RU2658276C1 - Kit for forming a volumetric body and method for manufacturing thereof - Google Patents

Abstract

FIELD: games.

SUBSTANCE: group of inventions relates to developing games and to methods for manufacturing kits for creativity. Method for manufacturing a kit for forming a volumetric body comprises unreeling a reel of raw material into rectangular sheets, forming flexible modules, containing at least one planar geometric figure, knuckle lines and valves configured to apply glue on them, and cutting out modules of complex configuration by means of cutting blades. As a raw material, a material with a three-layer structure, in which a core layer is made of a cellulose-based material and edge layers are made in the form of a film containing mica, plates and metal particles, is used. One-sided printing is further performed on rectangular sheets with the formation of contours and knuckle lines of the kit modules by ultraviolet offset paints for forming a volumetric body. Kit modules of rectangular sheets are cut out with separating or weakening modules in rectangular sheets by slits for subsequent separation during the formation of a volumetric body and a kit of modules or rectangular sheets with weakened modules are completed. Kit for forming a volumetric body, made by the method for manufacturing a kit for forming a volumetric body comprises at least one flexible module.

EFFECT: generalized technical result is increased strength of module material and reduced number of defective articles in the production of kits.

12 cl, 2 dwg

Description

The group of inventions relates to developing games and to methods for the production of sets for creativity, in particular, sets for forming three-dimensional bodies, which can be used to create various prefabricated structures or as devices for developing various design skills in creating art forms and models.

The most important component of spatial thinking is spatial imagination. His role in the creative activity of man in the field of science, technology, art is very great.

Problems in the study and development of space are solved by effective modeling methods. One of the oldest branches in this area is Origami, which is the ancient folk art of Japan in folding paper figures.

From the "prior art" there is known a method of manufacturing a set for origami, including the dissolution of the roll of source material on rectangular sheets. Then stamping is performed - cutting down sheets of curly segments of ribbon blanks with simultaneous drawing on them by forcing fold lines that form the correct geometric shapes along the entire plane of the module blank. Next, longitudinal bending and folding into the envelope of the tape blanks are carried out with the simultaneous joining of the curved side free sides in the middle part of the tape blank. The billet is cut into a double tape with a knife-heater at an angle of 45 ° to the longitudinal axis with melting along the cutting line into equal strips with the formation of a large parallelogram and two equal small parallelograms, congruent with the parallelogram with the connector line in the middle of the module. Paper or thin cardboard can be used for the manufacture of modules (see RF patent No. 2223809, class A63H 33/16, publ. 02.20.2004).

In addition, from the "prior art" a set of modules for origami is known in which each module contains a planar geometric figure formed by three parallelograms, the largest of which is the middle one and joined along the embossing line with its smaller sides and the larger sides of two equal smaller parallelograms, the combination of which when folded and joined by their free large sides, it is congruent to a larger parallelogram, and paper or thin cardboard can be used as the materials of the modules (see RF patent No. 2223809, class A63H 33/16, publ. 02.20.2004). The technical problem is the low strength of the module material, in particular, the bend of a part of the module during the production or manufacture of a three-dimensional body can be accompanied by a rupture of paper or thin cardboard, in addition, bending not along the bend line will lead to rupture of the material of the module or plastic deformation, which will lead to damage to the module and will not allow it to be used further to create a volumetric body.

The task of the group of inventions is to eliminate the above disadvantages.

The general technical result consists in increasing the strength of the material of the module and reducing the number of defective products in the manufacture of a volumetric body.

The technical result is ensured by the fact that the method of manufacturing a kit for forming a three-dimensional body includes the dissolution of a roll of source material on rectangular sheets, the formation of flexible modules containing at least one planar geometric figure, bend lines and valves made with the possibility of applying glue to them, and die cutting modules of complex configuration by cutting knives. As a starting material, a material with a three-layer structure is used, in which the central layer is made of cellulose-based material, and the edge layers are made in the form of a film containing mica, plates and metal particles. One-sided printing is carried out on rectangular sheets with the formation of the outline and inflection lines of the set modules for forming a three-dimensional body with ultraviolet offset inks. Die-cutting the modules of a set of rectangular sheets with their separation or weakening of the modules in rectangular sheets with slots for subsequent separation during the formation of a three-dimensional body. Creasing lines are performed on all kink lines and a set of modules or rectangular sheets with weakened modules is completed. In accordance with particular cases of implementation, the method has the following features.

