CONSTRUCTIONAL PANEL

Abstract

A panel and accompanying method of construction thereof, the panel comprising a first panel element, the first panel element having a substantially planar outer surface, the second, opposite surface having extending therefrom a plurality of paired walls, each pair extending laterally at least partway across the face of the second surface and defining a channel therebetween, a plurality of throughapertures defined in the first panel element, a second panel element having a substantially planar outer surface, and a second, opposite surface having extending therefrom a plurality of paired walls, each pair extending laterally at least partway across the face of the second surface and defining a channel therebetween, the second panel element defining a plurality of throughapertures therethrough, one or more of the throughapertures opening into a tubular element extending from the second surface, a strengthening member located in a channel between paired walls of a panel element.

Claims

1. A panel, the panel comprising a first panel element, the first panel element having a substantially planar outer surface, the second, opposite surface having extending therefrom a plurality of paired walls, each pair extending laterally at least partway across the face of the second surface and defining a channel therebetween, a plurality of throughapertures defined in the first panel element, a second panel element having a substantially planar outer surface, and a second, opposite surface having extending therefrom a plurality of paired walls, each pair extending laterally at least partway across the face of the second surface and defining a channel therebetween, the second panel element defining a plurality of throughapertures therethrough, one or more of the throughapertures opening into a tubular element extending from the second surface, a strengthening member located in a channel between paired walls of a panel element, the first and second panel elements being secured together in fluid-tight manner such that paired walls on the first and second panel elements co-operate to retain the strengthening member and that the free end of a tubular member passes through a throughaperture in the first panel element, a rivet head formed of a plastics material, heat welded to the free end of the tubular member to seal the free end and the throughaperture in the first panel element.

2. A panel according to claim 1, wherein the tubular member has a conical cross-section to strengthen the panel against downward forces applied.

3. A panel according to claim 1, wherein the first panel element includes a receiver to receive the tubular member, the receiver further preferably having a shape complementary to that of the tubular member to form a push-fit connection therewith.

4. A method of constructing a panel, the method comprising the steps of selecting a first panel element, the first panel element having a substantially planar outer surface, the second, opposite surface having extending therefrom a plurality of paired walls, each pair extending laterally at least partway across the face of the second surface and defining a channel therebetween, a plurality of throughapertures defined in the first panel element, selecting a second panel element having a substantially planar outer surface, and a second, opposite surface having extending therefrom a plurality of paired walls, each pair extending laterally at least partway across the face of the second surface and defining a channel therebetween, the second panel element defining a plurality of throughapertures therethrough, one or more of the throughapertures opening into a tubular element extending from the second surface, selecting a strengthening member and inserting said strengthening member in the channel between paired walls of a panel element, the method comprising the further step of bringing the first and second panel elements together such that paired walls on the first and second panel elements co-operate to retain a strengthening member and that the free end of a tubular member passes through a throughaperture in the first panel element, sealing the first and second panel elements together in fluid-tight manner, placing a rivet head formed of a plastics material in contact with a free end of a tubular member and heat welding the rivet to the tubular member to seal the free end and the throughaperture in the first panel element.

5. A method according to claim 4, wherein the tubular member has a conical cross-section to strengthen the panel against downward forces applied.

6. A method according to claim 4, wherein the first panel element includes a receiver to receive the tubular member, the receiver further preferably having a shape complementary to that of the tubular member to form a push-fit connection therewith.

Description

BRIEF DESCRIPTION OF THE DRAWINGS

[0025] FIGS. 1A-1G show, respectively, a perspective, top, first and second side, first and second ends, and bottom view of an embodiment of floor panel;

[0026] FIG. 2 shows the perspective view of FIG. 1A in more detail;

[0027] FIG. 3 is an exploded view of the panel of FIGS. 1A-1G;

[0028] FIG. 4 is a first sectional view of a panel prior to the elements being secured together; and

[0029] FIG. 5 is a second sectional view of the panel of FIG. 4 with the elements secured together.

