Patent Publication Number: US-8109515-B2

Title: Three-dimensional puzzle

Description:
FIELD OF THE INVENTION 
     The present invention relates generally to three-dimensional puzzles. More particularly, the present invention relates to 3D puzzles comprise elements rotated in respect to each other to achieve the ordered condition with respect to a shape and color of the corresponding 3D shaped body. The present invention can be use particularly, but not exclusively, as a further development of the famous Rubik&#39;s cube family puzzles that significantly increase puzzles attraction. 
     BACKGROUND OF THE INVENTION 
     There are numerous designs of puzzles belong to a family of the worldwide famous Rubik&#39;s cube. For example, there are known puzzles of this type invented by Erno Rubik and disclosed in the Hungarian Patent HU No. 170062 and U.S. Pat. No. 4,378,116 “A Spatial Logical Toy”. Such puzzles comprise elements assembled with spaced inside an intersecting axes member thus forms a 3D shaped body like a three layers cube mainly. The elements form groups of elements each of them have a possibility to rotate around the corresponding axis of the intersecting axes member. The mentioned designs relatively are not simple due to the necessity of the intersecting axes member and, therefore, are costly. 
     By now, the attraction of such puzzles is practically exhausted because all assembling algorithms are well-known and described, thus, the puzzles attraction is increased in an extensive way by increasing the number of layers. That led to further increasing of the design complexity and cost correspondingly. 
     There are known puzzles of the mentioned type that have a simplified design, for example, described in the PCT Patent Application WO83/01203 “Three-Dimensional Geometric Puzzle”. Such design disclosed a 3D puzzle that comprises only elements form a various 3D shaped body, without the intersecting axes member. Each element has means cooperating with all adjacent elements permitting the sliding of the elements relative to the adjacent elements along an imaginary spherical surface. The means are made as a tongue and groove inter-engagement structure. The puzzle assembling provided by the positioning of each element with the following snapping into place by external pressure. The mentioned 3D puzzle has the same difficulty level during assembling the puzzle like the mentioned above Spatial Logic Toy as well as the assembling algorithms, and therefore, has the same level of the attraction. 
     Despite the design of the 3D puzzle according to the PCT Patent Application WO83/01203 is more simple, additional problems are arisen. Because the puzzle assembled by applying external pressure, there must be enough clearance at the tongue and groove inter-engagement structure, otherwise some of elements could be destroyed. But such clearance between two adjacent elements summarized with clearances of other elements, that form the group of element which is currently rotated, led to the loss of the shape stability of the group and embarrassed the rotation in respect to other elements. 
     There is also known puzzle, that provides increasing the puzzle attraction by the possibility to be open if puzzle elements are arranged in the correct order. For example, the U.S. Pat. No. 5,452,895 “Three Dimensional Rotating Puzzle That Open” discloses a spherical puzzle comprises eight fife-sided elements and thirty six-sided elements which are connected by means of a locking rail system that allows all of the elements to be shiftable around the three equatorial planes of the puzzle. According to the mentioned patent the puzzle is hollow inside and can be opened by removing one of the six-sided elements if the elements are arranged in the correct order. 
     But, despite to the presence of a new feature like opening the puzzle, the attraction of the puzzle in comparison with the mentioned above puzzles is the same or less, depending on the goal of the assembling. If the goal of the puzzle according the U.S. Pat. No. 5,452,895 is the arranging all of the elements in the correct order defined by the colored patterns, the difficulty level will be the same. And, if the goal of the puzzle is the puzzle opening by removing one of the six-sided elements, the difficulty level will be less. In fact, it is evident that the necessity condition for such opening is the arrangement of the element which is opened and the adjacent elements only, in the correct order, all other elements could be arranged at any order. There are a lot of combinations of the arranged elements allowed to open the puzzle that decrease the puzzle difficulty level. 
     And more, the puzzle design is not simple and the puzzle comprises the small parts like removable rail, which is flush-mounted into the corresponding five-sided element. It will be difficult to catch that removable rail due to the friction; otherwise, if the corresponding clearance will be increased, the removable rail can fall out of the puzzle during the play and lost. The last circumstance is very dangerous if such small part would be swallowed by small-age children. 
