HU231132B1 - Three-dimensional puzzle - Google Patents

Description

1176 / KZS

Spatial logic game

The present invention relates to a spatial logic game comprising a support structure, a moving structure attached to the supporting structure, and toy elements connected to the moving structure.

Spatial logic games are still very popular today. One of their best-known representatives is the so-called Rubik's cube, registered in Hungary under number 120062. The six sides of a Rubik's cube are made up of the surfaces of smaller cubes, which are marked differently on each side. The smaller cubes can be rotated relative to each other so that the uniform markings on one side can be mixed and unloaded again.

U.S. Pat. No. 2005/098947 discloses a three-dimensional logic game comprising rearrangably connected elements comprising a support structure, a moving structure attached to the support structure, and toy elements connected to the moving structure. In the solution shown, the support structure 20 is formed along the lines of gravity of two tetrahedra with the same center of gravity, at the vertices of which tetrahedron or octahedron-shaped play elements are incorporated, which can be moved along rails. The actuator is provided with gear and flexible connections.

U.S. Pat. No. 5,645,278 discloses a spatial logic game in which the game elements 25 are rotatably arranged around the vertices of a tetrahedron, where the game elements can be slid along trajectories and the axes of rotation are axially deflected.

U.S. Pat. No. 4,881,738 discloses a three-dimensional patience game having play elements assembled from longitudinal rail segments slidable and rotatable along longitudinal rail tracks.

U.S. Pat. No. 5,035,430 discloses a sliding rod spatial logic game in which game elements can be displaced along spatial axes, thereby rearranging the configuration of the toy body, and where the spatial axes are located along a rectangular coordinate system.

UHUM MII

SZTNH-100268431

-2This type of puzzling spatial logic games develop spatial vision and combination skills. There would be a need for a spatial logic game with a similar principle but allowing for different spatial movements.

It is an object of the present invention to provide a new type of spatial logic game different from previous spatial logic games.

The object of the invention is achieved by a spatial logic game according to claim 1.

Some preferred embodiments of the invention are defined in the subclaims.

Further details of the invention will now be described with reference to the accompanying drawings. In the drawing is

Figure 1 is a perspective view of a preferred embodiment of a spatial logic game according to the invention in the first rest position of the game;

Figure 2 is a perspective view of the support structure of the embodiment of Figure 1;

Figure 3 is a perspective view of the actuating structure of the embodiment of Figure 1;

Figure 3a is a perspective view of the actuating elements of the actuator of Figure 3 without the push rods;

Figure 3b is a perspective view illustrating the arrangement of the push rods of the actuator of Figure 3;

Figure 4 is a perspective view of an actuator of the actuator of Figure 3;

Figure 5 is a perspective view of three actuators mounted on the support structure of the embodiment of Figure 1;

Figure 6 is a perspective view of the spatial logic game of Figure 1 with the carriages partially removed in the first rest position;

Figure 7 is an exploded perspective view of a rail and its car of the spatial logic game of Figure 1;

Figure 8 is a perspective view of the spatial logic game of Figure 1 in the second rest position of the game;

Figure 9 is a perspective view of the spatial logic game of Figure 1 with the carriages partially removed in the second rest position;

Figure 10 is a perspective view of the drive structure and a rail and a carriage thereon in the first rest position of the embodiment of Figure 1;

Figure 11 is a perspective view of the drive structure and a rail and the carriage arranged thereon in the second rest position,

Fig. 12 is a view of Fig. 11 showing two push rods.

1 -7. Figures 1 to 5 show elements of a preferred embodiment of a spatial logic game 10 according to the invention in the first rest position of the game 10.

The spatial logic game 10 has a support structure 70 (Figure 2) and an actuator 80 attached to the support structure 70 (Figures 3 to 5). Mounted on the moving structure 80 10 are curved rails 40 on which are mounted carriages 60 slidable along the rails 40 (Figure 7).

The support structure 70 includes an octahedral frame 72 having 6 apexes 73 in the geometric sense and edges 74 connecting them 12. The edges 74 in the present case are formed by rods 75 which are held together by clamps 76 at their tips 73. As another example! it is possible that the end of the rods 75 is threaded and threadedly connected to the clamping elements arranged at the tips 73. Of course, the octahedral frame 72 may be formed in a number of other ways, as will be apparent to those skilled in the art, e.g. with printing.

