KR20170121537A - Assembly of functional modularized block - Google Patents

Abstract

The present invention relates to a functional module block assembly in which module blocks having different shapes are randomly combined and assembled into various types of three-dimensional structures, wherein the module blocks consist of a AA type first module block (A), a BB type second module block, a CC type third module block (C), and DD type fourth module block (D). A horizontal fitting protrusion portion (10) or a horizontal fitting groove portion (20) is formed on a side surface of the module blocks, and the horizontal fitting protrusion portion (10) or the horizontal fitting groove portion (20) of each module block is fitted and coupled to each other, so that the module blocks are able to infinitely be assembled and expanded in a plane direction or a vertical direction only with limited types of module blocks to form various multi-functional three-dimensional structures such as toys or outdoor activity items.

Description

[0001] ASSEMBLY OF FUNCTIONAL MODULARIZED BLOCK [0002]

The present invention relates to a module block assembly formed by combining module blocks, and more particularly, to a functional module block assembly in which module blocks of different shapes are arbitrarily combined to be assembled and expanded into various types of three-dimensional structures.

In a typical block, two or more blocks are assembled by a combination of a protrusion formed by a convex portion and a groove formed by a concave portion when assembled into a three-dimensional structure. The conventional toy block may be formed in various shapes such as a protrusion such as 'Lego', which is inserted or connected to a groove formed in a lower portion of another block. In other words, it can be assembled into a desired shape by appropriately combining various types of blocks. Especially, it is useful for infants and children at the time of brain development, and is also popular as an infant toy.

However, conventional toy blocks have limitations in that their use is restricted for toys. Blocks made only for this purpose have a drawback in that they can not be utilized for other purposes, while they are focused on weight reduction and mobility enhancement. In other words, it is difficult to utilize various functions such as being used as an outdoor activity item such as a chair or a table, or being used as a boat which can be directly loaded on the water surface.

Accordingly, there is a demand for a functional module block assembly that can be assembled and expanded in an unlimited manner in a plane direction as well as in a vertical direction based on a limited type of module block. In particular, a module block assembly having a variety of designs A functional module block assembly is required. At the same time, there has been a need for a functional module block assembly having coupling portions that can be maintained or increased in stability as well as ease in combining the module blocks.

In order to recognize the above limitations and solve the problems, the present invention can be expanded and expanded indefinitely in a planar direction or a vertical direction with only a limited type of module block, and the multi-functionality can be utilized as a toy, The present invention also provides a functional module block assembly capable of forming a three-dimensional structure of various designs.

Particularly, it is an object of the present invention to provide a functional module block assembly in which the module blocks can be easily combined while expanding the assembly in a plane direction or a vertical direction, and the assembly can be stably maintained by increasing the folding force.

'타입의 제1 모듈 블록(A), '

'타입의 제2 모듈 블록(B), '

'타입의 제3 모듈 블록(C) 및 '

'타입의 제4 모듈 블록(D)으로 형성되어지되, 상기 모듈 블록들의 측면에는 수평끼움돌부(10) 또는 수평끼움홈부(20)가 형성되어 각 모듈 블록들의 수평끼움돌부(10) 또는 수평끼움홈부(20)가 서로 끼움 결합됨으로써 평면 방향으로 조립 확장되어지는 것을 특징으로 한다.In order to achieve the above object, a functional module block assembly according to the present invention is a functional module block assembly in which module blocks having different shapes are arbitrarily combined and assembled and expanded into various types of three-dimensional structures,

'Type first module blocks A,

'Type second module block B', '

'Type third module block (C) and the'

A horizontal fitting protrusion 10 or a horizontal fitting recess 20 is formed on a side surface of the module blocks so that the horizontal fitting protrusion 10 or the horizontal fitting protrusion 10 of each module block And the grooves 20 are assembled and expanded in a planar direction by being fitted to each other.

'타입의 제1 모듈 블록(A), '

'타입의 제2 모듈 블록(B), '

'타입의 제3 모듈 블록(C) 및 '

'타입의 제4 모듈 블록(D)에 '

'타입의 제5 모듈 블록(E)이 더 포함되어지되, 상기 제5 모듈 블록(E)의 일측 평면 측면에는 수평끼움돌부(10)가 형성되고, 인접한 타측 평면 측면에는 수평끼움홈부(20)가 형성되는 것을 특징으로 한다.In addition,

'Type first module blocks A,

'Type second module block B', '

'Type third module block (C) and the'

'In the fourth module block D'

A horizontal fitting protrusion 10 is formed on one side surface of one side of the fifth module block E and a horizontal fitting groove 20 is formed on a side surface of the other adjacent side surface of the fifth module block E, Is formed.

