CN2790554Y

CN2790554Y - Combined spherical building block structruce

Info

Publication number: CN2790554Y
Application number: CN 200520015790
Authority: CN
Inventors: 郑明显
Original assignee: LonPos Braintelligent Co Ltd
Current assignee: LonPos Braintelligent Co Ltd
Priority date: 2005-04-28
Filing date: 2005-04-28
Publication date: 2006-06-28
Anticipated expiration: 2015-04-28
Also published as: AU2006100264A9; AU2006100264A4; JP3113955U; HK1081056A2; CA2536811A1; EP1716894A1

Abstract

The utility model relates to a combined spherical building block structure which is composed of twelve building blocks with different moldings, wherein each building block is respectively composed of 3 to 5 spheres and the total number of the spheres of the twelve building blocks is 55. A four-side tapered pyramid of which the bottom edges are respectively formed by the arrangement of five spheres is formed, or three groups of identical building blocks with totally 165 spheres form the other kind of three-surface tapered pyramid of which the bottom edges are respectively provided with nine spheres. Because of different angles, the difficulty of permutation and combination is different. Thereafter, the difficulty of the permutation and the combination is enhanced, the intelligence potentiality is raised and the recreation effect is achieved.

Description

Combined spherical building block structure

Technical Field

The present invention relates to a modular spherical building block structure, and more particularly to a building block structure of a three-sided pyramid, in which 55 spherical bodies are arranged to form a four-sided pyramid, and 165 spherical bodies of three groups are converted into three-sided pyramid with different arrangement angles.

Background

Although the playing methods of the traditional 'jigsaw' and the 'jigsaw' are difficult and different, the playing methods are limited to intelligent development and game of a jigsaw group, and the 'jigsaw' has various changes, but is limited to a plane playing method, so that the difficulty cannot be improved. In view of the above, the inventor has developed a combined building block suitable for all levels and different age levels, which not only has a planar combination function but also has a three-dimensional stacking change effect, and has also applied for various patents, such as patent document 1.

Patent document 1: taiwan bulletin No. 398313, "a modeling block capable of changing 60 °, 90 ° and 120 ° combinations", is the same author as the present case.

Patent document 1 is characterized in that 19 blocks are combined with a base to form a single-layer or multi-layer three-dimensional shape, such as a four-sided pyramid. However, the building blocks of the above patent documents can only be arranged and combined to form a four-sided pyramid, but three-sided pyramid is not arranged, because the angles of the four sides and the three-sided pyramid are different, and the combination quantity is different, so the starting point of thinking is also different, especially the quantity of the building blocks of the three-sided pyramid is more than that of the four-sided pyramid, so the difficulty is higher, therefore how to convert the building blocks into the building blocks of the three-sided pyramid from the four sides and the design thereof become the problem to be solved by the present invention.

Novel content

An object of the utility model is to provide a modular spheroid building blocks structure is with the four sides toper pyramid building blocks that 55 spheroids are constituteed to the same building blocks of three groups 165 spheroids of the same are constituteed into another kind of trilateral toper pyramid altogether, because the angle is different, consequently the degree of difficulty of permutation and combination is just different, in view of the above in order to improve the permutation and combination degree of difficulty and promote intelligent potentiality and reach the recreational effects. The method comprises the following specific steps:

a modular spheroid building blocks structure, its characterized in that includes:

12 different shapes to the building blocks of constituteing by 3 to 5 spheroids respectively, the spheroid total number of 12 building blocks is 55, these 12 building blocks shapes are respectively:

the building block A is in an L shape formed by 4 spheres, wherein the 1 st to 3 rd spheres are horizontally connected from right to left, and the 4 th and 3 rd spheres are vertically connected;

the building block B is in a P shape formed by 5 spheres, wherein the 1 st to 3 rd spheres are horizontally connected from right to left, the 4 th and 5 th spheres are also horizontally connected from right to left, and the 1 st and 2 nd spheres are vertically connected with the 4 th and 5 th spheres;

the building block C is in an L shape formed by 5 spheres, the 1 st to the 4 th spheres are horizontally connected from right to left, and the 5 th and the 4 th spheres are vertically connected;

building block D is formed into '*' shape by 5 spheres, the 1 st to 4 th spheres are horizontally connected from right to left, and the 5 th and 3 rd spheres are vertically connected;

building block E is composed of 5 spheres; the 1 st to 3 rd spheres are horizontally connected from right to left, the 4 th sphere is vertically connected with the 1 st sphere, and the 4 th and 5 th spheres are horizontally connected from left to right;

building block F is formed into '*' shape by 3 spheres; the No. 1 and No. 2 spheres are horizontally connected from right to left, and the No. 3 and No. 2 spheres are vertically connected;

