KR20090003694A - Emblem of expressing multi-colors, and the fabricating method of the same - Google Patents

Abstract

A metal, a hologram emblem, and a manufacturing method thereof are provided to satisfy a surface protection function of a surface process layer by laminating respective layers composed of multilayer film type as one sheet and to obtain various colors by using a printing method. An emblem with a solid pattern includes a thermoplastic base film(11) and a surface process film(13). The surface process film is laminated and coupled on an upper part of the base film. One or two thermoplastic bases film are laminated and coupled. The surface process layer is coated and formed in the bottom surface of the surface process film and a printing layer(14) is coated and formed in the top surface of the surface process film.

Description

Emblem and expressing multi-colors, and the fabricating method of the same

1 is an exploded perspective view of a first embodiment emblem of the present invention.

Figure 2 is a cross-sectional structural view of the emblem of the first embodiment of the present invention.

Figure 3 is a process block diagram showing a method of manufacturing an embodiment of the present invention emblem.

4 is a front view of the emblem of the first embodiment of the present invention;

The schematic diagram for demonstrating the perforation method of a laminated sheet.

Figure 6 is a partial process block diagram showing a method of manufacturing another embodiment emblem of the present invention.

Figure 7 is an exploded perspective view of the thermoforming mold and the composite sheet showing an embodiment thermoforming processing method constituting the method of the present invention.

Figure 8 is a cross-sectional view of the thermoforming mold and the composite sheet showing an embodiment of the thermoforming process constituting the method of the present invention.

Figure 9 is an exploded perspective view of the cutting mold and the composite sheet showing an embodiment cutting processing method constituting the method of the present invention.

Figure 10 shows an embodiment cutting method constituting the method of the present invention,

  (A) is a cross-sectional view of the cutting mold and laminated sheet laminated before being cut,

  (B) is a cross-sectional view of the cutting mold and laminated sheet laminated after cutting.

11 is a cross-sectional structural view of a second embodiment emblem of the present invention;

12 is a cross-sectional structure diagram of a third embodiment emblem of the present invention.

           ((Explanation of symbols for main part of drawing))

         10. Prosthetic film 11. Base film

         12. Surface treatment layer 13. Surface treatment film

         14. The printed layer 41. The emblem

         41A. Core Glyph 41B. Border

         41C. Blank sheet 51.

         71.Guide Pin 72. Thermoforming Lower Mold

         73. Thermoforming Mold 91. Cutting Blade

         92. Lower die mold 93. Upper die mold

         G. Guide pin groove H. Standard by standard ball

         P. Composite Sheet Reference Point

According to the present invention, a bottom surface of a thermoplastic resin is bonded to a prosthetic film having a higher heat resistance than the base film or a strength greater than that of the base film, and various surface treatment layers such as a metal deposition layer or a hologram layer are formed on the top surface of the base film. The present invention relates to a metal and hologram emblem and a method of manufacturing the same, which are capable of expressing a multi-color in one emblem by forming a precise printed layer of various colors on the upper surface of the laminated sheet combining the formed surface treatment film.

Emblem is a symbol of a unique symbol or representation that represents a nation, family, or individual.A symbol is used to represent an individual, family, clan, group, or association. It has been mainly used only in certain families, such as the nobility.

In addition, the traditional emblems, such as those embroidered on fabrics and used mainly in specific groups, have recently increased their brand value for companies and products, along with rapid industrial development, and at the same time, awareness of their names and products. In order to increase the social has been widely used, these emblems are generally used in the form of stickers and then attached to the surface of various products.

The emblem may be classified into planar and three-dimensional, which is flat, and dried by applying a transparent synthetic resin solution on the surface after printing figures or letters on a base surface such as aluminum sheet or film. Because of its simplicity, it is not used much in recent years.

Instead of the planar emblem as described above, the three-dimensional emblem mainly used in recent years, metal plating or metal deposition is used in order to obtain a luxurious metal texture.

The method using metal plating is injection molding of synthetic resin into a specific shape and then metal plating on the surface of it, and it has a three-dimensional effect, but it is difficult to obtain two or more colors of synthetic resin injection molded products due to the characteristics of injection molding. Not only can not be avoided, because the rigidity of the injection-molded synthetic resin and metal plating layer does not have the flexibility of the emblem itself, there is a disadvantage that it is difficult to attach to parts other than the surface suitable for the injection shape.

