CN220237749U - Intelligence-improving assembled toy - Google Patents

Abstract

The utility model discloses an intelligent assembled toy, which comprises a bottom box and building blocks, wherein the building blocks comprise four building blocks with different shapes and chirality; all building blocks are assembled according to the correct assembly arrangement sequence and can be assembled on a plane to form an irregular terrace with a narrow upper part and a wide lower part, no gap exists at the joint of the upper surfaces of the four building blocks in the irregular terrace formed by the joint, gaps exist at the joint of the lower surfaces of the four building blocks, arc surfaces are arranged on the four building blocks, the four arc surfaces form a cylindrical through groove after the four building blocks are assembled according to the correct assembly sequence, the inner cavity of the bottom box is inclined outwards from the opening end to the bottom, the inclination is the same as the outward inclination of the irregular terrace, and the bottom of the inner cavity of the bottom box is the same as the bottom of the irregular terrace. The cup pad has a simple structure, is interesting in playing method, has practicability, and can be used as a cup pad, a pen container and other storage spaces after the four building blocks are placed in the box.

Description

Intelligence-improving assembled toy

Technical Field

The utility model relates to a toy, in particular to an intelligent assembled toy.

Background

The children can not leave accompanies of various toys in growth, parents can purchase a lot of toys for the children, the types of toys on the market are a lot of, the building block toy is popular among children, the building block toy is usually a cubic wood or plastic solid toy, letters or pictures are generally decorated on each surface, different arrangements or various patterns of building movable building blocks are allowed to be carried out, the building block toy has great effect on the intelligence development of the children, houses, various animals and the like can be spliced, the building blocks are helpful for developing the intelligence, training the hand-eye coordination ability of the children, the arrangement, the connection, the ring shape, the symmetry, the chirality and the like in the building blocks are beneficial to the intelligence of the children. When building blocks are assembled, children must have problems of proportion, symmetry, chirality and the like, which is beneficial to early culture of advanced concepts such as stereochemistry, universe symmetry dissatisfaction and the like.

The existing building blocks have single functions, have no other functions except for the animal houses with different patterns and shapes constructed by different arrangements, have insufficient practicability, lose interest after being spliced once, are idle or discarded, have relatively complex structures, are difficult to disassemble, are difficult to process and manufacture, and are difficult to meet the requirements of different age groups, and the components after the structures are disassembled are easy to lose.

Disclosure of Invention

The utility model aims at: aiming at the situation that the prior art lacks of fun and function combination, the intelligent building block toy is simple in structure, fun in playing method and practical.

The technical scheme of the utility model is as follows:

the utility model relates to an intelligent assembled toy, which comprises a bottom box and building blocks, wherein the building blocks comprise four building blocks I, two, three and four with different shapes and chirality; all building blocks are assembled according to the correct assembling arrangement sequence and placed on a plane to form an irregular prismatic table with a narrow upper part and a wide lower part, the joints of the upper surfaces of four building blocks in the irregular prismatic table formed by splicing are gapless, gaps exist at the joints of the lower surfaces of the four building blocks, the gaps can be folded under the action of external force extrusion, and the lower surfaces of the four building blocks are spliced into a square after the gaps are folded; the size of the opening end of the inner cavity of the bottom box is the same as the square size of the lower surface after the four gaps are folded, the inner cavity of the bottom box is inclined outwards from the opening end to the bottom, the inclination is the same as the outwards inclination of the irregular terrace, and the size of the bottom of the inner cavity of the bottom box is the same as the size of the bottom of the irregular terrace.

