KR101268074B1 - Multilayer optical sheet module - Google Patents

Abstract

PURPOSE: A multi-layer optical sheet module is provided to improve adhesion quality and durability by increasing an adhesion area in adhesion of an optical sheet and to minimize reduction of illuminance by refraction of light in the adhesion area. CONSTITUTION: A multi-layer optical sheet module includes an upper optical sheet(410) having a first structure pattern(412) protruded upward, a lower optical sheet(420) having a second structure pattern(422) protruded to the upper optical film side while being arranged in a laminate type in a lower part of the upper optical sheet and an adhesive layer arranged in the upper optical sheet and the lower optical sheet. The second structure pattern has a light transfer unit in which a cross-section decreases as it goes to the upper part and a reclamation unit in which a part is reclaimed by the adhesive layer by being continuously connected to the upper part of the light transfer unit and length of the circumference of the cross-section in which the reclamation unit and the adhesive layer contact with each other has a greater than an edge of an orbit of the virtual cross-section formed by extent of the light transfer unit to the upper part.

Description

Multilayer Optical Sheet Module

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to a multilayer optical sheet module, and more particularly, to a multilayer optical sheet module having improved durability by increasing bonding area and improving luminance.

The liquid crystal display device is a display device used for a notebook computer, a personal computer, a smart phone, or a TV, and its characteristics are improving each year as the demand for a liquid crystal display device increases.

A liquid crystal panel of a liquid crystal display device which is a non-light emitting device requires a backlight unit because of its structure. The backlight unit is composed of various optical systems. In addition, the backlight unit uses a periodic array of optical films to improve brightness.

1 is a view schematically showing a configuration of a liquid crystal display device which has been conventionally developed.

As shown in FIG. 1, the backlight unit 10 includes a light emitting source 1, a reflecting plate 2, a light guide plate 3, a diffusion sheet 4, a first optical sheet 5, and a second optical sheet 6. And a protective sheet 7.

The light emitting source 1 generates visible light. As the light emitting source 1, a light emitting diode (LED) and a cold cathode fluorescent lamp (CCFL) may be selectively used.

Light emitted from the light emitting source 1 is incident on the light guide plate 3 to cause total reflection inside the light guide plate 3, and light incident on the surface of the light guide plate 3 at an angle of incidence smaller than the critical angle is total reflection. Because it is not transmitted, it is emitted to the upper side and the lower side.

At this time, the reflection plate 2 reflects the light emitted downward and re-enters the light guide plate 3 to improve the light efficiency.

The diffusion sheet 4 diffuses the light emitted through the upper surface of the light guide plate 3 to uniform the brightness and widen the viewing angle. The light passing through the diffusion sheet 4 has a lower front emission brightness. .

The first optical sheet 5 is composed of a substrate portion 5b and a structured pattern 5a, and refracts light incident from the diffusion sheet 4 to be first focused and emitted so as to be vertically incident.

The structured pattern 5a is integrally formed on the upper surface of the substrate portion 5b and has a structure for refracting and outputting light incident through the substrate portion 5b in the vertical direction.

The structured pattern is generally formed so that the cross section has a triangular shape, and the vertex angle of the triangular shape is generally made around 90 degrees.

The second optical sheet 6 has the same shape as the first optical sheet 5 and condenses and emits secondary light to enhance the brightness of the light firstly condensed by the first optical sheet 5. In this case, the first optical sheet 5 and the second optical sheet 6 may have different periods, heights, and refractive indexes as necessary.

Here, the first optical sheet 5 and the second optical sheet 6 extends the extension direction of the structured pattern of the first optical sheet 5 and the structured patterns of the second optical sheet 6 in order to further increase the brightness. The directions are arranged to cross at right angles to each other, and the first optical sheet 5 is integrally bonded through the adhesive layer 6a applied to the lower surface of the base portion of the second optical sheet 6.

The protective sheet 7 is attached to the upper surface to prevent surface damage of the second optical sheet 6.

When the upper and lower layers of the first optical sheet 5 are laminated and bonded to each other by the adhesive layer 6a applied to the lower surface of the second optical sheet 6, the structured pattern 5a of the first optical sheet 5 is bonded. As shown in Fig. 1B, a part of the apex portion 5c is embedded in the adhesive layer 6a and is integrally bonded while contacting.

However, when the bonding strength is determined by the area where the apex 5c is buried in the adhesive layer 6a and bonded, there is a limit in the area of the apex 5c that is embedded in the adhesive layer 6c. Accordingly, there is a problem in that the bonding strength is lowered.

Bonding strength between the first optical sheet 5 and the second optical sheet 6 is lowered to generate a peeling phenomenon in which the first optical sheet 5 and the second optical sheet 6 are separated from each other. There was a problem of lowering.

An object of the present invention is to solve the problems of the conventional multi-layer optical sheet module, to increase the bonding area in the bonding of a pair of optical sheet to improve the bonding quality and durability as well as the refraction of light in the bonding region It is to provide a multilayer optical sheet module that can minimize the reduction of the brightness through.

According to an aspect of the present invention in order to solve the above problems, an upper optical sheet having a first structured pattern protruding upward, provided in a laminated form on the lower portion of the upper optical sheet, protruding toward the upper optical sheet side A lower optical sheet having a two-structured pattern and an adhesive layer provided between the upper optical sheet and the lower optical sheet, wherein the second structured pattern includes a light transmitting part and an upper part of the light transmitting part having a smaller cross-sectional area toward the upper part; It has a buried portion that is continuously connected to at least a portion of the buried in the adhesive layer, the circumferential length of the cross section in which the buried portion is in contact with the adhesive layer is less than the circumference of the trajectory of the virtual cross section formed by extending the upper portion of the light transmitting portion has a continuous slope Is formed larger.

In addition, the second structured pattern may be formed such that the derivative of the cross section trajectory has at least one or more discontinuities between the lowermost and the uppermost.

In addition, the discontinuous point may be located at the boundary point of the cross section trajectory of the buried portion and the light transmitting portion.

In addition, the light transmitting unit may be characterized in that the trajectory of the cross section is made of a straight line.

In addition, the buried portion may be characterized in that the trajectory of the cross section in contact with the adhesive layer is made of a straight line.

Here, the buried portion may be characterized in that it comprises a pair of extending surface extending from the light transmitting portion and the connection surface connecting between the pair of the extension surface.

In addition, the buried portion may be provided with a pair of extension surfaces extending upwardly inclined upward from the light transmitting portion, and the upper ends of the extension surfaces may meet each other.

In addition, the buried portion may be characterized in that the uppermost portion is in contact with the lower portion of the upper optical sheet.

In addition, the second structured pattern may have the same cross-sectional shape and may extend in a transverse direction.

Here, the upper optical sheet and the lower optical sheet may be arranged such that the extending direction of the first structured pattern and the extending direction of the second structured pattern cross each other, and the extending direction of the first structured pattern is the second structured pattern. It may be characterized in that it perpendicularly crosses the extending direction of the.

In addition, it may be characterized in that it further comprises a reflective polarizing film which is arranged in a stacked form with the lower optical sheet or the upper optical sheet and selectively transmits light according to the wavelength of light transmitted from the lower.

Here, the reflective polarizing film may be stacked between the upper optical sheet and the lower optical sheet, it may be characterized by being laminated on the upper optical sheet.

