KR102539217B1 - Combined Textile Having Stereoscopic Pattrern And Article Using the Textile - Google Patents

Abstract

The present invention relates to a combined fabric having a three-dimensional optical illusion pattern capable of easily changing a three-dimensional pattern to be formed on fabric and easily forming various patterns giving a three-dimensional optical illusion effect, and a product to which the same is applied. A combined fabric having a three-dimensional optical illusion pattern formed thereon and a product applying the same include a magnetic pattern mold for generating lines of magnetic force in a predetermined pattern; A hot-melt bonding film in the form of a film in which a hot-melt resin is mixed with a metallic pigment made of ferromagnetic powder and laminated together with a fabric on the magnetic pattern mold; And, in the state where the hot melt bonding film and the fabric are laminated on the magnetic pattern mold, a heating and pressing unit that applies pressure and heat to the hot melt bonding film and the fabric to the magnetic pattern mold to melt the hot melt bonding film and adhere it to the fabric. , The metal pigments in the hot melt bonding film form a predetermined pattern while being arranged along the lines of magnetic force generated in the magnetic pattern mold when the hot melt bonding film is melted by the heat of the heating and pressing unit.

Description

Combined fabric with three-dimensional optical illusion pattern and product to which it is applied {Combined Textile Having Stereoscopic Pattern And Article Using the Textile}

The present invention relates to a combined fabric having a pattern giving a three-dimensional impression (three-dimensional optical illusion pattern), and more particularly, by mixing a metal pigment having ferromagnetism in a hot melt resin to produce a hot melt bonding film, and manufacturing the hot melt bonding film to fabric. When laminated and combined by applying heat and pressure, the hot-melt bonding film melts and softens, and the metal pigment in the hot-melt resin layer flows by magnetic force to give a three-dimensional illusion pattern (on a two-dimensional plane that gives the illusion of a three-dimensional pattern pattern) and products to which it is applied.

In general, in order to form patterns on various fabrics, a screen printing method is usually used, and through this, various designs ranging from letters, figures, pictures, or actual images are implemented, but the situation is limited to flat expression.

Therefore, recently, technologies for three-dimensionally expressing various types of designs on the surface of the fabric have been developed and used. And a lamination method that expresses three-dimensionally by layering, or a PU casting method that expresses a three-dimensional pattern by injecting liquid PU (polyurethane) into a mold is applied.

More specifically, in the case of the pop screen method, after applying the foamed resin to the fabric, hot air drying or natural drying at room temperature, heat is applied to the fixed foamed resin to foam it so as to have a three-dimensional pattern.

This pop-screen method has a problem in that the working process is very complicated and the working time is also very long.

In addition, since the worker takes the form of manually painting the fabric with foamed resin, a difference in the expression of the design occurs depending on the skill level of the worker, which causes a difference in the quality of the finished fabric, as well as a complete foaming state If not, there are problems such as not being able to sufficiently express a desired three-dimensional texture.

In the case of the lamination method, a composition for forming a pattern is sprayed and laminated on the surface of a fabric from a nozzle using a device having a drawing mechanism, and the composition is cured to form a three-dimensional display unit.

In the case of this lamination method, not only does it take a long time for spraying and lamination, but also it takes a very long time to harden the three-dimensionally displayed pattern, which still takes a lot of time.

In addition, in the case of the PU casting method, a base sheet is injected into a mold corresponding to the desired pattern, resin is injected, and then molded and cured to form a three-dimensional pattern. The curing time for the three-dimensionally displayed pattern is very long. However, there is still a problem in that it takes a lot of time to work.

In order to solve this conventional problem, an adhesive fabric is manufactured in the form of a mesh fabric using a hot melt resin-coated yarn or a hot-melt resin-coated yarn and TPU (thermoplastic polyurethane) yarn, and this is a base fabric. After laminating on the surface, through a simple process of molding the surface, a three-dimensional pattern can be implemented on the adhesive fabric itself, so that a method that can extremely shorten the work process and time has been developed.

However, even when the fabric is manufactured using an adhesive fabric using yarn coated with a hot melt resin, it is difficult for the manufacturer to arbitrarily change the pattern, and there is a problem in expressing a pattern giving various three-dimensional effects.