'타입의 제6 모듈 블록(F)이 더 포함되어지는 것을 특징으로 한다.Also, '

≪ RTI ID = 0.0 > (F) < / RTI >

'형상으로 돌출 형성되고, 상기 수평끼움홈부(20)는 상기 수평끼움돌부(10)에 대응되도록 '

'형상으로 요입 형성되는 것을 특징으로 한다.In addition, the horizontal fitting protrusion 10 may be formed as a '

And the horizontal fitting groove portion 20 is formed so as to correspond to the horizontal fitting projection portion 10,

Shaped " shaped. ≪ / RTI >

'형상으로 돌출된 수직끼움돌부(30)가 형성되고, 하부면에는 상기 수직끼움돌부(30)와 대응되도록 '

'형상으로 요입된 수직끼움홈부(40)가 형성되며, 상기 제2 모듈 블록(B)의 하부면에는 '

'형상으로 요입된 수직끼움홈부(40)가 형성되어 제1 모듈 블록(A) 및 제2 모듈 블록(B)들이 상하로 결합됨으로써 수직방향으로 조립 확장되어지는 것을 특징으로 한다.Further, on the upper surface of the first module block A,

And the lower surface of which is formed with a vertical protrusion 30, which corresponds to the vertical protrusion 30,

And a vertical fitting groove 40 is formed in the lower surface of the second module block B,

And the first module block A and the second module block B are vertically coupled to each other so as to be assembled and expanded in the vertical direction.

The module blocks may be made of expanded polypropylene (EPP).

Further, the module blocks are formed in different colors so as to match the image of the assembled three-dimensional structure.

The number of the first module block A is N, the number of the second module block B is M, the number of the third module block C is L, and the number of the fourth module block D is K, Wherein the N + M value is an integer equal to or greater than 0, the L + K value is equal to or greater than 0, and the N + M + L + K value is an integer equal to or greater than 1.

By the above-mentioned solution, by merely expanding and assembling in an infinite manner in a planar direction or a vertical direction with only a limited type of module block, it is possible to form various multifunctional three-dimensional structures such as toys and outdoor products.

Particularly, since the horizontal fitting projections 10 or the horizontal fitting recesses 20 of the module blocks are fitted to each other, the vertical fitting projections 30 or the vertical fitting recesses 40 are vertically coupled And can be assembled and expanded in the vertical direction, and it is advantageous in that the assembling body can be stably maintained by increasing the folding force while being easily coupled.

Also, since the module blocks are made of a foamed polypropylene (EPP) material, the user can assemble the module blocks to form an environmentally-friendly and lightweight functional module block assembly. In addition, since it floats in the water due to buoyancy, it is suitable for a user of the infant floor especially as a swimming water product, and has a certain level of bearing capacity and strength, so that it can be used as a table or a chair in outdoor activities.

Furthermore, since the module blocks are formed in different colors so as to match the images of the assembled three-dimensional structures, the assembled structure of the module blocks can be easily grasped, and the appearance of the assembled three-dimensional structure can be displayed in a functional and aesthetic manner .

FIG. 1 is a general view of an embodiment of a functional module block assembly according to the present invention.
FIG. 2 (a) to FIG. 2 (d) separately show perspective views of the first, second, third and fourth module blocks, respectively.
Fig. 3 (a) is a perspective view of the fifth module block, and Fig. 3 (b) is a perspective view of the sixth module block.
FIGS. 4 to 9 illustrate a process of forming a three-dimensional structure having a shape of a flower plate as an embodiment of the functional module block assembly according to the present invention.
FIG. 10 shows a three-dimensional structure having a shape of a partition as one embodiment of the functional module block assembly according to the present invention.
FIG. 11 shows a three-dimensional structure having a shape of a tea table as an embodiment of the functional module block assembly according to the present invention.
12 shows a three-dimensional structure having a shape of a desk as one embodiment of the functional module block assembly according to the present invention.
FIG. 13 shows a three-dimensional structure having a shape of a chair as an embodiment of the functional module block assembly according to the present invention.
Fig. 14 shows a three-dimensional structure having a boat as one embodiment of the functional module block assembly according to the present invention.
FIG. 15 shows a three-dimensional structure having a shape of a swan according to an embodiment of the functional module block assembly of the present invention.
16 shows a three-dimensional structure having a whale shape as an embodiment of the functional module block assembly according to the present invention.

