KR20130060016A - Surface armored sheet - Google Patents

Abstract

PURPOSE: A surface exterior material is provided to apply a three-dimensional lens sheet having a certain image to the exterior of a domestic appliance, thereby making the exterior luxurious with a stable aesthetic sense and three-dimensional effect. CONSTITUTION: A surface exterior material includes a diffused reflection embo-layer(19), a first lens layer(22) beneath the embo-layer, a refraction bonding layer(23) beneath the first lens layer, a second lens layer bonded to the first lens layer by the refraction bonding layer, a focal distance layer(25) beneath the second lens layer, and a finishing bonding layer(31) beneath the focal distance layer. [Reference numerals] (AA) Diffused reflection pattern

Description

 Surface armored sheet

The present invention relates to a surface packaging material, and more particularly to the three-dimensional appearance in addition to the appearance of home appliances, such as a refrigerator. More specifically, the present invention relates to a surface packaging material formed of a specific image through a three-dimensional lens formed on the surface packaging material and having a visually stable aesthetic feeling.

Among home appliances that are mainly used in home appliances, refrigerators, kimchi refrigerators, and upright air conditioners have become important not only for their original functions but also for the interior interior that is visible to the naked eye. According to this trend, various efforts have been made, such as introducing colors and patterns to make the appearance of home appliances more luxurious.

In addition to these efforts, the use of steel sheets to reinforce the exterior strength, or the use of stainless steel plates, glass members, etc. to change the appearance of the home appliance design. However, all of these efforts have been limited in that they are simply a change of design in terms of the appearance of home appliances.

In recent years, since all electronic products are functional and visually appealing design is an important determinant factor for purchase desire, home appliances are also becoming larger and larger, and the design with important interior elements is important. As a result, the trend is advanced.

In the related art, Korean Patent Application No. 10-2008-0015780 relates to the appearance of a refrigerator and a home appliance in which a jewelry member is provided on an exterior member of a refrigerator, and a light emitting means for irradiating light to the jewelry member is provided.

In the case of patent application 10-2008-0007114, a transparent window is provided at the rear of the exterior member which forms the exterior of the refrigerator, and a light emitting mechanism is provided at the outside of the transparent window so that the light of the light emitting mechanism passes through the transparent window to the outside through the pattern of the exterior member. It relates to the appearance of the refrigerator and home appliances to be emitted to.

In addition, patent applications 10-2008-0081396, 10-2001-0055219, 10-2005-7006342, 10-2003-0025558 and other prior application patents have been proposed for the surface improvement of the refrigerator.

However, these patents are all based on a general image, and the visual aesthetic, that is, the three-dimensional image implementation is difficult to expect and had a problem inevitably have design limitations due to high-end.

In addition, in the case of refrigerators among home appliances, many foods and the like are stored and opened and closed many times, so that the exterior becomes easily dirty, and thus, the need for frequent cleaning of the surface occurs.

In addition, when a general three-dimensional sheet is used for the appearance of home appliances, convex portions of the lens made of plastic resin are exposed on the surface, and thus, there has been a problem in that it is also vulnerable to scratches.

The technical problem to be solved by the present invention is to provide a surface exterior material that improves the value of the product while looking at the appearance of home appliances. Specifically, a three-dimensional lens sheet engraved with a specific image is used for the exterior of home appliances to provide a surface aesthetic material that brings out a sense of luxury by providing a stable aesthetic and three-dimensional appearance.

The embodiment according to the present invention for achieving the technical problem is a diffuse reflection embossing layer 19, the first lens layer 22 formed below the diffuse reflection embossing layer, the refractive adhesive layer 23 of the lower portion of the first lens layer 22 A second lens layer 24 adhered to the first lens layer 22 by the refractive adhesive layer 23, a focal length layer 25 formed below the second lens layer, and the focal length layer 25. It characterized in that it comprises a finish adhesive layer 31 formed on the bottom.

