KR101970109B1 - Transparent parts having micro protrusion applying mobile display - Google Patents

Abstract

A transparent member which is applied to a portable apparatus and which has a thin thickness and improves the degree of concealment, as well as a fine irregularity which reduces a step caused by the print layer and reduces haze is proposed. The film includes a shatterproof film and a laminated sheet laminated with the shatterproof film, and the rim and the surface of the center portion of the shatterproof film are provided with a microstructure in which roughness is imparted to the surface by bending to make the shatterproof film translucent Unevenness is located. At this time, the laminate sheet includes a transparent substrate and an adhesive layer, and the adhesive layer penetrates into a space between the fine irregularities to convert the semi-transparent anti-scattering film into a transparent anti-scattering film, On the uneven surface, a printed layer is included.

Description

TECHNICAL FIELD [0001] The present invention relates to a transparent member having micro-irregularities applied to a portable device,

BACKGROUND OF THE INVENTION 1. Field of the Invention [0002] The present invention relates to a transparent member including fine irregularities, and more particularly, to a transparent member applied to a protective sheet and window of a portable device using fine irregularities.

A display such as a liquid crystal display (LCD), an organic light emitting diode (OLED), and an electrophoretic display (EPD) forms a screen. Such a display device is applied to various image display devices. On the other hand, the apparatus employs a touch screen to provide ease of operation. A window is disposed on the front of the touch screen and protects the display device from external shock or contact damage. In addition, the protective sheet is attached to the window of the portable device and serves to protect the window. Recently, a window and a protective sheet corresponding to the emergence of a flexible display have been demanded. These windows and protective sheets are transparent members other than the printing layer.

BRIEF DESCRIPTION OF THE DRAWINGS FIG. 1 is a view showing a conventional transparent member having a print layer. FIG. 1, the transparent member includes an adhesive layer 100, an anti-scattering film 102, an adhesive layer 104, a region where the print layer 106 is present, a transparent substrate 108, and a functional layer 110 sequentially Are laminated. Optionally, the adhesive layer 104 has a variety of layer structures, such as being disposed between the transparent substrate 108 and the print layer 106, and so on. The print layer 106 is present in the bezel region and may be present on the lower surface a of the transparent substrate 108 or between the adhesive layer 104 and the anti-scattering film 102 as shown ). Although not shown, the print layer 106 may be disposed on the lower surface of the transparent substrate 108 and on the upper surface of the anti-scattering film 102 at the same time. This printing layer 106 is described in detail in domestic patent publication No. 2015-0038709 and the like.

The print layer 106 typically has a thickness of a few micrometers, and its thickness causes a step difference g in the adhesive layer 100. [ When the step g is present, if the transparent member is attached to a skin complex such as a window or a touch screen, the portion having the step difference g is not completely attached, and bubbles or the like are generated. A method of forcibly adhering the adhesive layer 100 to the skin complex may be considered. However, in order to facilitate the attachment and detachment of the transparent member, the adhesive strength of the adhesive layer 100 can not be increased more than necessary. In addition, if the thickness of the print layer 106 is made too thin, the print layer 106 must maintain an appropriate thickness, especially since the degree of occlusion of the selectively applied white print layer is reduced.

In order to overcome the step (g), various layer structures are attempting. In order to reduce the step difference g, the distance between the adhesive layer 100 and the print layer 106 may be increased or the thickness of the print layer 106 may be reduced. However, if the distance between the adhesive layer 100 and the print layer 106 is large, the thickness of the transparent member becomes thick. In addition, when the thickness of the print layer 106 is reduced, the degree of concealment of the print layer 106 is lowered, and visibility of the internal structure is visually observed. On the other hand, it is preferable that the thickness of the print layer 106 is thin within a range in which the degree of concealment is satisfied. This is because if the print layer 106 is thick, a haze occurs due to a difference in refractive index at the end of the print layer 106. [

A problem to be solved by the present invention is to provide a transparent member which is applied to a portable apparatus and has a thickness reduced and a degree of concealment is improved, as well as a step caused by the printing layer is reduced and haze is reduced I have to.