     The main problem of all known three-dimensional puzzles is that all designs can not resolve the contradiction between the tendency to increase the attraction of the puzzle from one hand and the design simplification from the other hand simultaneously. 
     Therefore, it would be generally desirable to provide a reliable, low cost design of the three-dimensional puzzle that is not complicated and at the same time more attractive in comparison with known 3D puzzles, thus overcome mentioned problems. 
     SUMMARY OF THE INVENTION 
     According to the present invention a three-dimensional puzzle comprises of elements formed as a result of splitting of a three-dimensional shaped body by three pairs of coaxial identical right circular conical surfaces. The three-dimensional shaped body has a hollow sphere inside with a center O and three mutually perpendicular main axes OX, OY and OZ, thus defining three main planes XOZ, XOY and YOZ. The axes of each pair coincide with one of the main axes correspondingly. Both conical surfaces of each pair are symmetrical in respect with the center O. 
     The elements from all sides, being a result of splitting by the conical surfaces, comprise outer and inner junction means that provide for each two adjacent elements to join with the possibility of sliding with respect to each other. All elements contiguous with similar sides of each pair of conical surfaces have outer junction means, while all elements contiguous with the other sides of the same pair of conical surfaces have inner junction means, thus the elements spaced from one side of each conical surface have the possibility to rotate around the axis of the same pair of conical surfaces independently in respect to all other elements. 
     The elements are three types of elements depending on the shape of the surface belong to the hollow sphere. The elements of the first type are six polar quadrilateral shaped elements crossing by the main axes. The elements of the second type are twelve median rectangular shaped elements spaced between two nearest polar elements. The elements of the third type are eight triangular shaped elements surrounded by three nearest median elements. 
     The three-dimensional shaped body transformed from initial ordered orientation to disordered orientation by series of 90 degrees rotations of the elements spaced from one side of the conical surfaces in respect to the main axes correspondingly. The outer surface of each elements has coordination means thus define the initial orientation of the elements in respect with the ordered orientation of the three-dimensional shaped body. At the initial orientation of the three-dimensional shaped body the outer and inner junction means of the elements adjacent to one conical surface comprise key open means that provide for each two adjacent elements spaced from both sides of the same conical surface able to move apart with respect to each other in a direction parallel to the axis of the same conical surface, thus all elements spaced from one side of the same conical surface have a possibility to move together along the same direction and the three-dimensional shaped body being separated for two spaced apart parts. 
     The goal of the three-dimensional puzzle is to put in right order the three-dimensional shaped body from the disordered orientation by series of 90 degrees rotations of the elements spaced from one side of the conical surfaces in respect to the main axes correspondingly, to the initial ordered orientation, where the three-dimensional shaped body has the ability to be separated for two spaced apart parts, thus providing access to the space located inside the hollow sphere. The additional goal is to assemble the three-dimensional shaped body from a disassembled condition where all elements are spaced apart from each other, to the initial ordered orientation. 
     The preferred embodiment according to the present invention comprises the three-dimensional shaped body made as a cube and the apex angle of each conical surface is equal 180 degrees, thus each of the conical surfaces degenerates to a plane parallel to one of the main planes. Each of the planes spaced aside from the center O at the distance of one-sixth of the length of the edge of the cube substantially, thus provide the equal side lengths of the outer surface of each elements. 
     According to the other embodiment of the present invention the three-dimensional shaped body is a ball and both conical surfaces of each pair have a common apex. Each of the conical surfaces may have the apex angle of 137 degrees substantially, thus provide the approximately equal side lengths of the outer surface of each elements. 
     For all embodiments the outer junction means can be made as a ledge protruded along a side part of the elements, and the ledge made as a part of a torus ring integrated by a shorter part of a narrow cylindrical ring with the side part. Correspondingly, the inner junction means can be made as a groove spaced along a side part of the elements, and the groove has the bigger similar cross-section like the ledge, thus the ledge at least partially surrounded by the groove. 
     The coordination means can be made as colored surfaces with letters and/or numbers. The coordination means can be also made as numbers that form a magic quadrate on each differently colored side of the cube, if the three-dimensional shaped body made as a cube. 
