JP2016083182A - Three-dimensional puzzle - Google Patents

Abstract

PROBLEM TO BE SOLVED: To provide a three-dimensional puzzle capable of reducing sliding resistance in operation, and facilitating assembly after disassembly.SOLUTION: A three-dimensional puzzle 10 is composed of a ball-shaped core part 11 made of a steel ball, eight blocks 12 capable of sliding along a surface of the ball-shaped core part 11, and magnets 18 provided inside the eight blocks 12 each and disposed opposite to the ball-shaped core part 11. Four optional blocks 12 along a predetermined plane from among the eight blocks 12 can slidably rotate relative to four other blocks 12 with the ball-shaped core part 11 as the center.SELECTED DRAWING: Figure 2

Description

  The present invention relates to a three-dimensional puzzle used as a toy.

  Conventionally, a solid puzzle in which a plurality of blocks having different colors on the surface are assembled so as to be movable with each other and the colors of the outer surfaces are separated and then combined with the same color has been used as a toy. In addition, some of these three-dimensional puzzles are composed of a plurality of blocks that can be formed into a predetermined shape, and each block is divided into pieces and then returned to the predetermined shape after breaking the shape (see, for example, Patent Document 1). .

  This three-dimensional puzzle includes a base unit, a plurality of central blocks, a plurality of side blocks, and an edge block. The base unit is provided with six fixed connection columns, and a fixed base block is formed by connecting a central block to each fixed connection column. Further, the side block and the edge block are assembled so as to be rotatable between the central block, an inlet and an outlet are formed in a predetermined central block, and a hollow passage is formed in the side block and the edge block. . Then, by rotating the side block and the edge block, the entrance and the exit can be communicated with each other through the passage. In this state, when the sphere is inserted from the entrance, the sphere goes out from the exit through the passage.

Japanese Patent Application Laid-Open No. 2006-271569

  However, in the above-described three-dimensional puzzle, since the base unit, the central block, the side block, and the edge block are assembled in a complicatedly intertwined state, there is a problem that sliding resistance increases during operation. In addition, once the three-dimensional puzzle is disassembled, there is a problem that it is difficult to assemble the original puzzle.

  The present invention has been made to address the above-described problems, and an object thereof is to provide a three-dimensional puzzle that can reduce sliding resistance during operation and can be easily assembled after disassembly. . In the description of each constituent element of the present invention below, the reference numerals of corresponding portions of the embodiment are shown in parentheses in order to facilitate understanding of the present invention. The present invention should not be construed as being limited to the configurations of the corresponding portions indicated by the reference numerals of the forms.

  In order to achieve the above-described object, the structural features of the three-dimensional puzzle (10, 20) according to the present invention include a spherical core (11, 21) and a plurality of blocks that can slide along the surface of the spherical core. (12, 22, 23, 24) and a suction part (18, 28) provided on each of the plurality of blocks and arranged to face the spherical core, the plurality of blocks having a predetermined vertical surface and a predetermined Arbitrary vertical planes, other vertical planes orthogonal to the vertical planes, and predetermined horizontal planes orthogonal to both vertical planes, with the inner surfaces positioned respectively, and a predetermined vertical plane, another vertical plane, or any plurality along a predetermined horizontal plane The block can be slidably rotated around the spherical core with respect to other opposing blocks, and one of the spherical core and the attracting part is made of a magnetic material, and the other is made of a magnet. There is in being.

  A three-dimensional puzzle according to the present invention includes a spherical core portion, a plurality of blocks that can slide along the surface of the spherical core portion, and an adsorption portion that is provided in each of the plurality of blocks and is disposed to face the spherical core portion. And one of the spherical core portion and the attracting portion is made of a magnetic material, and the other is made of a magnet. For this reason, each block can slide along the surface of the spherical core while being attracted to the spherical core by the suction force of the spherical core and the suction portion. The movement of the block at this time is a set of a plurality of arbitrary blocks along a predetermined surface, with the spherical core portion as the center with respect to the other blocks opposed across the predetermined surface described above. It is a movement that slides and rotates.