One example of the transparent member including fine irregularities applied to a portable device for solving the problems of the present invention includes a transparent substrate and a laminated sheet laminated with the transparent substrate, and the rim and the surface of the central portion of the transparent substrate are Fine convexo-concaves for translucency of the transparent substrate are provided by applying roughness to the surface by bending. At this time, the laminate sheet includes a scattering-preventing film and an adhesive layer, and the translucent transparent substrate is converted into a transparent transparent substrate by the adhesive layer digging into the space between the fine irregularities.

In one example of the present invention, the transparent substrate may be made of any one selected from a glass substrate, a plastic substrate, or a substrate on which they are laminated. The adhesive layer detaches or bonds the laminate sheet to the transparent substrate. The fine irregularities may be implemented directly on the transparent substrate or in a separate layer on the window. The fine irregularities may be arranged in any one of a line shape, a lattice shape, an island shape, or a combination thereof. The micro concavity and convexity may be formed in any shape selected from a cylinder, a hemisphere, a polygonal pyramid, a polygonal pyramid, or a combination thereof. The fine irregularities may include any one of beads or beads and a binder. And a transparent printed layer may be formed on the irregular surface of the rim.

Another example of the transparent member including fine unevenness applied to a portable device for solving the problems of the present invention includes a shatterproof film and a laminated sheet laminated with the shatterproof film, and the rim of the shatterproof film and the The surface is provided with fine irregularities for imparting roughness to the surface by bending to make the anti-scattering film translucent. At this time, the laminate sheet includes a transparent substrate and an adhesive layer, and the adhesive layer penetrates into a space between the fine irregularities to convert the semi-transparent anti-scattering film into a transparent anti-scattering film, On the uneven surface, a printed layer is included.

In another embodiment of the present invention, the fine irregularities may be embodied directly on the anti-scattering film or as a separate layer on the anti-scattering film. The printing layer may be a background printing layer disposed on the concave-convex boundary surface of the shatterproof film frame. The printing layer may be a color printing layer disposed on the irregular surface of the edge of the transparent substrate.

According to the transparent member including the fine irregularities applied to the portable device of the present invention, by utilizing the fine irregularities, the thickness can be thinned and the degree of hiding can be improved. Further, steps caused by the printing layer can be reduced, haze can be reduced, and printability and adhesion can be increased.

BRIEF DESCRIPTION OF THE DRAWINGS FIG. 1 is a view showing a conventional transparent member having a print layer. FIG.
2 is an exploded cross-sectional view for explaining a first transparent member according to the present invention.
3 is a cross-sectional view showing an example of fine unevenness shown in Fig.
4 is a partial perspective view showing an example of the arrangement of fine concavities and convexities in FIG.
5 is an exploded cross-sectional view for explaining a second transparent member according to the present invention.
6 is a cross-sectional view for comparing the third transparent member and the conventional transparent member according to the present invention.
7 is a cross-sectional view showing a fourth transparent member according to the present invention.
8 is a cross-sectional view showing a fifth transparent member according to the present invention.

Hereinafter, preferred embodiments of the present invention will be described in detail with reference to the accompanying drawings. The embodiments described below can be modified into various other forms, and the scope of the present invention is not limited to the embodiments described below. The embodiments of the present invention are provided to enable those skilled in the art to more fully understand the present invention. Also, in the figures, the thicknesses of the films (layers, patterns) and regions may be exaggerated for clarity. Further, when it is mentioned that the film (layer, pattern) is in the "upper", "upper", "lower", "one side" of another film (layer, pattern) Or a different film (layer, pattern) may be interposed therebetween.

The embodiment of the present invention proposes a transparent member which not only improves the degree of concealment but also reduces steps caused by the print layer by reducing the thickness by utilizing the fine unevenness. To this end, the process of thinning the thickness of the transparent member and the print layer by fine unevenness will be separately described. The portable device applied to the embodiment of the present invention refers to all image processing devices such as a mobile device, an information processing terminal, and a television. The mobile device includes a mobile phone, a smart phone, a tablet, and the like. The information processing terminal includes an ATM, a kiosk, and the like.