The structure comprises a first building block, a second building block, a third building block and a fourth building block, wherein the upper surfaces of the first building block, the second building block, the third building block and the fourth building block are the same, the lower surfaces of the first building block, the second building block, the third building block and the fourth building block are different, the four building blocks are respectively provided with chirality, the chirality is that the four building blocks respectively form new four building blocks through mirror symmetry, the correct splicing sequence of the four building blocks is opposite to the correct splicing sequence of the first building block, the second building block, the third building block and the fourth building block, the first building block, the second building block, the third building block and the fourth building block are only one, namely the sequence of the first building block, the second building block, the third building block and the fourth building block is clockwise, an irregular terrace with a narrow upper part and a wide lower part is spliced, the upper surface of the irregular terrace is square and the center is buckled into a round shape, and the lower surface is outwards inclined due to the outwards inclined side of the outer side of the building block. The bottom of the inner cavity of the bottom box is inclined outwards, the size of the opening end of the inner cavity of the bottom box is the same as the size of the square section after the four gaps are folded, so that building blocks are directly assembled in the box, the last building block can be put in the box because the opening end of the inner cavity of the bottom box is too small, the four building blocks can be spliced into an irregular terrace with edges after being combined in the correct sequence by a correct playing method, the lower end of the irregular terrace with edges is extruded forcefully, and gaps exist at the spliced positions of the lower surfaces of the four building blocks to be folded, so that the building blocks can be put in the bottom box together.

Further, a face a of the building block I, a face b of the building block II, a face c of the building block III and a face d of the building block IV are arc-shaped faces, and after the four building blocks are spliced, the four arc-shaped faces form a cylindrical through groove.

With the structure, the cylindrical through groove at the center of the four arc-shaped surfaces in the irregular terrace formed by splicing the four building blocks can be used for placing a cup or other small parts, and the spliced toy is used as a cup pad or a storage barrel.

Further, the four gaps at the splicing positions of the four building blocks on the lower surface of the irregular terrace with edges formed by splicing are the same in size.

Further, the correct assembling and arranging sequence of the four building blocks is clockwise a building block I, a building block II, a building block III and a building block IV.

Further, the first face A, the second face B and the third face D of the building block are inclined outwards relative to the upper surface of the building block, and the second face C is inclined inwards relative to the upper surface of the building block; the surface E of the second building block is inclined outwards relative to the upper surface of the building block, the surface F is inclined inwards relative to the upper surface of the building block, and the surface G is vertical relative to the upper surface of the building block; the face H of the third block is inclined outwardly relative to the upper block surface, the face I is inclined inwardly relative to the upper block surface, and the face J is perpendicular relative to the upper block surface; the faces K, L and N of the fourth block are inclined outwardly relative to the upper block surface and the face M is inclined inwardly relative to the upper block surface.

Further, the correct arrangement sequence is that the face D of the first building block is spliced with the face F of the second building block, the face G of the second building block is spliced with the face I of the third building block, the face J of the third building block is spliced with the face M of the fourth building block, and the face N of the fourth building block is spliced with the face C of the first building block.

Further, the gap formed by the two splicing surfaces is the same as the size of outwards inclined surfaces D and N relative to the upper surface of the building block.

Above structure, through the slope design to four building blocks a plurality of limits, guarantee that the irregular terrace with edges after the concatenation has following characteristic: the side surface is provided with a plurality of outward inclined surfaces, so that the whole irregular terrace has narrow upper part and wide lower part; four gaps exist at the splicing positions of the four building blocks on the lower surface of the irregular terrace with edges, the sizes of the four gaps are the same as the size of the inclination angle of the side edge of the irregular terrace with edges, the four gaps can be folded under the action of external force extrusion, and the four building blocks form a cube after the gaps are folded.

Further, the building block comprises a building block five, a building block six, a building block seven and a building block eight which are respectively mirrored with the building block one, the building block two, the building block three and the building block four, the building block five, the building block six, the building block seven and the building block eight form another splicing method, and the splicing correct arrangement sequence is opposite to that of the building block one, the building block two, the building block three and the building block four.

The structure increases the difficulty of playing the building block, selects correct four building blocks from eight building blocks to splice, and the first building block, the second building block, the third building block and the fourth building block are one set, the fifth building block, the sixth building block, the seventh building block and the eighth building block are one set, and the correct splicing sequences of the two sets are opposite.

Further, the building blocks are respectively coated with distinguishable different colors.

Further, the bottom box is a non-cover bottom box, and the bottom box and the building blocks are made of wood, metal or plastic materials.

Compared with the prior art, the utility model has the beneficial effects that:

1. the utility model can be assembled into an irregular terrace with square by ingenious design of a plurality of different building blocks, the playing method has certain difficulty, and mental observation and trial are required, thereby being beneficial to the intelligence of children; the whole structure is simple, the manufacturing difficulty is low, the splicing mode is novel, and the bottom box can be put into the bottom box after the bottom box is assembled outside and then pinched; the building blocks can be used for building the household practicality, such as a pen box, a teacup pad and the like, so that the practicality is high, the learning interest of children can be effectively improved, and the practical ability of the children is improved.

