KR20100019020A - Multi functional 3 layers optical film for back light unit - Google Patents

Abstract

PURPOSE: A multi functional three multi-layer optical film for back light unit are provided to implement durability against thermal transformation or bending and dispersion and collection of the light by manufacturing a sheet and acrylic sheet to be a three multi-layer. CONSTITUTION: A multi functional three multi-layer optical film for back light unit is formed by collecting diffusion convex micro lens(5) of hemispherical. The convex micro lens of hemispherical is a three multi-layer and has light diffusion characteristic. The three multi-layer is formed by stacking a polycabonate sheet(1) and an acrylic sheet(2).

Description

MULTI FUNCTIONAL 3 LAYERS OPTICAL FILM FOR BACK LIGHT UNIT}

The present invention relates to a multifunctional optical film used in a backlight unit, and more particularly, to provide a polycarbonate sheet and an acrylic sheet in a three-polymer structure, and the hemispherical convex or concave diffused microlenses to the upper and lower surfaces of the three-polymer sheet, Since the condensing prism is configured in various ways, it provides durability against heat deformation and warpage deformation by a single film, and provides light diffusion and condensing functions. In particular, the present invention relates to a multifunctional optical film for a backlight unit that is effectively applied to a large screen.

In general, liquid crystal displays (LCDs), which are widely used in computer monitors, notebook computers, LCD TVs, mobile phones, camcorders, digital cameras, PDAs, and navigation devices, cannot emit light on their own and require external light sources.

Such a device for providing a light source is called a back light unit (BLU).

The backlight unit is classified into an edge type and a direct type according to the position of the light source.

Such a backlight unit has a plurality of optical films, for example, a reflective film for reflecting light, a diffuser plate for scattering light to make the panel uniform, and a brightness enhancement film (BEF) DBEF) and the like.

In addition, in recent years, in order to increase the brightness, thickness, and low power of the backlight unit, there is a demand for a technology capable of increasing the optical characteristics while minimizing the number of optical films.

In addition, as the backlight unit becomes thinner and larger, there is a need for a technology that can effectively solve the problem of thermal deformation and warpage deformation.

Of course, the recent studies on materials such as polycarbonate as a material excellent in optical properties, heat resistance, and impact resistance, but the conventional problems of increasing the optical properties, bending deformation, thermal deformation, etc. have not been fundamentally solved.

The present invention has been invented to solve the above problems of the prior art, and provides a polycarbonate sheet and an acrylic sheet in a three-polymer structure, and hemispherical convex or groove-type diffused microlenses, condensing to the upper and lower surfaces of the three-polymer sheet. Since the prism is configured in various ways, a single film provides durability against heat deformation and warpage deformation, and provides light diffusion and condensing functions, and is particularly effective for large screens.

SUMMARY OF THE INVENTION Since the beads are mixed and molded in a polycarbonate sheet located inside and outside of the three-polymer structure of the polycarbonate sheet and the acrylic sheet, the purpose of the present invention is to provide an excellent shielding function by enhancing the diffusion function and forming a haze.

This invention,

It is characterized by intensively forming a hemispherical convex diffused microlens having light diffusing characteristics or a condensing prism having light condensing characteristics on the upper or upper and lower surfaces of a tripolymer structure in which a polycarbonate sheet and an acrylic sheet are laminated.

The present invention is characterized in that the upper and lower surfaces of a tripolymer structure in which a polycarbonate sheet and an acrylic sheet are laminated to form a light collecting prism having light condensing properties and a hemispherical convex diffusing microlens having light diffusing properties.

The present invention is a combination of a hemisphere convex diffused microlens having a light condensing prism or a light diffusing characteristic and a hemispherical convex diffused microlens having a light diffusing characteristic as an upper and lower surfaces of a tripolymer structure in which a polycarbonate sheet and an acrylic sheet are laminated. It is characteristic in forming.

The present invention is characterized in that the acrylic sheet is laminated on the upper and lower parts of the polycarbonate sheet, or the polycarbonate sheet is laminated on the upper and lower parts of the acrylic sheet.

The present invention is characterized by mixing and molding beads in a polycarbonate sheet of the tripolymer structure.

The present invention provides a single optical film, which provides a polycarbonate sheet and an acrylic sheet in a triple polymerization structure, and a variety of hemispherical convex or grooved diffusion microlenses and condensing prisms are formed on the upper and lower surfaces of the triplex sheet. The film provides durability against heat deformation and bending deformation, and provides light diffusion and condensing functions as well as mixing and molding beads on the sheet, thus enhancing the diffusion function and forming high haze to provide excellent shielding function. It is effective to apply to.

Hereinafter, the present invention will be described in more detail.