  For this reason, a predetermined plane that becomes a boundary when a set of blocks slides relative to a plurality of other blocks is defined as a predetermined vertical plane, another vertical plane orthogonal to the predetermined vertical plane, and both vertical planes. The arrangement of each block can be changed by rotating a set of blocks while changing to any one of predetermined orthogonal horizontal planes. As a result, the arrangement of each block can be disassembled or returned to the original state. Further, since each block slides on the surface of the spherical core portion via the suction portion, the sliding resistance when operating the three-dimensional puzzle is reduced. Furthermore, even if the three-dimensional puzzle is disassembled into a spherical core part and a plurality of blocks, the blocks can be assembled to the spherical core part simply by making the adsorption part and the spherical core part face each other, so that the original state can be easily obtained. Can be returned to.

  In the present invention, for example, a virtual axis extending left and right passing through the center of the spherical core portion is extended to the X axis, a virtual axis extending front and rear passing through the center of the spherical core portion is extended to the Y axis, and extending vertically through the center of the spherical core portion. When the imaginary axis is the Z axis, if the predetermined vertical plane is a vertical plane including the X axis and a vertical plane parallel thereto, the other vertical planes are a vertical plane including the Y axis and a vertical plane parallel thereto. Thus, the predetermined horizontal plane is a horizontal plane orthogonal to the Z axis. These vertical and horizontal planes are virtual planes.

  Another structural feature of the three-dimensional puzzle according to the present invention is that the inner surface (13b, 23a, 24a) of the block is formed with a concave portion (14) and a convex portion (14a) having a sliding surface, respectively. When the inner surfaces of the blocks to be opposed face each other, the sliding surface is opposed to the concave portion of the one inner surface facing each other, and the convex portion of the other inner surface is engaged.

  According to the present invention, the positioning between the blocks can be accurately performed by engaging the concave portion and the convex portion. In addition, since the concave portion and the convex portion are engaged each time the three-dimensional puzzle is operated, a click feeling is generated, so that the user can feel the operation not only visually but also by tactile sensation. In addition, the shape of the recess in the present invention may be any shape such as a circle or a long and thin line. Moreover, it is preferable that the shape of a convex part is a shape provided with sliding surfaces, such as a spherical surface and a sector shape which can be lightly engaged with a recessed part.

  In short, when the convex part is in contact with the inner surface of the block, sliding between the blocks is not hindered by the slidable surface. As long as it causes the problem. Further, when the convex portion engages with the concave portion or when the engagement is released, the sliding surface is brought into contact with the inner surface of the concave portion, thereby reducing the sliding resistance. In addition, it is preferable to form a small flat portion having a width longer than the gap between the two blocks at the tip of the convex portion. According to this, when the convex portion passes across the gap between the two blocks, , Is prevented from being caught.

  Still another structural feature of the three-dimensional puzzle according to the present invention is that the concave portion is constituted by a groove (14) extending outward from the spherical core side on the inner surface of the block, and the convex portion is formed from the inside of the groove. It is formed by projecting to the outside of the groove, and the positions of the convex portions of the plurality of blocks from the end portions of the grooves are different from each other.

  According to the present invention, a concave portion made of a groove is formed on the inner surface of each block, a convex portion is formed in the concave portion, and the position of the convex portion from the end of the groove is made different. It does not occur that the convex portions of the inner surfaces facing each other come into contact with each other and the engagement with the concave portion is prevented. Moreover, since a convex part exists in the position along a groove | channel, when the inner surface which each block opposes exactly corresponds, it can comprise so that a convex part may engage with a groove | channel. In addition, about the convex part formed in three or four inner surfaces of the same block, the position from the edge part of a groove may be the same.

  Still another structural feature of the three-dimensional puzzle according to the present invention is that the spherical core portion is made of a magnetic material and the attracting portion is made of a magnet (18, 28).