An example of the functional module block assembly according to the present invention can be variously applied, and a most preferred embodiment will be described below with reference to the accompanying drawings.

FIG. 1 is a general view of an embodiment of a functional module block assembly according to the present invention.

'타입의 제1 모듈 블록(A), '

'타입의 제2 모듈 블록(B), '

'타입의 제3 모듈 블록(C) 및 '

'타입의 제4 모듈 블록(D)으로 형성된다. 바람직하게는, '

'타입의 제5 모듈 블록(E)이 더 포함될 수 있으며, '

'타입의 제6 모듈 블록(F)이 더 포함될 수 있다.Referring to FIG. 1, a functional module block assembly according to the present invention is assembled and expanded into various types of three-dimensional structures by arbitrarily combining module blocks having different shapes. The module blocks include '

'Type first module blocks A,

'Type second module block B', '

'Type third module block (C) and the'

Type module block " D ". Preferably, the '

≪ / RTI > type module block < RTI ID = 0.0 > (E)

≪ RTI ID = 0.0 > (F) < / RTI >

The horizontal fitting projections 10 or the horizontal fitting recessed portions 20 are formed on the side surfaces of the module blocks except for the sixth module block F so that the horizontal fitting projections 10, (20) can be assembled and expanded in a planar direction by being fitted to each other.

2 (a) to 2 (d) show the first module block A, the second module block B, the third module block C and the fourth module block D separately will be.

'형상으로 돌출 형성되고, 타 측면(A-4)(A-5)에는 상기 수평끼움돌부(10)에 대응되도록 수평끼움홈부(20)가 '

'형상으로 요입 형성될 수 있다. 나아가, 상기 제1 모듈 블록(A)의 상부면(A-1)에는 '

'형상으로 돌출된 수직끼움돌부(30)가 형성되고, 하부면(A-6)에는 상기 수직끼움돌부(30)와 대응되도록 '

'형상으로 요입된 수직끼움홈부(40)가 형성될 수 있다. 여기서, 상기 수직끼움돌부(30) 및 수직끼움홈부(40)는 환형으로 형성될 수 있다.2, the first module block A is formed to extend by a predetermined thickness with respect to the top surface A-1 having a square shape, In the side surface (A-2) (A-3), the horizontal fitting projections 10 '

And the horizontal fitting groove 20 is formed in the other side A-4 and A-5 so as to correspond to the horizontal fitting projection 10,

Shaped " shape. Further, on the upper surface (A-1) of the first module block (A)

And the lower surface A-6 is formed with a vertical protrusion 30 protruding from the lower surface A-

The vertical fitting recessed portion 40 can be formed. Here, the vertical fitting projections 30 and the vertical fitting recesses 40 may be formed in an annular shape.

'형상으로 돌출 형성되고, 타 측면(B-4)(B-5)에는 상기 수평끼움돌부(10)에 대응되도록 수평끼움홈부(20)가 '

'형상으로 요입 형성될 수 있다. 상기 제1 모듈 블록(A)과는 다르게 상기 제2 모듈 블록의 상부면(B-1)은 평편하나, 상기 제2 모듈 블록(B)의 하부면(B-6)에는 '

'형상으로 요입된 수직끼움홈부(40)가 형성될 수 있다. 마찬가지로, 상기 수직끼움홈부(40)는 환형으로 형성될 수 있다.Referring to FIG. 2B, the second module block B is formed to extend by a predetermined thickness with respect to the top surface B-1 of the square shape, and two adjacent side surfaces B- 2) In (B-3), the horizontal fitting protrusion 10 '

And horizontal fitting grooves 20 are formed in the other side surfaces B-4 and B-5 so as to correspond to the horizontal fitting projections 10,

Shaped " shape. Unlike the first module block A, the upper surface B-1 of the second module block is flat, while the lower surface B-6 of the second module block B has a '

The vertical fitting recessed portion 40 can be formed. Similarly, the vertical fitting groove 40 may be formed in an annular shape.

