent building panel. In the shown example of FIG. 2A, the pivoting motion may pivot around an upper portion 4b of the fourth edge 2d of the second building panel 1′. The pivoting motion may also be referred to as a pivoting assembly PA. In the assembled position of the short edges, the connecting means 12c of the second mechanical locking device 10′ arranged in the third edge 2c of the first building panel 1 is locked to the connecting means 12d of the second mechanical locking device 10′ arranged in the fourth edge 2d of the second building panel 1′, the uppermost part of the third edge 2c of the first building panel 1 are juxtaposed creating a seal S, preferably a tight seal, with the uppermost part of the fourth edge 2d of the second building panel 1′, and the two adjacent building panels 1, 1′ are locked in at least a horizontal direction.

In a second step, the first and second building panel 1, 1′ are assembled to the third building panel 1″, by means of the first edge 2a of the first and second building panel 1, 1′ and the second edge 2b of the third building panel 1″, i.e., the long edges in the illustrated example. This is achieved by lifting the second edge 2b of the first and second building panel 1, 1′ and arranging the connecting means 12a of the opposite first edge 2a in the connecting means 12b of the second edge 2b of the third building panel 1″, such that the two connecting means 12a, 12b are able to cooperate to lock the adjacent building panels 1, 1′, 1″. The second edge 2b of the first and second building panel 1, 1″ is then lowered down such that a pivoting motion around the cooperating connecting means 12a, 12b of the first and second edge 2c, 2d is achieved. During the pivoting motion and into the assembled position, where the building panels 1, 1′, 1″ are arranged flush with each other, the cooperating connecting means 12a, 12b of each edge 2a, 2b locks the two adjacent edges 2a, 2b of the building panels 1, 1′, 1″ together. The pivoting motion may pivot around an upper portion of the edge of the adjacent building panel. In the shown example of FIG. 2C, the pivoting motion may pivot around an upper portion 4b of the second edge 2b of the third building panel 1″. The pivoting motion may also be referred to as a pivoting assembly PA. In the assembled position of the long edges, the connecting means 12a of the first mechanical locking device 10 arranged in the first edge 2a of the first and second building panel 1, 1′ is locked to the connecting means 12b of the first mechanical locking device 10 arranged in the second edge 2b of the third building panel 1″, the uppermost part of the first edge 2a of the first and second building panel 1, 1′ are juxtaposed creating a seal S, preferably a tight seal, with the uppermost part of the second edge 2b of the third building panel 1″, and the adjacent building panels 1, 1′, 1″ are locked in at least a horizontal direction.

A more detailed view of the pivoting assembly PA is illustrated in FIGS. 4A-4C.

In an alternative installation (not shown) the first building panel may be simultaneously assembled to the second and third building panel, in which the pivoting assembly in the short edges are achieved simultaneously with the pivoting assembly in the long edges.

The detailed description of embodiments below is based on the assembled position. Since all building panels 1, 1′, 1″ are similar or essentially identical, all features of the mechanical locking device are present on each building panel 1, 1′, 1″.

The first mechanical locking device 10 and the second mechanical locking device 10′ may be similarly, or at least essentially similarly, configured.

The first mechanical locking device 10 and the second mechanical locking device 10′ may be identical, or at least essentially identical.

Further, the first mechanical locking device 10 and the second mechanical locking device 10′ may be substantially the same type of locking device. Therefore, the below description together with FIGS. 3A-18, are embodiments of both the first mechanical locking device and the second mechanical locking device, from now on called just the mechanical locking device.

FIG. 3A illustrate a cross section of the mechanical locking device 10 arranged, preferably, along the second edge 2b and the fourth edge 2d of the building panel 1 whereas FIG. 3B illustrate a cross section of the mechanical locking device 10 arranged preferably along the first edge 2a and the third edge 2c of the building panel 1. To simplify the description of the mechanical locking device 10, the illustration of FIG. 3A is described as being the second edge 2b, but may, as described above, also correspond to the fourth edge 2d. Respectively, the illustration of FIG. 3B is described as being the first edge 2a, but may, as described above, also correspond to the third edge 2c.

So, the mechanical locking device 10 in FIG. 3A comprises a locking strip 15, preferably integrally formed in the edge 2b of the building panel 1. The locking strip 15 is arranged in a lower edge portion 4a of the edge 2b, projecting outwards from the lower edge portion 4a in a direction substantially parallel to the front surface 6a of the building panel 1.

The locking strip 15 has an elongated shape and includes, at the outermost end of the locking strip 15, a locking element 16. The outermost end may be a most distal end of the locking strip 15, as seen from the vertical plane. The vertical plane is formed in the assembled state by a locking surface 30 of an upper edge portion 4b, configured to cooperate with a corresponding opposite upper locking surface 45 of the upper edge portion 5b of the adjacent building panel, illustrated as an essentially vertical surface forming the vertical plane. In the non-assembled position as in FIG. 3A, the outermost end of the locking strip 15 may be a most distal end of the locking strip as seen from the locking surface 30. The locking element 16 extends in a direction perpendicular to the extension of the locking strip 15, at least partially in a direction towards the front surface 6a of the building panel 1.

The locking element 16 is configured to be received in a locking groove 32 arranged in the edge 2a of an adjacent building panel 1 during the assembly of two building panels 1. The locking element 16 and the locking groove 32 are together configured to lock the adjacent building panels 1 in at least the horizontal direction.

The locking element 16 comprises a locking surface 18 which is configured to cooperate, and preferably be in contact, with a corresponding locking surface 34 arranged in the locking groove 32. The two locking surfaces 18, 34 are together configured to lock the adjacent building panels 1 in at least the horizontal direction. The locking surface 18 of the locking element 16 is arranged with an acute angle α in relation to the plane extending parallel to the front surface 6a of the building panel 1, in the illustrated examples parallel to the horizontal plane. The acute angle α is preferably between 40° and 60°, even more preferably about 50°. The corresponding locking surface 34 in the locking groove 32 is preferably substantially parallel to the locking surface 18 of the locking element 16.

The locking surface 18 of the locking element 16 is located in an upper portion of the locking element 16. It is further arranged to face towards the edge 2b and the rest of the building panel 1. The locking surface 18 of the locking element 16 may extend between an upper surface 19a of the elongated part 19 of the locking strip 15 and an upper surface 20a, preferably an uppermost surface, of the locking element 16.

The locking element 16 further comprises an impact surface 22 which is configured to cooperate with a corresponding impact surface 38 arranged in the locking groove 32. The two impact surfaces 22, 38 are together configured to cooperate with each other, preferably be in contact with each other, and support each other, when a force, acting, at least partially, in a vertical direction, is applied to any one of the building panels 1, in the assembled position.

The force acting, at least partially in the vertical direction, may be a force resulting from a load applied on the building panel 1 in the assembled position. The force may act on the at least one building panel 1 in the assembled position during conventional use, for example when being installed in a room.

The force may be applied on the front surface 6a of at least one the building panels 1, opposite the back surface of at least one of the building panels 1.

The load, and the resulting force, may applied by footsteps, loads from furniture and the like, loads from objects being transported, loads form objects falling on the top surface, etc., on the building panel 1 in the assembled position, for example, when installed to form a flooring in a room. The force may originate from dynamic loads and/or static loads. The force may be such forces conventionally occurring during normal use, for example when installed as a flooring in a room. The force may originate from a permanent or temporary load on the building panel 1 in the assembled position.

Such force and/or load may be referred to as an impact impacting on the mechanical locking devices. Such impact may activate the impact surfaces 22, 38 of the mechanical locking device, such that the impact surfaces 22, 38 cooperate with each other, such as contact each other.

The impact surface 22 and the impact surface 38 may also be referred to as a support surface 22 and a support surface 38, respectively, in the present disclosure.

The impact surface 22 of the locking element 16 is located in a lower portion of the locking element 16. It is further arranged to face away from the edge 2b and the rest of the building panel 1. For building panels arranged on a sub-floor, the impact surface 22 of the locking element 16 is arranged to face the sub-floor. The impact surface 22 of the locking element 16 may extend between a lower surface 19b of the elongated part 19 of the locking strip 15 and an outer surface 20b, preferably an outermost surface, of the locking element 16. The outer surface 20b may be a distal surface of the locking element 16, such as a most distal surface of the locking element 16, as seen from the vertical plane. In the non-assembled position as in FIG. 3A, the outer surface 20b of the locking element 16 may be a distal surface, such as a most distal surface, of the locking element 16 as seen from the locking surface 30 of the upper edge portion 4b. The impact surface 22 may extend from the outer surface 20b of the locking element 16 in a direction towards the back surface 6b of the building panel 1, and preferably in a direction towards the building panel in which the impact surface 22 is arranged.