According to another aspect of the present invention to solve the above problems, an upper optical sheet having a first structured pattern protruding to the upper is provided on the lower portion of the upper optical sheet, the second structured pattern protruding toward the upper optical sheet The branch includes a lower optical sheet and an adhesive layer formed between the upper optical sheet and the lower optical sheet, wherein the second structured pattern has one or more discontinuities in which the cross-sectional area becomes smaller toward the top and the slope discontinuously increases from the lowermost to the uppermost. Has a point.

In addition, the second structured pattern may be characterized in that the refractive index of the formed material is greater than the refractive index of the adhesive layer.

In addition, the second structured pattern may include a light transmitting part having a predetermined slope and a buried part extending to an upper portion of the light transmitting part without being embedded in the adhesive layer at a lower part and at least partially embedded in the adhesive layer. have.

In addition, the buried portion may be composed of at least two or more characterized in that it has an extending surface extending in the upper direction.

In addition, the buried portion is composed of a pair has an extension surface extending in the upper direction and may be characterized in that the cross section by the extension surface to form a triangular shape.

In addition, the buried portion may be formed to have a height equal to or smaller than the thickness of the adhesive layer.

In addition, it may be characterized in that it further comprises a reflective polarizing film which is arranged in a stacked form with the lower optical sheet or the upper optical sheet and selectively transmits light according to the wavelength of light transmitted from the lower.

The reflective polarizing film may be stacked between the upper optical sheet and the lower optical sheet, and may be stacked on the upper optical sheet.

In addition, the second structured pattern may have the same cross-sectional shape and extend in a lateral direction.

In addition, the upper optical sheet and the lower optical sheet may be arranged so that the extending direction of the first structured pattern and the extending direction of the second structured pattern intersect.

The extending direction of the first structured pattern may be perpendicular to the extending direction of the second structured pattern.

According to another aspect of the present invention to solve the above problems, an upper optical sheet having a first structured pattern protruding upward, the second structure provided on the lower portion of the upper optical sheet, protruding toward the upper optical sheet And a lower optical sheet having a pattern and an adhesive layer formed between the upper optical sheet and the lower optical sheet, wherein the second structured pattern has a shape in which a cross-sectional area decreases toward an upper portion, and has a straight cross section. And it has a straight buried portion connected inclined upward from the light transmitting portion.

In addition, the buried portion may be provided with a pair of extension surfaces extending upwardly upward from the light transmission unit, the upper end portion of the extension surface may be characterized in that meet each other.

In addition, the buried portion may be characterized in that the cross section is formed in a triangular shape.

In addition, it may be characterized in that it further comprises a reflective polarizing film which is arranged in a stacked form with the lower optical sheet or the upper optical sheet and selectively transmits light according to the wavelength of light transmitted from the lower.

In addition, the reflective polarizing film may be characterized by being laminated between the upper optical sheet and the lower optical sheet.

In addition, the reflective polarizing film may be characterized in that it is provided laminated on the upper optical sheet.

According to another aspect of the present invention to solve the above problems, the upper optical sheet having a first structured pattern projecting to the upper, provided in a laminated form on the lower portion of the upper optical sheet, protruding toward the upper optical sheet And a lower optical sheet having a second structured pattern composed of a plurality of patterns, and an adhesive layer provided between the upper optical sheet and the lower optical sheet, wherein the second structured pattern has a cross-sectional area of a portion of the plurality of patterns toward an upper portion thereof. It is small and formed to have one or more discontinuities with a discontinuous increase in slope between the lowest and the highest.

In addition, the second structured pattern may be characterized in that a distance from the top to the bottom is longer than a portion of the plurality of patterns adjacent to each other.

In addition, the second structured pattern may be characterized in that the patterns of different shapes are repeatedly arranged.

In addition, the second structured pattern may be characterized in that it has a light-transmitting portion that is partially cross-sectional area as the upper portion of the pattern and the buried portion is continuously connected to the upper portion of the light-transmitting portion at least partially embedded in the adhesive layer have.

In addition, the circumferential length of the cross section where the buried portion is in contact with the adhesive layer may be formed to be larger than the circumference of the trajectory of the virtual cross section formed by the light transmitting portion extending upward with a continuous slope.

In addition, the second structured pattern may be characterized in that the refractive index of the formed material is greater than the refractive index of the adhesive layer.

In addition, it may be characterized in that it further comprises a reflective polarizing film which is arranged in a stacked form with the lower optical sheet or the upper optical sheet and selectively transmits light according to the wavelength of light transmitted from the lower.

In addition, the reflective polarizing film may be characterized by being laminated between the upper optical sheet and the lower optical sheet.

In addition, the reflective polarizing film may be characterized in that it is provided laminated on the upper optical sheet.

In addition, the second structured pattern may have the same cross-sectional shape and may extend in a transverse direction.

In addition, the upper optical sheet and the lower optical sheet may be arranged so that the extending direction of the first structured pattern and the extending direction of the second structured pattern intersect.

In order to solve the above problems, the present invention has the following effects.

First, the present invention optimizes the structured pattern embedded in the adhesive layer provided between the upper optical sheet and the lower optical sheet to increase the bonding area with the adhesive layer, thereby maximizing the bonding area between the buried portion and the adhesive layer. This has the effect of improving the durability and consequently improving the durability of the optical sheet module.

In particular, the present invention is connected to the light transmitting portion and the buried portion constituting the structured pattern provided on the lower optical sheet in a discontinuous form, it is possible to maximize the bonding area in contact with the adhesive layer while maintaining a constant thickness of the adhesive layer. .

Second, the buried portion is inclined upwardly to have a larger inclination angle than the inclination angle of the light transmitting part and is formed in a triangular shape, thereby condensing light incident on the inside of the buried portion having at least a portion of the adhesive layer embedded therein and condensing it upwards. , The brightness of the optical sheet can be increased.

FIG. 1 schematically shows the structure of a conventional liquid crystal display device; FIG.
2 is a perspective view showing a schematic configuration of a multilayer optical sheet module according to an embodiment of the present invention;
3 is a view showing the shape of the second structured pattern in the optical sheet module of FIG.
4 is a cross-sectional view illustrating a state in which an upper optical sheet and a lower optical sheet of FIG. 2 are combined;
FIG. 5 is a diagram illustrating a cross section locus and a derivative of the cross section locus of the second structured pattern of FIG. 2; FIG.
FIG. 6 is a view showing a comparison of a buried portion embedded into an adhesive layer in the second structured pattern of FIG. 2; FIG.
FIG. 7 is a view illustrating a difference according to a length of a circumference of a second structured pattern in contact with an adhesive layer in the adhesive layer of FIG. 6;
FIG. 8 is a view illustrating a comparison of a light transmitting part not embedded into an adhesive layer in the second structured pattern of FIG. 2; FIG.
9 is a view showing a difference according to the transverse length of the light transmitting part of FIG. 8;
10 is a view showing the refraction of light passing through the optical sheet in the embodiment of FIG.
FIG. 11 is a view illustrating a bonded state in a state where the thickness of the adhesive layer is thicker than the height of the buried portion in the embodiment of FIG. 2; FIG.
12 shows the position of the point at which the derivative of the cross section trajectory is discontinuous in the second structured pattern according to the thickness of the adhesive layer of FIG. 2;
FIG. 13 is a view showing an embodiment in which the cross section trajectory of the light transmitting unit is straight in the second structured pattern of FIG. 2; FIG.
FIG. 14 is a view illustrating an embodiment in which the cross section trajectory of the light transmitting unit is not a straight line in the second structured pattern of FIG. 2; FIG.
FIG. 15 illustrates an embodiment in which the derivative of the cross section trajectory of the second structured pattern of FIG. 2 does not have a discontinuity point; FIG.
FIG. 16 is a view illustrating a configuration in which the second structured pattern has a non-uniform pattern in the optical sheet module of FIG. 2; FIG.
17 is an exploded perspective view showing a state in which the reflective polarizing film is further included in the optical sheet module of FIG. 2; And
18 is a view illustrating a state in which light is transmitted or reflected by the reflective polarizing film of FIG. 17.