'형상으로 돌출 형성되고, 타 측면(C-4)에는 상기 수평끼움돌부(10)에 대응되도록 수평끼움홈부(20)가 '

'형상으로 요입 형성될 수 있다. 상기 제1 모듈 블록(A) 및 제2 모듈 블록(B)과는 다르게 상기 제3 모듈 블록의 상부면(C-1) 및 하부면(C-5)은 평편하다.2 (c), the third module block C is formed to extend by a predetermined thickness with respect to the top surface C-1 having an equilateral triangle shape, and two adjacent sides C -2) In (C-3), the horizontal fitting projections 10 '

And the horizontal fitting groove 20 is formed on the other side C-4 so as to correspond to the horizontal fitting projection 10,

Shaped " shape. Unlike the first module block A and the second module block B, the upper surface C-1 and the lower surface C-5 of the third module block are flat.

'형상으로 돌출 형성되고, 타 측면(D-3)(D-4)에는 상기 수평끼움돌부(10)에 대응되도록 수평끼움홈부(20)가 '

'형상으로 요입 형성될 수 있다. 상기 제3 모듈 블록(C)과 마찬가지로 상기 제4 모듈 블록의 상부면(D-1) 및 하부면(D-5)은 평편하다.Referring to FIG. 2 (d), the fourth module block D is formed to extend by a predetermined thickness with respect to the top surface D-1 having an equilateral triangle shape like the third module block C, 3, the horizontal fitting projection 10 is formed on one side (D-2)

And the horizontal fitting groove 20 is formed in the other side surfaces D-3 and D-4 so as to correspond to the horizontal fitting projection 10,

Shaped " shape. Like the third module block C, the upper surface D-1 and the lower surface D-5 of the fourth module block are flat.

3 (a) shows the fifth module block (E), and (b) shows the sixth module block (F) separately.

'형상으로 돌출 형성되고, 인접한 타측 평면 측면(E-3)에는 상기 수평끼움돌부(10)에 대응되도록 수평끼움홈부(20)가 '

'형상으로 요입 형성될 수 있다. 상기 제3,4 모듈 블록(C)(D)과 마찬가지로 상기 제5 모듈 블록의 상부면(E-1) 및 하부면(E-5)은 평편하다.3 (a), a horizontally fitting protrusion 10 is formed on one side surface of one side of the fifth module block E, and a horizontal fitting groove 20 is formed on a side surface of the other adjacent side. Specifically, the fifth module block E is formed so as to extend by a predetermined thickness with respect to the quadrangle-shaped upper surface E-1, and the side surface of the fifth module block E is formed of two planes E-2 ) (E-3) and the curved surface (E-4). Here, the horizontal fitting projections 10 are formed on one flat side (E-2)

And a horizontally fitting groove portion 20 is formed on the other flat side surface E-3 adjacent thereto so as to correspond to the horizontal fitting projection portion 10,

Shaped " shape. Like the third and fourth module blocks C and D, the upper surface E-1 and the lower surface E-5 of the fifth module block are flat.

Referring to FIG. 3 (b), the sixth module block F is formed to extend by a predetermined thickness with respect to the circular upper surface F-1. The upper surface F- (F-3) is flat, and is divided into a curved side (F-2).

By providing the above-mentioned module blocks, it is possible to form various multi-functional structures such as toys, outdoor activities, and the like by assembling and expanding infinitely in a planar direction or a vertical direction with only a limited type of module block.

Particularly, since the horizontal fitting projections 10 or the horizontal fitting recesses 20 of the module blocks are fitted to each other, the vertical fitting projections 30 or the vertical fitting recesses 40 are vertically coupled And can be assembled and expanded in the vertical direction, and it is advantageous in that the assembling body can be stably maintained by increasing the folding force while being easily coupled.

Here, the thicknesses of the module blocks are all the same. In other words, the height of the sides of the module blocks may be the same. Further, the thickness extending from the upper surface of the module blocks may be less than the length of one side of the upper surface of the module block, preferably less than one half of the length of one side of the upper surface of the module block.

In addition, the length of one side of the upper surface between the module blocks may be the same. That is, the length of one side of the square, which is the shape of the top surface A-1 of the first module block A, is equal to the length of one side of the equilateral triangle, which is the shape of the top surface C- Can be the same. Likewise, the length of one side of the square, which is the shape of the top surface A-1 of the first module block A, is equal to the length of one side of the straight line constituting the quadrants of the top surface E- Can be equal to the length of the sides.

Accordingly, the module blocks can be modularized so that they can be assembled and expanded infinitely in a planar direction or a vertical direction.

