JP3113955U - Assembled spherical volume wood - Google Patents

Abstract

An object of the present invention is to realize the assembly of four-sided and three-sided pyramids with different shapes, quantities, angles, and difficulty levels of building blocks to enhance intelligence and enhance the entertainment effect.
SOLUTION: Twelve blocks of different shapes are provided, each building block is a combination of 3 to 5 spheres, the total number of spheres is 55, 5 squares on each side, and 25 lowermost layers. A four-sided pyramid is assembled according to the arrangement. In addition, three sets of the same building blocks, a total of 36 blocks, and a total of 165 spheres are combined, and a pyramid having a three-sided structure is combined with an array of nine triangles on three sides and a total of 45 lowermost layers. .
[Selection] Figure 8

Description

  The present invention relates to an assembly-type spherical volume tree, and in particular, assembles four-sided and three-sided pyramids (cone-shaped three-dimensional modeling) with an arrangement of a plurality of different blocks of 3 to 5 spheres. ) It relates to a game-type assembly-type spherical volume tree.

The difficulty of playing the conventional “puzzle” and “tamamram” is different, but it is limited to one kind of heart game. There are many types of “graphic puzzle” changes, but since it is limited to a plane, the difficulty cannot be raised. For this reason, the inventor of the present application has applied to each (user's) level and each age group, and has developed a combination block having a three-dimensional change effect while being flat. This combination block is described in Patent Document 1. In this building block, 19 blocks and a pedestal are provided, and each block is assembled in a single layer or a plurality of layers on the pedestal, and a three-dimensional structure such as a conical pyramid is assembled into four surfaces (structures).
Taiwan No. 398313 promulgated on July 11, 2000 “Combined modeling blocks capable of changing 60 °, 90 ° and 120 °”

  However, in the above-mentioned conventional building blocks, the pyramid (cone-shaped solid modeling) is simply assembled into a four-sided structure, and it is not considered to combine the pyramids into three (structured) structures. There is a problem that it cannot be assembled. Since the number and angle of building blocks differ between the 4th and 3rd surfaces, the difficulty of combination also differs. In particular, since the number of blocks when assembling a pyramidal pyramid into a three-sided structure is greater than four, the difficulty is very high.

  The present invention has been made in view of the above-described conventional problems, and the three-dimensional structure (pyramid) of a cone shape is changed from a four-surface configuration having a different shape, quantity, angle, and combination difficulty of a building block to a three-surface configuration. It is an object of the present invention to provide an assembled spherical volume tree that can be used.

  In order to solve the above-mentioned problem, the assembly-type spherical volume tree of the present invention includes twelve blocks having different shapes, and each block is a combination of three to five spheres, and the total number of spheres of twelve blocks is 55. It is a configuration of pieces. The shape of building blocks is as follows. The building block A forms an “L” shape from four spheres, the first to third spheres are connected in the horizontal direction from right to left, and the fourth and third are connected in the vertical direction. Building block B forms a “P” shape from five spheres, the first to third spheres are connected horizontally from right to left, and the fourth and fifth are connected horizontally from right to left. However, the first, second, fourth, and fifth spheres are connected vertically. The building block C forms an “L” shape from five spheres, the first to fourth spheres are connected in the horizontal direction from right to left, and the fifth and fourth are connected in the vertical direction. The building block D forms a “┴” shape from five spheres, the first to fourth spheres are connected in the horizontal direction from right to left, and the fifth and third are connected in the vertical direction. Block E is made up of five spheres, the first to third spheres are connected horizontally from right to left, the fourth and first are vertical, the fourth and fifth are horizontal from left to right Articulated. The building block F forms a “┌” shape from three spheres, the first and second spheres are connected in the horizontal direction from right to left, and the third and second spheres are connected in the vertical direction. Building blocks G form a “┌” shape from five spheres, the first to third spheres are connected horizontally from right to left, and the fifth and fourth spheres are connected vertically in the vertical direction. To do. The building block H forms a “W” shape from five spheres, the first and second spheres are vertically connected vertically, the second and third are horizontally connected from right to left, The fourth and fifth spheres are connected vertically in the vertical direction, and the fourth and fifth spheres are connected horizontally from right to left. Block I forms a “よ り” shape from five spheres, the first to third spheres are connected horizontally from right to left, and the fourth, third and fourth spheres are vertically oriented. The fifth and first are connected in the vertical direction. The building block J forms a “-” shape from four spheres, and the first to fourth spheres are connected horizontally from right to left. The building block K forms a “ro” shape from four spheres, the first and second spheres are connected horizontally from right to left, and between the first, second, third, and fourth spheres. Are connected vertically. The building block L forms a “ten” shape from five spheres, the first to third spheres are connected horizontally from right to left, and the fourth sphere is connected to the second sphere vertically. The fifth sphere is directly connected below the second sphere.