The actuator 80 includes actuators 81 and push rods 92, shown in Figure 3 without the support 70 shown. Fig. 3a shows the arrangement of the moving elements 81 relative to each other, and Fig. 3b shows the arrangement of the push rods 92. Fig. 4 shows a single actuator 81 per se, and Fig. 5 shows three actuators 81 on the support structure 70.

Each of the actuators 81 includes a pair of gears 82 disposed along the edges 74 connecting the ends 73 of the octahedral frame 72. Each gear 82 has two gears 83, 84 arranged rotationally relative to each other, preferably the gear 82 is formed as an element, each end of which forms the gears 83 and 84, respectively. Within a gear 82, the non-rotational arrangement of the gears 83, 84 can of course be realized in other ways, for example, so that the rods 75 forming the edges 74 can rotate about their own axis, and the gears 83, 84 of the gears 82 for these rods 75 are fixed without rotation, so that the gears 83, 84 of a gear 82 cannot rotate relative to each other, but only together with the rod 75. Optionally, the rod 75 and the associated gear 82 may be formed as a single element, i.e., the gear 82 may also act as a link between the tips 73 of the support structure 70. For the sake of uniform terminology, the solid or tubular core of the gears 82 is considered to be part of the support structure 70, while the toothed outer part of the gears 82 is considered to be part of the drive structure 80.

Each of the gears 83, 84 is in drive communication with the gears 83 or 84 of the gears 82 arranged along adjacent edges 74 (running into the same apex 73), so that one of the gears 82 is rotated by means of all the gears 83 and 84 in communication with each other. 84 gears, and so all 82 gears come into rotation. The gears 82 in such a drive connection form a braingear structure,

The brain gear structure can also be described as the gear 83 of the first gear 82 arranged along the first edge 74 connecting the first and second tips 73 closer to the first tip 73 and the gears 83 on the edges 74 adjacent the first edge running into the first tip 73 closer to the first tip 73. It is in drive communication with the gears 83, and the gear 84 of the first gear 82 closer to the second apex 73 is in communication with the gears 84 of the gears 82 arranged at the edges 74 adjacent the first edge 73 and closer to the first tip 73. The terms “first and second” used herein are for convenience only and do not imply any difference in structure or function.

Since the axes of rotation of the adjacent gears 83 and 84, respectively, are at an angle to each other, the gears 83, 84 are preferably tapered.

-5The actuators 81 have an actuator arm 86 associated with each of the gears 82 for that gear 82! can be rotated together about the axis of rotation t of the gear 82 (Id. Fig. 5). For example, the gear 82 and the associated actuating arm 86 may be formed as an element, as can be seen in FIG. Enné! In the embodiment, grooves 88 are formed in the free end 87 of the arms 86 into which the appropriately formed rails 40 can be snapped and the longitudinal axis of the grooves 87 can be tilted relative to the arm 86, but of course any other type of connection (e.g. articulated) is possible. the 40 rails are 180 degrees or so! 180 degrees of transfer from one side of the actuator 81 to the other.

In conventional braingear structures, the gears of the gears are generally serrated along the entire circumference, i.e., in a 360-degree angular range. In contrast, in the present game 10, this is not necessary because the gears 82 do not allow the gears 82 to rotate completely around their axis of rotation t. Therefore, preferably, only a portion of the circumference of the gears 83, 84 of the gear 82, preferably approx. A portion corresponding to an angle range of 250 degrees is provided with teeth, as will be explained in more detail later.

In a particularly preferred embodiment, the actuator 80 also includes four push rods 92, also shown in FIG. is arranged differently from

The side of the slide heads 94 facing the push rod 92 is tapered, preferably conically or pyramidally, so that the side of the push head 94 facing the push rod 92 gradually forces it to move away (tip over) prior to the push. stationary moving elements 81, as will be explained in more detail below.

Preferably, the movement means 81 in both the 94 pools oidaián conical heads ^va 9y gúíaszerű adapted in shape the notch 89, which preferably continues as the gear wheel 82 couples the opposite side of the arm 86 in Figure 5

-6 can be observed. The function of the notches 89 is to further assist the movement of the sliding heads 94 in the space enclosed by the moving elements 81.