2. The utility model increases the diversity and complexity of playing methods through the arrangement of two sets of mirror image building blocks, is suitable for the demands of different age groups, and exercises the perception capability and intelligence of children.

Drawings

FIG. 1 is a schematic view of a block of the present utility model in a bottom box;

FIG. 2 is a schematic view of the structure of the bottom case of the present utility model;

FIG. 3 is a schematic view of the structure of the bottom box in vertical section of the present utility model;

FIG. 4 is a schematic diagram of a first block of the present utility model;

FIG. 5 is a schematic diagram of a second embodiment of a building block of the present utility model;

FIG. 6 is a schematic diagram of a third embodiment of a building block of the present utility model;

FIG. 7 is a schematic diagram of a fourth embodiment of a building block of the present utility model;

FIG. 8 is a schematic view showing the structure of four blocks of the utility model with the bottom surface upwards in an irregular terrace formed by splicing the blocks outside the bottom box;

fig. 9 is a schematic view showing a structure in which four building blocks are spliced outside a bottom box to form an irregular terrace with a downward bottom surface.

Reference numerals: 1. a face a of the first building block; 2. face b of block two; 3. face c of the building block three; 4. a face d of the building block four; 11. face a of block one; 12. face B of block one; 13. face C of block one; 14. a face D of the first building block; 21. face E of building block two; 22. a face F of the second building block; 23. a face G of the second building block; 31. face H of block three; 32. face I of the building block three; 33. face J of block three; 41. a face K of the building block four; 42. a face L of the building block four; 43. a face M of the building block four; 44. face N of block four.

Detailed Description

It is noted that relational terms such as "first" and "second", and the like, are used solely to distinguish one entity or action from another entity or action without necessarily requiring or implying any actual such relationship or order between such entities or actions. Moreover, the terms "comprises," "comprising," or any other variation thereof, are intended to cover a non-exclusive inclusion, such that a process, method, article, or apparatus that comprises a list of elements does not include only those elements but may include other elements not expressly listed or inherent to such process, method, article, or apparatus. Without further limitation, an element defined by the phrase "comprising one … …" does not exclude the presence of other like elements in a process, method, article, or apparatus that comprises the element.

The features and capabilities of the present utility model are described in further detail below in connection with examples.

As shown in fig. 1, the utility model discloses an intelligent assembled toy, which comprises a bottom box and building blocks, wherein the building blocks comprise four building blocks one, two, three and four which are different in shape and have chirality; all building blocks are assembled according to the correct assembling arrangement sequence and placed on a plane to form an irregular prismatic table with a narrow upper part and a wide lower part, the joints of the upper surfaces of four building blocks in the irregular prismatic table formed by splicing are gapless, gaps exist at the joints of the lower surfaces of the four building blocks, the gaps can be folded under the action of external force extrusion, and the lower surfaces of the four building blocks are spliced into a square after the gaps are folded; as shown in fig. 2 and 3, the size of the opening end of the inner cavity of the bottom box is the same as the square size of the lower surface after the four gaps are folded, the inner cavity of the bottom box is inclined outwards from the opening end to the bottom, the inclination is the same as the outwards inclination of the irregular terrace, and the size of the bottom of the inner cavity of the bottom box is the same as the size of the bottom of the irregular terrace.

In this embodiment: the four building blocks have different shapes and sizes, an irregular terrace with narrow upper part and wide lower part can be spliced outside the box according to the correct arrangement sequence, as shown in figure 9, the splicing parts of the four building blocks on the upper surface of the irregular terrace have no gap, as shown in figure 8, the splicing parts of the four building blocks on the lower surface of the irregular terrace have gaps; the irregular terrace with edges is under external force extrusion, the lower extreme can inwards shrink and draw in the clearance, four building blocks form the square after the clearance draws in, but this square upper surface can upwards arch a part, building blocks under this state just can put into the end box simultaneously, because end box inner chamber bottom outwards inclines, also be the structure of upper narrow width down, and end box inner chamber open end's size is the same with square section size after four clearances draw in, consequently directly put into and splice into the terrace with a cylindrical through-hole in the centre in a piece place in the box, first three building blocks can put in proper order, but when needing to put into to last building block, no matter how put, can not form the complete shape that has a cylindrical through-hole in the centre.