FIGS. 4 to 9 illustrate a functional module block assembly according to an embodiment of the present invention. In detail, the first, second, third and fourth module blocks A, B, C, A process of forming a three-dimensional structure having a shape of a plate (Flower Plate) is shown.

Referring to FIG. 4, one side of a third module block C having horizontal fitting protrusions 10 formed on one side of the first module block A where the horizontal fitting grooves 20 are formed is coupled. Similarly, one side of the fourth module block D having horizontal fitting protrusions 10 is coupled to another side surface of the first module block A having the horizontal fitting grooves 20 )).

In the second module block B, one side of the third module block C having the horizontal fitting protrusion 10 formed on one side where the horizontal fitting groove 20 is formed is coupled to the horizontal fitting groove 20 A fourth module block D having horizontal fitting protrusions 10 is coupled to one side surface of the first module block A having the first module block A formed thereon (FIG. 4B).

5, the other side where the horizontal fitting grooves 20 of the third module block C and the fourth module block D, respectively coupled with the adjacent side surfaces of the first module block A, are formed, And is engaged with one side of the third module block C and the fourth module block D where the horizontal fitting projections 10 are formed.

When the module blocks are continuously coupled in the above-described manner, as shown in FIG. 6, a planar structure having a circular plate shape is formed by being assembled and expanded in the planar direction.

Next, as shown in FIG. 7, four circular plate-like structures are formed, and the horizontal fitting projections 10 and the horizontal fitting recesses 20 ). At the same time, a suitable type of module block is inserted and coupled so that the vacated space is filled.

Here, as shown in FIG. 8, the first module block A and the second module block B can be vertically assembled and expanded by being vertically coupled. More specifically, the vertical fitting projections 30 and the vertical fitting grooves 40 are formed between the first module blocks A, and between the first module blocks A and the second module blocks B, The vertical fitting shaft 30 formed on the first module block A and the vertical fitting groove 40 formed on the second module block B are combined to form the vertical axis of the module block assembly.

As a result, as shown in Fig. 9, another structure expanded in the planar direction is assembled and expanded in the vertical direction to the planar structure formed previously. Accordingly, as shown in FIG. 1, a three-dimensional structure having a shape of a flower plate is formed as an embodiment of the functional module block assembly according to the present invention.

In addition, the module blocks may be made of foamed polypropylene (EPP) material. Advantageously, at least 80% of the volume making up the module blocks may be composed of air. This has the advantage that the user can assemble the module block to form an environmentally friendly and lightweight functional module block assembly. That is, the foamed polypropylene material is almost harmless to the human body because the environmental hormone is hardly detected, and it is possible to prevent the generation of toxic chemical substances in the processing process. In addition, since it floats in the water due to buoyancy, it is suitable for a user in the infant, especially as a water sporting goods, and has a certain level of support force and strength, so that it can be utilized as a table or a chair in outdoor activities.

In addition, the module blocks may be formed in different colors so as to match the image of the assembled three-dimensional structure. In other words, the module blocks may be colored with one or two colors for each module block (see Figs. 1, 10 to 16).

Accordingly, the assembling structure of each module block can be easily grasped, and the appearance of the assembled three-dimensional structure can be displayed in a functional and aesthetic manner.

The number of the first module block A is N, the number of the second module block B is M, the number of the third module block C is L, and the number of the fourth module block D is K, The N + M value is an integer equal to or greater than 0, and the L + K value is an integer equal to or greater than 0. However, the value of N + M + L + K may be an integer equal to or greater than 1. This means that the module block alone can expand and assemble in a planar direction or a vertical direction, thereby forming various stereoscopic structures unlimitedly.

For example, in the embodiment shown in FIG. 1, N = 28, M = 5, L = 28, and K = 40.

10 to 16 illustrate other embodiments of the functional module block assembly of the present invention.

10 shows a three-dimensional structure in which the module blocks are assembled and have the shape of a partition. As shown in FIG. 6, the module blocks form a three-dimensional structure in the form of a partition, in which planar structures in the shape of circular plates are assembled and expanded in the planar direction and are erected from the ground again, L = 27, and K = 81.

11 shows a three-dimensional structure in which the module blocks are assembled to form a shape of a tea table. In this embodiment, the third module block C and the fourth module block D are assembled together, and a glass plate is additionally provided on the upper part to form a three-dimensional structure of a tee table shape. N = 0, M = 0, L = 7, and K = 161.

