CN215741803U - Mutually-embedded building block - Google Patents

Abstract

The utility model discloses an embedded building block, which comprises a plurality of building block monomers, wherein each building block monomer is cuboid, two of the three dimensions of length, width and height are the same, the numerical value of the third dimension is a positive integer multiple of the numerical values of the two same dimensions, each building block monomer is provided with a rectangular groove and a rectangular boss, the length direction of the groove is through, the length of the boss is the same as the length and the width of the groove, the height of the boss is the same as the depth of the groove, and the width of the groove is the positive integer multiple of the width of the boss. The building block single body provided by the utility model has various splicing surfaces, splicing and fixing among the building blocks are realized by mutually embedding and clamping the surfaces, the splicing planes and directions among the building blocks are various, abundant and complex structural forms can be formed, the playability and the interest of the building blocks are improved, and the building block single body is beneficial to the cultivation of the spatial thinking of children and the improvement of the practical ability.

Description

Mutually-embedded building block

Technical Field

The utility model relates to a mutually-embedded building block.

Background

The splicing mode of the existing building blocks is mainly extrusion splicing of a circular boss and a groove. The splicing of the building blocks can only be combined between the boss surface and the concave surface, and the splicing direction between the two building blocks is fixed. Therefore, to splice a specific structure, building blocks with various shapes and structures need to be manufactured according to a determined shape, manufacturing cost is high, and meanwhile, a set of building blocks has fewer changeable splicing forms.

Disclosure of Invention

The utility model aims to provide a mutually-embedded building block, which can be used for splicing various structural shapes by using simple and same building blocks.

In order to achieve the purpose, the utility model adopts the technical scheme that: the utility model provides an each other inlay type building blocks, its includes a plurality of building blocks monomer, every the building blocks monomer is the cuboid form, in its three sizes of length, width, height, two sizes are the same, and the numerical value of third size is the positive integer times of two same size numerical values, every have the recess of rectangle and the boss of rectangle on the building blocks monomer, the length direction of recess link up, the length of boss with the length and the width of recess are the same, the height of boss with the degree of depth of recess is the same, the width of recess is the positive integer times of the width of boss.

Preferably, the overall dimension of the single building block is a × a × b, a groove with a × (n-1) a plane size and a half a depth is formed in one a × b rectangular plane of the single building block, the grooves are symmetrically distributed along the center line of the plane, wherein a and b are side lengths, b = na, and n is an integer.

Further, when n is 2, the building block single body has an overall structure size of a × a × 2a, the building block single body is composed of 2a × a square planes and 4 a × 2a rectangular planes, a groove with a × a plane size and a depth of one half a is formed in the central area of one a × 2a rectangular plane, the grooves are symmetrically distributed along the center line of the plane, and 2 0.5a × a planes and 1 a × a concave surface located in the center are formed on the plane with the groove.

Furthermore, when n is 3, the building block monomer has the overall structure size of a × a × 3a, the building block is composed of 2a × a square planes and 4 a × 3a rectangular planes, a × 2a plane size and a half a depth of a groove are formed in the central area of one a × 3a rectangular plane, the grooves are symmetrically distributed along the center line of the plane, and 2 0.5a × a planes and 1 a × 2a concave surface located in the center are formed on the planes with the grooves.

Furthermore, the bottom of the groove of the single building block body is provided with an outward-expanding groove which is communicated with the upper end surface and the lower end surface of the single building block body and the groove.

Preferably, the building block single bodies are provided with two grooves, and the grooves are separated by a boss.

Preferably, an arc-shaped convex block is arranged on the lower end face of the building block single body.

Due to the application of the technical scheme, compared with the prior art, the utility model has the following advantages: the building block single body provided by the utility model has various splicing surfaces, splicing and fixing among the building blocks are realized by mutually embedding and clamping the surfaces, the splicing planes and directions among the building blocks are various, abundant and complex structural forms can be formed, the playability and the interest of the building blocks are improved, and the building block single body is beneficial to the cultivation of the spatial thinking of children and the improvement of the practical ability.