     The key open means of the ledge can be made by reducing of length of the corresponding ledge for 30%, while the key open means of the corresponding groove are made by deleting of the narrow part of the groove along corresponding length of the key open means of the ledge. 
     The three-dimensional puzzle may further comprise prize means located with a clearance inside of the hollow sphere. The prize means can be a similar three-dimensional puzzle. 
     All elements of the three-dimensional puzzle are made from self-lubricated plastic material. 
     The foregoing and other objectives, features and advantages of the invention will be more readily understood upon consideration of the following detailed description of the invention, taken in conjunction with the accompanying drawings. 
    
    
     
       BRIEF DESCRIPTION OF THE DRAWINGS 
         FIG. 1  is a perspective view showing the construction according to the present invention where the three-dimensional shaped body having inside a hollow sphere. 
         FIG. 2  is a perspective view showing the construction according to the present invention where the three-dimensional shaped body splitted by one pair of the conical surfaces with axis coincided with the main axis OX. 
         FIG. 3  is a plane front view showing the construction according to the present invention where the three-dimensional shaped body splitted by one pair of the conical surfaces with axis coincided with the main axis OZ. 
         FIG. 4  is a perspective view showing the construction according to the present invention where the polar quadrilateral shaped element is a result of splitting the 3D shaped body by two pairs of the conical surfaces with the axes coincided with the main axes OX and OY. 
         FIG. 4A  is a perspective view showing the polar quadrilateral shaped element according to the present invention where the 3D shaped body is a ball. 
         FIG. 5  is a perspective view showing the construction according to the present invention where the median rectangular shaped element is a result of splitting the 3D shaped body by one pair of the conical surfaces with the axis coincided with the main axes OY and by two conical surfaces belong to different pairs with the axis coincided with the main axes OX and OZ. 
         FIG. 5A  is a perspective view showing the median rectangular shaped element according to the present invention where the 3D shaped body is a ball. 
         FIG. 6  is a perspective view showing the construction according to the present invention where the triangular shaped element is a result of splitting the 3D shaped body by three conical surfaces belong to different pairs with the axis coincided with the main axes OX, OY and OZ. 
         FIG. 6A  is a perspective view showing the triangular shaped element according to the present invention where the 3D shaped body is a ball. 
         FIG. 7  is a perspective view showing according to the present invention the joining of the polar quadrilateral shaped element and the median rectangular shaped element with the possibility of sliding with respect to each other. 
         FIG. 7A  is a perspective view showing according to the present invention the joining of the median rectangular shaped element and the triangular shaped element with the possibility of sliding with respect to each other. 
         FIG. 8  is a plane top view showing the second embodiment of the present invention where the 3D shaped body is a ball. 
         FIG. 8A  is a sectional view along sectional plane A-A from  FIG. 8 . 
         FIG. 9  is a perspective view showing the second embodiment of the present invention where the 3D shaped body is a ball. The coordination means are not shown. 
         FIG. 10  is a perspective view showing the second embodiment of the present invention at the initial ordered orientation. 
         FIG. 11  is a perspective view showing the second embodiment of the present invention at the disordered orientation. 
         FIG. 12  is a perspective view showing according to the present invention the joining of the polar quadrilateral shaped element and the median rectangular shaped element with the possibilities of sliding and moving apart with respect to each other. 
         FIG. 13  is a perspective view showing according to the present invention the joining of the triangular shaped element and the median rectangular shaped element with the possibilities of sliding and moving apart with respect to each other. 
         FIG. 14  is a perspective view showing the second embodiment of the present invention where the three-dimensional shaped body being separated for two spaced apart parts. 
         FIG. 15  is a perspective view showing the first embodiment of the present invention where the 3D shaped body is a cube splitted by the conical surfaces. The coordination means are not shown. 
         FIG. 16  is a plane top view showing the preferred embodiment of the present invention where the 3D shaped body is a cube and the conical surfaces degenerate to planes parallel to the corresponding main planes. 
         FIG. 16A  is a sectional view along sectional plane A-A from  FIG. 16 . 
