KR20050013893A - Multi layer color film - Google Patents

Abstract

PURPOSE: A multilayer color film is provided to replace a complicated fluorescent material or a color filter in a color display by illuminating a variety of colors by differentiating thicknesses at separate regions. CONSTITUTION: A multilayer color film is made by laminating two media having diffraction indices different from each other. The multilayer film has different thicknesses at separate regions(7-2,7-3,7-4) such that a specific wavelength is obtained at the separate regions. The separate regions represent a red region, a green region, and a blue region.

Description

Multi-layered color film {Multi layer color film}

The present invention relates to an optical film that obtains light in different wavelength bands, and more particularly, to transmit or reflect light in specific wavelength bands in different areas by using a multilayer film in which two materials having different refractive indices are alternately stacked. It relates to a multilayer color film designed to be able to. The multilayer color film that can simultaneously obtain light of several wavelength bands can be applied to various fields such as a display.

Conventionally, multilayer thin films in which a medium having different refractive indices are alternately deposited in a vacuum are used as a method for reflecting or transmitting light of a specific wavelength band. However, in manufacturing a multilayer color thin film using a multilayer thin film, a multilayer thin film must be formed under different conditions, and a specific region must be etched through a photolithography process after depositing each condition. In the case of the conventional multilayer film, only a specific wavelength or white light can be reflected or transmitted, thereby limiting the application field.

In the conventional color display, a color image is realized by forming three subpixels of red, green, and blue in one pixel as a method for obtaining a color image. That is, the case of using the color filter which selectively filters red, green, and blue light from a white light source, and the method of emitting a fluorescent substance from an electron or ultraviolet energy were mainly used. The color filter and the phosphor used to obtain the color were formed by applying red, green, and blue different materials on the display substrate three times, and then photo-etching them.

As an example, Fig. 1 shows a cross-sectional view of a color filter composed of red, green, and blue pigments in a conventional color display. In Fig. 1, (1-1) shows a color filter substrate, and (1-2), (1-3), and (1-4) are red, green, and blue colors formed to separate colors from white light, respectively. Pigments. And (1-5) represent one pixel. In order to form a color filter in a conventional color liquid crystal display, a pigment coating and a pattern shape process should be repeatedly performed for each of red, green, and blue. The description of the general manufacturing process for the color filter is omitted here. In FIG. 1, the color filter pigment receives light from white light, passes through the corresponding color, and absorbs the remaining color light. That is, in the case of a red pigment, red light passes from white light and green light and blue light are absorbed. In other words, the light efficiency of the color filter is theoretically only 33.3% and the remaining 67.7% of light is absorbed.

According to the present invention, a multilayer film made by alternately stacking two transparent materials n _L and n _H having different refractive indices is multi-layered in which a specific light can be transmitted and reflected in different regions by controlling the thickness of the multilayer film in different regions. The purpose is to provide a film.

In particular, it is an object of the present invention to replace the existing phosphor or color filter process by manufacturing a color display device using a multilayer film devised in the present invention.

Multi-layered color film according to the present invention uses the principle that can pass or reflect light of a specific wavelength by controlling the thickness of the transparent material having different refractive index. That is, multilayer films having different thicknesses are formed in the lower pixels of one pixel, respectively, to selectively transmit or reflect red, green, and blue light from white light to form a multilayer color film. Whereas color filters or phosphors absorb 67.7% of light from a white light source, multilayer color films transmit or reflect light of a particular wavelength (if red) from the white light source, and reflect the remaining light (green and blue light). Alternatively, there is a characteristic that can transmit these light due to the property to transmit.

The technical principle of the present invention is as follows. FIG. 2 is a schematic diagram of electric field components of reflected light and transmitted light when light is incident on a medium having a refractive index of n _T and a film having a refractive index of n ₁ and a thickness of l in the region n ₀ .

At this time, the electric field component of the transmitted light _(T E), the electric field component of the reflected light (E _0), can be expressed the relationship of the incident light of the electric field component (E ₀₎ to the matrix as follows.

A simple expression of (Equation-1) is as follows.

here, Is the reflectivity, Is the transmittance and M is the following determinant.

When the multilayer film of N layer is formed, (Formula-2) can be represented as follows.

Here, the matrix M can be expressed as follows.

In this case, the reflectivity and transmittance of the incident light can be written as follows from Equation-4 and Equation-5.

The qualitatively derived matrix (Equation-5) can obtain the conditions of high permeability and high reflection multilayer film under the following special cases.