In the first rest position of the play 10, the push rods 92 extend an equilateral first tetrahedron 100 so that the push rods 92 run along the weight lines 102 and the push heads 94 at one end of the push rods 92 define the vertices 104 of the tetrahedron 100, while the other the sliding heads 94 at their ends fall inside (or into) the tetrahedron 100. By the center of gravity 102 of the tetrahedron 100 is meant a line connecting the apex 104 of the tetrahedron 100 to the center of gravity of the opposite side of the tetrahedron 100. The center of gravity of the triangle 10 forming the side face is the point of intersection of the lines connecting the vertices of the triangle with the midpoint of the opposite sides. The centers of gravity 102 of the tetrahedron 100 also intersect at a point, the center of gravity S.

It is also possible to draw an equilateral tetrahedron 100 of various side lengths around the push rods 92, depending on the distance between the vertices 104 of the tetrahedron 100 from the center 15 of the pushheads 94 farther from the center of gravity S. This is irrelevant to the invention, the tetrahedron 100 being merely an auxiliary shape to help describe the two resting positions of the game 10. Hereinafter, an equilateral tetrahedron 100 defined by the slides 94 farther from the center of gravity S means a regular tetrahedron 20 with the smallest side length, the lines of gravity 102 of which are parallel to each of the slides 92, and the tips 104 of which touch the outer surface of the slides 94. Each of the vertices 104 of the tetrahedron 100 is denoted separately by the letters A, B, C, D.

The outer surface of the slider 94 may be formed as a marking surface 96, thereby further increasing the number of combinations provided by the spatial logic game 10. Markings 25 96 may be applied by any known technique, such as printing, painting, decals, coloring or machining the material of the markings 96 (e.g., embossing or forming openings, notches, etc.). The relief, engravings or other similar tactile markings on the markings 96 enable the blind and partially sighted to recognize and distinguish the markings.

In the first rest position of the actuating device 80, the arms 86 of the actuating elements 81 are in the same direction as the triple head 94 of one of the pushing rods 92 (Fig. 3). For each of the three moving 86 arms in one direction, one lake lake lake lake lake lake

By connecting the rails 40, they form the rail rings 48 shown in Fig. 6, and the carriages 60 can be rotated around these rail rings, as illustrated by the arrows in Fig. 1a. The directions of rotation are only examples, the carriages 60 can also be rotated in the opposite direction along the respective rail ring 48.

There are also a first marking surface 62a and a second marking surface 62b on either side of the carriages 60. The markings 62a, 62b, like the markings 96, may be marked by any known technique, such as printing, painting, decals, coloring or machining the material of the markings 62a, 62b (e.g., embossing or openings, notching, etc.).

design). In a particularly preferred embodiment, the carriages 60 consist of two halves 60a, 60b (Id. Figure 6) made of a material of a different color (e.g. plastic), in which case the marking on one of the halves 60a as the marking surface 62a is the color of the halves 60a itself. and similarly, on one surface of the half 60b as the marking surface 62b, the marking is the color of the half 60b itself, which is preferably different from the color of the half 60a. For the blind and partially sighted, the marking surfaces 62a and 62b may also include relief, engravings or other similar hand-tactile markings.

The rails 40 may also consist of several pieces, as can be seen in Figure 7. In this case, each rail 40 includes a rail frame 42 and a rail insert 20. In this embodiment, the lower and upper protruding edges 43 of the rail frame 42 guide the inwardly sloping lower and upper hook edges 64 of the carriages 60, as seen in Figure 6, from which the carriages 60 are partially removed for illustration. In Fig. 6, some rails 40 are specifically indicated by reference numerals 40a, 40b, 40c, which are the same rails as the others, with the different designations 25 being used to describe the two rest positions of the actuator 80, as will be described later.

The rail 40, in this case the rail insert 44, is preferably provided with nests 45 in which magnets 46 for positioning the carriages 60 are arranged. The placement of the magnets 46 is aided by the fact that the rail insert 44 consists of two halves 44a, 44b, which are fastened to each other, for example by a snap connection. Before the two halves 44a, 44b snap together, the magnets 46 can be conveniently inserted into the sockets 45 of one of the halves 44a, 44b, and the magnet 46 closes into the socket 45 by placing the other half 44b, 44a on top. To do this, the opening of the nest 45 and the opening of the nest 46

A yíío · '

The diameter of the magnets 8 is chosen so that the magnets 46 do not pass through the opening of the housing 45 after the two halves 44a, 44b of the rail insert 44 have been sealed. Of course, each rail 40 may be formed as a single element or from other types of pieces, in which case the magnets 46 (if any) may be positioned differently (e.g., may be glued to the outer surface of the rail 40). The multi-piece design shown in Figure 7 allows the magnets 46 to be placed in the rails 40 in a preferred manufacturing manner.