Another embodiment of the present invention for achieving the technical problem is the first lens layer 22 formed below the tempered glass layer 20, the tempered glass layer 20, the lower portion of the first lens layer 22 Refractive adhesive layer 23, the second lens layer 24 to be bonded to the first lens layer 22 by the refractive adhesive layer 23, the focal length layer 25 formed below the second lens layer, the focus It characterized in that it comprises a finish adhesive layer 31 formed on the distance layer (25).

The surface coating material according to the present invention obtains the advantages of a natural lenticular image beyond the limitation of left and right stereoscopic implementation by a pearly print layer and a stable repeating stereoscopic pattern and 45 degree interlacing through a lenticular lens sheet for a microlens combined use. It can be effective.

In addition, by heating and evaporating a metal or a compound in a vacuum state by vacuum deposition on the back side of the three-dimensional layer, and by treating the lower portion of the three-dimensional layer with a color of the desired transparency through the vacuum deposition to coat the vapor with a thin film on the surface of the object It is possible to express more brightly than the plated and to express more luxuriously, and it is possible to deposit various materials and colors as well as to reduce the burden of pollution.

In addition, as the three-dimensional lens is visually concealed, there is an advantage that can realize a three-dimensional effect in the state of a flat sheet, by using tempered glass on the surface of the three-dimensional lens sheet to improve the hardness of the surface and easy management, As it becomes narrower, the three-dimensional effect is increased and the use of the refractive index adjusting adhesive layer not only makes it easy to adjust the thickness of the lens, that is, the focal length, but also prevents damage to the three-dimensional lens layer due to external impact. .

1 is an exploded cross-sectional view of a surface packaging material according to a first embodiment of the present invention.
Figure 2 is based on the first embodiment of the present invention, shows one of the examples modified from this.
3 is an exploded cross-sectional view of the surface packaging material according to the second embodiment of the present invention.
Figure 4 is based on the second embodiment of the present invention, it shows one of the examples modified from this.

Hereinafter, embodiments of the present invention will be described in detail with reference to the drawings. Before describing the embodiments of the present invention, it should be noted that the same reference numerals refer to the same configuration.

1 is an exploded cross-sectional view of a surface packaging material according to a first embodiment of the present invention. As shown in FIG. 1, the surface covering material of the present invention includes the first lens layer 22 by the diffuse reflection emboss layer 19, the first lens layer 22, the refractive adhesive layer 23, and the refractive adhesive layer 23. The second lens layer 24 to be bonded, the focal length layer 25 formed under the second lens layer, and the finish adhesive layer 31 formed under the focal length layer 25 are sequentially stacked.

Many other modifications are possible based on the first embodiment of the invention. For example, a pearl printing layer or a deposition layer is further formed between the bottom of the focal length layer 25 and the top of the finishing adhesive layer 31, or the color adjustment for adjusting the coloring of the pearl printing layer or the deposition layer. Embodiments in which the printed layer 27 is further formed are also possible.

It is also possible to form the shielding printed layer 28 between the bottom of the focal length layer 25 and the top of the finish adhesive layer 31.

It is also possible to form the three-dimensional image layer 29 between the bottom of the focal length layer 25 and the top of the finish adhesive layer 31.

It is also possible to form the base ink layer 30 between the bottom of the focal length layer 25 and the top of the finish adhesive layer 31.

The detachable release film 16 may be attached to the lower portion of the finish adhesive layer 31, and the diffuse reflection emboss layer 19 may be further formed on the upper portion of the first lens layer 22 to induce diffuse reflection. In addition, a UV blocking adhesive layer 21 may be further added to the upper portion of the first lens layer 22, and the UV blocking adhesive layer 21 may be attached to the first lens layer 22 for adhesion. It is more preferable to include a component.

If, on the basis of the first embodiment, all the embodiments modified from this as described above are stacked and formed, as shown in FIG. 2. Description of each layer will be described later.

