CN203935621U - Hexagonal blocks - Google Patents

Abstract

The utility model relates to a hexagonal building block, which is formed by combining a plurality of building blocks with different three-dimensional shapes, wherein the basic shape of each building block can be divided into 1 to a plurality of hexagonal units which are formed by injecting in the shape of horizontal and vertical multilayer connection, and the building blocks can be combined with each other by longitudinal stacking in cooperation with corresponding bases and grooves; the base can be replaced, the original number of building blocks are combined in a horizontal matching mode to be stacked and combined with each other, and each building block is formed by a fixed number of hexagonal units, so that the base is matched with the stacking in a longitudinal or horizontal mode to be sorted and combined without any gap, the three-dimensional shape formed by the base is completed, certain difficulty is achieved in stacking and sorting combination, and the purpose of training logical thinking ability can be achieved.

Description

Hexagonal blocks

technical field

The utility model relates to a hexagonal building block, which uses several different three-dimensional building blocks composed of one to several hexagonal units, cooperates with the corresponding base for each hexagonal unit to pass through different positions and stacking sequences, and has the following advantages: A variety of stacking methods can form a three-dimensional shape. the

Background technique

Common educational building blocks sold in the general market are mostly in the shape of square, plate, sphere, etc. Among them, the shape of the square is mainly formed by the extension of its six sides in the X and Y directions, but the structure of the building blocks is all horizontal. Or vertical angles for corresponding combinations, because the human brain is easier to combine building blocks in horizontal or vertical angles, and it is easy to identify when combining, so it may be helpful for children, but this combination of building blocks is too simple, it is not suitable for exercise Relatively weak in logical thinking and strengthening group concepts;

Later, some industry players introduced detachable square building blocks with different shapes and corresponding bases to improve the variability of building block combinations. However, the horizontal and vertical angles used by this type of base and square building blocks are easy to use as long as you use the edge of the base to try. The combination is successful, although compared with the former building block structure, the combination variability and difficulty have been improved, but it is still slightly insufficient. There is still room for further improvement such as the above-mentioned various deficiencies. the

Utility model content

The utility model is a hexagonal building block, which is mainly composed of several building blocks with different three-dimensional shapes. The building block is composed of one to several units. Unit 1 (a1) is connected horizontally with unit 2 (a2), and unit 3 (a3) and unit 4 (a4) are respectively connected on both sides of the connection; building block B (12) has the shape of unit 1 ( b1) is connected horizontally with the second unit (b2), and connects the third unit (b3) and the fourth unit (b4) below; building block C (13), whose shape is the first unit (c1), the second unit (c2) ) and the third unit (c3) are vertically connected, and the fourth unit (c4) is connected to the side of the first unit (c1); the building block D (14), whose shape is the first unit (d1) and the second unit (d2) vertical connection, and after the third unit (d3) is vertically connected to the fourth unit (d4), it is connected to the side of the first unit (d1); the building block E (15), its shape is the first unit (e1), the first After unit 2 (e2) and unit 3 (e3) are vertically connected, unit 4 (e4) is connected to the side of unit 2 (e2); building block F (16), whose shape is unit 1 (f1) and unit 1 After unit 2 (f2) is vertically connected, unit 3 (f3) is connected to the side of unit 2 (f2), unit 4 (f4) is connected to the side of unit 1 (f1); building block G(17), its The shape is such that after the 2nd unit (g2), the 3rd unit (g3) and the 4th unit (g4) are connected to each other, the 1st unit (g1) is connected above the 2nd unit (g2). the

Preferably, the hexagonal building block also includes: a base (18), which is provided with a groove, and the groove has positions A～Z (182～188) for 7 units to be placed, so that different shapes 7 kinds of building blocks (11-17) are vertically placed in the shape of the base, and each layer is stacked with 7 units and 4 layers high, with a total of 28 units. the

Preferably, the said hexagonal building block also includes: a base (19) provided with a groove, the groove allows 7 kinds of building blocks (11-17) to be placed in the base horizontally, stacking 3 layers , the number of each layer is 8, 12, 8 units, a total of 28 units. the