Preferably, the rails 40 also have sockets 45 and magnets 46 on their sides toward the adjacent rails 40 (Figures 6 and 7), thereby facilitating the formation of the rail rings 48 shown in Figure 10 so that the adjacent rails 40 Its 46 magnets are arranged with opposite (attractive) polarity. Thus, the north pole of the magnet 46 arranged in the socket 45 formed on the side of one of the rails 40 faces outward, while the south pole of the magnet 46 arranged in the socket 45 of the adjacent side 40 of the rail 40 faces outward, so that the two magnets 46 attract each other and help in one hold, which facilitates the sliding of the carriages 60 from one of the rails 40 to the adjacent rails 40. Alternatively, instead of two magnets 46, a magnet 46 and a magnetizable material may be used for positioning. By magnetizable material is meant a material that is inherently non-magnetic but becomes external 20 so that the magnet 46 can attract these materials. Examples are ferromagnets and paramagnets. In this case, the magnet 46 is placed in one of the rails 40 and the magnetizable material is placed in the other rail 40 to be positioned relative to it.

The positioning of the rails 40 and the stabilization of the rail ring 48 can also be achieved in another way, for example an embodiment in which cams or recesses are provided in the corresponding position for the snap-in connection on the side of the adjacent rails 40.

The carriages 60 are also provided with seats 65 corresponding to the seats 45 in the rail inserts 44, into which magnets 66 30 with a polarity opposite to those of the rail inserts 44 are similarly inserted. By this is meant that the magnets 46 and 66 are arranged to attract each other when the magnet 66 arranged in the seat 65 of the carriage 60 slidable along the rail 40 is arranged in a seat 46 of the rail insert 44.

It is close to the -9 "magnet, so for example, if the south pole of the magnet 46 faces the opening of the nest 45, the north pole of the magnet 66 faces the opening of the nest 65. Of course, an embodiment is also conceivable in which, instead of the two magnets 46, 66, a magnet 46 or 66 and a magnetizable material 5 are used for positioning. In this case, the magnet 46 or 66 is placed in one element and the magnetizable material is placed in the other element to be positioned relative to it.

The carriages 60 may also be one or more pieces, and there are a number of obvious options for those skilled in the art to secure the magnets 66, such as by gluing or by placing a ring that narrows the opening of the larger diameter nests 65 to hold the magnet 66.

In the present embodiment, one carriage 60 is arranged on each rail 40, more carriages can be arranged. The number of carriages 60 on a rail ring 48 is preferably three or a multiple thereof, more preferably three, six or nine carriages 60 on each rail ring 48.

It can be seen in Figure 6 that in the present case the rail insert 44 has three sockets 45 for receiving a magnet 46 facing the carriages 60. . In the first case, the magnet 46 is arranged in the middle socket 45, in the second case in the two outermost sockets, in the third case in all three sockets 45, and in the sockets 65 of each of the carriages 60 of the appropriate size.

Of course, an embodiment is conceivable in which the number of nests 45 in the rails 40 is adjusted to the number of carriages 60 on the rails 40, with each carriage 60 being positioned by one or more magnets 46 and 66, respectively.

Instead of magnets 46 and 66, respectively, a magnetizable material may be placed in one of the nests 45 and 65, respectively, as previously described.

The positioning of the carriages 60 can be solved in another way, for example an embodiment in which cams or recesses 30 are provided on the rails 40 and on the carriages 60 to ensure a snap-fit connection.

'• S

-10The 80 moving structure of the spatial logic 10 game can be moved between the first and second rest positions. Figures 1 and 6 show the first rest position. In this position, the triad of rails 40 form first rail rings 48 around the vertices 104 of the first tetrahedron 100, the central axis k of which coincides with the center of gravity 102 starting from a given apex 104 of the tetrahedron 100. The first marking surface 62a of the carriages 60 on the first rail rings 48 is located outwardly facing the center of gravity S of the tetrahedron 100, and the second marking surface 62b is located inwardly. The rails 40 forming the ring rings 48 are connected to each other so that the carriages 60 within a rail ring 48 can be slid over the adjacent rails 40 of the respective rail ring 48. The carriages 10 60 can thus be slid (rotated) along the respective rail rings 48, as illustrated by the arrows in FIG.