Figure 3 shows an exploded cross-sectional view of the surface packaging material according to a second embodiment of the present invention. As shown in FIG. 3, the surface covering material of the present invention may be formed of the first lens layer 22 by the tempered glass layer 20, the first lens layer 22, the refractive adhesive layer 23, and the refractive adhesive layer 23. The second lens layer 24 to be bonded, the focal length layer 25 formed under the second lens layer, and the finish adhesive layer 31 formed under the focal length layer 25 are sequentially stacked.

Based on the second embodiment of the present invention, other embodiments modified therefrom are possible. For example, a pearl printing layer or a deposition layer is further formed between the bottom of the focal length layer 25 and the top of the finishing adhesive layer 31, or the color adjustment for adjusting the coloring of the pearl printing layer or the deposition layer. Embodiments in which the printed layer 27 is further formed are also possible.

It is also possible to form the shielding printed layer 28 between the bottom of the focal length layer 25 and the top of the finish adhesive layer 31.

It is also possible to form the three-dimensional image layer 29 between the bottom of the focal length layer 25 and the top of the finish adhesive layer 31.

It is also possible to form the base ink layer 30 between the bottom of the focal length layer 25 and the top of the finish adhesive layer 31.

A detachable release film 16 may be attached to the lower portion of the finish adhesive layer 31, and a diffuse reflection emboss layer 19 may be further formed on the finish adhesive layer 31 to induce diffuse reflection. In addition, a UV blocking adhesive layer 21 may be further added to the upper portion of the first lens layer 22, and the UV blocking adhesive layer 21 may be attached to the first lens layer 22 for adhesion. It is more preferable to include a component.

As described above, if all of the embodiments modified from the second embodiment are stacked and formed as shown in FIG. 4. Description of each layer will be described later.

In all the basic and modified embodiments of the present invention, the first lens layer 22 may be a lenticular lens for a micro lens.

Such surface sheathing material is preferably attached to the outer wall of a home appliance, such as a refrigerator, in particular, such as a door (door) because it allows consumers to see the surface sheathing of the present invention to feel a three-dimensional feeling.

The refractive adhesive layer 23 formed under the first lens layer 22 integrates the first lens layer 22 and the second lens layer 24 and freely adjusts the focal length of the lens by adjusting the angle of view according to the change of the refractive index. To adjust. Naturally, the refractive adhesive layer 23 may include an adhesive component for adhesion of both lenses.

The focal length layer 25 formed below the second lens layer 24 adjusts the focal length by the refractive adjustment adhesive layer 23 of the second lens layer 24. Since the focal length is well known that it is simultaneously affected by many factors such as the refractive index of the lens, the thickness and the material of the focal length layer 25, a detailed description thereof will be omitted.

The pearl printing layer formed under the focal length layer 25 forms a pearl pattern in part by spraying or printing paint or the like.

The color adjustment printing layer 27 formed below the pearl printing layer is for adjusting the glitter of the pearl printing layer.

The shielding printing layer 28 formed below the color adjustment printing layer 27 is for maintaining the color adjustment according to the transparency of the color adjustment printing layer 27.

The three-dimensional image layer 29 formed below the shielding printed layer 28 three-dimensionally expresses a pattern or image calculated in advance in consideration of the first lens layer or the second lens layer.

The base ink layer 30 formed below the stereoscopic image layer 29 serves to correct color of the stereoscopic image and to protect the stereoscopic image layer 29.

The diffuse reflection embossing layer 19 is a layer using the principle that the reflected light is reflected in all directions when the light is reflected in the rugged state of the object. This expresses the phenomenon of the new pattern that shines according to the viewing angle. In FIG. 1, the diffuse reflection emboss layer 19 is formed above the first lens layer 22, but in FIG. 4, the diffuse reflection emboss layer 19 is formed below the base ink layer 30.

Finally, the detachable release layer 16 is attached to the lower portion of the finish adhesive layer 31 for easy use when attaching the surface exterior material of the present invention to the exterior of a home appliance such as a door of a refrigerator. .

