KR20150007455A - light cover with three-dimensional embossed layer and method for forming three-dimensional embossed layer - Google Patents

Abstract

The present invention provides a light cover with a three-dimensionally embossed pattern layer, in which since an embossed pattern is simply formed without a separate mold, productivity is improved, and since the embossed pattern is formed in various shapes according to the individuality of a user, the satisfaction with respect to a product is improved. The present invention provides the light cover with the three-dimensionally embossed pattern layer, the light cover comprising: a three-dimensional panel to be coated formed of a transparent material so as to transmit light emitted from a light source; an embossed boundary layer formed along a three-dimensional boundary pattern defining an edge of an embossed pattern pre-set on the three-dimensional panel to be coated; and an embossed pattern layer formed in a convex shape by defining a resin for the embossed pattern spray-coated on the three-dimensional panel to be coated, inside the embossed boundary due to a surface tension difference from the embossed boundary layer.

Description

A light cover having a three-dimensional embossed pattern layer and a method of forming a three-dimensional embossed pattern layer,

The present invention relates to a light cover having a three-dimensional embossed pattern layer and a method of forming a three-dimensional embossed pattern layer. More particularly, the present invention relates to a method of forming a three-dimensional embossed pattern layer by simply forming a three- The present invention also relates to a method of forming a three-dimensional embossed pattern layer and a light cover in which a three-dimensional embossed pattern layer is formed.

In recent years, more and more consumers are seeking functional individuality in mass-produced automobiles and home appliances. As a result, the tuning of the exterior or interior of a car is becoming popular, and various home appliances are increasingly utilized as decorations on the interior side.

Accordingly, techniques for printing unique images on the surfaces of automobile interior materials or exterior materials of household appliances are continuously being developed. Here, the exterior material of the automobile interior material and the household appliance is a molded article having a curved surface rounded in various shapes, which is a three-dimensional object to which a pattern or the like is expressed.

On the other hand, in the vehicle light cover, embossed layers of various patterns are formed on the surface of a transparent or translucent synthetic resin in consideration of a kind of decoration and beauty. At this time, the emboss layer is formed of a plurality of protrusions protruding freely and refracts the light emitted from the light source arranged therein to form a colorful illumination at various angles.

In this case, in order to form an emboss layer having various patterns on the surface of a synthetic resin, a mold having an inverted shape of the emboss layer is manufactured on the inner side and a synthetic resin is injected using the mold to produce a finished product Respectively.

However, the conventional mold injection method has a problem in that it takes a lot of cost to manufacture a mold, and when a new design is developed, a new mold must be manufactured accordingly, which hinders rapid development.

Moreover, since it is virtually impossible to produce a product with a specificity to the consumer's taste due to the cost of producing a mold, the customer's satisfaction is lowered and a large work space is required for injection of the synthetic resin.

In addition, since it takes a long time to inject the synthetic resin into the mold and separate the finished product from the mold, the productivity is lowered, and since the completeness of the product depends on the pressure and temperature of the injection of the synthetic resin into the mold, There is a problem that an expensive production equipment is required.

Korean Patent Publication No. 10-2001-0043763

In order to solve the above problems, the present invention provides a three-dimensional emboss pattern in which the three-dimensional embossed pattern layer is formed simply without a separate mold to improve productivity and is formed into various shapes according to the user's individuality, Layered light cover and a method of forming a three-dimensional embossed pattern layer.

According to an aspect of the present invention, there is provided a stereoscopic panel comprising: a three-dimensional conductor panel formed of a transparent material to transmit light emitted to a light source; An embossed boundary layer formed along a three-dimensional boundary pattern dividing an edge of a predetermined emboss pattern in the three-dimensional embossed panel; And a embossed pattern layer formed on the embossed boundary layer and formed by embossing on the embossed boundary layer, the embossed pattern layer being formed in the embossed boundary layer so as to be convexly formed in the embossed boundary layer with a difference in surface tension from the embossed boundary layer. Is provided.

Here, it is preferable that the resin forming the embossed boundary layer is formed by adding a resin having a lower surface tension than the resin forming the embossed pattern layer.

At this time, it is preferable that the resin forming the embossed boundary layer is formed by adding liquid silicone which causes a difference in surface tension to the resin forming the embossed pattern layer.

In addition, the embossed pattern layer is preferably formed of a transparent acrylic resin.

The embossed pattern layer may be formed of a transparent material, and a dye for a synthetic resin may be contained in one of the three-dimensional conductor panel and the embossed pattern layer.

