FR3040310B1 - BUILDING ELEMENTS ASSEMBLED BETWEEN THEM. - Google Patents

Abstract

The invention relates to elementary blocks 10, such that each block comprises at least one pair of magnetic poles 13N, 13S of opposite polarities, inducing a magnetic field centered on a magnetic axis X13, and at least one pair of bearing faces. 11, parallel to each other and perpendicular to said magnetic axis, each magnetic pole being substantially flush with one of the bearing faces, each bearing face comprising, at one longitudinal end 12 of the block, a convex semicircular shape substantially centered on the X13 axis.

Description

The present invention relates to a set of elements assembled together, of the brick type.

Such bricks provided under the trademark Lego ™ are particularly known. These bricks include interlocking elements between them and to position and maintain two bricks between them. However, such bricks can assemble only so that they are coplanar or at right angles to one another.

Kapla ™ boards are also known. All the faces of these boards are smooth and do not allow the maintenance of the boards between them, except by their own weight. The invention aims to provide bricks allowing including assembly in other positions.

To achieve its purpose, the invention proposes a set of elementary blocks, such that for each block: it comprises at least one pair of magnetic poles of opposite polarities, inducing a magnetic field centered on a magnetic axis; it comprises at least one pair of support faces parallel to each other and perpendicular to the magnetic axis; each magnetic pole is substantially flush with a respective bearing surface of this pair of faces; each of the bearing faces comprises, at least at one longitudinal end of the block, a shape of a convex semicircle substantially centered on the magnetic axis; - The two bearing faces are interconnected by preferably rectilinear generatrices.

Preferably, the generatrices are parallel to each other and even more preferably parallel to the magnetic axis.

Preferably, each block comprises two opposite longitudinal ends, each forming a half-cylinder around a respective magnetic axis. Such a block may further comprise at least a third magnetic axis, coplanar with the magnetic axes of the ends, the distance between two immediately adjacent axes being substantially equal to the diameter of the half-cylinders, so that the diameter of the half-cylinders defines a module longitudinally separating two successive poles of the same face.

The two poles may be two opposite poles of the same magnet, preferably cylindrical or be carried by two different magnets of substantially coaxial magnetic axes.

At least one of the bearing faces, preferably each bearing face, advantageously comprises a non-slip layer.

Several embodiments of the invention will be described below, by way of non-limiting examples, with reference to the accompanying drawings in which: - Figure 1 is a perspective view of a double block according to the invention; FIG. 2 illustrates an object made with twenty blocks such as that of FIG. 1; FIG. 3 is a view from above of the block of FIG. 1; - Figure 4 is an elevational view of a frustoconical block according to the invention; - Figure 5 is a view of another block of another form, oblong; - Figure 6 is a longitudinal elevational view of a triple block comprising a transverse window; - Figure 7 is a longitudinal elevational view of a triple block provided to be slidable in the transverse window of the block of Figure 6; - Figure 8 is a top view of a triple block; FIG. 9 is a perspective view of a cylindrical block; FIG. 10 is a view from above of the block of FIG. 9; FIG. 11 illustrates a detail of an end of a block according to the invention in which each dipole consists of two magnets; and FIG. 12 illustrates a detail of an end of a block according to the invention in which each dipole consists of the two poles of the same magnet.

Figures 1 and 3 illustrate a building block 10 according to the invention. This block comprises two bearing faces 11 parallel to each other, each substantially flat. Each face 11 comprises, at least at one longitudinal end 12 of the block, a convex half-circle shape centered on an end axis X13. This axis X13 is perpendicular to the face. The two faces being interconnected by rectilinear generatrices and perpendicular to this face. The two axes are distant from a module M, equal to the diameter of the circle of each of the ends. In addition, in the illustrated example, the thickness E10 of a block, measured between the two faces 11 is close to three fifths of the module M, and substantially equal to M / 1.618.

Thus, the block illustrated in Figure 1 comprises two ends each formed of two half-cylinders, each oriented on a respective axis XI3, interconnected by a rectangular parallelepiped in top view. The block has a width equal to the module M and a length equal to two modules M, ie 2M. The generatrices also form two opposite planar lateral faces 14, connecting the half-cylinders to each other.

Each end 12 of a bearing face 11 comprises a respective magnetic pole 13, flush with the rest of the surface of the face 11. Thus, as shown in Figure 1, the visible face 11 comprises two magnetic poles noted 13N, the N indicating that they constitute the north pole of the magnet that carries them. In the illustrated example, one of the faces comprises two north poles, the other of the faces comprises two south poles, as illustrated in FIGS. 11 and 12. In addition, the magnetic field coming from each pole 13 is substantially centered on the respective axis X13; the axis X13 therefore constitutes a magnetic axis of the block 10. Thus, each end 12 of the block 10 comprises two opposite poles 13S, 13N and coaxial, that is to say whose magnetic fields are coaxial with each other, thus forming a 13S pair, 13N of single magnetic axis poles X13.

As illustrated in FIGS. 11 and 12, a pair of poles can be formed with two separate magnets (FIG. 11), of small thickness El3 relative to the thickness E10 of the block 10, which can be economical when expensive magnets are used. . Another possibility, illustrated in FIG. 12, is to use a single magnet whose length is substantially equal to the thickness E10 of the block 10.