If a conventional three-dimensional lens sheet made of plastic is used for the appearance of home appliances, the surface hardness is inevitably limited, and accordingly, the application of the three-dimensional lens sheet may be limited. However, the first lens layer may be applied as in the second embodiment of the present invention. 22) by integrating the thin film of the tempered glass layer 20 and the UV-blocking adhesive layer 21 to improve the surface hardness can be applied as a surface exterior material of the appearance of more various home appliances.

In the case of a conventional micro lens, the stereoscopic implementation of a general image is limited, but a simple repetitive pattern can be visually and stereoscopically implemented in a stereoscopic sense. In the case of a lenticular lens, it is easy to implement a stereoscopic image for a general image while restricting the stereoscopic direction. The difference is that visual dizziness can be caused.

The surface exterior material of the exterior of the home appliance according to an embodiment of the present invention uses a tempered glass layer 20 having a strong hardness on the surface of the lens sheet, and uses an ultraviolet blocking adhesive layer 21 which is an adhesive resin capable of blocking ultraviolet rays. By integrating through the surface, the advantage of glass is smoother, more glossy, and effective in removing foreign matters while preventing the discoloration of the internal three-dimensional representation ink layer.

In addition, the surface graphics of most home appliances, including refrigerators, are complicated and beautiful, and relatively simple graphics are applied due to the characteristics of everyday products.

Therefore, by adhering the pearl printing layer to the back surface of the second lens layer 24 and partially performing pearl printing, the fine pearl particles are enlarged and produced by the micro-lens lenticular lens 22 with different reflection angles. You can feel more sparkling like jewelry.

In this case, when light is reflected on the lower surface of the base ink layer 30 or on the surface of the microlens combined lenticular lens in an uneven state of the object, the reflected light forms a reflective pattern layer which is reflected in all directions. By reflecting and scattering light in many directions, the pearl print layer has a more jewel-like feel.

Therefore, in order to take advantage of both, through the lenticular lens 22 sheet combined with a microlens, the natural lenticular image of the pearl printing layer, stable repeating stereoscopic pattern, and the stereoscopic left and right stereoscopic implementation by 45 degree interlacing described above are obtained. Benefits can be obtained.

Instead of the pearl printing layer, a vapor deposition layer may be formed. This creates a desired color by heating and evaporating a metal or compound in a vacuum and coating the vapor with a thin film on the surface of the object to create a desired color, which makes it possible to express brightness according to more transparency than plating. Classy expression is possible.

As the deposition material, aluminum (Al), gold (Au), silver (Ag), copper (Cu), chromium (Cr), or tin may be used, and the transparency of the deposition layer 100 may be varied depending on the combination of these materials. % To 50%).

The base ink layer 30 on the back of the stereoscopic image layer 29 is colored using Zion ink. Zion ink is an ink that functions as a change in color as a change in temperature.

There are many substances that change color by temperature, but in practical use, the discoloration by temperature change should be sure and the temperature range of discoloration should be narrow.

As the type of Zion ink, there are an irreversible type and a reversible type that do not recolor even when the temperature is returned to its original state. The latter is mainly put to practical use.

The reversible type Zion ink currently used is three types of a gold complex salt, a cholesteric liquid crystal, and a metamorphic color.

Zion pigments vary with temperature, with each grade varying in color from -15 ° C to + 65 ° C.

There are pigment grades that change when rising from 20 ° C. to 2 ° C. and pigment grades that change at 31 ° C., 43 ° C., and 65 ° C.

In the case of a typical Zion pigment 31 ° C. TP, the color disappears at 33 ° C. and returns to the original color when it is lowered to the original temperature.

In the present invention, 0 ℃ ~ 40 ℃ in consideration of the change in the normal room temperature Will grade and do appropriate.

However, due to the various changes in temperature and temperature in various countries, the specifications of the products are inevitably different.

The embossed pattern surface of the embossed sheet composed of three-dimensional embossing is colored on the back surface of the three-dimensional image layer 26 by gravure printing machine or screen printing.