The embossed boundary layer and the embossed pattern layer may be formed of a transparent material, and the embossed boundary layer and the embossed pattern layer may each contain a coloring material for a synthetic resin having a different color.

The embossed boundary layer and the embossed pattern layer may be formed of a transparent acrylic resin, and a thin film layer may be formed on the upper surface of the embossed pattern layer by spray coating a thin film coating containing a dye for synthetic resin.

A first step of forming an ink groove on the printed sheet along the three-dimensional boundary pattern dividing the frame of the predetermined emboss pattern; A second step of filling the ink groove with the ink for embossed boundary and transferring the filled ink for embossed boundary to the printing pad; A third step of transferring the transferred embossed boundary ink to a three-dimensional conductor panel of a transparent material to form an embossed boundary layer; And a resin for forming an emboss pattern is formed on the three-dimensional conductor panel on which the embossed boundary layer is formed, wherein the resin for emboss pattern is divided into the embossed boundary layer by a difference in surface tension between the embossed pattern layer and the embossed boundary layer, A method for forming a three-dimensional embossed pattern layer comprising four steps is provided.

Preferably, the embossing boundary ink is formed by adding a resin having a lower surface tension than the resin for the emboss pattern.

Preferably, the embossed boundary ink is formed by adding liquid silicone to the same resin as the resin for the emboss pattern, which causes a difference in surface tension.

The resin for the emboss pattern is preferably formed of a transparent acryl-based resin.

It is preferable that the resin for emboss pattern is made of a transparent acrylic resin, and the dye for synthetic resin is contained in either one of the three-dimensional conductor panel and the resin for emboss pattern.

It is preferable that the ink for embossed boundary and the resin for embossed pattern are made of a transparent acryl-based resin, and the embossed boundary ink and the embossed pattern resin each contain a coloring material for a synthetic resin different in color.

The embossed boundary ink and the embossed pattern resin may be formed of a transparent acrylic resin. In the fourth step, a step of spray painting a coating material containing a coloring material for synthetic resin on the upper surface of the embossed pattern layer may be further included .

At this time, the ink for embossed boundary and the resin for embossed pattern are formed of transparent acryl-based resin, and in the fourth step, the step of spray painting a thin film paint added with nanoparticles on the upper surface of the embossed pattern layer is further included .

Through the above solution, the method of forming a three-dimensional embossed pattern layer and a light cover in which the three-dimensional embossed pattern layer of the present invention is formed provides the following effects.

First, since the embossed boundary ink is transferred to the three-dimensional conductor panel by using a printing pad which is elastically deformed, the embossed boundary layer can be clearly and variously formed on the curved surface of the rounded corrugated surface of the three-dimensional conductor panel In addition, the emboss pattern resin sprayed without a separate mold is pushed out from the embossed boundary layer due to a difference in surface tension, and forms a convex embossed pattern layer by aggregating, thereby reducing the production cost and improving the economical efficiency.

Secondly, since the light emitted from the light source passes through the convex embossed pattern layer and is refracted in various directions, and is irradiated with a color through a substantially transparent light cover, it is possible to provide a new and dazzling illumination that has not been existed, In addition, when the light cover is applied to a turn signal lamp of a vehicle, stability of the travel can be improved by concentrating the gaze of the town electrons.

Third, since the embossed pattern layer is changed into various forms only by changing the divided form of the embossed boundary layer, it is possible to simplify the production process and reduce the production cost, and to use the production equipment in a compatible manner, The product variety and economical efficiency can be improved.

Fourth, by merely adding different coloring pigments to the three-dimensional conductor panel, the embossed boundary layer and the embossed pattern layer, each color can be shiny and variously implemented, so that it can be used as a high-grade decorative panel, .

1 is a side view showing a pad printing apparatus applied to a method of forming a three-dimensional embossed pattern layer according to an embodiment of the present invention;
FIG. 2A and FIG. 2B are schematic views illustrating a working process of a pad printing apparatus applied to a method of forming a three-dimensional embossed pattern layer according to an embodiment of the present invention.
3 is a flowchart illustrating a method of forming a three-dimensional embossed pattern layer according to an embodiment of the present invention.
FIGS. 4A, 4B, 4C and 4D are views illustrating a method of forming a three-dimensional embossed pattern layer according to an embodiment of the present invention; FIGS.
5 is a plan view showing a state where an embossed boundary layer is formed in a method of forming a three-dimensional embossed pattern layer according to an embodiment of the present invention.
6 is a view illustrating an example of a light cover in which a three-dimensional embossed pattern layer is formed according to an embodiment of the present invention.
7 is a flowchart illustrating a method of forming a three-dimensional embossed pattern layer according to another embodiment of the present invention.
8 is a sectional view showing a light cover in which a three-dimensional embossed pattern layer is formed according to another embodiment of the present invention.