The impact surface 22 of the locking element 16 is arranged with an acute angle β in relation to the plane extending parallel to the front surface 6a of the building panel 1, or to the horizontal plane. The acute angle β is preferably between 40° and 70°. Depending on the thickness of the building panel 1 the acute angle β may vary. In an embodiment, when the building panel has a thickness of between 3 and 4.5 mm, the impact surface 22 of the locking element 16 may be arranged at the acute angle β of between 40° and 60° in relation to the horizontal plane. In an alternative embodiment, when the building panel 1 has a thickness of 4.5 mm or more, e.g., 5 mm or 8 mm, the impact surface 22 of the locking element 16 may be arranged at the acute angle β of between 40° and 70° in relation to the horizontal plane.

The impact surface 22 of the locking element 16 is in the illustrated example a continuous surface but may in other embodiments have two or more sections arranged at different angles, see e.g. FIGS. 10 and 11. Thus, it is possible that one or several sections of such impact surface is/are configured to cooperate, and even be in contact, with the corresponding impact surface of the locking groove in the adjacent building panel.

The elongated part 19 of the locking strip 15 may be able to flex in a direction perpendicular to the extension of the elongated part 19, or in the vertical direction. A flexible locking strip 15 may be configured to create a pretension in the locking surfaces 18, 34 of the mechanical locking device 10 such that the edges 2a, 2b of two adjacent building panels 1 are in contact with each other, in the assembled position. The pretension may be created by the two locking surfaces 18, 34 of the locking element 16 and the locking groove 32 respectively, which are in the assembled position in contact with each other.

A pretension, in the assembled position, between the two locking surfaces 18, 34 of the locking element 16 and the locking groove 32 respectively, may also be created without a flexible locking strip 15, e.g., by having a flexible layer arranged under the building panel during installation.

At an inner portion of the locking strip 15 and above the locking strip 15 there is arranged a tongue groove 24. The tongue groove 24 is configured to cooperate with a locking tongue 40 arranged in the edge 2a of the adjacent building panel 1. The tongue groove 24 and the locking tongue 40 are together configured to lock the adjacent building panels 1 in at least the vertical direction.

The tongue groove 24 comprises an upper surface 25 which is configured to cooperate with a corresponding upper surface 41 of the locking tongue 40. The two upper surfaces 25, 41 are together configured to lock the adjacent building panels 1 in at least the vertical direction.

Arranged above the tongue groove 24 is an upper locking tongue 27. The upper locking tongue 27 is preferably integrally formed in the edge 2b of the building panel 1 and extends out from the edge 2b of the building panel 1. The upper locking tongue 27 is configured and shaped to be received in an upper tongue groove 42 arranged in the edge 2b of the adjacent building panel 1. The upper locking tongue 27 and the upper tongue groove 42 are together configured to lock the adjacent building panels in at least the vertical direction. The upper locking tongue 27 and the upper tongue groove 42 are together further configured to create a tight seal TS such that any liquid, e.g., water, is prevented, or at least obstructed, from penetrating further into the building panel 1. In order to create the desirable tight seal TS it is preferred that the height h1 of the upper locking tongue 27 is greater than, or at least the same as, the height h2 of the upper tongue groove 42. The difference between the height h1 of the upper locking tongue 27 and the height h2 of the upper tongue groove 42 is in the range of 0.01 to 0.2 mm, preferably 0.01 to 0.1 mm, even more preferably 0.01 or 0.05 mm. The height h1 of the upper locking tongue 27 is preferably between 0.2 and 2.0 mm, or between 0.2 and 1.0 mm.

The upper locking tongue 27 comprises an upper surface 28 which is configured to cooperate with an upper surface 43 the upper tongue groove 42. The upper surface 28 of the upper locking tongue 27 and the upper surface 43 of the upper tongue groove 42 are together configured to create the tight seal TS and lock the adjacent building panels 1 at least in the vertical direction.

The upper locking tongue 27 and the corresponding upper tongue groove 42 are optional features, and embodiments without these features are illustrated in FIGS. 6-12 and 15-18. However, it is possible to add or remove the upper locking tongue 27 and the corresponding upper tongue groove 42 with every embodiment described herein.

In the upper edge portion 4b, above the upper locking tongue 28, there is provided an upper locking surface 30, illustrated as an essentially vertical surface. The locking surface 30 is configured to cooperate with a corresponding opposite upper locking surface 45, illustrated as an essentially vertical surface forming the vertical plane in the assembled position, arranged in the upper edge portion 5b of the adjacent building panel 1′. The two locking surfaces 30, 45 are configured to cooperate and preferably be in contact with each other in the assembled position. The upper locking surface 30 of the first building panel 1 and the upper locking surface 45 of the adjacent building panel 1′ are configured to create the seal S, as illustrated in FIG. 2B and 2D.

The mechanical locking device 10 in FIG. 3B comprises locking groove 32 which is configured to receive the locking strip 15 with the locking element 18 of the adjacent building panel 1, as described above. The locking groove 32 is arranged in a lower edge portion 5a of the edge 2a, extending inwards, in a direction substantially parallel to the front surface 6a of the building panel 1, into the building panel 1. The locking groove 32 further extends, at an innermost end of the locking groove 32, up towards the front surface 6a of the building panel 1, in which space the locking element 18 is to be received.

The locking groove 32 and the locking element 16 are together configured to lock the adjacent building panels 1 in at least the horizontal direction.

The locking groove 32 comprises a locking surface 34 which is configured to cooperate, and preferably be in contact, with the corresponding locking surface 18 of the locking element 16. The two locking surfaces 18, 34 are together configured to lock the adjacent building panels 1 in at least the horizontal direction. The locking surface 34 of the locking groove is preferably essentially parallel to the locking surface 18 of the locking element 16. Thus, the locking surface of the locking groove may be arranged with an acute angle δ in relation to the plane extending parallel to the front surface 6a of the building panel 1, or to the horizontal plane. The acute angle δ is preferably between 40° and 60°, even more preferably about 50°.

The locking surface 34 of the locking groove 32 is located in an upper portion of the locking groove 32. It is further arranged to face in towards the rest of the building panel 1. The locking surface 34 of the locking groove 32 may extend between an upper surface 35 of the locking groove 32, which is opposite the upper surface 19a of the elongated part 19 of the locking strip 15 of the adjacent building panel 1 in the assembled position, and an upper surface 36, preferably an uppermost surface, of the locking groove 32, which is opposite the upper surface 20a of the locking element 16 of the adjacent building panel 1 in the assembled position.

The locking groove 32 further comprises an impact surface 38 which is configured to cooperate with the corresponding impact surface 22 of the locking element 16. The two impact surfaces 22, 38 are together configured to cooperate with each other, be in contact with and support each other, when a force, acting, at least partially, in a vertical direction, is applied to any one of the building panels 1, in the assembled position.

The impact surface 38 and the impact surface 22 may be referred to as a support surface 38 and a support surface 22 in the present disclosure.

The impact surface 38 of the locking groove 32 may be parallel to the impact surface 22 of the locking element 16, alternatively the impact surface 38 of the locking groove 32 may be non-parallel to the impact surface 22 of the locking element 16.

The impact surface 38 of the locking groove 32 is located in a lower portion of the locking groove 32. It is further arranged to face away from the rest of the building panel 1. The impact surface 38 may extend from an inner surface 36b, preferably an innermost surface, of the locking groove 32 in a direction towards, and in some embodiments all the way to, the back surface 6b of the building panel 1, and preferably in a direction away from the building panel 1.

The inner surface 36b may be a distal surface of the locking groove 32, such as a most distal surface of the locking grove 32, as seen from the vertical plane. In the non-assembled position as in FIG. 3B, the inner surface 36b of the locking groove 32 may be a distal surface, such as a most distal surface, of the locking groove 32 as seen from the locking surface 45 of the upper edge portion 5b.

The impact surface 38 may be arranged with an acute angle ϕ in relation to the plane extending parallel to the front surface 6a of the building panel 1, or to the horizontal plane. The acute angle ϕ is preferably between 40° and 70°. Depending on the thickness of the building panel 1 the acute angle ϕ may vary. In an embodiment, when the building panel has a thickness of between 3 and 4.5 mm, the impact surface 38 of the locking groove 32 may be arranged at the acute angle β of between 40° and 60° in relation to the horizontal plane. In an alternative embodiment, when the building panel 1 has a thickness of 4.5 mm or more, e.g., 5 mm or 8 mm, the impact surface 38 of the locking groove 32 may be arranged at the acute angle ϕ of between 40° and 70° in relation to the horizontal plane.

