RU208682U1 - Detail of the magnetic constructor - Google Patents

Abstract

The utility model relates to the field of light industry, namely the production of children's construction sets with elements for fastening parts in the form of magnets. The technical result of the claimed utility model is the creation of a constructor, the details of which make it possible to construct arbitrary three-dimensional forms by connecting the parts by means of magnets fixed in a certain way on the faces of the parts, with the possibility of attaching the parts to each other along each of the three mutually perpendicular axes in three-dimensional space and maintaining the strongest possible magnetic connection. The part of the magnetic constructor is made in the form of a three-dimensional body, the surface of which includes two triangular regions adjacent to each other with sides of equal length, while one of the poles of the magnet built into the part is located opposite the center of mass of one of the triangular regions, and opposite the center of mass of the other triangular area is the opposite pole of the magnet built into the part.

Description

The following solutions are known from the prior art.

Known designer, the details of which are made of multifaceted shape with connecting surfaces that are made with the possibility of connection with other connecting surfaces of the parts of the designer. The parts have magnetic parts on the connecting surfaces, wherein the magnetic parts of the connecting surfaces of the parts are configured to be connected to each other by means of their magnetic force. The magnetic part contains a magnet, both magnetic poles of which are located facing different directions, while the magnet is installed in the recess for installing the magnet formed in the part, and the separation prevention means for preventing the magnet from separating from the recess for installing the magnet (RF patent No. 2310493, published on 20.11 .2004).

A constructor consisting of cubes is also known (RF patent No. 253582011, published on 09/11/2019). Each side of the cube has a magnet in the center. The connection is provided by the presence of many types of cubes, each of which has a different cube scan. On the development of the cube, the faces of the cube and the magnets installed on each of the faces with the designation of the magnetic poles are indicated.

The disadvantage of the cubes of this constructor is that it is not possible to place the cube in an arbitrary position on a structure assembled from parts, because not all parties can be paired with each other.

The closest analogue of the patented solution is a constructor part made in the form of a polyhedron, contains magnets fixed on the face of the polyhedron with the possibility of joining it with another similar part. Each face of the polygon contains at least two magnets, while the magnet with a north plus near the surface of the part and the magnet with a south pole near the surface of the part are located on a line parallel to the face of the prism, equidistant relative to the perpendicular to its edge, built through the center of the face (patent RF No. 193528, published on October 31, 2019).

The disadvantage of the known product is the complexity of the design. Since the cube has 6 faces and 8 magnets are installed on each face, there are 48 magnets in total for one part. Magnets alternate their poles near the surface of the part, as a result of which the magnetic field created on the surface of one face with magnetic fastening often changes its direction to the opposite, which causes a weak magnetic connection. In addition, a large number of magnets makes them small enough to fit into the parts of the designer, so that the magnetic field of each magnet cannot have a high magnetic intensity relative to the size of the part.

Based on the foregoing, the magnetic connection of such magnets has a correspondingly small strength in comparison, for example, with the strength of the connection of a pair of large magnets inscribed in the space of the connected parts. In addition, each change in the direction of the magnetic field to the opposite leads to losses in the strength of the magnetic connection. These two factors generally result in a small magnetic field strength on the magnetic attachment surface and hence a small connection force. In addition, a large number of components for each part of the designer complicates production. Smaller magnets are more prone to falling out when struck or accidentally removed from the product when playing compared to larger magnets.

The technical problem solved by the proposed utility model is to expand the arsenal of technical means in the field of games related to magnetic constructors consisting of three-dimensional parts.

The technical result of the claimed utility model is the creation of a constructor, the details of which make it possible to construct arbitrary three-dimensional forms by connecting the parts by means of magnets fixed in a certain way on the faces of the parts, with the possibility of attaching the parts to each other along each of the three mutually perpendicular axes in three-dimensional space and maintaining a strong magnetic connections.

The claimed technical result is achieved due to the design of the part of the magnetic designer, made in the form of a three-dimensional body having a flat surface, including two triangular regions adjacent to each other along the sides of the triangular regions of equal length with full alignment of the sides, while opposite the center of mass of one of the triangular one of the poles of the magnet built into the part is located, and opposite the center of mass of the other triangular area, the opposite pole of the magnet built into the part is located.

In a particular case of the implementation of the utility model, the triangular region, which determines the position of the magnetic pole and determines the relative location of areas of such a shape and purpose, has three straight segments related to each other as the length of the side of the square to the length of half the diagonal of this square to the length of the half of the diagonal of this square.

In a particular case, the part has two faces with a common edge, containing two triangular regions of location of opposite magnetic poles adjacent by long sides along the indicated edge, while the completely combined long sides of the triangular regions lie on the indicated edge.