Hereinafter, a light cover in which a three-dimensional embossed pattern layer is formed and a method of forming a three-dimensional embossed pattern layer in a preferred embodiment of the present invention will be described in detail with reference to the accompanying drawings.

First, a pad printing apparatus and its operation principle applied to a three-dimensional embossed pattern layer forming method according to a preferred embodiment of the present invention will be briefly described.

FIG. 1 is a side view showing a pad printing apparatus applied to a method of forming a three-dimensional embossed pattern layer according to an embodiment of the present invention. FIGS. 2A and 2B are views showing a method of forming a three-dimensional embossed pattern layer according to an embodiment of the present invention Fig. 1 is a schematic view showing a working process of a pad printing apparatus applied to a pad printing apparatus.

As shown in Figs. 1 and 2B, the pad printing apparatus 31 according to the present invention fills in the ink pattern 33a with the engraved pattern of the printed pattern 33 engraved with the print pattern, Refers to a general pad printing apparatus in which the ink is transferred to the printing pad 35 and the printing pad 35 onto which the ink 33a is transferred is pressed against the surface of the three-dimensional conductor panel 45 to perform printing.

Here, the three-dimensional conductor panel 45 refers to a plastic molding having rounded curved surfaces in various forms such as an outer cover for household appliances and a light cover for a vehicle.

Referring to FIG. 1, the pad printing apparatus 31 may be of a cup type. In detail, the cup type pad printing apparatus 31 includes a main body 37, a printing pad 35, a printing separator 33, an ink supply device 39, and driving devices 41 and 43.

The printing pad 35 is positioned on the upper side of the conductor 45 fixed by the jig 47 and the ink 33a of the printing separator 33 is transferred to the upper side of the stereoscopic conductor panel 45 And an end portion of the printing pad 35 is rounded so that transferring is performed.

Accordingly, the printing pad 35 can be brought into close contact with various curved surfaces and rounded surfaces by pressure deformation, so that the print quality of the surface of the three-dimensional conductor panel 45 can be improved.

The printing separator 33 is mounted on a mounting plate 49 near the jig 47 so that the printing pad 35 is reciprocally moved together with the ink supply device 39 by the reciprocating drive unit 43 And is vertically moved by the up and down driving unit 41 to be inked. The ink supply device 39 is provided on the main body 37 and is in close contact with the upper surface of the print separator 33 on which the ink grooves are formed to reciprocate with the printing pad 35, (39a).

The driving devices 41 and 43 are installed in the main body 37 and are configured to reciprocate and vertically move the printing pad 35. The driving devices 41 and 43 are driven by the reciprocating driving part 43 and an up-and-down driving unit 41.

At this time, the reciprocating drive unit 43 and the up and down drive unit 41 are provided with a driving device such as a cylinder or a motor driving unit and a cam for driving the printing pad 35 to reciprocate forward and backward and up and down, A control device such as a circuit may be provided for controlling the driving device. A jig mounting portion 51 is provided on the lower side of the jig 47 so as to be movable up and down while fixing the jig 47.

2A and 2B, the ink groove of the printing separator 33 mounted on the pad printing apparatus 31 is filled with ink. At this time, the printing pad 35 of the pad printing apparatus 31 is moved downward, and the ink filled in the ink groove is transferred to the surface of the printing pad 35.

The printing pad 35 is moved to the upper side of the stereoscopic coated panel 45 and moved downward to the surface of the stereoscopic coated panel 45 to press the surface of the stereoscopic coated panel 45, Ink is transferred. A solid pattern may be formed on the surface of the three-dimensional conductor panel 45 through such a work process.

FIG. 3 is a flowchart illustrating a method of forming a three-dimensional embossed pattern layer according to an embodiment of the present invention. FIGS. 4A, 4B, 4C, and 4D illustrate a method of forming a three-dimensional embossed pattern layer according to an embodiment of the present invention. FIG. 5 is a plan view showing a state in which the embossed boundary layer is formed in the method of forming a three-dimensional embossed pattern layer according to an embodiment of the present invention. FIG.