The impact surface 38 of the locking groove 32 is in the illustrated example a continuous surface but may in other embodiments, see e.g., FIG. 11, have two or more sections arranged at different angles. Thus, it is possible that one or several sections of such impact surface is/are configured to cooperate with the corresponding impact surface of the locking element in the adjacent building panel.

At a lowermost end of the impact surface 38 of the locking groove 32 there may be provided a chamfer 39, preferably a vertical chamfer, extending from the impact surface 38 to the back surface 6b of the building panel 1. This chamfer 39 is an optional feature but may be beneficial to have for installation properties. For example, if it is desirable to design the impact surfaces 38 with an acute angle β, ϕ of between 40° and 45° and parallel to each other, it may be beneficial to remove material, shorten the impact surface 38 of the locking groove 32, and have the chamfer 39 in order to decrease the risk that the features of the mechanical locking device 10 arranged in the first or third edge 2a, 2c to abut features of the mechanical locking device 10 arranged in the second or fourth edge 2b respectively during the assembly of building panels 1. The height H3 of the chamfer 39 may vary depending on the acute angle β, ϕ, the thickness of the building panel 1 and possibly other features of the mechanical locking device 10, see e.g., FIG. 9. In an embodiment where the building panel has a thickness of 3.5 mm and the impact surfaces 22, 38 are arranged with the angles of between 40° and 70° a preferred maximum height H3 may be 0.6 mm. In an embodiment where the building panel has a thickness of 5 mm and the impact surfaces 22, 38 are arranged with the angles of between 40° and 70° the maximum height H3 may be 1.4 mm.

Opposite the locking groove 32, in the horizontal direction, a locking tongue 40 is arranged, which is preferably integrally formed in the edge 2a of the building panel 1 and which extends out from the edge 2a. The locking tongue 40 is configured and designed to be received in the tongue groove 24 arranged in the edge 2b of the adjacent building panel 1. The tongue groove 24 and the locking tongue 40 are together configured to lock the adjacent building panels 1 in at least the vertical direction.

The locking tongue 40 comprises an upper surface 41 which is configured to cooperate with the corresponding upper surface 25 of the tongue groove 24. The two upper surfaces 25, 40 are together configured to lock the adjacent building panels 1 in at least the vertical direction.

Arranged above the locking tongue 40 is an upper tongue groove 42. The upper tongue groove 42 extends into the edge 2a of the building panel, preferably as a continuation of the upper surface 40 of the locking tongue 40. The upper tongue groove 42 is configured to receive the upper locking tongue 27 arranged in the edge 2b of the adjacent building panel 1. The upper tongue groove 42 and the upper locking tongue 27 are together configured to lock the adjacent building panels in at least the vertical direction. The upper tongue groove 42 and the upper locking tongue 27 are together further configured to create the tight seal TS such that any liquid, e.g. water, is prevented, or at least obstructed, from penetrating further into the building panel 1. In order to create the desirable tight seal TS it is preferred that the height h1 of the upper locking tongue 27 is greater than, or at least the same as, the height h2 of the upper tongue groove 42. The difference between the height h1 of the upper locking tongue 27 and the height h2 of the upper tongue groove 42 is in the range of 0.01 to 0.2 mm, preferably 0.01 to 0.1 mm, even more preferably 0.01 or 0.05 mm.

The upper tongue groove 42 comprises an upper surface 43 which is configured to cooperate with the upper surface 28 of the upper locking tongue 27. The upper surface 43 of the upper tongue groove 42 and the upper surface 28 of the upper locking tongue 27 are together configured to create the tight seal TS and lock the adjacent building panels 1 at least in the vertical direction.

The upper locking tongue 27 and the corresponding upper tongue groove 42 are optional features, and embodiments without these features are illustrated in FIGS. 6-12 and 15-18. However, it is possible to add or remove the upper locking tongue 27 and the corresponding upper tongue groove 42 with every embodiment described herein.

In the upper edge portion 5b, above the upper tongue groove 42, there is provided an essentially upper locking surface 45. The locking surface 45 is configured to cooperate with the corresponding opposite essentially upper locking surface 30 arranged in the upper edge portion 4b of the adjacent building panel 1. The two locking surfaces 30, 45 are configured to cooperate and preferably be in contact with each other in the assembled position, thereby forming the vertical plane. The upper locking surface 30 of the first building panel 1 and the upper locking surface 45 of the adjacent building panel 1′ are configured to create the seal S, as illustrated in FIG. 2B and 2D.

FIGS. 4A-4C illustrate a more detailed view of the cross section of the mechanical locking device during the pivoting assembly PA. The pivoting motion may begin when the locking tongue 40 is at least partially arranged in the tongue groove 24 and the building panel 1 to be assembled is arranged at an angle compared to the adjacent building panel 1′. The building panel 1 is then pivoted down such that the locking tongue 40 is displaced further into the tongue groove 24 and the locking element 16 of the locking strip 15 is displaced into the locking groove 32, and the angle, in which the building panel 1 being pivoted is arranged, is decreased. Further, the upper locking tongue 27 (if present) is displaced into the upper tongue groove 42 in order to create the tight seal TS. When the pivoting motion has resulted in the assembled position the vertical surfaces 30, 45 of the upper edge portion 4b, 5b are preferably cooperating, and even more preferably in contact with each other in order to create the seal S and the two adjacent building panels 1, 1′ are locked together in both the vertical and horizontal direction.

As seen in FIGS. 4A-4B, the first edge 2a of the first building panel 1 pivots around the upper portion 4b of the second building panel 1′.

Similarly, the third edge 2c of the building panel 1 may pivot around the upper portion 4b of the second building panel 1′.

FIG. 5A illustrates a cross section of the first edge 2a of a first building panel 1 assembled to the second edge 2b of an adjacent second building panel 1′ with a mechanical locking device 10 as illustrated in FIG. 3A and 3B. FIG. 5B is a more detailed view of the assembly of the locking element 16 in the locking groove 32 and the two cooperating locking surfaces 18, 34 and the two cooperating impact surfaces 22, 38.

In the assembled position the locking element 16 of the second building panel 1′ is arranged in the locking groove 32 of the first building panel 1. The locking strip 15 of the second building panel 1′ extends below the first edge 2a of the first building panel 1, more specifically, the elongated part 19 of the locking strip 15 is arranged below a portion of the first edge 2a between the locking tongue 40 and the locking groove 32.

Further, the locking tongue 40 of the first building panel 1 is arranged in the tongue groove 24 of the second building panel 1′ and the upper locking tongue 27 of the second building panel 1 is arranged in the upper tongue groove 42.

The two adjacent building panels 1, 1′ are in the assembled position locked in both the vertical direction, by means of at least the locking tongue 40 in the tongue groove 24 and the upper locking tongue 27 in the upper tongue groove 42, and in the horizontal direction, by means of the at least the locking element 16 in the locking groove 32. Further, the two adjacent building panel 1, 1′ are, in the assembled position, arranged such that the two essentially upper locking surfaces 30, 45 of respective building panel 1, 1′, cooperate and create a seal S in the upper edge portions 4b, 5b of the building panels 1, 1′. Yet further, the upper locking tongue 27 and the upper tongue groove 42 are, in the assembled position, are configured to create the tight seal TS between respective upper surface 28, 43.

The seal S may extend in the vertical plane.

Taking a closer look at the locking element 16 arranged in the locking groove 32, this embodiment comprises locking surfaces 18, 34 of the locking element 16 and locking groove 32 respectively, that are essentially parallel to each other. In alternative embodiments (not shown) the two locking surfaces may be non-parallel to each other.

As described above, the locking surface 18 of the locking element 16, and preferably also the locking surface 34 of the locking groove 32, are arranged with the acute angles α, δ in relation to the horizontal plane. The acute angles α, δ are preferably between 40° and 60°, even more preferably about 50°.

The impact surfaces 22, 38 of the locking element 16 and locking groove 32 respectively, are essentially parallel to each other in this embodiment. In alternative embodiments, see FIGS. 7 and 8 the two impact surfaces 22, 38 are non-parallel to each other. The two impact surfaces 22, 38 are together configured to cooperate with each other, and support each other, when a force, acting, at least partially, in a vertical direction, is applied to any one of the building panels 1, in the assembled position, see FIGS. 20A-20C.