  Since the spherical core is the center of the three-dimensional puzzle, each block needs to have a surface area that can be touched and needs to be relatively large, but the adsorption part only adsorbs to a part of the surface of the spherical core. Therefore, it can be configured with a small member. For this reason, a solid puzzle can be made cheap by comprising not a spherical core part but an adsorption | suction part with a magnet. Moreover, it is preferable to comprise the spherical core part in this case with a steel ball. Furthermore, it is preferable to provide a yoke material on the opposite side of the surface facing the spherical core in the adsorption portion. According to this, it is possible to amplify the suction force of the suction portion to the spherical core portion, and it is possible to prevent the block from being detached from the spherical core portion with a small force such as a light impact.

  Still another structural feature of the three-dimensional puzzle according to the present invention is that the overall shape is a legitimate body, the outer surfaces of the blocks located on the outer surfaces thereof are the same color, and the six outer surfaces of the cube are different from each other. This is because the blocks can be assembled as shown.

  According to the present invention, the three-dimensional puzzle can be configured like a so-called Rubik's cube. For this reason, it is possible to perform a puzzle so that the operation is started in a state where the colors of the four surfaces of the blocks forming the outer surfaces are disjoint and the colors of the outer surfaces become the same color.

  Still another structural feature of the three-dimensional puzzle according to the present invention is that a plurality of blocks are composed of 8 or 26 blocks.

  When a plurality of blocks are configured with eight blocks, any four blocks can be slid and rotated around the spherical core with respect to the other four blocks. The plane in which a block of a set slides relative to another set of four blocks includes a vertical plane that includes the X axis, a vertical plane that includes a Y axis that is orthogonal to the X axis, and an X axis and a Y axis. The arrangement of each block can be changed by changing to any one of the horizontal planes. When the plurality of blocks are composed of 26 blocks, the plane on which each set of 9 blocks slides with respect to the other 17 blocks is a vertical plane including the X axis and a vertical plane parallel to the vertical plane. By changing to a plane, a vertical plane including the Y-axis, a vertical plane parallel to the Y-axis, and a horizontal plane orthogonal to the Z-axis, the arrangement of each block can be changed.

It is the perspective view which showed the solid puzzle which concerns on 1st Embodiment of this invention. It is the disassembled perspective view which showed the solid puzzle which concerns on 1st Embodiment of this invention. It is the disassembled perspective view which showed the block. It is sectional drawing which showed the block. It is sectional drawing which showed the state which the groove and the positioning protrusion engaged. It is the perspective view which showed the solid puzzle which concerns on 2nd Embodiment of this invention. It is the schematic of the cross section which showed the three-dimensional puzzle which concerns on 2nd Embodiment of this invention.

(First embodiment)
Hereinafter, a first embodiment of the present invention will be described with reference to the drawings. 1 and 2 show a three-dimensional puzzle 10 according to the embodiment. The three-dimensional puzzle 10 is configured such that eight blocks 12 are assembled to the spherical core portion 11 so that the overall shape becomes a cube. The length of one side of the three-dimensional puzzle 10 is set to 45 mm. Moreover, the spherical core part 11 is comprised with the steel ball whose diameter is 15 mm. As shown in FIG. 3, the block 12 includes an inner surface portion 13, an outer surface portion 16, a magnet 18, and a yoke material 19. The inner surface portion 13 and the outer surface portion 16 are formed of a resin molded body.

  The inner surface portion 13 includes an inner surface portion main body 13a formed by assembling three substantially square plate-shaped inner surface forming portions 13b so as to be orthogonal to each other, and three inner surface forming portions on the outer surface of the inner surface portion main body 13a. A sliding recess 13c that extends along the curved surface of the spherical core 11 is formed at a portion where 13b intersects. Further, on the outer surface of each inner surface constituting portion 13b, a V-shaped groove 14 having a cross section extending from the sliding recess 13c in the diagonal direction of the inner surface constituting portion 13b is formed.