Republic of Korea Patent No. 10-1509157 Republic of Korea Patent No. 10-0278061 Republic of Korea Patent No. 10-1577008

The present invention is to solve the above problems, and an object of the present invention is to melt and soften the hot melt bonding film in the process of combining the hot melt bonding film and fabric in which the metal pigment is mixed, so that the metal pigment has fluidity in the hot melt layer. This is given, and the metal pigment is arranged while flowing in a predetermined pattern by magnetic force to provide a patterned fabric fabric having various three-dimensional optical illusion effects and a product to which it is applied.

The combined fabric having the three-dimensional optical illusion pattern according to the present invention for achieving the above object is formed,

According to the present invention, a hot-melt bonding film containing metal pigment is laminated on a magnetic pattern mold that generates magnetic lines of force in a predetermined pattern, and heat and pressure are applied to the hot-melt bonding film to melt the metal along the magnetic line of force of the magnetic pattern mold. It can be bonded to the fabric while forming a pattern by flowing the pigment. Therefore, since the metal pigments can be rearranged and bonded to the fabric in a desired pattern shape, the combined fabric can have a simple pattern shape as well as a pattern giving a three-dimensional optical illusion effect as desired.

In addition, when changing the pattern shape to be formed on the fabric, the pattern shape can be changed simply by replacing the magnetic pattern mold, so it can be changed into various three-dimensional optical illusion patterns.

The combined fabric of the present invention is applied to various products such as uppers of shoes or fashion accessories such as clothes and bags to provide effects that can produce various fashion senses.

1 is an exploded perspective view showing an embodiment of a fabric combining device for producing a combined fabric according to the present invention.
FIG. 2 is a cross-sectional view of the fabric combining device shown in FIG. 1 .
FIG. 3 is an enlarged cross-sectional view of a main part showing the principle of pattern formation by the fabric combining device shown in FIG. 1. FIG.
4 is a view showing an example in which a pattern is formed on a combined fabric by the fabric combining device shown in FIG. 1;
5 is a flowchart illustrating a method of combining fabrics according to an embodiment of the present invention.
6 is a perspective view showing a shoe to which a combined fabric according to an embodiment of the present invention is applied.
7 is a view showing clothes to which a combined fabric according to an embodiment of the present invention is applied.

The embodiments described in this specification and the configurations shown in the drawings are only one preferred example of the disclosed invention, and there may be various modifications that can replace the embodiments and drawings in this specification at the time of filing of the present application.

Hereinafter, with reference to the accompanying drawings, a combined fabric having a three-dimensional optical illusion pattern and a product to which it is applied will be described in detail according to the following embodiments. Like symbols in the drawings indicate like components.

1 to 3, the fabric bonding device according to an embodiment of the present invention has a predetermined three-dimensional optical illusion pattern by bonding a hot melt bonding film 20 containing a metal pigment 21 to a fabric T. It is for manufacturing a combined fabric, and the magnetic pattern mold 10 for generating magnetic lines of force in a predetermined pattern, and the hot melt bonding film 20 and the fabric T for the magnetic pattern mold 10 Hot melt by applying pressure and heat It includes a heating and pressing unit 40 that melts the bonding film 20 and adheres it to the fabric.

The magnetic pattern mold 10 serves to rearrange the metal pigments mixed in the hot melt bonding film 20 in a predetermined pattern by forming magnetic lines of force in a pattern corresponding to a pattern to be formed on the fabric. The magnetic pattern mold 10 is made of a magnet having magnetic force, and has a non-magnetic pattern engraved in a predetermined pattern (for example, in a pattern opposite to the pattern to be formed on the fabric) in order to form magnetic lines of force in a predetermined pattern. 11) is formed, and magnetic lines of force are formed in the outer region of the non-magnetic pattern 11. The inside of the non-magnetic pattern 11 engraved on the magnetic pattern mold 10 may be filled with a filler 12 made of a non-magnetic resin that is not melted by the heat of the heating and pressing unit 40 . As the filler 12 filled inside the non-magnetic pattern 11, silicon having excellent heat resistance and stability may be applied, but various heat-resistant resins may be used in addition to it. The filler 12 increases the strength of the magnetic pattern mold 10 inside the non-magnetic pattern 11 so that the pattern can be maintained constant even if a disconnection occurs in the outer region of the non-magnetic pattern 11.