The transparent member shown in the embodiment of the present invention includes a protective sheet or window for protecting a window or a touch screen, respectively, in a portable device. The portable device may be flat, curved, or flexible. Particularly, a portable device including a curved surface refers to a device having a rim, a central portion, and a curved surface. Portable devices having both a rim and a curved surface in the center portion may have a flexible display. In addition, the portable device of the embodiment of the present invention is divided into a rim and a central portion, and generally has a bezel region with a printed layer on the rim. In some cases, the screen extends from the center to the frame. Hereinafter, the region of the transparent member corresponding to the rim of the portable device will be referred to as a frame (a), and the region corresponding to the center portion will be referred to as a central portion (b).

2 is an exploded cross-sectional view for explaining a first transparent member 100 according to an embodiment of the present invention. However, it is not intended to express a cross-section in the strict sense, and for the convenience of explanation, there may be a component that may not appear on the cross-section.

2, the first transparent member 100 is divided into a rim a and a central b. The screen of the portable device can be seen extending from the center portion (b) to the frame (a). Generally, a printing layer is formed on the rim a. The first transparent member 100 includes a transparent substrate 30 including fine irregularities 20 and a first laminated sheet 10 bonded thereto. The first sheet of composite sheet 10 comprises an adhesive layer 11, a scattering-preventing film 12, and a functional layer 13. The adhesive layer 11 is coated with a transparent pressure-sensitive adhesive or an adhesive, and may be, for example, any one of acrylic resin, silicone resin, epoxy resin, urethane resin or a composite resin thereof. The adhesive layer 11 can be detached from the transparent substrate 30 using a pressure sensitive adhesive, or can be permanently bonded using an adhesive.

The shatterproof film 12 can be used without restriction as long as it is made of a transparent plastic material. For example, the plastic material is made of a thermoplastic resin and is preferably made of PET (PolyEthylene Terephthalate), PEN (PolyEthylene Naphthalate), PES (Polyether Sulfone), PI (Polyimide), PAR (Polyarylate) And may be at least one selected from the group consisting of PMMA (PolyMethyl Methacrylate), PU (Polyurethane), TAC (Tri-Acryl-Cellulose) and COC (Cycloolefin Copolymer).

The functional layer 13 may impart characteristics such as fingerprint prevention, antireflection, blue light blocking, electromagnetic wave blocking, privacy, and antibacterial properties. For example, a fluorine-based coating liquid may be wet-coated, or may be dry-coated by vacuum deposition to form a fingerprint-preventing coating layer that provides a fingerprint-proofing function. The functional layer 13 may be a glass which has been subjected to anti-fingerprinting or anti-fingerprinting and antimicrobial treatment, or a plastic substrate having anti-fingerprinting or anti-fingerprinting and anti- As such, the coating may allow the first sheet of composite sheet 10 to exhibit various functions.

The transparent substrate 30 can be used without limitation as long as it is made of a transparent material. For example, a glass substrate or a plastic substrate. Specifically, the glass substrate may be tempered glass, and the plastic substrate is made of a thermoplastic resin. Preferably, the plastic substrate is made of PET (PolyEthylene Terephthalate), PEN (PolyEthylene Naphthalate), PES (Polyether Sulfone) ), PC (PolyCarbonate), PMMA (PolyMethyl Methacrylate), PU (Polyurethane), TAC (Tri-Acrylic-Cellulose) or COC (Cycloolefin Copolymer). The transparent substrate 30 may be a laminated structure in which the reinforcing glass and the plastic substrate are formed in multiple layers.

Alternatively, the transparent sheet 30 may employ a slim tempered glass having a thickness of approximately 10 mu m to 150 mu m. The slim tempered glass has a breakage mechanism that causes cracks that do not involve debris. Since there are no scattered fragments and no sharp edges, there is no debris that injures or injures the user or is sucked into the human body. The slim tempered glass is more flexible when it is applied to a curved surface portable device because it is free to bend.