Within the rail ring 48, the adjacent rails 40 are substantially continuous in the sense that there is no gap, breakage, or other obstruction between them that would prevent the carriages 60 from slipping through. This is also aided by the side magnets 46 and, if appropriate, the magnetizable materials, which ensure the positioning and better fixing of the rails 40.

In the second rest position of the actuator 80, the spatial logic game takes the form shown in Figures 8 and 9, in which the sliding heads 94 of the push rods 92 define a second tetrahedron 200, at the apexes 204 of which 202 lines of gravity run from the center of gravity S. In Figs. For a better comparison of Figures 1 and 6 of the first rest position and Figures 8 and 9 of the second rest position 25, each of the vertices A, B, C, D, and 204 of the first and second tetrahedra 100, 200, respectively. It is marked E, F, G, H. Since the peaks 104, 204 are defined by the sliding heads 94, the lettering of the peaks 104, 204 is also shown in Figure 5, which illustrates the position of the sliding rods 92, with the sliding rods 92 corresponding to the first rest position.

The 104 vertices of 100 tetrahedra are defined. The lettering of the vertices 204 of the second tetrahedron 200 is indicated next to the sliding head 94 of the push rod 92 which defines this peak 204 at rest, so that

-11 it can be traced where the individual peaks 104, 204 (or the sliding heads 94 defining them) move.

The first 100 tetrahedra and the second 200 tetrahedra are centrally symmetric to each other. That is, the second tetrahedron 200 can be obtained by reflecting the vertices 104 of the first tetrahedron 100 at the center of gravity S. It also follows that the position of the center of gravity S of the two tetrahedra 100, 200 does not change, and the center of gravity S is approx. It divides the push rods 92 in a ratio of 2: 1, but in the first tetrahedron 100 the push head 94 of a push rod 92 is further away from the center of gravity S, and in the second tetrahedron 200 it is closer to the center of gravity S.

Második In the second rest position of the actuator 80, the triad of rails 40 form second rail rings 48 'around the vertices 204 of the second tetrahedron 200, with each rail 40 in the first tetrahedron position 100 from the first rail rings 48 adjacent to the two adjacent vertices 104 - a rail 40 forms a second rail ring 48 'around the apex 204 of the second tetrahedron 200. Thus, in Fig. 7, the rail ring 48 'around the apex 204 E is formed by the rails 40a, 40b, 40c of the rail ring 48 around the apexes 104B, C in Fig. 5.

The center axis k of the second rail rings 48 also coincides with the center of gravity 202 from the respective apex 204 of the second tetrahedron 200, since the push rods 92 move in their axial direction along their own axes and cannot rotate about their own axis.

On the second rail rings 48 ', the second marking surface 62b of the carriages 60 faces outward from the center of gravity of the second tetrahedron 200, while the first marking surface 62a faces inwardly, i.e., the rails 40 rotate with the carriages 60 while the actuator 80 moves from the first rest position to the second at rest, as will be explained in more detail below.

The rails 40 of the second rail rings 48 'are also connected to each other so that the carriages 60 within the respective rail ring 48' can be slid over the adjacent rails 40.

It is noted that the rails 40 may be comprised of a plurality of separate rail pieces, however, in the context of the invention, all rail pieces that could rotate around two given 104 and 204 in the first and second rest positions of the actuator 80, e.g. 11 - 12.

W:

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In Figs. The same is true for a given moving element (consisting of one or more pieces) of 40 sints, so that the moving element can consist of several pieces of 5 separate moving elements. It is also important to distinguish the moving elements between the two vertices 104, 204 which move the rails 40 (consisting of one or more pieces).

Hereinafter, the actuator 80 will move each of the elements 10 from their first rest position to their second rest position.