         FIG. 17  is a perspective view showing the preferred embodiment of the present invention where the three-dimensional shaped body being separated for two spaced apart parts. 
         FIG. 18  is a sectional perspective view showing the outer and inner junction means made as ledges and grooves according to the present invention. 
         FIG. 18A  is an enlarged sectional side view A from  FIG. 18 . 
         FIG. 19  is a perspective view showing the preferred embodiment of the present invention where coordination means are numbers form a magic quadrate on each differently colored side of the cube. The coordination means made as colored surfaces are not shown. 
         FIG. 20  is a sectional perspective view showing the key open means of the inner junction means made by deleting of the narrow part of the groove. 
         FIG. 20A  is an enlarged sectional side view A from  FIG. 20 . 
         FIG. 21  is a perspective view showing the preferred embodiment of the present invention where the three-dimensional shaped body being separated for two spaced apart parts and there is a similar three-dimensional puzzle located inside of the hollow sphere. 
         FIG. 22  is a perspective exploded view showing the disassembled condition of the preferred embodiment of the present invention where all element are spaced apart from each other. 
         FIG. 23  is a perspective exploded view showing the disassembled condition of the second embodiment of the present invention where all element are spaced apart from each other. 
         FIG. 24  is a perspective view showing all kind of elements from  FIG. 22 . 
         FIG. 25  is a perspective view showing all kind of elements from  FIG. 23 . 
         FIGS. 26-29  are perspective views showing step-by-step assembling of the preferred embodiment of the present invention from the disassembled condition shown on  FIG. 22  to the assembled initial ordered condition shown on  FIG. 17 . 
         FIG. 30  is a perspective view showing the preferred embodiment of the present invention where all elements arranged to the initial ordered position, but the orientation of the polar elements does not corresponds to the initial ordered orientation. 
     
    
    
     DETAILED DESCRIPTION OF PREFERRED EMBODIMENTS 
     Preferred embodiment of the present invention will be described in detail below with reference to the accompanying drawings. 
       FIGS. 1-29  show embodiments of the present invention. 
     The three-dimensional puzzle  1  comprises of elements  2  formed as a result of splitting of a three-dimensional shaped body  3  by three pairs  5  of coaxial identical right circular conical surfaces  6  ( FIGS. 1-6 ). The three-dimensional shaped body  3  has a hollow sphere  4  inside with a center O and three mutually perpendicular main axes OX, OY and OZ ( FIG. 1 ), thus defining three main planes XOZ, XOY and YOZ. For the simplification only one pair  5  of the conical surfaces  6  and  6 A is shown on  FIGS. 2 and 3 . The axes of each pair  5  coincide with one of the main axes correspondingly. On  FIG. 2  the axis of the pair  5  is coincided with the main axes OX, while on  FIG. 3  the axis of the pair  5  is coincided with the main axes OZ. Both conical surfaces  6  of each pair  5  are symmetrical in respect with the center O. The three-dimensional shaped body  3  may have numerous shapes, for example, cube, ball, apple-shaped etc. 
     The elements  2  from all sides being a result of splitting by the conical surfaces  6 . Thus, on  FIG. 4  the element  2  is a result of splitting the three-dimensional shaped body  3  by the four conical surfaces  6 ,  6 A,  6 B and  6 C belonging to two pairs  5  and  5 A with the axes coincided with the main axes OX and OY correspondingly. On  FIG. 5  the element  2  is a result of splitting the three-dimensional shaped body  3  by the four conical surfaces  6 ,  6 A,  6 B and  6 C. The conical surfaces  6  and  6 A belong to the pair  5  with the axis coincided with the main axes OY, while the conical surfaces  6 B and  6 C belong to the two different pairs  5 B and  5 C with the axes coincided with the main axes OX and OZ correspondingly. And, on  FIG. 6  the element  2  is a result of splitting the three-dimensional shaped body  3  by the three conical surfaces  6 ,  6 A and  6 B belonging to the three different pairs  5 ,  5 A and  5 B with the axes coincided with the main axes OY, OX and OZ correspondingly. 
