阅读说明：本技术 三维逻辑游戏 (Three-dimensional logic game ) 是由 J.绍博尔奇 于 2019-07-22 设计创作，主要内容包括：本发明涉及一种三维逻辑游戏,该三维逻辑游戏包括支撑结构(20、70)、附接至支撑结构(20、70)的致动结构(30、80)、以及附接至致动结构(30、80)的游戏元件,其特征在于,所述游戏元件形成为具有第一和第二标记表面(62a、62b)的滑架(60),并且可滑动地安装在附接至致动结构(30、80)的轨道(40)上；致动结构(30、80)可在第一静止位置和第二静止位置之间移动,在第一静止位置,由三个轨道(40)组成的第一组轨道形成围绕第一四面体(100)的顶点(104)的第一轨道环(48),其中滑架(60)的第一标记表面(62a)在远离第一四面体(100)的几何中心(S)的方向上面向外,而第二标记表面(62b)面向内,并且第一环的轨道(48)允许滑架(60)在相邻轨道(40)上滑动；在致动结构(30、80)的第二静止位置,由三个轨道(40)组成的第二组轨道形成围绕第二四面体(200)的顶点(204)的第二轨道环(48’),第二四面体(200)的顶点(204)是第一四面体(100)在其几何中心(S)上方反射的点反射图形,其中在第一静止位置,每个轨道(40)与围绕第一四面体(100)的相邻顶点(104)最靠近它的两个轨道(40)一起形成围绕第二四面体(200)的一个顶点(204)的第二轨道环(48’)之一,并且在第二轨道环(48’)上,滑架(60)的第二标记表面(62b)在远离第二四面体(200)的几何中心(S)的方向上面向外,同时第一标记表面(62a)面向内,并且第二环的轨道(48’)允许滑架(60)在相邻轨道(40)上滑动；支撑结构(20)包括沿着第一和第二四面体(100、200)的中线(102、202)布置的具有相对于彼此偏斜的轴线的推动杆(22),并且致动结构(30)包括双臂致动元件(32),双臂致动元件(32)的臂(34)分别附接至推动杆(22)之一。(The invention relates to a three-dimensional logic game comprising a support structure (20, 70), an actuation structure (30, 80) attached to the support structure (20, 70), and a game element attached to the actuation structure (30, 80), characterized in that the game element is formed as a carriage (60) having a first and a second marking surface (62a, 62b) and is slidably mounted on a track (40) attached to the actuation structure (30, 80); the actuation structure (30, 80) is movable between a first rest position, in which a first group of rails consisting of three rails (40) forms a first rail ring (48) around the vertices (104) of the first tetrahedron (100), wherein the first marking surface (62a) of the carriage (60) faces outwards in a direction away from the geometric centre (S) of the first tetrahedron (100) and the second marking surface (62b) faces inwards, and the rails (48) of the first ring allow the carriage (60) to slide on the adjacent rails (40); in a second rest position of the actuation structure (30, 80), a second group of tracks consisting of three tracks (40) forms a second ring of tracks (48 ') around the vertices (204) of the second tetrahedron (200), the vertices (204) of the second tetrahedron (200) being a point reflection pattern of the reflection of the first tetrahedron (100) above its geometric center (S), wherein in the first rest position each track (40) forms, together with the two tracks (40) around the adjacent vertex (104) of the first tetrahedron (100) closest thereto, one of the second rings of tracks (48 ') around one vertex (204) of the second tetrahedron (200), and on the second ring of tracks (48 '), the second marking surface (62b) of the carriage (60) faces outwards in a direction away from the geometric center (S) of the second tetrahedron (200) while the first marking surface (62a) faces inwards, and the track (48') of the second loop allows the carriage (60) to slide on the adjacent track (40); the support structure (20) comprises pusher bars (22) arranged along the midline (102, 202) of the first and second tetrahedrons (100, 200) having axes that are skewed with respect to each other, and the actuation structure (30) comprises a two-arm actuation element (32), the arms (34) of the two-arm actuation element (32) being attached to one of the pusher bars (22), respectively.)

1. A three-dimensional logical game comprising a support structure (20, 70), an actuation structure (30, 80) attached to the support structure (20, 70), and a game element attached to the actuation structure (30, 80), characterized in that the game element is formed as a carriage (60) having first and second marking surfaces (62a, 62b) and is slidably mounted on a track (40) attached to the actuation structure (30, 80); the actuation structure (30, 80) is movable between a first rest position, in which a first group of rails consisting of three rails (40) forms a first rail ring (48) around the vertices (104) of a first tetrahedron (100), wherein the first marking surface (62a) of the carriage (60) faces outwards in a direction away from the geometric centre (S) of the first tetrahedron (100) and the second marking surface (62b) faces inwards, and the rails (48) of the first ring allow the carriage (60) to slide onto the adjacent rails (40); in a second rest position of the actuation structure (30, 80), a second group of tracks consisting of three tracks (40) forms a second ring of tracks (48 ') around the vertices (204) of the second tetrahedron (200), the vertices (204) of the second tetrahedron (200) being a point reflection pattern of the reflection of the first tetrahedron (100) above its geometric center (S), wherein in the first rest position each track (40) forms, together with the two tracks (40) around the adjacent vertex (104) of the first tetrahedron (100) closest thereto, one of the second rings of tracks (48 ') around one vertex (204) of the second tetrahedron (200), and on the second ring of tracks (48 '), the second marking surface (62b) of the carriage (60) faces outwards in a direction away from the geometric center (S) of the second tetrahedron (200) while the first marking surface (62a) faces inwards, and the track (48') of the second loop allows the carriage (60) to slide onto the adjacent track (40); the support structure (20) comprises pusher bars (22) arranged along the midline (102, 202) of the first and second tetrahedrons (100, 200) having axes that are skewed with respect to each other, and the actuation structure (30) comprises a two-arm actuation element (32), the arms (34) of the two-arm actuation element (32) being attached to one of the pusher bars (22), respectively.