A preferred embodiment of the multilayer optical sheet module according to the present invention configured as described above will be described with reference to the accompanying drawings. However, it is not intended to limit the invention to any particular form but to facilitate a more thorough understanding of the present invention.

In the following description of the present embodiment, the same components are denoted by the same reference numerals and symbols, and further description thereof will be omitted.

First, referring to FIGS. 2 and 3, a schematic configuration of a multilayer optical sheet module according to an exemplary embodiment of the present invention will be described.

2 is a perspective view illustrating a schematic configuration of a multilayer optical sheet module according to an exemplary embodiment of the present invention, and FIG. 3 is a view illustrating a shape of a second structured pattern in the optical sheet module of FIG. 2.

The multilayer optical sheet module according to the present invention may be applied to various fields for changing the path of light, and in this embodiment, a form applied to the liquid crystal display device will be described as an example.

As shown in the figure, a back light unit (BLU) for providing light to the liquid crystal panel should be provided. The backlight unit is largely composed of a light source 100, a light guide plate 200, a diffusion sheet 300, and a multilayer optical sheet module 400.

The light source 100 generally includes a light emitter that emits light, and emits light from the side of the light guide plate 200 to transmit light toward the light guide plate 200.

The light guide plate 200 reflects and scatters the light emitted from the light source 100 and transmits the light toward the diffusion sheet 300. The diffusion sheet 300 is disposed above the light guide plate 200 and diffuses the light transmitted from the light guide plate 200 to spread the light evenly and transfers the light upwardly.

In addition, the multilayer optical sheet module 400 collects and transfers the light transmitted to the upper portion of the diffusion sheet 300. The multilayer optical sheet module 400 is generally composed of a pair of an upper optical sheet 410 and a lower optical sheet 420.

Light is condensed and refracted in a direction orthogonal to the plane of the optical sheet module 400 by the structured pattern formed on the upper optical sheet 410 and the lower optical sheet 420 configured as described above.

Looking at the multilayer optical sheet module 400 in more detail, the optical sheet module 400 is composed of the upper optical sheet 410, the lower optical sheet 420 and the adhesive layer 430.

The upper optical sheet 410 has a first structured pattern 412 formed to protrude upward and to have a smaller cross sectional area toward the upper surface.

The upper optical sheet 410 emits the light by refracting and condensing the light transmitted from the lower by the first structured pattern 412. In general, the first structured pattern 412 may be formed so that a triangular prism extends in one direction, and a plurality of first structured patterns 412 are arranged.

The adhesive layer 430 is provided below the upper optical sheet 410 and allows the lower optical sheet 420 and the upper optical sheet 410 to be bonded to each other. At this time, the adhesive layer 430 is preferably made of a material having a high light transmittance so as to transmit the light transmitted from the diffusion sheet 300.

The lower optical sheet 420 is disposed below the upper optical sheet 410 and has a second structured pattern 422 formed on an upper surface thereof.

The second structured pattern 422 is connected to the light transmitting part 422a having a smaller cross-sectional area toward the upper part and the buried part which is continuously connected to the light transmitting part 422a and at least partially embedded in the adhesive layer 430. 422b.

The light transmitting part 422a is not embedded in the adhesive layer 430 and is exposed to air therein to refract light transmitted from the diffusion sheet 300 to transmit the light upward.

The buried portion 422b is connected to an upper portion of the light transmitting portion 422a, and a circumference of a cross section trajectory in contact with the adhesive layer 430 is formed by extending the light transmitting portion 422a with a continuous slope. It is formed larger than the circumference of the trajectory T.

The buried portion 422b may be formed in various forms. In the present embodiment, the buried portion 422b includes a pair of extension surfaces S1 extending upwardly inclined upward from the light transmitting portion 422a. The upper ends of the extension surface S1 are formed to meet each other.

As shown in FIG. 3, the second structured pattern 422 including the buried portion 422b and the light transmitting portion 422a protrudes in an upper direction to decrease a cross sectional area toward an upper portion thereof, and an inclination of an upper portion thereof. It is formed to be inclined upwardly than the inclination of the lower portion.

Here, the trajectory of the cross section of the light transmitting unit 422a may be formed in a straight line, and the trace of the cross section contacting the adhesive layer 430 may be formed in a straight line. The buried portion 422b may have a triangular shape having a pair of the extension surfaces S1. However, the shape of the buried portion 422b is not limited, but selected to facilitate understanding of the configuration according to the embodiment of the present invention.

The upper optical sheet 410 and the lower optical sheet 420 configured as described above are formed with the first structured pattern 412 and the second structured pattern 422 having the same cross-sectional area and extending along the transverse direction. The extension direction of the first structured pattern 412 and the extension direction of the second structured pattern are bonded to each other.

In this case, various crossing angles may be applied to the extending direction of the first structured pattern 412 and the extending direction of the second structured pattern 422.

Next, the state in which the upper optical sheet 410 and the lower optical sheet 420 are bonded by the adhesive layer 430 will be described with reference to FIG. 4.

4 is a cross-sectional view illustrating a state in which the upper optical sheet 410 and the lower optical sheet 420 of FIG. 2 are combined.

As shown, the lower optical sheet 420 is bonded to the lower portion of the upper optical sheet 410 by the adhesive layer 430 and the buried portion 422b is embedded into the adhesive layer 430. The buried portion 422b may be formed such that an uppermost point is in contact with a lower surface of the upper optical sheet 410.

When the upper portion of the buried portion 422b comes into contact with the lower side of the upper optical sheet 410, the distance that the light incident and refracted by the buried portion 422b passes through the adhesive layer 430 is shortened. By the operation 430, a phenomenon in which the luminance is reduced can be minimized.

A state in which light is refracted in the buried portion 422b will be described later with reference to FIG. 10.

On the other hand, as shown in the buried portion 422b is buried in the adhesive layer 430 and the circumferential length of the cross section in contact with the adhesive layer 430 is formed by extending the light transmitting portion 422a has a continuous slope Is larger than the circumference of the virtual cross section trajectory T.

Thus, as the circumference of the buried portion 422b is larger than the circumference of the virtual cross-section trajectory T of the light transmitting portion 422a, the area in contact with the adhesive layer 430 becomes larger, and thus the upper optical Bonding quality of the sheet 410 and the lower optical sheet 420 is increased.

Next, the cross-sectional trajectory of the second structured pattern 422 will be described with reference to FIG. 5.

FIG. 5 is a diagram illustrating a cross section locus and a derivative of the cross section locus of the second structured pattern 422 of FIG. 2.

The second structured pattern 422 may be formed in various shapes, and the derivative of the cross section trajectory is formed to have at least one discontinuity point (P1, P2) at the lowermost and the uppermost.

As shown, the second structured pattern 422 is formed to protrude upward and to reduce the cross-sectional area toward the top. Here, the second structured pattern 422 protrudes upward and has an inclination inclined at a predetermined angle, and the cross-sectional area of the second structured pattern 422 is formed to be smaller and the inclination of the upper portion is inclined upwardly than the inclination of the lower portion.