The present invention is to provide a multi-functional optical film constituting various combinations of a polycarbonate sheet and an acryl sheet, and the hemispherical convex or concave diffused microlens and the condensing prism in the upper and lower surfaces of the tripolymer structure.

In other words, by using a triple polymer structure of a polycarbonate sheet having excellent durability against heat deformation and bending deformation and an acrylic sheet having excellent optical characteristics, various diffused microlens structures and condensing prism structures are integrated and provided on the upper and lower surfaces thereof. will be.

That is, the tripolymer structure of the present invention is a type A structure in which the acrylic sheet 2 is laminated on the upper and lower portions of the polycarbonate sheet 1 and a type B structure in which the polycarbonate sheet 1 is laminated on the upper and lower portions of the acrylic sheet 2. It is composed roughly.

At this time, the polycarbonate sheet located in the inner center of the A-type or the polycarbonate sheet located in the upper and lower parts of the B-type in the polymerization structure of the bead (10) mixed molding to enhance the diffusion function and increase the haze to maximize the shielding function. You can do it.

In addition, the hemispherical convex diffused microlens 5, the hemispherical grooved diffused microlens 6, and the condensing prism 7 are formed in various combinations on the upper and lower portions of the film having the three-polymer structure.

Such various embodiments of the present invention multifunctional optical film will be described with reference to the accompanying drawings.

First, the embodiment illustrated in FIGS. 1A to 1G is an A-type tripolymer structure in which an acrylic sheet 2 is stacked on top and bottom of a polycarbonate sheet 1, and the embodiment illustrated in FIGS. 2A to 2G is an acrylic sheet ( It is a B-type tripolymer structure which laminated | stacked the polycarbonate sheet 1 on the upper and lower parts of 2).

The A-type tripolymer structure has excellent durability against heat deformation and warpage deformation compared to a single optical film. However, since the acrylic sheet (2) is laminated on the upper and lower portions of the polycarbonate sheet (1), the acrylic sheet has high light transmittance. Has a higher optical characteristic than the B-type tripolymer structure, and the B-type tripolymer structure has a higher heat than the A-type tripolymer structure because the polycarbonate sheet 1 is laminated on the upper and lower portions of the acrylic sheet 2. It has the advantages of high durability against deformation and bending deformation, and better impact resistance and scratch resistance.

In the A-type tripolymer structure and the B-type tripolymer structure, the thickness ratio of the sheet located inside and the sheet located outside is preferably 8 to 4: 1 to 3, and is integrally formed by extrusion molding or fusion bonding. You can do it.

First, a description will be given of the A-type tripolymer structure.

1A and 1B collectively form hemispherical convex diffused microlenses 5 having light diffusing characteristics on the upper or upper and lower surfaces of a tripolymer structure in which an acrylic sheet 2 is laminated on top and bottom of a polycarbonate sheet 1. .

In particular, the hemispherical convex diffusion microlens 5 is preferably formed such that the hemispherical height has a length equal to or less than 1/2 with respect to the diameter.

This embodiment provides a semi-spherical convex diffused microlens (5) with a triple optical structure in which an acrylic sheet (2) is laminated on top and bottom of a polycarbonate sheet (1) as a single optical film. To provide the light diffusion function.

1C and 1D collectively form a condensing prism 7 having light condensing properties on the upper or upper and lower surfaces of a tripolymer structure in which acrylic sheets 2 are laminated on upper and lower polycarbonate sheets 1.

This embodiment is a single optical film by the condensation prism (7) to improve the durability against thermal deformation and bending deformation by the tri-polymerization structure in which the acrylic sheet (2) is laminated on top and bottom of the polycarbonate sheet (1) It is to provide the light condensing function.

FIG. 1E shows a light collecting prism 7 having light condensing properties and a hemispherical convex diffusing microlens 5 having light diffusing properties in the upper and lower surfaces of a tripolymer structure in which an acrylic sheet 2 is laminated on top and bottom of a polycarbonate sheet 1. It is a composite formed.

This embodiment provides a semi-spherical convex diffused microlens (5) with a triple optical structure in which an acrylic sheet (2) is laminated on top and bottom of a polycarbonate sheet (1) as a single optical film. It provides a light diffusing function and a light condensing function of the light by the condensing prism (7).

1F and 1G are top and bottom surfaces of a tripolymer structure in which an acrylic sheet 2 is laminated on top and bottom of a polycarbonate sheet 1, and a light converging prism 7 having a light condensing characteristic or a hemispherical convex diffusing microlens having a light diffusing characteristic. (5) and the hemispherical groove-diffusion microlens 6 having light diffusing characteristics are formed in a composite.

This embodiment provides a semi-spherical convex diffused microlens (5) with a triple optical structure in which an acrylic sheet (2) is laminated on top and bottom of a polycarbonate sheet (1) as a single optical film. And the light diffusing function by the hemispherical groove diffusing microlens 6 or the light condensing function by the condensing prism 7 and the light diffusing function by the hemispherical groove diffusing microlens 6.