  A positioning protrusion 14 a that protrudes from the groove 14 is formed in the vicinity of the end of the groove 14 opposite to the sliding recess 13 c. The positioning projection 14a is formed in a plate shape along the width direction of the groove 14, and the tip surface of the portion protruding from the groove 14 is formed in a substantially arc shape. In addition, a small flat portion having a width longer than the gap between the two blocks 12 is formed at the tip of the positioning projection 14a. This prevents the protrusion 14a from being caught in the gap when the positioning protrusion 14a passes across the gap between the two blocks 12. The positioning protrusion 14a is preferably formed in accordance with the shape of the groove 14, and the contact area between the positioning protrusion 14a and the groove 14 is preferably increased. According to this, wear of the positioning protrusion 14a can be reduced.

  Further, the positioning protrusions 14 a formed on the inner surface constituent portions 13 b are arranged so that the positions from the end portions of the groove 14 are different from each other. However, the positioning protrusions 14a formed on the three inner surface constituting portions 13b of the same block 12 may have the same position from the end portion of the groove 14. In addition, the groove | channel 14 comprises the recessed part which concerns on this invention, and the convex part which concerns on this invention is comprised by the positioning protrusion 14a. In addition, a sliding curved surface is formed by the tip surface of the positioning protrusion 14a.

  A large boss portion 15 and three small boss portions 15b are formed on the inner surface of the inner surface portion main body 13a. The boss portion 15 is formed in a cylindrical shape extending so that the distance from the inner surface corner portion (a portion corresponding to the sliding recess 13c) of the inner surface portion main body 13a to each inner surface constituting portion 13b is the same. A hole 15a is formed between the recess 13c. For this reason, both ends of the boss 15 communicate with the outside. Further, the diameter of the hole 15 a is shorter than the inner diameter of the boss 15, and the peripheral edge of the hole 15 a protrudes to the inside of the boss 15. The boss portion 15 b is provided in the vicinity of a corner portion where the inner surface constituent portions 13 b on the inner surface of each inner surface constituent portion 13 b do not intersect with each other, and is formed in a cylindrical shape extending in parallel with the boss portion 15. In FIG. 3, the inner surface constituting portion 13b located below is hidden and cannot be seen.

  The outer surface portion 16 includes an outer surface portion main body 16a formed by assembling three square plate-shaped outer surface constituting portions 16b so as to be orthogonal to each other. A boss portion 17 and 3 are provided on the inner surface of the outer surface portion main body 16a. Two engaging projections 17b (see FIG. 4) are formed. Different color stickers 16c are attached to the outer surface of each outer surface constituting portion 16b. As the seals 16c, a total of four of six colors are used. Further, the boss portion 17 is formed in a cylindrical shape extending so that the distance from the inner surface corner portion of the outer surface portion main body 16a to each outer surface configuration portion 16b is the same, as shown in FIG. Is closed by the corner of the outer surface main body 16a, and the tip is opened. The inner peripheral surface of the boss portion 17 is formed in a step difference in which the diameter of the back end side portion is smaller than the diameter of other portions.

  The diameter of the internal large diameter side of the boss portion 17 is set to a size that allows the boss portion 15 to be fitted. When the boss portion 15 is fitted inside the boss portion 17, the boss portion The tip of 15 reaches a stepped portion 17 a formed on the inner peripheral surface of the boss portion 17, and the boss portion 15 is fixed to the boss portion 17 in this state. The engaging convex part 17b is formed in a rod shape having a size that can be fitted inside the boss part 15b. Each engaging convex part 17b is arrange | positioned in the position which can each be fitted in the inside of the boss | hub part 15b, when the boss | hub part 15 is fitted inside the boss | hub part 17. FIG. Although not shown in the drawing, the engaging convex portion 17b is located on the left and right corners of the lower surface of the outer surface constituting portion 16b located on the upper side and on the lower side 2 in the outer surface portion 16 shown in FIG. It is located at the lower end of the corner of the inner surface of the two outer surface constituting portions 16b.

  The magnet 18 is formed of a cylindrical neodymium magnet having a diameter of 5 mm and an axial length of 5 mm, and is accommodated on the hole 15 a side in the boss portion 15. Note that the diameter of the hole 15a is set to be shorter than 5 mm, and thus the magnet 18 cannot be removed from the hole 15a. Further, the yoke material 19 is made of an iron material, the diameter is slightly shorter than the diameter of the rear end portion of the boss portion 17, and the axial length is the boss portion 15 and the boss portion 17 together with the magnet 18. When accommodated in the space to be formed, it is formed to a length that fits without shaking.