3 to 5, the method of forming a three-dimensional embossed pattern layer 61 according to an exemplary embodiment of the present invention includes a step of forming a three-dimensional boundary pattern by dividing an edge of a predetermined emboss pattern, (S20) of filling the embossed boundary ink 51 with the ink groove and transferring the filled ink 51 to the printing pad 35 (step s20), forming the transferred embossed boundary ink 51 Transferring the boundary ink 51 to the stereoscopic conductor panel 55 made of a transparent material to form the embossed boundary layer 52 so that the embossed boundary layer 52 is formed.

The embossed pattern resin 60 is sprayed onto the embossed patterned panel 55 on which the embossed boundary layer 52 is formed and the resin 60 for embossed pattern is applied to the embossed boundary layer 52, And forming a convex emboss pattern layer 61 partitioned in the embossed boundary layer 52 to form a three-dimensional emboss pattern layer 61.

Here, the predetermined emboss pattern refers to various forms in which a plurality of protrusions protruding upwardly are disposed and embodied on the stereoscopic body panel 55, and may be variously set according to a user's taste or personality. The three-dimensional conductor pattern panel 55 is exposed to each of the sections partitioned by the three-dimensional boundary pattern, and the three-dimensional conductor pattern panel 55 is exposed to each of the portions A convex embossed pattern layer 61 is formed.

In detail, ink grooves are formed on the printed sheet along the three-dimensional boundary pattern dividing the border of the predetermined emboss pattern (s10).

Here, the printing plate may be formed by a photosensitive plate printing method. At this time, the photosensitive plate making process is a process in which a film on which an image is formed is closely adhered to a semi-cured resin plate on which a photosensitive agent layer for causing a photochemical reaction by light is formed, exposed to ultraviolet rays to be photosensitive, and then worked in the order of etching, washing and curing, This means the method is provided.

When the semi-cured resin plate is exposed to ultraviolet rays to be exposed to light, portions of the image that are exposed to ultraviolet rays and portions that are not exposed are generated. At this time, since the exposed portion is cured by the photochemical reaction of the photosensitive layer and the unexposed portion is not cured, an etching process may be performed to remove the uncured portion to form an ink groove.

Here, in the etching step, the ultraviolet treated semi-cured resin plate may be immersed in a solution of 80%: 20% of alcohol and water, respectively, to remove uncured portions of the semi-cured resin plate.

The image may form a shadow that does not transmit ultraviolet rays along a line portion of the three-dimensional boundary pattern to form an ink groove having a line shape of the three-dimensional boundary pattern on the semi-cured resin plate.

4A to 4B, the embossed boundary ink 51 is filled in the ink groove formed on the printing separator, and the filled ink 51 for embossed boundary is transferred to the printing pad 35 s20). Here, the printing pad 35 may be formed of an elastic material such as silicon.

Since the printing pad 35 formed of an elastic body is moved to the three-dimensional conductor panel 55 and is contracted and relaxed as it is pressed and changed in accordance with the surface profile of the three-dimensional conductor panel 55, The ink 51 can be closely adhered to the three-dimensional conductor panel 55 having various curvatures.

Accordingly, distortion or alteration due to uneven contact due to rounded curved surfaces is prevented, and various types of three-dimensional boundary patterns are accurately printed on the three-dimensional conductor panel 55 having rounded corners, Can be improved, and the production process can be simplified by simple printing and the productivity can be improved.

Referring to FIG. 4C, the transferred embossed boundary ink 51 is transferred to a three-dimensional conductor panel 55 made of a transparent material to form an embossed boundary layer 52 (s30). At this time, the three-dimensional conductor panel 55 is provided with a degreasing operation for removing grease so that the embossed boundary ink 51 can be firmly adhered, an etching operation for smoothing the surface, a static elimination operation for preventing static electricity from being generated on the surface Is preferably performed.

Preferably, the embossing boundary ink 51 is formed by adding a resin having a lower surface tension than the resin 60 for the emboss pattern. Here, the resin having a low surface tension may be silicon, Teflon, or the like.

Since the embossing boundary ink 51 is formed by adding a resin having a low surface tension, the embossing boundary ink 51 has a low cohesive strength, and when filled in the ink grooves, the embossing boundary ink 51 is scattered widely and thinly .

The surface of the embossed boundary layer 52 has a low surface tension when the embossed boundary ink layer 51 is formed as the embossed boundary ink 51 is transferred to the stereoscopic coated panel 55 and dried . At this time, when the resin 60 for the emboss pattern is sprayed, the resin 60 for the emboss pattern having a higher surface tension than the surface of the embossed boundary layer 52 is pushed from the surface of the embossed boundary layer 52, (60) are coagulated.