As illustrated in Figure 2, blocks 10 identical to each other and to that shown in Figure 1 can be stacked to create objects. In this example, an object 20, of substantially humanoid shape, was made with twenty blocks 10. To make such an object, two blocks are superimposed between them so that a pole 13 of one is in contact with a pole 13 of opposite polarity of the other block.

Thus, the respective magnetic axes XI3 of these poles are substantially aligned. The two blocks can then be oriented relative to each other around the common axis X13, 360 ° if another block does not interfere. This is the case of a first block 10A which can rotate without interference of 360 ° around the common magnetic axis X13 with a second block 10B, on which it is supported. The second block 10B and a third block 10C bear on the same bearing face of a fourth block 10D. They are not completely free of their orientation, one annoying the other. Nevertheless, the cylindrical shape of their respective ends 12 allows them to take an infinity of relative positions around their magnetic axes XI3 respectively common with the fourth block 10D, until their lateral faces come into contact. The poles serve to both maintain a block to another, centering since the magnetic fields tend to align naturally, and pivot.

It is noted in Figures 11 and 12 that the block comprises, on each support face 11, a non-slip layer 22; such a layer helps to keep blocks on top of each other in their chosen relative position.

Figures 4 to 10 illustrate other forms for blocks according to the invention.

FIG. 4 illustrates a frustoconical block comprising a single magnetic axis X13 for a single pair of poles 13. It comprises a first bearing face 11A formed by a large base of the truncated cone; this first face 11A is circular, of diameter D equal to the module M, and centered on the magnetic axis X13. It comprises a second bearing face 11B formed by a small base of the truncated cone; this second face 11B is circular, of smaller diameter than the module M, and focused on the magnetic axis.

FIG. 5 illustrates a block having substantially the same proportions as the block of FIGS. 1 to 3, except that it comprises only one magnetic axis XI 3, and in that this axis XI 3 is perpendicular to the lateral faces 14, halfway between the ends 12, and in that the bearing faces are constituted by the lateral faces 14.

FIG. 6 illustrates a triple block 10 since it has a length equal to three modules M and comprises along its length three magnetic axes XI 3, two of which are coaxial with the cylindrical ends 13 and the third is between the two others at a distance equal to the module M. it has a thickness E10. It further comprises a through opening 24 between the two lateral faces 14, equidistant from the ends 12 and equidistant from the bearing faces 11. The height of the window is substantially equal to one third of the thickness E10 and its width is equal to module M. FIG. 8 illustrates a view from above of the block of FIG. 6.

Figure 7 illustrates a triple block which differs from that of Figure 6 in that its thickness is substantially equal to one third of the thickness E10 of the block of Figure 6 and that it has no window. FIG. 8 also illustrates a view from above of the block of FIG. 7. The block of FIG. 7 is adapted to be disposed through the window of the block of FIG. 6.

Figures 9 and 10 illustrate a same cylindrical block, respectively in perspective and in top view. This block does not comprise lateral faces, it includes only one magnetic axis XI3, coaxial with the cylinder formed by the block 10. Its diameter is equal to the module M.

Of course, the invention is not limited to the preferred embodiments which have just been described, but on the contrary the invention is defined by the following claims.

It will be apparent to those skilled in the art that various modifications can be made to the embodiments described above, in the light of the teaching that has just been disclosed.

Thus, in all the examples illustrated, the magnets employed are cylindrical, they could, for example, be parallelepipedic.

The shapes of the blocks and their thicknesses are not limited either to those described. For example, a block may be cylindrical, like that of Figure 9, and have a thickness substantially equal to one third of the module.

A block according to the invention may in particular have a length equal to any multiple of the module, such as the double and triple blocks previously described. Thus, a block may be quadruple or fivefold, that is to say have a length equal to four or five modules respectively and comprise four or five magnetic axes along their length, each separated by a distance equal to one module and two are coaxial with the cylindrical ends.

A set of blocks according to the invention is particularly suitable for constituting a building set. It can also be used to make furniture items, mountable and removable, made as needed, for example a plant pot, a display, decorative elements or feet that can support a shelf; in addition, such furniture, once disassembled, is compact, since it can be stored in a volume that does not exceed or just the volume of only blocks.

Claims (5)

claims 1. A set of elementary blocks (10), each block of which is characterized in that: it comprises at least one pair of magnetic poles (13N, 13S) of respective opposite polarity (N, S), inducing a centered magnetic field on a magnetic axis (XI3), it comprises at least one pair of bearing faces (11) parallel to each other and perpendicular to said magnetic axis; each magnetic pole is substantially flush with a respective bearing face of said pair of faces; each of said bearing faces comprises, at least at one longitudinal end of the block, a shape of a convex semicircle substantially centered on said magnetic axis, the two bearing faces are interconnected by generatrices of rectilinear preference. 2. Set of blocks according to claim 1, characterized in that the generatrices are parallel to each other, and preferably parallel to the magnetic axis. 3. Set of blocks according to one of claims 1 and 2, characterized in that it comprises a block comprising two opposite longitudinal ends (12), each forming a half-cylinder about a respective magnetic axis (XI3). 4. Set of blocks according to claim 3, characterized in that it comprises a block comprising two opposite longitudinal ends (12), and further comprising at least a third magnetic axis, coplanar with the magnetic axes of said ends, the distance between two immediately adjacent axes being substantially equal to the diameter of said half-cylinders. 5. Set of blocks according to one of claims 1 to 4, characterized in that at least one of the bearing faces, preferably each bearing face, comprises a non-slip layer (22).