As described above, the impact surface 22 of the locking element 16, and preferably also the impact surface 38 of the locking groove 32, are arranged with the acute angles β, ϕ in relation to the horizontal plane. The acute angles β, ϕ are preferably between 40° and 70°. Depending on the thickness of the building panel 1 the acute angles β, ϕ may vary. In an embodiment, when the building panel has a thickness of between 3 and 4.5 mm, the impact surface 22 of the locking element 16 may be arranged at the acute angle β of between 40° and 60° in relation to the horizontal plane. In an alternative embodiment, when the building panel 1 has a thickness of 4.5 mm or more, e.g., 5 mm or 8 mm, the impact surface 22 of the locking element 16 may be arranged at the acute angle β of between 40° and 70° in relation to the horizontal plane. In an embodiment, when the building panel has a thickness of between 3 and 4.5 mm, the impact surface 38 of the locking groove 32 may be arranged at the acute angle ϕ of between 40° and 60° in relation to the horizontal plane. In an alternative embodiment, when the building panel 1 has a thickness of 4.5 mm or more the impact surface 38 of the locking groove 32 may be arranged at the acute angle ϕ of between 40° and 70° in relation to the horizontal plane. The impact surface 38 of the locking groove 32 may or may not be parallel to the impact surface 22 of the locking element 16.

Further, there may be a play P1 arranged between the impact surface 22 of the locking element 16 and the impact surface 38 of the locking groove 32 in the assembled position. The play P1 may be between 0 mm and 0.2 mm, or between 0.02 and 0.1 mm, or about 0.05 mm.

The play P1 may be measured by a feeler gauge.

The play P1 arranged between the impact surface 22 of the locking element 16 and the impact surface 38 of the locking groove 32 may be present in the assembled position at least when no force, acting at least partially, in the vertical direction, applied to at least one of the building panels. The play P1 is measured in the assembled position, when the upper vertical surfaces 30, 45 are in contact.

The building panels may be configured to have the play P1 in an assembled position, prior to application of a force, acting, at least partially, in a vertical direction, is applied to at least one of the building panels 1, 1′, 1″. Thereafter, the force may reduce the play P1 and cause the impact surface 38 of the locking groove 32 to cooperate with the impact surface 22 of the locking element 16.

In one example, as illustrated in FIG. 5C, there may be a second play P2 between the locking surface 18 of the locking element 16 and the locking surface 34 of the locking groove 32 in the assembled position. The second play P2 may be between 0 mm and 0.2 mm, or between 0.02 and 0.1 mm, or about 0.05 mm. The second play P2 arranged between the locking surface 18 of the locking element 16 and the locking surface 34 of the locking groove 32 is present in the assembled position at least when no force, acting at least partially, in the vertical direction, applied to at least one of the building panels. The second play P2 is measured in the assembled position, when the upper vertical surfaces 30, 45 are in contact. The second play P2 may be measured by a feeler gauge.

In an embodiment, the play P1 is present, while the second play P2 is not present. In an embodiment, the second play P2 is present, while the play P1 is not present. In another embodiment, both the play P1 and the second play P2 are present.

FIG. 6 illustrates an embodiment of the mechanical locking device 10 with all the features of the previously described and illustrated embodiment except for the upper locking tongue and the upper locking groove, which here are removed and as explained earlier, these features are optional. The adjacent building panels 1, 1′ are still locked in both the horizontal and vertical direction, by means of the mechanical locking device 10. The two cooperating locking surfaces 18, 34 are in this embodiment parallel with each other. The two cooperating impact surfaces 22, 38 are in this embodiment parallel with each other. Further, the locking surfaces 18, 34 are, in this embodiment, essentially parallel to the impact surfaces 22, 38.

FIG. 7 illustrates an embodiment of the mechanical locking device 10 without the upper locking tongue and the upper locking groove and with non-parallel impacts surfaces 22, 38. The rest of the features of the mechanical locking device 10 are present as for previous embodiments. The impact surface 22 of the locking element 16 is in the illustrated example arranged with an angle β, still acute in relation to the horizontal plane, smaller than the angle ϕ with which the impact surface 38 of the locking groove 32 is arranged. The impact surface 38 of the locking groove 32 is, in the illustrated example, not parallel to the impact surface 22 of the locking element 16. The impact surface 38 of the locking groove 32 is in the illustrated example arranged with an angle ϕ, still acute in relation to the horizontal plane, greater than the angle β with which the impact surface 22 of the locking element 16 is arranged. In this illustrated embodiment at least an upper portion of respective impact surface 22, 38 is configured to cooperate, and preferably be in contact with the opposite impact surface 22, 38 when pressure is applied to at least one of the building panels 1, 1′.

FIG. 8 illustrates an embodiment of the mechanical locking device 10 without the upper locking tongue and the upper locking groove and with non-parallel impacts surfaces 22, 38. The rest of the features of the mechanical locking device 10 are present as described for previous embodiments. The impact surface 22 of the locking element 16 is, in this embodiment, arranged with an angle β, still acute in relation to the horizontal plane, but greater than the angle ϕ in which the impact surface 38 of the locking groove 32 is arranged. The impact surface 38 of the locking groove 32 is, thus, in the illustrated example, not parallel to the impact surface 22 of the locking element 16. The impact surface 38 of the locking groove 32 is in the illustrated example arranged with an angle ϕ, still acute in relation to the horizontal plane, smaller than the angle β with which the impact surface 22 of the locking element 16 is arranged.

FIG. 9 illustrates an embodiment of the mechanical locking device 10 without the upper locking tongue and the upper locking groove and with a greater chamfer 39. The rest of the features of the mechanical locking device 10 are present as described for previous embodiments. In the illustrated embodiment the locking groove 32 is provided with the chamfer 39 extending from the impact surface 38 in a direction towards the back surface 6b of the building panel 1. This chamfer 39 is an optional feature but may be beneficial to have for installation properties. For example, if it is desirable to design the impact surfaces 38 with an acute angle β, ϕ of between 40° and 45° and parallel to each other, it may be beneficial to remove material, shorten the impact surface 38 and have the vertical surface 39 in order to decrease the risk the features of the mechanical locking device 10 arranged in the first or third edge 2a, 2c to abut features of the mechanical locking device 10 arranged in the second or fourth edge 2b respectively during the assembly of building panels 1. The height H3 of chamfer 39 may vary depending on the acute angle β, ϕ, the thickness of the building panel 1 and possibly other features of the mechanical locking device 10. Further, in the illustrated embodiment the locking surfaces 18, 34 are non-parallel to the impact surfaces 22, 38.

FIG. 10 illustrates an embodiment of the mechanical locking device 10 without the upper locking tongue and the upper locking groove and with a discontinuous impact surface 22 of the locking element 16. The rest of the features of the mechanical locking device 10 are present as described for previous embodiments. In the illustrated embodiment the impact surface 22 of the locking element 16 has a lower surface 22a arranged with a first acute angle β and an upper surface 22b arranged with a second acute angle β′, greater than the first acute angle β. In this example at least the lower surface 22a will cooperate with the opposite impact surface 38 of the locking groove 32 when a force is applied to the building panel 1, 1′. Whereas, in FIG. 11 also the impact surface 38 of the locking groove 32 is a discontinuous impact surface with a lower surface 38a arranged with a first acute angle ϕ and an upper surface 38b arranged with a second acute angle ϕ′, greater than the first acute angle ϕ. In this illustrated embodiment the first angle β of the lower surface 22a of the impact surface 22 of the locking element 16 is parallel to the first angle o of the lower surface 38a of the impact surface 38 of the locking groove 32, and the second angle β′ of the upper surface 22b of the impact surface 22 of the locking element 16 is parallel to the second angle ϕ′ of the upper surface 38b of the impact surface 38 of the locking groove. The rest of the features of the mechanical locking device 10 are present as described for previous embodiments.