Referring to FIG. 5, the embossed boundary layer 52 formed on the three-dimensional conductor panel 55 defines a portion a where each pattern is to be formed. The embossed pattern resin 60 is pushed by a portion of the embossed boundary layer 52 due to a difference in surface tension and then pushed into a portion a defined by the embossed boundary layer 52. The embossed pattern resin 60 is convexly and agglomerated to form the embossed pattern layer 61 in the partitioned portion (a).

Here, the embossed pattern resin 60 is pushed by the embossed boundary layer 52 in accordance with the area of the portion (a) defined by the embossed boundary layer 52 and on which the predetermined emboss pattern is formed, It is preferable that the difference in surface tension is set experimentally so as to be convexly cohered.

At this time, it is preferable that the embossing boundary ink 51 is formed by adding liquid silicone which generates a difference in surface tension to the same resin as the resin 60 for the emboss pattern. Here, the resin 60 for the emboss pattern may be formed of an acrylic resin.

The acrylic resin has a surface tension higher than the silicon surface tension of 20-22 dyne / cm. Accordingly, the resin 60 for the emboss pattern is pushed out of the embossed boundary layer 52 formed of the embossed boundary ink 51.

4D, a resin 60 for an emboss pattern is sprayed onto the three-dimensional conductor panel 55 on which the embossed boundary layer 52 is formed, and the embossed pattern resin 60 is applied to the embossed boundary layer The embossed pattern layer 61 is divided into the embossed boundary layer 52 to form a convex embossed pattern layer 61.

Here, the resin 60 for the emboss pattern may be sprayed onto the three-dimensional conductor panel 55 through a spray process or the like. At this time, the embossed boundary layer 52 is formed on the three-dimensional conductor panel 55, and the embossed boundary layer 52 defines a portion where the embossed pattern layer 61 is to be formed.

When the resin 60 for embossing is sprayed onto the surface of the molded body 55, the resin 60 for the embossed pattern is applied to the surface of the exposed molded body 55, The embossed pattern resin 60 sprayed onto the embossed boundary layer 52 is pushed up by the embossed boundary layer 52 due to a difference in surface tension and is accumulated on the exposed surface of the stereoscopic coated panel 55, 60).

Thus, the agglomerated resin for emboss pattern 60 forms convex protrusions. Since the protrusion and coagulation phenomenon occur in the entire area partitioned by the embossed boundary layer 52, a plurality of protrusions are formed in a convex shape along the shape partitioned by the embossed boundary layer 52, so that the embossed pattern layer 61 are formed.

Since the embossed boundary ink 51 is transferred to the three-dimensional conductor panel 55 by using the printing pad 35 which is elastically deformed, the embossed boundary layer 52 can be easily The embossed pattern resin 60 to be sprayed is pushed into the portion partitioned by the embossed boundary layer 52 due to the difference in surface tension and is agglomerated to form the convexly embossed pattern layer 61 So that the convex surface of various patterns can be formed without a separate mold, and the economical efficiency of the product can be improved by reducing the production cost.

Meanwhile, the resin 60 for the emboss pattern may be formed of a transparent acryl-based resin. At this time, the embossed pattern layer 61 is formed in a transparent manner to form an embossed texture on the surface of the stereoscopic conductor panel 55 formed of a transparent material.

Accordingly, since the light radiated to the outside from the light source provided inside the three-dimensional conductor panel 55 passes through the embossed pattern layer 61 and is refracted in various directions, it is possible to provide new, It can provide a luxurious appearance.

Any one of the three-dimensional conductor panel 55 and the resin for embossed pattern 60 may contain a dye for synthetic resin. At this time, the coloring material for the synthetic resin may impart various colors to the stereophotosensitive panel 55 and the resin for emboss pattern 60.

The emboss pattern resin 60 may be provided with a color and the resin 60 for the emboss pattern may be provided in a transparent manner so that the emboss pattern resin 60 is colored, 55 may be provided in a transparent manner.

At this time, the light source that has passed through the three-dimensional conductor panel 55 and the embossed pattern layer 61 has a color depending on a color given to one side, but is refracted in various directions to form more luxurious and colorful illumination.

The embossing boundary ink 51 and the embossing pattern resin 60 are made of a transparent acrylic resin. The embossing boundary ink 51 and the embossing pattern resin 60 may have different colors Of synthetic resin pigments may be contained.