the building block G is formed into a shape of * by 5 spheres; the No. 1 to No. 3 spheres are horizontally connected from right to left, the No. 4 sphere is vertically connected with the No. 3 sphere, and the No. 5 sphere is vertically connected with the No. 4 sphere;

building block H is formed by 5 spheres into a W shape; the 1 st and 2 nd spheres are vertically connected from top to bottom, the 2 nd and 3 rd spheres are horizontally connected from right to left, the 3 rd and 4 th spheres are vertically connected from top to bottom, and the 4 th and 5 th spheres are horizontally connected from right to left;

the building block I is in a reverse U shape formed by 5 spheres; the 1 st to the 3 rd spheres are horizontally connected from right to left, the 4 th and the 3 rd spheres are vertically connected, and the 5 th and the 1 st spheres are vertically connected;

building blocks J are in a shape of a straight line formed by 4 spheres; the 1 st to 4 th spheres are horizontally connected from right to left;

the building block K is in a mouth shape formed by 4 spheres; the 1 st and 2 nd spheres are horizontally connected from right to left, the 3 rd and 4 th spheres are horizontally connected from right to left, and the 1 st and 2 nd spheres are vertically connected with the 3 rd and 4 th spheres;

the building block L is in a cross shape formed by 5 spheres; the 1 st to the 3 rd spheres are horizontally connected from right to left, the 4 th sphere is vertically connected to the 2 nd sphere, and the 5 th sphere is vertically connected below the 2 nd sphere.

Or,

the utility model provides a modular spheroid building blocks structure which characterized in that:

including foretell 7 building blocks: A. b, C, F, I, J, K, a total of 30 spheres, forming a four-sided pyramid shape with 4 bases and 16 bases.

The combined sphere building block structure is characterized in that: the 7 building blocks form a four-side conical pyramid on a base with 16 positioning concave holes, and the base is provided with 4 positioning concave holes which are arranged in a square shape on each side.

Or,

the building block comprises three groups of 12 building blocks, and 165 spheres of 36 building blocks form a three-face conical pyramid shape with 9 spheres on each side and 45 spheres on the bottom layer.

The utility model discloses effect and efficiency:

through the structure, 12 building blocks in different shapes can be matched with three different bases to be arranged and combined into a single-layer square shape, a single-layer rectangular shape and a single-layer triangular shape; in addition, the playing method can be matched with different bases to change plane arrangement into three-dimensional combination, and the multiple-change and intelligent development functions can be achieved.

And three groups of building blocks with the same 12 different shapes are matched with the base to be arranged and combined into a three-sided conical pyramid, so that the playing method has different angles, different quantity of the building blocks and higher playing difficulty, and the building block playing method is brought into play to the maximum limit.

In addition, 7 blocks in 12 blocks can be matched with the base to be arranged and combined into a four-side conical pyramid or a single-layer rectangle, so that the intelligent blocks have more game options and players have more imagination spaces.

Drawings

FIG. 1: the utility model discloses the three-dimensional model picture of 12 building blocks.

FIG. 2: the present invention relates to embodiment 1, model 1.

FIG. 3: the present invention is the 2 nd figure of embodiment 1.

FIG. 4: the present invention is the 1 st model of the 2 nd embodiment.

FIG. 5: the present invention is the 2 nd figure of embodiment 2.

FIG. 6: the present invention relates to embodiment 3, model 1.

FIG. 7: the present invention is the 2 nd figure according to the 3 rd embodiment.

FIG. 8: the present invention is the figure of embodiment 4.

FIG. 9: the present invention relates to embodiment 5, model 1.

FIG. 10: the present invention relates to the 2 nd figure of the 5 th embodiment.

Detailed Description

The following detailed description is made in accordance with embodiments illustrated in the drawings as follows:

as shown in fig. 1, for the utility model discloses building blocks A, B, C, D, E, F, G, H, I, J, K, L totally 12, its shape diverse, these 12 building blocks are become by 3 to 5 spheroids 10 respectively, and the spheroid total number of 12 building blocks is 55, and its shape is respectively:

the building block B is in a P shape consisting of 5 spheres, wherein the spheres from 1 st to 3 rd are horizontally connected from right to left, the spheres from 4 th to 5 th are also horizontally connected from right to left, and only the spheres from 1 st to 2 nd are vertically connected with the spheres from 4 th to 5 th;

the building block C is in an L shape formed by 5 spheres, wherein the 1 st to the 4 th spheres are horizontally connected from right to left, and the 5 th and the 4 th spheres are vertically connected;

the building block D is formed by 5 spheres in an * shape, wherein the spheres from 1 st to 4 th are horizontally connected from right to left, and the spheres from 5 th to 3 rd are vertically connected;

building block E is composed of 5 spheres; the 1 st to the 3 rd spheres are horizontally connected from right to left, the 4 th and the 1 st spheres are vertically connected, and the 4 th and the 5 th spheres are horizontally connected from left to right;

