KR200281633Y1 - Sectional cubic block - Google Patents

Abstract

The present invention relates to a prefabricated cube block comprising a multi-layered structural element, the smallest of the structural elements being a base cube, the others being proportional increases in volume based on the base cube, x, y and z. It comprises an axially separated three-walled wall and thus defines an interior space suitable for receiving the next smaller structural element therein. Except for the smallest, each structural element is formed from a plurality of base frames in which the volume is sequentially increased in proportion to the base cube. Each basic frame includes three consecutive right angle portions each included in three surfaces extending in the x, y and z axis directions. This special configuration of the base frame allows the children to freely stack the base frame to create many varying shapes.

Description

Prefabricated Cube Blocks {SECTIONAL CUBIC BLOCK}

The present invention relates to a prefabricated cube block comprising a plurality of structural elements, wherein each of the structural elements forms a layer of the prefabricated cube block and includes a plurality of basic frames. By building up these basic frames, children can unleash their imagination in creating a variety of varied and balanced forms.

Children need proper "activity" as their brains and muscles develop, and as a result, they develop the ability to think and balance. Blocks are most often recommended by specialists as constructive toys, because children observe and manipulate scattered pieces into a finished shape through repeated thinking and assembly. During the process of stacking blocks to form a completed shape, children naturally develop and understand the concept of space, the relationship between individual parts and the whole, and the concept of quantity. With blocks, children can shape and enjoy their imagination. From building safe three-dimensional figures, children train their intellectual skills well. Thus, blocks are toys that are of substantial value to children.

However, a really good set of block toys capable of accomplishing the brain-training goal is not necessarily a group of blocks with different geometries. An ideal set of blocks should preferably contain basic items that make it easy to grasp and stack, making it easy to grasp and stack, creating a variety of interesting, ever-changing, and balanced structures. Unfortunately, such blocks are not easily found in the market.

It is therefore an object of the present invention to provide a prefabricated cube block comprising a plurality of basic members of different sizes but of similar structure, so that the prefabricated cube block can be disassembled into individual parts, and then assembled into these parts to form an unlimited number of three. You can create dimensional shapes. All created forms, on the other hand, are multi-layered, contoured and balanced in structure.

1 is an assembled perspective view of an illustrated five-layer assembled cube block according to a first embodiment of the present invention.

FIG. 2 is a perspective view showing the five-layer assembled cube block of FIG. 1 broken down into five structural elements.

3 shows the first of the five structural elements of FIG. 2 and the largest element seen from the outer side.

4 is an exploded perspective view showing the structural elements of FIG. 3 in five basic frames.

FIG. 5 is a view of the second of the five structural elements of FIG. 2 from the outer side; FIG.

6 is an exploded perspective view showing the structural elements of FIG. 5 in four basic frames.

FIG. 7 is a view of the third of the five structural elements of FIG. 2 from the outer side; FIG.

FIG. 8 is a perspective view illustrating the structural element of FIG. 7 in three basic frames.

FIG. 9 is a view of the fourth of the five structural elements of FIG. 2 from the outer side; FIG.

FIG. 10 is a perspective view of the structural element of FIG. 9 broken down into two basic frames.

11 is an exploded perspective view showing the outermost largest of the five basic frames of the structural element of FIG.

12 is an exploded perspective view showing the second of five basic frames of the structural element of FIG.

FIG. 13 is an exploded perspective view illustrating a third of five basic frames of the structural element of FIG. 3. FIG.

14 is an exploded perspective view showing a fourth of five basic frames of the structural element of FIG.

FIG. 15 is an exploded perspective view showing the sequence of assembling the different basic frames of FIGS. 4, 6, 8 and 10 to make the first specific shape.

16 is an assembled perspective view of a first shape formed from the basic frame of FIG. 15.

FIG. 17 is an exploded perspective view showing the sequence of assembling the different basic frames of FIGS. 4, 6, 8 and 10 to make a second specific shape.

18 is an assembled perspective view of a second shape formed from the basic frame of FIG. 17.

FIG. 19 is an exploded perspective view showing the sequence of assembling the different basic frames of FIGS. 4, 6, 8 and 10 to make a third specific shape.

20 is an assembled perspective view of a third shape formed from the basic frame of FIG. 19.