In a particular case of the implementation of the utility model, the three-dimensional body is a cube.

In a particular case of the implementation of the utility model, the three-dimensional body is a straight prism.

In a particular case of the implementation of the utility model, the three-dimensional body is a pyramid with a square-shaped base.

In a particular case of the implementation of the utility model, a three-dimensional body is a figure having concave and/or convex surfaces, including at least one flat surface with a magnetic fastening described above.

In a particular case of the implementation of the utility model, the magnet embedded in the part is located in such a way that one of the poles is located opposite the center of the area where the magnetic pole is located.

In a particular case of the implementation of the utility model, the magnet embedded in the part is located in such a way that one of the poles is located opposite the center of the first region of the magnetic pole, and the opposite pole is located opposite the center of the second region of the magnetic pole, while the first and second regions are adjacent to each other. to a friend by completely matching the short side of one area with the short side of another area or by completely matching the long side of one area with the long side of another area.

The proposed part of the magnetic designer uses fewer magnets than the closest analogue, which allows you to place larger magnets inside the part, thereby providing a stronger connection with other parts. At the same time, at least two magnets are located near the surface of one face with a magnetic fastening, which makes it possible to construct, by installing the part in any available position along each of the three mutually perpendicular axes in three-dimensional space, and to complete the structure from the designer’s parts using the designer’s part, at the point where there is an open magnetic mount.

Further, the solution is explained by reference to the figures, which show the following.

Fig. 1 is a general view of the location of the magnets on the side of the free-form part, forming a magnetic mount.

Fig. 2 - a variant of pairing two square faces of one part with magnetic fastening on each face.

Fig. 3 - a scan of the cube indicating the location of the poles of the magnets.

Fig. 4 is a general view of a piece in the form of a cube, indicating the location of the poles of the magnets.

Fig. 5 is a general view of the part in the form of a pyramid, indicating the location of the poles of the magnets.

Fig. 6, 7 - options for the location of the magnet built into the part.

The proposed part of the magnetic constructor in the general case is a three-dimensional body of arbitrary (any) shape with at least one flat surface, in which magnets are embedded and fixed according to the following principle.

Any of the faces of the part may include at least two triangular regions, opposite each of which is the side of the magnet embedded in the part.

On each of these sides of the magnets is a magnet pole. Such triangular regions and the positions of the sides of the magnets near the surfaces defined by said regions are shown in Fig. 1, which shows the face surface 1 having an arbitrary shape, but such a shape that it completely includes at least two triangular regions 2 representing is the location of the magnetic pole. The division into regions is conditional and is used only at the stage of marking the location of the magnets. On the finished product, the boundaries of the areas where the magnets are located are not shown. The location of these areas, relative to each other, remains unchanged for fastening, as shown in Fig. 1, if it is necessary to obtain a partial magnetic fastening by excluding some of the magnets.

To indicate the location of the magnet with the north or south pole to the surface of the part, the generally accepted designations are taken: “N” for the north pole of magnet side 3 and “S” for the south pole of magnet side 4.

The sides of the magnets 3 and 4 are strictly within their area of the magnet, namely in the center of mass of the triangular area of the magnet.

.Within the framework of the entire constructor and, in particular, within the framework of the part, the magnet location area is a fixed shape of a triangular surface with a fixed size, enclosed within three straight segments, which relate to each other in the following ratio: the length of the side of the square to the length of half the diagonal of this square to the length of half the diagonal of that square. Which is expressed by the following proportion:

.

Part of the part surface belonging to the magnet location area can have only one magnet located at the center of mass of the triangular area. Location zones of sides 3 or 4 of the magnet on the surface of the part cannot intersect with each other, but can adjoin each other with full alignment of their sides of equal length.

Figure 1 shows a plurality of areas of the magnet, each of which is a magnet.

Each of the magnet location areas, together with the magnet located on it, may not be mandatory for an arbitrary part, due to the shape and purpose of the part.

A part can have one or more pairs of connected faces. Such a pair of connected faces is two faces that are perpendicular to each other and have a common edge. Each of these two faces has a flat surface with magnets as in Fig. 1 located so that it is adjacent to a common edge of a pair of connected faces.

On the faces belonging to a pair of connected faces, the location of the magnet location areas and the location of the magnets with the designation of the type of the magnetic pole near the surface, shown in Fig. 2.

In a particular and preferred case, the main structural detail of the designer is a cube. The development of its faces with the image of the areas where the magnet is located and with the image of the magnets with the designation of the poles of the magnets near the surface of the part is shown in Fig. 3.

All of the magnets and magnet pole locations shown in FIG. 3, are an integral part of the details of the constructor cube.