That is, when the injection surface of the emblem is ejected in a flat state, it is possible to attach only to the flat surface, and in the case of being ejected in a bent form, only the bent surface.

In addition, in the case of an injection molded product, the monotony of color may be avoided. In order to do this, it is necessary to perform a coloring operation through a masking operation on the injection molded product.

As described above, in order to solve the disadvantage of the emblem using the injection, in particular, there is little flexibility, the method of using metal deposition, generally aluminum deposition, has been developed on the film having the coincidence.

The conventional method of manufacturing the emblem using metal deposition is to produce a composite sheet by laminating a surface treatment film formed by metal deposition on a thermoplastic base film, and then use a high frequency thermoforming process for forming irregularities on the composite sheet using high frequency or the like. Since the film is used in comparison with the injection molding emblem having a high rigidity, the flexibility of the emblem is good, and the free attachment is almost free from the flat surface as well as the condition of the skin adhesion surface such as the curved surface. There are possible advantages.

However, in the method of manufacturing the emblem using metal deposition, only one color of the deposited metal layer can be expressed, so that monotony cannot be avoided, and the decoration and aesthetic quality of the product by the emblem attached to the surface of the product can be avoided. There is a limit to increase.

In addition, since the emblem is made of almost pure logos, numbers, letters and the like, there is a disadvantage in that it is not suitable for attaching to flexible and repeatedly curved portions such as uppers of shoes.

In other words, when the upper of a shoe is repeatedly bent, bent, or bent when walking or exercising, when an emblem represented only by the metal deposition layer is attached to the outer surface, the deformation force is also applied to the emblem attached to the outer surface according to the movement of the upper. As a result, cracks may occur in the metal deposition layer, or the emblem may be damaged such that the metal deposition layer is easily peeled off from the surface of the film, thereby degrading the aesthetic quality of the product.

The present invention was devised to solve all the problems of the conventional emblem and its manufacturing method, by laminating and combining each layer formed of a multi-layered film into one sheet, the flexibility of the material itself and the metal deposition layer While satisfying the surface protection function of the surface treatment layer such as a hologram layer and the like, the flexibility of the emblem is not deteriorated, and precise printing is possible, so that various effects such as multicolor expression, metallic effect, and etching effect can be obtained. It is an object of the present invention to provide an emblem and a method of manufacturing the same.

Then, after forming various sizes of margins around the basic patterns to be expressed by the emblem, embossing patterns such as lattice shapes are formed on the margins so as to absorb deformation forces applied from the outside, thereby providing a repetitive bending motion. It is another object of the present invention to provide an emblem and a method of manufacturing the same, which can be attached to shoes, clothing, etc. without being damaged for a long time, as well as being capable of expressing multicolors.

The above object of the present invention is achieved by a base film, a surface treatment film and a prosthetic film having different heat resistance and rigidity.

Emblems capable of expressing a multi-color of the present invention, as shown in Figures 1 and 2, the base film 11; A surface treatment layer 12 laminated on the top surface of the base film 11; A surface treatment film 13 laminated and bonded to the top surface treatment layer 12; It has a cross-sectional structure consisting of a printing layer 14 or the like formed on the upper surface of the surface treatment film 13.

The surface treatment layer 12 may be, for example, a metal deposition layer in which a metal such as aluminum or chromium is deposited on the bottom surface of the surface treatment film 13, or may be a hologram layer treated with nano embossing. The surface treatment layer 12 may be formed through various methods, such as a printing layer using ink or a transfer layer using a transfer technique without using deposition or hologram.

At this time, the print layer as the surface treatment layer 12 and the print layer 14 as a component of the emblem of the present invention are separate, and the print layer 14 is formed of the surface treatment film 13 laminated on the base film 11. It is coated on the upper surface.

In addition, the base film 11 is, as a recessive form good thermoplastic resin film, UTP U (T hermoplastic P oly U rethane) film, Ti ACF (T hermoplastic P oly O lefin) film, P V's (P oly V inyl hloride C) can be exemplified a film, Phi (P oly P ropylene) film feeder (P oly E tylene) film or the like.