Next, the embodiment shown in FIGS. 2A to 2G is a B-type tripolymer structure, in which the polycarbonate sheet 1 is laminated on the upper and lower portions of the acrylic sheet 2 as compared with FIGS. 1A to 1G described above. As having a difference, the structure and the effect of the same by intensively forming the hemispherical convex diffused microlens 5, the hemispherical grooved diffused microlens 6 and the condensing prism 7 on the upper and lower surfaces are the same, and thus the detailed description is omitted. Let's do it.

Next, FIGS. 3A to 3G and FIGS. 4A to 4G stack an A-type structure in which the acrylic sheet 2 is laminated on the upper and lower portions of the polycarbonate sheet 1 and the polycarbonate sheet 1 on the upper and lower portions of the acrylic sheet 2. In one B-type structure, the bead 10 may be mixed and molded to maximize the shielding function by increasing the haze to the polycarbonate sheet 1 positioned on the inner or upper and lower surfaces thereof.

This embodiment achieves improved durability against thermal deformation and flexural deformation by the tripolymer structure in which the polycarbonate sheet 1 and the acrylic sheet 2 are laminated as a single optical film, and the hemispherical convex diffusion microlenses 5 And the hemispherical grooved diffusion microlens 6 provides a light diffusion function, and a light condensing prism 7 provides a light condensing function, as well as a diffusion function by mixing and molding the beads 10 inside the polycarbonate sheet. It is to provide an integrated solution to maximize the shielding function by increasing the efficiency and the haze.

1A to 1G are examples of the multifunctional optical film of the present invention, in which a hemispherical diffused microlens and a condenser prism are formed on the upper and lower surfaces of an acrylic sheet stacked on top and bottom of a polycarbonate sheet.

Figure 2a to 2g is another example of the multi-function optical film of the present invention, a composite of the hemispherical diffuse microlens and the condensing prism formed on the upper and lower surfaces of the polycarbonate sheet laminated on the upper and lower parts of the acrylic sheet.

Figures 3a to 3g, Figures 4a to 4g is another example of the multi-function optical film of the present invention, a mixture of molding the beads on the polycarbonate sheet in a laminated structure of the polycarbonate sheet and the acrylic sheet.

** Description of the symbols for the main parts of the drawings **

1: polycarbonate sheet 2: acrylic sheet

5: Hemispherical Convex Diffusion Microlens

6: Hemispherical grooved diffuse microlens

7: condensing prism

10: Bead

Claims (7)

In the multifunctional optical film, For the backlight unit, characterized in that the hemispherical convex diffused microlenses 5 having light diffusing characteristics are collectively formed on the upper or upper and lower surfaces of a tripolymer structure in which the polycarbonate sheet 1 and the acrylic sheet 2 are laminated. Tripolymer multifunctional optical film. In the multifunctional optical film, Multi-polymerization multi-function for backlight unit, characterized in that the condensing prism (7) having light condensation characteristics are formed by forming the upper surface or the upper and lower surfaces of the three-layer structure of the polycarbonate sheet (1) and the acrylic sheet (2) laminated Optical film. In the multifunctional optical film, A light collecting prism 7 having light condensing properties and a hemispherical convex diffusing microlens 5 having light diffusing properties are formed by forming a polycarbonate sheet 1 and an acrylic sheet 2 on the upper and lower surfaces of a tripolymer structure. Multi-functional optical film for the backlight unit, characterized in that made. In the multifunctional optical film, The upper and lower surfaces of the tripolymer structure in which the polycarbonate sheet 1 and the acrylic sheet 2 are laminated, and a light collecting prism 7 having a light condensing property, a hemispherical convex diffusion microlens 5 having a light diffusing property, and a light diffusing property. Triple polymer multi-function optical film for a backlight unit, characterized in that formed by forming a complex hemispherical groove diffused micro lens (6) having a. The method according to claim 1 or 2 or 3 or 4, The multi-polymer optical film for a backlight unit, characterized in that the polycarbonate sheet (1) upper and lower parts of the acrylic sheet (2) laminated in a three-polymer structure. The method according to claim 1 or 2 or 3 or 4, The multi-functional optical film for the backlight unit, characterized in that the acrylic sheet (2) formed of a triple polymerization structure in which the polycarbonate sheet (1) is laminated. The method according to claim 1 or 2 or 3 or 4, The tripolymer structure in which the polycarbonate sheet 1 and the acrylic sheet 2 are laminated is formed by mixing and molding the beads 10 in the polycarbonate sheet 1 located inside or on the upper and lower surfaces thereof. Tripolymer multifunctional optical film.

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