  Using these twelve blocks, five of the four lowest layers are arranged, and 25 conical pyramids of the lowest layer are combined into four sides. In this case, the above 12 blocks are arranged in four positions on each of the localization concave holes, and conical pyramids are combined into four sides on all 25 square arrangement bases. In addition, the above 12 blocks are configured by combining a single-layered rectangle on a pedestal of rectangular arrangements of 11 vertical, 5 horizontal, and 55 horizontal positioning holes. Further, the above 12 blocks are configured by combining single-layered triangles with pedestals of 55 triangular arrangements, each having 10 positioning recesses from three sides. Furthermore, the 12 blocks described above are combined with a single-layered thin plate shape on 55 locating concave holes and one convex column base. The twelve blocks are combined by one of the following methods, and the tenons are fitted into the tenon between the spheres, and the spheres are bonded together by integral injection molding.

  Further, the assembling-type spherical volume tree of the present invention arranges the seven blocks of A, B, C, F, I, J, and K in a total of 30 spheres, each of which is arranged in four sides, and the total number of bottom layers is 16 Combine four conical pyramids on four sides. In this case, seven blocks are arranged in four sides on the localization concave holes, and a total of 16 conical pyramids in the lowest layer are combined on four sides. The seven blocks are combined with a single-layer rectangle on a pedestal of six rectangular, five horizontal, and a total of thirty rectangular arrangements in the localization concave hole.

  Furthermore, the assembly-type spherical volume tree of the present invention is a conical shape with 9 blocks on each side and 45 layers on the bottom layer in total of 36 blocks and 165 balls in total, using three sets of the above 12 blocks. Combine the pyramids of the three sides. In this case, the six blocks are combined in three positions with conical pyramids on the pedestal of 45 in the bottom layer, with nine sides on each side, and 45 pedestals in the lowest layer.

  The assembly-type spherical volume tree of the present invention has the above-described configuration, and arranges twelve different types of blocks on three different pedestals and combines them into a single-layer square, a single-layer rectangle, and a single-layer triangle. In addition, it can be assembled on a pedestal into a four-sided pyramid. By arranging twelve blocks with different shapes on the pedestals with different shapes as described above, the way of playing to change from a planar arrangement to a three-dimensional arrangement can achieve the effects of multiple change and ability development.

  Also, the assembly-type spherical volume tree of the present invention arranges seven blocks out of twelve blocks on a pedestal and assembles them into a four-sided pyramid shape (conical three-dimensional model) or a single-layer rectangle. be able to. Thereby, the choice of how to play the mind game is increased, and more imaginary space can be given to the game player.

  Further, the assembly-type spherical volume tree of the present invention can be assembled into a three-sided pyramid shape (conical three-dimensional modeling) by arranging the three sets of twelve different shapes of blocks on a pedestal. This way of playing is different in angle and quantity of blocks, so the difficulty becomes high and the way of playing blocks can be maximized.

  Therefore, according to the present invention, it is possible to realize the assembling of a pyramid having a four-sided structure and a three-sided structure having different building shapes, quantities, angles, and difficulty levels, thereby enhancing intelligence ability and enhancing an entertainment effect.

  Hereinafter, embodiments of the present invention will be described with reference to the drawings. As shown in FIG. 1, this assembling-type spherical volume tree consists of 12 different blocks A, B, C, D, E, F, G, H, I, J, K, and L. These blocks are The total number of 12 building blocks is composed of 55 pieces, each of which is a combination of 3 to 5 spheres 10.

  The shape of each building block is as follows. The blocks 10 are joined to each other between the spheres 10 by fitting the mortise 11 and the mortise 12, by bonding (for example, Higer bond) fixing, or by integral injection molding.