FIG. 12 illustrates an embodiment of the mechanical locking device 10 without the upper locking tongue and the upper locking groove. The rest of the features of the mechanical locking device 10 are present as described for previous embodiments. In the illustrated example, the two cooperating upper surfaces 25, 41 of respective tongue groove 24 and locking tongue 40 extend in a horizontal direction, which previously has been illustrated as slightly tilted surfaces. Further, the cooperating locking surfaces 18, 34 of respective locking element 16 and locking groove 32 are, in the assembled position arranged in contact with each other. This is to enable a pretension between the locking surfaces 18, 34 in the assembled position. In order to facilitate the pretension it is preferred that the locking strip 15 is flexible at least in the direction perpendicular to the extension of the locking strip, which in the illustrated example is essentially in the vertical direction. A pretension in the locking surfaces 18, 34 may create a tighter fit between the edges 2a, 2b of the adjacent building panels 1, 1′, for example a tighter fit in the vertical surfaces 30, 45 in the upper edge portions 4b, 5b of the adjacent building panels 1, 1′. Yet further, the locking strip 15 and its lower surface 19b may extend either in a horizontal direction of with an angle in relation to the horizontal plane. The lower surface 19b may include a cut. Different designs of the locking strip 15 and its lower surface 19b may provide the locking strip with different properties, for example, the locking strip 15 may become more or less flexible. Another advantage with a lower surface 19b of the locking strip 15 according to any of the illustrated examples in FIG. 12 is that the effect of unevenness of the surface on which the building panels are to be assembled, or of material sticking up around the area of the mechanical locking device 10 is decreased. The same applies to a possible calibration portion 37 arranged in edge 2a, in the back surface 6b of the building panel in which the locking groove 32 is arranged. The calibration portion 37 extend from the locking groove 32 and the chamfer 39 in towards the rest of the building panel 1.

Whereas FIGS. 6-12 and 15-18 illustrate preferred embodiment of the mechanical locking device for building panels having a thickness of between 2 and 5 mm but which are also possible for building panels having a greater thickness, FIGS. 13 and 14 illustrate possible embodiments of the mechanical locking device for building panels having a thickness about or greater than 5 mm.

FIGS. 13 and 14 illustrate embodiments of the mechanical locking device 10 again with the upper locking tongue 27 and the upper locking groove 42 and with parallel impacts surfaces 22, 38. The difference between this embodiment and the previously described embodiment illustrated in FIGS. 3A-5B is that there is a more distinct difference in angle between the locking surfaces 18, 34 of the locking element 16 and locking groove 32 respectively and the impact surfaces 22, 38.

In the first illustration, FIG. 13, the parallel locking surfaces 18, 34 are arranged with greater angles α, δ in relation to the horizontal plane compared to angles β, ϕ with which the parallel impact surfaces 22, 38 are arranged.

In the first illustration, FIG. 13, the parallel locking surfaces 18, 34 are arranged with greater angles α, δ in relation to the horizontal plane compared to the angles β, ϕ with which the parallel impact surfaces 22, 38 are arranged.

In the second illustration, FIG. 14, the parallel locking surfaces 18, 34 are arranged with smaller angles α, δ in relation to the horizontal plane compared to the angles β, ϕ with which the parallel impact surfaces 22, 38 are arranged.

FIGS. 15 and 16 illustrate alternative embodiments of the mechanical locking device 10 which may be assembled by either a pivoting assembly or by a snapping assembly. Such a snapping assembly is achieved by a more horizontal displacement of the building panels 1, 1′ being assembled, compared to a pivoting assembly. One or both building panels 1, 1′ are pushed in an essential horizontal direction towards each other until the locking strip 15 with its locking element 16 is snapped into the locking groove 32. By having a locking tongue 40 with a slanted lower surface 40a, slanting in a direction towards the back surface 6b of the building panel 1 the snapping assembly is facilitated. The slanted lower surface 40a extends to a lower ridge 40b of the locking tongue 40 which the locking element 16 must pass to be snapped into the locking groove 32.

Further, the mechanical locking device 10 illustrated in FIGS. 15 and 16 comprises features described for previous embodiment and, even if an upper locking tongue and an upper tongue groove is not illustrated, the embodiments may further have such features.

Yet two other possible embodiments are illustrated in FIGS. 17 and 18, having features already described for previous embodiments above. Also these embodiments may be provided with an upper locking tongue and an upper tongue groove is desirable. The building panels 1, 1′ in these two embodiments are preferably assembled by means of a pivoting assembly.

FIGS. 19A-19D illustrate an alternative assembly, a snaping assembly as described above. The snapping assembly is achieved by an essentially horizontal displacement of the building panel 1 being assembled to an adjacent building panel 1′. Such a snapping assembly is facilitated, e.g., by a more flexible locking strip 15. The locking strip 15 is configured to be pushed downwards by the first edge 2a of the building panel 1 being assembled and then flex back and be displaced upwards. The locking strip 15 is displaced upwards when the locking element 16 can move up into the locking groove 32.

In order to facilitate pushing down the locking strip 15 the locking element 16 includes a tilted guiding surface 17 arranged in a front portion of the locking element 16. The guiding surface 17 of the locking element 16 is configured to cooperate with a corresponding guiding surface 34 arranged in the lower edge portion, below the locking tongue 40, of the first edge 2a of the building panel 1 being assembled. The two guiding surfaces 17, 34 are configured to guide the locking element 16 and in turn the locking strip 15 downwards when they are in contact with each other, i.e., in the moment after FIG. 19A.

In order to facilitate the right position of the building panel 1 being assembled there is provided corresponding upper guiding surfaces 26, 44. The first upper guiding surface 26 is arranged in the upper portion of the tongue groove 24 and may preferably extend between the upper surface 25 of the tongue groove 24 and the upper locking surface 30. The second upper guiding surface 44 is arranged in the upper portion of the locking tongue 40 and may preferably extend between the upper surface 41 of the locking tongue 40 and the frontmost surface of the locking tongue 40. The two guiding surfaces 26, 44 are configured to guiding the locking tongue 40 into the correct position in the tongue groove 24 and in turn guide the edge 2a of the building panel 1 being assembled into the right position in relation to the edge 2b of the adjacent building panel 1′. As the locking tongue 40 is guided into the tongue groove 24 the locking strip 15 is pushed further down, see FIG. 19C.

FIG. 19D illustrate the assembled position where the locking element 16 has snapped into position in the locking groove 32, the locking tongue 40 is in the correct position in the tongue groove 24, the two upper locking surfaces 30, 45 create the desirable seal between the two adjacent building panels 1, 1′, and the upper surfaces of the two adjacent edges 2a, 2b are arranged flush with each other.

The mechanical locking device 10 illustrated in FIGS. 19A-19D are configured to be assembled by either a pivoting assembly or by a snapping assembly as described above.

EXAMPLES

In the following examples tests have been made to establish the technical effect of the presence and cooperation of the impact surface in the locking element and the corresponding impact surface of the locking groove.

Test 1—Pressure

The building panels are manufactured from a SPC panel with a PVC-base. The building panels further have a 0.2 mm wear layer. For the tested building panels the modulus of elasticity is about 7000 MPa, and the density is about 2000 kg/m³.

In Test 1, two building panels 1, 1′ having a polymer-based substrate, such as a thermoplastic-based substrate, were assembled by means of a mechanical locking device 10 as described above. Subsequently a pressure F was applied, close to the mechanical locking device 10, to one of the building panels. See FIGS. 20A and 20B for a possible set up for Test 1. In Test 1 the building panels 1, 1′ have a width of 60 mm and the fixing plates extend over and even beyond the width of the building panels 1, 1′. Photographs of the test are shown in. FIGS. 21A-21C. Pressure was increased until any part of the building panel broke. FIG. 21A shows the two building panels just before pressure is applied and FIGS. 21B and 21C shows the two building panels when the pressure is applied and increased.

For reference, two assembled building panels, having a polymer-based substrate, such as a thermoplastic-based substrate, with a mechanical locking device having no impact surfaces on the locking element and locking groove respectively, were tested with the above method. A reference was made for each building panel thickness.

Test 1 was then performed on two assembled building panels of the same material composition as the reference, i.e., having a polymer-based substrate, such as a thermoplastic-based substrate, having different thicknesses. The building panels had a mechanical locking device with impact surfaces on the locking element and locking groove respectively, tested with varying angles β, ϕ, according to the present inventive concept, for example as illustrated in FIG. 6. Some tests were performed on building panels having a mechanical locking device including upper locking tongue and upper tongue groove, for example as illustrated in FIGS. 3A-3B. The results were compared to the relevant reference which are presented in the Table 1-5. In the tables below the specimens with the impact surfaces are named IS.

The thicknesses tested are 3.5 mm (see Table 1 and 2), 5.0 mm (see Table 3), 7.0 mm (see Table 4) and 8.0 mm (see Table 5).

The reference specimens for every thickness are provided with locking surfaces, α, δ, arranged at 65°. The IS specimens for every thickness are provided with locking surfaces, α, δ, arranged at 50°. Having the locking surfaces arranged at 50° enables a variety of angles, β, ϕ, at which the impact surfaces are arranged, especially when it comes to enabling the assembly of two adjacent building panels.