the building block F is formed by 3 spheres in a shape of *; the No. 1 sphere and the No. 2 sphere are horizontally connected from right to left, and the No. 3 sphere and the No. 2 sphere are vertically connected;

the building block G is formed by 5 spheres in a shape of *; the 1 st to the 3 rd spheres are horizontally connected from right to left, the 4 th and the 3 rd spheres are vertically connected, and the 5 th and the 4 th spheres are vertically connected;

the building block H is in a W shape formed by 5 spheres; the spheres 1 and 2 are vertically connected from top to bottom, the spheres 2 and 3 are horizontally connected from right to left, the spheres 3 and 4 are vertically connected from top to bottom, and the spheres 4 and 5 are horizontally connected from right to left;

the building block I is in an inverted U shape formed by 5 spheres; the No. 1 to No. 3 spheres are horizontally connected from right to left, the No. 4 and No. 3 spheres are vertically connected, and the No. 5 and No. 1 spheres are vertically connected;

the building block J is in a shape of a straight line consisting of 4 spheres; the 1 st to the 4 th spheres are horizontally connected from right to left;

the building block K is in a mouth shape consisting of 4 spheres; the 1 st and 2 nd spheres are horizontally connected from right to left, the 3 rd and 4 th spheres are horizontally connected from right to left, and the 1 st and 2 nd spheres are vertically connected with the 3 rd and 4 th spheres;

the building block L is in a cross shape formed by 5 spheres; is that 1 st to 3 rd spheroid is from right to left horizontal connection, and the 4 th spheroid is connected perpendicularly on the 2 nd spheroid, and the 5 th spheroid is connected perpendicularly under the 2 nd spheroid.

The 12 building blocks described above are each composed of 3 to 5 spheres, and the combination is one of the following ways, in which the spheres 10 are embedded with each other by tenons 11 and grooves 12, the spheres 10 are fixed by gluing (such as thermal fusion) or the spheres 10 are combined by integral injection molding.

Through above-mentioned 12 building blocks can cooperate the base of different molding and arrange different embodiment forms, and can form different three-dimensional forms with the cooperation of 3 groups of the same building blocks, can form different planes or three-dimensional forms when arranging with 7 building blocks in 12 building blocks and constitute, its embodiment is as follows:

embodiment 1

As shown in fig. 2, the 12 building blocks can be arranged on the base 20 to form a four-sided pyramid, the base 20 is provided with positioning concave holes 21 having a length of 5 and a width of 5 and arranged in a square, and the positioning concave holes 21 are preferably circular and have a semicircular cross section.

As shown in fig. 3, the 12 building blocks can be arranged on the base 20 to form a single-layer rectangle, the base 20 is provided with 11 positioning concave holes 22 with a length of 11 and a width of 5 arranged to form a rectangle, and the positioning concave holes 22 are preferably circular and have a semicircular cross section.

The arrangement shown in fig. 2 and 3 can be implemented on the same rectangular base 20, for example, the base 20 is pivotally connected by an upper cover 23 and a lower seat 24, wherein the positioning concave holes 21, 22 are respectively disposed on the upper cover 23 and the lower seat 24, so that players can respectively arrange and combine the four-sided pyramid and single-layer rectangular shape on the upper cover 23 and the lower seat 24.

Embodiment 2

As shown in fig. 4, the 12 building blocks can be arranged on a base 30 to form a four-sided pyramid, the base 30 is provided with positioning concave holes 31 which are 5 in length and 5 in width and are arranged in a square, and the positioning concave holes 31 are in a circular concave shape.

As shown in fig. 5, the 12 building blocks can be arranged and combined into a single-layer triangle on the base 30, the base 30 is provided with 10 triangular positioning concave holes 32 on each side, and the positioning concave holes 32 are in the shape of circular concave pits.

The arrangement shown in fig. 4 and 5 can be implemented on the same semicircular base 30, for example, the base 30 is pivotally connected to an upper cover 33 and a lower base 34, wherein the positioning holes 31, 32 are respectively disposed on the upper cover 33 and the lower base 34, so that players can respectively arrange and combine the four-sided pyramid and the single-layer triangle on the upper cover 33 and the lower base 34.

Embodiment 3

As shown in fig. 6, the 12 building blocks can be arranged on the base 40 to form a four-sided pyramid, the base 40 is provided with positioning concave holes 41 which are 5 in length and 5 in width and are arranged in a square, and the positioning concave holes 41 are in a circular concave shape.

As shown in fig. 7, the 12 blocks can be arranged on the base 40 to form a single-layer laminated plate, the base 40 has 55 positioning holes 42 and 1 protruding column 43 arranged to form a laminated plate, and the protruding column 43 can be integrally formed with the base 40 or inserted into a predetermined insertion hole (not shown) of the base 40 for fixing.