Drawings

FIG. 1 is a perspective view of a single block of the first embodiment;

FIG. 2 is a perspective view of another perspective of a single block of the first embodiment;

FIG. 3 is a schematic view of a manner in which two building blocks are spliced according to an embodiment one;

FIG. 4 is a schematic view of a manner in which two building blocks are spliced according to an embodiment one;

FIG. 5 is a schematic view of one way of splicing two building blocks according to the first embodiment;

FIG. 6 is a schematic view of a manner in which two building blocks are spliced according to an embodiment one;

FIG. 7 is a schematic view of a manner in which three building blocks are spliced according to an embodiment one;

FIG. 8 is a schematic view of a manner in which three building blocks are spliced according to an embodiment one;

FIG. 9 is a perspective view of a single block of the second embodiment;

FIG. 10 is a schematic view of two single blocks of the first embodiment and one single block of the second embodiment;

FIG. 11 is a perspective view of a single block according to a third embodiment;

FIG. 12 is a perspective view of a single block according to a fourth embodiment;

FIG. 13 is a perspective view of a single block of the fifth embodiment;

FIG. 14 is a perspective view of a single block of the sixth embodiment;

FIG. 15 is a perspective view of a single block of the seventh embodiment;

FIG. 16 is a perspective view of a single block of the eighth embodiment;

reference numerals: 1 is the front surface of the building block; 2 is the top right side; 3 is a groove side surface; 4 is a concave surface; 5 is the upper left side; 6 is the side surface of the building block; 7 is the bottom surface of the building block; 8 is a concave surface of a building block with the side length of 3 a.

Detailed Description

The utility model will be further described with reference to examples of embodiments shown in the drawings to which the utility model is attached.

Each other embedded building block includes a plurality of building block monomers, every the building block monomer is the cuboid form, and in its three sizes of length, width, height, two sizes are the same, and the numerical value of third size is the positive integer multiple of two the same size numerical values, every have rectangular recess and the boss of rectangle on the building block monomer, the length direction of recess link up, the length of boss with the length and the width of recess are the same, the height of boss with the degree of depth of recess is the same, the width of recess is the positive integer multiple of the width of boss.

The building block single body has the external dimension of a multiplied by b, a groove with the plane size of a multiplied by (n-1) a and the depth of one half a is formed in one rectangular plane of the building block single body, the grooves are symmetrically distributed along the center line of the plane, wherein a and b are side lengths, b = na, and n is an integer.

When n is 2, the overall structure size of the building block monomer is a multiplied by 2a, the building block monomer is composed of 2a multiplied by a square planes and 4 a multiplied by 2a rectangular planes, a groove with a multiplied by a plane size and a depth of one half a is formed in the central area of one a multiplied by 2a rectangular plane, the grooves are symmetrically distributed along the central line of the plane, and 2 0.5a multiplied by a planes and 1 a multiplied by a concave surface positioned in the center are formed on the plane with the groove; when n is 3, the building block monomer has the overall structure size of a multiplied by 3a, the building block is composed of 2a multiplied by a square planes and 4 a multiplied by 3a rectangular planes, a multiplied by 2a plane size and a depth of a groove of one half a are arranged in the central area of one a multiplied by 3a rectangular plane, the grooves are symmetrically distributed along the center line of the plane, and 2 0.5a multiplied by a planes and 1 a multiplied by 2a concave surface positioned in the center are formed on the plane with the groove.

The bottom of the groove of the building block single body can be provided with an outward-expanding groove which is communicated with the groove and the upper end surface and the lower end surface of the building block single body; or two grooves are arranged on the building block single body and are separated by a boss; or the lower end surface of the building block monomer is provided with an arc-shaped convex block.