21 is an assembled perspective view of the illustrated five-layer assembled cube block according to the second embodiment of the present invention.

FIG. 22 is a perspective view exploded into five structural elements of the five-layer assembled cube block of FIG. 21; FIG.

FIG. 23 shows the first of the five structural elements of FIG. 22 and the largest element from the outside.

24 is a perspective view illustrating the structural elements of FIG. 23 in five basic frames.

FIG. 25 is a view of the second of the five structural elements of FIG. 22 from the outside.

FIG. 26 is an exploded perspective view showing the structural elements of FIG. 25 in four basic frames.

FIG. 27 is a view of the third of the five structural elements of FIG. 22 from the outer side; FIG.

28 is an exploded perspective view showing the structural elements of FIG. 27 broken down into three basic frames.

FIG. 29 is a view of the fourth of the five structural elements of FIG. 22 from the outer side; FIG.

30 is a perspective view illustrating the structural elements of FIG. 29 in two basic frames.

31 is an assembled perspective view of the illustrated five-layer assembled cube block according to the third embodiment of the present invention.

FIG. 32 is a perspective view exploded into five structural elements of the five-layer assembled cube block of FIG.

33 is the first of the five structural elements of FIG. 32 and is viewed from the outer side.

FIG. 34 is a perspective view illustrating the structural elements of FIG. 33 in five basic frames.

FIG. 35 is a view of the second of the five structural elements of FIG. 32 from the outside.

FIG. 36 is a perspective view illustrating the structural elements of FIG. 35 in four basic frames.

FIG. 37 shows the third of the five structural elements of FIG. 32 from the outside.

FIG. 38 is a perspective view illustrating the structural element of FIG. 37 in three basic frames.

FIG. 39 shows the fourth of the five structural elements of FIG. 32 from the outside.

FIG. 40 is a perspective view of the structural element of FIG. 39 broken down into two basic frames. FIG.

In order to achieve the above and another object, the prefabricated cube block of the present invention mainly comprises a multi-layered structural element, the smallest of which is the basic cube and the others are proportionally increased based on the basic cube. These include a wall of three sides extending separately in the x, y and z-axis directions and thus defining an interior space suitable for receiving the next smaller structural elements therein. Except for the smallest, each structural element is formed from a plurality of base frames in which the volume is sequentially increased in proportion to the base cube. Each of the base frames other than the base cube is contained within the cube of the virtual cube and consists of two adjacent edges on each side of the cube of the virtual cube. That is, each of the basic frames other than the basic cube includes three consecutive rectangular portions included in three surfaces extending in the x, y, and z-axis directions, respectively. This special configuration of the base frame allows the children to freely stack the base frame to create many varying shapes.

The construction and technical means employed to achieve the above or other objects in the present invention can be best understood by the following detailed description of the preferred embodiments and the corresponding drawings.

Please refer to FIG. 1 which shows a prefabricated cube block according to a first embodiment of the present invention. The prefabricated cube block consists of a plurality of structural elements. Each structural element forms a layer of prefabricated cube blocks. The number of structural elements can be freely increased or decreased. In the prefabricated cube block shown in FIG. 1, only five structural elements are included for the convenience of description of the present invention.

The prefabricated cube block of FIG. 1 is assembled from five layers or five structural elements A, B, C, D and E with proportionately reduced volume. 2 is an exploded perspective view showing these five structural elements. As shown in Fig. 2, the structural element A is the largest first of these five structural elements, and the structural element E is the smallest fifth to form the basic cube in the prefabricated cube block of the present invention. The first, second, third and fourth structural elements A, B, C and D are all three-walled walls (A01, A02, A03), (B01, B02, B03, extending in three directions in the x, y and z axes ), (C01, C02, C03) and (D01, D02, D03) and thus form respective inner spaces A04, B04, C04 and D04 for the structural elements A, B, C and D. The structural elements B, C, D and E can in turn be accommodated in the interior spaces A04, B04, C04 and D04, thus forming a complete prefabricated cube block of the present invention as shown in FIG.

3, 5, 7 and 9 show the structural elements A, B, C and D sequentially from the outside. These structural elements A, B, C and D can be broken down into several basic frames. 4 shows the first structural element A decomposed into five basic frames, in which the five basic frames are A10, A20, A30, A40 and A50 in order from the outermost largest to the smallest innermost. Is indicated. The smallest basic frame A50 at this time is also the smallest structural element E and basic cube in the prefabricated cube block of the present invention.