TABLE 1
Test 1a—thickness of 3.5 mm, with an upper locking tongue/
upper tongue groove and locking surfaces at different angles
TEST 1a	Reference	IS 1a	IS 2a	IS 3a	IS 4a
Thickness =	α, δ = 65°	α, δ = 50°	α, δ = 50°	α, δ = 50°	α, δ = 50°
3.5 mm	β, ϕ = no	β, ϕ = 45°	β, ϕ = 50°	β, ϕ = 60°	β, ϕ = 70°
Sample 1	494	596	608	408	375
Max (N)
Sample 2	444	571	530	415	330
Max (N)
Sample 3	453	528	477	416	319
Max (N)
Sample 4	426	498	606	399	350
Max (N)
Sample 5	444	443	589	406	372
Max (N)
Mean value	452.2	527.2	562.0	408.8	349.2
(N)

TABLE 2
Test 1b—thickness of 3.5 mm and no upper
locking tongue/upper tongue groove
	TEST 1b	Reference	IS 1b
	Thickness =	α, δ = 65°	α, δ = 50°
	3.5 mm	β, ϕ = no	β, ϕ = 50°
	Sample 1	368	773
	Max (N)
	Sample 2	362	758
	Max (N)
	Sample 3	345	750
	Max (N)
	Sample 4	354	748
	Max (N)
	Sample 5	363	725
	Max (N)
	Mean value	358.4	750.8
	(N)

TABLE 3
Test 1c—thickness of 5 mm, with an upper locking tongue/
upper tongue groove and locking surfaces at different angles
TEST 1c	Reference	IS 1c	IS 2c	IS 3c
Thickness =	α, δ = 65°	α, δ = 50°	α, δ = 50°	α, δ = 50°
5 mm	β, ϕ = no	β, ϕ = 45°	β, ϕ = 60°	β, ϕ = 70°
Sample 1	648	1055	749	683
Max (N)
Sample 2	481	991	768	653
Max (N)
Sample 3	512	987	787	678
Max (N)
Sample 4	501	999	695	572
Max (N)
Sample 5	515	1001	627	573
Max (N)
Mean value	531.4	1006.6	725.2	631.8
(N)

TABLE 4
Test 1d—thickness of 7 mm and no upper
locking tongue/upper tongue groove
	TEST 1d	Reference	IS 1d
	Thickness =	α, δ = 65°	α, δ = 50°
	7 mm	β, ϕ = no	β, ϕ = 50°
	Sample 1	807	1253
	Max (N)
	Sample 2	780	1225
	Max (N)
	Sample 3	750	1159
	Max (N)
	Sample 4	716	1108
	Max (N)
	Sample 5	716	1061
	Max (N)
	Mean value	753	1161
	(N)

TABLE 5
Test 1e—thickness of 8.0 mm and no upper
locking tongue/upper tongue groove
	TEST 1e	Reference	IS 1e
	Thickness =	α, δ = 65°	α, δ = 50°
	8 mm	β, ϕ = no	β, ϕ = 50°
	Sample 1	1035	1664
	Max (N)
	Sample 2	947	1630
	Max (N)
	Sample 3	945	1554
	Max (N)
	Sample 4	945	1511
	Max (N)
	Sample 5	848	1379
	Max (N)
	Mean value	944	1547
	(N)

Conclusion: For building panels having a thickness of 3.5 mm, Test 1a shows that the maximum load capacity of the mechanical locking device, in the vertical direction, increases, or at least are about the same, compared to the reference, when the mechanical locking device comprises impact surfaces of the locking element respective locking groove, arranged with an angle β, ϕ below 60°.

For building panels having a thickness of 3.5 mm, Test 1b shows that the maximum load capacity of the mechanical locking device, in the vertical direction, increases when the mechanical locking device comprises impact surfaces of the locking element respective locking groove, compared to the reference with no impact surfaces.

For building panels having a thickness of 5 mm, Test 1c shows that the maximum load capacity of the mechanical locking device, in the vertical direction, increases when the mechanical locking device comprises impact surfaces of the locking element respective locking groove, compared to the reference with no impact surfaces. Here the angle β, ϕ with which the impact surfaces are arranged matter less than when the building panel has a tinner thickness, e.g., 3.5 mm.

For building panels having a thickness of 7 mm, Test 1d shows that the maximum load capacity of the mechanical locking device, in the vertical direction, increases compared to the reference.

For building panels having a thickness of 8 mm, Test 1e shows that the maximum load capacity of the mechanical locking device, in the vertical direction, increases compared to the reference.

Test 2—Revolutions

The building panels are manufactured from a SPC panel with a PVC-base. The building panels further have a 0.2 mm wear layer. For the tested building panels the modulus of elasticity is about 7000 MPa, and the density is about 2000 kg/m³.

In Test 2, several building panels were assembled together by means of mechanical locking devices. Subsequently a Castor Chair test according to ISO 4918: 2016 with wheel type W, EN 425: 2002, and a foam Dongguan Hongzhida 0610 was performed on the assembled building panels.

Test 2 were performed on some of the same specimens as for Test 1. Test 2a is performed on building panels having a thickness of 3.5 mm, and where the mechanical locking device further was provided with an upper locking tongue and a corresponding upper tongue groove, see Table 6. Test 2b is performed on building panels having a thickness of 3.5 mm, but where the mechanical locking device did not have the upper locking tongue and the corresponding upper tongue groove, see Table 7.

TABLE 6
Test 2a—thickness of 3.5 mm, with an upper locking tongue/
upper tongue groove and locking surfaces at different angles.
TEST 2a	Reference	IS 1a	IS 2a	IS 3a	IS 4a
Thickness =	α, δ = 65°	α, δ = 50°	α, δ = 50°	α, δ = 50°	α, δ = 50°
3.5 mm	β, ϕ = no	β, ϕ = 45°	β, ϕ = 50°	β, ϕ = 60°	β, ϕ = 70°
Castor Chair	4000 rev	4000 rev	7200 rev	6800 rev	2000 rev
ISO 4918

TABLE 7
Test 2b—thickness of 3.5 mm and no upper
locking tongue/upper tongue groove
	TEST 2b	Reference	IS 1b
	Thickness =	α, δ = 65°	α, δ = 50°
	3.5 mm	β, ϕ = no	β, ϕ = 50°
	Castor Chair	5000 rev	15000 rev
	ISO 4918

Conclusion: For building panels having a thickness of 3.5 mm, Test 2a shows that the value of maximum applied revolutions increases, or at least is about the same, compared to the reference, when the mechanical locking device comprises impact surfaces of the locking element respective locking groove, arranged with an angle β, ϕ below 60°.

For building panels having a thickness of 3.5 mm and no upper locking tongue/upper tongue groove Test 2b shows that the maximum load capacity of the mechanical locking device, in the vertical direction, increases significantly, compared to the reference, when the mechanical locking device comprises impact surfaces of the locking element respective locking groove.

Test 3—Pressure

The building panels are manufactured from a laminate panel with a HDF core. The laminate panels have a thickness of 5 mm. The building panels further have a surface layer including a resin impregnated decorative paper and a resin impregnated overlay paper, and a balancing layer, including a resin impregnated paper, on a surface of the core, opposite the surface layer. The density of the laminate panel is about 910 kg/m³.

In Test 3, two laminate building panels 1 were assembled by means of a mechanical locking device 10 as described above. Subsequently a pressure F was applied, close to the mechanical locking device 10, to one of the building panels. See FIGS. 20A and 20B for a possible set up for Test 3. In Test 3 the building panels 1, 1′ have a width of 60 mm and the fixing plates extend over and even beyond the width of the building panels 1, 1′. Photographs of the test are shown in. FIGS. 22A-22C. Pressure was increased until any part of the building panel broke. FIG. 22A shows the two building panels just before pressure is applied and FIGS. 22B and 22C shows the two building panels when the pressure is applied and increased.

For reference, two assembled laminate building panels, with a mechanical locking device having no impact surfaces on the locking element and locking groove respectively, were tested with the above method.

Test 3 was then performed on two assembled building panels of the same material composition as the reference, i.e., laminate panels. The building panels had a mechanical locking device with impact surfaces on the locking element and locking groove respectively, according to the present inventive concept, and with upper locking tongue and upper tongue groove, for example as illustrated in FIGS. 3A-3B. The results were compared to the relevant reference which are presented in the Table 3. In the table below the specimens with the impact surfaces are named IS.