The fine unevenness 20 is formed on the surface of the transparent substrate 30, and is not flat and has a curvature to generically refer to imparting roughness to the surface. The curvature may be angled, curvilinear, or a combination thereof. For example, the fine irregularities 20 may be in the shape of a band having a constant width, or may be a cylinder, a hemisphere, a polygonal pyramid such as a triangular pyramid, a polygonal pyramid such as a pyramidal pyramid, and a combination of the above shapes. In other words, the fine irregularities 20 are possible in various forms within the scope of the present invention. The fine irregularities 20 will be described in detail with reference to FIGS. 3 and 4 as an example. The fine irregularities 20 have an irregular surface 21 corresponding to the shape.

The fine irregularities 20 are formed by various methods. For example, it can be formed by mixing semi-transparent beads such as silica with a UV or thermosetting resin and coating them on the adhered layer and curing them. Further, it can be formed by coating a UV or thermosetting resin or the like with a sheet or roll mold in which the shape for forming the fine unevenness 20 is formed, and curing it. A film or a sheet coated with UV or a thermosetting resin can be transferred to the adhered layer. Can be formed by molding into a mold having a shape conforming to the fine unevenness (20).

The fine irregularities 20 can be formed by coating a resin or the like after masking, forming fine irregularities 20 by exposure or etching, and removing the mask. Can be formed directly on the surface of the detachable layer using a laser beam. Can be formed by printing directly on the surface of the adhered layer using UV or thermosetting ink. The fine irregularities 20 can be formed on the surface by directly applying a physical impact to the surface of the surface layer. The fine irregularities 20 formed by the above method may be implemented directly on the transparent substrate 30 and may be implemented as separate layers. This is represented by a dotted line.

When the first laminated sheet 10 is attached to the transparent substrate 30 on which the fine unevenness 20 is formed according to the embodiment of the present invention, the adhered layer 11 of the first laminated sheet 10 is bonded to the fine unevenness 20, And the translucent screen changes transparently. In the drawing, the transparent rugged interfacial boundary surface 21a formed by dicing the space between the irregular interfacial surfaces 21a of the adhesive layer 11 of the first sheet of rubbers 10 is represented by a dotted line. Accordingly, even if the transparent substrate 30 on which the fine irregularities 20 are formed is used, the display clarity in the transparent state can be maintained.

The fine irregularities 20 exhibit various effects such as prevention of fingerprints, prevention of contamination and prevention of reflection. If fine irregularities (20) are present, the fingerprints or contaminants are discontinuously formed to prevent the formation of fingerprints and adhesion of contaminants. Specifically, fingerprints or contaminants may adhere to the protruding portions of the fine unevenness 20, but they do not adhere to the concave portions. Thus, the fine irregularities 20 have an effect of preventing fingerprints and preventing contamination. Accordingly, the transparent substrate 30 including the fine irregularities 20 need not have a separate fingerprint prevention function.

On the other hand, the irregular interfacial boundary surface 21a induces a slight diffuse reflection as compared with the case where the fine irregularities 20 are not present. The diffusive reflection shields the external light from being reflected on the screen corresponding to the first transparent member 100. Reflections on the screen are the cause of glare. The fine unevenness 20 of the present invention can reduce the glare phenomenon. In addition, this diffuse reflection slightly diffuses the light going straight from the display, and particularly enhances the degree of concealment at the edge (a). Furthermore, since the concave and convex portions 20 have concave portions, the discharge of bubbles is easy. That is, the fine unevenness 20 allows the first sheet of composite sheet 10 to be stably attached to the transparent substrate 30.

The fine irregularities 20 in the first transparent member 100 according to the embodiment of the present invention are divided into the first irregularities 20a in the frame a and the second irregularities 20b in the center part b . The screen of the portable device exists over the central portion b or the central portion b and the frame a so that the second unevenness 20b corresponds to the screen of the portable device. As described above, the second concavity and convexity 20b can attain an effect of reducing the glare phenomenon and the like.