The mechanism of operation of the actuator 80 is illustrated in Figures 10-12, with Figure 10 for the first rest position of the actuator 80 and Figure 11 for the second rest position showing the same rail 40 and carriage 60 thereon. In Fig. 10, in the first rest position, the free ends 87 of the moving elements 81 face the vertices 104 A, B, C, D of the first tetrahedron 100. In this case, the first marking surface 62a of the carriage 60 faces outwardly, while the second marking surface 62b faces inwardly and is only minimally visible after all the carriages 60 have been placed, as can be seen in FIG. By tilting any of the actuators 81 in the direction of the two actuators 81 in drive toward the two adjacent peaks 104, all of the actuators 81 move in motion through the gears 83, 84 of the gears 82 and coincide with the axis of rotation t of the gears 82. 72 with the edge 74 of the frame 72) turn toward the drive elements 81 originally facing the two adjacent peaks 104, thereby forming the peaks 204 E, F, G, and H of the second tetrahedron 200. The actuating elements 81 in the direction of the apex 104, in the drive relationship 81 e, 81 h and 81 g, rotate in the direction of the apexes 204 E, H and G of the second tetrahedron 200.

In the second rest position shown in FIG

204 are placed in a position facing the peaks. Meanwhile, the rails 40 and the carriages 60 connected to the free ends 87 of the actuating elements 81 also turn over, in this embodiment they turn 180 degrees relative to the arms 86 in one of the

-13 from the end position to the other end position. Note that the rotation of the rails 40 and the carriages 60 relative to themselves is 109 ° 28 '16 (109 degrees, 28 angular minutes and 16 angular seconds), which is equal to the larger (obtuse) angle formed by the centers of gravity 102 of the tetrahedra 100 and 200, respectively. Meanwhile, the angle of rotation of the arms 86 is 70 ° 31 '5 44, which in turn corresponds to a smaller (pointed) angle formed by the weight lines 102. As the arms 86 rotate, the gears 83, 84 of the gears 82 may contact the gears 83, 84 of the adjacent gears 82 in an angular range of up to 250 ° 31 '44. It is provided with teeth within an angular range of 250 °, while facing in the direction of the 86 arms is approx. In the angular range of 110 ° 10 (more precisely 109 ° 28 '16), no teeth need to be formed, since this section does not participate in the transmission of the rotating motion.

The actuating mechanism is shown in Figures 10 and 11 through the movement of a rail 40 and a carriage 60 connected to the actuating element 81g 81g. As the free end 87 of the moving member 81 approaches the free end 87 of the adjacent moving members 81, the carriages 60 connected thereto meet at a certain point and exert a force on each other which tilts the rails 40 and with it the carriages 60 through the carriage. 87 to the other side of the free ends. Thus, in the second rest position, the second marking surface 62b of the carriages 60 already faces outwards, i.e. the user is seen primarily by the marking surfaces 62b, as opposed to the first rest position 20, where the user has primarily sensed the first marking surface 62a.

In this embodiment, for the user to move the toy 10 from the first rest position 62a to the first rest position of the actuator 80 to the second rest position 62b to the rest position, it is sufficient to depress the surrounding 81 However, it is advisable to push more than one push rod 92 at a time, as this will cause the gear 82 of the tilting actuators 81 to rotate and the braingear structure to rotate all the other 82 gears in a direction such that each of the actuators 81 tilts in the direction of the actuator 81 adjacent to it but facing another apex 104. For example, in Fig. 11, by pressing the sliders 94 (possibly more or less 94) located at the vertices A and B, the game 10 is the first resting W te w

-14 can be transferred from position to the second rest position. The notches 89 formed along the length of the actuating elements 81 help the sliding heads 94, which are preferably conical in shape, to move in the space enclosed by the actuating elements 81, so that the tilting of the actuating elements 81 is gradual and cannot jam.

The movement of the actuating elements 81 lasts until they are tilted into the position corresponding to the second rest position around the sliding heads 94 defining the vertices 204 of the second tetrahedron 200. Meanwhile, the 60 carriages approaching each other sit on top of each other and turn over as a result of the force. Thus, in the second rest position, their second marking surface 62b already faces outwards.

The toy 10 can be transferred from one rest position to the other at rest in the absence of push rods 92, for example by reaching under the carriages 60 along two rail rings 48 and turning the carriages 60 by pulling the two rail rings 48 apart. However, it has been found that the splitting of the rail rings 48 and the carriage 60, despite the simple mechanism, require significantly more dexterity than in the prior art. .

It is noted that in the absence of push rods 92, the tips of the first tetrahedron 104 and the apexes 204 of the second tetrahedron 20 are defined by the ring rings 48 and 48 ', respectively.

