CN115770399A - Particle type building block toy conversion bolt and manufacturing method - Google Patents

Abstract

The invention relates to the technical field of research, development and manufacture of 'particle type' building block toy splicing particles, in particular to a particle type building block toy conversion bolt and a manufacturing method thereof; the particle type building block toy conversion bolt and the manufacturing method thereof take a plane which passes through the middle point of the axial length of the limiting table B and is vertical to the bolt axis as an interface, the bolt structure below the interface is the size structure of one type of bolt of a 'small particle' building block toy, and the bolt structure above the horizontal interface is the size structure of the same type of bolt of a '6 mm particle' building block toy; the bolt that granule class building blocks were used has: through designing a manufacturing method and bolt of granule building blocks toy conversion bolt, solved "6 millimeter granule" building blocks toy and "granule" building blocks toy effectively, conveniently and splice out the technological problem of more desirable scenery molding together, not only convenient and fast, the input is low moreover, efficient, convenient and fast.

Description

Particle type building block toy conversion bolt and manufacturing method

Technical Field

The invention relates to the technical field of research, development and manufacturing of splicing particles of particle type building block toys, in particular to a particle type building block toy conversion bolt and a manufacturing method thereof.

The invention relates to a particle type building block toy conversion bolt, which is a bolt capable of directly splicing small splicing particles with bolt holes in a 6 mm particle type building block toy and splicing particles with bolt holes in the building block toy.

Background

As shown in fig. 1a, fig. 2, fig. 3, fig. 4, fig. 5, fig. 6, fig. 7 and fig. 8, the structure of some typical plugs commonly used in "particle-type" building block toys is schematically illustrated.

The structure of each bolt comprises three basic parts A, B and C: for the convenience of note, the structure of the plug pin is defined as follows: each bolt comprises a first inserting end A, a limiting table B and a second inserting end C.

Taking the small particle building block toy as an example, the size and the structure of various bolts are briefly annotated. The small particle building block toy is a building block toy like a Legao classical particle.

In the small-particle building block toy, the sizes of the first inserting end A, the limiting table B and the second inserting end C of various inserting pins are all related to the basic size of 8 mm: the diameters of the first inserting end A and the second inserting end C are 0.6 times of 8 mm, namely 4.8 mm, the axial lengths of the first inserting end A and the second inserting end C are n times-0.2 mm (n is a natural number) of 8 mm, and the axial length of the second inserting end C only of the III type bolt is 0.5 times-0.2 mm of 8 mm, namely 3.8 mm; the diameter of the limiting table B is 0.7 times of 8 mm, namely 5.6 mm, and the axial length is 0.1 times or 0.2 times of 8 mm, namely 0.8 mm or 1.6 mm.

The main dimensions of the other connected particles in the "small particle" block toy are also designed on the basis of the basic dimension of 8 mm: the height of the "plate" is 0.4 times of 8 mm, i.e., 3.2 mm, the height of the "brick" is 1.2 times of 8 mm, i.e., 9.6 mm, and the side lengths of the "plate" and the "brick" are both "n times of 8 mm-0.2 mm" (n is a natural number).

According to the size specification and the structural characteristics of 'small granule' building block toy splicing granules, research personnel develop a granule type building block toy taking '6 mm' as basic size parameters, and for the convenience of annotation, the application defines the granule type building block toy taking '6 mm' as the basic size parameters as a '6 mm granule' building block toy.

As shown in fig. 10, the splicing particles of the "6 mm particle" block toy and the "small particle" block toy using the plug basically include three types i, ii, and iii: the type I and the type II are strip splicing particles, and the difference is that the arrangement forms of bolt holes on the strip splicing particles are different; the III-type spliced particles are square frames, the arrangement form of pin holes on the frames of the III-type spliced particles is the same as that of the I-type spliced particles or the II-type spliced particles, and the number of the pin holes on the frames of each strip-type spliced particle or the square-type spliced particle is usually odd, namely 3 holes, 5 holes, 7 holes, 9 holes, 11 holes, 13 holes, 15 holes, and also 2 holes, 4 holes and 6 holes.

Compared with the 'small particle' building block toy, the scenery modeling spliced by the '6 mm particle' building block toy is more exquisite, fine and vivid, and the scenery modeling has stronger texture.

If the '6 mm particle building block toy' is combined with the 'small particle' building block toy to carry out the splicing design of the scenery modeling, the respective advantages of the '6 mm particle' building block toy and the 'small particle' building block toy can be fully exerted, and the scenery modeling which is more desirable is spliced.

The relation between the main size of the splicing particles of the 'small particle' building block toy and 8 mm can be deduced, and the size structure of the plug pin used by the '6 mm particle' building block toy is similar to that of the 'small particle' building block toy, but the size is smaller. In the building block toy of '6 mm particles', the sizes of the first inserting end A, the limiting table B and the second inserting end C of various bolts are all related to the basic size of 6 mm: the diameters of the first inserting end A and the second inserting end C are 0.6 times of 6 mm, namely 3.6 mm, the axial lengths of the first inserting end A and the second inserting end C are n times to 0.2 mm of 6 mm (n is a natural number), and the axial length of the second inserting end C of only the III type bolt is 0.5 times to 0.2 mm of 6 mm, namely 2.8 mm; the diameter of the stop B is 0.6 times 6 mm, i.e. 4.8 mm, and the axial length is 0.25 times 6 mm, i.e. 1.5 mm.

Therefore, if a bolt capable of directly splicing the splicing particles of the 'small particle' building block toy and the splicing particles of the '6 mm particle' building block toy is designed, the technical problem that the '6 mm particle' building block toy and the 'small particle' building block toy are combined together to be spliced into a more desirable scenery shape can be conveniently solved.

Disclosure of Invention

In order to solve the technical problem that the '6 mm particle' building block toy and the 'small particle' building block toy are conveniently combined together to splice a more desirable scenery model in the background art, the invention provides a particle type building block toy conversion bolt and a manufacturing method thereof, and the technical scheme of the particle type building block toy conversion bolt and the manufacturing method thereof is as follows:

the invention relates to a method for manufacturing a particle type building block toy conversion bolt, which is derived from a multiplication pithy formula which is uttered by an inventor when thinking about how to solve the technical problem of conveniently combining a 6 mm particle building block toy and a small particle building block toy to splice a more desirable scenery model: "sixty-eight-forty-eight", based on this multiplication pithy formula, the inventors found that: forty eight is 8 times of 6 mm, is exactly the length of the center distance of the bolt holes at two ends of the strip-shaped splicing particles of the building block toy 9 holes of 6 mm particles, forty eight is 6 times of 8 mm, is exactly the length of the center distance of the bolt holes at two ends of the strip-shaped splicing particles of the building block toy 7 holes of small particles, namely the center distance of the bolt holes at two ends of the strip-shaped splicing particles of the building block toy 9 holes of 6 mm particles is equal to the center distance of the bolt holes at two ends of the strip-shaped splicing particles of the building block toy 7 holes of small particles; therefore, the inventor proposes that the manufacturing method of the particle type building block toy conversion plug comprises the following steps:

step 1: the type and size structure of the splicing particles using the pins in the '6 mm particle' building block toy and the 'small particle' building block toy are analyzed:

step 1.1: type structure analysis

The splicing particles of the '6 mm particle' building block toy and the 'small particle' building block toy using the bolt basically comprise three types of types I, II and III: the type I and the type II are strip splicing particles, and the difference is that the arrangement forms of bolt holes on the strip splicing particles are different; the type III is square spliced particles, the arrangement form of pin holes on the frame of the square spliced particles is the same as that of the type I spliced particles or the type II spliced particles, the number of the pin holes on the frame of each strip spliced particle or the square spliced particles is usually odd, namely 3 holes, 5 holes, 7 holes, 9 holes, 11 holes, 13 holes and 15 holes, and the number of the pin holes also comprises 2 holes, 4 holes and 6 holes;

step 1.2: dimensional structure analysis

The bar concatenation granule and the square frame concatenation granule shape of "6 millimeter granule" building blocks toy and "tiny particle" building blocks toy are similar, and the size is different: the cross section size of the strip splicing particles and the frame of the square splicing particles of the '6 mm particles' building block toy is 6 mm multiplied by 6 mm, the center distance of the pin holes is 6 mm, the diameter of the pin holes is 3.6 mm, and the total length of the strip splicing particles and the length of the frame of the square splicing particles are equal to the number of the pin holes multiplied by 6 mm; the cross section size of the strip splicing particles and the frame of the square splicing particles of the small particle building block toy is 8 millimeters multiplied by 8 millimeters, the center distance of the pin holes is 8 millimeters, the diameter of the pin holes is 4.8 millimeters, and the total length of the strip splicing particles and the length of the frame of the square splicing particles are equal to the number of the pin holes multiplied by 8 millimeters;

step 2: mathematical analysis of equality relationships between values of integer multiples of 6 mm length and different integer multiples of 8 mm length

The strip-shaped splicing particles with equal center distance and length between the bolt holes at the two ends are as follows:

in the above table: k2 is a multiple of an integral multiple of 6 millimeters, and k is an even number greater than or equal to 2; m3 is a multiple of integral multiple of 8 mm, and m is a natural number more than or equal to 1;

a mathematical expression for the equality relationship between the values of two different integral multiples of the respective lengths of 6 mm and 8 mm:

when k is 2, 4, 6, 8, \ 8230 \ 8230;, k, and correspondingly, m is 1, 2, 3, 4, \ 8230; \ 8230;, m, in turn, there are: n2 times 6 mm = m3 times 8 mm;

and step 3: the invention relates to a particle type building block toy conversion bolt

Step 3.1: the size structure of the bolt used in the "6 mm granule" building block toy and the "small granule" building block toy is analyzed:

the sizes and structures of various types of bolts used in the 6 mm particle building block toy and the small particle building block toy respectively have related standard provisions in the industry, and the basic structures of various types of bolts comprise three parts: the device comprises a first inserting end A, a limiting table B and a second inserting end C; the upper end of the first inserting end A is connected to the lower end of the limiting table B, and the lower end of the second inserting end C is connected to the upper end of the limiting table B;

step 3.2: the particle type building block toy conversion bolt is designed and manufactured as follows:

for the same type of bolts in the '6 mm particle' building block toy and the 'small particle' building block toy in the step 3.1, a plane which passes through the axial length midpoint of the bolt limiting table B and is perpendicular to the bolt axis is taken as a separating surface, the limiting table and the bolt structure below the separating surface are in a standard size structure of the 'small particle' building block toy, the axial length of the limiting table is one half of the axial length of the original limiting table, the limiting table and the bolt structure above the separating surface are in a standard size structure of the '6 mm particle' building block toy, and the axial length of the limiting table is one half of the axial length of the original limiting table; or: the limiting platform and the plug pin structure below the interface are of a size structure of 6 mm particle building block toy standard, the axial length of the limiting platform is one half of the axial length of the original limiting platform, the limiting platform and the plug pin structure above the interface are of a size structure of small particle building block toy standard, and the axial length of the limiting platform is one half of the axial length of the original limiting platform.

A particle type building block toy conversion bolt is characterized in that any type bolt of a particle type building block toy with the size of 6 mm and a particle type building block toy comprises a first inserting end A, a limiting table B and a second inserting end C; the upper end of the first inserting end A is connected to the lower end of the limiting table B, and the lower end of the second inserting end C is connected to the upper end of the limiting table B; according to the manufacturing method of the particle type building block toy conversion bolt, a plane which passes through the middle point of the axial length of the bolt limiting table B and is perpendicular to the axis of the bolt is used as an interface, the limiting table and the bolt structure below the interface are of a standard size structure of a small particle building block toy, the axial length of the limiting table is one half of the axial length of the original limiting table, the limiting table and the bolt structure above the interface are of a standard size structure of a 6 mm particle building block toy, and the axial length of the limiting table is one half of the axial length of the original limiting table; or: the limiting platform and the plug pin structure below the interface are of a size structure of 6 mm particle building block toy standard, the axial length of the limiting platform is one half of the axial length of the original limiting platform, the limiting platform and the plug pin structure above the interface are of a size structure of small particle building block toy standard, and the axial length of the limiting platform is one half of the axial length of the original limiting platform.

The invention relates to a use method of a particle type building block toy conversion bolt, which comprises the following steps: in the 'small particle' building block toy model needing to be spliced with the '6 mm particle' building block toy model, the corresponding splicing particles of the 'small particle' building block toy with the pin holes are designed according to the '6 mm particle' building block toy model to be spliced, the particle type building block toy conversion pin is inserted into the pin holes of the corresponding 'small particle' building block toy splicing particles, then the corresponding '6 mm particle' building block toy with the pin holes is spliced on the particle type building block toy conversion pin, a splicing basic table top of the '6 mm particle' building block toy model is established, and then the '6 mm particle' building block toy can be shaped and spliced according to the preset design.

The particle type building block toy conversion bolt and the manufacturing method have the beneficial effects that: through designing a granule building blocks toy conversion bolt and manufacturing method, solved "6 millimeter granule" building blocks toy and "granule" building blocks toy effectively, conveniently promptly and splice out the figurative technical problem of scenery of more gratuitous looking after combining together, not only convenient and fast drops into lowly moreover, efficient, convenient and fast.

On the basis of the core technical scheme, through improvement on some technical characteristics, a plurality of optimized particle building block conversion bolts can be created.