12 shows a three-dimensional structure in which module blocks are assembled to form a shape of a desk. Particularly, in this embodiment, the first module blocks A are assembled and expanded in a 'C' shape, and a fifth module block E or the like is formed on the upper and side portions formed by the side surfaces of the first module blocks A By assembling, the book can be plugged. N = 65, M = 13, L = 0, and K = 4, and five fifth module blocks E are additionally assembled.

Fig. 13 shows a three-dimensional structure in which the module blocks are assembled and have the shape of a chair. Side structure is expanded and assembled into a first module block A and a second module block B to form a chair-shaped three-dimensional structure, and N = 103 and M = 17 L = 0, and K = 0, and 16 modules of the fifth module block E are additionally assembled.

14 shows a three-dimensional structure in which the module blocks are assembled and have the shape of a boat. As shown in FIG. 13, a two-sided structure that is assembled and extended in the planar direction is provided, and the module blocks are assembled and expanded toward the inside to form a boat-shaped three-dimensional structure. N = 50, M = 10, L = = 28, and the fifth module block E and the sixth module block F are additionally assembled.

Figure 15 shows a three-dimensional structure in which the module blocks are assembled and have the shape of a swan. M = 6, L = 20, and K = 27, and the fifth module is assembled so that the upper part protrudes while the lower part is assembled and expanded so that the inner space is partially emptied so as to form a swallow- Ten blocks E are additionally assembled.

Figure 16 shows a three-dimensional structure in which the module blocks are assembled to form a whale. As shown in FIG. 13, there is provided a two-side structure expanded and assembled in a planar direction, and module blocks are assembled and expanded toward the inside, and the tail portion is assembled to be protruded to form a whale-like three- , L = 21, and K = 38, and 46 modules of the fifth module block E are additionally assembled.

The functional module block assembly according to the present invention has been described above. It will be understood by those of ordinary skill in the art that various changes in form and details may be made therein without departing from the spirit and scope of the invention as defined by the appended claims.

It is to be understood, therefore, that the embodiments described above are in all respects illustrative and not restrictive.

A: first module block B: second module block
C: third module block D: fourth module block
E: fifth module block F: sixth module block
10: Horizontal fitting projection 20: Horizontal fitting groove
30: vertical fitting projection 40: vertical fitting groove

Claims (8)

A functional module block assembly in which module blocks of different shapes are arbitrarily combined and assembled and expanded into various types of three-dimensional structures,
The module blocks include '

'Type first module blocks A,

'Type second module block B', '

'Type third module block (C) and the'

A horizontal fitting protrusion 10 or a horizontal fitting recess 20 is formed on a side surface of the module blocks so that the horizontal fitting protrusion 10 or the horizontal fitting protrusion 10 of each module block And the grooves (20) are fitted and extended to each other in a planar direction.
The method according to claim 1,
remind '

'Type first module blocks A,

'Type second module block B', '

'Type third module block (C) and the'

'In the fourth module block D'

A horizontal fitting protrusion 10 is formed on one side surface of one side of the fifth module block E and a horizontal fitting groove 20 is formed on a side surface of the other adjacent side surface of the fifth module block E, Is formed between the first and second ends of the module.
3. The method of claim 2,
'

≪ RTI ID = 0.0 > (F) < / RTI >
3. The method according to any one of claims 1 to 2,
The horizontally-fitting projecting portion 10 '

And the horizontal fitting groove portion 20 is formed so as to correspond to the horizontal fitting projection portion 10,

Shaped " shape.
The method according to claim 1,
On the upper surface of the first module block A,

And the lower surface of which is formed with a vertical protrusion 30, which corresponds to the vertical protrusion 30,

The vertical fitting groove portion 40 is formed in the shape of a '
On the lower surface of the second module block (B)

Wherein the first module block (A) and the second module block (B) are vertically coupled to each other so as to be vertically assembled and expanded.
4. The method according to any one of claims 1 to 3,
Wherein the module blocks are made of expanded polypropylene (EPP) material.
4. The method according to any one of claims 1 to 3,
Wherein the module blocks are formed in different colors to match the image of the assembled three-dimensional structure.
The method according to claim 1,
The number of the first module block A is N, the number of the second module block B is M, the number of the third module block C is L, and the number of the fourth module block D is K, Wherein the N + M value is an integer equal to or greater than 0, the L + K value is an integer equal to or greater than 0, and the N + M + L + K value is an integer equal to or greater than 1.

Images