In addition, as the surface treatment film 13, a P y (Poly E thylen T erphthalate) film, a P vie V y ily D ene F luoride film, E thylene V inyl alc OH l For example, film and the like can have heat and press molding properties and high surface strength while maintaining the surface effect of the surface treatment layer by metal deposition, hologram embossing, printing and transfer. It is preferable to use the film which has a.

At this time, the surface treatment film 13 and the base film 11 on which the surface treatment layer 12 is formed may be bonded using an adhesive, or may be directly bonded by heating and pressing without an adhesive. An adhesive layer may be interposed between 11) and the surface treatment layer 12.

As described above, the emblem of the present invention, in which two thermoplastic resin films are laminated and bonded, has a structural feature in the print layer 14 formed on the upper surface of the surface treatment film 13 when compared with the conventional emblem. By varying the printing technique for forming such a printed layer 14, it is possible to give various effects to the emblem.

However, in order to form a printed layer on the surface of the film, and to precisely perform operations such as drying, thermoforming, and cutting after forming the printed layer, the surface of the film should be kept as flat as possible. The base film 11 and the surface Heat and pressure are applied to the film when the surface treatment film 13 coated with the treatment layer 12 is combined. When the two films are combined and cut into sheets, the two-layer sheet (film only) ) Is not easy to maintain a flat state, it is easy to be bent or bent, as a result, it is difficult to form a precise printed layer on the surface of the two-layer sheet is not flat.

That is, in the case of forming a printing layer on the upper surface of the surface treatment film by using various printing techniques including screen printing and gravure printing, when the flatness of the two-layer sheet falls, the printing state for each sheet cannot be kept constant and is uneven. It is easy to be done.

In addition, the sheet is deformed by drying heat in the process of drying the ink after printing, so that it is difficult to precisely position the sheet during the thermoforming process or the cutting operation, so that precise work may be difficult and productivity may be reduced. Due to the inherent flexibility and elasticity of good thermoformable films, printing, thermoforming and cutting are not easy.

That is, in order to be able to process the sheet smoothly and precisely, the sheet must have good thermoforming, flexibility and elasticity, and at the same time, the proper stiffness, which is opposite to the flexibility and elasticity, to maintain the flatness of the sheet during processing. There is a difficulty to have.

Therefore, in order to solve the above problems, the bonding film of the relatively high heat resistance and rigidity is bonded to the bottom surface of the base film before printing, and the work such as cutting, drying, printing and thermoforming processing with the bonding film being combined There are technical features of the method of the present invention.

That is, the emblem of the present invention ignores the surface treatment layer or the print layer, which is a coating layer, and in terms of the film alone, a two-layer sheet having a structure in which the base film and the surface treatment film are laminated, or a surface treatment film in the process of manufacturing the emblem. The three films, the base film and the complementary film, are laminated and bonded sequentially in a three-layered sheet, that is, the work is made in the form of a laminated sheet.

As described above, the prosthetic film for easy and precise emblem processing operation, although thermoplastic resin film is used as the base film, the heat resistance and the rigidity should be higher than the base film, but the thermal formation is relatively lower than the base film, Although it is possible to mold by the relatively less elasticity than the base film (stiffness, that is, it should have a characteristic that the rigidity is maintained properly.

A film that has the characteristics as described above, are exemplified such as blood ET film, piahyi (P oly I mide) film, blood two yen (P oly E thylene N aphthalate) film, Oh Phi (O rieted P oly P ropylene) film In terms of price and functionality, PTI film is preferable.

In other words, the film having higher heat resistance and rigidity than the base film and the surface treatment film is used as the prosthetic film. The temperature conditions such as drying or thermoforming processing during the manufacturing process are suitable for the base film and the surface treatment film, but the rigidity of the prosthetic film is excellent. It should be carried out within a range that can be properly maintained.

Of course, the prosthetic film is separated and removed after the manufacture of the emblem of the present invention is completed.