Drawings

Fig. 1a is a schematic diagram of a shape structure of a particle type building block toy conversion plug pin, which is an improved design of a type i plug pin in a 'small particle' building block toy and a '6 mm particle' building block toy: the I-type-1 conversion bolt is characterized in that a first inserting end A of the I-type bolt is set to be a bolt-shaped structure of a small-particle building block toy, and a second inserting end C of the I-type bolt is set to be a bolt-shaped structure of a 6-millimeter-particle building block toy; the I type-2 conversion bolt is characterized in that a first inserting end A of the I type bolt is set to be a bolt-shaped structure of a building block toy with 6 mm particles, and a second inserting end C of the I type bolt is set to be a bolt-shaped structure of a building block toy with small particles.

Fig. 1b is a schematic diagram of the shape and structure of the particle type conversion bolt for building block toys, which is a limiting table of the particle type building block toy bolt shown in fig. 1a, wherein 6 mm particles of the conversion bolt for building block toys are omitted, and the length of the limiting table is added to the length of the bolt at the end, so that the particle type building block toy conversion bolt has the advantages of simplifying the structure and saving materials.

Fig. 2 is a schematic diagram of a shape structure of a particle type building block toy conversion plug pin, which is an improved design of a type ii plug pin in a small particle type building block toy and a 6 mm particle type building block toy: the type II-1 conversion bolt is characterized in that a first inserting end A of the type II bolt is set to be a bolt-shaped structure of a small particle building block toy, and a second inserting end C1 is set to be a bolt-shaped structure of a 6 mm particle building block toy; the type II-2 conversion bolt is characterized in that a first inserting end A of the type II bolt is set to be a bolt-shaped structure of a building block toy with 6 mm particles, and a second inserting end C1 is set to be a bolt-shaped structure of a building block toy with small particles.

Fig. 3 is a schematic diagram of a shape structure of a particle-type building block toy conversion plug, which is an improved design of a type iii plug in a "small particle" building block toy and a "6 mm particle" building block toy: the III-1 conversion bolt is characterized in that a first inserting end A1 of the III-type bolt is set to be a bolt-shaped structure of a small-particle building block toy, and a second inserting end C2 of the III-type bolt is set to be a bolt-shaped structure of a 6-millimeter-particle building block toy; the III-2 conversion bolt is characterized in that a first inserting end A1 of the III-type bolt is set to be a bolt-shaped structure of a building block toy with 6 mm particles, and a second inserting end C2 is set to be a bolt-shaped structure of a building block toy with small particles.

Fig. 4 is a schematic diagram of a shape structure of a particle type building block toy conversion plug pin, which is an improved design of an iv-type plug pin in a 'small particle' building block toy and a '6 mm particle' building block toy: the IV-type-1 conversion bolt is characterized in that a first inserting end A2 of the IV-type bolt is set to be a bolt-shaped structure of a small-particle building block toy, and a second inserting end C3 of the IV-type bolt is set to be a bolt-shaped structure of a 6-millimeter-particle building block toy; the IV-type-2 conversion bolt is characterized in that a first inserting end A2 of the IV-type bolt is set to be a bolt-shaped structure of a building block toy with 6 mm particles, and a second inserting end C3 is set to be a bolt-shaped structure of a building block toy with small particles.

Fig. 5 is a schematic diagram of a shape structure of a particle type building block toy conversion plug pin, which is an improved design of a type i plug pin in a small particle type building block toy and a 6 mm particle type building block toy: the V-shaped-1 conversion bolt is characterized in that a first inserting end A2 of the V-shaped bolt is set to be a bolt-shaped structure of a small-particle building block toy, and a second inserting end C4 is set to be a bolt-shaped structure of a 6-millimeter-particle building block toy; the V-shaped-2 conversion bolt is a bolt-shaped structure of a building block toy with 6 mm particles at a first inserting end A2 of the V-shaped bolt, and a bolt-shaped structure of a building block toy with small particles at a second inserting end C4.

Fig. 6 is a schematic diagram of a particle type building block toy conversion plug pin, which is an improved design of a vi-shaped plug pin in a 'small particle' building block toy and a '6 mm particle' building block toy: the VI-type-1 conversion bolt is characterized in that a first inserting end A3 of the VI-type bolt is set to be a bolt-shaped structure of a 6 mm particle building block toy, and a second inserting end C3 is set to be a bolt-shaped structure of a small particle building block toy; the VI-type-2 conversion bolt is characterized in that a first inserting end A3 of the VI-type bolt is set to be a bolt-shaped structure of a small-particle building block toy, and a second inserting end C3 of the VI-type bolt is set to be a bolt-shaped structure of a 6-millimeter-particle building block toy.

Fig. 7 is a schematic diagram of the shape and structure of a particle-type block toy conversion plug, which is an improved design of a vii-type plug in a 'small particle' block toy and a '6 mm particle' block toy: the VII-1 conversion bolt is characterized in that a first inserting end A4 of the VII-type bolt is set to be a bolt-shaped structure of a 6 mm particle building block toy, and a second inserting end C3 is set to be a bolt-shaped structure of a small particle building block toy; the VII-2 conversion bolt is characterized in that a first inserting end A4 of the VII-shaped bolt is set to be a bolt-shaped structure of a small-particle building block toy, and a second inserting end C3 of the VII-shaped bolt is set to be a bolt-shaped structure of a 6-millimeter-particle building block toy.

Fig. 8 is a schematic diagram of a shape and structure of a particle-type block toy conversion plug, which is an improved design of a type viii plug in a "small particle" block toy and a "6 mm particle" block toy: the VIII-1 conversion bolt is a bolt-shaped structure of a building block toy with 6 mm particles at a first inserting end A5 of the VIII bolt, and a bolt-shaped structure of a small particle building block toy at a second inserting end C3; the VIII-type-2 conversion bolt is a bolt-shaped structure which is formed by setting a first inserting end A5 of the VIII-type bolt as a small particle building block toy, and setting a second inserting end C as a 6 mm particle building block toy.

Fig. 9a is a schematic diagram of a shape structure of a particle building block toy conversion bolt, which is a schematic diagram of a shape structure of an IX type conversion bolt with an eccentricity delta changed from the I type-1 conversion bolt shown in fig. 1 a.

Fig. 9b is a schematic diagram of the size relationship between 9-hole and 7-hole strip-shaped splicing particles of a "6 mm particle" block toy and 7-hole x 5-hole square-shaped splicing particles of a "small particle" block toy.

FIG. 9c is a view showing that the 9-hole splicing particles of the "6 mm particle" block toy in FIG. 9b are spliced with the 7-hole splicing particles of the "small particle" block toy using the IX-type switching pins shown in FIG. 9a, and the 7-hole splicing particles of the "6 mm particle" block toy can be directly spliced with the 9-hole strip-shaped splicing particles of two "6 mm particle" block toys using the pins of the "6 mm particle" block toy.