3 is the thickness The case where a 2N layer of phosphorus film is formed is shown. Thickness In (Equation-3) ego Becomes Therefore, M of (equation-5) can be represented as follows.

Substituting the matrix element of (Equation-8) into (Equation-6) to obtain the reflectance (R) is as follows (when n ₀ = n _T ):

In the case where n _H > n _L , when the multilayer film is formed, when N → ∞, R = 1 to obtain a high reflective film.

4 is a film block diagram for selective transmission. That is, the refractive index is n _L , n _H , n _L

The thickness of each film In the case of forming this, the matrix M can be expressed as follows.

In (Equation 10), the reflectance r and the transmittance t are as follows.

Where n ₀ = n _T , the reflectance is zero and the transmittance is one. That is, a laminated transmission film is obtained.

When the thin film of FIG. 4 is constituted as follows, a highly transmissive multilayer film can be obtained. That is, FIG. 5 is a schematic diagram of a high-permeability multilayer film designed for high transmission of light of a specific wavelength from white light.

That is, two optical media with different refractive indices When stacked as shown in Fig. 5 so as to be, the determinant M is expressed as follows.

That is, the same result as in Equation 10 can be obtained, and light of a specific wavelength having high purity can be transmitted. Here again, when n ₀ = n _T , the reflectance becomes 0 and the transmittance becomes 1. When the multilayer film is formed as described above, specific light, that is, red, green, and blue light may be reflected or transmitted from white light, and thus may be applied to pixels of a display. In addition, when the laminated film of FIG. 4 is repeatedly laminated, a high-permeability multilayer film may also be obtained, and a description thereof will be omitted.

1 is a cross-sectional view of a color filter according to a conventional structure

6 is a cross-sectional view of a multi-layer transparent film according to the present invention

7 is a cross-sectional view of a multilayer reflective film according to the present invention.

8 is a method of forming a multilayer film of different thickness according to the present invention

* Explanation of symbols for the main parts of the drawings

(1-1): Substrate (1-2): Red Pigment (1-3): Green Pigment

(1-4): Blue pigment (1-5): One pixel (6-1): Substrate

(6-2): multilayer red permeable film (6-3): multilayer green permeable film

(6-4): multilayer blue transparent film (6-5): one pixel

(7-1) Substrate (7-2) Multilayer Red Reflective Film

(7-3) Multilayer Green Reflective Film (7-4) Multilayer Blue Reflective Film

(7-5) Molds for Forming Multi-Layered Films of Different Thicknesses with Pixels (8-1)

(8-2) Roller for Pressing the Multi-Layered Film

(8-3) A multilayer film laminated at two different refractive indices

(8-4) Multilayer Blue Transmissive or Reflective Film

(8-5) Multilayer Green Transmissive or Reflective Film

(8-6) Multilayer Red Transmissive or Reflective Film

6 is a cross-sectional view of a multilayer transmissive color film having different thicknesses devised in the present invention. In FIG. 6, (6-1) shows a substrate on which a multilayer film is formed, and (6-2), (6-3), and (6-4) show red, green, and blue light from white light as shown in FIG. It represents the multilayer film formed in order to filter. That is, Fig. 6 (6-2) shows a multilayer red transparent film, (6-3) shows a multilayer green transparent film, and (6-4) shows a multilayer blue transparent film. The films of different thicknesses transmit specific light and reflect the remaining light. That is, in the multi-layered green transmissive film region G, which is (6-3), the green light G is transmitted from the white light W, and the remaining red light R and blue light B are reflected. (6-5) is a case where the multilayer transmissive films of a specific thickness are arranged adjacent to each other, and can also be applied to the pixels of the transmissive display.

7 is a cross-sectional view of a multilayer reflective film having different thicknesses devised in the present invention, and is a cross-sectional view showing reflection of specific light for each region. In FIG. 7, (7-1) shows a substrate on which a multilayer film is formed, and (7-2), (7-3), and (7-4) show red, green, and blue light from white light as shown in FIG. The multilayer film area | region formed in order to reflect this is shown. 7 (7-2) shows a multilayer red reflective film, (7-3) shows a multilayer green reflective film, and (7-4) shows a multilayer blue reflective film. Each sub-pixel reflects specific light and transmits the remaining light. That is, in the multilayer green reflective film region G of (7-3), the green light G is reflected from the white light W, and the remaining red light R and blue light B are transmitted. (7-5) is a case where the multilayer transmissive films of a specific thickness are arranged adjacent to each other, and can also be applied to the pixels of the reflective display.