For example, the embossed boundary layer 52 may be formed in a red color on the surface of the three-dimensional conductor panel 55, and a transparent embossed pattern layer 61 may be formed. Accordingly, a red boundary line is formed along the red embossed boundary layer 52 so that the light source having passed through the three-dimensional conductor panel 55 can form an improved illumination.

The embossed boundary layer 52 is not only easily realized in various forms but also imparts a different color to the embossed boundary layer 52 and the embossed pattern layer 61 so that characters and symbols It is possible to provide the illumination in which the image is formed, and the satisfaction of the product can be improved.

Furthermore, since the steps of imparting different color tones to the embossed boundary layer 52 and the embossed pattern layer 61 are simplified, the cost of providing illuminations in which letters or symbolic images are formed is remarkably reduced according to the user's taste or personality. So that the economical efficiency of the product can be improved.

Further, by merely adding different coloring pigments to the three-dimensional conductor panel 55, the embossed boundary layer 52 and the embossed pattern layer 61, it is possible to realize various colors in a brilliant and colorful manner, So that the usability of the product can be improved.

6 is a view illustrating an example of a light cover in which a three-dimensional embossed pattern layer is formed according to an embodiment of the present invention.

6, the light cover 100 in which the three-dimensional embossed pattern layer 61 is formed includes a three-dimensional conductor panel 55, an embossed boundary layer 52, and an embossed pattern layer 61.

Here, the three-dimensional conductor panel 55 is a plastic molding having rounded curved surfaces in various shapes, and is formed of a transparent material to transmit light emitted to a light source provided inside. At this time, a dye for synthetic resin is added to the three-dimensional conductor panel 55 to have various colors.

The embossed boundary layer 52 is formed along a three-dimensional boundary pattern that defines an edge of a predetermined emboss pattern on the inner surface of the three-dimensional conductor panel 55. Here, the predetermined emboss pattern refers to various forms in which a plurality of protrusions protruding upward are disposed on the inner side of the stereoscopic coated panel 55, and may be varied depending on the purpose of use of the light cover or the taste or personality of the user . ≪ / RTI >

The three-dimensional boundary pattern is a line for dividing the rim of each projection forming the predetermined emboss pattern. The surface of the three-dimensional body panel 55 is exposed to each part partitioned by the three-dimensional boundary pattern, A convex embossed pattern layer 61 is formed at each portion.

The embossed pattern layer 61 is formed on the embossed boundary layer 52 by forming the embossed pattern resin on the embossed boundary layer 52 with the surface tension difference between the embossed pattern layer 61 and the embossed boundary layer 52, (52).

Here, the resin forming the embossed boundary layer 52 is preferably formed by adding a resin having a surface tension lower than that of the resin forming the embossed pattern layer 61. Accordingly, the resin for the emboss pattern projected on the upper surface of the embossed boundary layer 52 is pushed from the surface of the embossed boundary layer 52, and the embossed pattern resin is agglomerated to form convex protrusions.

The resin forming the embossed boundary layer 52 is preferably formed by adding liquid silicone to the resin forming the embossed pattern layer 61 to cause a difference in surface tension. Here, the resin for the emboss pattern may be formed of an acrylic resin.

The acrylic resin has a surface tension higher than the silicon surface tension of 20-22 dyne / cm. Accordingly, the embossed pattern resin sprayed onto the three-dimensional conductor panel 55 is transferred from the embossed boundary layer 52 to the embossed pattern layer 61, which is formed by the mirror or the embossed boundary layer 52, Respectively.

As described above, the embossed pattern layer 61, which is densely raised and expresses various patterns, can be produced through a simple printing process without a separate metal mold, and the economical efficiency of the product can be remarkably improved. In addition, since various shapes of patterns can be expressed without forming a mold, it is possible to supply a unique product at a low price only for a person who meets the personality and taste of the user, and the satisfaction of the product can be remarkably improved.

Meanwhile, the embossed pattern layer 61 may be formed of a transparent acryl-based resin. The inner surface of the three-dimensional conductor panel 55 formed of a transparent material has a convex texture. Accordingly, light transmitted to the outside from the light source provided inside the three-dimensional conductor panel 55 can be refracted in various directions in the embossed pattern layer 61 to form a colorful illumination.

In addition, a dye for a synthetic resin may be contained in either one of the three-dimensional conductor panel 55 and the embossed pattern layer 61. At this time, the coloring material for the synthetic resin may impart various colors to the stereoscopic conductor panel 55 and the embossed pattern layer 61.

