CN217697922U - Module assembly capable of splicing box body - Google Patents

Abstract

The utility model discloses a can splice module assembly of box, module assembly's processing base member is the flat structure of square on the basis of base member, the wave mosaic structure of connecting adjacent module assembly, its characterized in that are seted up to this module assembly's four sides: the wave splicing structures are formed by connecting lugs and grooves which are equal in number and alternately appear in sequence, and the lugs and the grooves are of rectangular structures; meanwhile, the wave splicing structures on the four sides of the module assembly are rotationally symmetrical by taking the center of the module assembly as a fixed point. The splicing of the box body structure can be realized by utilizing a plurality of module assemblies of the utility model with the same specification, for manufacturers, the box body structure consisting of the utility model can be manufactured, only a mould with one specification can be designed, and the manufacturing cost is saved; for a user, the splicing can be completed only by adapting the concave-convex structures among the module components, so that the splicing efficiency is improved, and the splicing process is simpler and easier.

Description

Module assembly capable of splicing box body

Technical Field

The utility model relates to a life field and building materials field specifically are a can splice module components of box.

Background

The splicing type box body can be freely spliced and disassembled, is convenient to store and the like, and is widely applied to the living fields of furniture, toys and the like and some industrial fields. The existing splicing type box body has some defects that the box body structure can be assembled in a three-dimensional mode only by using various module assemblies, for example, a multifunctional interpenetration splicing maze with the bulletin number of CN 214808439U has the advantages that the basic outlines of different module assemblies are similar, but the concave-convex structures at the edge connecting parts are different, and the box body structure is not well distinguished without special marks. For a user, the structural design may need the guidance of a drawing to quickly determine the position of the corresponding module assembly in a finished product, so that the splicing efficiency is reduced. If the structure design is applied to the building block toy, for some young children without patience or lack of spatial thinking, the interest of assembly can be lost quickly, and the intelligent development effect cannot be achieved. Most of the existing building block toys consisting of single module components can only be spliced along one direction or spliced into a plane, and the three-dimensional splicing of a box-type structure cannot be realized.

SUMMERY OF THE UTILITY MODEL

To the not enough among the prior art, the technical purpose of the utility model is to design a novel module group of splicing the box, utilize a plurality of these module groups to splice into the box structure.

The technical scheme of the utility model is that:

the utility model provides a can splice module assembly of box, module assembly's processing base member is the dull and stereotyped structure of square on the basis of base member, the wave mosaic structure who connects adjacent module assembly is seted up to this module assembly's four sides, its characterized in that:

the wave splicing structures on any side of the module assembly are formed by connecting lugs and grooves which are equal in number and alternately appear in sequence, the lugs and the grooves are both rectangular structures, and the total number of the lugs and the grooves is more than 4; meanwhile, the wave splicing structures on the four sides of the module assembly are rotationally symmetrical by taking the center of the module assembly as a fixed point;

if the extending direction parallel to the module component edge is the width direction, the extending direction perpendicular to the module component edge is the depth direction of the convex height or the groove, then in the wave splicing structure on any edge of the module component: all the grooves have equal width and equal depth, and the depth is equal to the thickness n of the plate body of the module assembly; the heights of all the bumps are equal, the widths of the bumps at the non-tail end positions and the grooves are equal, and the thickness n of 1 plate body is reduced compared with the widths of other bumps;

the lug at the tail end position refers to a lug which is positioned at a corner and is connected with the groove at the tail end position in the wavy splicing structure of the adjacent edge.

On the basis of the scheme, the further improved or preferable scheme also comprises the following steps:

further, in the wave splicing structure on any side of the module component, when the total number of the convex blocks and the grooves is more than or equal to 6:

the same side of at least two non-tail end position convex blocks is provided with a limit convex point or a limit concave point matched with the limit convex point, and the limit convex points and the limit concave points are alternately distributed.

Furthermore, the limit salient point is a solid hemispherical protrusion, and the limit concave point is a hemispherical groove matched with the limit concave point.

Furthermore, in the wave splicing structure on any side, the total number of the convex blocks and the grooves is 6, that is, the wave splicing structure on any side comprises a first convex block, a second convex block and a third convex block, wherein the third convex block is the convex block at the tail end position, the side surface of the first convex block close to the third convex block is provided with the limiting convex point, and the side surface of the second convex block close to the third convex block is provided with the limiting concave point.