Fig. 9d is a schematic diagram of the direct splicing of 3-pore spliced particles of a "6 mm particle" block toy with 2-pore spliced particles of a "small particle" block toy using the ix type conversion plug shown in fig. 9a, with an eccentricity δ =2 mm.

Fig. 9e is a schematic diagram of the direct splicing of 3-hole splicing particles of a "6 mm particle" block toy with 3-hole splicing particles of a "small particle" block toy using the ix type conversion plug shown in fig. 9a, with an eccentricity δ =2 mm.

Fig. 9f is a schematic diagram of a 4-hole splice particle of a "6 mm particle" block toy directly spliced with a 3-hole splice particle of a "small particle" block toy using the ix-type pin of fig. 9a, with an eccentricity δ =1 mm.

Fig. 9g is a schematic diagram of a 6-hole splice particle of the "6 mm particle" block toy directly spliced with a 5-hole splice particle of the "small particle" block toy using the ix-type pin of fig. 9a, with an eccentricity δ =1 mm.

FIG. 10 is a schematic diagram of bar-shaped and square-shaped stitching particles in a "6 mm particle" and "small particle" block toy.

Description of reference numerals:

a, the shape structures of first inserting ends of a 6 mm particle building block toy and small particle building block toys, namely I-shaped inserting pins and II-shaped inserting pins;

a1, the shape structures of a first inserting end of a 6 mm particle building block toy and a small particle building block toy III-type bolt;

a2, the shape structures of the first inserting ends of the 6 mm particle building block toy and the IV-shaped inserting pins and the V-shaped inserting pins of the small particle building block toy are in the same shape structure;

a3, the shape structures of the first inserting ends of the 6 mm particle building block toy and the small particle building block toy VI type bolt are adopted;

a4, the shape structures of the first inserting ends of the 6 mm particle building block toy and the small particle building block toy VII-shaped bolt are adopted;

a5, the shape structures of a first inserting end of a 6 mm particle building block toy and a small particle building block toy VIII type inserting pin are shown;

b, the shape structures of the limiting tables of the 6 mm particle building block toy and the I-shaped bolt and the II-shaped bolt of the small particle building block toy;

b1, limiting tables of 6 mm particle building block toys and small particle building block toys III-type bolts are arranged;

b2, the shape structures of the limiting tables of the 6 mm particle building block toy and the small particle building block toy IV-type bolt, V-type bolt, VI-type bolt and VII-type bolt;

b3, the shape structures of the limiting table of the building block toy with 6 mm particles and the VIII-type bolt of the small particle building block toy are combined;

subscript 6 indicates the shape and structure of the stopper of the "6 mm granule" building block toy pin, and subscript 8 indicates the shape and structure of the stopper of the "small granule" building block toy pin, e.g. B ₆ Per 2 represents one half of the axial length of the limiting platform of the I-shaped bolt of the 6 mm particle building block toy, B2 ₈ The/2 represents one half of the axial length of the limiting platforms of the IV-type bolt, the V-type bolt, the VI-type bolt and the VII-type bolt of the small-particle building block toy;

the shape structures of the second inserting ends of the C6 mm particle building block toy and the small particle building block toy I-shaped bolt;

c1, the shape structures of the second inserting ends of the 6 mm particle building block toy and the small particle building block toy II-shaped bolt;

the C2 '6 mm particle' building block toy and the 'small particle' building block toy are in the shape structure of the second inserting end of the III-type bolt;

the shape structures of the second inserting ends of the C3 '6 mm particle' building block toy and the 'small particle' building block toy IV-type bolt, VI-type bolt, VII-type bolt and VIII-type bolt;

the shape structures of the C4 '6 mm particle' building block toy and the second inserting end of the V-shaped bolt of the 'small particle' building block toy are the same;

d, the shape structures of the limit table chamfered edges of the 6 mm particle building block toy and the small particle building block toy III-type bolt;

d1, a '6 mm particle' building block toy and a 'small particle' building block toy VII-shaped bolt are deformed;

delta eccentricity.

Detailed Description

The technical scheme of the particle type building block toy conversion bolt and the manufacturing method thereof is further explained by combining the specific implementation mode as follows:

the first embodiment is as follows:

in order to solve the technical problem that the '6 mm particle' building block toy and the 'small particle' building block toy are conveniently combined together to be spliced into a more desirable scenery shape in the background art, the invention provides a particle type building block toy conversion bolt and a manufacturing method thereof, and the technical scheme of the particle type building block toy conversion bolt and the manufacturing method thereof is as follows:

a manufacturing method of a particle type building block toy conversion bolt comprises the following steps:

step 1: analyzing the types and size structures of splicing particles using the pins in the building block toy of 6 mm particles and the building block toy of small particles:

step 1.1: type structure analysis

The splicing particles of the '6 mm particle' building block toy and the 'small particle' building block toy using the bolt basically comprise three types of types I, II and III: the type I and the type II are strip splicing particles, and the difference is that the arrangement forms of bolt holes on the strip splicing particles are different; the type III is square spliced particles, the arrangement form of pin holes on the frame of the square spliced particles is the same as that of the type I spliced particles or the type II spliced particles, the number of the pin holes on the frame of each strip spliced particle or square spliced particle is usually odd, namely 3 holes, 5 holes, 7 holes, 9 holes, 11 holes, 13 holes and 15 holes, and the number of the pin holes also comprises 2 holes, 4 holes and 6 holes;

step 1.2: dimensional structure analysis

The bar concatenation granule and the square frame concatenation granule shape of "6 millimeter granule" building blocks toy and "granule" building blocks toy are similar, and the size is different:

step 2: mathematical analysis of equality relationships between values of integer multiples of 6 mm length and different integer multiples of 8 mm length

The strip-shaped splicing particles with equal center distance and length between the bolt holes at the two ends are as follows:

in the above table: k2 is a multiple of an integral multiple of 6 millimeters, and k is an even number greater than or equal to 2; m3 is a multiple of an integral multiple of 8 millimeters, and m is a natural number more than or equal to 1;

a mathematical expression for the equality relationship between the values of two different integral multiples of the respective lengths of 6 mm and 8 mm:

when k is 2, 4, 6, 8, \ 8230 \ 8230;, k, and correspondingly, m is 1, 2, 3, 4, \ 8230; \ 8230;, m, in turn, there are: n2 times 6 mm = m3 times 8 mm;

and step 3: the invention relates to a particle type building block toy conversion bolt