At this time, the inclination of the upper and lower portions of the second structured pattern 422 is changed at the discontinuous points (P1, P2).

The discontinuous points P1 and P2 are points at which the derivative of the trajectory along the cross section of the second structured pattern 422 is discontinuous.

Looking at the cross-sectional trajectory derivative of the second structured pattern 422 shown in FIG. 5, it can be seen that discontinuities occur at points P1 and P2 without the graph uniformly running along the x-axis.

As described above, the second structured pattern 422 has a cross-sectional trajectory in a discontinuous shape, and thus the inclination and shape of the upper and lower portions are differently formed, and the buried portion 422b is embedded in the adhesive layer 430. The shape of the light transmitting unit 422a may be different.

Next, referring to FIGS. 6 and 7, the circumferential difference between the bonding points according to the shape of the buried portion 422b buried into the adhesive layer 430 is as follows.

FIG. 6 is a view illustrating a comparison between the buried portion 422b embedded in the adhesive layer 430 in the second structured pattern 422 of FIG. 2, and FIG. 7 illustrates a second structured pattern in the adhesive layer 430 of FIG. 6. 422 is a view showing a difference according to the length of the circumference of contact with the adhesive layer 430.

FIG. 6A is a view illustrating a state in which the second structured pattern 422 is bonded by the adhesive layer 430, and the second structured pattern 422 is the light transmission. The portion 422a and the inclination of the cross section trajectory are constituted by the buried portion 422b inclined upwardly than the inclination of the cross section trajectory of the light transmitting portion 422a so that the buried portion 422b is embedded into the adhesive layer 430. It is.

And (b) of FIG. 6 is configured to have a virtual cross section (T) formed by the buried portion 422b extends upward with a continuous slope of the light transmitting portion 422a, the buried portion ( A cross section trajectory of the light transmitting portion 422b and the light transmitting portion 422a is formed to have a uniform slope so that the buried portion 422b is embedded into the adhesive layer 430.

6A and 6B, although the buried portion 422b is embedded in the adhesive layer 430 having the same thickness d, as shown, the adhesive layer 430 and the buried portion ( It can be seen that the circumference of the cross section 422b) is larger in FIG. The larger the circumference of the cross section which is in contact with the adhesive layer 430, the more the bonding area is increased, thereby increasing the bonding quality.

In more detail, with reference to FIG. 7, the circumference of a cross section of the buried portion 422b of FIG. 6A and FIG. 6B that is in contact with the adhesive layer 430 having the same d thickness may be calculated. Specifically, the equation is as follows.

로 나타내며, 상기 광전달부(422a)의 경사각은

이고, 상기 매립부(422b)는 상기 광전달부(422a)보다

만큼 상향 경사지도록 형성되었기 때문에 상기 매립부(422b)의 경사각은

이다. 따라서 상기 매립부(422b)와 상기 접착층(430)이 접하는 지점의 길이는 아래와 같은 수학식을 통해서 구할 수 있다.First, in FIG. 6A, the cross-sectional locus length at the point where the buried portion 422b and the adhesive layer 430 are in contact

Indicated by the inclination angle of the light transmission unit 422a

The buried portion 422b is smaller than the light transmitting portion 422a.

Since it is formed to be inclined upwards, the inclination angle of the buried portion 422b is

to be. Therefore, the length of the contact point between the buried portion 422b and the adhesive layer 430 may be obtained through the following equation.

임을 알 수 있다. As shown in Equation 1, when the buried portion 422b is formed in the shape of FIG.

.

로 나타내며, 상기 광전달부(422a) 및 상기 매립부(422b)의 기울기는

이다. 여기서, 상기 매립부(422b)의 단면 궤적은 상기 광전달부(422a)가 상부로 연장되어 형성하는 가상 단면 궤적(T)을 가진다. 그래서 상기 매립부(422b)와 상기 접착층(430)이 접하는 지점의 길이는 수학식2와 같다.Subsequently, the cross-sectional locus length at the point where the buried portion 422b and the adhesive layer 430 are in contact with each other in FIG.

The slope of the light transmitting part 422a and the buried part 422b is represented by

to be. Here, the cross section trajectory of the buried portion 422b has a virtual cross section trajectory T formed by the light transmitting portion 422a extending upward. Thus, the length of the contact point between the buried portion 422b and the adhesive layer 430 is expressed by Equation 2 below.

임을 알 수 있다.As shown in Equation 2, when the buried portion 422b is formed to have a virtual cross section trajectory T of the light transmitting portion 422a

.

와 가상 단면 궤적(T)을 가지는 상기 매립부(422b)와 상기 접착층(430)과 접하는 지점의 길이

를 비교해보면 수학식3과 같다.According to the above result, the length of the point of contact with the buried portion 422b and the adhesive layer 430 having an actual cross section trajectory

And a length of a point of contact with the buried portion 422b and the adhesive layer 430 having a virtual cross section trajectory T

When compared with Equation (3).

이고 이에 따라서

임을 알 수 있다.Here, since the inclination of the cross section trajectory of the buried portion 422b is 90 ° or less,

And accordingly

.

Through the above result, when the buried portion 422b is formed such that the inclination of the cross section trajectory is inclined upwardly than the inclination of the cross section trajectory of the light transmitting unit 422a as shown in FIG. 6A. It can be seen that the circumference of the point of contact with the adhesive layer 430 is larger.

6 and 7, the area bonded to the adhesive layer 430 increases according to the shape of the buried portion 422b, so that the upper optical sheet 410 and the lower optical sheet 420 are more effectively. It can be seen that is bonded.

In this case, the cross-sectional trajectories of the first structured pattern 412 and the second structured pattern 422 may be curved rather than linear. In addition, the first structured pattern 412 and the second structured pattern 422 are rounded or incompletely shaped at the end of the lower end, the end of the upper direction, and the point where the derivative of the cross section trajectory is discontinuous. Since it may be formed, it is difficult to accurately measure the inclination angle of the cross section trajectories of the first structured pattern 412 and the second structured pattern 422.

In addition, the aforementioned points may be deformed when the upper optical sheet 410 and the lower optical sheet 420 are bonded to each other, so that the first structured pattern 412 and the second structured pattern 422 may be deformed. The cross-sectional trajectory of may be modified.

Therefore, since it is difficult to accurately measure the inclination angles of the cross-sectional trajectories of the first structured pattern 412 and the second structured pattern 422, an average inclination angle is calculated to calculate the first structured pattern 412 and the second structured pattern. At 422, the inclination angle of the cross section trajectory is determined.

The average inclination angles of the first structured pattern 412 and the second structured pattern 422 are inclined surfaces of regions except for the above-described points in the cross-sectional trajectories of the first structured pattern 412 and the second structured pattern 422. Measure the average inclination angle of the area for condensing light using the. The inclination angles of the first structured pattern 412 and the second structured pattern 422 are adjusted by using the measured average inclination angle.

In particular, in the second structured pattern 422, the inclination angles of the cross-sectional trajectories of the light transmitting portion 422a and the buried portion 422b are different from each other. Thus, the light transmitting part 422a measures the average inclination angle of the cross section trajectory in the remaining area except for the lower end part and the upper end part connected to the buried part 422b, and thus the inclination angle of the light transmitting part 422a. Determine. In addition, the buried portion 422b also measures the average inclination angle of the cross section trajectory except for the upper end portion joined to the lower surface of the upper optical sheet 410 and the lower end portion transmitted to the light transmitting portion 422a. The inclination angle of the buried portion 422b may be determined.