See FIGS. 2, 5 and 6. Similarly, the second structural element B can be broken down into four basic frames labeled B10, B20, B30 and B40 in order from the outermost largest to the smallest innermost. The smallest base frame B40 at this time is also the smallest structural element E and the base cube in the prefabricated cube block of the present invention.

See FIGS. 2, 7 and 8. Similarly, the third structural element C can be broken down into three basic frames labeled C10, C20 and C30 in order from the outermost largest to the smallest innermost. The smallest element frame C30 at this time is also the smallest structural element E and basic cube in the prefabricated cube block of the present invention.

See FIGS. 2, 9 and 10. Similarly, the fourth structural element D can be broken down into two basic frames labeled D10 and D20 in order from the outermost largest to the smallest innermost. The smallest base frame D20 at this time is also the smallest structural element E and the base cube in the prefabricated cube block of the present invention.

4, 6, 8 and 10, any base frame of A10, A20, A30, A40, B10, B20, B30, C10, C20 and D10 that is not a base cube may be included in the virtual cube. It consists of two adjoining corners on each side of the virtual cube. That is, each of the basic frames A10, A20, A30, A40, B10, B20, B30, C10, C20, and D10 includes three consecutive right angle portions each included in three planes extending in the x, y, and z-axis directions. . The base frames A10, A20, A30, A40, B10, B20, B30, C10, C20 and D10 also sequentially define the inner spaces A11, A21, A31, A41, B11, B21, B31, C11, C21 and D11. In addition, the basic frames A10, A20, A30, B10, B20 and C10 define openings, respectively, through which the internal spaces A11, A21, A31, B11, B21 and C11 respectively represent the basic frames A10, A20, A30, B10, B20 and The outer and inner sides of C10 meet.

See FIGS. 4, 11, 12, 13 and 14. The base frames A10, A20, A30 and A40 are all assembled from a plurality of the smallest base frames A50, which is the same as the smallest structural element E of the prefabricated cube block of the present invention. As mentioned above, the smallest basic frames B40, C30 and D20 are all identical to the smallest structural element E. The smallest structural element E is provided with at least one insertion bar E10 and one or more insertion holes E20 on six sides. When the plurality of pieces of the smallest structural element E are connected to each other in such a manner that one insertion bar E10 of the rear structural element E is inserted into the insertion hole E20 of the front structural element E as shown in Figs. Frame A10; A20 and B10; A30, B20 and C10; And A40, B30, C20 and D10 are formed, respectively.

By stacking or assembling the basic frame and / or structural elements of the prefabricated cube block of the present invention in various ways and orders, it is possible to make an unlimited number of shapes in a balanced state at all times. Several such original, interesting and balanced shapes are illustrated in FIGS. 15-20.

See FIG. 15. The basic frames A20, A30, A40 and A50 of the first structural element A are located sequentially in the internal spaces A11, A21, A31 and A41 defined within the basic frames A10, A20, A30 and A40, but are defined by these basic frames. The basic frames A10, A20, A30, A40 and A50 are stacked one by one from bottom to top in order to form the first unit. Similarly, the base frames B20, B30 and B40 of the second structural element B are placed sequentially in the interior spaces B11, B21 and B31 defined within the base frames B10, B20 and B30 but within the opening defined by this base frame. The base frames B10, B20, B30 and B40 are thus stacked one by one from bottom to top in order from the largest to the smallest to form a second unit. Similarly, the base frames C20 and C30 of the third structural element C are sequentially positioned in the inner spaces C11 and C21 defined within the base frames C10 and C20, but are not coupled within the openings defined by these base frames, and thus The base frames C10, C20 and C30 are stacked one by one from the bottom up from the largest to the smallest to form a third unit. Then, the second unit is stacked on the first unit, the third unit is stacked on the second unit, the base frame D10 is stacked on the third unit, and within the space D11 defined by the base frame D10. The base frame D20 (ie structural element E) is stacked, resulting in the first specific shape as shown in FIG. 16. In this shape, each upper unit can be projected in a central position in front of the lower unit, providing a shape with a multi-layered stepped contour and also providing a well-divided space concept.