The reference specimens are provided with locking surfaces, α, δ, arranged at 50°.The IS specimens for every thickness are provided with locking surfaces, α, δ, arranged at 50°. Having the locking surfaces arranged at 50° enables a variety of angles, β, ϕ, at which the impact surfaces are arranged, especially when it comes to enabling the assembly of two adjacent building panels.

TABLE 3
Test 3—thickness of 5 mm, with an upper
locking tongue/upper tongue
	TEST 3	Reference	IS
	Thickness =	α, δ = 50°	α, δ = 50°
	5 mm	β, ϕ = no	β, ϕ = 50°
	Sample 1	379	737
	Max (N)
	Sample 2	380	534
	Max (N)
	Sample 3	442	557
	Max (N)
	Sample 4	394	468
	Max (N)
	Sample 5	425	415
	Max (N)
	Sample 6	371	696
	Max (N)
	Sample 7	395	721
	Max (N)
	Mean value	398	590
	(N)

Conclusion: For building panels having a thickness of 5 mm, Test 3 shows that the maximum load capacity of the mechanical locking device, including upper locking tongue and upper tongue groove, in the vertical direction, increases compared to the reference, when the mechanical locking device comprises impact surfaces of the locking element respective locking groove, arranged with an angle β, ϕ below 60°.

As visible in the photos of FIGS. 22B-C, the locking surface of the locking element continues to be in engagement with the locking surface in the locking groove when pressure is applied.

Clauses

1. A set of building panels, such as floor panels, comprising similar or essentially identical building panels wherein each building panel (1, 1′, 1″) comprises a first mechanical locking device (10) configured to horizontally and vertically lock a first edge (2a) of a building panel (1, 1′, 1″) to a second edge (2b) of an adjacent building panel (1, 1′, 1″), wherein the first edge (2a) and the second edge (2b) preferably are the long edges of said building panels (1, 1′, 1″), and a second mechanical locking device (10′) configured to horizontally and vertically lock a third edge (2c) of a building panel (1, 1′, 1″) to a fourth edge (2d) of an adjacent building panel (1, 1′, 1″), wherein the third edge (2c) and the fourth edge (2d) preferably are the short edges of said building panels (1, 1′, 1″),

• • wherein each mechanical locking device (10, 10′) comprises, at one of the first edge (2a) or second edge (2b), and at one of the third edge (2c) or fourth edge (2d), a locking strip (15) extending from respective edge in a direction away from said edge,
  • wherein the locking strip (15) comprises, at its outermost portion, a locking element (16) extending in a direction perpendicular to the extension of the locking strip (15),
  • wherein the locking element (16) is configured to cooperate with a locking groove (32) arranged in the other of the first edge (2a) or second edge (2b), and in the other of the third edge (2c) or fourth edge (2d), such that adjacent building panels (1, 1′, 1″) are locked in a horizontal direction in an assembled position,
  • wherein the locking element (16) comprises an impact surface (22) extending from an outer surface (20b) of the locking element (16) in a direction towards a back surface (6b) of the building panel (1, 1′, 1″), at an acute angle (β) in relation to the horizontal plane,
  • wherein the locking groove (32) comprises an impact surface (38) extending from an inner surface (36b) of the locking groove (32) in a direction towards the back surface (6b) of the building panel (1, 1′, 1″), at an acute angle (99 ) in relation to the horizontal plane, and configured to cooperate with the impact surface (22) of the locking element (16) in an assembled position, when a force, acting, at least partially, in a vertical direction, is applied to at least one of the building panels (1, 1′, 1″).

2. The set of building panels according to clause 1, wherein the impact surface (22) of the locking element (16) is arranged at the acute angle (β) of between 40° and 70° in relation to the horizontal plane.

3. The set of building panels according to clause 1 or 2, wherein the impact surface (38) of the locking groove (32) is arranged at the acute angle (ϕ) of between 40° and 70° in relation to the horizontal plane.

4. The set of building panels according to any one of the clauses 1-3, wherein the impact surface (22) of the locking element (16) is essentially parallel to the impact surface (38) of the locking groove (32).

5. The set of building panels according to any one of the clauses 1-3, wherein the impact surface (22) of the locking element (16) is non-parallel to the impact surface (38) of the locking groove (32).

6. The set of building panels according to any one of the preceding clauses, wherein the building panel has a thickness of between 3 and 6 mm.

7. The set of building panels according to any one of the preceding clauses, wherein the building panel (1, 1′, 1″) has a thickness of between 3 and 4.5 mm and the impact surface (22) of the locking element (16) is arranged at the acute angle (β) of between 40° and 60° in relation to the horizontal plane.

8. The set of building panels according to any one of the clauses 1-6, wherein the building panel (1, 1′, 1″) has a thickness of between 4.5 and 6 mm and the impact surface (22) of the locking element (16) is arranged at the acute angle (β) of between 40° and 70° in relation to the horizontal plane.

9. The set of building panels according to any one of the preceding clauses, wherein the locking element (16) further comprises a locking surface (18) configured to cooperate with a locking surface (34) of the locking groove (32) in which the locking element (16) is arranged in an assembled position.

10. The set of building panels according to clause 9, wherein the locking surface (18) of the locking element (16) and the locking surface (34) of the locking groove (32) are essentially parallel.

11. The set of building panels according to claim clause 9 or 10, wherein the locking surface (18) of the locking element (16) is arranged at an acute angle (α) of between 40° and 60°, preferably about 50°, in relation to the horizontal plane.

12. The set of building panels according to any one of the preceding clauses, wherein the mechanical locking device (10, 10′) further comprises, at one of the first edge (2a) or second edge (2b), and at one of the third edge (2c) or fourth edge (2d), an upper locking tongue (27) extending from respective edge in a direction away from said edge, and configured to be received in and cooperate with an upper tongue groove (42) arranged in the other of the first edge (2a) or second edge (2b), and in the other of the third edge (2c) or fourth edge (2d).

13. The set of building panels according to clause 12, wherein the height (h1) of the upper locking tongue (27) is greater than the height (h2) of the upper tongue groove (42) in order to create a tight seal (TS) between the adjacent building panels (1, 1′, 1″).

14. The set of building panels according to clause 13, wherein the difference between the height (h1) of the upper locking tongue (27) and the height (h2) of the upper tongue groove (42) is in the range of 0.01 to 0.2 mm, or in the range of 0.01 to 0.1 mm, or in the range of 0.01 or 0.05 mm.

15. The set of building panels according to any one of the preceding clauses, wherein at least a substrate (7) of the building panel (1, 1′, 1″) comprises a thermoplastic material, preferably the substrate (7) comprises 10-50 wt. %, or preferably 20-40 wt. %, of the thermoplastic material.

16. The set of building panels according to any one of the preceding clauses, wherein each building panel (1, 1′, 1″) comprises a single layered substrate (7), wherein the impact surface (22) of the locking element (16) and the impact surface (38) of the locking groove (32) are arranged in said substrate (7).

17. A set of building panels, such as floor panels, comprising similar or essentially identical building panels wherein each building panel (1, 1′, 1″) comprises a first mechanical locking device (10) configured to horizontally and vertically lock a first edge (2a) of a building panel (1, 1′, 1″) to a second edge (2b) of an adjacent building panel (1, 1′, 1″), wherein the first edge (2a) and the second edge (2b) preferably are the long edges of said building panels (1, 1′, 1″), and a second mechanical locking device (10′) configured to horizontally and vertically lock a third edge (2c) of a building panel (1, 1′, 1″) to a fourth edge (2d) of an adjacent building panel (1, 1′, 1″), wherein the third edge (2c) and the fourth edge (2d) preferably are the short edges of said building panels (1, 1′, 1″),

• • wherein each mechanical locking device (10, 10′) comprises, at one of the first edge (2a) or second edge (2b), and at one of the third edge (2c) or fourth edge (2d), a locking strip (15) extending from respective edge in a direction away from said edge,
  • wherein each locking strip (15) comprises, at its outermost portion, a locking element (16) extending in a direction perpendicular to the extension of the locking strip (15),
  • wherein each locking element (16) is configured to cooperate with a locking groove (32) arranged in the other of the first edge (2a) or second edge (2b), and in the other of the third edge (2c) or fourth edge (2d), such that adjacent building panels (1, 1′, 1″) are locked in a horizontal direction in an assembled position,
  • wherein each locking element (16) comprises an impact surface (22) extending from an outer surface (20b) of the locking element (16) in a direction towards a back surface (6b) of the building panel (1, 1′, 1″), at an acute angle (β) in relation to a horizontal plane,
  • wherein each locking groove (32) comprises an impact surface (38) extending from an inner surface (36b) of the locking groove (32) in a direction towards the back surface (6b) of the building panel (1, 1′, 1″), at an acute angle (ϕ) in relation to the horizontal plane, and configured to cooperate with the impact surface (22) of the locking element (16) in an assembled position, when a force, acting, at least partially, in a vertical direction, is applied to at least one of the building panels (1, 1′, 1″),
    • wherein the first mechanical locking device (10) and the second mechanical locking device (10′) are configured to be assembled together by means of a pivoting motion, or by a snapping assembly by an essentially horizontal displacement of the building panel (1, 1′, 1″) being assembled to the adjacent building panel (1, 1′, 1″).