The magnetic pattern mold 10 may be made of a magnet made of an elastic material such as a rubber magnet, and it is preferable that the NS poles are magnetized in the vertical direction to form a constant pattern on the fabric T. When the NS poles are magnetized in the left and right directions in the magnetic pattern mold 10, the metal pigment 21 of the hot melt bonding film 20 is not accurately arranged in the intended pattern, and an unintended stripe pattern is formed on the fabric T. In some cases, when the NS pole of the magnetic pattern mold 10 is magnetized in the vertical direction, such an unintended stripe pattern can be prevented from occurring.

The hot melt bonding film 20 functions to form a three-dimensional pattern on the fabric T while being combined with the fabric T, and is in the form of a film in which a metal pigment 21 made of ferromagnetic powder is mixed with a hot melt resin. It is laminated together with the fabric (T) in the magnetic pattern mold (10). The hot melt bonding film 20 may be made, for example, by melting a film made of hot melt resin, mixing the powdery metal pigment 21 in a predetermined weight ratio, and then curing the film into a film form. The metal pigment 21 includes a ferromagnetic metal such as iron, manganese, cobalt, nickel, chromium dioxide, etc., which can flow by magnetic force, and is a pigment particle having a predetermined color such as green, blue, or red, and is a known metal. Pigments can be used.

Meanwhile, a support plate 30 made of a weakly magnetic material or a non-magnetic material may be stacked on one of the upper and lower surfaces of the magnetic pattern mold 10 or on both the upper and lower surfaces. The support plate 30 is made of a metal with very weak magnetism such as aluminum or a highly heat-resistant plastic so as not to prevent the magnetic force of the magnetic pattern mold 10 from affecting the metal pigment 21 of the hot melt bonding film 20. It may be made, and has a film or flat plate shape having a thin thickness. As the support plate 30 is laminated on the magnetic pattern mold 10, even if pressure and heat from the heating and pressing unit 40 are repeatedly applied, the magnetic pattern mold 10 is not damaged and pattern formation and combining operations can be performed for a long period of time. can be done

The heating and pressing unit 40 applies the hot melt bonding film 20 and the fabric T to the magnetic pattern mold 10 in a state where the hot melt bonding film 20 and the fabric T are stacked on the magnetic pattern mold 10. It functions to adhere to the fabric T while melting the hot melt bonding film 20 by applying pressure and heat. The heating and pressing unit 40 may be configured by applying a known press device or a pressure roller device used in a process of combining a known adhesive film or adhesive fabric with another fabric, and the magnetic pattern mold 10 and support A bonding process of the hot melt bonding film 20 and the fabric T is performed by applying heat and pressure to the upper and lower portions of the laminate including the plate 30, the fabric T, and the hot melt bonding film 20.

When heat and pressure are applied to the hot melt bonding film 20 by the heating and pressing unit 40, the hot melt bonding film 20 melts and the metal pigment 21 particles mixed in the hot melt bonding film 20 form a magnetic pattern. While flowing and arranged along the lines of magnetic force generated in the mold 10, a predetermined pattern is formed and bonded to the original fabric (T) together with the hot melt resin.

Referring to FIGS. 1 to 5, a detailed description of a method of manufacturing a combined fabric using the fabric combining device having such a configuration is as follows.

First, in the magnetic pattern mold 10, a non-magnetic pattern 11 is formed in an intaglio in a pattern opposite to the pattern to be formed on the fabric T, and inside the intaglio non-magnetic pattern 11, heat resistance such as silicon and non-magnetic A magnetic pattern mold 10 is manufactured by filling and curing a filler 12 made of a resin having a property.

A hot melt bonding film 20 is manufactured by melting a film or pellet made of a hot melt resin, mixing particles of a metal pigment 21 having a predetermined color therein, forming a film, and curing the hot melt resin.

Next, after installing the magnetic pattern mold 10 manufactured as described above in the heating and pressing unit 40, the fabric T and the hot melt bonding film 20 are laminated on the upper side of the magnetic pattern mold 10 to form a laminate. is configured (step S1). At this time, a support plate 30 made of a weak magnetic material or a non-magnetic material is further laminated on one of the upper and lower surfaces of the magnetic pattern mold 10, or on both the upper and lower surfaces, and then hot-melt bonded to the fabric (T) A laminate may be formed by laminating the films 20 .