For example, after dividing the light transmitting unit 422a into three, the average inclination angle may be calculated using the center portion. In other words, the center portion is subdivided into minute length units, and then the slope of each subdivided minute length region is calculated and averaged to calculate an average inclination angle. The calculated mean inclination angle of the center portion is the inclined plane of the light transmitting part 422a. It can be determined by the inclination angle of. In this case, the center portion may be viewed as one region without subdividing into multiple micro units, and the slope of the region may be calculated to determine the average inclination angle.

Through the above method, when the cross-sectional locus of the first structured pattern 412 and the second structured pattern 422 is not a straight line, the inclination angle of the cross-sectional locus can be adjusted by measuring an average inclination angle.

Next, referring to FIGS. 8 and 9, when the buried portions 422b have the same cross-sectional area, the widths along the transverse direction at the boundary points between the light transmitting portions 422a and the buried portions 422b are compared. As follows.

FIG. 8 is a view illustrating a comparison of the light transmitting parts 422a not embedded in the adhesive layer 430 in the second structured pattern 422 of FIG. 2, and FIG. 9 is a lateral direction of the light transmitting parts 422a of FIG. 8. It is a figure which shows the difference by length.

As shown in FIG. 8, the buried portion 422b is buried into the adhesive layer 430, and FIG. 8A illustrates a second structured pattern 422 according to an embodiment of the present invention. The second structured pattern 422 has the inclination of the light transmitting portion 422a and the cross-sectional locus higher than the inclination of the cross-sectional locus of the light transmitting portion 422a. The buried portion 422b is inclined so that the buried portion 422b is embedded into the adhesive layer 430.

And (b) of FIG. 8 is configured such that the buried portion 422b has a virtual cross-sectional trajectory (T) formed to extend upward with a continuous slope of the light transmitting portion 422a, the buried portion ( A cross section trajectory of the light transmitting portion 422b and the light transmitting portion 422a is formed to have a uniform slope so that the buried portion 422b is embedded into the adhesive layer 430.

Here, the buried portion 422b of FIGS. 8A and 8B is embedded in the adhesive layer 430 such that the trajectory of the cross section in contact with the adhesive layer 430 is the same.

However, referring to the boundary point between the light transmitting part 422a and the buried part 422b in FIG. 8A, the width of the boundary point along the transverse direction is relatively light in FIG. 8B. It can be seen that it is narrower than the width of the boundary point between the transfer portion 422a and the buried portion 422b.

When the width along the transverse direction is narrow at the boundary between the light transmitting part 422a and the buried part 422b, the area for collecting more light transmitted from the diffusion sheet 300 and transmitting the light to the upper part becomes wider. . As such, when the area capable of condensing light becomes wider, the light uniformity and luminance increase accordingly, thereby increasing the effect of the multilayer optical sheet module 400.

More specifically, referring to FIG. 9, the light transmission in the state in which the buried portions 422b of FIGS. 8A and 8B have the same bonding area is embedded in the adhesive layer 430. Looking at the width in the lateral direction of the boundary point between the portion 422a and the buried portion 422b through the following equation.

로 나타내며, 상기 광전달부(422a)의 경사각은

이고, 상기 매립부(422b)는 상기 광전달부(422a)보다

만큼 상향 경사지도록 형성되었기 때문에 상기 매립부(422b)의 경사각은

이다. 그래서 상기 매립부(422b)와 상기 광전달부(422a)의 경계 지점의 횡 방향 폭은 수학식4와 같다.First, in the form of FIG. 8A, the width at the boundary point between the buried portion 422b and the light transmitting portion 422a is determined.

Indicated by the inclination angle of the light transmission unit 422a

The buried portion 422b is smaller than the light transmitting portion 422a.

Since it is formed to be inclined upwards, the inclination angle of the buried portion 422b is

to be. Therefore, the width in the lateral direction of the boundary between the buried portion 422b and the light transmitting portion 422a is expressed by Equation 4.

임을 알 수 있다.As shown in Equation 4, when the buried portion 422b is formed in the form (a) of FIG.

.

로 나타내며, 상기 광전달부(422a) 및 상기 매립부(422b)의 기울기는

이다.Subsequently, in the form of FIG. 8B, the width at the boundary point between the light transmitting part 422a and the buried part 422b is determined.

The slope of the light transmitting part 422a and the buried part 422b is represented by

to be.

Here, the cross section trajectory of the buried portion 422b has a virtual cross section trajectory T formed by the light transmitting portion 422a extending upward. Under such conditions, the width in the lateral direction at the boundary point between the light transmitting part 422a and the buried part 422b is expressed by Equation 5 below.

임을 알 수 있다.As shown in Equation 5, when the buried portion 422b is formed to have a virtual cross section trajectory T of the light transmitting portion 422a

.

와 가상 단면 궤적(T)을 가지는 상기 매립부(422b)와 상기 광전달부(422a)의 경계 지점에서 횡 방향 폭의 길이

를 비교해보면 수학식6과 같다.So, using the equations (4) and (5), the width of the transverse width at the boundary between the buried portion 422b and the light transmitting portion 422a having the actual cross-sectional trajectory

And the length of the transverse width at the boundary point between the buried portion 422b and the light transmitting portion 422a having a virtual cross section trajectory T;

When compared with Equation (6).

이고 이에 따라서

임을 알 수 있다.Here, since the inclination of the cross section trajectory of the buried portion 422b is 90 ° or less,

And accordingly

.

As a result, when the buried portion 422b is in contact with the adhesive layer 430 in the same area, the buried portion 422b has an inclination of the cross section trajectory as shown in FIG. When the inclination of the cross section trajectory of 422a is formed to be inclined upwardly, it can be seen that the width length in the transverse direction is smaller at the boundary point between the buried portion 422b and the light transmitting portion 422a.

Next, referring to FIG. 10, the buried portion 422b collects light transmitted from the diffusion sheet 300 in a state where the buried portion 422b is embedded in the adhesive layer 430.

FIG. 10 is a view illustrating refraction of light passing through the lower optical sheet 420 in the embodiment of FIG. 2.

의 각도로 상기 광전달부(422a)의 단면 궤적에 입사되며,

의 각도로 굴절된다.As shown, when light transmitted from the diffusion sheet 300 is incident and passed through the light transmitting part 422a and then transferred to the upper part, refraction occurs in the cross-sectional trajectory of the light transmitting part 422a. Here, the light L1 refracted in the cross section trajectory of the light transmitting part 422a is mainly centered on a normal line.

Is incident on the cross section trajectory of the light transmission unit 422a at an angle of

Is refracted at an angle of.

의 각도보다

의 각도가 더 크게 굴절된다. 이와 같은 원리는 수학식 7에 의해서 알 수 있다.At this time, since the light L1 refracted in the cross section trajectory of the light transmitting part 422a is refracted in the air direction and the refractive index n2 of the air is smaller than the refractive index n1 of the light transmitting part 422a.

Than the angle of

The angle of refraction is larger. This principle can be understood from Equation (7).

이고 공기의 굴절률은

이기 때문에, 수학식 7에 의해서

임을 알 수 있다.In Equation 7, the refractive index of the light transmitting unit 422a is

And the refractive index of air

Because of this,

.

On the other hand, the buried portion 422b buried in the adhesive layer 430 may be refracted by the light incident from the diffusion sheet 300 to be transmitted to the upper portion.

Here, the adhesive layer 430 should be able to transmit light, and the refractive index n1 of the material on which the buried portion 422b is formed should be larger than the refractive index n3 of the adhesive layer 430.