DETAILED DESCRIPTION OF THE INVENTION

[0030] Constructional panels of the type contemplated herein are widely used in the entertainment industry to convert and/or protect the surface of an arena, such as a sports arena. Where, for example, the arena has a grass surface on which sport is played, then this surface needs to be converted into an area on which an audience can move around and on which chairs can be placed without the grass being damaged. The panels are assembled together to cover the surface. It is important that the surface provided for the audience does not present trip hazards to the audience, and so care needs to be taken that the edges along which adjacent panels are joined together are at the same level. Moreover, such a level surface must not deform too much with the changing mass applied to it. Once the particular event is over, then the panels usually need to be easily removed and stored for future events.

[0031] As well as in the entertainment industry, such surfaces can also be used to transform a field or the like into an area on which vehicles, including aircraft, can move around and also be stored. It is important therefore that the individual panels be strong enough to support the mass applied.

[0032] Such a panel is shown in FIGS. 1A-5. The panels illustrated in the Figures can be releasably joined together by securing means (not shown), to neighbouring panels to form a continuous surface. Turning initially to FIGS. 1A and 2, these show a panel in accordance with the current invention and constructed in accordance with a method thereof. The panel, generally referenced 10, has a rectangular cuboid shape, although other shapes can be chosen for the panel without departing from the invention. The panel 10 comprises two sections, 11a, 11b, each having a peripheral side wall 12a, 12b, which are joined together along a line 13 by means of a heat weld, forming a fluid-tight seal.

[0033] The panel 10 has an in-use upper, planar surface 14 and a lower surface 15 which faces and is in contact with the ground during use. The plastics material from which the panel 10 is formed is chosen to suit the intended use, but is typically a mouldable plastics material such as polypropylene or co-polymer thereof

[0034] Regarding the section 11a, this includes throughapertures 20, formed through the upper surface 14 connecting the internal volume of the panel 10 with the outside. Additionally, around a throughaperture 20, the surface 14 is recessed to form a recess 21 (see FIG. 4) to accommodate a rivet (not shown). Extending from the inside surface 22 of the section 11a, is a plurality of walls 23. The walls 23 extend laterally across the inside surface 22 across the width of the section 11a. In further embodiments, not illustrated, a wall extends partially across the width of the section 11a, which reduces the weight of the panel 10. The walls 23 are deployed in pairs 23a, 23b defining therebetween a channel 24 in which a strengthening member 25 is housed.

[0035] A plurality of walls 33 similarly extends at least partially across the inside surface 32 of the section 11b, with the walls 33 being deployed pairwise 33a, 33b to form channels 34 therebetween. Throughapertures 30 are also defined in the lower surface 15. The side of the throughaperture 30 extends away from the lower surface 15 towards the section 11a to form a tube 35, open at both ends which in the embodiment shown has a frusto-conical cross-section.

[0036] When the two sections 11a, 11b are brought together as is illustrated in FIG. 5, the tube 35 is in contiguous engagement with the walls of a receiver 36 of complementary cross-section to the tube 35. Preferably, the tube forms a friction-fit connection with the receiver 36. As can also be seen from FIG. 5, once the sections 11a, 11b of the panel are brought together, the strengthening members 25 are housed in and extend along the channels 24 to resist deformation of the panel 10 when a stress force is applied.

[0037] In order to construct a panel 10 in accordance with the invention therefore, panel sections 11a, 11b are selected. Elongate strengthening members 25 are placed inside the channels 24 in one or both of the panel sections 11a, 11b.Care is taken that strengthening members 25 housed in opposing channels of the sections 11a, 11b do not prevent the sections 11a, 11b from being brought together. The sections 11a, 11b are then brought together so that the edges of the side walls 12a, 12b are sufficiently close to each other, to allow the edges to be secured together in a fluid-tight manner such as by welding.

[0038] As the sections 11a, 11b are brought together, the tubes 35 pass through a corresponding receiver 36 such that the end of a tube 35 extends into the recess 21 with the outside wall of the tube 35 in contact with the wall of the receiver 36. The edges are welded together. Additionally, rivets are welded to the top of each tube 35. As the tubes 35 and rivets are formed of a plastics material, the welding can be through the application of heat to raise the plastics material above its glass transition temperature so that the material can flow and be moulded. The rivet and the top of the tube 35 are formed to seal the end of the tube 35 and also to seal the tube 35 against the recess 21 to prevent fluid penetrating inside the panel 10.