2. Three-dimensional logic game according to claim 1, characterized in that each pusher arm (22) is provided at its two ends with a pusher head (24), respectively, the two arms (34) of the actuating element (32) being joined together at one of their ends by a coupling element (36) connected to one of the rails (40), and their free ends (38) being connected to a pair of adjacent pusher arms (22) in the vicinity of one of the pusher heads (24) that are close to each other.

3. Three-dimensional logic game according to claim 2, characterized in that said pusher bar (22) and said actuation element (32) are dimensioned:

in a first rest position of the actuation structure (30), a first pusher head (24) of a first pusher rod (22) among two adjacent pusher rods (22) connected to the arm (34) of a given actuation element (32) is located at one of the vertices (104) of the first tetrahedron (100), the track (40) of the linking element (36) connected to the given actuation element (32) constitutes one track (40) of a first track ring (48) formed around this vertex (104), and a second pusher head (24) of a second pusher rod (22) among the two adjacent pusher rods (22) connected to the arm (34) of the given actuation element (32) that is located closer to the given actuation element (32) is located closer to the geometric center (S) of the first tetrahedron (100) than the first pusher head (24), preferably such that the second pusher head (24) is located within the first tetrahedron (100), and is

In the second rest position of the actuating structure (30), the second pusher head (24) is located at one of the vertices (204) of the second tetrahedron (200), while the trajectory (40) of the linking element (36) connected to a given actuating element (32) constitutes one trajectory (40) of a second loop of trajectories (48') formed around this vertex (204) of the second tetrahedron (200), and the first pusher head (24) is closer to the geometric center (S) of the second tetrahedron (200) than the second pusher head (24), preferably so that the first pusher head (24) is located within the second tetrahedron (200).

4. Three-dimensional logical game according to claim 2 or 3, characterised in that the two arms (34) of the actuation element (32) are made of an elastic material, allowing bending by elastic deformation with respect to the coupling elements (36) that couple them together.

5. Three-dimensional logical game according to claim 2 or 3, characterized in that the coupling elements (36) of the actuation elements (32) respectively comprise joints allowing the two arms (34) coupled together to rotate with respect to each other.

6. Three-dimensional logical game according to one of the claims 1 to 5, characterized in that at least two carriages (60) are arranged on each track (40).

7. A three-dimensional logical game according to any one of claims 1 to 6, wherein the first and second marker surfaces (62a, 62b) of each carriage (60) carry first and second markers, respectively, that are different from each other, and the logical game has a first solution state in which the first markers on the outwardly facing marker surfaces (62a) of the carriages (60) on any given first orbital ring (48) are the same as each other and different from the first markers on the outwardly facing marker surfaces (62a) of the carriages (60) on any other orbital ring (48), and a second solution state in which the second markers on the outwardly facing marker surfaces (62b) of the carriages (60) on any given second orbital ring (48 ') are the same as each other and different from the second markers on the outwardly facing marker surfaces (62b) of the carriages (60) on any other second orbital ring (48') The notation is different.

8. Three-dimensional logical game according to one of claims 1 to 8, characterized in that pairs of magnets (46, 66) and/or magnets (46, 66) and magnetizable elements with opposite polarities are arranged on the track (40) and carriage (60), respectively, for positioning the carriage (60).

9. Three-dimensional logical game according to one of claims 1 to 9, characterized in that a side magnet (46) is arranged on one side of a track (40), the polarity of which is opposite to the polarity of the other side magnet (46) of the adjacent track (40), or a side magnet (46, 66) and a magnetizable element are arranged on the adjacent side of a track (40) for positioning a track (40) within a track ring (48, 48').

10. Three-dimensional logical game according to one of claims 1 to 8, characterized in that protrusions and recesses are formed at corresponding positions on the track (40) and carriage (60), which together form a snap connection for positioning the carriage (60) relative to the track (40) and the track (40) within the track ring (48, 48').

11. A three-dimensional logic game according to any of claims 1 to 11, wherein the marking surfaces (62a, 62b) of the carriages contain embossed, debossed or other tactile markings.

Technical Field

The present invention relates to a three-dimensional logical game comprising a support structure, an actuation structure attached to the support structure, and a game element attached to the actuation structure.

Background

Three-dimensional logic games are popular today. The most well-known game among such games is the magic cube, which has acquired patent No. 170062 in hungary. The six faces of the cube are made up of faces of small cubes with different markings on each visible face. The cubes can be rotated relative to each other so that the conforming marks on one face of the cube can be mixed with the different marks on the other face, and the cube can be restored by rearranging the conforming marks. Such three-dimensional logic puzzle games help to enhance geometric perception and combinatorial skills. There is a need for a three-dimensional logical game that has similar concepts but allows for different spatial movements.

Disclosure of Invention

It is an object of the present invention to provide a new three-dimensional logic game that is different from the three-dimensional logic games of the prior art.

