KR20160072653A - Enhancement of Prism function Using the Low Refractive Index Light Dispersive Coating Layer for Quantum Dot Sheet - Google Patents

Abstract

According to a barrier film structure of the present invention, a base coating layer is formed on a base film and a transparent inorganic thin film coating layer is formed on the base coating layer. On the transparent inorganic thin film coating layer, low refractive particles are dispersed on one or all of the base coating layer and a protection coating layer in a structure having the protection coating layer for protection. According to the present invention, a quantum dot sheet is utilized and a prism structure is integrated with the quantum dot sheet in order to improve light efficiency of a prism sheet integrated with the quantum dot sheet.

Description

(Enhancement of Prism Function Using Low Refractive Index Light Dispersive Coating Layer for Quantum Dot Sheet) for Improving Prism Function of Quantum Dot Sheet [

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to a Quantum Dot sheet, and more particularly, to a quantum dot sheet which is positioned between a backlight used in an LCD display and a display, And a prism structure to which the barrier film is applied in combination.

BACKGROUND OF THE INVENTION [0002] The background art of the present invention relates to the structure and physical properties of a composite sheet incorporating a quantum dot sheet and a prism sheet while using a quantum dot sheet as a backlight of a liquid crystal display.

Quantum dot layer of quantum dot sheet and the structure of prism structure combined with barrier film. It improves the efficiency of light condensation by making difference of refractive index of layer incident on prism structure.

The problem to be solved by the present invention is to minimize the increase in the price of the backlight by using the Quantum dot sheet as an LCD backlight.

In particular, LCD backlights have a complex structure such as reflective sheet, light guide plate, LED light source, prism sheet, and diffusion sheet. When Quantum Datesheet is added to this, the number of sheets increases and the price increases.

Thus, using the Quantum Dotsheet to integrate the prism structure into the Quantum Dot Sheet, it is intended to increase the light efficiency of the Quantum Datesheet composite prism sheet.

For this purpose, the refractive index of the coating layer of the barrier film constituting the quantum dot sheet is lowered, and the diffusing function is added so as to increase the light condensing efficiency by increasing the path of the light incident on the prism.

As a solving means of the present invention, in a structure in which a prism structure is combined with a barrier film of Quantum's dot sheet, a base coating layer is formed on the base film of the barrier film and a protective coating layer for protecting the inorganic thin film layer having a barrier function formed on the base coating layer, And a light scattering function is added so that light incident on the prism can be refracted upward.

In order to add a scattering function to the coating solution while maintaining a low refractive index, inorganic particles having a low refractive index should be added. In the present invention, a MgF2 fine powder is mixed with a transparent ultraviolet curable coating solution.

In addition to MgF2, a mixed coating of inorganic fine powder with a low refractive index is possible.

The effect of the present invention is to enhance the light converging function of the prism by making the refraction of the light incident on the prism upward in producing a prism composite structure on the barrier film of a totathe seat.

Fig. 1 shows a structure in which a Quantum Dot Sheet is mounted on an LCD for constituting the present invention.
2 is a cross-sectional view of a conventional structure of a barrier film.
3 shows a cross-sectional view of the structure of a typical Quantum dot sheet.
4 is a cross-sectional view of a structure in which a prism is formed on a Quantum dot sheet.
5 is a path of light incident on the prism sheet.
FIG. 6 shows the optical path structure of the Quantum dot sheet.
7 is a cross-sectional view of a structure in which low refractive index particles are dispersed in a protective coating layer to a base coating layer according to the present invention.

A basic structure in which a Quantum Dot Sheet is mounted on a LCD for constituting the present invention together with a prism sheet is shown in FIG.

The backlight unit is composed of a reflective sheet 104, a light guide plate 105, a Quantum Dot Sheet, and a backlight unit 103. The backlight unit 103 includes an LCD panel 102 and a backlight unit 103, A first prism sheet 107, a second prism sheet 108, and a diffusion sheet 109 serving as a protective sheet.

