3D tile

Abstract

The invention relates to a three-dimensional tile, of metal or plastic, having at least one face (1) with an octagonal socket (2) and another face (1) with an octagonal projection (3). Each tile is joined in this way with a similar tile, forming structures in space. The octagonal socket (2) has an inner embossed cord (7) miming along it to which a tooth (6) carried on the straight sections (4), which together with the corner sections (5) form the octagonal projection (3), attaches. The 3D tile can be used to create structures of both aesthetic and utility nature.

Claims

1. A tile cube, comprising: six faces, wherein at least one face of the six faces has an octagonal socket and at least one other face of the six faces has an octagonal protrusion each said octagonal protrusion formed by four straight members and four corner members, alternating between a straight member of the four straight members and a corner member of the four corner members, with oppositely oriented straight members of the four straight members being parallel to each other and to edges of the tile cube, each said straight member of the four straight members being flexible and separate from adjacent corner members of the four corner members, wherein each said straight member of the four straight members has an outwardly-oriented tooth, and wherein each said octagonal socket has an embossed inner protrusion extending inwardly along an interior of said octagonal socket and to which the tooth on each corresponding straight section of the four straight sections of another tile cube is attachable.

2. The tile cube of claim 1, wherein the embossed inner protrusion is attachable to the tooth of the octagonal protrusion of said another tile cube at up to a 45 degree angle.

Description

BRIEF DESCRIPTION OF THE DRAWINGS

(1) The invention will be apparent to those skilled in the art with reference to the accompanying drawings in which it is illustrated in a non-limiting manner.

(2) FIG. 1 shows a plan view of one of the sides of the three-dimensional tile of the present invention.

(3) FIG. 2 shows a side view of the three-dimensional tile with the octagonal protrusion allowing for the creation of tile arrays.

(4) FIG. 3 shows a plan view of the three-dimensional tile side, with the octagonal protrusion attachable to one of the faces of another tile, to create the deployed structure in space.

(5) FIG. 4 shows an illustrative combination of three 3D tiles, in perspective view, to create a structure in space.

(6) FIG. 5 shows a section of a three-dimensional tile showing the faces, with the sockets for inserting the protrusions. Correspondingly, the embossed inner cord running along the sockets is shown, allowing for the assembly and disassembly of three-dimensional tiles in structures extending into space.

DETAILED DESCRIPTION OF THE PREFERRED EMBODIMENT

(7) Referring now to the accompanying drawings, we will describe illustrative embodiments of the three-dimensional tile in order to show both its advantages and its structural features.

(8) The three-dimensional tile of the invention consists of 6 faces (1), FIG. 1, wherein at least one of the faces (1) has an octagonal socket (2). Each octagonal socket (2) has such a depth that it allows inserting an octagonal protrusion (3), FIG. 3, in such a way that the joined faces are in contact. Each three-dimensional tile has an octagonal protrusion (3).

(9) The 3D tile joining in the above manner contributes to the creation of three-dimensional structures, FIG. 4, that deploy in space and create shapes, extending to three dimensions, depending on the way the tiles are joined together.

(10) The octagonal protrusion (3) is formed by separate sections, where the four straight sections (4) are per two parallel to each other and parallel to the edges of the cube, and there are four corner sections (5) located between the straight sections (4). The straight sections (4) play an important role in joining the three-dimensional tiles as they are flexible and have tolerances to allow the formed octagonal protrusion (3) to be inserted into the corresponding octagonal socket (2). To assemble and disassemble the three-dimensional tiles, the straight sections (4) have a tooth (6), FIG. 2, extending outwardly with respect to the straight section (4). Each tooth (6) enters the octagonal socket (2) when assembling the tiles and secures, by overlapping the corresponding tooth of an embossed inner cord (7), FIG. 5, extending along the interior of the octagonal socket (2). Consequently, due to its flexibility, the user has to exert slight pressure inwardly so that the octagonal protrusion (3) enters the octagonal socket (2) in such a way that the tooth (6) is secured by overlapping the opposite tooth of the embossed inner cord (7).

(11) An important advantage of this particular connection and the presence of an embossed inner cord (7), all along the interior of the octagonal socket (2), is that the connection between two 3D tiles can be made even at an angle of 45°. In this way, the three-dimensional tile structures can extend to different levels and in different orientations in space, always using the same element.

(12) The three-dimensional tile can be made of any material, but it is preferable to be made of plastic, such as the acrylonitrile butadiene styrene, known as abs, metal or a combination thereof.

(13) It should be noted at this point that the invention was described with reference to illustrative examples of application, but not limited to. Thus any change or modification in the shape, dimensions, morphology, materials used and components of construction and assembly, as long as they do not constitute a new inventive step and do not contribute to the technical development of the already known are considered to be contained in the purposes and aspects of the present invention as summarized in claims below.