The arrangement shown in fig. 6 and fig. 7 can be implemented on the same home plate base 40, for example, the top surface of the base 40 is provided with positioning holes 41 for 12 blocks to be arranged and combined into a four-sided pyramid, and the back surface of the base 40 is provided with 55 positioning holes 42 and a base 43 for 12 blocks to be arranged and combined into a home plate.

Embodiment 4

Next, the 12 blocks can be arranged and combined into different three-dimensional shapes in multiple groups, as shown in fig. 8, 36 blocks a to L (12 × 3 ═ 36) are shown in fig. 1 in 3 groups, the total number of spheres is 165 (55 × 3 ═ 165), and 9 blocks on each side and 45 blocks in a single layer are arranged and combined into a three-sided pyramid.

The 36 blocks can be fitted with a base 50 having 45 positioning recesses 51, the positioning recesses 51 being arranged in a triangle with 9 on each side.

Embodiment 5

As shown in fig. 9, which is a 1 st aspect of the present embodiment, 30 spheres 10 of the 7 building blocks A, B, C, F, I, J, K disclosed in fig. 1 are arranged and combined into a four-sided pyramid by 4 bottom edges thereof; the 7 building blocks can also be arranged on a base 60 to form a four-sided pyramid, and the base 60 is provided with 4 positioning concave holes 61 which are arranged in a square shape and are arranged on each side.

As shown in fig. 10, in the 2 nd embodiment of the present invention, the 7 building blocks can be arranged in a single-layer rectangular shape on a base 60, and positioning concave holes 62 which are arranged in a rectangular shape and have a length of 6 and a width of 5 are provided on the base 60.

The arrangement shown in fig. 9 and 10 can be implemented on the same base 60, for example, the top surface of the base 60 is provided with positioning holes 61 for 7 blocks to be arranged and combined into a four-layered pyramid, and the back surface of the base 60 is provided with 30 positioning holes 62 arranged in a rectangular shape.

The present invention has been described in detail with reference to the preferred embodiments shown in the drawings; however, the present invention is not limited to the above embodiments, and various equivalent modifications can be made without departing from the scope of the present invention.

Claims

1. A modular spheroid building blocks structure, its characterized in that includes:

building block I is composed of 5 spheresShaping; the 1 st to the 3 rd spheres are horizontally connected from right to left, the 4 th and the 3 rd spheres are vertically connected, and the 5 th and the 1 st spheres are vertically connected;

2. The modular spherical building block structure of claim 1, wherein: the 12 building blocks mutually form a four-side conical pyramid shape on a base with 25 positioning concave holes, and each side of the base of the four-side conical pyramid is provided with 5 positioning concave holes which are arranged in a square shape.

3. The modular spherical building block structure of claim 1, wherein: the 12 building blocks form a single-layer rectangle on a base with 55 positioning concave holes, and the base is provided with 11 positioning concave holes with the length and 5 positioning concave holes with the width arranged into a rectangle.

4. The modular spherical building block structure of claim 1, wherein: the 12 building blocks form a single-layer triangle on a base with 55 positioning concave holes, and the base is provided with 10 positioning concave holes which are arranged into a triangle on each side.

5. The modular spherical building block structure of claim 1, wherein: the 12 building blocks are arranged into a single-layer overlapped plate shape on a base with 55 positioning concave holes and 1 convex column, and the base is provided with an overlapped plate shape formed by 55 positioning concave holes and 1 convex column.

6. The modular spherical building block structure of claim 1, wherein: the 12 building blocks are formed by connecting spheres embedded with the holes and the grooves by tenons, spheres glued with each other or spheres integrally formed by injection molding.

7. The utility model provides a modular spheroid building blocks structure which characterized in that:

comprising 7 of the devices of claim 1: A. b, C, F, I, J, K, a total of 30 spheres, forming a four-sided pyramid shape with 4 bases and 16 bases.

8. The modular spherical building block structure of claim 7, wherein: the 7 building blocks form a four-side conical pyramid on a base with 16 positioning concave holes, and the base is provided with 4 positioning concave holes which are arranged in a square shape on each side.

9. The modular spherical building block structure of claim 7, wherein: the 7 building blocks form a single-layer rectangle on a base with 30 positioning concave holes, and the base is provided with 6 positioning concave holes with 6 lengths and 5 widths which are arranged into a rectangle.

10. The utility model provides a modular spheroid building blocks structure which characterized in that:

comprising three sets of 12 blocks as claimed in claim 1, wherein 165 spheres of 36 blocks form a three-sided pyramidal shape with 9 spheres per side and 45 spheres at the bottom.

11. The modular spherical building block structure of claim 10, wherein: the 36 building blocks form a three-surface conical pyramid on a base with 45 positioning concave holes, and the base is provided with 9 positioning concave holes which are arranged into a triangle on each side.