     The elements  2  from all sides, being a result of splitting by the conical surfaces  6 , comprise outer and inner junction means  7  and  8  ( FIGS. 4A ,  5 A and  6 A), which provide for each two adjacent elements  2  to join with the possibility of sliding with respect to each other ( FIGS. 7 and 7A ). All elements  2  contiguous with similar sides of each pair  5  of the conical surfaces  6  have outer junction means  7 , while all elements  2  contiguous with the other sides of the same pair  5  of the conical surfaces  6  have inner junction means  8 , thus the elements  2  spaced from one side of each conical surface  6  have the possibility to rotate around the axis of the same pair  5  of the conical surfaces  6  independently in respect to all other elements  2 . 
     This is illustrated on  FIG. 8A , where all elements  2  and  2 C correspondingly contiguous with the similar inner sides of the conical surfaces  6 A and  6  of the pair  5  with the axis coincided with the main axis OZ, have the outer junction means  7 . And, all elements  2 A contiguous with the other outer sides of the conical surfaces  6  and  6 A of the same pair  5  have the inner junction means  8 . Therefore, the elements  2  and  2 B spaced from one side of the conical surface  6 A have the possibility to rotate around the axis OZ of the same pair  5  independently in respect to all other elements  2 A and  2 C. At the same time the elements  2 C spaced from one side of the conical surface  6  have the possibility to rotate around the same axis OZ of the same pair  5  independently in respect to all other elements  2 ,  2 A and  2 B. It is evident, that the outer junction means  7  and the inner junction means  8  can be mutually switched, keeping the same possibility of the rotation around the axis OZ ( FIG. 16A ). 
     The elements  2  are three types of elements  10 ,  12  and  14  ( FIGS. 4-8A ) depending on the shape of the surface  9  belong to the hollow sphere  4 . The elements of the first type  10  are six polar quadrilateral shaped elements  11  ( FIG. 9 ) crossing by the main axes OX, OY and OZ. The elements of the second type  12  are twelve median rectangular shaped elements  13  spaced between two nearest polar elements  11 . The elements of the third type  14  are eight triangular shaped elements  15  surrounded by the three nearest median elements  13 . 
     The three-dimensional shaped body  3  can be transformed from the initial ordered orientation ( FIGS. 10 ,  14 ,  16  and  19 ) to the disordered orientation ( FIG. 11 ) by series of 90 degrees rotations of the elements  2  spaced from one side of the conical surfaces  6  in respect to the main axes OX, OY and OZ correspondingly. The outer surfaces  16  of each elements  2  ( FIGS. 8 and 16 ) have coordination means  17  thus define the initial orientation of the elements  2  in respect with the ordered orientation of the three-dimensional puzzle  1 . At the initial orientation of the three-dimensional puzzle  1  the outer and inner junction means  7  and  8  of the elements  2  adjacent to the one conical surface  6  comprise key open means  18  that provide for each two adjacent elements  2  spaced from the both sides of the same conical surface  6  able to move apart with respect to each other in direction parallel to the axis of the same conical surface  6  ( FIGS. 12 and 13 ), thus all elements  2  spaced from one side of the same conical surface  6  have a possibility to move together along the same direction and the three-dimensional puzzle  1  being separated for two spaced apart parts  19  and  19 A ( FIGS. 14 ,  17  and  21 ). 
     The goal of the three-dimensional puzzle  1  is to put in right order the three-dimensional shaped body  3  from the disordered orientation ( FIG. 11 ) by series of 90 degrees rotations of the elements  2  spaced from one side of the conical surfaces  6  in respect to the main axes OX, OY and OZ correspondingly, to the initial ordered orientation ( FIGS. 10 ,  14 ,  16  and  19 ), where the three-dimensional shaped body  3  has the ability to be separated for two spaced apart parts  19  and  19 A ( FIGS. 14 ,  17  and  21 ), thus providing access to the space  20  located inside the hollow sphere  4  ( FIGS. 8A and 16A ). The additional goal is to assemble the three-dimensional shaped body  3  from a disassembled condition ( FIGS. 24 and 25 ) where all elements  2  are spaced apart from each other, to the initial ordered orientation ( FIGS. 10 ,  14 ,  16  and  19 ). 