의 각도로 상기 매립부(422b)의 단면 궤적에 입사되며,

의 각도로 굴절된다. As shown, the light L2 incident and refracted into the cross section trajectory of the buried portion 422b is centered on the normal line in the cross section trajectory of the buried portion 422b.

Is incident on the cross section trajectory of the buried portion 422b at an angle of

Is refracted at an angle of.

임을 알 수 있다.Here, since the refractive index n1 of the buried portion 422b is larger than the refractive index n3 of the adhesive layer 430,

.

As such, the buried portion 422b is configured to be refracted and transmitted in an upward direction, thereby reducing uniformity and brightness of light by bonding the upper optical sheet 410 and the lower optical sheet 420. Can reduce the amount of

On the other hand, the propagation direction of light refracted by the light transmitting part 422a and the buried part 422b is similar by the upward inclination angle of the buried part 422b corresponding to the inclination angle of the light transmitting part 422a. Can be adjusted.

Next, referring to FIG. 11, the buried portion 422b is not in contact with the bottom surface of the upper optical sheet 410 when embedded in the adhesive layer 430.

FIG. 11 is a view showing a state in which the thickness of the adhesive layer 430 is bonded in a state where the thickness of the buried portion 422b is thicker in the embodiment of FIG. 2.

When the upper optical sheet 410 and the lower optical sheet 420 are coupled while the height of the buried portion 422b is lower than the thickness of the adhesive layer 430, the uppermost point of the buried portion 422b is It may not be in contact with the lower surface of the upper optical sheet 410.

As shown, even though the uppermost point of the buried portion 422b is not in contact with the lower surface of the upper optical sheet 410, the point where the derivative of the cross section trajectory is discontinuous between the lowermost and uppermost portions of the second structured pattern 422 is not. When located at the boundary point between the light transmitting part 422a and the buried part 422b, as described above, the light refracted by the cross section trajectory of the buried part 422b and the cross section trajectory of the light transmitting part 422a are provided. Light refracted at may travel in a similar direction.

Of course, since the thickness of the adhesive layer 430 is thick, the brightness can be reduced, but because the inclination of the cross-sectional trace of the buried portion 422b is formed to be inclined upwardly than the inclination of the cross-sectional trace of the light transmitting portion 422a. According to Equation 7, even if the uppermost point of the buried portion 422b is not in contact with the lower surface of the upper optical sheet 410 may have a similar effect.

Next, referring to FIG. 12, a position of a point at which the derivative of the cross section trajectory is discontinuous in the second structured pattern 422 will be described.

FIG. 12 is a diagram illustrating a position of a point where the derivative of the cross section trajectory is discontinuous in the second structured pattern 422 according to the thickness of the adhesive layer 430 of FIG. 2.

As shown, the size of the buried portion 422b and the light transmitting portion 422a embedded in the adhesive layer 430 varies according to the thickness of the adhesive layer 430.

As shown in FIG. 12A, not only the buried portion 422b but also a part of the light transmitting portion 422a are embedded in the adhesive layer 430. As such, when a part of the light transmitting part 422a is embedded into the adhesive layer 430, the discontinuous points P1 and P2 are also buried together.

As shown in FIG. 12B, only a part of the buried portion 422b is embedded into the adhesive layer 430, and the light transmitting portion 422a is not buried. As such, when only a part of the buried portion 422b is embedded into the adhesive layer 430, the discontinuous points P1 and P2 may be bonded to the upper optical sheet 410 while being positioned outside.

As such, the discontinuities P1 and P2 may be located at the boundary between the light transmitting part 422a and the buried part 422b, and may be located outside or inside the adhesive layer 430. Can be.

As described with reference to FIGS. 11 and 12, the second structured pattern 422 may be bonded to the adhesive layer 430 in various forms depending on the height and the thickness of the adhesive layer 430.

Next, various embodiments of the second structured pattern 422 will be described with reference to FIGS. 13 to 15.

FIG. 13 is a view showing an embodiment in which the cross section trajectory of the light transmitting part 422a is straight in the second structured pattern 422 of FIG. 2, and FIG. 14 is a light transmitting in the second structured pattern 422 of FIG. 2. The cross-sectional trajectory of the portion 422a is a view showing a non-linear embodiment, and FIG. 15 is a diagram in which the derivative of the cross-sectional trajectory of the second structured pattern 422 of FIG. 2 does not have discontinuities P1 and P2. It is a figure which shows an Example.

First, referring to FIG. 13, it can be seen that the cross section trajectory of the light transmitting unit 422a is formed in a straight line shape. Since the light transmitting unit 422a has a straight line shape, the light transmitting unit 422a collects and refracts the light transmitted from the diffusion sheet 300 and transmits the light to the upper portion.

FIG. 13A illustrates a cross-sectional trajectory of the buried portion 422b in the second structured pattern 422 having a rectangular shape at a boundary point between the light transmitting portion 422a and the buried portion 422b. It can be seen that the derivative of the cross section trajectory is discontinuous.

In FIG. 13A, the buried portion 422b is a connection surface connecting between a pair of extension surfaces S1 extending upward from the light transmission unit 422a and a pair of extension surfaces S1. It is comprised including (S2). It can be seen that the buried portion 422b configured as described above has a larger circumference of the cross section trajectory of the buried portion 422b than the circumference of the virtual cross section trajectory T of the light transmitting portion 422a.

In FIG. 13B, the cross-sectional trajectory of the buried portion 422b is formed in a spherical shape in the second structured pattern 422, and is disposed on the light transmitting portion 422a. In addition, as shown in FIG. 13A, it can be seen that the derivative of the cross section trajectory is discontinuous at the boundary point between the light transmitting part 422a and the buried part 422b. Since the cross section trajectory of the buried portion 422b is formed in a spherical shape, an area in which the buried portion 422b is bonded to the adhesive layer 430 increases.

 Subsequently, in FIG. 14, the cross section trajectory of the light transmitting part 422a is formed in a curved shape rather than a straight line shape. In fact, when the light transmission unit 422a is manufactured, a lot of cross-section trajectories are produced in a straight line, but when the upper optical sheet 410 and the lower optical sheet 420 are bonded to each other, bending occurs due to pressure. It may be formed in the form.

FIG. 14 illustrates one example, and FIG. 14A illustrates a cross-sectional trajectory of the buried portion 422b formed in a curved shape, and a circumference of the cross-sectional trace of the buried portion 422b is defined by the light transmitting unit ( It can be seen that 422a is greater than the circumference of the virtual cross-section trajectory T which extends upward and has a continuous slope.

In addition, referring to the graph shown, the discontinuities P1 and P2 having the discontinuity in the cross section trajectory are located at the boundary between the buried part 422b and the light transmitting part 422a.

14B and 14C, the cross section trajectory of the light transmitting unit 422a is formed in a curved shape, but the cross section trajectory of the buried portion 422b is formed in a triangular shape of a straight line. . Here, as in FIG. 14A, it can be seen that the discontinuous points P1 and P2 are located at the boundary between the buried portion 422b and the light transmitting portion 422a.

As such, the second structured pattern 422 may have a cross-sectional locus of the light transmitting part 422a that is not a straight line.

Next, referring to FIG. 15, the cross-sectional trajectories of the buried portion 422b and the light transmitting portion 422a are formed to be curved.

It can be seen that the circumference of the cross section trajectory of the buried portion 422b is also larger than the circumference of the virtual cross section trajectory T formed by extending upwardly with the continuous inclination portion 422a.