17 and 18 show a second specific shape assembled from structural elements A, B, C, D and E. FIGS. As shown in Fig. 17, the basic frames B20, B30 and B40 of the second structural element B are sequentially positioned in the internal spaces B11, B21 and B31 defined within the basic frames B10, B20 and B30, but by these basic frames. It is not coupled within the defined openings, and thus the base frames B10, B20, B30 and B40 are stacked one by one from bottom to top in order from the largest to the smallest to form the first unit. Similarly, the base frames C20 and CB30 of the third structural element C are sequentially positioned in the inner spaces C11 and C21 defined within the base frames C10 and C20, but are not coupled within the openings defined by these base frames, and thus The base frames C10, C20 and C30 are stacked one by one from the bottom up from the largest to the smallest to form a second unit. Then, the second unit is stacked on the first unit, and the base frames D10 and D20 are stacked on the second unit sequentially to form a pyramid shape. The basic frames A20, A30, A40 and A50 of the first structural element A are then sequentially positioned in the internal spaces A11, A21, A31 and A41 defined within the basic frames A10, A20, A30 and A40. It is not coupled in the openings defined by them, so that the base frames A10, A20, A30, A40 and A50 are stacked one by one from bottom to top in order from the largest to the smallest to form a third unit. The third unit then moves to the position just above the pyramid-shaped base frame D20. At this point, the maximum base frame A10 goes down to position above base frame B10, the base frame A20 goes down to position above base frame B20, and the base frames A30, A40 and A50 sequentially move through base frames D10 and D20. Going down to locate, ultimately form a second specific shape in which protrusions and depressions are arranged alternately as shown in FIG. 18.

19 and 20 illustrate a third specific shape assembled into some basic frames of the present invention. See FIG. 19. The base frames A10, A20 and A30 are sequentially connected to each other longitudinally using the base frames A40, B30 and C20 as connectors between them, so that the base frames A10, A20 and A30 are internal to the base frames A40, B30 and C20. It is individually seated and supported in spaces A41, B31 and C21. Then, as shown in FIG. 20, the base frame D10 and the minimum structural element E are sequentially stacked on the base frame A30 to obtain a third specific shape.

Figure 21 shows a prefabricated cube block according to a second embodiment of the present invention. The prefabricated cube block also consists of a plurality of structural elements. Each structural element forms a layer of prefabricated cube blocks. The number of structural elements can be freely increased or decreased. In the prefabricated cube block shown in FIG. 21, only five structural elements are included for the convenience of description of the present invention.

The prefabricated cube block of FIG. 21 is assembled from five layers or five structural elements F, G, H, I and J whose volume is proportionally reduced. 22 is an exploded perspective view showing these five structural elements. As shown in Fig. 22, the structural element F is the largest first of these five structural elements, and the structural element J is the smallest fifth and forms the basic cube in the prefabricated cube block of the present invention. The first, second, third and fourth structural elements F, G, H and I are all three-walled walls (F01, F02, F03), (G01, G02, G03) extending in three directions in the x, y and z axes ), (H01, H02, H03) and (I01, I02, I03) and thus form respective internal spaces F04, G04, H04 and I04 for the structural elements F, G, H and I. The structural elements G, H, I and J can in turn be accommodated in the inner spaces F04, G04, H04 and I04, thus forming a complete prefabricated cube block of the present invention as shown in FIG.

23, 25, 27 and 29 show the structural elements F, G, H and I sequentially seen from the outer side. These structural elements F, G, H and I can be broken down into several basic frames. Figure 24 shows the first structural element F decomposed into five basic frames, in which the five basic frames are F10, F20, F30, F40 and F50 in order from the outermost largest to the smallest innermost. Is indicated. The smallest base frame F50 at this time is also the smallest structural element J and the base cube in the prefabricated cube block of the present invention.

See FIGS. 22, 25 and 26. Similarly, the second structural element G can be decomposed into four basic frames labeled G10, G20, G30 and G40 in order from the outermost largest to the smallest innermost. The smallest base frame G40 at this time is also the smallest structural element J and the base cube in the prefabricated cube block of the present invention.

See FIGS. 22, 27 and 28. Similarly, the third structural element H can be broken down into three basic frames, labeled H10, H20 and H30, from the outermost largest to the smallest innermost. The smallest element frame H30 is also the smallest structural element J and basic cube in the prefabricated cube block of the present invention.