  The block 12 in which each member is configured as described above is configured such that the boss 15 and the boss 17 are fitted in the boss 15 of the inner surface 13 with the magnet 18 and the yoke material 19 being inserted, and the boss The inner surface portion 13 and the outer surface portion 16 are fixed by fitting the portion 15b and the engaging convex portion 17b, and the seal 16c is attached to the outer surface of each outer surface constituting portion 16b. Then, the three-dimensional puzzle 10 shown in FIG. 1 is formed by combining the sliding concave portions 13c of the respective blocks 12 with the peripheral surface of the spherical core portion 11 and combining the eight blocks 12 into a cube.

  In this case, each block 12 is maintained in a cubic shape in a state in which the magnet 18 is attracted to the spherical core portion 11 and is slidable with respect to the spherical core portion 11. At that time, the positioning protrusions 14a and the grooves 14 formed on the inner surface constituting portion 13b facing each other in the adjacent block 12 are engaged with each other and maintained in a stable state. In this initial state, the colors of the seals 16c attached to the four outer surface constituent portions 16b located on each surface of the three-dimensional puzzle 10 are the same, and different colors appear for each surface of the three-dimensional puzzle 10. To do.

  As shown in FIG. 1, the three-dimensional puzzle 10 configured in this way includes the X axis when the horizontal direction is the X axis, the front and rear direction is the Y axis, and the vertical direction is the Z axis. The four blocks 12 positioned on the front side and the block 12 positioned on the rear side can be rotated with respect to the spherical core portion 11 with respect to the vertical plane. Further, the four blocks 12 positioned on the left side and the block 12 positioned on the right side can be rotated around the spherical core portion 11 with the vertical plane including the Y axis as a boundary. Further, with the horizontal plane including the X-axis and the Y-axis, that is, the plane orthogonal to the Z-axis, the four blocks 12 positioned on the upper side and the block 12 positioned on the lower side are centered on the spherical core portion 11. Can rotate with each other.

  For this reason, when the three-dimensional puzzle 10 is used, first, any four blocks 12 that can be divided into the front, back, left, and right, respectively, are set as a set and rotated with respect to the other set of four blocks 12. As a result, the color of each surface of the three-dimensional puzzle 10 is separated. From that state, the arbitrary four blocks 12 are set as a set again and rotated with respect to the other set of four blocks 12 so that the colors of the respective faces of the three-dimensional puzzle 10 match. The puzzle ends when the color of each surface of the three-dimensional puzzle 10 matches.

  When the three-dimensional puzzle 10 is rotated, if the inner surfaces of the blocks 12 coincide with each other, as shown in FIG. 5, the positioning protrusions 14a and the grooves 14 are engaged with each other, and a “click” sound is heard. Because vibration is transmitted, you can feel the click feeling. FIG. 5 shows a state in which the positioning projection 14a of the right inner surface constituting portion 13b is engaged with the groove 14 of the left inner surface constituting portion 13b. The positioning protrusion 14a is engaged with the groove 14 of the right inner surface constituting portion 13b.

  As described above, the three-dimensional puzzle 10 according to the present embodiment includes the spherical core portion 11 made of a steel ball and the eight blocks 12 that can slide along the surface of the spherical core portion 11 through the sliding recess 13c. It has. The eight blocks 12 are each provided with a magnet 18 disposed to face the spherical core portion 11. For this reason, each block 12 can slide along the surface of the spherical core portion 11 while being attracted to the spherical core portion 11 by the attractive force of the spherical core portion 11 and the magnet 18. The movement of the block 12 at this time is a movement in which arbitrary four blocks 12 form a set and slide and rotate with respect to the other four blocks 12 around the spherical core portion 11.