18. The set of building panels according to clause 17, wherein the impact surface (22) of the locking element (16) is arranged at the acute angle (β) of between 40° and 70° in relation to the horizontal plane.

19. The set of building panels according to clause 17 or 18, wherein the impact surface (38) of the locking groove (32) is arranged at the acute angle (ϕ) of between 40° and 70° in relation to the horizontal plane.

20. The set of building panels according to any one of the clauses 17-19, wherein the impact surface (22) of the locking element (16) is essentially parallel to the impact surface (38) of the locking groove (32).

21. The set of building panels according to any one of the clauses 17-19, wherein the impact surface (22) of the locking element (16) is non-parallel to the impact surface (38) of the locking groove (32).

22. The set of building panels according to any one of the preceding clauses 17-21, wherein the building panel (1, 1′, 1″) has a thickness of between 3 and 6 mm.

23. The set of building panels according to any one of the preceding clauses 17-22, wherein the building panel (1, 1′, 1″) has a thickness of between 3 and 4.5 mm and the impact surface (22) of the locking element (16) is arranged at the acute angle (β) of between 40° and 60° in relation to the horizontal plane.

24. The set of building panels according to any one of the clauses 17-22, wherein the building panel (1, 1′, 1″) has a thickness of between 4.5 and 6 mm and the impact surface (22) of the locking element (16) is arranged at the acute angle (β) of between 40° and 70° in relation to the horizontal plane.

25. The set of building panels according to any one of the preceding clauses 17-24, wherein the locking element (16) further comprises a locking surface (18) configured to cooperate with a locking surface (34) of the locking groove (32) in which the locking element (16) is arranged in an assembled position.

26. The set of building panels according to clause 25, wherein the locking surface (18) of the locking element (16) and the locking surface (34) of the locking groove (32) are essentially parallel.

27. The set of building panels according to clause 25 or 26, wherein the locking surface (18) of the locking element (16) is arranged at an acute angle (α) of between 40° and 60°, preferably about 50°, in relation to the horizontal plane.

28. The set of building panels according to any one of the preceding clauses 17-27, wherein the mechanical locking device (10, 10′) further comprises, at one of the first edge (2a) or second edge (2b), and at one of the third edge (2c) or fourth edge (2d), an upper locking tongue (27) extending from respective edge in a direction away from said edge, and configured to be received in and cooperate with an upper tongue groove (42) arranged in the other of the first edge (2a) or second edge (2b), and in the other of the third edge (2c) or fourth edge (2d).

29. The set of building panels according to clause 28, wherein a height (h1) of the upper locking tongue (27) is greater than a height (h2) of the upper tongue groove (42) in order to create a tight seal (TS) between the adjacent building panels (1, 1′, 1″).

30. The set of building panels according to clause 29, wherein the difference between the height (h1) of the upper locking tongue (27) and the height (h2) of the upper tongue groove (42) is in the range of 0.01 to 0.2 mm, or in the range of 0.01 to 0.1 mm, or in the range of 0.01 or 0.05 mm.

31. The set of building panels according to any one of the preceding clauses 17-30, wherein at least a substrate (7) of the building panel (1, 1′, 1″) comprises a thermoplastic material, preferably the substrate (7) comprises 10-50 wt. %, or preferably 20-40 wt. %, of the thermoplastic material.

32. The set of building panels according to any one of the preceding clauses 17-31, wherein each building panel (1, 1′, 1′') comprises a single layered substrate (7), wherein the impact surface (22) of the locking element (16) and the impact surface (38) of the locking groove (32) are arranged in said substrate (7).

33. The set of building panels according to any one of the preceding clauses 17-32, wherein the first mechanical locking device (10) and the second mechanical locking device (10′) are the same type of locking device.

Claims

1. A set of building panels, comprising similar or essentially identical building panels wherein each building panel comprises a first mechanical locking device configured to horizontally and vertically lock a first edge of a building panel to a second edge of an adjacent building panel, and a second mechanical locking device configured to horizontally and vertically lock a third edge of a building panel to a fourth edge of an adjacent building panel, wherein each mechanical locking device comprises, at one of the first edge or second edge, and at one of the third edge or fourth edge, a locking strip extending from a respective edge in a direction away from said respective edge,wherein each locking strip comprises, at its outermost portion, a locking element extending in a direction perpendicular to the extension of the locking strip,wherein each locking element is configured to cooperate with a locking groove arranged in the other of the first edge or second edge, and in the other of the third edge or fourth edge, such that adjacent building panels are locked in a horizontal direction in an assembled position,wherein each locking element comprises an impact surface extending from an outer surface of the locking element in a direction towards a back surface of the building panel, at an acute angle (β) in relation to a horizontal plane,wherein each locking groove comprises an impact surface extending from an inner surface of the locking groove in a direction towards the back surface of the building panel, at an acute angle (ϕ) in relation to the horizontal plane, and configured to cooperate with the impact surface of the locking element 0 in an assembled position, when a force, acting, at least partially, in a vertical direction, is applied to at least one of the building panels,wherein the first mechanical locking device and the second mechanical locking device are configured to be assembled together by means of a pivoting motion, or by a snapping assembly by an essentially horizontal displacement of the building panel being assembled to the adjacent building panel.

2. The set of building panels according to claim 1, wherein the impact surface of the locking element is arranged at the acute angle (β) of between 40° and 70° in relation to the horizontal plane.

3. The set of building panels according to claim 1, wherein the impact surface of the locking groove is arranged at the acute angle (ϕ) of between 40° and 70° in relation to the horizontal plane.

4. The set of building panels according to claim 1, wherein the impact surface of the locking element is essentially parallel to the impact surface of the locking groove.

5. The set of building panels according to claim 1, wherein the impact surface of the locking element is non-parallel to the impact surface of the locking groove.

6. The set of building panels according to claim 1, wherein the building panel has a thickness of between 3 and 6 mm.

7. The set of building panels according to claim 1, wherein the building panel has a thickness of between 3 and 4.5 mm and the impact surface of the locking element is arranged at the acute angle (β) of between 40° and 60° in relation to the horizontal plane.

8. The set of building panels according to claim 1, wherein the building panel has a thickness of between 4.5 and 6 mm and the impact surface of the locking element is arranged at the acute angle (β) of between 40° and 70° in relation to the horizontal plane.

9. The set of building panels according to claim 1, wherein the locking element further comprises a locking surface configured to cooperate with a locking surface of the locking groove in which the locking element is arranged in an assembled position.

10. The set of building panels according to claim 9, wherein the locking surface of the locking element and the locking surface of the locking groove are essentially parallel.

11. The set of building panels according to claim 9, wherein the locking surface of the locking element is arranged at an acute angle (α) of between 40° and 60°, in relation to the horizontal plane.

12. The set of building panels according to claim 1, wherein the mechanical locking device further comprises, at one of the first edge or second edge, and at one of the third edge or fourth edge, an upper locking tongue extending from respective edge in a direction away from said edge, and configured to be received in and cooperate with an upper tongue groove arranged in the other of the first edge or second edge, and in the other of the third edge or fourth edge.

13. The set of building panels according to claim 12, wherein a height of the upper locking tongue is greater than a height of the upper tongue groove in order to create a tight seal between the adjacent building panels .

14. The set of building panels according to claim 13, wherein the difference between the height of the upper locking tongue and the height of the upper tongue groove is in the range of 0.01 to 0.2 mm.

15. The set of building panels according to claim 1, wherein at least a substrate of the building panel comprises a thermoplastic material, preferably the substrate comprises 10-50 wt. %, of the thermoplastic material.

16. The set of building panels according to claim 1, wherein each building panel comprises a single layered substrate, wherein the impact surface of the locking element and the impact surface of the locking groove are arranged in said substrate.

17. The set of building panels according to claim 1, wherein the first mechanical locking device and the second mechanical locking device are the same type of locking device.