  The building block A forms an “L” shape from four spheres, the first to third spheres are connected in the horizontal direction from right to left, and the fourth and third are connected in the vertical direction. Building block B forms a “P” shape from five spheres, the first to third spheres are connected horizontally from right to left, and the fourth and fifth are connected horizontally from right to left. However, the first, second, fourth, and fifth spheres are connected vertically. The building block C forms an “L” shape from five spheres, the first to fourth spheres are connected in the horizontal direction from right to left, and the fifth and fourth are connected in the vertical direction. The building block D forms a “┴” shape from five spheres, the first to fourth spheres are connected in the horizontal direction from right to left, and the fifth and third are connected in the vertical direction. Block E is made up of five spheres, the first to third spheres are connected horizontally from right to left, the fourth and first are vertical, the fourth and fifth are horizontal from left to right Articulated. The building block F forms a “┌” shape from three spheres, the first and second spheres are connected in the horizontal direction from right to left, and the third and second spheres are connected in the vertical direction. Building blocks G form a “┌” shape from five spheres, the first to third spheres are connected horizontally from right to left, and the fifth and fourth spheres are connected vertically in the vertical direction. To do. The building block H forms a “W” shape from five spheres, the first and second spheres are vertically connected vertically, the second and third are horizontally connected from right to left, The fourth and fifth spheres are connected vertically in the vertical direction, and the fourth and fifth spheres are connected horizontally from right to left. The building block I forms a “┌” shape from five spheres, the first to third spheres are connected horizontally from right to left, the fourth and third spheres are connected vertically, The fifth and first are connected vertically. The building block J forms a “-” shape from four spheres, and the first to fourth spheres are connected horizontally from right to left. The building block K forms a “ro” shape from four spheres, the first and second spheres are connected horizontally from right to left, and between the first, second, third, and fourth spheres. Are connected vertically. The building block L forms a “ten” shape from five spheres, the first to third spheres are connected horizontally from right to left, and the fourth sphere is connected to the vertical direction of the second sphere. The fifth sphere is directly connected below the second sphere.

  The twelve blocks are arranged on differently shaped pedestals, arranged in different planes or three-dimensional forms, and further different planes or three-dimensional forms can be formed by arranging three sets of the same blocks. Further, by arranging 7 blocks out of 12 blocks, different planes or three-dimensional forms are formed. The plane or three-dimensional form is as follows.

  As shown in FIG. 2, twelve blocks can be arranged on a pedestal 20 in a conical pyramid with a four-sided configuration. On this pedestal 20, there are provided a total of 25 positioning concave holes 21 in a square, five on each side. In this case, the shape of the localization concave hole 21 is preferably circular when viewed from above, and the cross section is preferably semicircular.

  As shown in FIG. 3, twelve blocks can be combined on a pedestal 20 into a single-layer rectangle. On this pedestal 20, there are 11 rectangular holes, 5 horizontal holes, and 55 concave holes 22 in total. In this case, the shape of the localization concave hole 21 is preferably circular when viewed from above, and the cross section is preferably semicircular.

  2 and 3 can be implemented on the same rectangular base 20. The pedestal 20 is composed of one upper lid 23 and one lower pedestal 24, and positioning recesses 21 and 22 are provided on the upper lid 23 and the lower pedestal 24, respectively. Thereby, the game player can assemble a four-sided pyramid and a single-layer rectangle separately on the upper lid 23 and the lower cradle 24.

  As shown in FIG. 4, twelve blocks can be combined on a pedestal 30 in a four-sided conical pyramid. On this pedestal 30, there are provided a total of 25 positioning concave holes 31 each having a square shape, five on each side. In this case, the shape of the localization concave hole 31 is a circular depression.

  As shown in FIG. 5, twelve blocks can be combined into a single-layer triangle on the pedestal 30. On this pedestal 30, there are provided a total of 55 positioning recessed holes 32 in a triangular shape, 10 on three sides. In this case, the shape of the localization concave hole 32 is a circular depression.

  4 and 5 can be implemented on the same semicircular pedestal 30. FIG. The pedestal 30 has one upper lid 33 and one lower pedestal 34 coupled to each other, and positioning concave holes 31 and 32 are provided on the upper lid 33 and the lower pedestal 34, respectively. Thereby, the game player can combine a pyramid having a four-sided structure and a single-layer triangle separately on the upper lid 33 and the lower cradle 34.

  As shown in FIG. 6, twelve blocks can be combined on a pedestal 40 in a conical pyramid with a four-sided configuration. On this pedestal 40, there are provided 25 positioning recesses 41 in a square shape, 5 on each side and 25 in total. In this case, the shape of the localization concave hole 41 is a circular depression.