3 is a cross-sectional view showing an example of fine unevenness 20 existing in the transparent substrate 30 of FIG.

Referring to FIG. 3, the transparent substrate 30 is formed with various types of fine irregularities 20. Here are some examples. Here, the fine unevenness 20 is formed by forming the irregularities in the shape of any one of the triangle 21a, quadrangle 21b and hemispherical 21c, or by forming the bead or the bead and the binder 21d For example. That is, the interface between the fine irregularities 20 may have an angle, a curvature, or a combination thereof. When the fine unevenness 20 is formed on the transparent substrate 30, the transparent substrate 30 is translucent and the light transmittance is low. The transparent substrate 30 including the fine irregularities 20 whose transmittance is decreased has a low transmittance and is separated from the transparent window without the fine irregularities 20 by the naked eye.

4 is a partial perspective view showing an example of the arrangement of fine concavities and convexities 20 existing in the transparent substrate 30 of FIG.

4, the fine irregularities 20 can be arranged in a line shape (a, 21e), a lattice shape (b, 21f), an island shape (c, 21g) or the like. At this time, although the arrangement of the fine concavities and convexities 20 is exemplified as the case where the boundary surface is the triangle 21a, it may be formed into any one shape selected from the quadrangle 21b and the circular shape 21c, (21d). That is, the boundary surface of the fine irregularities 20 has an angle, a curvature, or a combination thereof. In addition, the fine irregularities 20 may be regularly arranged at regular intervals, but they may be irregularly arranged without a constant interval.

5 is an exploded cross-sectional view for explaining a second transparent member 200 according to an embodiment of the present invention. At this time, the second transparent member 200 is the same as the first transparent member 100 except that a transparent print layer 40 is added. Accordingly, detailed description of the same reference numerals will be omitted. Here, the irregularity boundary surface 21 is taken as an example of the irregularity boundary surface 21a in Fig.

According to Fig. 5, the transparent print layer 40 is located on the irregularity boundary surface 21a of the rim a. The transparent print layer 40 is a transparent print layer. The transparent print layer 40 may be made of a metal oxide such as ITO, ATO, ZnO, or the like, or a material that imparts conductivity such as Cu, a conductive polymer, or a silver nanowire. The transparent print layer 40 is sandwiched between the minute irregularities 20a of the irregular surface 21a. Accordingly, the transparent printed layer 40 can be made thinner than the case where the fine unevenness 20a is not present based on the same physical properties. For example, when the thickness of the conventional print layer without fine irregularities is several 占 퐉, the thickness of the transparent print layer 40 of the second transparent member 200 having fine irregularities 20a becomes smaller than the above-mentioned several 占 퐉 . This is because the contact area between the fine unevenness 20a and the transparent printed layer 40 is increased, and the same properties can be realized.

When the thickness of the transparent print layer 40 becomes small, the diffuse reflection of the fine unevenness 20a causes destructive interference with the end of the transparent print layer 40, and the haze disappears. In addition, the anchoring effect described above increases the adhesion of the transparent print layer 40 compared to the prior art. Furthermore, since the surface area of the fine unevenness 20a is increased, the printability of the transparent print layer 40 is improved, and printing is easily performed.

6 is a cross-sectional view for comparing a third transparent member 300 and a conventional transparent member according to an embodiment of the present invention. The third transparent member 300 is the same as the second transparent member 200 except that the positions of the scattering prevention film 12 and the transparent substrate 30 are changed from each other. Accordingly, detailed description of the same reference numerals will be omitted.

6, the fine unevenness 20 in the third transparent member 300 is located on one side of the anti-scattering film 12. The color printing layer 42 is provided on the lower surface of the transparent substrate 30 opposite to the background printing layer 41 with respect to the adhesive layer 11 in the fine unevenness 20a of the frame a, Lt; / RTI > The background print layer 41 is mainly white, and the color print layer 42 may be a monochromatic or color print layer. The laminate sheet including the transparent substrate 30 is referred to as a second laminate sheet 50 in order to distinguish it from the first laminate sheet 10 of the first and second transparent members 100 and 200. The adhesive layer 60 applied to the anti-scattering film 12 facilitates detachment of the skin complex (window or touch screen). The fine irregularities 20 may be directly formed on the anti-scattering film 12 as shown in FIG. 2, and may be implemented as separate layers. This is represented by a dotted line.