The emblem of the present invention manufactured using the prosthetic film as described above, as shown in Figure 2,

Laminating and bonding the base film on the upper surface of the prosthetic film as a support (100);

A step 200 of laminating a surface treatment film having a surface treatment layer formed on the surface of the base film and cutting the film to a predetermined size to obtain a laminated sheet having a structure in which three films are laminated;

First drying the composite sheet in a range of 80 to 150 ° C. (300);

Printing an emblem pattern on a surface of the dried laminated sheet (400);

A second step (500) of drying the laminated sheet on which the print layer is formed at 80 to 150 ° C;

Performing a thermoforming process to give a three-dimensional shape to the emblem pattern of the secondary dried plywood sheet;

Cutting only the shape of the emblem 700 so that the prosthetic film is not cut in the thermoformed composite sheet;

Bar sequential processes, such as the step of separating the cut emblem from the sheet 800, look at each step in detail as follows.

The first step 100 and the second step 200 of laminating the film may be reversed, and the two steps 100 and 200 may be performed together.

Then, the primary drying step 300, after printing and secondary drying to minimize the deformation of the foam sheet by shrinkage by the heat applied to the foam sheet during the secondary drying step 500 for drying the ink after printing Pre-drying is a process that allows precise positioning of the composite sheet during the process operation.

That is, the pre-shrinkage of the composite sheet is sufficiently caused by primary drying, thereby minimizing the shrinkage of the composite sheet during the secondary drying after printing, thereby preventing the shape change of the printed emblem and maintaining the flatness of the composite sheet itself properly. It becomes possible.

In addition, the temperature in each drying step 300, 500 may be changed depending on the type of film, the presence or absence of the adhesive, the ink type or the thickness of the printing layer, etc., if the lower than the lower limit temperature The drying time becomes longer, and if it is higher than the upper limit temperature, the drying time becomes short.

Therefore, the above-described drying temperature described in one example may be appropriately adjusted to suit the working conditions, but excessive deformation of the film may occur even if the drying time is shortened in order to increase the productivity in order to increase the productivity. Special care should be taken as this may result.

The printing step 400 is a step of forming a printing layer on a surface of a laminated sheet having a predetermined size, for example, a width × length of 500 mm × 600 mm, that is, a surface of a surface treatment film. The pattern may be printed, or a plurality of emblem patterns may be printed together.

And at this stage. Depending on the printing technique, not only more than 2 degrees of color, but also various patterns, as well as a variety of processing such as high gloss, matte, metallic and pearl, etching, gradation or fading, pattern or texture, hairline or brushing, etc. Do.

The thermoforming processing step 600, a three-dimensional (3D) shape is given to the laminated sheet printed with the emblem pattern is a shape of the entire emblem is made by using a high frequency, preheating, oscillation and cooling It consists of a sequential process, such as preheating is performed at about 50 ℃ for 2 to 5 seconds, the cooling temperature is room temperature.

At this time, as shown in Figure 4, the emblem emblem of the emblem 41 as a whole, the core pattern portion 41A and the border pattern portion 41B and other margin pattern portion (to be actually displayed in the emblem, such as trademark, logo ( 41C), it is preferable to form an embossed pattern having a relatively small unevenness, that is, a relatively small size using a mold used for thermoforming processing in the margin pattern 41C.

And, the size of each irregularities constituting the embossed structure formed on the margin pattern 41C is preferably small, which is the margin pattern except for the core pattern 41A that is three-dimensionally processed when metal deposition is formed on the surface treatment film ( To minimize damage to the metal deposition layer of 41C).

That is, when the margin glyph 41C remains flat without uneven processing, when the emblem is attached to the upper of the shoe, the metal deposition of the entire emblem is separated or cracked from the film according to the movement of the upper. This can easily happen.

However, if uneven processing is performed on the margin pattern 41C, the irregularities of the margin pattern 41C, which increase in flexibility while increasing the surface area, absorb the deformation force generated by the movement of the upper to thereby damage the metal deposition layer. Prevent or delay.

In addition, in the decorative aspect of the emblem pattern, the border pattern part 41B and the margin pattern part 41C may be treated the same without distinction, but the border pattern part 41B and the margin pattern part 41C may be distinguished. It is advisable to carry out printing and finishing.

In addition, it is also preferable that the core glyph 41A and the edge glyph 41B protrude more than the margin glyph 41C when the three-dimensional shape is imparted by the thermoforming process, and in addition, if necessary, the core glyph ( 41A) and the edge pattern portion 41B and the margin pattern portion 41C can be printed and post-processed in various ways so as to be clearly distinguished.