Specifically, the method comprises the following steps:

example one

As shown in fig. 1-2, when n is 2, the building block single body has an overall structure size of a × a × 2a, and is composed of 2a × a square planes and 4 a × 2a rectangular planes, in the central area of one a × 2a rectangular plane, there are grooves with a × a plane size and a depth of one half a, the grooves are symmetrically distributed along the center line of the plane, and 2 0.5a × a planes and 1 a × a concave surface located at the center are formed on the plane with the grooves. As shown in fig. 3-8, fig. 3 shows that two single blocks are embedded into each other in a groove-to-groove manner, so that the two single blocks are spliced into a whole. Fig. 4 shows that the single building blocks 9 are embedded in a manner that end faces of the single building blocks 10 are concave, the end faces of the single building blocks 9 are in an a × a square shape, and the concave faces of the single building blocks 10 are in an a × a square shape. Therefore, the end face of the single building block 9 can still be embedded and clamped with the concave surface of the single building block 10 by rotating 90 degrees along the normal of the center of the end face, so that different splicing bodies are formed. Fig. 5 shows that the front or back of the single building block 9 is embedded with the concave surface of the single building block 10. Because the length of the two sides of the front surface of the building block single body 9 is a, the building block single body can be embedded into the groove of the building block single body 10, and the building block single body 9 can move along the 2a side length direction of the building block single body 9, so that splicing bodies with different structural forms are formed from the surface. Fig. 6 shows that the bottom surface of the single building block 9 and the concave surface of the single building block 10 are embedded into each other, the single building block 9 can move along the 2a side length direction of the single building block 9, and the structural forms of the formed splicing bodies are different due to the difference of the embedded positions of the single building block 9 and the single building block 10. As can be seen from fig. 3, 4, 5 and 6, two identical building block units have various mutually-embedded parts, different embedding angles and adjustable embedding positions, so that various splices can be formed. Fig. 3, fig. 4, fig. 5, and fig. 6 only show some simple insertion ways of the two single building blocks, and do not represent that the two single building blocks only have the above splicing forms. As long as the side of the side length a exists in the single building block, the side length a can be embedded into the concave surface of another single building block. Fig. 7 shows a splicing manner of 3 single building blocks. The width of the upper top surface of one side of the building block single body 12 is 0.5a, and the upper top surface of one side of the other building block single body 13 is attached together to form a plane with the size of a multiplied by a square, and the plane is embedded together with the concave surface of the building block single body 11, so that a new structure is formed. Fig. 8 shows another form of 3-block single body splicing. The bottom surface of the single building block 12 is attached to the bottom surface of the single building block 13 and embedded into the concave surface of the single building block 11. As can be seen from fig. 8 and 9, the concave surface of the single building block may be directly embedded into the surface with the side length a, or may be spliced with the plane with the side length a.

Example two

Fig. 9 is a rectangular parallelepiped with a side length of a × a × 3a, a plane size of a × 2a, and a depth of 0.5 a. The difference between the single blocks of the block of fig. 9 and the single blocks of fig. 1 is that the length of the single blocks of the block is increased from 2a to 3a, and the size of the plane of the groove is increased from a x a to a x 2 a. Fig. 10 shows a splicing of 3 building elements, which comprise a building element 14 with a side length of 3 a. The size of the concave surface of the single building block 14 is a multiplied by 2a, and the concave surface of the single building block 14 can be directly embedded with a surface with the side length of 2a or spliced with a plane with the side length of 2 a.

EXAMPLE III

As shown in fig. 11, the bottom surface of the single building block is a circular arc surface, and the diameter of the circular arc surface can be changed, so that the single building blocks with different heights and shapes are formed. The bottom surface of the single building block can also be a triangular structure or other shapes of structures. The size of the groove structure of the single building block is consistent with that of the original single building block.

Example four

As shown in fig. 12, the recessed groove with a plane size of 0.5a × a and a depth of 0.5a is cut downwards from the recessed surface of the original single block, so that the single block can be spliced with more single blocks in the new recessed groove under the condition that the original recessed groove is embedded with other single blocks, and the splicing form and structure are more diversified.