Step 3.1: the size structure of the bolt used in the "6 mm granule" building block toy and the "small granule" building block toy is analyzed:

the sizes and structures of various types of bolts used in the 6 mm particle building block toy and the small particle building block toy respectively have related standard provisions in the industry, and the basic structures of various types of bolts comprise three parts: the device comprises a first inserting end A, a limiting table B and a second inserting end C; the upper end of the first inserting end A is connected to the lower end of the limiting table B, and the lower end of the second inserting end C is connected to the upper end of the limiting table B;

step 3.2: the particle type building block toy conversion bolt is designed and manufactured as follows:

for the same type of bolts in the '6 mm particle' building block toy and the 'small particle' building block toy in the step 3.1, a plane which passes through the axial length midpoint of the bolt limiting table B and is perpendicular to the bolt axis is taken as a separating surface, the limiting table and the bolt structure below the separating surface are in a standard size structure of the 'small particle' building block toy, the axial length of the limiting table is one half of the axial length of the original limiting table, the limiting table and the bolt structure above the separating surface are in a standard size structure of the '6 mm particle' building block toy, and the axial length of the limiting table is one half of the axial length of the original limiting table; or: the limiting platform and the plug pin structure below the interface are of a size structure of 6 mm particle building block toy standard, the axial length of the limiting platform is one half of the axial length of the original limiting platform, the limiting platform and the plug pin structure above the interface are of a size structure of small particle building block toy standard, and the axial length of the limiting platform is one half of the axial length of the original limiting platform.

Example two:

as shown in fig. 1b, compared with the first embodiment, the present embodiment is different in that: in the step 3, the bolt part of the building block toy with the particles of 6 mm is not provided with a limiting table, and the axial length of the limiting table is added to the axial length of the bolt.

Example three:

in the process of implementing step 2, the inventor finds that the center distance length of pin holes at two ends of some strip-shaped splicing particles of the '6 mm particle' building block toy is different from the center distance length of pin holes at two ends of some strip-shaped splicing particles of the 'small particle' building block toy by 2 mm or 4 mm, for example: the center distance between the pin holes at two ends of the strip-shaped splicing particles of 7 holes of the 6 mm particle building block toy is 36 mm, the center distance between the pin holes at two ends of the strip-shaped splicing particles of 5 holes of the small particle building block toy is 32 mm, and the difference between the two center distances is 4 mm; the center distance between the bolt holes at two ends of the strip-shaped splicing particles of the holes of the 6 mm particle building block toy is 54 mm, the center distance between the bolt holes at two ends of the strip-shaped splicing particles of the holes of the small particle building block toy is 56 mm, and the difference between the two center distances is 2 mm; according to the discovery, the inventor proposes to manufacture an eccentric bolt, so that two strip-shaped splicing particles with the conditions can be directly spliced;

in order to implement the design of the invention, it is necessary to find how many groups of strip-shaped splicing particles meet the conditions in a building block toy with 6 mm particles and a building block toy with small particles so as to provide a basis for company decision, design and production, and therefore, the inventor needs to solve the technical problem: how many groups of strip-shaped splicing particles meeting the condition that the center distance between pin holes at two ends has a difference of 2 mm or 4 mm in length in a 6 mm particle building block toy and a small particle building block toy?

The solution proposed by the inventor is as follows:

compared with the first embodiment, the difference of the present embodiment is: further mathematical analysis of the relationship between the value of the integer multiple of the 6 mm length and the value of the different integer multiple of the 8 mm length described in step 2, to find a data set in which the value of the integer multiple of the 6 mm length differs from the value of the different integer multiple of the 8 mm length by 2 mm or 4 mm, the analysis step comprising:

designing software: hardware environment: a CPU: inter (R) Core (TM) i5 3570K @3.4GHz; software environment: windows7x64 flagship edition; c. programming language: JAVA; version number: jdk1.8.0_221; no program load to call third party: 70 lines of code; the main functions are as follows: for two given positive integers (positive integer a and positive integer b) in the number sequence of the natural numbers, finding a pair of positive integers (one integer is named as aT and the other integer is named as bT), and requiring that the product of 'a x aT' is different from the product of 'b x bT' by 2 or 4, and exhausting the first 50 groups of data according to the condition;

the first 50 groups of data were classified: wherein: 24 groups differing by 2 mm, 12 groups each of greater than 2 mm and less than 2 mm; 26 groups differing by 4 mm, 13 groups each of greater than 4 mm and less than 4 mm;

the mathematical relation is summarized from the above data types:

the mathematical relationship greater than 2 mm is: (n 2+ 5) × 6+2 (n is an even number), which is a value of an integer multiple of 8;

the mathematical relationship of less than 2 mm is: (n 2+ 3) × 6-2 (n is an even number), which is an integer multiple of 8;

the mathematical relationship between greater than 4 mm and less than 4 mm is: (n 2) × 6 ± 4 (n is an odd number of 1 or more), which is an integer multiple of 8; the following table shows the first five data sets of the four types of data:

for the particle type building block toy conversion bolt in the step 3, the center of the bolt at the upper part and the center of the bolt at the lower part in the boundary surface are eccentrically arranged with the eccentricity delta.

Example four:

a particle type building block toy conversion bolt is characterized in that any type bolt of a particle type building block toy with the size of 6 mm and a particle type building block toy comprises a first inserting end A, a limiting table B and a second inserting end C; according to the manufacturing method of the particle type building block toy conversion bolt, a plane which passes through the middle point of the axial length of the bolt limiting table B and is perpendicular to the axis of the bolt is taken as an interface, the limiting table and the bolt structure below the interface are in a standard size structure of a 'small particle' building block toy, the axial length of the limiting table is one half of the axial length of the original limiting table, the limiting table and the bolt structure above the interface are in a standard size structure of a '6 mm particle' building block toy, and the axial length of the limiting table is one half of the axial length of the original limiting table; or: the limiting platform and the plug pin structure below the interface are of a size structure of 6 mm particle building block toy standard, the axial length of the limiting platform is one half of the axial length of the original limiting platform, the limiting platform and the plug pin structure above the interface are of a size structure of small particle building block toy standard, and the axial length of the limiting platform is one half of the axial length of the original limiting platform.

Example five:

as shown in fig. 1a, the present embodiment is different from the fourth embodiment in that: the particle type building block toy conversion bolt is an I-1 conversion bolt or an I-2 conversion bolt, the lower part of an interface of a limiting table B of the I-1 conversion bolt is a size structure of a first inserting end A of the I-type bolt of a 'small particle' building block toy, and the upper part of the interface is a size structure of a second inserting end C of the I-type bolt of a '6 mm particle' building block toy: the lower part of the interface of the limiting platform B of the I-type-2 conversion bolt is of a size structure of a first inserting end A of the I-type bolt of the 6 mm particle building block toy, and the upper part of the interface is of a size structure of a second inserting end C of the I-type bolt of the small particle building block toy.