As a technical optimization scheme of the utility model, a surface a1 of a building block I, a surface b2 of a building block II, a surface c3 of a building block III and a surface d4 of a building block IV are arranged to be arc surfaces, and four arc surfaces are spliced to form a cylindrical through groove.

In this embodiment, the four building blocks are formed by cutting four different quadrangular tables, before cutting, the upper surfaces of the four quadrangular tables are the same and square, after cutting, the upper surfaces of the four arc surfaces are the same in size, and the cutting positions are circular arcs of a quarter circle, and the radius of the circular arc is set according to the actual situation, so as to meet the use requirements of different purposes; for example, when the four arc surfaces are spliced to form a cylindrical through groove as a cup pad, the radius of the arc to be cut needs to meet the radius of the placed cup for setting; when the cylindrical through groove is formed as a pen container or other storage barrels, the height of the toy and the radius of the arc to be cut are also adjusted according to actual conditions.

When the irregular terrace with edges that four building blocks splice and form is not by external force extrusion, this cylinder leads to the outside surface of groove and all outwards inclines, forms narrow structure wide under, when the clearance that four building blocks splice were extruded by external force draws in, the arc face inwards contracts, forms a bellied cylinder and leads to the groove for the end box in upper end.

As a technical optimization scheme of the utility model, the four gaps at the splicing positions of the four building blocks on the lower surface of the irregular terrace with edges formed by splicing are the same in size.

In this embodiment, in the irregular terrace with edges formed by last concatenation, the clearance size that the side formed is the same, guarantees that all clearances can all draw in to zero simultaneously under external force, forms the square of a upper surface middle arch.

As a technical optimization scheme of the utility model, the correct assembly arrangement sequence of the four building blocks is clockwise building block one, building block two, building block three and building block four.

In this embodiment, the correct assembling and arranging sequence does not include the order of which block is placed first, which means that the formed irregular prism table is seen as a first block, a second block, a third block and a fourth block in clockwise order, and the order can be divided into four types, for example, a second block is placed first, then the blocks spliced clockwise by the blocks must be a third block, and so on.

As a technical optimization scheme of the utility model, as shown in FIG. 4, a face A11, a face B12 and a face D14 of a building block I are inclined outwards relative to the upper surface of the building block, and a face C13 is inclined inwards relative to the upper surface of the building block; as shown in FIG. 5, face E21 of block two is inclined outwardly relative to the upper surface of the block, face F22 is inclined inwardly relative to the upper surface of the block, and face G23 is perpendicular relative to the upper surface of the block; as shown in FIG. 6, face H31 of block three is inclined outwardly relative to the upper surface of the block, face I32 is inclined inwardly relative to the upper surface of the block, and face J33 is perpendicular relative to the upper surface of the block; as shown in FIG. 7, face K41, face L42 and face N44 of block four are inclined outwardly relative to the upper surface of the block and face M43 is inclined inwardly relative to the upper surface of the block.

In this embodiment, the first face a11 and the second face B12 of the first block are inclined outwardly by 5 ° with respect to the upper surface of the block, the first face C13 is inclined inwardly by 10 ° with respect to the upper surface of the block, and the second face D14 is inclined outwardly by 5 ° with respect to the upper surface of the block; face E21 of block two is inclined 5 outwardly relative to the block upper surface, face F22 is inclined 10 inwardly relative to the block upper surface, and face G23 is perpendicular relative to the block upper surface; face H31 of block three is inclined 5 outwardly relative to the block upper surface, face I32 is inclined 5 inwardly relative to the block upper surface, and face J33 is perpendicular relative to the block upper surface; face K41 and face L42 of the four-white face of the block are inclined 5 outwardly relative to the upper face of the block, face M43 is inclined 5 inwardly relative to the upper face of the block, and face N44 is inclined 5 outwardly relative to the upper face of the block.