Typically, the Quantum dot sheet is positioned below the prism sheet and is designed so that total reflection light reacts with quantum dot to cause color change.

FIG. 2 shows a typical structure of a barrier film used in a Quantum dot sheet.

The barrier film is a film that functions to minimize penetration of oxygen and moisture, and is a structure in which an organic material coating and an inorganic material thin layer coating are commonly used.

As shown in FIG. 2, a base coating layer 202 is formed on the base film 201 of the barrier film 200, a transparent inorganic thin film coating layer 203 is formed on the base coating layer, and a protective coating layer (204) are formed.

The base coating layer 202 and the protective coating layer 204 usually coat an optically transparent UV curable polymer resin which is cured by ultraviolet rays.

(1.46), Al2O3 (1.7), TiO2 (2.45), Ta2O5 (2.2), and ZrO2 (2.05) as a transparent thin film such as a metal oxide film or a metal fluoride film. ), HfO2 (2.0), Nb2O5 (2.33), Si3N4 (2.02), and MgF2 (1.38) can be coated with a single layer by sputtering, E Beam Evaporation or PECVD, May be coated with several layers.

3 shows a typical structure of a Quantum dot sheet.

The quantum dot sheet 300 has a base coating layer 202 formed on the base film 201 and a transparent inorganic thin film coating layer 203 formed on the base coating layer and a protective coating layer 204 for protecting the inorganic thin coating layer. A quantum dot layer 301 is formed on the upper barrier film 200-1 and a base coating layer 202 is formed on the base film 201. The quantum dot layer 301 is formed on the base film 201, And a lower barrier film 200-2 on which a transparent inorganic thin film coating layer 203 is formed on the coating layer and a protective coating layer 204 for protecting the inorganic thin film coating layer.

The Quantum dot layer consists of a Quantum dot material and a transparent polymer resin.

FIG. 4 shows a structure in which a prism is formed on a Quantum dot sheet.

A prism 401 structure made of a transparent UV curable resin is formed on the base film 201 of the upper barrier film 200-1 of the Quantum dot sheet 300. [

This prism structure has a function of condensing upward the same light as the prism sheet of the BEF (Brightness Enhancement Film) function used in a general LCD backlight,

In a typical structure of a prism film, light is incident on a film having a refractive index of usually 1.5 or more in air having a refractive index of 1, and upward refraction occurs, and a second upward refraction occurs while passing through the prism structure.

This optical path is shown in Fig.

As shown in the drawing, light is incident at a certain angle in air having a refractive index of 1 at a certain angle (501), light is incident on a film having a refractive index of usually 1.5 or more, upward refraction occurs (502) (503) where the car upward refraction occurs.

4, the refractive indexes of the base film 201, the base coating layer 202, the protective coating layer 204, and the quantum dot layer 301 are not greatly different from each other, The upward refraction does not occur at the interface of the film.

A simple conceptual diagram thereof is shown in Fig.

As shown, light is incident at a constant angle (501) in air with a refractive index close to 1, upward refraction occurs (502) with light incident on a film having a refractive index of typically at least 1.5, and this light again passes through the quantum dot layer . (503) where the second upward refraction occurs again through the prism structure.

However, in the Quantum dot layer, light is scattered to become a light diffusion (603), and the diffused light does not greatly differ in refractive index from the quantum dot layer, the protective coating layer, the base layer, or the base film. The upward refraction is less likely to occur in the path (604) and the light collection efficiency is lowered.

In this figure, the optical path incident on the base film in the quantum dot layer is shown as being completely unchanged. However, in reality, the optical path changes are not finely changed so long as the difference in refractive index between the quantum dot layer, So that the optical path is not largely changed.

Accordingly, in the present invention, light scattering is formed while increasing the difference in refractive index between the protective coating layer and the base coating layer while increasing the difference in refractive index between the protective coating layer and the base coating layer, thereby enhancing the light focusing effect by increasing the optical path incident on the base film.