8 is an example showing the thickness forming method of the multilayer film according to the present invention. That is, a method of forming multilayer films having different thicknesses in order to obtain respective red light, green light, and blue light from white light using the conditions of FIG. 5 (the condition of FIG. 3 is applied in the case of reflective type, and the description is omitted). It is shown. (8-1) is a metal mold | die (or cylindrical roller) used in order to determine the thickness of a multilayer film. That is, the thickness is formed so that the thickness of one layer of the multilayer transmissive film becomes the conditions as shown in FIG. 3 and FIG. 5 with respect to the wavelengths of the red, green, and blue light. (8-2) represents the roller used for obtaining the thickness of a multilayer film. (8-3) shows a red light multilayer film laminated as shown in Fig. 5 at two different refractive indices. (In order to easily explain the principle of the technique, the structure of the initial multilayer film is assumed to be a multilayer red transmissive film.) Blue, In order to obtain a multi-layer filter film of green light, a depth 8-4 of a hole of blue light λ _B and a depth 8-5 of a hole of green light λ _G are formed in a mold of (8-1), and a red light The depth of the hole is formed by the thickness of the multilayer red transparent film. In this state, when the multilayer red filter film is pressed with a roller (8-2), the thickness of the film is reduced in the areas (8-4) and (8-5) to form a multilayer blue transparent film and a multilayer green transparent film, respectively. The multilayer red permeable film 8-6 maintains the initial thickness.

As described above, the present invention can design a different color color on the existing multilayer film, which can be widely applied in the field of industrial design, and in particular, a color display can be implemented using a multilayer film instead of a color filter or phosphor. Thus, it can replace the existing complicated phosphor or color filter process.

When the multilayer film of the present invention is used as a transmissive display, the reflected light can be recycled to achieve a display with high brightness.

Claims (11)

In a multilayer film in which two media having different refractive indices are formed in a laminated structure, the thickness of the multilayer film is formed differently in each region (eg, region 1, region 2, region 3, ...), Multi-layer film to obtain a specific wavelength (Ae, λ ₁ , λ ₂ , λ ₃ , ...) In a multilayer film in which two media having different refractive indices are formed in a laminated structure, the thickness of the multilayer film is formed differently for each region (for example, red region, green region, blue region, etc.), and in each region, specific light Multilayer color films (e.g. red, green, blue, etc.) In a multilayer transmissive film in which two media having different refractive indices are formed in a laminated structure, the thickness of the multilayer film is formed differently for each region (for example, red region, green region, blue region, etc.), and in each thickness region, Multi-layer color transmissive film to get specific light (e.g. red, green, blue, etc.) 4. The color display device according to claim 3, wherein a multi-layered multilayer film having a different thickness is formed on a lower pixel of one pixel of the display, respectively, in a red transmissive multilayer film, a green transmissive multilayer film, and a blue transmissive multilayer film. In a multilayer reflective film in which two media having different refractive indices are formed in a laminated structure, the thickness of the multilayer film is formed differently for each region (for example, red region, green region, blue region, etc.), and in each thickness region, Multi-layered color reflective film to get specific light (e.g. red, green, blue, etc.) 6. The color display device according to claim 5, wherein a multilayer reflective film having a different thickness and a red reflective multilayer film, a green reflective multilayer film, and a blue reflective multilayer film are respectively formed on the lower pixels of one pixel of the display. In a multilayer film in which two media having different refractive indices are formed in a laminated structure, a multilayer color film that realizes color by controlling the thickness to form shapes, drawings, and the like The thickness of two media with different refractive indices Multi-layer reflective color film formed by stacking 2N times to form a multilayer reflective film, and having different thicknesses in order to obtain a specific wavelength for each region. Thickness of the refractive index medium ( n _H ) among the two media having different refractive indices Medium with small refractive index ( n _L ) Firstly placed on both sides with a thickness, and again a medium ( n _H ) having a large refractive index In the secondary position to form a multi-layer transmission process repeatedly to film on both sides to a thickness _L n, to form a different thickness in order to transmit light of a specific wavelength by the transmissive areas multilayer color film After forming holes in a mold or roller at different depths (e.g., d ₁ , d ₂ , d ₃ ...), the different thicknesses (e.g., d ₁ , d ₂ , film production of d ₃ ...) In a multilayer film in which two media having different refractive indices are formed in a laminated structure, the multilayer film produced by compressing the thickness of the film