As a technical optimization scheme of the utility model, the correct arrangement sequence is that the face D14 of the first building block is spliced with the face F22 of the second building block, the face G23 of the second building block is spliced with the face I32 of the third building block, the face J33 of the third building block is spliced with the face M43 of the fourth building block, and the face N44 of the fourth building block is spliced with the face C13 of the first building block.

As a technical optimization scheme of the utility model, the gap size formed by the two splicing surfaces is the same as the size of outwards inclining surface D (14) and surface N (44) relative to the upper surface of the building block.

In this embodiment, according to the side inclination of each building block and the connection sequence, the size of the included angle between the two building blocks is 5 ° and the degree of the included angle is the same as the degree of the side inclination. All gaps in the irregular prism table formed by splicing the four building blocks can be folded to be zero under external force, and the outward inclined part protruding from the outer side can also shrink inwards to form a cube.

As a technical optimization scheme of the utility model, the utility model further comprises a building block five, a building block six, a building block seven and a building block eight which are respectively mirrored with the building block one, the building block two, the building block three and the building block four, wherein the building block five, the building block six, the building block seven and the building block eight form another splicing method, and the splicing correct arrangement sequence is opposite to that of the building block one, the building block two, the building block three and the building block four.

In the embodiment, the fifth building block is in mirror image relationship with the fourth building block, the sixth building block is in mirror image relationship with the sixth building block, the seventh building block is in mirror image relationship with the third building block, the eighth building block is in mirror image relationship with the fourth building block, the first building block, the second building block, the third building block and the fourth building block are provided with chiral features, and the chirality is expressed as the fifth building block, the sixth building block, the seventh building block and the eighth building block; therefore, the first building block, the second building block, the third building block and the fourth building block are one set, the fifth building block, the sixth building block, the seventh building block and the eighth building block are one set, and the correct assembling and arranging sequence of the fifth building block, the sixth building block, the seventh building block and the eighth building block is opposite to that of the first building block, the second building block, the third building block and the fourth building block, and the first building block, the second building block, the third building block and the fourth building block are clockwise seen as the eighth building block, the seventh building block, the sixth building block and the fifth building block.

As a technical optimization scheme of the utility model, the building blocks are respectively coated with different distinguishable colors.

As a technical optimization scheme of the utility model, the bottom box is a non-cover bottom box.

As a technical optimization scheme of the utility model, the bottom box and the building blocks are made of wood, metal or plastic materials

Working principle:

embodiment one: if only one set of building blocks is provided, namely only one building block, two building blocks, three building blocks and four building blocks, or five building blocks, six building blocks, seven building blocks and eight building blocks, firstly combining the four building blocks outside a box according to the correct assembling arrangement sequence into an irregular prismatic table with a cylindrical through groove from small to penetrating downwards at the center; the lower ends of the irregular prism tables are gathered by hands, gaps can be gathered under the action of external force extrusion, after the gaps are gathered, four building blocks form cubes, a part of the middle of the upper surface of each cube is arched upwards, at the moment, the bottoms of the gathered cubes are downwards put into the bottom box from the opening end of the bottom box, because the bottoms of the bottom box are larger than the opening end, the bottoms of the inner cavities of the bottom box are outwards inclined, the inclination size is the same as the outwards inclined size of the irregular prism tables, after the cubes are put into the bottom box, the bottoms of the cubes are re-spread, and at the moment, the whole toy which is spliced and put into the bottom box can be used as a cup pad or a pen container; if four building blocks are to be taken out from the box, the box needs to be reversely buckled to take out the four building blocks at the same time, and if any one building block is pressed, the other three building blocks cannot fall out when the bottom box is reversely buckled.

Embodiment two: compared with the first embodiment, the difference of the embodiment is that the inner cavity of the bottom box can be set as a cube inner cavity, namely the opening end is as large as the bottom, at the moment, the spliced building blocks are put into the bottom box, the bottom box is only required to be reversely buckled, the spliced irregular prism table is covered on the spliced irregular prism table, then the spliced irregular prism table is extruded downwards slowly, the spliced irregular prism table is put into the bottom box by utilizing the extrusion force of the inner cavity of the bottom box, at the moment, the bottom of the irregular prism table is put into the bottom box upwards, and the gap is always kept in a folded state.