     The preferred embodiment according to the present invention comprises the three-dimensional shaped body  3  made as a cube  21  ( FIGS. 15-16A  and  19 ) and the apex angle of each conical surface is equal 180 degrees ( FIGS. 16 and 16A ), thus each of the conical surfaces  6  degenerates to a plane  23  parallel to one of the main planes XOY, XOZ and YOZ correspondingly. Each of the planes  23  spaced aside from the center O at the distance d of one-sixth of the length D of the edge  24  of the cube  21  substantially, thus provide the equal side lengths of the outer surface  16  of each elements  2 . On  FIG. 16A  the conical surfaces  6  and  6 A of the pair  5  correspondingly degenerate to the planes  23  and  23 A parallel to the main plane XOY. 
     According to the second embodiment of the present invention the three-dimensional shaped body  3  is a ball ( FIGS. 8-11  and  14 ) and both conical surfaces  6  of each pair  5  have a common apex. In common case both conical surfaces  6  of each pair  5  may have non-coincided apexes. Each of the conical surfaces  6  may have the apex angle α of 137 degrees substantially, thus provide the approximately equal side lengths of the outer surface  16  of each of the elements  2 . 
     For all embodiments the outer junction means  7  can be made as a ledge  27  protruded along a side part  30  of the elements  2  ( FIGS. 7 ,  7 A and  12 ), and the ledge  27  made as a part of a torus ring  29  integrated by a shorter part of a narrow cylindrical ring with the side part  30  ( FIGS. 18A and 20A ). Correspondingly, the inner junction means  8  can be made as a groove  31  spaced along a side part  30  of the elements  2 , and the groove  31  has the bigger similar cross-section like the ledge  27 , thus the ledge  27  at least partially surrounded by the groove  31  ( FIGS. 7 ,  7 A,  12 ,  18  and  18 A). 
     The coordination means  17  ( FIGS. 8 ,  10 ,  11 ,  14 ,  16 ,  17 ,  21 - 23 ) can be made as colored surfaces  33  with letters and/or numbers  34 . The coordination means  17  can be also made as numbers  34  that form a magic quadrate on each differently colored side of the cube  21 , if the three-dimensional shaped body  3  made as a cube  21  ( FIG. 19 ). The numbers  34  put in order of the magic quadrate characterized that for each colored side of the cube  21  the sums of the numbers  34  in horizontal, vertical and diagonal directions are equal to 15. 
     The key open means  35  of the ledge  27  can be made by reducing of length of the corresponding ledge  27  for 30%, while the key open means  36  of the corresponding groove  31  are made by deleting of the narrow part  29  of the groove  31  along corresponding length of the key open means  35  of the ledge ( FIGS. 12-14 ,  17 ,  20 - 25 ). 
     The three-dimensional puzzle  1  may further comprise prize means  37  located with a clearance inside of the hollow sphere  4 . The prize means  37  can be a similar three-dimensional puzzle  38 . On  FIG. 21  it is shown that inside of the three-dimensional puzzle  1  made as a cube  21  there is the three-dimensional puzzle  1  of a smaller size made as a ball  22 . 
     On  FIG. 24  all elements  2 , needed to assemble the three-dimensional puzzle  1  according to the preferred embodiment of the present invention, made as a cube  21 . The full set of elements  2  comprises two elements  11  ( 101 ) without key open means, four elements  11  ( 102 ) with one key open means  35 , four elements  13  ( 103 ) without key open means, four elements  13  ( 104 ) with one key open means  35 , four elements  13  ( 105 ) with one key open means  36 , four elements  15  ( 106 ) with one key open means  36  and four elements  15  ( 107 ) without key open means. 
     And, on  FIG. 25  all elements  2 , needed to assemble the three-dimensional puzzle  1  according to the second embodiment of the present invention, made as a ball  22 . The full set of elements  2  comprises two elements  11  ( 201 ) without key open means, four elements  11  ( 202 ) with one key open means  36 , four elements  13  ( 203 ) without key open means, four elements  13  ( 204 ) with one key open means  36 , four elements  13  ( 205 ) with one key open means  35 , four elements  15  ( 206 ) without key open means and four elements  15  ( 207 ) with key open means  35 . 