Preferably, the base of said hexagonal building block further includes: a plurality of planes A~J (C1~C10), of which plane A (C1) and plane B (C2), plane C (C3) and plane D ( C4), plane D (C4) and plane E (C5), plane F (C6) and plane G (C7), plane I (C9) and plane J (C10) present an angle of 120 degrees; and plane B (C2) The angle between plane C (C3), plane E (C5) and plane F (C6), plane H (C8) and plane I (C9) is 240 degrees, and the angle formed by multiple planes (C1～C10) is 120 degrees. And the included angle of 240 degrees allows the building blocks A~G (11~17) to remain stable after being placed and easy to take by hand. the

In summary, the implementation of the utility model has the following advantages:

1. Each building block is composed of a fixed number of hexagonal units. When stacked together with the base, it can inspire users to think in a three-dimensional space, imagine and try to stack up the correct combination of arrangements. It has certain training and inspiration effect. the

2. The base can be replaced, and most of the related products on the market are stacked vertically. This utility model allows users to choose building blocks to arrange and combine vertically and horizontally, and then stimulates users to think about building block combinations in different directions. It has a unique The innovative style, the combination of thinking in different directions, and the arrangement and combination of each building block is composed of a fixed number of hexagonal units. When arranging and stacking, it takes more attempts to stack without leaving a vacant three-dimensional shape. the

Compared with the previous technical features, this utility model uses the same number of building blocks, which can be stacked and combined vertically and horizontally according to different bases, and each building block is mainly designed and constructed in a hexagonal shape. The three-dimensional shape formed by the base, in order to achieve this purpose, its combination must leave no gaps, which is difficult for the training of logical thinking and stacking and sorting combinations. the

In order to facilitate a further understanding of the technical means and effects adopted by the utility model to achieve the above-mentioned purpose and features, the preferred embodiments are exemplified and described as follows with reference to the drawings. the

Description of drawings

Fig. 1 is one of structural representations of parts of the present utility model. the

Fig. 2 is a three-dimensional combined schematic view of the utility model. the

Fig. 3 is a schematic diagram of each layer after the stack combination of the present invention. the

Fig. 4 is a schematic diagram of each layer after another stack combination of the present invention. the

Fig. 5 is a perspective view of another embodiment of the utility model. the

Fig. 6 is a schematic cross-sectional view of A-A of another embodiment of the utility model. the

Fig. 7 is a three-dimensional combined schematic view of another embodiment of the utility model. the

Fig. 8 is a schematic diagram of each layer after stacking and assembling according to another embodiment of the present invention. the

Fig. 9 is a schematic view of each layer after another stack combination according to another embodiment of the present invention. the

Fig. 10 is the second structural diagram of parts of the utility model. the

Fig. 11 is the third schematic diagram of the parts of the utility model. the

Fig. 12 is the fourth schematic diagram of the parts of the utility model. the

Fig. 13 is the fifth structural diagram of parts of the present utility model. the

Fig. 14 is the sixth structural diagram of parts of the present utility model. the

Fig. 15 is the seventh schematic diagram of the parts of the utility model. the

【Symbol Description】

10 units

C1～C10 Plane 1～Plane 10

11～17 Building Block A～Building Block G

a1～a4 Unit 1～Unit 4

18 base

b1～b4 Unit 1～Unit 4

181 Groove

c1～c4 unit 1～unit 4

182～188 Position A～Position G

d1～d4 unit 1～unit 4

19 base

e1～e4 Unit 1～Unit 4

191 Groove

f1～f4 unit 1～unit 4

201～208 Position A’～Position H’

g1～g4 unit 1～unit 4

Detailed ways

Usually according to the utility model, the best feasible embodiment, and after cooperating with the drawings in detail, increase the understanding of the utility model; please refer to Fig. 1-shown in Fig. 15, the utility model is a kind of hexagonal building block, And the building blocks A～G (11～17) used are respectively 4 hexagonal units (10) with the shape that horizontal and vertical multi-layers are connected to form the hexagonal building block combination of 7 kinds of different three-dimensional shapes, for more understanding following implementation The positional relationship in the example is explained with the unit (10) as the basic unit. The shapes of each building block are as follows:

Building block A (11), its shape is that the first unit (a1) and the second unit (a2) are connected horizontally, and the third unit (a3) and the fourth unit (a4) are respectively connected on both sides of the connection; building block B ( 12), its shape is that the first unit (b1) and the second unit (b2) are connected horizontally, and the third unit (b3) and the fourth unit (b4) are connected below; the building block C (13), its shape is the first Unit (c1), unit 2 (c2) and unit 3 (c3) are connected vertically, unit 4 (c4) is connected to the side of unit 1 (c1); building block D (14), its shape is unit 1 (d1) is vertically connected to the second unit (d2), and after the third unit (d3) is vertically connected to the fourth unit (d4), it is connected to the side of the first unit (d1); building block E (15), its shape After the 1st unit (e1), the 2nd unit (e2) and the 3rd unit (e3) are vertically connected, the 4th unit (e4) is connected to the side of the 2nd unit (e2); the building block F (16), its shape After unit 1 (f1) is vertically connected to unit 2 (f2), unit 3 (f3) is connected to the side of unit 2 (f2), unit 4 (f4) is connected to unit 1 (f1) Side; building block G (17), its shape is that after the 2nd unit (g2), the 3rd unit (g3) and the 4th unit (g4) are connected to each other, the 1st unit (g1) is connected above the 2nd unit (g2) . the

Please refer to Fig. 1～Fig. 3 and shown in Fig. 10～Fig. 15, a base (18) has groove (181) and can supply building blocks A～G (11～17) when putting into arrangement stack, form and this groove ( 181) The three-dimensional shape of the shape has several changes in its combination mode. It can be seen from the figure that the shape in the groove (181) of the base (18) is formed by connecting 6 hexagonal shapes with the central hexagonal shape with 6 faces. In the groove (181) are respectively position A (182), position B (183), position C (184), position D (185), position E (186), position F (187) and position G (188), by It can be seen that the height formed after stacking is 4 layers, with 7 units (10) in each layer, and a total of 28 units (10). The stacking method is to use the second unit (g2) and the third unit ( After g3) and the fourth unit (g4) correspond to position C (184), position D (185), and position G (188); continue to stack building blocks F (16) and use the second unit (f2) and the third unit (f3) below ) corresponds to position B (183) and position A (182), and the fourth unit (f4) is located above the third unit (g3); continue to stack blocks E (15) and use the third unit (e3) to correspond to position F (187 ); continue to stack building block C (13) using the corresponding position E (186) of the third unit (c3), while the fourth unit (c4) is located above the first unit (g1); continue stacking building block D (14) using the lower Unit 2 (d2) and Unit 4 (d4) are located above Unit 4 (g4) and Unit 4 (f4); continue stacking block B (12) with Unit 3 (b3) and Unit 4 (b4) located Above the 4th unit (e4) and the 3rd unit (f3); continue to stack the building block A (11) and use the 1st unit to the 4th unit (a1, a2, a3, a4) to be located in the 1st unit (c1), the 4th unit (c4), the first unit (d1), and the first unit (e1), the stack has put 7 kinds of building blocks A~G (11~17) into the complete arrangement; the above-mentioned building blocks A can be more clearly understood from the layers in Figure 3 ~G(11~17) sorting combination method. the

Please refer to Figure 4, which is another combination method. Firstly, the first unit to the fourth unit (a1-a4) of building block A (11) correspond to position G (188), position B (183), position C (184), position A (182); continue to stack building block B (12) and use the first unit (b2) and second unit (b2) corresponding to position D (185), position E (186); continue to stack building block D14 to use Unit 2 (d2) corresponds to position F (187), and unit 4 (d4) is located above unit 3 (a3); continue to stack blocks C (13) using unit 1 (c1) and unit 4 (c4) Located above unit 2 (a2) and unit 1 (a1); continue stacking block E(15) with unit 1 (e1) above unit 3 (a3), and unit 4 (e4) at unit 3 Above the unit (b3); continue to stack the building block F(16) to use the 4th unit (f4), the 2nd unit (f2) and the 3rd unit (f3) to be located at the 4th unit (e4), the 4th unit (b4) and the 3rd unit Above unit 1 (d1); continue to stack building block G (17) by using unit 1 (g1), unit 3 (g3) and unit 4 (g4) to be located at unit 4 (c4), unit 3 (f3), On the top of unit 3 (d3), 7 types of building blocks A~G (11~17) have been placed in the stack so far to complete the arrangement. the