  As shown in FIG. 7, the twelve blocks can be combined on the pedestal 40 in a single-layer thin plate shape. On the pedestal 40, 55 localization holes 42 and one convex column 43 are provided. In this case, the convex column 43 is fixed by an insertion hole (not shown) integrally formed with the pedestal 40 or previously installed in the pedestal 40.

  The arrangement of blocks shown in FIGS. 6 and 7 can be implemented on the same thin plate base 40. A positioning concave hole 41 is provided on the top surface of the base 40, and 12 blocks can be combined with a pyramid having a four-surface structure on this surface. On the back surface of the pedestal 40, 55 localization recessed holes 41 and one convex column 43 are provided, and 12 blocks can be combined with a thin plate shape on this surface.

  As shown in FIG. 8, three sets of 12 blocks A to L in FIG. 1 above, a total number of blocks of 36 (12 × 3 sets = 36), a total number of spheres of 165 (55 × 3 sets = 165) In this configuration, nine conical pyramids, three on each side, and a total of 45 conical pyramids in the lowest layer can be combined into a three-surface configuration. In this case, the 36 blocks are arranged on a pedestal 50 having a total of 45 localization recessed holes 51, each having nine triangles on three sides, and arranged in a triangle.

  As shown in FIG. 9, seven blocks of A, B, C, F, I, J, and K shown in FIG. 1 and a total of 30 spheres 10 are arranged in four squares on four sides, A four-sided pyramid can be combined. In this case, the seven blocks are arranged on a pedestal 60 having a total of 20 positioning holes 41, four on each side of a square, and can be assembled into a four-sided pyramid.

  As shown in FIG. 10, when the seven blocks are arranged in the positioning concave holes 62 arranged on the pedestal 60 in a rectangular arrangement of six vertically and five horizontally, a single layer is formed. Can be arranged in a rectangle.

  9 and 10 can be implemented on the same thin plate base 60. FIG. A stereotaxic hole 61 is provided on the top surface of the pedestal 60, and seven blocks can be combined in this plane with a conical pyramid having a four-sided configuration. Thirty localization concave holes 62 are provided on the back surface of the pedestal 60, and seven blocks can be combined into a single-layer rectangle on this surface.

  The present invention has been described in detail with reference to the drawings. However, a trader can make various modifications within the scope of the present invention, and such modifications are included in the scope of the present invention.

The disassembled perspective view which shows the structure of 12 blocks of the assembly-type spherical volume tree in one embodiment of this invention The partially exploded perspective view which shows the 1st three-dimensional modeling by the building block and the base of the embodiment The partially exploded perspective view which shows the 2nd three-dimensional modeling by the building block and pedestal of the embodiment The partially exploded perspective view which shows the 3rd solid modeling by the building block and pedestal of the embodiment The partially exploded perspective view which shows the 4th three-dimensional modeling by the building block and pedestal of the embodiment Partially exploded perspective view showing fifth solid modeling by blocks and pedestals of the embodiment The partially exploded perspective view which shows the 6th solid modeling by the building block and the base of the embodiment The partially exploded perspective view which shows the 7th solid modeling by the building block and the base of the embodiment The partially exploded perspective view which shows the 8th three-dimensional modeling by the building block and the base of the embodiment The partially exploded perspective view which shows the 9th solid modeling by the building block and the base of the embodiment

Explanation of symbols

DESCRIPTION OF SYMBOLS 10 Sphere 11 Mortise 12 Mortise 20 Pedestal 21, 22 Stereotaxic concave hole 23 Upper lid 24 Lower pedestal 30 Pedestal 31, 32 Stereotaxic concave hole 33 Upper lid 34 Lower pedestal 40 Pedestal 41, 42 Stereotaxic concave hole 50 Pedestal 51 Recessed hole for localization 60 Pedestal 61, 62 Recessed hole for localization

Claims (11)