However, looking at the graph shown, it can be seen that the derivative of the cross section trajectory is continuous at the boundary point between the light transmitting part 422a and the buried part 422b.

As such, even if the derivative of the cross section trajectory is not between the bottom and top of the second structured pattern 422 without the discontinuous points P1 and P2 which are discontinuous, the circumference of the cross section trajectory of the buried portion 422b is transmitted. It may be formed larger than the circumference of the virtual cross section trajectory T of the unit 422a.

That is, even if the cross section trajectory is not bent at the boundary point between the buried portion 422b and the light transmitting portion 422a, the periphery of the cross section trajectory of the buried portion 422b is increased to bond the area to the adhesive layer 430. By increasing, the effect similar to the form having the discontinuous points (P1, P2) can be exhibited without departing from the spirit of the present invention.

Next, referring to FIG. 16, a state in which the second structured pattern is formed of a non-uniform pattern is as follows.

FIG. 16 is a view illustrating a configuration in which the second structured pattern has a non-uniform pattern in the optical sheet module of FIG. 2.

As illustrated in FIG. 16, the second structured pattern 422 is formed in a form in which a plurality of patterns formed in different shapes are continuously arranged without forming a uniform pattern as described above.

The second structured pattern 422 is a mixture of a pattern consisting of the light transmitting portion 422a and the buried portion 422b and a pattern consisting only of the light transmitting portion 422a to form the second structured pattern, respectively. Some of the patterns may not be embedded into the adhesive layer 430.

That is, the second structured pattern 422 is composed of two patterns, and some of the patterns are embedded in the adhesive layer 430, and the others are not embedded. Here, the pattern embedded in the adhesive layer 430 is made of a configuration including the light transmitting part 422a and the buried portion 422b, and the pattern not embedded in the adhesive layer 430 is the light transmitting part ( 422a) only. Of course, depending on the thickness of the adhesive layer 420 and the adhesive thickness of the upper optical sheet 410, the upper part of the two patterns may be embedded into the adhesive layer 430.

The buried portion 422b may be formed in various shapes, and as shown in FIG. 16, the buried portion 422b extends upward from the light transmitting portion 422a to a pair of extension surfaces S1. ) Is provided and is formed to meet the upper end of the extension surface (S1).

At this time, the pattern consisting only of the light transmitting part 422a has a shorter distance from the uppermost point to the lowest point than the pattern consisting of the light transmitting part 422a and the buried part 422b. Thus, the buried portion 422a is embedded into the adhesive layer 430 to bond the upper optical sheet 410 and the lower optical sheet 420.

Meanwhile, as shown in the drawing, the second structured pattern 422 includes a pattern including only the light transmitting part 422a and a pattern including the buried part 422b and the light transmitting part 422a among a plurality of patterns. This may be arranged repeatedly in succession.

Of course, different patterns of different shapes may be arranged irregularly, rather than uniformly, as shown in the drawings.

As shown in the figure, the uppermost portion of the buried portion 422b may be in contact with the lower surface of the upper optical sheet 410, and may be buried in the adhesive layer 430 without being in contact.

Next, referring to FIG. 17 and FIG. 18, a configuration in which an additional reflective polarizing film is further included in the optical sheet module according to the embodiment of the present invention is as follows.

FIG. 17 is an exploded perspective view illustrating a state in which the reflective polarizing film is further included in the optical sheet module of FIG. 2, and FIG. 18 is a view illustrating a state in which light is transmitted or reflected by the reflective polarizing film of FIG. 17.

Referring to the drawings, a separate reflective polarizing film 500 is further included on the top of the upper optical sheet 410 and is provided in a stacked form so that the upper optical sheet 410 and the lower optical sheet 420 are provided. It selectively transmits the light condensed by.

The reflective polarizer 500 selectively transmits light according to the wavelength of light and returns light having a different wavelength to the light guide plate 200. An example of such a device is a dual brightness enhancement film (DBEF).

The reflected light that does not pass through the DBEF is reflected back through the light guide plate 200 at the bottom of the BLU and is directed upward. DBEF passes through only the light with the right wavelength and reflects the rest of the light.

By repeating the above process, only the light having a desired wavelength is emitted upward, thereby reducing the loss of emitted light and increasing the brightness of the display module.

In more detail, as shown in FIG. 18, the reflective polarizing film 500 is stacked on the upper optical sheet 410 and is disposed on the lower optical sheet 420 and the upper optical sheet 410. The light collected through the light beam is directed toward the reflective polarizing film 500. Here, the light directed toward the reflective polarization film 500 is a mixture of light of different wavelengths, the light of P1 having a wavelength of the region transmitted by the reflective polarization film 500 and the reflective polarization film 500 It consists of the light of P2 which has the wavelength of the area | region which does not transmit.

As shown, the light passing through the upper optical sheet 410 and the lower optical sheet 420 is a mixed state of P1 and P2, but the reflective polarizing film 500 transmits only P1 light and the light of P2 is lower again. Reflect in the direction.

Thus, the light of P1 is emitted to the outside, but the light of P2 is reflected and returned to the bottom, and is reflected by the light guide plate 200 to move upward. Through this process, the light of P2 changes its direction and wavelength and is converted into a state suitable for transmitting the reflective polarizing film 500 through such repetition.

As described above, the reflective polarizing film 500 reduces the loss of light and simultaneously emits light having a desired refractive angle and wavelength to increase the brightness of the display module.

Meanwhile, the reflective polarization film 500 may not only be stacked and disposed on the upper optical sheet 410, but also may be stacked and disposed between the upper optical sheet 410 and the lower optical sheet 420. It may be.

As described above, the preferred embodiments of the present invention have been described, and the present invention can be embodied in other forms without departing from the spirit or scope of the present invention. The present embodiments are therefore to be considered in all respects as illustrative and not restrictive, and the invention is not to be limited to the foregoing description, but may be modified within the scope and equivalence of the appended claims.

100: light source 200: light guide plate
300: diffusion sheet 400: optical sheet module
410: upper optical sheet 412: first structured pattern
420: lower optical sheet 422: second structured pattern
430: adhesive layer T: virtual cross section trajectory

Claims (43)