The central layer is made of paper with a density of 290 g / m ² .

The central layer is made of cardboard.

The film contains a film-forming substance and a pigment mixture comprising mica particles coated with titanium oxide of 0.1-35 μm in size, plates of 0.5-25 μm in size and metal particles of 0.1-12 μm in size. The plates are made of precipitated calcium carbonate and a binder.

The plates are made in the form of flakes obtained by the sol-gel method by hydrolysis of a metal alcoholate solution using a basic catalyst.

The metal particles are made of aluminum, or zirconium, or tin, or titanium.

When printing, the kink lines are made in the form of open lines, which mean the module is folded inwards, and in the form of open lines with dots, which mean the module is folded out.

The technical result is also ensured by the fact that the kit for forming a three-dimensional body includes at least one flexible module containing at least one planar geometric figure, inflection lines, scoring lines made on all inflection lines, and valves.

The essence of this group of inventions is illustrated by the following illustrations:

FIG. 1 is a flowchart illustrating a method;

FIG. 2 is a general view of a module for forming a volumetric body.

In FIG. 2 displays the following items:

1 - module for the formation of a volumetric body;

2 - line of inflection;

3 - valve.

A method of manufacturing a kit for forming a three-dimensional body includes the manufacture of a central layer based on cellulose fibers in the form of a web. The central layer can be made in the form of paper or cardboard. The fibrous web is formed, the web is dried, calendaring to the required thickness, the edge layers are applied with the help of a spray nozzle and rolls providing the required film thickness of 2-10 microns. Edge layers contain mica, plates, and metal particles. Film-coated web is dried. Next, produce the dissolution of the roll of source material on rectangular sheets. Then, one-sided printing is carried out with the formation of ultraviolet offset inks of the contours, valves and inflection lines of the set modules for forming a three-dimensional body. When printing, the kink lines are made in the form of open lines, which mean the module is folded inwards, and in the form of open lines with dots, which mean the module is folded out.

Then, the modules of complex configuration are cut by means of cutting knives, as well as the formation of scoring lines on the inflection lines. Die cutting and formation of scoring lines is carried out with a stamp with installed cutting knives and scoring lines. Die cutting is carried out with knives with sharp edges cutting through cardboard or paper. The knives have a cutting angle of 30 ° -110 ° and are made of laser-hardened spring steel chemically etched. At the same time, depending on the configuration of the set, they can completely die cut modules from rectangular sheets or weaken them in rectangular sheets through or through notches. Scoring is performed using scoring lines with rounded edges that form grooves by pressing the surface of the cardboard or paper into the groove of the counter-stamp. Knives are longer than scoring rulers, as they must cut through the cardboard through. Complete a set of modules or from rectangular sheets with weakened modules. The kit module 1 for forming a three-dimensional body is made flexible and contains kink lines 2 and scoring lines. It has a three-layer structure, while the edge layers are made in the form of a film containing mica, plates and metal particles. The implementation of the module with a three-layer structure increases its strength, and the presence of edge films containing mica, plates and metal particles eliminate the rupture of the material of module 1 during the formation of a three-dimensional body. The kink not in the line of kink 2 will not lead to rupture of the material of module 1, the residual deformation will be insignificant, while module 1 will not be destroyed or damaged and can be used further to create a volumetric body. Inflection beyond the inflection line 2 is practically excluded due to the presence of scoring lines. Module 1 additionally contains valves 3, providing the possibility of applying glue to them and connecting either with other valves 3 of the same module 1, or with valves of other modules included in the kit. The central layer is made of cellulose-based material, while the central layer can be made of paper with a density of 290 g / m ² or cardboard.