     All elements  11 ,  13  and  15  shown at  FIG. 24  have the same inner surfaces  9  belong to the hollow sphere, like elements  11 ,  13  and  15  correspondingly, shown at  FIG. 25 . The corresponding elements  11 ,  13  and  15  shown at  FIGS. 24 and 25  are different by the outer surfaces which for all elements shown at  FIG. 24  are partial surfaces of the cube, while for all elements shown at  FIG. 25  are partial surfaces of the sphere. 
     All elements  2  for all embodiments can be made from the self-lubricated plastic material, thus provide smooth and easy rotation of all elements during assembling the three-dimensional puzzle  1 . The design of the puzzle  1  does not require a big clearance between elements  2  and between key open means  35  and  36  correspondingly. For example, the clearance between the elements  2  defined by the thickness of the conical surfaces  6  tends to a zero value preferably, thus prevent the loss of the shape stability of the group of elements  2  and not embarrassed the rotation in respect to other elements  2 . 
     The preferred embodiment of the present invention, where the 3D shaped body is a cube, can be assembled from the disassembled condition shown on  FIG. 22  to the assembled condition with the initial ordered orientation shown on  FIG. 17 , in the following way. 
     For the simplification for all elements  101 - 107  needed for assembly and shown on  FIG. 24 , the coordination means made as colored surfaces are not shown, but it is understood that each element  101 - 107  that will place in assembly corresponds to their own position and orientation in respect to the initial ordered three-dimension puzzle  1 . 
     At the first step ( FIG. 26 ), the element  102  placed between two elements  104 , thus the corresponding ledges  27  of the element  102  partially inserted into the corresponding grooves  31  of the elements  104 . After the corresponding rotation of the element  102  around the axis OX, the element  102  and two elements  104  form the group of elements  111  ( FIG. 26A ). At the same time, by the analogous way, the element  103  and two elements  107  form the group of elements  112  as well ( FIG. 26A ). 
     At the second step the group of elements  111  attached to the group of elements  112  ( FIG. 26B ), thus the corresponding ledges  27  of the group of elements  111  partially inserted into the corresponding grooves  31  of the group of elements  112 . After the corresponding rotation of the group of elements  111  around the axis OZ, the group of elements  111  and the group of elements  112  form the group of elements  113  ( FIG. 26C ). 
     At the third step ( FIG. 27 ), the element  101  placed between two elements  103 , thus the corresponding ledges  27  of the element  101  partially inserted into the corresponding grooves  31  of the elements  103 , while two elements  102  attached to the corresponding elements  103 , thus the corresponding ledges  27  of the elements  102  partially inserted into the corresponding grooves  31  of the elements  103 . After the corresponding rotation of the element  101  around the axis OX and the elements  102  around the axis OZ, the element  101 , two elements  102  and two elements  103  form the group of elements  114  ( FIG. 27A ). 
     At the next step the group of elements  114  attached to the group of elements  113  ( FIG. 27B ), thus the corresponding ledges  27  of the group of elements  114  partially inserted into the corresponding grooves  31  of the group of elements  113 . After the corresponding rotation of the group of elements  114  around the axis OY, the group of elements  113  and the group of elements  114  form the group of elements  115  ( FIG. 27C ). 
     At the fifth step ( FIG. 28 ), the element  102  placed between two elements  104 , thus the corresponding ledges  27  of the element  102  partially inserted into the corresponding grooves  31  of the elements  104 . After the corresponding rotation of the element  102  around the axis OX, the element  102  and two elements  104  form the group of elements  116  ( FIG. 28 ). At the same time, by the analogous way, the element  103  and two elements  107  form the group of elements  117  as well ( FIG. 28 ). 
     At the six step the group of elements  116  attached to the group of elements  117  ( FIG. 28A ), thus the corresponding ledges  27  of the group of elements  116  partially inserted into the corresponding grooves  31  of the group of elements  117 . After the corresponding rotation of the group of elements  116  around the axis OZ, the group of elements  116  and the group of elements  117  form the group of elements  118  ( FIG. 28A ). 