  According to this, the arrangement of each block 12 can be disassembled or returned to the original state. Moreover, since each block 12 slides on the surface of the spherical core part 11 via the magnet 18, the sliding resistance when operating the three-dimensional puzzle 10 becomes small. Further, since each block 12 is assembled to the spherical core 11 by the attractive force of the magnet 18, even if the three-dimensional puzzle 10 is disassembled into the spherical core 11 and the eight blocks 12, the magnet of each block 12. Each block 12 can be assembled to the spherical core 11 simply by making 18 and the spherical core 11 face each other in order. For this reason, the decomposed spherical core 11 and the eight blocks 12 can be easily returned to the original three-dimensional puzzle 10 state.

  In addition, a groove 14 and a positioning protrusion 14a positioned in the groove 14 are formed on the inner surface constituting portion 13b that constitutes a surface where the adjacent blocks 12 face each other. When the two inner surface constituting portions 13b face each other so as to coincide with each other, the positioning protrusion 14a of the other inner surface constituting portion 13b engages with the groove 14 of the one inner surface constituting portion 13b. As a result, a click feeling is generated each time the three-dimensional puzzle 10 is operated, so that not only visual observation but also tactile feeling can be felt, and positioning between the blocks 12 can be accurately performed. Furthermore, since the yoke material 19 is provided on the opposite side of the surface of the magnet 18 that faces the spherical core 11, the attractive force of the magnet 18 to the spherical core 11 can be amplified.

(Second Embodiment)
6 and 7 schematically show a three-dimensional puzzle 20 according to the second embodiment of the present invention. The three-dimensional puzzle 20 is configured such that eight blocks 22, twelve blocks 23, and six blocks 24 are assembled to the spherical core portion 21 so that the overall shape becomes a cube. The three-dimensional puzzle 20 is assembled so that a total of nine blocks of four blocks 22 and 23 and one block 24 appear on each surface, and the length of each side is set to about 60 mm. In addition, the block 22 is located at each of the eight corners of the three-dimensional puzzle 20, and the block 23 is the center of the corner portion where the two surfaces of the three-dimensional puzzle 20 intersect (a portion sandwiched between the two blocks 22) The block 24 is located at the center of each of the six faces of the three-dimensional puzzle 20.

  The spherical core portion 21 is composed of a steel ball having a diameter of about 40 mm. Moreover, the block 22 is provided with the inner surface part (not shown) which has three inner surface structure parts and the outer surface part which has three outer surface structure parts 22a like the block 12 mentioned above, and a magnet ( Although not shown in the figure, the same magnet as that shown by reference numeral 28 in FIG. That is, the block 22 removes the yoke material 19 from the block 12, and the boss portion 15 of the inner surface portion 13 and the boss portion 17 of the outer surface portion 16 have a shape that can accommodate the magnet 28, and is further provided on the inner surface portion 13. The sliding concave portion 13 c is formed in a shape so as to be along the surface of the spherical core portion 21. For this reason, the three inner surface constituent portions of the inner surface portion of the block 22 are respectively formed with V-shaped cross-section grooves and positioning protrusions similar to the groove grooves 14 and the positioning protrusions 14a. The configuration of other parts of the block 22 is the same as that of the block 12.

  The block 23 includes an inner surface portion having four inner surface constituting portions 23a and an outer surface portion having two outer surface constituting portions 23b, and a magnet 28 is provided therein. Of the four inner surface constituting portions 23a, the two inner surface constituting portions 23a facing the block 22 have the same shape as the inner surface constituting portion of the block 22 (a shape close to the block 23 shown in FIG. The remaining two inner surface constituting portions 23a are formed in the same shape as the inner surface constituting portion 24a of the block 24 (similar to the block 24 shown in FIG. The recess 24c is formed slightly smaller than that in FIG. The outer surface constituting portion 23 b is formed in a square having the same size as the outer surface constituting portion 22 a of the block 22.