The above object is achieved by a three-dimensional logical game according to claim 1.

A particularly advantageous embodiment of the three-dimensional logical game is defined in claim 2.

Further advantageous embodiments of the invention are defined in the appended dependent claims.

Drawings

Further details of the invention will become apparent from a reading of the attached drawings and exemplary embodiments, wherein:

FIG. 1 is a perspective view of a first embodiment of a three-dimensional logical game of the present invention in its first rest position.

FIG. 2 is a perspective view of the support structure of the three-dimensional logical game of FIG. 1 in its first rest position.

FIG. 3 is a perspective view of the support structure and interconnected actuating structures of the three-dimensional logical game of FIG. 1 in a first rest position.

FIG. 4 is a view of the three-dimensional logical game of FIG. 1 cut in two halves.

FIG. 5 is a perspective view of the three-dimensional logical game of FIG. 1 with the carriage partially removed in a first rest position.

FIG. 6 is an exploded perspective view of one track and two carriages disposed thereon of the three-dimensional logical game of FIG. 1.

FIG. 7 is a perspective view of the three-dimensional logical game of FIG. 1 in its second rest position.

FIG. 8 is a perspective view of the support structure and interconnected actuating structures of the three-dimensional logical game of FIG. 1 in a second rest position.

FIG. 9 is a perspective view of two pusher rods of the support structure of the three-dimensional logic game of FIG. 1 and a dual-arm actuation element engaging the actuation structure of the two pusher rods in a first resting position.

FIG. 10 is a perspective view of the two pusher rods and the coupled double arm actuation member of FIG. 9 in a second rest position.

Figure 11 is a perspective view showing the position of the track and the carriage arranged thereon relative to the dual-arm actuation element of figure 9 in a first rest position.

Figure 12 is a perspective view showing the position of the track and the carriage arranged thereon relative to the dual-arm actuation element of figure 10 in a second rest position.

Detailed Description

The perspective views depicted in fig. 1-5 illustrate a first embodiment of a three-dimensional logic game 10 of the present invention in a first resting position of game 10.

Three-dimensional logical game 10 includes a support structure 20 (fig. 2), and an actuation structure 30 (fig. 3) coupled to support structure 20. The arcuate track 40 is attached to the actuation structure 30, and the carriage 60 is slidably mounted on the track 40 (fig. 4 and 5).

According to this embodiment, the support structure 20 comprises push rods 22 having axes that are skewed with respect to each other. Each push rod 22 is provided with a push head 24 at each of both ends thereof. The push rods 22 span the regular tetrahedron 100 such that the push rods 22 lie along the midline 102 of the tetrahedron 100, and the push head 24 at one end of each push rod 22 defines the vertex 104 of the tetrahedron 100, while the push head 24 at the other end of each push rod 22 is located inside the tetrahedron 100 (or at a position closer to the inside of the tetrahedron 100). The midline 102 of the tetrahedron 100 is the line connecting one vertex 104 of the tetrahedron and the geometric center of the opposing face of the tetrahedron 100. The geometric center of the triangle that constitutes the face of the tetrahedron 100 is the intersection of three lines connecting the three vertices of the triangle and the center of the opposing face. The midline 102 of the tetrahedron 100 also intersects a point, which is the geometric center S of the tetrahedron 100.

Tetrahedrons 100 of different side lengths can be drawn around the push rod 22, depending on the distance of the apex 104 of the tetrahedron 100 from the push head 24, which is further from the geometric center S. This is not important from the point of view of the present invention, and tetrahedron 100 is simply one auxiliary object that helps to illustrate the two rest positions of game 10. In the following disclosure, the tetrahedron 100 defined by the pushing heads 24 remote from the geometric center S is understood to be the smallest regular tetrahedron, wherein the lines 102 are each parallel to one of the pushing rods 22 and the vertices 104 thereof are in contact with the outer surface of the pushing head 24. The individual vertices 104 of the tetrahedron 100 are designated by the letters A, B, C, D.

According to this embodiment, each pusher head 24 comprises at least two portions: a body 26 formed integrally with the respective push rod 22, and a cap 27 permanently attached to the body 26 (e.g., by adhesive) or detachably attached to the body 26 (e.g., by a snap-fit connection). The outer surface of pusher head 24 may be formed as a marker surface 28 for increasing the number of combinations achievable by three-dimensional logic game 10. The marking surface 28 may be provided with markings in any known manner, for example by printing, by painting, by using stickers, by coloring the material of the marking surface 28, or by modifying the surface structure (for example with a relief or by forming recesses therein). Embossed marks, debossed marks, or other similar tactile marks allow blind or visually impaired individuals to identify and distinguish the marks. According to a particularly preferred embodiment, the pusher head 24 comprises a cap 27 made of a coloured material, whereby the marking on the marking surface 28 may be the colour of the material.

According to this embodiment, the actuating structure 30 comprises a two-arm actuating element 32, the arms 34 of which 32 are connected to each other at one end thereof by a coupling element 36, while the other ends (free ends 38) thereof are connected to a pair of adjacent pusher rods 22, the pair of pusher rods 22 being located in the vicinity of the pusher heads 24 that are closer to each other (see fig. 3). "near the pusher head 24" is to be understood as meaning the third of the pusher rod 22 closest to a given pusher head 24, including the possibility of the free end 38 being connected to the pusher rod 22 by means of the pusher head 24, as shown for example in fig. 4, in which the free end 38 is inserted into a recess 29 formed between the body 26 and the cap 27 of the pusher head 24.