Accordingly, the light source provided inside the three-dimensional coated conductor panel 55 is transmitted through the three-dimensional conductor panel 55 and the embossed pattern layer 61, and is colored in various directions To provide luxurious and colorful illumination. Further, when the light cover is applied to a turn signal lamp of a vehicle, the sight stability of the town electrons can be concentrated and driving stability can be improved.

Meanwhile, the embossed boundary layer 52 and the embossed pattern layer 61 are formed of a transparent acryl-based resin, and may contain pigments for synthetic resins of different colors.

For example, the embossed boundary layer 52 may be formed in red on the three-dimensional conductor panel 55, and a transparent embossed pattern layer 61 may be formed. Accordingly, a red boundary line is formed along the red embossed boundary layer 52 so that the light source having passed through the three-dimensional conductor panel 55 can provide illumination with improved perception.

In this way, the embossed boundary layer 52 is realized in various forms through a simple printing process, and the process of imparting different colors to the embossed boundary layer 52 and the embossed pattern layer 61 is simplified, And a light cover having a character or symbolic image formed according to the personality can be provided at a low cost, thereby improving the satisfaction of the product.

Further, since the emboss pattern layer 61 is changed into various forms only by changing the divided shape of the embossed boundary layer 52, it is possible to simplify the production process and reduce the production cost, Newly designed patterns can easily be applied to production, resulting in improved product diversity and economy.

FIG. 7 is a flowchart illustrating a method of forming a three-dimensional embossed pattern layer according to another embodiment of the present invention, and FIG. 8 is a cross-sectional view illustrating a light cover in which a three-dimensional embossed pattern layer is formed according to another embodiment of the present invention.

 In the present embodiment, except for the step of spray coating a thin film paint containing a dye for synthetic resin on the upper surface of the embossed pattern layer, the basic structure is the same as that of the above-mentioned embodiment, so that the description of the same parts will be omitted.

As shown in FIGS. 7 to 8, the method for forming a three-dimensional embossed pattern layer may include forming an ink groove in a print separator along a three-dimensional boundary pattern for dividing an edge of a predetermined emboss pattern (s110) Filling the grooves with the ink for embossed boundary, transferring the filled embossed boundary ink to the printing pad (s120), transferring the transferred embossed boundary ink to the stereoscopic coated panel 255 having a transparent property A resin for the emboss pattern is sprayed onto the embossed boundary layer 252 on which the embossed boundary layer 252 is formed to form the embossed boundary layer 252, And forming a convex emboss pattern layer 261 partitioned in the embossed boundary layer 252 by a difference in surface tension between the embossed boundary layer 252 and the embossed boundary layer 252.

At this time, the embossed boundary ink and the embossing pattern resin 60 are formed of a transparent acryl-based resin, and spraying a paint containing a coloring material for synthetic resin on the upper surface of the embossed pattern layer 261 (s150 ) Is further included.

The embossed boundary layer 252 and the embossed pattern layer 261 are formed of a transparent acryl-based resin, and the embossed pattern layer 261 is formed on the upper surface of the embossed pattern layer 261 And a thin film layer 270 formed by spray painting a paint containing a dye for a synthetic resin.

The coating material may be formed by forming the thin film layer 270 on the inner surface of the three-dimensional coated conductor panel 255 so that the light emitted from the light source provided inside the three- It is changed according to the coloring pigment.

Accordingly, a desired color can be imparted to the three-dimensional conductor panel 255 and the embossed pattern layer 261 through the thin layer 270 without adding any additional color, Can be improved.

The thin film layer 270 not only improves the adhesion of the embossed boundary layer 252 and the emboss pattern layer 261 to the stereoscopic coated panel 255 but also improves the adhesion of the emboss pattern layer 261 A convex protrusion feeling can be realized more prominently.

Accordingly, the angle difference between the lights passing through the emboss pattern layer 261 and refracted in various directions is further enhanced by the light source provided inside the three-dimensional conductor panel 255, .

The embossed boundary ink and the resin for the embossed pattern are formed of a transparent acrylic resin, and the thin film paint to which the nanoparticles are added may be sprayed on the upper surface of the embossed pattern layer 261. The nanoparticles are preferably formed of particles having metallic luster. Accordingly, a metallic texture may be formed on the thin film layer 270.

At this time, since the embossed boundary layer 252 contains liquid silicon and pushes the thin film with low surface tension, the thin film paint sprayed on the upper surface of the emboss pattern layer 261 is pushed and moved, and the embossed boundary layer 252 ) Can be kept in a transparent state.