     At the next step the group of elements  118  attached to the group of elements  115  ( FIG. 28B ), thus the corresponding ledges  27  of the group of elements  115  partially inserted into the corresponding grooves  31  of the group of elements  118 . After the corresponding rotation of the group of elements  118  around the axis OY, the group of elements  115  and the group of elements  118  form the part of elements  19  ( FIGS. 17 ,  21  and  28 B). 
     At the eighths step ( FIGS. 29 and 29A ), the element  105  placed between two elements  106 , thus the corresponding ledges  27  of the element  105  partially inserted into the corresponding grooves  31  of the elements  106 . After the corresponding rotation of the element  105  around the axis OX, the element  105  and two elements  106  form the group of elements  119  ( FIG. 29 ). At the same time, by the analogous way, the element  101  and two elements  105  form the group of elements  120  as well ( FIG. 29A ). 
     At the ninth step the group of elements  120  attached to the group of elements  119  ( FIG. 29B ), thus the corresponding ledges  27  of the group of elements  120  partially inserted into the corresponding grooves  31  of the group of elements  119 . After the corresponding rotation of the group of elements  120  around the axis OY, the group of elements  119  and the group of elements  120  form the group of elements  121  ( FIG. 29B ). 
     At the next step ( FIG. 29C ), the element  105  placed between two elements  106 , thus the corresponding ledges  27  of the element  105  partially inserted into the corresponding grooves  31  of the elements  106 . After the corresponding rotation of the element  105  around the axis OX, the element  105  and two elements  106  form the group of elements  122  ( FIG. 29C ). 
     And at the last step ( FIG. 29D ), the group of elements  122  attached to the group of elements  121 , thus the corresponding ledges  27  of the group of elements  121  partially inserted into the corresponding grooves  31  of the group of elements  122 . After the corresponding rotation of the group of elements  122  around the axis OY, the group of elements  121  and the group of elements  122  form the part of elements  19 A ( FIGS. 17 ,  21  and  29 D). After the attaching the part of elements  19 A to the part of elements  19 , thus the key open means  35  of ledge  27  of the corresponding elements of the group of elements  19  inserted into the key open means  36  of grooves  31  of the corresponding elements of the group of elements  19 A, and the three-dimensional puzzle  1  became assembled to the initial ordered orientation. 
     It is understood that all other embodiments with the different 3D shaped body can be assembled in the same manner. 
     The three-dimensional puzzle  1  according to the present invention can be open by the separation for two spaced apart parts  19  and  19 A if the position and orientation of all elements  2  are correspond to the initial ordered orientation. Each of the polar elements  11  placed to the initial ordered position may be oriented by four different ways, but only one of them corresponds to the initial ordered orientation of the element  11 , thus provide the ability to open the three-dimensional puzzle  1  ( FIG. 17 ). For example, the positions of all elements  2  correspond to the initial ordered position, while the orientation of all elements  2 , except the polar elements  11 , also corresponds to the initial ordered orientation ( FIG. 30 ), thus the orientation of the polar elements  11  does not corresponds to initial ordered orientation. In that case, the three-dimensional puzzle  1  can not be opened and need further arrangement. But at the same time, such arrangement of the three-dimensional puzzle  1  corresponds to the final goal of the known puzzle like Rubik&#39;s Cube. Therefore the three-dimensional puzzle  1  according to the present invention has increased difficulty level, thus provides more attraction of the puzzle. 
     The design of the three-dimensional puzzle according to the present invention is simple, comprises the elements  2  only which can be easily and at low cost manufactured from the low cost waxy self-lubricated plastic material, for example from polypropylene. 
     The samples of the three-dimensional puzzle with different 3D shaped bodies like a sphere and a cube according to the present invention, were manufactured and tested, thus successfully prove the reliable achievement of the goal. 
     Therefore the three-dimensional puzzle according to the present invention provides a more attractive, compact, simple, reliable and less expensive design of the puzzle. 
     While the invention has been described with reference to various embodiments, it will be understood that these embodiments are only illustrative that the scope of invention is not limited to them. Many variations, modifications and improvements of the embodiments described are possible. Variations and modifications of the embodiments disclosed herein may be made based on description set forth herein, without departing from the scope and spirit of the invention as set forth in the following claims.