Fig. 4 also shows that a track 40 is connected to each coupling element 36 of the actuating element 32, thereby maintaining the track 40 in a fixed position relative to the coupling elements 36. For example, a groove may be formed within the track 40, and the coupling element 36 may be snapped into the groove. It will be appreciated that the connection may be secured by other types of releasable or non-releasable connections (e.g. gluing), and further, the track 40 and the coupling element 36 may be integrally formed, optionally together with the entire actuating element 32.

According to this embodiment, the two arms 34 of each actuating element 32 are formed of an elastic material so as to be able to bend by elastic deformation with respect to the coupling element 36 that couples them, whereby the two free ends 38 of the two arms 34 can move towards and away from each other, which allows the two push rods 22 connected by a given actuating element 32 to slide with respect to each other, as will be explained in greater detail below.

The movement of the push rods 22 relative to each other can also be achieved in other ways, for example, the two-arm actuating element 32 can have rigid arms 34 connected by a coupling element 36 formed as a hinge or comprising a hinge, so that the two arms 34 can be rotated relative to each other, and the angle formed by the two arms 34 can be varied respectively, which allows pushing the interconnected push rods 22 along the axis of the push rods 22.

The carriage 60 is provided with a first mark surface 62a and a second mark surface 62b on both sides thereof. The marking surfaces 62a, 62b may be provided with markings in any known manner, for example by printing, by painting, by using stickers, by coloring the material of the marking surfaces 62a, 62b, or by modifying the surface structure (for example with a relief or by forming grooves therein). According to a particularly preferred embodiment, the carriage 60 is composed of two halves 60a, 60b (see fig. 6) made of a material of different color (e.g. plastic), in which case the marking on the side of the first half 60a serving as the marking surface 62a is the color of the first half 60a and, similarly, the marking on the side of the second half 60b serving as the marking surface 62b is the color of the second half 60b, which is preferably different from the color of the first half 60 a. The marking surfaces 62a, 62b may include embossed marks, recessed marks, or other similar marks that are tactile for the blind or visually impaired.

The guide rail may also consist of more than one member. In this case, each track 40 comprises a track frame 42 and a track core 44. According to this embodiment, the upper and lower flanges 43, 43 of the track frame 42 serve to guide the inwardly inclined upper and lower hook edges 64, respectively, of the carriage 60, as shown in fig. 5, with a portion of the carriage 60 removed to make the connection visible. A portion of the tracks 40 in fig. 5 are indicated with individual reference numerals 40a, 40b, 40c, these tracks 40 being not different from the other tracks 40, the different reference numerals being introduced to better illustrate the two rest positions of the actuating structure 30, as will be discussed below in connection with fig. 7.

A recess 45 is preferably formed in the track 40 (in this case in the track core 44) in which a magnet 46 for positioning the carriage 60 is arranged. The arrangement of the magnets 46 may be achieved by forming the track core member 44 from two halves 44a, 44b, which halves 44a, 44b may be attached to each other, for example by means of a snap connection. It is easy to place the magnet 46 in the recess 45 formed in one of the halves 44a, 44b before the halves 44a, 44b are snapped together, and then place the other half of the halves 44b, 44a over the magnet 46 so that the magnet 46 is trapped in the recess 45. To accomplish this, the size of the opening of the dimple 45 and the diameter of the magnet 46 may be selected so that the magnet 46 cannot pass through the opening of the dimple 45 once the two halves 44a, 44b of the rail core piece 44 are joined together. It is also contemplated to form each of the tracks 40 as a single element or to form them as different types of components, in which case the magnets 46 (if any) are otherwise arranged (e.g., using an adhesive to secure the magnets 46 to the outer surface of the tracks 40). From a manufacturing perspective, the multi-part design shown in fig. 6 provides an advantageous way of arranging the magnets 46 within the track 40.

Preferably, the track 40 is also provided with a recess 45 and magnets 46 (see fig. 5 and 6) on its side facing the adjacent track 40 to facilitate formation of the track ring 48 shown in fig. 5 by arranging the magnets 46 of the adjacent track 40 to be of opposite polarity (e.g., to attract one another). Thus, the north pole of the magnet 46 disposed within the recess 45 formed in the side of one rail 40 faces outward, while the south pole of the magnet 46 disposed within the recess 45 formed in the side of the adjacent rail 40 faces outward, whereby the two magnets attract each other and help hold the rail ring 48 together, which helps the carriage 60 slide from one rail 40 to the adjacent rail 40. Another possibility is to use a magnet 46 and a magnetizable material instead of two magnets 46 for positioning purposes. A magnetizable material is understood to be a material which is initially non-magnetic but becomes magnetic under the influence of an external magnetic field, whereby the magnet 46 can attract this material. Ferromagnetic and paramagnetic substances are such magnetizable materials, for example. In this case one rail 40 is provided with a magnet 46 and the other rail 40, which is positioned relative to the previous rail, is provided with magnetizable material.

The positioning of the rails 40 and the stabilization of the rail rings 48 can also be achieved in other ways, for example, embodiments are conceivable in which the sides of adjacent rails are provided with projections and recesses which together form a snap connection.