The film contains a film-forming substance and a pigment mixture, including mica particles coated with titanium oxide, 0.1-35 μm in size - 30-70%, plates in the size of 0.5-25 μm - 15-30% and metal particles in the size of 0.1- 12 microns - 15-30%, an organic binder was used as the film-forming substance - the rest is up to 100 wt. % Polyvinyl alcohol, polyvinyl acetate dispersions, latexes and resins can be used as a binder. Get the substance of the film by conventional methods of mixing a binder with a filler.

The plates can be made of precipitated calcium carbonate and an anionic polar binder. In this case, calcium carbonate is precipitated in the form of aragonite, its content in the plates is up to 75%, the content of the anionic polar binder is up to 100 wt. % Polyvinyl alcohol, polyvinyl acetate dispersions, latexes and resins can be used as a binder. The plates are obtained by conventional methods of mixing a binder with a filler and grinding. The plates can be made in the form of flakes obtained by the sol-gel method by hydrolysis of a solution of a metal alcoholate (aluminum, zirconium, tin, titanium) using a basic catalyst. The metal particles can be made of aluminum, or zirconium, or tin, or titanium.

The advantages of this group of inventions are as follows:

- a sufficiently high strength of the material of the module;

- due to the layered structure of obtaining a module with more rounded edges, eliminating the possibility of applying cuts to the user when forming a three-dimensional body;

- the ability to obtain from the modules of the three-dimensional body, resistant to plastic deformation, pollution and exposure to sunlight;

- reduction in the number of defective products in the manufacture of sets;

- development of fine motor skills in children;

- the exception of damage to the part during the formation of the three-dimensional body.

Claims (12)

1. A method of manufacturing a kit for forming a three-dimensional body, including the dissolution of the roll of source material on rectangular sheets, the formation of flexible modules containing at least one planar geometric figure, bend lines and valves, made with the possibility of applying glue on them, and die cutting modules complex configuration by means of cutting knives, characterized in that as the starting material use a material with a three-layer structure, in which the Central layer is made of cellulose-based material PS, and the edge layers are made in the form of a film containing mica, plates and metal particles, they perform one-sided printing on rectangular sheets with the formation by the UV offset inks of the contours and inflection lines of the set modules to form a three-dimensional body, die set modules are made of rectangular sheets with their separation or by weakening the modules in rectangular sheets with slots for subsequent separation during the formation of the volumetric body, scoring lines are made on all the inflection lines and a set of modules or from rectangular sheets with weakened modules. 2. The method according to p. 1, characterized in that the Central layer is made of paper with a density of 290 g / m ² . 3. The method according to p. 1, characterized in that the Central layer is made of cardboard. 4. The method according to p. 1, characterized in that the film contains a film-forming substance and a pigment mixture comprising mica particles coated with titanium oxide, a size of 0.1-35 μm, a plate size of 0.5-25 μm and a metal particle size of 0, 1-12 microns. 5. The method according to p. 4, characterized in that the plates are made of precipitated calcium carbonate and a binder. 6. The method according to p. 4, characterized in that the plates are made in the form of flakes obtained by the sol-gel method by hydrolysis of a solution of a metal alcoholate using a basic catalyst. 7. The method according to p. 4, characterized in that the metal particles are made of aluminum. 8. The method according to p. 4, characterized in that the metal particles are made of zirconium. 9. The method according to p. 4, characterized in that the metal particles are made of tin. 10. The method according to p. 4, characterized in that the metal particles are made of titanium. 11. The method according to p. 1, characterized in that when printing the kink lines are made in the form of open lines, indicating the bend of the module inward, and in the form of open lines with dots, indicating the bend of the module outward. 12. Set for the formation of a volumetric body made by the method according to any one of paragraphs. 1-11, comprising at least one flexible module comprising at least one planar geometric figure, inflection lines, scoring lines made on all inflection lines, and valves.

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