When the laminate is configured as described above, the heating and pressing unit 40 applies heat and pressure to the hot melt bonding film 20 by simultaneously applying heat and pressure to the laminate at the top or bottom, or at the top and bottom of the laminate. When heat higher than the melting point of the hot melt resin is applied to the hot melt bonding film 20, the hot melt bonding film 20 is melted and bonded to the fabric. It flows in the hot melt resin layer by the magnetic force of the pattern mold 10 and forms a pattern while being arranged along the magnetic force lines of the magnetic pattern mold 10 (step S2).

Therefore, as a pattern is formed on the fabric T by the metal pigment 21, the combined fabric is completed (see FIG. 4).

As described above, when the hot melt bonding film 20 is melted by the heating and pressing unit 40 and bonded to the fabric T to form a combined fabric having a three-dimensional optical illusion pattern, the combined fabric is separated from the heating and pressing unit 40. The combined fabric in which the three-dimensional pattern is formed is completed by removing the heat and pressure applied to the combined fabric, followed by cooling and curing (step S3).

According to the present invention as described above, the hot-melt bonding film 20 containing the metal pigment 21 is laminated on the magnetic pattern mold 10 that generates magnetic lines of force in a predetermined pattern, and hot-melt by applying heat and pressure thereto By melting the bonding film 20 and flowing the metal pigment 21 along the magnetic lines of force of the magnetic pattern mold 10, the combined fabric can be produced by bonding to the fabric T while forming a pattern. Therefore, since the metal pigment 21 can be rearranged in a desired pattern shape on the combined fabric, not only a simple pattern shape but also a pattern giving a three-dimensional optical illusion effect can be easily formed as desired.

In addition, when changing the pattern shape to be formed on the fabric T, the pattern shape can be changed simply by replacing the magnetic pattern mold 10, so the pattern can be changed very easily.

The combined fabric with the three-dimensional optical illusion pattern formed in this way is used for the whole or part of the upper of the shoe 100 as shown in FIG. 6, or used for clothing as shown in FIG. 7 to provide various three-dimensional optical illusion effects. can do.

In the above, the present invention has been described in detail with reference to the examples, but those skilled in the art to which the present invention belongs will be able to make various substitutions, additions, and modifications without departing from the technical idea described above. Of course, it should be understood that such modified embodiments also belong to the protection scope of the present invention, which is defined by the appended claims below.

T: fabric 10: magnetic pattern mold
11: non-magnetic pattern 12: filling material
20: hot melt bonding film 21: metal pigment
30: support plate 40: heating and pressing unit

Claims (7)

with fabric;
A hot-melt bonding film in the form of a film in which a ferromagnetic metal pigment is mixed in a hot-melt resin, laminated on the fabric, and then bonded to the fabric by applying heat and pressure by a heating and pressing unit;
Including,
The fabric and the hot melt bonding film are magnets made of an elastic material in which NS poles are magnetized in the vertical direction and are laminated on a magnetic pattern mold that generates lines of magnetic force in a predetermined pattern, and then bonded to each other by applying heat and pressure,
When the fabric and the hot-melt bonding film are laminated on the magnetic pattern mold and bonded by applying heat and pressure, the hot-melt bonding film is melted and softened, and the metal pigment in the hot-melt resin flows by the magnetic force generated in the magnetic pattern mold to form a predetermined A composite fabric that is arranged in a pattern and has a three-dimensional optical illusion pattern. delete The method of claim 1, wherein a non-magnetic pattern engraved in a predetermined pattern is formed on the magnetic pattern mold so that magnetic lines of force are generated in an area outside the non-magnetic pattern, so that the metal pigment of the hot melt bonding film is transferred to the non-magnetic pattern of the magnetic pattern mold. A combined fabric arranged in a pattern corresponding to the outer region of the The combined fabric according to claim 3, wherein the inside of the non-magnetic pattern of the magnetic pattern mold is filled with a filler made of a non-magnetic resin that is not melted by the heat of the heating and pressing unit. delete Shoes made using the combined fabric according to claim 1. Clothing made using the combined fabric according to claim 1.

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