The carriage 60 is also provided with a dimple 65 at a position corresponding to the position of the dimple 45 formed in the track core member 44, in which a magnet 66 is arranged in a similar manner, and the magnet 66 has an opposite polarity to the magnet 46 of the track core member 44. This is understood to mean that the magnets 46 and 66 are arranged to attract each other when the carriage 60, which is displaceable along the track 40, reaches a position where the magnet 66 arranged in the recess 65 of the carriage 60 approaches the magnet 46 arranged in one of the recesses 45 of the track core member 44, e.g. if the south pole of the magnet 46 faces the opening of the recess 45, the north pole of the magnet 66 faces the opening of the recess 65. It is also contemplated that magnets 46 or 66 and magnetizable material may be provided in place of the two magnets 46 and 66 for positioning purposes. In this case one of the elements is provided with a magnet 46 or 66 and the other element, which is positioned relative to the preceding element, is provided with a magnetizable material.

The carriage 60 can also be made of one or more parts and the person skilled in the art has a number of ways to fix the magnet 66, for example by gluing or by providing an opening with a recess 65 of larger diameter and narrowing the opening with a ring and holding the magnet 66 inside.

According to this embodiment, two carriages 60 are provided per track 40, but more or fewer carriages 60 may be provided. It is preferred that the number of carriages 60 on orbital ring 48 be a multiple of three or three, and it is particularly preferred that three, six or nine carriages 60 be provided on each orbital ring 48.

As can be seen from fig. 5, the track core member 44 in this case comprises three recesses 45 for receiving the magnets 46, the three recesses 45 facing the carriage 60. When the two carriages 60 are fully seated on the track 40, the two side pockets 45 respectively face one of the pockets 65 of the two carriages 60. The central recess 45 of the track core member 44 may be empty or a third magnet 46 may be placed therein such that its polarity is opposite to the polarity of the other two magnets 46, i.e. its polarity is the same as the polarity of the magnets 66 arranged within the carriage 60. The middle magnet 46 helps to move the carriages 60 to either side of the track 40 and prevents them from stopping in a position where one carriage 60 is in the middle of the track 40 and the other carriage 60 extends therefrom onto the adjacent track 40, where the game 10 cannot pass from one rest position to the other, as will become apparent from the description below.

Another embodiment is contemplated in which the number of pockets 45 formed on each track 40 corresponds to the number of carriages 60 that may be disposed on a given track 40 such that each carriage 60 is held in place by one or more magnets 46 and 66.

The positioning of the carriage 60 can also be achieved in other ways, for example one embodiment can be envisaged in which the track 40 and the carriage 60 are provided with projections and recesses at respective positions which together ensure a snap connection.

The actuation structure 30 of the three-dimensional logic game 10 is movable between a first rest position and a second rest position. The first rest position can be seen in fig. 1-3 and 5. In this position, a set of three orbits 40 forms a first orbital ring 48 around the vertices 104 of the first tetrahedron 100. The central axis k of each orbital ring 48 coincides with a midline 102 terminating at a respective vertex 104 of the tetrahedron 100. The first marker surface 62a of the carriage 60 on the first orbital ring 48 faces outward in a direction away from the geometric center S of the first tetrahedron 100, while the second marker surface 62b faces inward. The tracks 40 forming the first endless track 48 are connected to each other, allowing the carriage 60 to slide on adjacent tracks 40 within each track ring 48. Accordingly, the carriage 60 can slide (rotate) around each orbital ring 48, as indicated by the arrow in fig. 1.

Adjacent tracks 40 within orbital ring 48 are substantially continuous, i.e., there are no gaps, discontinuities, or other obstructions that would impede sliding of carriage 60 from one track 40 to another. This is further ensured by the side magnets 46, which side magnets 46 contribute to a better positioning and attachment of the rail 40.

In the second rest position of the actuating structure 30, the three-dimensional logical game 10 assumes the geometry shown in fig. 7, wherein the pusher bar 22 and the pusher head 24 define a second tetrahedron 200, the second tetrahedron 200 having a midline 202 terminating at a vertex 204 and intersecting at a second geometric center S' of the second tetrahedron 200. The axes of the pusher rods 22 in fig. 7 do not change, but the pusher heads 24 of all four pusher rods 22 initially located at the vertices 104 of the first tetrahedron 100 have been displaced in the direction of the geometric center S of the tetrahedron 100, as can be better seen in fig. 8. To better compare the first rest position shown in fig. 3 with the second rest position shown in fig. 8, the vertices 104 and 204 of the first and second tetrahedrons 100 and 200 are denoted by the letters A, B, C, D and E, F, G, H, respectively. Since the vertices 104, 204 are defined by the pusher head 24, the letters of the vertices 104, 204 are also shown in the figures, with the pusher head 24 defining another tetrahedron 100 or 200. In this manner, it is possible to trace back how each vertex 104, 204 (and pusher head 24 defining a given vertex 104, 204) is misaligned.

The second tetrahedron 200 is a point reflection pattern of the first tetrahedron 100 reflected above the geometric center S. Thus, the second tetrahedron 200 can be obtained by reflecting each vertex 104 of the first tetrahedron 100 above the geometric center S. This means that the position of the geometric center S of the two tetrahedrons 100, 200 remains unchanged and the geometric center S divides the push rod 22 in a ratio of about 2:1, but the push head 24 that is farther from the geometric center S in the first tetrahedron 100 is closer to the geometric center S in the second tetrahedron 200.