Its structure is shown in Fig.

A base coating layer 202 is formed on the base film 201 of the Quantum Dot sheet 300 and a transparent inorganic thin film coating layer 203 is formed on the base coating layer and a protective coating layer 204 is formed on the inorganic thin coating layer. A quantum dot layer 301 is formed on the upper barrier film 200-1 and a base coating layer 202 is formed on the base film 201. The quantum dot layer 301 is formed on the base film 201, And a lower barrier film 200-2 in which a transparent inorganic thin film coating layer 203 is formed on the coating layer and a protective coating layer 204 for protecting the inorganic thin film coating layer is formed on the coating layer, And a prism 401 structure made of a transparent UV curable resin is formed on the base film 201 of the upper barrier film 200-1. (Low Refractive Index Powders) 202-1 and 204-1 are dispersed in the layer 202 to the protective coating layer 204. [

 The base coating layer and the protective coating layer, which are usually made of a transparent UV curable resin, are made of a material having a refractive index of between 1.4 and 1.5, and are made by mixing low refractive index particles, for example NgF2 particles, Thereby reducing the refractive index and scattering the light so as to form a structure capable of refracting the light path that is incident on the base film having a refractive index of 1.5 to 1.7.

Accordingly, the structure of the barrier film according to the present invention is characterized in that a base coating layer 202 is formed on the base film 201, a transparent inorganic thin film coating layer 203 is formed on the base coating layer, In the structure in which the coating layer 204 is formed, the low refractive index particles are dispersed in the base coating layer, the protective coating layer, or one layer.

When MgF2 particles are used, particles having a particle size between 0.01 micrometer and 1 micrometer are usually used. Since the refractive index is around 1.38, when the coating is applied to the base coating layer or the protective coating layer, And the scattering effect is caused by the refractive index difference with the transparent ultraviolet ray hardening resin.

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, on the contrary, It will be understood that the present invention can be changed.

101: LCD display 102: LCD panel
103; Backlight unit 104: reflective sheet
105: light guide plate 106: Quantum dot sheet
107: first prism sheet 108: second prism sheet
109: diffusion sheet 200: barrier film
201: base film 202: base coating layer
203: inorganic thin film coating layer 204: protective coating layer
300: Quantum Dot Sheet 200-1: Upper Barrier Film
200-2: lower barrier film 401: prism
501: in-air optical path 502: optical path in film 503: optical path after prism
202-1 and 204-1: low refractive index particles

Claims (3)

In an optical structure having a prism sheet function of a Quantum Dot Sheet used for a backlight of a liquid crystal display,
A base coating layer 202 is formed on the base film 201 of the Quantum Dot sheet 300 and a transparent inorganic thin film coating layer 203 is formed on the base coating layer and a protective coating layer 204 is formed on the inorganic thin coating layer. A quantum dot layer 301 is formed on the upper barrier film 200-1 and a base coating layer 202 is formed on the base film 201. The quantum dot layer 301 is formed on the base film 201, And a lower barrier film 200-2 in which a transparent inorganic thin film coating layer 203 is formed on the coating layer and a protective coating layer 204 for protecting the inorganic thin film coating layer is formed on the coating layer, And a prism 401 structure made of a transparent UV curable resin is formed on the base film 201 of the upper barrier film 200-1. (202) to protect the coating layer 204, the organic material to inorganic material particles of low refractive index (Low Refractive Index Powder) Quantum Dot seat of the liquid crystal display back light, characterized in that the dispersion (202-1, 204-1).
As the structure of the structure of the barrier film,
A base coating layer 202 is formed on the base film 201 and a transparent inorganic thin film coating layer 203 is formed on the base coating layer and a protective coating layer 204 is formed on the inorganic thin coating layer, Wherein the low refractive index particles are dispersed in one or both of the protective coating layer and the protective coating layer.
The method of claim 2,
And the low refractive index particles are MgF2 particles.

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