See also shown in Fig. 5 ~ Fig. 8, replace with the base (19) of different design, this base (19) can utilize same building blocks A ~ G (11 ~ 17) to change and insert wherein in the horizontal mode, and then improve the utility model. The variability of the sequence combinations of the new building blocks A～G (11～17). The inner side of the base (19) has a groove (191), and the groove (191) has a plurality of planes 1-10 (C1-C10), wherein plane 1 (C1) and plane 2 (C2), plane 3 (C3) and plane 4 (C4), plane 4 (C4) and plane 5 (C5), plane 6 (C6) and plane 7 (C7), plane 9 (C9) and plane 10 (C10) are all intersected by two planes The angle between plane 2 (C2) and plane 3 (C3), plane 5 (C5) and plane 6 (C6), plane 8 (C8) and plane 9 (C9) is 240 degrees. The 120-degree and 240-degree included angles formed by multiple planes 1-10 (C1-C10) allow building blocks A-G (11-17) to be placed into 3 floors, and the number of each floor from bottom to top is 8, 12, 8 units (10) have 28 units (10) in total, and are easy to take, because used building blocks A～G (11～17) are hexagonal in the utility model so each inner angle is 120 degree, when inserting When on the base (19), the above-mentioned plane with an included angle of 120 degrees cooperates with the hexagonal unit (10), so that each building block A～G (11～17) is placed firmly, such as the plane 4 (C4) mentioned in the figure This is the case with the matched hexagonal unit (10) of the 120 degree included angle with the plane 5 (C5). The above-mentioned base (19) shows that it is mainly 3 floors high, and the bottom layer can accommodate 8 hexagonal units (10). The relevant positions of the arrangement and combination can be referred to Figures 7 to 8, which are respectively position A' (201 ), Position B'(202), Position C'(203), Position D'(204), Position E'(205), Position F'(206), Position G'(207), Position H'(208) , when sorting building blocks A～G(11～17), first put building block G(17) using the third unit (g3) corresponding to position D’(204); then place building block F(16) using the second unit (f2 ) corresponds to position H' (208), the first unit (f1) corresponds to position G' (207) and the fourth unit (f4) corresponds to position C' (203); d4) The corresponding position B' (202) and the corresponding position A' (201) of the third unit (d3); then put the building block B (12) and use the corresponding position F' (206) of the third unit (b3) and the first unit (b1) corresponds to the position E'(205), and the bottom layer is placed at this time; then the building block C(13) is placed above the second unit (g2) by the third unit (c3), and the second unit (c2) is located on the second Unit 1 (g1), unit 4 (c4) is located above unit 3 (b3); then block E (15) is placed above unit 3 (f3) by unit 3 (e3), unit 2 (e2) ), unit 4 (e4) is located on the right side of unit 2 (c2) and unit 1 (g1), and unit 1 (e1) is located above unit 4 (b4); finally, block A (11) is used The 3rd unit (a3), the 2nd unit (a2) and the 4th unit (a4) are located above the 3rd unit (d3), the 1st unit (b1), and the 2nd unit (b2), so far, 7 kinds of building blocks have been stacked A～G (11～17) are inserted into the base (19) to complete the arrangement. the