The utility model has the advantages that:

utilize a plurality of the same specifications the utility model discloses modular component can realize the concatenation to the box structure, the box structure can be the cube, also can be the cuboid, and the size can be adjusted along with modular component's quantity. For manufacturers, the box body structure formed by the utility model can be manufactured, only a mould with one specification can be designed, and the manufacturing cost is saved; to the user, as long as the concave-convex structure adaptation between each modular component, can accomplish the concatenation, saved the step of confirming modular component spatial position in the finished product, improved concatenation efficiency, also make the concatenation process simple and easy more, work as the utility model relates to a when being used for building blocks toy or teaching aid, children can assemble and dismantle very easily, to understanding plane figure, stereograph, development space imagination can provide effective support.

Drawings

Fig. 1 is a schematic diagram of a front structure of an embodiment of the present invention;

fig. 2 is a schematic diagram of a back structure of the embodiment of the present invention;

fig. 3 is a schematic diagram of a side structure of an embodiment of the present invention;

fig. 4 is a schematic view of a three-dimensional structure of an embodiment of the present invention;

FIG. 5 is a schematic diagram of the distribution of the limiting protrusions and the limiting indentations in the embodiment of the present invention;

FIG. 6 is a schematic structural view of a limiting convex point and a limiting concave point in an embodiment of the present invention;

fig. 7 is a first usage reference diagram of the present invention;

fig. 8 is a second usage reference diagram of the present invention;

fig. 9 is a third use reference diagram of the present invention.

Detailed Description

The present invention will be described in detail with reference to the accompanying drawings.

As shown in FIG. 1, the basic contour of the module assembly is square (dotted line), and on the basis of the basic contour, the four sides of the module assembly are provided with wave splicing structures for connecting adjacent module assemblies.

The wave splicing structures on the four sides of the module assembly are rotationally symmetrical by taking the center of the module assembly as a fixed point, namely the wave splicing structure on any side rotates 90 degrees by taking the center and can be superposed with the wave splicing structures on the adjacent sides, and the wave splicing structures belong to one kind of special symmetry.

The wave mosaic structure equals by quantity, and lug and the recess that appears in turn connect gradually and constitute, just lug and recess are the cuboid structure. Typically, the total number of projections and recesses is greater than 4.

The utility model discloses a manufacturing idea is with a square panel, every limit falls into the even number equal parts that is greater than 2, like 4, 6, 8 \8230, \8230, etc., with 2, 4, 6, 8 \8230, \8230, the share cuts out a little rectangle, (can also keep 2, 4, 6, 8 \8230, \8230, the share, at 1, 3, 5, 7 \8230, the share cuts out a little rectangle), forms a plurality of open slots that the degree of depth is panel thickness, and after carrying out same processing on every limit, obtain to have wave mosaic structure, and the panel that every limit structure is the same.

Taking the embodiment shown in fig. 1 and 5 as an example, in the wave splicing structure on any side, the total number of the bumps and the grooves is 6, that is, the wave splicing structure on any side includes a first bump 1, a second bump 2 and a third bump 3, and the first groove, the second groove and the third groove are respectively arranged on the sides of the three bumps in the same direction.

If the width direction parallel to the extending direction of the edges of the module assemblies (or the edges of the plates) is set, and the height of the bump or the depth direction of the groove perpendicular to the extending direction of the edges of the module assemblies (or the edges of the plates) is set, in the wave splicing structure on any edge of the module assemblies:

the widths of the first lug, the second lug and the three grooves are all

The heights of the three bumps and the depths of the three grooves are both n (the heights of the bumps are the depths of the grooves), and the n is the thickness of the square plate; meanwhile, the third bump 3 at the end position is reduced by 1 thickness n compared with the width values of the bumps at other positions due to the engagement with the first grooves at the adjacent sides.

The module component with the structural characteristics can be spliced into a cubic structure and a cuboid structure, and can be tiled naturally, as shown in fig. 7, 8 and 9, and is suitable for implementation and application in building block toys or teaching aid products.