See FIGS. 22, 29 and 30. Similarly, the fourth structural element I can be broken down into two basic frames labeled I10 and I20 in order from the outermost largest to the smallest innermost. The smallest base frame I20 at this time is also the smallest structural element J and the base cube in the assembled cube block of the present invention.

As shown in FIGS. 24, 26, 28 and 30, any base frame of F10, F20, F30, F40, G10, G20, G30, H10, H20 and I10 that is not a base cube may be included in the virtual cube. It consists of two adjoining corners on each side of the virtual cube. That is, each of the basic frames F10, F20, F30, F40, G10, G20, G30, H10, H20, and I10 includes three consecutive right angle portions respectively included in three planes extending in the x, y, and z axis directions. . The base frames F10, F20, F30, F40, G10, G20, G30, H10, H20 and I10 also sequentially define the inner spaces F11, F21, F31, F41, G11, G21, G31, H11, H21 and I11. In addition, the basic frames F10, F20, F30, G10, G20 and H10 define openings, respectively, through which the internal spaces F11, F21, F31, G11, G21 and H11 respectively represent the basic frames F10, F20, F30, G10, G20 and The outer side and the inner side of H10 meet.

The base frames F10, F20, F30, F40, G10, G20, G30, H10, H20 and I10 forming the gross are provided with unit marks using the minimum structural element J as one unit over their three right angled portions. These unit marks allow children to actually understand the basic structures contained within the three-dimensional structure and the number of units in those basic structures, to encourage children to read and discuss different mathematical units and numbers accurately, and to Train to describe the shape of the three-dimensional structure.

Figure 31 shows a prefabricated cube block according to a third embodiment of the present invention. The prefabricated cube block also consists of a plurality of structural elements. Each structural element forms a layer of prefabricated cube blocks. The number of structural elements can be freely increased or decreased. In the prefabricated cube block shown in FIG. 31, only five structural elements are included for the convenience of description of the present invention.

The prefabricated cube block of FIG. 31 is assembled from five layers or five structural elements K, L, M, N and O in which the volume is proportionally reduced. 32 is an exploded perspective view showing these five structural elements. As shown in FIG. 32, the structural element K is the largest first of these five structural elements, and the structural element O is the smallest fifth, forming a basic cube in the prefabricated cube block of the present invention. The first, second, third and fourth structural elements K, L, M and N are all three-walled walls (K01, K02, K03), (L01, L02, L03 extending in three directions in the x, y and z axes ), (M01, M02, M03) and (N01, N02, N03) and thus form respective internal spaces K04, L04, M04 and N04 for the structural elements K, L, M and N. Structural elements L, M, N and O may in turn be accommodated in the inner spaces K04, L04, M04 and N04, thus forming a fully assembled cube block of the present invention as shown in FIG.

33, 35, 37 and 39 sequentially show the structural elements K, L, M and N seen from the outer side. These structural elements K, L, M and N can be broken down into several basic frames. 34 shows the first structural element K divided into five basic frames, with five basic frames K10, K20, K30, K40 and K50 in order from the outermost largest to the smallest innermost. Is indicated. At this time, the smallest basic frame K50 is also the smallest structural element O and basic cube in the prefabricated cube block of the present invention.

See FIGS. 32, 35, and 36. Similarly, the second structural element L can be broken down into four basic frames labeled L10, L20, L30 and L40 in order from the outermost largest to the smallest innermost. The smallest base frame L40 at this time is also the smallest structural element O in the prefabricated cube block of the present invention and is the base cube.

See FIGS. 32, 37 and 38. Similarly, the third structural element M can be decomposed into three basic frames labeled M10, M20 and M30 in order from the outermost largest to the smallest innermost. The smallest element frame M30 is also the smallest structural element O and basic cube in the prefabricated cube block of the present invention.

See FIGS. 32, 39, and 40. Similarly, the fourth structural element N can be broken down into two basic frames labeled N10 and N20 in order from the outermost largest to the smallest innermost. The smallest base frame N20 at this time is also the smallest structural element O in the prefabricated cube block of the present invention and is the base cube.