Please refer to Fig. 9, which is another sorting and combining method of the base (19) with the building blocks A ~ G (11 ~ 17), and the building block A (11) utilizes the corresponding position D' (204 ), the second unit (a2) corresponds to the position H' (208); then puts the building block E (15) and uses the first unit (e1) corresponding position C' (203), the second unit (e2) corresponding position B' ( 202), the third unit (e3) corresponds to the position A' (201); then the building block C (13) uses the first unit (c1) corresponding position G' (207), the second unit (c2) corresponding position F' ( 206), the third unit (c3) corresponds to the position E' (205), at this time the lowest layer is placed; then the building block B (12) is located in the third unit by using the second unit (b2) and the fourth unit (b4) (a3) and the first unit (e1), the first unit (b1) and the third unit (b3) are located above the first unit (a1) and the fourth unit (c4); Unit 3 (d3) is located on the right side of unit 1 (b1), unit 4 (d4) and unit 1 (d1) are located on the right side of unit 3 (b3) and unit 4 (c4); then block F( 16) Use the 4th unit (f4) to be located above the 2nd unit (d2), and the 3rd unit (f3) to be located above the 3rd unit (e3); finally put in the building block G (17) and use the 1st unit (g1) and the 3rd unit The 2nd unit (g2) is located above the 2nd unit (c2) and the 3rd unit (c3), and the 4th unit (g4) is located on the right side of the 2nd unit (f2). ~17) put into the base (19) to complete the arrangement. the

To sum up, the hexagonal building blocks of the present utility model have many different combinations, and can also replace different bases and use vertical and horizontal two-way stacking, and then derive different combination arrangements, and even extend the types of building blocks and the number of units, and the base can accommodate The number of installed units can be increased or decreased, resulting in richer and more diverse combinations, so that the utility model can more effectively stimulate users to think and study in a three-dimensional space. the

Claims (4)

1. hexangle type building blocks, it is characterized in that, mainly combined by the building blocks of several different three-dimensional contourings, these building blocks are formed to several unit by 1, each building blocks shape is as follows: building blocks A (11), it is shaped as the 1st unit (a1) and the 2nd unit (a2) level connection joint, connects respectively the 3rd unit (a3) and the 4th unit (a4) in the both sides of junction; Building blocks B (12), it is shaped as the 1st unit (b1) and the 2nd unit (b2) level connection joint, connects the 3rd unit (b3) and the 4th unit (b4) in below; Building blocks C (13), it is shaped as the 1st unit (c1), the 2nd unit (c2) and the 3rd unit (c3) and is vertically connected, and the 4th unit (c4) is connected in the 1st unit (c1) side; Building blocks D (14), it is shaped as the 1st unit (d1) and the 2nd vertical connection of unit (d2), another the 3rd unit (d3), with after the 4th vertical connection of unit (d4), is connected in the 1st unit (d1) side; Building blocks E (15), after it is shaped as the 1st unit (e1), the 2nd unit (e2) and the 3rd unit (e3) and is vertically connected, the 4th unit (e4) is connected in the 2nd unit (e2) side; Building blocks F (16), it is shaped as the 1st unit (f1) with after the 2nd vertical connection of unit (f2), the 3rd unit (f3) is connected in the 2nd unit (f2) side, and the 4th unit (f4) is connected in the 1st unit (f1) side; Building blocks G (17), after it is shaped as the 2nd unit (g2), the 3rd unit (g3) and the 4th unit (g4) and interconnects, the 1st unit (g1) is connected in the 2nd top, unit (g2).

2. hexangle type building blocks as claimed in claim 1, also include: a base (18), be provided with a groove, this groove has position A～Z (182～188) and can put for 7 unit, allow difform 7 kinds of building blocks (11～17) longitudinally to insert this base shape, it is high 4 layers that storehouse goes out every layer of 7 unit, totally 28 unit.

3. hexangle type building blocks as claimed in claim 1, also include: a base (19), is provided with a groove, this groove can allow 7 kinds of building blocks (11～17) laterally to insert this base, storehouse goes out high 3 layers, and its each number of plies amount is 8,12,8 unit, totally 28 unit.

4. hexangle type building blocks as claimed in claim 3, this base also includes: multiple plane A～J (C1～C10), and its plane A (C1) and plane B (C2), plane C (C3) and plane D (C4), plane D (C4) and plane E (C5), plane F (C6) present 120 degree angles with plane G (C7), planar I (C9) with plane J (C10); Plane B (C2) and plane C (C3), plane E (C5) and plane F (C6), plane H (C8) present 240 degree angles with planar I (C9), form 120 degree and 240 degree angles by multiple planes (C1～C10), can allow building blocks A～G (11～17) insert rear maintenance firmly and be easy to take.