EXAMPLE six

As shown in fig. 2, the present embodiment is different from the fourth embodiment in that: the particle type building block toy conversion bolt is a II-1 conversion bolt or a II-2 conversion bolt, the lower part of the interface of a limiting platform B of the II-1 conversion bolt is a size structure of a first inserting end A of the II-type bolt of a 'small particle' building block toy, and the upper part of the interface is a size structure of a second inserting end C1 of the II-type bolt of a '6 mm particle' building block toy: the lower part of the interface of the limiting platform B of the II-type-2 conversion bolt is the size structure of the first inserting end A of the II-type bolt of the 6 mm particle building block toy, and the upper part of the interface is the size structure of the second inserting end C1 of the II-type bolt of the small particle building block toy.

Example seven:

as shown in fig. 3, the present embodiment is different from the fourth embodiment in that: the particle type building block toy conversion bolt is a III-1 conversion bolt or a III-2 conversion bolt, the lower part of an interface of a limiting platform B1 of the III-1 conversion bolt is a size structure of a first inserting end A1 of the III type bolt of a small particle building block toy, and the upper part of the interface is a size structure of a second inserting end C2 of the III type bolt of a 6 mm particle building block toy: the lower part of the interface of the limiting platform B1 of the III-type-2 conversion bolt is of a size structure of a first inserting end A1 of the III-type bolt of the 6 mm particle building block toy, and the upper part of the interface is of a size structure of a second inserting end C2 of the III-type bolt of the small particle building block toy.

Example eight:

as shown in fig. 4, the present embodiment is different from the fourth embodiment in that: the particle type building block toy conversion bolt is an IV-type-1 conversion bolt or an IV-type-2 conversion bolt, the lower part of an interface of a limiting table B2 of the IV-type-1 conversion bolt is a size structure of a first inserting end A2 of the IV-type bolt of a 'small particle' building block toy, and the upper part of the interface is a size structure of a second inserting end C3 of the IV-type bolt of a '6 mm particle' building block toy: the lower part of the interface of the limiting platform B2 of the IV-type-2 conversion bolt is of a size structure of a first inserting end A2 of the IV-type bolt of a 6 mm particle building block toy, and the upper part of the interface is of a size structure of a second inserting end C3 of the IV-type bolt of a small particle building block toy.

Example nine:

as shown in fig. 1b, compared with any one of the fourth to eighth embodiments, the present embodiment is different in that: particle class building blocks toy conversion bolt, the first grafting end or the second grafting end of "6 millimeter particle" building blocks toy of particle class building blocks toy conversion bolt do not all establish spacing platform, the axial length of the spacing platform of first grafting end or the second grafting end of "6 millimeter particle" building blocks toy adds on the axial length of the bolt of first grafting end or second grafting end.

Example ten:

as shown in fig. 9a to 9g, compared with any one of the fourth to eighth embodiments, the present embodiment is different in that: the particle type building block toy conversion bolt is characterized in that a first inserting end or a second inserting end of a '6 mm particle' building block toy and a second inserting end or a first inserting end of a 'small particle' building block toy are arranged in a center of a limiting platform boundary face in an eccentric mode relatively, and the eccentric distance is delta.

Example eleven:

as shown in fig. 9a to 9g, the present embodiment is different from embodiment ten in that: the eccentricity is δ =1 mm, or δ =2 mm.

As shown in fig. 9b and 9c, the center distances of the 9-hole splicing particles of the "6 mm particle" building block toy and the 7-hole splicing particles of the "small particle" building block toy are equal, and are 48 mm, and any one of the types of the particle type building block toy conversion pins of the invention described in the fifth to ninth embodiments can be used for direct splicing, while the center distance of the 7-hole splicing particles of the "6 mm particle" building block toy is 36 mm, and the center distance of the 5-hole splicing particles of the "small particle" building block toy is 32 mm, so that after the 9-hole splicing particles of the "6 mm particle" building block toy and the 7-hole splicing particles of the "small particle" building block toy are spliced by the ix type conversion pins with the eccentricity distance δ =2 mm, the 9-hole splicing particles of the two "6 mm particle" building block toys and the 7-hole splicing particles of the "small particle" building block toy can be spliced on the 9-hole splicing particles of the two "6 mm particle" building block toys, and the pins of the "6 mm particle" building block "7-hole splicing particles are directly used for splicing toys;

as shown in fig. 9d, the center distance of the 3-hole splicing particles of the "6 mm particle" block toy is 12 mm, the center distance of the 2-hole splicing particles of the "small particle" block toy is 8 mm, and the two types of splicing particles can be directly spliced by using the ix-type conversion plug with the eccentric distance δ =2 mm described in this embodiment;

as shown in fig. 9e, the center distance of the 3-hole splicing particles of the "6 mm particle" building block toy is 12 mm, the center distance of the 3-hole splicing particles of the "small particle" building block toy is 16 mm, and the two types of splicing particles can be directly spliced by using the ix-type conversion plug with the eccentricity δ =2 mm described in this embodiment;

as shown in fig. 9f, the center distance of the 4-hole splicing particles of the "6 mm particle" block toy is 18 mm, the center distance of the 2-hole splicing particles of the "small particle" block toy is 16 mm, and the ix-type bolt with the eccentric distance of 1 mm described in this embodiment is used, so that the two types of splicing particles can be directly spliced;

as shown in fig. 9g, the center distance of the 6-hole splicing particles of the "6 mm particle" block toy is 30 mm, the center distance of the 5-hole splicing particles of the "small particle" block toy is 32 mm, and the two types of splicing particles can be directly spliced by using the ix type conversion plug with the eccentric distance δ =1 mm described in this embodiment.

Example twelve:

as shown in fig. 8, the present embodiment is different from the fourth embodiment in that: the particle type building block toy conversion bolt is a VIII type-1 conversion bolt, a VIII type-2 conversion bolt, a VIII type-3 conversion bolt or a VIII type-4 conversion bolt, the lower end face lower part of a limiting table B3 of the VIII type-1 conversion bolt is a size structure of a first inserting end A5 of the VIII type bolt of a '6 mm particle' building block toy, and the upper part of the lower end face of the limiting table B3 is a size structure of a VIII type bolt limiting table B3 and a second inserting end C3 of a 'small particle' building block toy: the lower part of the upper end face of the limit table B3 of the VIII-type-2 conversion bolt is a size structure of the limit table B3 and a first inserting end A5 of the VIII-type bolt of the small-particle building block toy, and the upper part of the upper end face of the limit table B3 is a size structure of a second inserting end C3 of the VIII-type bolt of the 6-millimeter-particle building block toy; the upper end face lower part of the limit table B3 of the VIII type-3 conversion bolt is the size structure of the limit table B3 and the first inserting end A5 of the VIII type bolt of the 6 mm particle building block toy, and the upper end face upper part of the limit table B3 is the size structure of the second inserting end C3 of the VIII type bolt of the small particle building block toy: the lower end face lower part of the limit table B3 of the VIII-type-4 conversion bolt is of a size structure of a first inserting end A5 of the VIII-type bolt of the small-particle building block toy, and the upper part of the lower end face of the limit table B3 is of a size structure of the limit table B3 and a second inserting end C3 of the VIII-type bolt of the 6-millimeter-particle building block toy.