The adhesive layer 60 has an adhesive force of 0.1 gf / 25 mm to 500 gf / 25 mm. The adhesive layer 60 may be made of various materials within the scope of the present invention and may be, for example, any one of acrylic resin, silicone resin, epoxy resin, urethane resin, and composite resin thereof. The adhesive layer 60 may be a detachable fluidized bed in the form of a pocket containing a fluid, or may be a detachable pattern in which a part is cured to form a pattern. Wherein the releasable fluidized bed includes an adhesive surface bonded to the transparent sheet in the form of a pocket, an adhesive surface adhered to the display component, and a side surface defining a side wall positioned between the adhesive surface and the adhesive surface, . The removable pattern has a pattern in which an adhesive layer having an adhesive force of about 0.1 gf / 25 mm to 500 gf / 25 mm and a cured layer of the adhesive layer are cured. The adhesive layer 60 has a self-adhesive force. The self-adhesive force is a property that the adhesive layer 60 adheres to itself without bubbling even if the adhesive layer 60 is placed on the skin complex.

Hereinafter, the third transparent member 300 of the present invention will be compared with a conventional transparent member. The conventional scattering prevention film 220 of the third transparent member 300 is formed of a conventional shrinkage preventing film 220. The adhesive layer 60 is a conventional adhesive layer 221 and the background printing layer 41 is a conventional background printing layer The conventional color print layer 211 and the second laminate sheet 50 correspond to the conventional second laminate sheet 200. In this case, The conventional adhesive layer 201 of the second sheet of ply sheet 50 and the conventional transparent substrate 202 of the transparent substrate 30 and the conventional functional layer 13 203). At this time, the adhesive layers 11 and 201 are preferably bonded to the anti-scattering films 12, unlike the first and second transparent members 100 and 200.

When the third transparent member 300 is compared with the conventional transparent member, the thickness of the conventional background print layer 210 is D0 and the thickness of the background print layer 41 of the third transparent member 300 is D1. That is, since the background printing layer 41 of the present invention is formed by flowing into the fine irregularities 20a, the thickness D1 is smaller than the thickness D0. As a result, the thickness of the background print layer 41 of the present invention is reduced. In addition, the degree of concealment of the background print layer 41 of the present invention is much greater than that of the conventional background print layer 210. This is because the fine irregularities 20a of the present invention cause irregular reflection, thereby increasing the degree of concealment of the background printing layer 41. [ Accordingly, the third transparent member 300 of the present invention can achieve a high degree of concealment even though the thickness of the background print layer 41 is small.

If the degree of concealment is high, the background printing layer 41 can be enhanced in clarity and effectively performed as a background. That is, even though the background printing layer 41 of the third transparent member 300 is made thin, it is possible to effectively perform the background role of the color printing layer 42 by printing with high hiding. On the other hand, the conventional background printing layer 210 has a thickness of several micrometers, and the thickness thereof causes a step difference g in the adhesive layer 221. When the step g is present, if the conventional transparent member is attached to a skin complex such as a window or a touch screen, the portion having the step difference g is not completely adhered, and bubbles or the like are generated. However, in the third transparent member 300 of the present invention, the level difference g of the background printing layer 41 is relatively reduced. In the drawing, there is an exaggerated point, but the step (g) is omitted.

It is needless to say that the characteristics of the background print layer 41 of the third transparent member 300 contributed by the fine irregularities 20a are all applied as described above. For example, the characteristics include haze, adhesion, printability, and the like. Accordingly, the physical properties will not be described in detail. The technical mapping of the background printing layer 41 of the third transparent member 300 is also applied to the transparent printing layer 40 of the second transparent member 200 as it is.