On the basis of the above embodiment, a further improved scheme further includes:

the module component is made of plastic and other materials with better toughness, when the total number of the convex blocks and the grooves is more than or equal to 6 in the wave splicing structure on any side, the same side surface of at least two convex blocks at non-tail end positions is provided with limiting convex points 4 or limiting concave points 5 matched with the convex points, and the limiting convex points 4 and the limiting concave points 5 alternately appear. When a plurality of module assemblies are assembled together, the limit salient point 4 of one module assembly is embedded in the limit concave point 5 of the other module assembly and is restrained by the other surface of the corresponding groove, and the limit salient point 4 and the limit concave point 5 cannot be separated easily. Utilize spacing bump 4 and spacing pit 5 can further strengthen modular component's joint strength, make modular component except being fit for using in building blocks class toy or teaching aid product, can also splice out the box structure that is fit for uses such as life is accomodate, construction.

In the specific embodiment shown in fig. 2, 3 and 5, in the wave splicing structure on any side: the first bump 1 is provided with a limit convex point 4 on one side close to the third bump 3, and the second bump 2 is provided with a limit concave point 5 on one side close to the third bump 3.

Considering that the limit salient points 4 are worn during repeated assembly and disassembly, the limit salient points 4 are preferably designed to be solid hemispherical bulges, so that the wear resistance of the product can be effectively improved, and the limit concave points 5 are matched hemispherical grooves, as shown in fig. 6.

Meanwhile, a structure different from the other surface is processed on one side plate surface of the module assembly to distinguish the front side and the back side, and a user can quickly correct the orientation of the module assembly by the aid of the criss-cross groove structure shown in fig. 1. Taking 6 module assemblies spliced into a cube as an example, all the modules can be spliced and formed with the front faces facing outwards or the back faces facing outwards.

Above only the utility model discloses an it is preferred embodiment, the utility model discloses a scope of protection not only limits in above-mentioned embodiment, and the all belongs to the utility model discloses a technical scheme under the thinking all belongs to the utility model discloses a scope of protection. It should be noted that various modifications and decorations can be made by those skilled in the art without departing from the principle of the present invention, and the scope of the present invention should be considered as the protection scope of the present invention.

Claims (4)

1. The utility model provides a can splice module assembly of box, module assembly's processing base member is the dull and stereotyped structure of square on the basis of base member, the wave mosaic structure who connects adjacent module assembly is seted up to this module assembly's four sides, its characterized in that:

the wave splicing structures on any side of the module assembly are all formed by connecting lugs and grooves which are equal in number and alternately appear in sequence, the lugs and the grooves are all rectangular structures, and the total number of the lugs and the grooves is more than 4; meanwhile, the wave splicing structures on the four sides of the module assembly are rotationally symmetrical by taking the center of the module assembly as a fixed point;

if the extending direction parallel with the module component edge is the width direction, the extending direction vertical with the module component edge is the depth direction of the raised height or the groove, then in the wave splicing structure on any edge of the module component: all the grooves have equal width and equal depth, and the depth is equal to the thickness n of the plate body of the module assembly; the heights of all the bumps are equal, the widths of the bumps at the non-tail end positions and the grooves are equal, and the thickness n of 1 plate body is reduced compared with the widths of other bumps;

the convex block at the tail end position is a convex block which is positioned at the corner and is connected with the groove at the tail end position in the wave splicing structure of the adjacent edges.

2. The module assembly of claim 1, wherein when the total number of the projections and the recesses in the wave splicing structure on either side of the module assembly is greater than or equal to 6:

the same side of at least two non-tail end position convex blocks is provided with a limit convex point (4) or a limit concave point (5) matched with the limit convex point, and the limit convex points (4) and the limit concave points (5) are alternately distributed.

3. The module assembly of a splicing box body according to claim 2, wherein the limit convex points (4) are solid hemispherical bulges, and the limit concave points (5) are matched hemispherical grooves.

4. The module assembly of a spliceable box according to claim 2, wherein the total number of the projections and the recesses in the wave-shaped splicing structure on either side is 6, that is, the wave-shaped splicing structure on either side comprises a first projection (1), a second projection (2) and a third projection (3), the third projection (3) is the projection at the end position, the first projection (1) is provided with the limit convex point (4) on the side close to the third projection (3), and the second projection (2) is provided with the limit concave point (5) on the side close to the third projection (3).

Images