In the second rest position of the actuating structure 30, a group of three orbits 40 forms a second orbital ring 48 'around the vertices 204 of the second tetrahedron 200, so that each orbit 40 forms, together with the two orbits 40 closest to it around the adjacent vertex 104 of the first tetrahedron 100 in the first rest position, one of the second orbital rings 48' around one of the vertices 204 of the second tetrahedron 200. Thus, in fig. 7, orbital ring 48' formed about apex 204, represented by letter E, is made up of orbits 40a, 40b, 40c belonging respectively to orbital ring 48 about apex 104, represented by A, B, C in fig. 5.

The central axis k of the second orbital ring 48' also coincides with the midline 202 of the second tetrahedron 200, starting from the respective vertex 204, because the pusher rods 22 are displaced along their own longitudinal axis and cannot rotate about their own axis.

On the second orbital ring 48', the second marking surface 62b of the carriage 60 faces outwards in a direction away from the geometric centre of the second tetrahedron 200, while the first marking surface 62a faces inwards, which means that the track 40 and the carriage 60 rotate while the actuation structure 30 is brought from the first rest position to the second rest position, as will be explained in more detail later on.

The tracks 40 of the second orbital ring 48 'are also connected to each other, allowing the carriage 60 to be displaced to an adjacent track 40 within the same orbital ring 48'.

It should be noted that each track 40 may also be composed of more than one independent track component, but in the context of the present invention, all track components are referred to as a single track 40, which track 40 may be rotated from one given pusher head 24 to another given pusher head 24 in the first and second rest positions of the actuation structure 30, respectively. For example, in fig. 11, 12, the track 40 located between the pusher head 24 defining the apex 104 represented by the letter a and the pusher head 24 defining the apex 204 represented by the letter H is considered a single track 40, even though it is composed of separate components, in that it functionally functions as a single track 40. The same terminology applies to a given actuating element 32 (consisting of one or more components) that actuates the track 40, which means that the actuating element 32 may also consist of more than one independent component. The actuating elements 32 are distinguished from each other according to which two pusher heads 24 they move between the rails 40 (which may be made up of one or more parts) interposed therebetween.

How the actuation structure 30 moves the components of the game 10 from their positions in the first rest position to their positions in the second rest position will now be described.

Fig. 9 shows the position of the two pusher rods 22 of the support structure 20 and the position of the actuating element 32 of the actuating structure 30 connecting them together in the first rest position of the actuating structure 30. In this position, the pusher head 24 at one end of each pusher arm 22 defines the vertices a and C of the first tetrahedron 100. Fig. 10 shows the same components in a second rest position, in which the pusher heads 24 at the other end of each pusher rod 22 define the vertices F and H of a second tetrahedron 200.

The user brings three-dimensional logical game 10 from a first resting position to a second resting position by pushing inward on pusher head 24 (or a portion of pusher head 24) that defines the vertices of first tetrahedron 100. According to the example shown in fig. 9-10, the user pushes the pushing head 24 defining the vertices denoted by a and C in the direction of the arrows (i.e., inward along the midline 102 of the tetrahedron 100 in the direction of the geometric center S of the tetrahedron 100) so that the vertex 104 denoted by a is close to the geometric center S and the vertex 204 denoted by H is far from the geometric center S. During this movement, the free ends 38 of the arms 34 of the actuating element 32 connecting the two push rods 22 come close to each other, which is allowed by the elastic deformation of the arms 34. The free ends 38 are closest to each other midway along the trajectory (i.e., when the two pusher arms 22 meet at their bisector point). Before this position is reached, when pushing the push rods 22, the user has to resist the reaction force due to the elastic deformation of the arms 34, from which position the elastic force helps to move the push rods 22 to their second rest position by moving the free ends 38 away from each other, which brings the push rods 22 into the second rest position shown in fig. 10, in which the free ends 38 are at the same maximum distance from each other as in fig. 9. In the second rest position, the pusher head 24 defining the vertices 104 denoted by H and F is located further away from the geometric center S, thereby forming the second tetrahedron 200, while the vertices 104 denoted by a and C of the original first tetrahedron 100 have entered the interior of the second tetrahedron, or at least have moved to a position closer to the geometric center S.

Other embodiments are envisaged in which the two arms 34 of the actuating element 32 are rigid (i.e. not elastically deformable). In this case, the coupling element 36 may be a hinge about which the arms 34 can be rotated so that the free ends 38 of the arms 34 approach each other while the two connected pusher rods 22 move relative to each other. In this case it can also be ensured that the actuating element 32 tries to return to one of its rest positions when the actuating element 32 is displaced from the rest position. For example, a spring may be provided between the two arms 34, which spring is compressed when the push rod 22 is displaced, the resulting spring force biasing the arms 34 at an angle corresponding to the first and second rest positions. The invention can also be implemented without any binding forces being formed in the actuating element 32 as a result of the actuation, but in this case it is preferred to provide magnets 46 on the sides of the track 40, which magnets 46 attract each other in order to stabilize the track rings 48, 48' belonging to the first and second rest positions.