Emblem cutting step 700, the upper surface of the prosthetic film after passing through the surface treatment film and the base film along the shape of the emblem in order to be able to separate the emblem pattern, that is, the emblem from the composite sheet, that is, A step of cutting from the printing layer to the surface treatment film and the surface treatment layer is carried out by a press method using a mold equipped with a Peruvian blade matching the shape edge of the emblem.

The emblem separation step 800 is to separate the emblem from the composite sheet, that is, to separate the emblem from the surface of the prosthetic film.

In the method of the present invention made as described above, in order to ensure that the precise thermoforming process is carried out along each emblem pattern printed on the composite sheet, and to precisely cut and separate so that the emblem is not damaged, the thermoforming process and the mold The position of the sheet should not change during cutting of the emblem.

Therefore, in the case of thermoforming processing or die cutting, the sheet is fixed with a jig. When fixing the position of the sheet as a jig, the sheet is deformed or deformed at the moment when the descending mold contacts the sheet. Since it is inevitably changed slightly, processing defects, cutting defects, etc., which cannot be thermoformed at the correct position, may occur.

In order to solve the above problems, it is necessary to minimize the deformation or change of position of the composite sheet. For this purpose, it may be necessary to reduce the work speed, that is, the productivity of production. Therefore, precise thermoforming and cutting without losing productivity It is also preferable to apply the guide pin method to enable the operation, looking at this as follows.

As shown in FIG. 5, after printing one or more of the sheet sheets of reference point P around the edge of the sheet 51 in the printing step 400, the sheet sheet using an automatic imaging device which is one of the perforation apparatuses. Punch to the reference point (P).

And, by using the NC (Numerical Control) punching machine, based on the perforated plywood sheet reference point (P), the emblem-specific reference ball (H) around each of the emblems 41 printed on the plywood sheet 51 Perforate.

At this time, the relationship between the composite sheet reference point (P) and the emblem-specific reference hole (H) is a predetermined value, NC puncher is automatically based on the emblem-specific reference hole (H) based on the composite sheet reference point (P). Perforated.

That is, between the secondary drying step 500 and the thermoforming processing step 600 after printing in the method of the present invention, as shown in Figure 6, through the hole for the guide pin for the post-processing in the secondary dried laminated sheet Perforation 500 'may be added.

In this case, the step 500 'of punching on the sheet includes the steps 500'-1 of punching the sheet of the sheet of plywood printed on the edge of the sheet of the sheet using the automatic imaging device; Comprising the perforated happo sheet reference point (P) on the basis of the punching is made to the punching emblem by the standard ball (H) (500-2).

In the case of punching using the automatic image device as described above, punching is possible with an error range of 0.05mm or less, and by drilling additional emblem-specific reference holes (H) using NC punching machines, the reference holes for guide pins (H) can be precisely positioned. ), And the thermoforming processing, cutting processing, etc. are made in the state where the guide pin penetrates each reference hole (H). Done.

Looking at the method of operation by perforation as described above, in the thermoforming processing step 600, as shown in Figures 7 and 8, a flat thermoforming lower mold (a plurality of guide pins 71 upright along the upper edge) ( 72, the laminated sheet 51 is printed with the emblem pattern so that each guide pin 71 penetrates the respective standard holes H of the fabric sheet 51, and then the emblem irregular pattern is engraved on the bottom surface. By heating and pressurizing the composite sheet 51 with the formed thermoformed mold 73, the flat emblem pattern has a three-dimensional effect.

Then, in the cutting step 700 for separating only the emblem 41 from the haptic sheet 51 after the thermoforming processing is completed, as shown in Figs. 9 and 10, on the top view, the lung having the same shape as the outline of the emblem The cutting edge 91 constituting the loop is upright and the lower cutting mold 92 in which a plurality of guide pins 71 are erected along the upper edge thereof, and each guide pin 71 is based on each emblem of the composite sheet 51. Unlike the thermoforming step, the laminated sheet 51 thermoformed to penetrate the ball H is positioned on the bottom so that the laminated sheet 51 is turned upside down and has a flat bottom. By pressing the composite sheet 51 with the upper cut mold 93, only the emblem in the composite sheet 51 can be cut apart.