12 blocks of different blocks A, B, C, D, E, F, G, H, I, J, K, L, each block comprising a combination of 3-5 spheres, The total number is composed of 55,
The building block A is formed in an “L” shape by four spheres, the first to third spheres are connected horizontally from right to left, and the fourth sphere is connected to the third sphere in the vertical direction. And
The building block B is formed in the shape of “P” by five spheres, the first to third spheres are connected in the horizontal direction from right to left, and the fourth and fifth spheres are in the horizontal direction from right to left. And connected vertically to the first and second spheres,
The building block C is formed in an “L” shape by five spheres, the first to fourth spheres are connected horizontally from right to left, and the fifth sphere is connected to the fourth sphere in the vertical direction. And
The building block D is formed by five spheres in the shape of “┴”, the first to fourth spheres are connected horizontally from right to left, and the fifth sphere is connected vertically to the third sphere. And
The building block E is formed by five spheres, the first to third spheres are connected in the horizontal direction from right to left, the fourth sphere is connected to the first sphere in the vertical direction, and the fourth and fifth spheres are connected. The sphere is connected horizontally from left to right,
The building block F is formed by three spheres in the shape of “┌”, the first and second spheres are connected horizontally from right to left, and the third and second spheres are connected vertically.
The building block G is formed in the shape of “┌” by five spheres, the first to third spheres are connected in the horizontal direction from right to left, and the fifth and fourth spheres are vertically aligned in the vertical direction. Articulated,
The building block H is formed in the shape of “W” by five spheres, the first and second spheres are connected vertically in the vertical direction, the second and third are connected in the horizontal direction from right to left, The third and fourth spheres are connected vertically in the vertical direction, and the fourth and fifth spheres are connected horizontally from right to left,
The building block I is formed in the shape of “に よ り” by five spheres, the first to third spheres are connected horizontally from right to left, and the fourth sphere is perpendicular to the third sphere. And the fifth sphere is vertically connected to the first sphere,
The building block J is formed in a shape of “-” by four spheres, and the first to fourth spheres are connected in a horizontal direction from right to left.
The building block K is formed in the shape of “B” by four spheres, and the first and second spheres are connected in the horizontal direction from right to left, and the first, second, third, and fourth spheres. The space is vertically connected,
The building block L is formed in a “ten” shape by five spheres, the first to third spheres are connected horizontally from right to left, and the fourth sphere is connected vertically to the second sphere. And the fifth sphere is connected directly below the second sphere,
An assembly-type spherical volume tree characterized by the above.   The assembly according to claim 1, comprising a pedestal having a total of 25 locating concave holes, five on each side in a square arrangement, and twelve blocks are assembled in a four-sided pyramid shape on the pedestal. Formula sphere volume tree.   2. A pedestal having a total of 55 locating recesses in a rectangular arrangement, 11 vertically and 5 horizontally, and 12 blocks are assembled into a single-layered rectangle on the pedestal. An assembly-type spherical volume tree as described in 1.   The assembly type according to claim 1, comprising a pedestal having a total of 55 locating concave holes, 10 in each of three sides in a triangular arrangement, and twelve blocks are assembled into a single-layer triangle on the pedestal. Sphere volume tree.   The assembly-type spherical volume tree according to claim 1, further comprising a pedestal having 55 localization holes and one convex column, wherein twelve blocks are assembled in a single-layer thin plate shape on the pedestal.   The assembled block volumetric tree according to claim 1, wherein each of the twelve blocks is combined between the spheres by fitting a tenon and a mortise, by integral injection molding, or by adhesive bonding.   Of the twelve blocks of claim 1, seven blocks A, B, C, F, I, J, K, and a total of 30 spheres are arranged in an array of four squares on four sides. An assembly-type spherical volume tree characterized in that it is assembled in a four-sided pyramid shape with a total of 16 lower-layer spheres.   The assembly according to claim 7, comprising a pedestal having a total of 16 dent holes for localization, four on each side in a square arrangement, and seven blocks are assembled in a four-sided pyramid shape on the pedestal. Formula sphere volume tree.   8. A pedestal having a total of 30 dent holes for localization in a rectangular arrangement with six vertically and five horizontally, and seven blocks are assembled into a single-layer rectangle on the pedestal. An assembly-type spherical volume tree as described in 1.   A three-sided configuration in which the 12 blocks of 3 in FIG. 1 are arranged in groups of 36 blocks and 165 spheres in total, and the number of spheres in the lowest layer is 45 in an array of 9 triangles on three sides. An assemblable spherical volumetric tree that is assembled into a pyramid shape. A pedestal having a total of 45 locating concave holes, each having nine in three sides in a triangular arrangement, and among the blocks of claim 10, six blocks have a total number of spheres of the lowest layer on the pedestal of 45. The assembly-type spherical volume tree according to claim 10, which is assembled into a three-sided pyramid shape.

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