Fig. 11 and 12 show the rail 40 connected to the coupling element 36 of the actuating element 32 shown in fig. 9 and 10, and carriages 60 (in this case two carriages 60) arranged on the rail 40 in the first and second rest positions of the actuating structure 30, respectively. As can be seen from fig. 11, in the first rest position, the rail 40 forms, together with the other two rails 40 (not shown here), a rail ring 48 around the vertices 104, indicated by a, of the first tetrahedron 100, while the other rail 40 forms part of another rail ring 48 around the vertices 104, indicated by C. In this position, the first marking surface 62a of the carriage 60 faces outward, i.e., the user can see the first marking surface 62a when the user turns the apex 104 indicated by a or the apex indicated by C in the direction thereof. In the second rest position shown in fig. 12, the trajectory 40 around the vertex 104 denoted by a rotates together with the coupling element 36 to the vertex H of the second tetrahedron 200 and forms, together with the other two trajectories 40 not shown, a second trajectory ring 48' around this vertex. The orbit 40 previously around vertex 104, denoted by C, rotates to vertex 204, denoted by F, of the second tetrahedron 200 and forms a second orbital ring 48' around this vertex. In this position, the second marking surface 62b of the carriage 60 is located on the outside, while the first marking surface 62a is partially covered by the carriage 60 located on the adjacent orbital ring 48' (see fig. 7). According to this embodiment, the rotation angle of the rail 40 and the carriage 60 around their own axes is 109 ° 28'16"(109 degrees 28 minutes 16 seconds angle), which corresponds to the larger angle (obtuse angle) formed by the centre lines 102 of the first and second tetrahedrons 100, 200.

In the first rest position of the actuating structure 30, the position of the support structure 20, the actuating structure 30 and the track 40 with respect to each other is always the same, and similarly in the second rest position of the actuating structure 30, the relative position of the same elements is always the same (but different from the relative position belonging to the first rest position). In contrast, the carriage 60 can assume a plurality of positions in the two rest positions; the number of state changes of the three-dimensional logic game that the user can distinguish depends on the difference between the markers disposed on the marker surfaces 62a and 62 b. According to one particularly preferred embodiment, game 10 has a first state in which actuation structure 30 is in its first rest position and the indicia on the outwardly facing first indicia surface 62a of carriage 60 on each orbital ring 48 located about each vertex 104 of first tetrahedron 100 are identical to one another, but different from the indicia carried by the first indicia surface 62a of carriage 60 located on different orbital rings 48. Similarly, game 10 has a second state (inverted state) in which the actuating structure 30 is in its second rest position and the indicia on the outwardly facing second indicia surface 62b of the carriage 60 on each orbital ring 48 'located around each vertex 204 of the second tetrahedron 200 are identical to one another, but different from the indicia carried by the second indicia surface 62b of the carriage 60 located on a different orbital ring 48'. This means that the marks of the quarter of the first marking surface 62a are identical and the marks of the quarter of the second marking surface 62b are identical.

According to a preferred embodiment, each carriage 60 comprises two halves 60a, 60b made of a coloured material, so that the marking is the colour of the halves 60a, 60 b. The half 60a including the first indicia surface 62a has four different colors such that one quarter of the half 60a has the same color. The half 60b containing the second indicia surface 62b has four other different colors such that one quarter of the half 60b has the same color. Thus, for example, if two carriages 60 are arranged on each track 40, there are 24 carriages 60 in total, thus 24 first halves 60a and 24 second halves 60 b. The first half 60a contains 6-6-6-6 parts of the same color and the second half 60b also contains 6-6-6-6 parts of the same color. It should be appreciated that this embodiment is equivalent to another embodiment of game 10 from a game play perspective (wherein each carriage 60 is a single (one-piece) object and first indicia surface 62a is provided with 6-6-6-6 identical stickers, paintings or other indicia and second indicia surface 62b is provided with 6-6-6-6 identical stickers, paintings or other indicia).

By arranging more carriages 60 on each track 40 (e.g., by arranging three carriages 60 on each track 40, whereby the game 10 contains a total of 36 carriages 60), the number of combinations of possible states of the game 10 can be increased. Another possibility is to increase the number of different markings, for example in the case of 24 carriages 60, each six surfaces of the same colour may be provided with a number from 1 to 6, so that the basic challenge of obtaining all marking surfaces 62a, 62b with markings of the same colour on the same orbital ring 48, 48' becomes more difficult if the user is also faced with the problem of arranging these numbers in sequence, for example in the solved state the marking surfaces 62a of the carriages 60 on one of the orbital rings 48 should all contain red markings and the numerical markings 1-6 should succeed each other in increasing order along a given orbital ring 48.

The pusher heads 24 may also be provided with different indicia, for example each pusher head 24 may have the same indicia as one of the indicia surfaces 62a, 62b, whereby it may be a further challenge to arrange the indicia surfaces 62a, 62b along the orbital rings 48, 48' around the pusher heads 24 provided with the same indicia.

It should be appreciated that the number of combinations provided by game 10 may also be reduced by reducing the number of carriages 60 (a single carriage 60 disposed on each track 40) and/or reducing the variety of indicia (e.g., first indicia surface 62a and second indicia surface 62b each contain two different indicia). In this way, game 10 may become more enjoyable to children and beginners.

It will be apparent to those skilled in the art that various modifications can be made to the embodiments disclosed above without departing from the scope of protection defined by the appended claims.