An illustration of an example of the basic detail of the constructor - a cube with the image of the areas of the magnet, with the image of the magnets and with the designation of the poles of the magnets is shown in Fig. 4.

Also, a three-dimensional body can be in the form of a straight prism, the base of which is a right-angled isosceles triangle, two adjacent side faces of which are squares at the right angle of the base. The square faces of this prism are magnetically attached, as shown in FIG. 1. The faces of this prism, having the form of a right-angled triangle, have on themselves a partial magnetic fastening from that magnetic fastening, which is shown in Fig. one.

Another example of a constructor detail is shown in Fig. 5, namely a detail in the form of a pyramid with the image of the areas of the magnet, with the image of the magnets and with the designation of the poles of the magnets. The base of the pyramid in Fig. 5 is a square. Two adjacent side faces of the pyramid are at right angles to the base. Various configurations of the pyramid-shaped part are possible. The first configuration includes a square face with a magnetic mount positioned as shown in FIG. one.

The rectangular triangular faces of this pyramid include a partial magnetic attachment from the magnetic attachment shown in FIG. one.

A pyramid-shaped part in another design contains metal inserts that allow you to attach the part to any magnetic fasteners of other parts on a square face and faces that have the shape of a right-angled triangle.

The execution of magnets embedded in the part can have different shapes. For exemplary embodiments, embodiments of the magnets are shown.

In FIG. 6 shows magnets 6 and 7 built into the part, located in such a way that each of the magnetic poles 3, 4 is located opposite the center of mass of the triangular region of the location of the magnetic pole on one of the perpendicular faces 9 or 10.

In FIG. 7 shows a magnet 8 built into the part, located in such a way that one of the magnetic poles 3 or 4 is located opposite the center of mass of the triangle of the first region of the magnet pole on face 9, and the opposite pole is located opposite the center of mass of the triangle of the second region of the magnet on face 10 , while the first and second regions are adjacent to each other in full alignment of their long sides.

For various forms of implementation, the following materials are used for various elements. The magnets are permanent magnets made of metal alloy. For the best connection, it is preferable to use neodymium alloy magnets with high magnetic force. The housing can be made of any non-magnetized, solid material: plastic, wood, metal.

Elements of parts (magnets/housing) are fastened together by welding, glue or by interference fit.

The utility model is implemented as follows.

The magnetic constructor can include an unlimited number of magnetic constructor parts.

To make the connection, it is necessary to bring two suitable magnetic attachments (Fig. 1) to each other until they touch so that opposite poles are aligned with each other.

This is determined due to the fact that there is a force of attraction that the player feels. If there is a force repelling the part from the target position, then the player brings the part, combining the poles of the same name. Then the player needs to rotate the part so as to combine opposite poles.

Acting in this way, the player connects the parts of the constructor to each other, thereby building the desired forms (models of buildings, statues, animals, geometric shapes). Then, at will, he uses the received figures for the game.

Claims (8)

1. A part of a magnetic construction kit made in the form of a polyhedron having a face including two triangular regions adjacent to each other with sides of the same length, opposite the center of mass of each triangular region located on the edge of the part, a permanent magnet is installed, while opposite the center of mass one of the triangular areas, which includes each face of the part, is one of the poles of the magnet built into the part, and opposite the center of mass of the other triangular area is the opposite pole of the magnet built into the part. 2. Detail of the magnetic construction kit according to claim 1, characterized in that the triangular area that determines the position of the magnet and determines the relative location of areas of this shape and purpose, includes three straight segments that relate to each other as the length of the side of the square to the length of half the diagonal of this square to the length of half the diagonal of that square. 3. Detail of the magnetic construction kit according to claim 1, characterized in that the part has two faces with a common edge, containing areas of magnetic poles adjacent to their long sides along the specified edge. 4. Detail of the magnetic constructor according to claim 1, characterized in that the three-dimensional body is a cube. 5. Detail of the magnetic constructor according to claim 1, characterized in that the three-dimensional body is a prism. 6. Detail of the magnetic constructor three segments according to claim 1, characterized in that the three-dimensional body is a pyramid. 7. The part of the magnetic constructor according to claim 1, characterized in that the magnet embedded in the part is located in such a way that one of the magnetic poles is located opposite the center of the area where the magnet pole is located. 8. The part of the magnetic constructor according to claim 1, characterized in that the magnet built into the part is located in such a way that one of the poles is located opposite the center of the first area of the magnet pole, and the opposite pole is located opposite the center of the second area of the magnet, while the first and second areas are adjacent to each other by complete alignment of the long sides of the magnet location areas along the common edge of the two faces of the part, which are at an angle of 90 degrees to each other.

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