Embodiment III: compared with the embodiment, the difficulty of the toy is increased, two sets of building blocks, namely, a first building block, a second building block, a third building block and a fourth building block, namely, a fifth building block, a sixth building block, a seventh building block and an eighth building block are manufactured through chiral characteristics, at this time, four building blocks which are the same as one set are selected from the eight building blocks, and then the four building blocks are placed in the bottom box according to the mode in the two embodiments, and if the four building blocks are misplaced, the spliced building blocks cannot be placed in the bottom box.

The foregoing examples merely represent specific embodiments of the present application, which are described in more detail and are not to be construed as limiting the scope of the present application. It should be noted that, for those skilled in the art, several variations and modifications can be made without departing from the technical solution of the present application, which fall within the protection scope of the present application.

Claims (10)

1. The intelligent assembled toy is characterized by comprising a bottom box and building blocks, wherein the building blocks comprise four building blocks I, II, III and IV which are different in shape and have chirality; all building blocks are assembled according to the correct assembling arrangement sequence and placed on a plane to form an irregular prismatic table with a narrow upper part and a wide lower part, the joints of the upper surfaces of four building blocks in the irregular prismatic table formed by splicing are gapless, gaps exist at the joints of the lower surfaces of the four building blocks, the gaps can be folded under the action of external force extrusion, and the lower surfaces of the four building blocks are spliced into a square after the gaps are folded; the size of the opening end of the inner cavity of the bottom box is the same as the square size of the lower surface after the four gaps are folded, the inner cavity of the bottom box is inclined outwards from the opening end to the bottom, the inclination is the same as the outwards inclination of the irregular terrace, and the size of the bottom of the inner cavity of the bottom box is the same as the size of the bottom of the irregular terrace.

2. The intelligent assembled toy according to claim 1, wherein a face a (1), a face b (2), a face c (3) and a face d (4) of a first building block, a second building block and a fourth building block are arranged to be arc-shaped faces, and after the four building blocks are spliced, four arc-shaped faces form a cylindrical through groove.

3. The intelligent assembled toy according to claim 1, wherein four gaps at which four building blocks are spliced on the lower surface of the irregular terrace formed by splicing are identical in size.

4. The educational assembled toy of claim 1, wherein the correct assembly arrangement of the four building blocks is clockwise building block one, building block two, building block three and building block four.

5. The educational assembled toy of claim 4, wherein face a (11), face B (12), and face D (14) of block one are inclined outwardly relative to the upper surface of the block, and face C (13) is inclined inwardly relative to the upper surface of the block; the surface E (21) of the second building block is inclined outwards relative to the upper surface of the building block, the surface F (22) is inclined inwards relative to the upper surface of the building block, and the surface G (23) is vertical relative to the upper surface of the building block; the face H (31) of the third block is inclined outwardly relative to the upper block surface, the face I (32) is inclined inwardly relative to the upper block surface, and the face J (33) is perpendicular relative to the upper block surface; the faces K (41), L (42) and N (44) of the fourth block are inclined outwardly relative to the upper block surface and the face M (43) is inclined inwardly relative to the upper block surface.

6. The intelligent assembled toy according to claim 4, wherein the correct assembling and arranging sequence is that a face D (14) of a first building block is spliced with a face F (22) of a second building block, a face G (23) of the second building block is spliced with a face I (32) of a third building block, a face J (33) of the third building block is spliced with a face M (43) of a fourth building block, and a face N (44) of the fourth building block is spliced with a face C (13) of the first building block.

7. An educational assembled toy according to claim 3 or 6, wherein the four gaps are of the same size as the faces D (14), N (44) are inclined outwardly relative to the upper surface of the building block.

8. The intelligent assembled toy according to claim 1, wherein the first, second, third and fourth chiral blocks are mirrored blocks five, six, seven and eight, respectively, and the blocks five, six, seven and eight form another splicing method, and the correct sequence of splicing is opposite to that of the blocks one, two, three and four.

9. The educational assembled toy of claim 8, wherein block one, block two, block three, block four, block five, block six, block seven, and block eight are each coated with a distinguishable different color.

10. The educational assembled toy of claim 1, wherein the bottom case is a capless bottom case, and the bottom case and building blocks are made of wood, metal, or plastic.