The claims (modification according to treaty clause 19)

1. A three-dimensional logical game comprising a support structure (20, 70), an actuation structure (30, 80) attached to the support structure (20, 70), and a game element attached to the actuation structure (30, 80), characterized in that the game element is formed as a carriage (60) having first and second marking surfaces (62a, 62b) and is slidably mounted on a track (40) attached to the actuation structure (30, 80); the actuation structure (30, 80) is movable between a first rest position, in which a first group of rails consisting of three rails (40) forms a first rail ring (48) around the vertices (104) of a first tetrahedron (100), wherein the first marking surface (62a) of the carriage (60) faces outwards in a direction away from the geometric centre (S) of the first tetrahedron (100) and the second marking surface (62b) faces inwards, and the rails (48) of the first ring allow the carriage (60) to slide onto the adjacent rails (40); in a second rest position of the actuation structure (30, 80), a second group of tracks consisting of three tracks (40) forms a second ring of tracks (48 ') around the vertices (204) of the second tetrahedron (200), the vertices (204) of the second tetrahedron (200) being a point reflection pattern of the reflection of the first tetrahedron (100) above its geometric center (S), wherein in the first rest position each track (40) forms, together with the two tracks (40) around the adjacent vertex (104) of the first tetrahedron (100) closest thereto, one of the second rings of tracks (48 ') around one vertex (204) of the second tetrahedron (200), and on the second ring of tracks (48 '), the second marking surface (62b) of the carriage (60) faces outwards in a direction away from the geometric center (S) of the second tetrahedron (200) while the first marking surface (62a) faces inwards, and the track (48') of the second loop allows the carriage (60) to slide onto the adjacent track (40); the support structure (20) comprises pusher bars (22) arranged along the midline (102, 202) of the first and second tetrahedrons (100, 200) having axes that are skewed with respect to each other, and the actuation structure (30) comprises a two-arm actuation element (32), the arms (34) of the two-arm actuation element (32) being attached to one of the pusher bars (22), respectively.

2. Three-dimensional logic game according to claim 1, characterized in that each pusher arm (22) is provided at its two ends with a pusher head (24), respectively, the two arms (34) of the actuating element (32) being joined together at one of their ends by a coupling element (36) connected to one of the rails (40), and their free ends (38) being connected to a pair of adjacent pusher arms (22) in the vicinity of one of the pusher heads (24) that are close to each other.

3. Three-dimensional logic game according to claim 2, characterized in that said pusher bar (22) and said actuation element (32) are dimensioned:

in a first rest position of the actuation structure (30), a first pusher head (24) of a first pusher rod (22) among two adjacent pusher rods (22) connected to the arm (34) of a given actuation element (32) is located at one of the vertices (104) of the first tetrahedron (100), the track (40) of the linking element (36) connected to the given actuation element (32) constitutes one track (40) of a first track ring (48) formed around this vertex (104), and a second pusher head (24) of a second pusher rod (22) among the two adjacent pusher rods (22) connected to the arm (34) of the given actuation element (32) that is located closer to the given actuation element (32) is located closer to the geometric center (S) of the first tetrahedron (100) than the first pusher head (24), preferably such that the second pusher head (24) is located within the first tetrahedron (100), and is

In the second rest position of the actuating structure (30), the second pusher head (24) is located at one of the vertices (204) of the second tetrahedron (200), while the trajectory (40) of the linking element (36) connected to a given actuating element (32) constitutes one trajectory (40) of a second loop of trajectories (48') formed around this vertex (204) of the second tetrahedron (200), and the first pusher head (24) is closer to the geometric center (S) of the second tetrahedron (200) than the second pusher head (24), preferably so that the first pusher head (24) is located within the second tetrahedron (200).

4. Three-dimensional logical game according to claim 2 or 3, characterised in that the two arms (34) of the actuation element (32) are made of an elastic material, allowing bending by elastic deformation with respect to the coupling elements (36) that couple them together.

5. Three-dimensional logical game according to claim 2 or 3, characterized in that the coupling elements (36) of the actuation elements (32) respectively comprise joints allowing the two arms (34) coupled together to rotate with respect to each other.

6. Three-dimensional logical game according to one of the claims 1 to 5, characterized in that at least two carriages (60) are arranged on each track (40).

7. A three-dimensional logical game according to any one of claims 1 to 6, wherein the first and second marker surfaces (62a, 62b) of each carriage (60) carry first and second markers, respectively, that are different from each other, and the logical game has a first solution state in which the first markers on the outwardly facing marker surfaces (62a) of the carriages (60) on any given first orbital ring (48) are the same as each other and different from the first markers on the outwardly facing marker surfaces (62a) of the carriages (60) on any other orbital ring (48), and a second solution state in which the second markers on the outwardly facing marker surfaces (62b) of the carriages (60) on any given second orbital ring (48 ') are the same as each other and different from the second markers on the outwardly facing marker surfaces (62b) of the carriages (60) on any other second orbital ring (48') The notation is different.

8. Three-dimensional logical game according to one of claims 1 to 7, characterized in that pairs of magnets (46, 66) and/or magnets (46, 66) and magnetizable elements with opposite polarities are arranged on the track (40) and carriage (60), respectively, for positioning the carriage (60).

9. Three-dimensional logical game according to one of claims 1 to 8, characterized in that a side magnet (46) is arranged on one side of a track (40), the polarity of which is opposite to the polarity of the other side magnet (46) of the adjacent track (40), or a side magnet (46, 66) and a magnetizable element are arranged on the adjacent side of a track (40) for positioning a track (40) within a track ring (48, 48').

10. Three-dimensional logical game according to one of claims 1 to 7, characterized in that protrusions and recesses are formed at corresponding positions on the track (40) and carriage (60), which together form a snap connection for positioning the carriage (60) relative to the track (40) and the track (40) within the track ring (48, 48').

11. A three-dimensional logic game according to any of claims 1 to 10, wherein the marking surfaces (62a, 62b) of the carriages contain embossed, debossed or other tactile markings.