At this time, the cutting blade 91 penetrates only from the printing layer 14 of the laminated sheet 51, which becomes the bottom in the upside state, to the base film 11, but does not penetrate the prosthetic film 10. The upper and lower molds 93 and 92 may be reversed in position, and the upper mold bottom edge portion in the thermoforming processing step 600 and the cutting stage 700 may include a lower mold upper edge portion. The guide pin grooves G into which the upright guide pins 71 are inserted are provided to correspond 1: 1.

As described above, since the laminated sheet is fixed in the penetrating state by the guide pins 71, precise thermoforming processing and cutting operations may be performed, but a problem caused by the guide pins 71 may occur in the thermoforming processing step 600. Can be.

In other words, the thermoforming process is a high frequency operation. When using a conventional general metal guide pin, when a guide pin upright in one mold is inserted into the guide pin hole of the other mold, a high frequency current is applied between the mold and the guide pin. Sparking and discharging may occur, and as a result, processing failure, damage to a mold or a guide pin may be caused.

Therefore, in the method of the present invention, by using a guide pin made of a material having a suitable heat resistance and insulation, such as a synthetic resin, or a guide pin coated with a material having heat and insulation properties on the outer surface of the metal guide pin, Solved the problem.

In addition, the emblem of the present invention has a two-layer structure of a base film and a surface treatment film, based on only the film except for the surface treatment layer and the print layer, and the laminated sheet at the time of manufacture is a prosthetic film, a base film and a surface. The three-layer structure of the treatment film, or the emblem and the composite sheet may each be composed of more than one film bar, each of the complementary film, the base film and the surface treatment film may be a structure in which two or more films are laminated and combined.

For example, in order to improve the properties of the emblem or workability of the composite sheet, the base film and the complementary film may be laminated in one or more sheets, respectively, and the surface treatment layer 12 and the printing layer 14 are coated together. As shown in FIG. 12, the treatment film 13 is coated with the first surface treatment film 13 ′ on which one surface of the surface treatment layer 12 is coated and the second layer on which the printing layer 14 is coated on the upper surface. It can also consist of two sheets of surface treatment film 13 ".

At this time, if necessary, the first surface treatment film 13 ′ is used for reinforcing simple properties without the surface treatment layer 12, and the surface treatment layer 12 and the surface treatment layer 12 ″ are formed on the surface of the second surface treatment film 13 ″. The print layer 14 may be coated together.

Further, the surface treatment layer 12 and the print layer 14 may be separately formed on the bottom and top surfaces of the surface treatment films 13 and 13 ″, respectively, as shown in FIG. 13, the print layer 14. And the surface treatment layer 12 may be laminated on one surface of the surface treatment film 13, in particular, the surface treatment layer 12 on the upper surface, and the printing layer 14 on the upper surface of the surface treatment layer 12. The number of laminated films of each film and the coating position and structure of the surface treatment layer 12 and the print layer 14 can be variously changed.

In the method of the present invention, the printing operation is carried out on the surface of the laminated sheet, and the printing layer 14 coated on the surface treatment films 13 and 13 " becomes the uppermost layer of the emblem, and the printing layer 14 A separate protective film may be additionally laminated to the surface treatment films 13 and 13 ″ having the printed layer formed thereon for protection.

Alternatively, the surface treatment layer 12 and the print layer 14 may be coated together on the first surface treatment film 13 ′, and the second surface treatment film 13 ″ may be used as a protective film.

As described above, the emblem and its manufacturing method of the present invention, since a heat-resistant and rigid film such as a Piti film is used as a prosthetic film that serves as a support, precise printing layer formation and post-processing for the emblem pattern It is possible to express various colors freely by applying printing technique to the emblem, as well as various processing effects such as high gloss, matte, metallic and pearl, etching, gradation, fading, pattern, texture, hairline, brushing, etc. You can get

In addition, it has excellent physical properties and high surface strength for heat and press molding, and also improves durability against elastic deformation of the surface treatment layer implemented by techniques such as actual metal deposition, hologram embossing, printing, and transfer. Of course, there is an advantage that can be attached to the curved and fluid parts such as shoes, clothes, etc.