34, 36, 38 and 40, any base frame of K10, K20, K30, K40, L10, L20, L30, M10, M20 and N10 that is not a base cube may be included in the virtual cube. It consists of two adjoining corners on each side of the virtual cube. That is, each of the basic frames K10, K20, K30, K40, L10, L20, L30, M10, M20, and N10 includes three consecutive right angle portions each included in three planes extending in the x, y, and z-axis directions. . The base frames K10, K20, K30, K40, L10, L20, L30, M10, M20 and N10 also sequentially define the inner spaces K11, K21, K31, K41, L11, L21, L31, M11, M21 and N11. In addition, the basic frames K10, K20, K30, L10, L20 and M10 define openings, respectively, and through them the internal spaces K11, K21, K31, L11, L21 and M11 are respectively the basic frames K10, K20, K30, L10, L20 and The outer and inner sides of M10 meet.

While the present invention has been described through some preferred embodiments, the illustrated embodiments are limited to only five layers for convenience of description. In the prefabricated cube block of the present invention, the number of layers may be increased or decreased, and the size may be proportionally enlarged or reduced. In addition, many changes and modifications may be made without departing from the scope of the present invention without departing from the scope and spirit of the present invention.

The usefulness of the prefabricated cube block of the present invention is described below.

First, all the basic frames constituting the prefabricated cube block of the present invention have a completely symmetrical shape, and thus, the center of gravity is very stable, so it is easy to stack these basic frames and is easy to balance. Children can freely assemble the base frame to fit their imagination in a variety of varying, solid and stable shapes.

Second, since the basic frame of the prefabricated cube block of the present invention has a proportional increase or decrease in volume and can be spatially associated, as a result, they can be constantly assembled into a cube. Children can learn about the concept of substitution in three-dimensional space and the effects achieved through such spatial substitution through these proportional basic frames. Children can train to do mathematical activities and to quickly read the number of elements in a three-dimensional structure.

Third, the basic frame of the prefabricated cube block of the present invention has a cute and symmetrical shape, and can be connected in different ways to create many fantastic and unexpected shapes showing a multi-layered well-woven appearance attractive to both children and adults.

Fourth, through the process of assembling the basic frame of the present invention it can create a number of surprisingly interesting shapes ranging from simple to highly complex structures. The invention is therefore suitable for people of all ages.

Claims (5)

A prefabricated cube block comprising two or more structural elements, The smallest of the structural elements is a basic cube of a prefabricated cube block, the other of the structural elements is a proportional increase in volume sequentially with the basic cube as a unit of measurement; All structural elements except the base cube define an interior space for each structural element, including walls of three sides separated and extended in three different directions on the x, y and z axes; And, proportionally smaller in the structural elements can be applied or removed to fit within the inner space of the next largest of the structural elements so that the structural elements start from the smallest and the inner space of the next largest one. Can be accommodated sequentially to form a complete prefabricated cube block; And All structural elements each consist of a plurality of basic frames, the smallest of the basic frames of each structural element being the same as the smallest structural element, the basic cube of the prefabricated solid block, and the other of each structural element being the basic cube. Volume is sequentially increased proportionally with as a unit of measurement; Each non-base cube base frame is contained within the cube of the virtual cube and consists of two adjacent corners on each side of the cube of the virtual cube, i.e. each non-base cube base frame extends in the x, y and z-axis directions. It includes three connected right-angle parts, each included on three sides, thereby defining the internal space for each base frame together, and each of the base frames, except the smallest and the second smallest of all the base frames, defines the central opening. And the inner space meets the inner and outer surfaces of each of the basic frames through an opening; The base frame is a prefabricated cube block, characterized in that can be stacked freely to obtain a variable shape. The prefabricated cube block of claim 1, wherein all of the base frames are integrally formed. 3. A prefabricated cube block according to claim 2, wherein all base frames other than the base cube are provided with a unit mark using the smallest base cube as one unit on each of their three right angled portions. 2. The prefabricated cube block of claim 1 wherein all of the base frames other than the base cube are formed by connecting a predetermined number of the smallest base frames (ie, the base cube) to each other. 5. The base cube of claim 4, wherein the base cube, which is the smallest unit of the base frame, is provided with an insertion bar on at least one of its six sides, one or more insertion holes are provided on the other five sides thereof, and each of the insertion bars is any Prefabricated cube block, characterized in that it is firmly inserted into one or more insertion holes.