EXAMPLE five

As shown in fig. 13, the single building block is formed by cutting a groove with a plane size of 0.5a × 2a and a depth of 0.5a downward on the concave surface of the original single building block with a side length of 3a, so as to achieve richness of the splicing structure of the single building block.

EXAMPLE six

As shown in fig. 14, the single building block body realizes the stepped splicing of the single building block bodies, and a first-order concave surface is added on the basis of the original single building block body.

EXAMPLE seven

As shown in FIG. 15, the single building block body comprises two grooves, so that the splicing expansion of the single building block body is realized, and the diversity of the splicing structure of the single building block body is improved. Similarly, the arrangement of the grooves of the single building blocks can be further increased on the basis of the single building blocks, and the single building blocks can be spliced with more building blocks by increasing the number of the grooves.

Example eight

As shown in fig. 16, the splicing type single building block is formed by splicing the single building block shown in fig. 2 and the original structural single building block. Since the single building block body in fig. 2 is further cut into the groove with the plane size of 0.5a × a and the depth of 0.5a on the original concave surface, it can be seen from fig. 6 that after two single building block bodies are spliced into a whole, a new concave surface with the plane size of a × a can be formed, and a new single building block body can be spliced on the newly formed concave surface.

The above embodiments are merely illustrative of the technical ideas and features of the present invention, and the purpose thereof is to enable those skilled in the art to understand the contents of the present invention and implement the present invention, and not to limit the protection scope of the present invention. All equivalent changes and modifications made according to the spirit of the present invention should be covered within the protection scope of the present invention.

Claims (7)

1. The utility model provides a each other inlay type building blocks, its includes a plurality of building blocks monomer, its characterized in that: every building blocks monomer is the cuboid form, and in its three sizes of length, width, height, two sizes are the same, and the numerical value of third size is the positive integral multiple of two same size numerical values, every building blocks monomer is last to have rectangular recess and rectangular boss, the length direction of recess link up, the length of boss with the length and the width of recess are the same, the height of boss with the degree of depth of recess is the same, the width of recess is the positive integral multiple of the width of boss.

2. The interlocking building block of claim 1, wherein: the building block single body has the external dimension of a multiplied by b, a groove with the plane size of a multiplied by (n-1) a and the depth of one half a is formed in one rectangular plane of the building block single body, the grooves are symmetrically distributed along the center line of the plane, wherein a and b are side lengths, b = na, and n is an integer.

3. The interlocking building block of claim 2, wherein: when n is 2, the overall structure size of the building block monomer is a multiplied by 2a, the building block monomer is composed of 2a multiplied by a square planes and 4 a multiplied by 2a rectangular planes, a groove with a multiplied by a plane size and a depth of one half a is arranged in the central area of one a multiplied by 2a rectangular plane, the grooves are symmetrically distributed along the center line of the plane, and 2 0.5a multiplied by a plane and 1 a multiplied by a concave surface positioned in the center are formed on the plane with the groove.

4. The interlocking building block of claim 2, wherein: when n is 3, the building block monomer has the overall structure size of a multiplied by 3a, the building block is composed of 2a multiplied by a square planes and 4 a multiplied by 3a rectangular planes, a multiplied by 2a plane size and a depth of a groove of one half a are arranged in the central area of one a multiplied by 3a rectangular plane, the grooves are symmetrically distributed along the center line of the plane, and 2 0.5a multiplied by a planes and 1 a multiplied by 2a concave surface positioned in the center are formed on the plane with the groove.

5. The interlocking building block of claim 2, wherein: the bottom of the groove of the building block single body is provided with a through outward-expanding groove which is communicated with the groove and is formed in the upper end face and the lower end face of the building block single body.

6. The interlocking building block of claim 1, wherein: the building block single bodies are provided with two grooves which are separated by a boss.

7. The interlocking building block of claim 1, wherein: and an arc-shaped convex block is arranged on the lower end face of the building block monomer.

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