7 is a cross-sectional view showing a fourth transparent member 400 according to an embodiment of the present invention. At this time, the fourth transparent member 400 is the same as the third transparent member 300 except that the third concavo-convex 20c of the color printing layer 43 is added. Accordingly, detailed descriptions of the duplicate expressions will not be given.

7, the color printing layer 43 of the fourth transparent member 400 is located in the third concavo-convex 20c of the frame a. The third concavo-convex 20c is present on the transparent substrate 30. The thickness of the color print layer 43 is D2, which is smaller than the color print layer 42 of the third transparent member 300. [ The reason why the thickness is small is that the third transparent member 300 is referred to. When the thickness of the color print layer 43 is reduced, the fourth transparent member 400 can further reduce the step difference g as compared with the third transparent member 300. [

8 is a cross-sectional view showing a fifth transparent member 500 according to an embodiment of the present invention. The fifth transparent member 500 is the same as the fourth transparent member 400 except that the fourth concave and convex portions 20d are added to the center portion b of the transparent substrate 30. Accordingly, detailed descriptions of the duplicate expressions will not be given.

8, a fourth concavo-convex portion 20d is added to the center portion b of the transparent substrate 30 in the fifth transparent member 500. As shown in Fig. The fourth irregularities 20d exhibit various effects such as prevention of fingerprints, prevention of contamination, prevention of reflection, and the like described above. Further, the irregular surface 21a is more likely to be slightly diffused as compared with the case where the irregularities 20 are not present. The diffused reflection shields the external light so that reflection on the screen corresponding to the fifth transparent member 500 does not occur. Reflections on the screen are the cause of glare. The fourth concavo-convex 20d of the present invention can reduce the glare phenomenon. In addition, since the fourth concavo-convex 20d has a concave portion, it is easy to discharge the bubbles.

While the present invention has been particularly shown and described with reference to exemplary embodiments thereof, it is to be understood that the invention is not limited to the disclosed exemplary embodiments, but many variations and modifications may be made without departing from the spirit and scope of the invention. It is possible. For example, although the embodiments of the present invention have been described with reference to a laminated sheet, the concept of the present invention can also be applied to a touch screen, a touch screen cover layer, and a display.

10, 50; The first and second laminate sheets
11; An adhesive layer 12; Shatterproof film
13; Functional layer 20; Fine unevenness
20a, 20b, 20c, 20d; First to fourth concave and convex
21, 21a, 21b, 21c, 21d, 21e, 21f, 21g; Irregularity boundary surface
30; Transparent substrate
40; A transparent printing layer 41; Background printing layer
42, 43; Color print layer
60; Adhesive layer

Claims (7)

A shatterproof film and a laminated sheet laminated with the shatterproof film,
Wherein the laminate sheet comprises a transparent substrate and an adhesive layer,
The surface of the shake prevention film and the surface of the center portion are provided with roughness on the surface by bending to induce irregular reflection, and the minute unevenness to make the shake prevention film translucent is located,
The surface of the rim of the transparent substrate or the surface of the rim and the center of the rim is subjected to bending to give roughness to the surface,
The adhesive layer is pierced into a space between the fine irregularities at the center of the shrinkage preventing film to remove the diffuse reflection to convert the translucent shatterproof film to a transparent shatterproof film to maintain the clarity of the screen,
And a printed layer formed on the fine irregularities located in the rim,
Wherein the print layer includes a background print layer disposed on an irregular surface of the edge of the shatterproof film and a color print layer disposed on an irregular surface of the edge of the transparent substrate. absence. The transparent member according to claim 1, wherein the fine irregularities are embodied directly on the anti-scattering film or as separate layers on the anti-scattering film. The transparent member according to claim 1, wherein the fine concavities and convexities are arranged in any one of a line shape, a lattice shape, an island shape, or a combination thereof. The transparent member according to claim 1, wherein the fine concavities and convexities are formed in any shape selected from a cylinder, a hemisphere, a polygonal pyramid, a polygonal pyramid, or a combination thereof. The transparent member according to claim 1, wherein the fine irregularities include any one of beads or beads and a binder.

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