This embodiment of the spatial logic 10 game is used as follows.

In the first rest position of the actuator 80, the position of the support structure 70 relative to the actuator 80 and the rails 40 is always the same, and in the second rest position of the actuator 80 the relative positions of these elements are always the same (but of course different from the first rest position). relative position). The position of the carriages 60, on the other hand, can be varied within each rest position, as the carriages 60 can be rotated along each of the rail rings 48 as shown in Figure 1a (and similarly along the bushings 48 'in the second rest position of the actuator 80). Depending on the differences between the markings used on the markers 62a and 62b, the number of states of the spatial logic game 10 is known to the user.

In a particularly preferred embodiment, the toy 10 has a first state in which the actuator 80 is in a first rest position and a first outwardly facing first carriage 60 is formed along each ring 48 formed around each apex 104 of the first tetrahedron 100. The marking surfaces 5a 5a have the same marking, which, however, differs from the first marking surfaces 62a of the carriages 60 of the other 48 car rings! from the markings carried. Similarly, the play 10 has a second (inverted) state in which the actuator 80 is in the second rest position and the outwardly facing second marking surfaces 62b of the carriages 60 located along each of the rail rings 48 'formed around each apex 204 of the second tetrahedron 200. they contain the same marking, but different from the markings carried by the second marking surfaces 62b of the carriages 60 of the other 48-ring rings. That is, a quarter of the first signaling surfaces 62a have the same designation and a quarter of the second signaling surfaces 62b have the same designation.

In a preferred embodiment, the carriages 60 comprise two halves 60a, 60b which are colored in their material, so that the marking is the color of the halves 60a, 60b itself. The halves 60a carrying the first marking surfaces 62a are of four different colors, with a quarter of the halves 60a being the same color. The halves 60b carrying the second marking surfaces 62b are of a further four colors and also a quarter of the same color. So, for example, if a carriage 60 can be placed on a rail 40, there are a total of 12 carriages 60, and thus there are 12 halves 60a and 60b, respectively. 3-3-3-3 of the halves 60a are the same color and 3-3-3-3 pieces of the same color. Of course, in terms of play, this is a completely equivalent game 10, in which all 60 cars are one-piece, with the first markers 62a containing 3-3-3-3 identical stickers, paintings, 25 embossments or other markings, while the second markers 62b also have 3-3 There are 3-3-3 different but identical stickers, paintings, embossing or other markings,

The number of variations in the game 10 can be increased by placing more than 60 carriages on the rails 40 (e.g., two carriages 60 on each of the 40 rails, so that the toy 10 contains a total of 24 carriages, or, for example, three carriages on each of the 40 rails, thus, the 10 games contain a total of 36 cars). Another option is to increase the variety of markings, for example, for 24 60 carriages, each 6-6-6-6 marking of the same color can contain a 1 to 6

- a falling number, so that not only can the marking surfaces 62a and 62b containing the markings of the same color be placed on a rail ring 48 or 48 *, but the user can also try to arrange the numbers, for example in the unloaded state on one of the rails 48 The marking surface 62a of the carriages is marked in red with 5 colors, and the numbers 1 to 6 follow each other in an ascending order along the respective rail ring 48.

Different types of markings may be provided on the heads 94, such as the same markings for the metal-type markers 62a, 62b, so that it may be a further challenge to have the same markings 62a and 62b on the rail ring 48 and 48 'formed around the same markers 94, respectively. brought together.

Of course, the number of variations in the game 10 can be reduced, for example, by reducing the variety of markings used (e.g., the markers 62a and 62b contain only 2-2 different markings 15), making the game 10 enjoyable by children and beginners.

Additional variation options are readily conceivable by one skilled in the art.

It is to be understood that alternatives to other embodiments described herein will be contemplated by those skilled in the art but are within the scope of the appended claims.