In addition, by drilling the through-hole for the guide pin of the mold, the precision during thermoforming or cutting by high frequency is further improved, and the defect rate is remarkably reduced, and the productivity is improved compared to the method using a jig or the like. have.

Claims (11)

In the emblem with the three-dimensional pattern, One or two or more thermoplastic base films 11 laminated and bonded; It is configured to include a thermoplastic surface treatment film 13 laminated on the upper surface of the base film 11, In this case, the surface treatment film 13, the surface treatment layer 12 and the print layer 14 is formed on the bottom and the upper surface, respectively, characterized in that the metal and hologram emblem capable of multi-color representation. In the emblem with the three-dimensional pattern, One or two or more thermoplastic base films 11 laminated and bonded; It is configured to include a thermoplastic surface treatment film 13 laminated on the upper surface of the base film 11, At this time, the surface treatment film 13, the surface treatment layer 12 and the printed layer 14 on the upper surface is a metal and hologram emblem capable of multi-color expression, characterized in that any one of the laminated coating formed sequentially. The emblem pattern according to claim 1 or 2, wherein the emblem is represented by the entire upper surface of the laminate in which the base film 11 and the surface treatment film 13 are laminated and bonded. It has a three-dimensional shape by thermoforming processing, A core glyph 41A to be actually displayed in the emblem; Metal and hologram emblems capable of multi-color expression, characterized in that consisting of a border pattern portion 41B which is the border of the emblem and the other margin pattern portion 41C. The method of claim 3, wherein the margin pattern 41C, Embossing pattern formed by the thermoforming process is a metal and hologram emblem capable of multi-color representation. The method of claim 1 or 2, wherein the surface treatment film 13, It consists of a first and second surface treatment film (13 ') (13 ") that is laminated and bonded sequentially to the base film (11), At this time, the surface treatment layer 12 and the print layer 14 is formed on the first and second surface treatment films 13 'and 13 ", respectively, Alternatively, both the surface treatment layer 12 and the print layer 14 are formed on the first surface treatment film 13 ′ and the second surface treatment film 13 ″ serving as a protective film is made of only a film. , Alternatively, the first surface treatment film 13 ′ is made of only a film, and the surface treatment layer 12 and the print layer 14 are both coated on the second surface treatment film 13 ″. Metal and hologram emblem with multicolor expression. The method of claim 1 or 2, wherein the surface treatment layer 12, Metal and hologram emblems capable of multi-color expression, characterized in that any one of a metal deposition layer, a hologram layer, a printing layer, a transfer layer. Laminating and bonding the base film on the upper surface of the prosthetic film each made of thermoplastic resin; Stacking and cutting a thermoplastic surface treatment film having a surface treatment layer on the upper surface of the base film to obtain a composite sheet (200); Primary drying the composite sheet (300); Printing an emblem pattern on a surface of the dried laminated sheet (400); Second drying the composite sheet on which the print layer is formed (500); Performing thermoforming on the second dried laminate sheet (600); Cutting only the emblem shape such that the prosthetic film is not cut in the thermoformed composite sheet 700; The method of manufacturing an emblem capable of multicolor, characterized in that it comprises a step (800) of separating the cut emblem from the sheet. The method of claim 7, wherein as the prosthetic film, A method of manufacturing an emblem with a multi-color expression, characterized in that a film having a higher heat resistance and rigidity than a base film and a surface treatment film is used. According to claim 7, Between the secondary drying step 500 and the thermoforming step 600, A method of manufacturing an emblem with a multi-color expression, characterized in that the step (500 ') of additionally punching through-holes for the guide pins of the thermoforming mold and the cutting mold on the secondary dried plywood sheet. The method of claim 9, wherein the perforating 500 ' Punching the sheet of the sheet of the composite sheet by using the automatic imaging device (500'-1); A method of manufacturing an emblem with a multi-color expression, characterized in that it comprises a step (500'-2) of punching the standard ball (H) by the emblem as a NC puncher on the basis of the perforated happo sheet reference point (P). The method of claim 9, wherein the guide pin, Made of a material having heat resistance and insulation, A method for manufacturing an emblem with a multi-color expression, characterized in that a material having heat resistance and insulation is coated on an outer surface of a metal guide pin.

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