An upper optical sheet having a first structured pattern protruding upward;
A lower optical sheet provided on a lower portion of the upper optical sheet and having a second structured pattern protruding toward the upper optical sheet; And
An adhesive layer provided between the upper optical sheet and the lower optical sheet;
/ RTI >
The second structured pattern is,
A light-transmitting portion having a smaller cross-sectional area toward an upper portion thereof and a buried portion which is continuously connected to an upper portion of the light-transmitting portion and at least partially embedded in the adhesive layer;
And a circumferential length of a cross section of the buried portion in contact with the adhesive layer is greater than a circumference of a trajectory of the virtual cross section in which the light transmitting portion extends upward with a continuous slope. The method of claim 1,
The second structured pattern is,
A multilayer optical sheet module, wherein the derivative of the cross section trajectory is formed to have at least one or more discontinuities between the lowermost and the uppermost. The method of claim 2,
The discontinuity point is,
The multilayer optical sheet module, characterized in that located at the boundary point of the cross section trajectory of the buried portion and the light transmitting portion. The method of claim 1,
The light transmitting unit,
Multi-layer optical sheet module, characterized in that the trajectory of the cross section is made of a straight line. The method of claim 1,
The buried portion,
Multi-layer optical sheet module, characterized in that the trajectory of the cross section in contact with the adhesive layer made of a straight line. 6. The method of claim 5,
The buried portion,
And a connection surface connecting the pair of extension surfaces extending upward from the light transmitting part and a pair of the extension surfaces. 6. The method of claim 5,
The buried portion,
And a pair of extension surfaces extending upwardly inclined upward from the light transmission unit, wherein the upper ends of the extension surfaces meet each other. The method of claim 1,
The buried portion,
A multilayer optical sheet module, wherein an uppermost portion is in contact with a lower portion of the upper optical sheet. 9. The method according to any one of claims 1 to 8,
The second structured pattern is,
Multilayer optical sheet module having the same cross-sectional shape and is formed extending in the transverse direction. The method of claim 9,
The upper optical sheet and the lower optical sheet,
And an extension direction of the first structured pattern and an extension direction of the second structured pattern intersect each other. The method of claim 10,
The extending direction of the first structured pattern is,
Multi-layered optical sheet module, characterized in that perpendicularly intersecting with the extending direction of the second structured pattern. The method of claim 1,
Multi-layer optical sheet module, characterized in that it further comprises a reflective polarizing film disposed in a stacked form with the lower optical sheet or the upper optical sheet to selectively transmit light according to the wavelength of light transmitted from the lower. The method of claim 12,
The reflective polarizing film,
Multi-layer optical sheet module, characterized in that the stack is provided between the upper optical sheet and the lower optical sheet. The method of claim 12,
The reflective polarizing film,
Multi-layer optical sheet module, characterized in that provided is stacked on top of the upper optical sheet. An upper optical sheet having a first structured pattern protruding upward;
A lower optical sheet provided below the upper optical sheet and having a second structured pattern protruding toward the upper optical sheet; And
An adhesive layer formed between the upper optical sheet and the lower optical sheet;
/ RTI >
The second structured pattern has a multi-layered optical sheet module having one or more discontinuities, the cross-sectional area is smaller toward the top and the slope is discontinuously increased from the bottom to the top. 16. The method of claim 15,
The second structured pattern is,
Multi-layered optical sheet module, characterized in that the refractive index of the formed material is larger than the refractive index of the adhesive layer. 16. The method of claim 15,
The second structured pattern is,
Multi-layered optical sheet module, characterized in that it comprises a light-transmitting portion having a predetermined slope in the lower portion and a buried portion extending to the upper portion of the light-transmitting portion at least partially embedded in the adhesive layer. 18. The method of claim 17,
The buried portion,
A multilayer optical sheet module comprising at least two and having an extending surface extending in an upward direction. 18. The method of claim 17,
The buried portion,
Multi-layered optical sheet module, characterized in that formed in a pair has an extended surface extending in the upper direction and the cross section is formed in a triangular form by the extended surface. 18. The method of claim 17,
The buried portion,
Multilayer optical sheet module, characterized in that formed in the same or less than the thickness of the adhesive layer. 16. The method of claim 15,
Multi-layer optical sheet module, characterized in that it further comprises a reflective polarizing film disposed in a stacked form with the lower optical sheet or the upper optical sheet to selectively transmit light according to the wavelength of light transmitted from the lower. The method of claim 21,
The reflective polarizing film,
Multi-layer optical sheet module, characterized in that the stack is provided between the upper optical sheet and the lower optical sheet. The method of claim 21,
The reflective polarizing film,
Multi-layer optical sheet module, characterized in that provided is stacked on top of the upper optical sheet. 24. The method according to any one of claims 15 to 23,
The second structured pattern is,
The multilayer optical sheet module having the same cross-sectional shape and extending along the transverse direction. 24. The method according to any one of claims 15 to 23,
The upper optical sheet and the lower optical sheet,
And an extension direction of the first structured pattern and an extension direction of the second structured pattern intersect each other. 26. The method of claim 25,
The extending direction of the first structured pattern is,
Multi-layered optical sheet module, characterized in that perpendicularly intersecting with the extending direction of the second structured pattern. An upper optical sheet having a first structured pattern protruding upward;
A lower optical sheet provided below the upper optical sheet and having a second structured pattern protruding toward the upper optical sheet; And
An adhesive layer formed between the upper optical sheet and the lower optical sheet;
/ RTI >
The second structured pattern is a multi-layered optical sheet module having a shape in which the cross-sectional area becomes smaller toward the top, and having a light-transmitting portion having a straight cross section and a buried portion of the straight-type connected obliquely upward from the light transmitting portion. 28. The method of claim 27,
The buried portion,
And a pair of extension surfaces extending upwardly upward from the light transmission unit, and upper ends of the extension surfaces meet with each other. 28. The method of claim 27,
The buried portion,
Multi-layer optical sheet module, characterized in that the cross section is formed in a triangular form. 28. The method of claim 27,
Multi-layer optical sheet module, characterized in that it further comprises a reflective polarizing film disposed in a stacked form with the lower optical sheet or the upper optical sheet to selectively transmit light according to the wavelength of light transmitted from the lower. 28. The method of claim 27,
The reflective polarizing film,
Multi-layer optical sheet module, characterized in that the stack is provided between the upper optical sheet and the lower optical sheet. 28. The method of claim 27,
The reflective polarizing film,
Multi-layer optical sheet module, characterized in that provided is stacked on top of the upper optical sheet. An upper optical sheet having a first structured pattern protruding upward;
A lower optical sheet provided on a lower portion of the upper optical sheet and having a second structured pattern formed of a plurality of patterns protruding toward the upper optical sheet; And
An adhesive layer provided between the upper optical sheet and the lower optical sheet;
/ RTI >
The second structured pattern is a multi-layered optical sheet module formed to have one or more discontinuities with a cross-sectional area of the plurality of patterns, the cross-sectional area is smaller toward the top and the slope is discontinuously increased from the bottom to the top 34. The method of claim 33,
The second structured pattern is,
The multi-layered optical sheet module, wherein a part of the plurality of patterns has a longer distance from the top to the bottom than the adjacent pattern. 34. The method of claim 33,
The second structured pattern is,
Multi-layer optical sheet module, characterized in that different patterns are repeatedly arranged. 34. The method of claim 33,
The second structured pattern is,
The multi-layered optical sheet module, characterized in that it has a light-transmitting portion of which a portion of the pattern is gradually increased toward the upper portion and a buried portion which is continuously connected to the upper portion of the light-transmitting portion and at least partially embedded in the adhesive layer. 37. The method of claim 36,
The circumferential length of the cross section where the buried portion is in contact with the adhesive layer is greater than the circumference of the trajectory of the virtual cross section formed by the light transmitting portion extending upward with a continuous slope. 34. The method of claim 33,
The second structured pattern is,
Multi-layered optical sheet module, characterized in that the refractive index of the formed material is larger than the refractive index of the adhesive layer. 34. The method of claim 33,
Multi-layer optical sheet module, characterized in that it further comprises a reflective polarizing film disposed in a stacked form with the lower optical sheet or the upper optical sheet to selectively transmit light according to the wavelength of light transmitted from the lower. 40. The method of claim 39,
The reflective polarizing film,
Multi-layer optical sheet module, characterized in that the stack is provided between the upper optical sheet and the lower optical sheet. 40. The method of claim 39,
The reflective polarizing film,
Multi-layer optical sheet module, characterized in that provided is stacked on top of the upper optical sheet. 42. The compound of any of claims 33 to 41 wherein
The second structured pattern is,
Multilayer optical sheet module having the same cross-sectional shape and is formed extending in the transverse direction. 43. The method of claim 42,
The upper optical sheet and the lower optical sheet,
And an extension direction of the first structured pattern and an extension direction of the second structured pattern intersect each other.

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