  Although not shown, the two inner surface constituting portions 23a facing the block 22 are formed with the same shape groove facing the groove of the block 22, and the positioning protrusion of the block 22 is formed in the groove. Positioning protrusions are formed by changing the distance from the spherical core portion 21. On the two inner surface constituting portions 23a facing the block 24, a groove extending outward from the sliding recess 23c through the center of the inner surface forming portion 23a and a positioning protrusion positioned in the groove are formed. . That is, in the state of FIG. 7, the groove formed in the two inner surface constituting portions 23 a facing the block 22 extends in an oblique direction, whereas it is formed in the two inner surface constituting portions 23 a facing the block 24. The groove is extended in the vertical direction or the horizontal direction.

  The block 24 includes an inner surface portion having four inner surface constituting portions 24a and an outer surface portion having one outer surface constituting portion 24b, and a magnet 28 is installed therein. All of the four inner surface constituting portions 24 a are formed in the same shape as the opposing inner surface constituting portion 23 a in the block 23. Each inner surface constituting portion 24a is formed with a groove having a shape opposed to the groove formed in the inner surface constituting portion 23a opposed to the block 23, and the positioning protrusion of the block 23 and the spherical core are formed in the groove. Positioning protrusions are formed by changing the distance from the portion 21. Colored seals (not shown) are attached to the outer surface constituent portions 22a, 23b, and 24b of the blocks 22 to 24, respectively. FIG. 6 shows a combination of 26 blocks 22 to 24 in the form of a cube in a state in which the sliding recesses 23c and 24c of the respective blocks 22 to 24 are combined with the peripheral surface of the spherical core portion 21. A three-dimensional puzzle 20 is formed.

  In this case, each of the blocks 22 to 24 is maintained in a cubic shape in a state where the magnet 28 is attracted to the spherical core portion 21 and is slidable with respect to the spherical core portion 21. Further, the positioning projections and the grooves formed on the inner surface constituting portions 23a and 24a facing each other of the adjacent blocks 22 to 24 are engaged with each other, and are maintained in a stable state. Moreover, in the initial state, the colors of the stickers attached to the nine outer surface components 22a, 23b, and 24b located on each surface of the three-dimensional puzzle 20 are the same, and each surface of the three-dimensional puzzle 20 has a different color. appear.

  The three-dimensional puzzle 20 configured in this way has nine blocks 22 to 24 positioned on the front side or 9 positioned on the rear side with two vertical planes parallel to the vertical plane including the X axis in FIG. One block 22-24 can mutually rotate centering on the spherical core part 21 with respect to the other blocks 22-24. In addition, the nine blocks 22 to 24 located on the left side or the nine blocks 22 to 24 located on the right side from the two vertical planes parallel to the vertical plane including the Y axis are changed to the other blocks 22 to 24. On the other hand, they can rotate around the spherical core 21. Further, the nine blocks 22 to 24 located on the upper side or the nine blocks 22 to 24 located on the lower side with respect to the other blocks 22 to 24 with respect to two horizontal planes orthogonal to the Z axis are spherical cores. The portions 21 can be rotated around each other.

  When using the three-dimensional puzzle 20, first, a set of nine blocks 22 to 24 that can be divided into front and rear, left and right, and upper and lower, respectively, is rotated with respect to the other blocks 22 to 24 as a set. The color of each face of the puzzle 20 is broken apart. From that state, any nine blocks 22 to 24 are set as a set and rotated with respect to the other blocks 22 to 24 so that the colors of the respective faces of the three-dimensional puzzle 20 match. The puzzle ends when the color of each surface of the three-dimensional puzzle 20 matches. As described above, the three-dimensional puzzle 20 can be used in the same manner as the three-dimensional puzzle 10 described above. However, since the number of blocks 22 to 24 is larger, the three-dimensional puzzle 20 is more complicated than the three-dimensional puzzle 10 and enables a game with a high difficulty level. Become. Other functions and effects of the three-dimensional puzzle 20 are the same as the functions and effects of the three-dimensional puzzle 10 described above.