In the modified embodiment as shown in Figs. 2 and 4, the spaces between the layers, for example, the empty spaces next to the three-dimensional printing layer 29 and the base ink layer 30 and the spaces above them are formed by printing. It should be noted that when forming the layer, only the unprinted space is represented. When the various layers are formed by printing, there will be areas where a pattern is formed, and there will be areas where the pattern is not formed. In addition, it should be noted that each layer in all the drawings of the present invention merely shows the formation process easily and is not expressed in proportion to the thickness.

While the present invention has been described in connection with what is presently considered to be the most practical and preferred embodiment, it is to be understood that the invention is not limited to the disclosed embodiments. It will be apparent to those skilled in the art that various modifications and variations can be made in the present invention without departing from the scope of the present invention.

16: release film layer 17: three-dimensional lens incident light
18: diffuse reflection incident light 19: diffuse reflection embossed layer
20: tempered glass layer 21: UV protection adhesive layer
22: first lens layer 23: refractive adjustment adhesive layer
24: second lens layer 25: focal length layer
26: pearl printing layer or deposition layer 27: color adjustment printing layer
28: shielding printed layer 29: stereoscopic image layer
30: base ink layer 31: finish adhesive layer

Claims (14)

Diffuse reflection embossing layer 19;
A first lens layer 22 formed below the diffuse reflection emboss layer;
A refractive adhesive layer 23 under the first lens layer 22;
A second lens layer 24 adhered to the first lens layer 22 by the refractive adhesive layer 23;
A focal length layer 25 formed below the second lens layer; And
Surface finishing material comprising a; and a finishing adhesive layer 31 formed below the focal length layer (25). Tempered glass layer 20;
A first lens layer 22 formed below the tempered glass layer 20;
A refractive adhesive layer 23 under the first lens layer 22;
A second lens layer 24 adhered to the first lens layer 22 by the refractive adhesive layer 23;
A focal length layer 25 formed below the second lens layer; And
Surface finishing material comprising a; and a finishing adhesive layer 31 formed below the focal length layer (25). The method according to claim 1 or 2,
Surface coating material characterized in that a pearl printing layer or a deposition layer is further formed between the lower portion of the focal length layer (25) and the upper portion of the finishing adhesive layer (31). The method of claim 3,
Surface coating material, characterized in that the color adjustment printing layer (27) for adjusting the coloring of the pearl printing layer or the deposition layer is further formed. The method according to claim 1 or 2,
Surface covering material further characterized in that the shielding printing layer (28) is further formed between the bottom of the focal length layer (25) and the top of the finishing adhesive layer (31). The method according to claim 1 or 2,
Surface mounting material, characterized in that the three-dimensional image layer (29) is further formed between the bottom of the focal length layer (25) and the top of the finishing adhesive layer (31). The method according to claim 1 or 2,
Surface covering material characterized in that the base ink layer 30 is further formed between the lower portion of the focal length layer (25) and the upper portion of the finish adhesive layer (31). The method according to claim 1 or 2,
Surface mounting material, characterized in that the removable release film is attached to the lower portion of the finishing adhesive layer (31). The method according to claim 1 or 2,
The first lens layer 22 is a surface covering material, characterized in that the lenticular lens. The method according to claim 1 or 2,
The surface packaging material is a surface packaging material, characterized in that attached to the exterior of the home appliance. The method according to claim 1 or 2,
The surface packaging material is attached to the exterior of the home appliance to improve the three-dimensional appearance of the surface packaging material. The method of claim 2,
Surface coating material, characterized in that the diffuse reflection embossing layer (19) is formed on top of the finishing adhesive layer (31). The method according to claim 1 or 2,
Surface mounting material, characterized in that the UV protection adhesive layer 21 is further added to the upper portion of the first lens layer (22). The method of claim 13,
The UV blocking adhesive layer 21 includes an adhesive component for adhesion with the first lens layer 22.

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