That is, the light generated from the light source provided inside the three-dimensional conductor panel 255 is transmitted to the embossed boundary layer 252 and diverged to the outside, and is incident from the outside to the inside of the three-dimensional conductor panel 255 Light is reflected on the thin film layer 270 formed on the embossed pattern layer 261 to provide a metallic luster. As a result, the light leaking through the opaque metallic luster creates a mysterious atmosphere, thereby providing a further enhanced level of illumination.

As described above, the present invention is not limited to the above-described embodiments, and variations and modifications may be made by those skilled in the art without departing from the scope of the present invention. And such modifications are within the scope of the present invention.

100: Light cover 31: Pad printing device
33: printing separator 35: printing pad
37: main body 39: ink supply device
41: Up and down driving part 43:
45, 55: Stereo conductor panel 47: Jig
49: mounting plate 51: jig mounting portion
51: embossed boundary ink 60: resin for emboss pattern
52, 252: embossed boundary layer 61, 261: embossed pattern layer

Claims (15)

A stereoscopic conductor panel formed of a transparent material to transmit light emitted to a light source;
An embossed boundary layer formed along a three-dimensional boundary pattern dividing an edge of a predetermined emboss pattern in the three-dimensional embossed panel; And
A three-dimensional embossed pattern layer formed on the three-dimensional conductor panel on which the embossed boundary layer is formed, the embossed pattern layer being formed by convexly forming the resin for the emboss pattern partitioned in the embossed boundary layer by a surface tension difference from the embossed boundary layer, Formed light cover. The method according to claim 1,
Wherein the resin forming the embossed boundary layer is formed by adding a resin having a surface tension lower than that of the resin forming the embossed pattern layer. The method according to claim 1,
Wherein the resin forming the embossed boundary layer is formed by adding liquid silicone to the resin forming the embossed pattern layer to cause a difference in surface tension. The method according to claim 1,
Wherein the embossed pattern layer is formed of a transparent acryl-based resin. The method according to claim 1,
The embossed pattern layer is formed of a transparent material,
Wherein the three-dimensional embedment panel and the embossed pattern layer each contain a dye for a synthetic resin. The method according to claim 1,
The embossed boundary layer and the embossed pattern layer are formed of a transparent material,
Wherein the embossed boundary layer and the embossed pattern layer each contain a coloring material for a synthetic resin different in color. The method according to claim 1,
Wherein the embossed boundary layer and the embossed pattern layer are formed of a transparent acrylic resin,
Wherein the embossed pattern layer further comprises a thin film layer formed by spraying a thin film paint containing a dye for synthetic resin on the upper surface of the embossed pattern layer. A first step of forming an ink groove on a printed sheet along a three-dimensional boundary pattern dividing a frame of a predetermined emboss pattern;
A second step of filling the ink groove with the ink for embossed boundary and transferring the filled ink for embossed boundary to the printing pad;
A third step of transferring the transferred embossed boundary ink to a three-dimensional conductor panel of a transparent material to form an embossed boundary layer; And
The resin for emboss pattern is sprayed onto the three-dimensional conductor panel on which the embossed boundary layer is formed, and the resin for the emboss pattern is divided into the embossed boundary layer due to the difference in surface tension between the embossed pattern layer and the embossed boundary layer to form a convex embossed pattern layer. ≪ / RTI > 9. The method of claim 8,
Wherein the embossed boundary ink is formed by adding a resin having a surface tension lower than that of the resin for the emboss pattern. 9. The method of claim 8,
Wherein the embossed boundary ink is formed by adding liquid silicone to the same resin as the resin for the emboss pattern to generate a difference in surface tension. 9. The method of claim 8,
Wherein the resin for the emboss pattern is formed of a transparent acrylic resin. 9. The method of claim 8,
The resin for the emboss pattern is formed of a transparent acrylic resin,
Wherein the dye for a synthetic resin is contained in either one of the three-dimensional conductor panel and the resin for the emboss pattern. 9. The method of claim 8,
The embossing boundary ink and the embossing pattern resin are formed of a transparent acrylic resin,
Wherein the embossing boundary ink and the embossing pattern resin each contain a dye for a synthetic resin of a different color. 9. The method of claim 8,
The embossing boundary ink and the embossing pattern resin are formed of a transparent acrylic resin,
Wherein the fourth step further comprises spraying a paint containing a pigment for a synthetic resin on the upper surface of the emboss pattern layer. 9. The method of claim 8,
The embossing boundary ink and the embossing pattern resin are formed of a transparent acrylic resin,
The method of claim 1, further comprising spraying a thin film paint having nanoparticles on the upper surface of the embossed pattern layer.

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