HU180639B - Spatial logic magnetic toy - Google Patents

Description

BACKGROUND OF THE INVENTION The invention is a logic game, a magnetic body capable of developing logical abilities and providing a pleasant pastime.

Three-dimensional .magnetic building toys are known, for example. Hungarian Patent No. 154,051. The common disadvantage of constructive toys is that they are practically only of interest to young children.

Magnetic puzzles, numerals or letters can be useful aids in education, but also only for young children. It gives such solutions eg. Hungarian Patent No. 165,196.

Many spatial logic games are known. Such are described e.g. Hungarian patents 170,062, French patents 2,161,379 and English patents 3,811,683. A common feature of the vast majority of these is that the possible connections between the elements are mechanical.

The advantage of applying magnetic interaction in a logic game is that the relationships between the elements are simple. It is an object of the present invention to provide a three-dimensional logic game which utilizes the attractive and repulsive properties of magnets and which is capable of developing certain logical capabilities.

BACKGROUND OF THE INVENTION The invention is a spatial logic game, a magnetic body of shaped bodies, called cloves, defined by the cluster, the clusters being disjointly disposed directly on each other around a three-dimensional Z axis, in one or more layers in the Z direction, respectively. . The cloves have surfaces such as colors or numbers or letters or pictures or drawings or tactile shapes.

In an exemplary embodiment, the magnetic body of all shaped bodies is a regular n-sided column of m layers and n clusters per layer, or a cylinder or sphere or sphere of m layers and n concavities within a single layer, but may be less regular or amo rf test is, m: 1, 2

Tg or 3 and n are positive integers. In some embodiments, the magnetic body has a hole (annular) along the Z axis.

In an advantageous embodiment for handling the toy, n is an even number, so the symmetry properties of the magnetic body are also better.

In a preferred embodiment, the cloves have iron strings which concentrate the energy of the magnetic field near the contact sides of the cloves, so that the cloves are bonded with great force.

In a preferred embodiment, the magnetic field is configured such that the cloves can only be positioned at specific locations and positions relative to one another, thereby providing easy handling and automatic exclusion of certain clusters, and adherence to the rules of the game.

In a further preferred embodiment, the magnetic poles are arranged along rays perpendicular to the Z axis of the magnetic body, i.e., for a given cluster in a given layer, the north pole is closer to the Z axis than for the adjacent cluster. vice versa and so on.

In a further preferred embodiment, the magnetic poles are arranged in the direction of the Z axis of the magnetic body, i.e., for a given clay in a given layer, the north pole is closer to the base plate, the south pole is closer to the base plate and vice versa.

The drawing illustrates a simple embodiment of a magnetic body according to the invention.

Figure 1 shows a 6-sided regular column with a hole along its axis of symmetry.

Figure 2 shows the structure of a clove of a 6-sided regular block.

Small columns are called cloves 1. The Z axis coincides with the symmetry axis of a six-sided regular column. The magnetic field of the clove 1 is provided by the permanent magnet 2. Concentration of the magnetic field energy near the side panels 7 is provided by the iron inserts 3 and 4. The permanent magnet 2 is magnetized radially perpendicular to the Z axis, the northern pole is closer to the Z axis than the southern pole for a given cluster, and vice versa for the adjacent cloves, and so on. The above solution ensures that the cloves can only move to specific locations and positions relative to one another. Further parts of the cloves are the filling bodies 5 and 6, for example made of plastic.

The clovers have 8 covers and 9 bases in two different colors, each plate is numbered identically and each cluster has one and only one number, e.g. the first clove with 1, the second with 2, etc.

With the toy of the invention, the game is performed as follows:

The cloves 1 are assembled e.g. so that their cover is the same color and the numbers are 1 to 6 in a circle. After assembling, the magnetic field holds the cloves tightly together. The object of the game is to put together a predefined sequence of color numbers in regular steps.

Specifically: unload the original sequence from the properly mixed cloves. The order of colors and numbers can be changed according to the following rule: by grasping the magnetic body with two hands along one of the three planes separating the cloves 1 passing through the symmetry axis Z, the two cluster groups are separated and then one of the clusters obtained and rotate the two clusters together. This operation is repeated, varying the fracture planes and the direction of rotation, until the desired color and number order is obtained.

As you can see, the logical magnetic game is very simple design, the magnetic field may be designed hogj ⁷ cloves sufficiently adhere to each other with great force, the magnetic iTest can not be observed disintegration of and compliance with the rules of the game section of the magnetic field itself provides, for example. in the case of a 6-sided symmetrical block, two or four cloves cannot be rotated. The complexity of the game depends strongly on the number of cloves and layers. The embodiment discussed is relatively simple.

The game is capable of developing or testing certain logical, some embodiments of arithmetic or grammar.

Claims (9)

Claims 1. A spatial logic magnetic game consisting of shaped bodies, so-called clusters (1), the clusters being arranged in a circle, directly adjacent to one another, in a Z direction in one or more layers, characterized in that the clusters (1) have corresponding sides. Permanent magnets (2) for generating concentrated magnetic field energies in the vicinity (7), and signals (8, 9) on the outer surface of the cloves, e.g. colors or .numbers, or letters or pictures, or any combination of these. The magnetic toy as defined in claim 1, characterized in that it has a n-sided regular block or cylinder, or sphere, or spherical layer, but may also be less regular or amorphous. An embodiment of the magnetic toy as defined in claim 1 or 2, characterized in that the layer or, in the case of multiple layers, each layer has an even number of ridges (1). An embodiment of the magnetic toy as defined in claim 2 or 3, characterized in that there is a hole in the magnetic body consisting of all clusters along the Z axis. The magnetic toy as defined in claim 1, characterized in that the ridges (1) contain ferromagnetic materials, such as iron inserts (3, 4), which concentrate the energy of the magnetic field near the contact sides (7) of the ridges. The magnetic toy as defined in claim 1 or 5, characterized in that the magnetic poles are arranged along rays perpendicular to the Z axis, such that adjacent adjacent ridges (1) are attracted to each other in the original order. . Magnetic toy according to claim 1 or 5, characterized in that the magnetic poles are arranged in the direction of the Z axis so that the adjacent ridges (1) are attracted to one another in the original order. The magnetic toy set as defined in claim 1, characterized in that the ridges (1) comprise a lightweight bulking material such as plastic (5, 6). Magnetic toy according to claim 3 or 4, 6 or 7, characterized in that the cloves (1) are preferably on the base and topsheet (8, 9), in two different colors and one , having numbers and / or letters different from the other cloves, or having two images on the base and topsheet (8, 9) of the magnetic body consisting of all cloves.