Claims (12)

Patent claims A spatial logic game comprising a support structure (70), an actuator (80) attached to the support structure (70), and toy elements connected to the actuator (80), characterized in that the support structure (70) is an octahedral frame (72). and the actuator (80) has actuators (81) for rotating gears (82) and arms connected to the gears (82) along the edges (74) connecting the ends (73) of the octahedral frame (72). 10, the gears (82) arranged along the adjacent edges (74) are in drive communication with each other, a rail (40) is connected to the free end (87) of the arms (86), and the play elements are slidably mounted on the rails (40), carriages (60) having first and second marking surfaces (62a, 62b), the actuating mechanism (80) can be moved between the first and second rest positions 15 by rotating the gears (82), the arms (86) being free in the first rest position with a triple of gei (87) facing the vertices (104) of a first tetrahedron (100) and with a triple of rails (40) connected to the free ends (87) forming first rings (48) around the vertices (104) of the first tetrahedron (100) on which the first marking surface (62a) of the carriages (60) is located outwardly facing the center of gravity (S) of the tetrahedron, the second marking surface (62b) of the carriages 20 is located inwardly facing the center of gravity (S), and the first rail rings (48) are designed to allow sliding; in the second rest position of the actuator (80), the free ends (87) of the arms (86) face the vertices 25 (204) of the second tetrahedron (200) symmetrically symmetrically to the center of gravity (S) of the first tetrahedron (100) and to the free ends ( ^{87) form a second ring (48!} ) Around the vertices (204) of the second tetrahedron (200) so that each rail (40) is positioned around the two adjacent vertices (104) in its position in the first tetrahedron (100). , with a rail (40) closest to it, forms a second annular ring (48 ') around a vertex (204) of the second tetrahedron (200), on which the second marking surface (62b) of the carriages (60) is located inwardly facing and the second rail rings (48 *) are adapted to allow the carriages (60) to slide over the adjacent rails (40). The spatial logic game of claim 1, further comprising four push rods (92) having a push head (94) at each end, the push rods (92) each having two opposite sides of the octahedral frame (72). is arranged intersectingly with respect to the other push rods (92), and in the first rest position of the actuator (80) with the free ends (87) of the arms (86) of the actuator (81) with a triple of one of the pusher heads (94) and in the second rest position of the actuator (80) are located in the vicinity of the second pusher head (94) of the push rods (92), and the push rods (92) - from the center of gravity (S) of the first and second tetrahedra (100, 200), respectively. pushing their distal sliding head (94) towards the center of gravity (S) - the arms (86) of the actuating elements (81) are designed to rotate from one rest position to another rest position, thereby rotating the gears (82). Spatial logic game according to Claim 2, characterized in that the side of the sliding heads (94) facing the pushing rod (92) is tapered, preferably pictorially or pyramidally, towards the pushing rod (92). The spatial logic game according to claim 3, characterized in that the arms of the actuating elements have a longitudinal notch (89) in the shape of the sides of the pusher heads (94) facing the pushrod (92). Spatial logic game according to any one of claims 1 to 4, characterized in that the gears (82) form a braingear structure. Spatial logic game according to any one of claims 1 to 5, characterized in that the circumference of the gears (83, 84) of the gear (82) is provided with teeth within an angular range of substantially 250 degrees. Spatial logic game according to one of Claims 1 to 6, characterized in that at least two carriages (60) are arranged on each rail (40). A spatial logic game according to any one of claims 1 to 7 5 characterized in that the first and second marking surfaces (62a, 62b) of each carriage (60) carry different markings, and in the unloaded first and second rest positions of the logic game (10), the carriages (60) on each ring (48, 48 ') extend outward. the markings of the facing markers (62a, 62b) are the same, but different from the outward facing markings (62a, 62b) of the carriages (60) on other rail rings (48, 48 *). Spatial logic game according to one of Claims 1 to 8, characterized in that the rails (40) and the carriages (60) are carriages. (60) are arranged with magnets (46, 66) of opposite polarity and or magnets (46, 66) and magnetizable materials are provided. Spatial logic game according to any one of claims 1 to 9, characterized in that on the side of the rails (40) there are magnets (46) for positioning the rails (40) inside the rail ring (48, 48 ') of the adjacent rails (40). 20 are arranged with opposite polarity to the magnets (46) and / or magnets (46) and magnetizable materials are arranged Spatial logic game according to any one of claims 1 to 8, characterized in that on the rails (40) and on the carriages (60) for positioning the carriages (60) relative to the rails (40) and on the rails (40) on the rail ring (48) , 48 '), the snap-in cams and the recesses are arranged in a suitable position. A spatial logic game according to any one of claims 1 to 11, characterized in that the marking surface of the carriages (60)! (62a, 62b) embossing, notching or other tactile marking.