The particle type building block toy conversion bolt and the manufacturing method have the beneficial effects that: through a mathematical method and a computer analysis method, a splicing and pairing method of splicing particles of a '6 mm particle' building block toy and a 'small particle' building block toy is found out, a mathematical formula for matching and pairing the splicing particles is summarized, and a particle type building block toy conversion bolt and a manufacturing method are designed according to the method, so that the technical problem that the '6 mm particle' building block toy and the 'small particle' building block toy are combined together to splice a more desirable scenery shape is effectively and conveniently solved, and the method is convenient and rapid, low in investment, high in efficiency, convenient and rapid.

The above description is only for the preferred embodiment of the present invention, but the scope of the present invention is not limited thereto, and any person skilled in the art should be able to cover the technical solutions and the inventive concepts of the present invention within the technical scope of the present invention.

Claims (11)

1. A manufacturing method of a particle type building block toy conversion bolt is characterized in that: the manufacturing method of the particle type building block toy conversion bolt comprises the following steps:

step 1: analyzing the types and size structures of splicing particles using the pins in the building block toy of 6 mm particles and the building block toy of small particles:

step 1.1: type structure analysis

The splicing particles of the '6 mm particle' building block toy and the 'small particle' building block toy using the bolt basically comprise three types of types I, II and III: the type I and the type II are strip splicing particles, and the difference is that the arrangement forms of bolt holes on the strip splicing particles are different; the type III is square spliced particles, the arrangement form of pin holes on the frame of the square spliced particles is the same as that of the type I spliced particles or the type II spliced particles, the number of the pin holes on the frame of each strip spliced particle or square spliced particle is usually odd, namely 3 holes, 5 holes, 7 holes, 9 holes, 11 holes, 13 holes and 15 holes, and the number of the pin holes also comprises 2 holes, 4 holes and 6 holes;

step 1.2: dimensional structure analysis

The bar concatenation granule and the square frame concatenation granule shape of "6 millimeter granule" building blocks toy and "granule" building blocks toy are similar, and the size is different:

step 2: mathematical analysis of equality relationships between values of integer multiples of 6 mm length and different integer multiples of 8 mm length

The equal bar concatenation granule of both ends bolt hole centre-to-centre spacing length, as follows the table:

in the above table: k2 is a multiple of an integral multiple of 6 millimeters, and k is an even number greater than or equal to 2; m3 is a multiple of an integral multiple of 8 millimeters, and m is a natural number more than or equal to 1;

a mathematical expression for the equality relationship between the values of two different integral multiples of the respective lengths of 6 mm and 8 mm:

when k is 2, 4, 6, 8, \ 8230 \ 8230;, k, and correspondingly, m is 1, 2, 3, 4, \ 8230; \ 8230;, m, in turn, there are: n2 times 6 mm = m3 times 8 mm;

and 3, step 3: design and manufacture of the particle type building block toy conversion bolt

Step 3.1: analyzing the size structure of the bolt used in the building block toy of '6 mm granule' and the building block toy of 'small granule':

the sizes and structures of various types of bolts used in the 6 mm particle building block toy and the small particle building block toy respectively have related standard provisions in the industry, and the basic structures of various types of bolts comprise three parts: the device comprises a first inserting end A, a limiting table B and a second inserting end C; the upper end of the first inserting end A is connected to the lower end of the limiting table B, and the lower end of the second inserting end C is connected to the upper end of the limiting table B;

step 3.2: the particle type building block toy conversion bolt is designed and manufactured as follows:

for the same type of bolts in the '6 mm particle' building block toy and the 'small particle' building block toy in the step 3.1, a plane which passes through the axial length midpoint of the bolt limiting table B and is perpendicular to the bolt axis is taken as a separating surface, the limiting table and the bolt structure below the separating surface are in a standard size structure of the 'small particle' building block toy, the axial length of the limiting table is one half of the axial length of the original limiting table, the limiting table and the bolt structure above the separating surface are in a standard size structure of the '6 mm particle' building block toy, and the axial length of the limiting table is one half of the axial length of the original limiting table; or: the limiting platform and the plug pin structure below the interface are of a size structure of 6 mm particle building block toy standard, the axial length of the limiting platform is one half of the axial length of the original limiting platform, the limiting platform and the plug pin structure above the interface are of a size structure of small particle building block toy standard, and the axial length of the limiting platform is one half of the axial length of the original limiting platform.

2. The method for manufacturing the particle type building block toy conversion plug pin as claimed in claim 1, wherein the method comprises the following steps: in the step 3, the bolt part of the building block toy with the particles of 6 mm is not provided with a limiting table, and the axial length of the limiting table is added to the axial length of the bolt.

3. The method for manufacturing the particle type building block toy conversion plug pin as claimed in claim 1, wherein the method comprises the following steps: in the process of implementing step 2, the inventor finds that the center distance length of pin holes at two ends of some strip-shaped splicing particles of the '6 mm particle' building block toy is different from the center distance length of pin holes at two ends of some strip-shaped splicing particles of the 'small particle' building block toy by 2 mm or 4 mm, for example: the center distance between the pin holes at two ends of the strip-shaped splicing particles of 7 holes of the 6 mm particle building block toy is 36 mm, the center distance between the pin holes at two ends of the strip-shaped splicing particles of 5 holes of the small particle building block toy is 32 mm, and the difference between the two center distances is 4 mm; the center distance between the pin holes at two ends of the strip-shaped splicing particles of the '6 mm particle' building block toy 9 hole is 54 mm, the center distance between the pin holes at two ends of the strip-shaped splicing particles of the 'small particle' building block toy 8 hole is 56 mm, and the difference between the two center distances is 2 mm; according to the discovery, the inventor proposes to manufacture an eccentric bolt, so that two strip-shaped splicing particles with the conditions can be directly spliced;

in order to implement the design of the invention, how many groups of strip-shaped splicing particles meeting the conditions in a 6 mm particle building block toy and a small particle building block toy need to be solved so as to provide bases for company decision, design and production, and therefore, the inventor needs to solve the technical problem: how many groups of strip-shaped splicing particles meeting the condition that the center distance between pin holes at two ends has a difference of 2 mm or 4 mm in length in a 6 mm particle building block toy and a small particle building block toy?