  Moreover, the three-dimensional puzzle according to the present invention is not limited to the above-described embodiment, and can be changed as appropriate. For example, in the above-described embodiment, the operation is started with the three-dimensional puzzles 10 and 20 made into cubes and the four outer surfaces of the blocks forming the outer surfaces are separated, and the colors of the outer surfaces are the same color. However, the three-dimensional puzzle according to the present invention is not limited to this. For example, a passage may be formed in each block, and the passage may be used as a puzzle that communicates the passage by operation. Alternatively, the outer shape may be a predetermined shape and the shape may be separated. Later, it may be used as a puzzle that returns to its original shape by an operation.

  Further, instead of the color of the surface of the three-dimensional puzzle 10, 20, a figure, a number arranged in a certain order, or the like may be used. The external shape of the three-dimensional puzzles 10 and 20 is not limited to a cube, and can be various shapes. Further, the number of blocks is not limited to 8 or 26, but may be more. Even in this case, since each block is assembled to the spherical core portion via the spherical core portion and the attracting portion made of a magnetic body and a magnet, the structure is not complicated. Moreover, in embodiment mentioned above, although the spherical core parts 11 and 21 are comprised with the steel ball and the adsorption part is comprised with the magnets 18 and 28, the spherical core parts 11 and 21 are comprised with the magnet, and the adsorption part is comprised. You may comprise steel. Furthermore, the spherical core parts 11 and 21 may be made of a material having magnetism other than steel balls, and when the spherical core parts 11 and 21 are made of magnets, the attracting part is provided with magnetism other than steel. It may be composed of different materials.

  Further, in the above-described embodiment, the concave portion is constituted by the groove 14 and the like, and the convex portion is constituted by the plate-like positioning projection 14a and the like whose tip surface is formed in an arc shape. The concave portion may be formed of a circular concave portion, and the convex portion may be formed of a circular convex portion. Furthermore, the yoke material 19 provided on one end side of the magnet 18 can be omitted. Further, the blocks 22 to 24 of the three-dimensional puzzle 20 may be enlarged and a yoke material may be provided on one end side of the magnet 28. Furthermore, the configuration of the other parts of the three-dimensional puzzle according to the present invention can be implemented with appropriate modifications within the technical scope of the present invention.

  10, 20 ... Solid puzzle, 11, 21 ... Spherical core, 12, 22, 23, 24 ... Block, 13b, 23a, 24a ... Inner surface component, 14 ... Strip groove, 14a ... Positioning protrusion, 18, 28 ... Magnet .

Claims (6)

A spherical core,
A plurality of blocks slidable along the surface of the spherical core;
An adsorption portion provided in each of the plurality of blocks and disposed opposite to the spherical core portion,
The plurality of blocks are arranged with their inner surfaces positioned on a predetermined vertical surface, another vertical surface orthogonal to the predetermined vertical surface, and a predetermined horizontal surface orthogonal to the two vertical surfaces, and the predetermined vertical surface Any other plurality of blocks along the other vertical surface or the predetermined horizontal plane can be slidably rotated around the spherical core portion with respect to the other plurality of opposing blocks,
One of the spherical core part and the attracting part is made of a magnetic material, and the other is made of a magnet.   The inner surface of each of the plurality of blocks is formed with a concave portion and a convex portion having a sliding surface, and when the inner surfaces of the adjacent blocks face each other, the sliding in the concave portion of the one inner surface facing each other The three-dimensional puzzle according to claim 1, wherein the convex portions on the other inner surface are engaged with the surfaces facing each other.   The concave portion is formed by a groove extending outward from the spherical core portion side on the inner surface of the block, the convex portion is formed by protruding from the inside of the groove to the outside of the groove, and the plurality The three-dimensional puzzle according to claim 2, wherein the positions of the convex portions of the blocks from the ends of the grooves are different from each other.   The three-dimensional puzzle according to any one of claims 1 to 3, wherein the spherical core portion is made of a magnetic material, and the attracting portion is made of a magnet.   2. The block can be assembled so that the overall shape is a legitimate body, and the outer surfaces of the blocks located on the outer surfaces thereof have the same color, and the six outer surfaces of the cube have different colors. The solid puzzle as described in any one of thru | or 4.   The three-dimensional puzzle according to any one of claims 1 to 5, wherein the plurality of blocks are configured by 8 or 26 blocks.

Images