The solution proposed by the inventors is as follows:

compared with the first embodiment, the difference of the present embodiment is: further mathematical analysis of the relationship between the value of the integer multiple of the 6 mm length and the value of the different integer multiple of the 8 mm length described in step 2, to find a data set in which the value of the integer multiple of the 6 mm length differs from the value of the different integer multiple of the 8 mm length by 2 mm or 4 mm, the analysis step comprising:

designing software: hardware environment: a CPU: inter (R) Core (TM) i5 3570K @3.4GHz; software environment: windows7x64 flagship edition; c. programming language: JAVA; version number: jdk1.8.0_221; no program load to call third party: 70 lines of code; the main functions are as follows: for two given positive integers (positive integer a and positive integer b) in the number sequence of the natural numbers, finding a pair of positive integers (one integer is named as aT and the other integer is named as bT), and requiring that the product of 'a x aT' is different from the product of 'b x bT' by 2 or 4, and exhausting the first 50 groups of data according to the condition;

the first 50 groups of data were classified: wherein: 24 groups differing by 2 mm, 12 groups each greater than 2 mm and less than 2 mm; 26 groups differing by 4 mm, 13 groups each of greater than 4 mm and less than 4 mm;

the mathematical relation is summarized from the above data types:

the mathematical relationship greater than 2 mm is: (n 2+ 5) × 6+2 (n is an even number), which is a value of an integer multiple of 8;

the mathematical relationship of less than 2 mm is: (n 2+ 3) × 6-2 (n is an even number), which is an integer multiple of 8;

the mathematical relationship between greater than 4 mm and less than 4 mm is: (n 2) × 6 ± 4 (n is an odd number of 1 or more), which is an integer multiple of 8; the following table is the first five data sets of the four data types:

for the particle type building block toy conversion bolt in the step 3, the center of the bolt at the upper part and the center of the bolt at the lower part in the boundary surface are eccentrically arranged with the eccentricity delta.

4. A particle type building block toy conversion bolt is characterized in that a bolt of any type of a 6 mm particle building block toy and a small particle building block toy comprises a first inserting end A, a limiting table B and a second inserting end C; the upper end of first grafting end A is connected spacing B's lower extreme, the lower extreme of second grafting end C is connected spacing B upper end, its characterized in that: according to the manufacturing method of the particle type building block toy conversion bolt, a plane which passes through the middle point of the axial length of the bolt limiting table B and is perpendicular to the axis of the bolt is used as a separating surface, the limiting table and the bolt structure below the separating surface are of a standard size structure of a small particle building block toy, the axial length of the limiting table is one half of the axial length of the original limiting table, the limiting table and the bolt structure above the separating surface are of a standard size structure of a 6 mm particle building block toy, and the axial length of the limiting table is one half of the axial length of the original limiting table; or: the limiting platform and the plug pin structure below the interface are of a size structure of 6 mm particle building block toy standard, the axial length of the limiting platform is one half of the axial length of the original limiting platform, the limiting platform and the plug pin structure above the interface are of a size structure of small particle building block toy standard, and the axial length of the limiting platform is one half of the axial length of the original limiting platform.

5. The particle type building block toy conversion bolt of claim 4, characterized in that: particle class building blocks toy conversion bolt is I type-1 conversion bolt or I type-2 conversion bolt, the interface lower part of I type-1 conversion bolt spacing platform B is the first grafting end A's of I type bolt size structure of "granule" building blocks toy, and interface upper portion is the size structure of the second grafting end C of I type bolt of "6 millimeter granule" building blocks toy: the lower part of the interface of the limiting platform B of the I-type-2 conversion bolt is of a size structure of a first inserting end A of the I-type bolt of the 6 mm particle building block toy, and the upper part of the interface is of a size structure of a second inserting end C of the I-type bolt of the small particle building block toy.

6. The particle type building block toy conversion bolt of claim 4, characterized in that: the particle type building block toy conversion bolt is a II-1 conversion bolt or a II-2 conversion bolt, the lower part of the interface of a limiting platform B of the II-1 conversion bolt is a size structure of a first inserting end A of the II-type bolt of a 'small particle' building block toy, and the upper part of the interface is a size structure of a second inserting end C1 of the II-type bolt of a '6 mm particle' building block toy: the lower part of the interface of the limiting platform B of the II-type-2 conversion bolt is of a size structure of a first inserting end A of the II-type bolt of the 6 mm particle building block toy, and the upper part of the interface is of a size structure of a second inserting end C1 of the II-type bolt of the small particle building block toy.

7. The particle type building block toy conversion bolt of claim 4, characterized in that: the particle type building block toy conversion bolt is a III type-1 conversion bolt or a III type-2 conversion bolt, the lower part of an interface of a limiting platform B1 of the III type-1 conversion bolt is a size structure of a first inserting end A1 of the III type bolt of a 'small particle' building block toy, and the upper part of the interface is a size structure of a second inserting end C2 of the III type bolt of a '6 mm particle' building block toy: the lower part of the interface of the limiting platform B1 of the III-type-2 conversion bolt is of a size structure of a first inserting end A1 of the III-type bolt of the 6 mm particle building block toy, and the upper part of the interface is of a size structure of a second inserting end C2 of the III-type bolt of the small particle building block toy.

8. The particle type building block toy conversion bolt of claim 4, characterized in that: the particle type building block toy conversion bolt is an IV-type-1 conversion bolt or an IV-type-2 conversion bolt, the lower part of an interface of a limiting platform B2 of the IV-type-1 conversion bolt is of a size structure of a first inserting end A2 of the IV-type bolt of a 'small-particle' building block toy, and the upper part of the interface is of a size structure of a second inserting end C3 of the IV-type bolt of a '6 mm-particle' building block toy: the lower part of the interface of the limiting platform B2 of the IV-type-2 conversion bolt is of a size structure of a first inserting end A2 of the IV-type bolt of a 6 mm particle building block toy, and the upper part of the interface is of a size structure of a second inserting end C3 of the IV-type bolt of a small particle building block toy.

9. The particle-based toy building block conversion latch as claimed in any one of claims 4 to 8, wherein: particle type building blocks toy conversion bolt, the first grafting end or the second grafting end of "6 millimeter particle" building blocks toy of particle type building blocks toy conversion bolt do not all establish spacing platform, the axial length of the spacing platform of first grafting end or the second grafting end of "6 millimeter particle" building blocks toy adds on the axial length of the bolt of first grafting end or second grafting end.

10. A particle-based construction toy transformation plug as claimed in any one of claims 4 to 8, characterized in that: the particle type building block toy conversion bolt is characterized in that a first inserting end or a second inserting end of a '6 mm particle' building block toy and a second inserting end or a first inserting end of a 'small particle' building block toy are eccentrically arranged relative to the center of the boundary surface of the limiting table, and the eccentricity is delta.

11. The particle type toy building block conversion bolt of claim 10, characterized in that: the eccentricity δ =1 mm, or the eccentricity δ =2 mm.

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