KR20190081027A - Diffusion Sheet Having Light Shielding Function and Backlight Unit Having the Same - Google Patents

Abstract

The present invention provides a light-emitting device comprising: a light-shielding layer formed of a light-transmitting material and having a predetermined thickness, the light-shielding layer including a plurality of particles therein according to a haze value of a predetermined value; And a pattern scattering layer formed on at least one of an upper surface and a lower surface of the shield layer and including a scattering pattern partially protruded and diffusing light transmitted from a lower portion of the scattered bead, There is provided a diffusion sheet having improved shielding performance in which beads are formed to have a relatively smaller size than the particles contained in the shielding layer.

Description

BACKGROUND OF THE INVENTION 1. Field of the Invention [0001] The present invention relates to a diffusion sheet having improved shielding performance and a backlight unit having the diffusion sheet.

The present invention relates to a diffusion sheet having improved shielding performance, and more particularly, to a diffusion sheet having improved shielding performance including a shielding layer having a different haze value in a diffusion sheet and a backlight unit having the same.

2. Description of the Related Art In recent years, the use of flat panel display panels has been expanding.

Generally, the liquid crystal display (LCD) requires a backlight unit that provides uniform light throughout the screen, unlike the conventional CRT. The backlight unit is provided with a light source lamp, a light guide unit for reflecting the light of the lamp, and a light condensing sheet unit, and converts the light into a surface light source.

At this time, the light source is disposed adjacent to the side surface of the light guide portion, and the light incident into the light guide portion is transmitted to the upper portion and is condensed by the light condensing sheet portion.

In general, the light transmitted from the light guiding portion to the light converging sheet portion is refracted and reflected by the lower portion and is transmitted to the upper portion, so that the light is not uniformly dispersed and a variation occurs in each region.

A diffusion sheet is provided between the light collecting sheet portion and the light guiding portion to diffuse the light transmitted from the lower portion and disperse the light uniformly.

Generally, the diffusion sheet is made of a light-transmitting material and is configured to have a certain pattern on the upper surface or lower surface.

By the pattern thus formed, the light transmitted from the lower portion is diffused and transmitted to the upper portion, so that light is uniformly condensed in the light condensing sheet portion.

In recent years, thinning of such a liquid crystal display device is a major issue, and accordingly, the backlight unit is becoming thinner.

Various problems have been caused by the thinning of the backlight unit. Specifically, the diffusion sheet is thinned and the pattern of the light guide plate under the diffusion sheet is visually recognized.

In order to solve such a problem, a method of using a diffusing sheet having a high-haze value is proposed so that the pattern of the light guide plate is not visually recognized. However, another problem occurs in that the luminance decreases as the haze value increases.

That is, simply increasing the haze value to prevent the pattern of the light guide plate from being viewed can not be a fundamental solution.

Therefore, it is necessary to develop a diffusion sheet capable of minimizing the decrease in brightness while preventing the lower pattern from being visually recognized.

SUMMARY OF THE INVENTION The present invention has been made to solve the above problems and it is an object of the present invention to provide a liquid crystal display device having a shield layer having a different haze value and a pattern scattering layer having a scattering pattern on an upper surface thereof, And a backlight unit having the diffusion sheet, which is capable of minimizing the luminance degradation, and having improved shielding performance.

According to an aspect of the present invention, there is provided a diffusion sheet having an improved shielding performance according to one aspect of the present invention. The diffusion sheet is formed of a light transmitting material and has a predetermined thickness. The diffusion sheet has a predetermined haze value, A shielding layer including a plurality of particles and a scattering pattern formed on at least one of an upper surface and a lower surface of the shielding layer, the scattering pattern having a part protruded therein, a plurality of beads dispersed therein, And a scattering layer, wherein the beads are formed in a size relatively smaller than the particles contained in the shielding layer.

In addition, the shielding layer may be characterized in that the particles having a predetermined size are uniformly dispersed therein.

The shielding layer may include a first sheet having a first haze value as a light transmitting material, and a second sheet laminated to the first sheet and having a second haze value as a light transmitting material .

The first sheet and the second sheet may have different thicknesses.

In addition, the pattern scattering layer may be characterized in that the distribution density of the beads is distributed relatively higher along the vertical direction toward the shielding layer.

The pattern scattering layer is formed on the upper surface and the lower surface of the shielding layer. In the pattern scattering layer formed on the upper surface of the shielding layer, the distribution density of the beads is higher as the shielding layer is closer to the shielding layer. And the beads are uniformly distributed in the pattern scattering layer formed on the bottom surface.

In addition, the beads are formed to have a size of 0.1 to 1 micrometers and can minimize the decrease in brightness by mie-scattering the light in the visible light wavelength range transmitted from the lower part.

The beads may be spherical and may be formed of at least one material selected from the group consisting of Alumina, TiO ₂ , Melamine, Silica, PMMA, PBMA, and PDMS, and may have a refractive index of 1.45 to 2.50.

The particles may be made of at least one material selected from the group consisting of silica, PMMA, and PBMA, and have a diameter ranging from 1 to 9 μm.

The pattern scattering layer may include a first layer including the protruding scattering pattern and a second layer including the plurality of beads between the shielding layer and the first layer.

The protruding scattering pattern may have a non-uniform size and may be formed on at least a part of one surface of the pattern scattering layer.

According to another aspect of the present invention, there is provided a backlight unit including a diffusion sheet having improved shielding performance.

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

First, the diffusion sheet is provided on the upper and lower surfaces with a shielding layer having a predetermined haze value, and a pattern scattering layer having a scattering pattern and scattering light is provided, so that the pattern of the light guide plate disposed under the diffusion sheet is prevented from being viewed by the user There is an advantage to be able to do.

Secondly, a separate bead is provided in the pattern scattering layer to increase the scattering and diffusing effect of light transmitted from below, and the bead is formed to have a size where mie-scattering occurs, Is transmitted to the upper portion, thereby minimizing the decrease in luminance.

The effects of the present invention are not limited to the above-mentioned effects, and other effects not mentioned can be clearly understood by those skilled in the art from the description of the claims.

FIG. 1 schematically shows a structure of a backlight unit having a diffusion sheet with improved shielding performance according to an embodiment of the present invention; FIG.
FIG. 2 is a side view of the backlight unit of FIG. 1;
3 is a schematic view of the configuration of a diffusion sheet in the backlight unit of Fig. 1; Fig.
FIG. 4 is a view showing whether a lower pattern is visible depending on the presence or absence of a shielding layer in the diffusion sheet of FIG. 3; FIG.
5 illustrates a configuration in which separate beads are included in a pattern scattering layer in the diffusion sheet of FIG. 1;
FIG. 6 is a diagram showing scattering of light according to the arrangement of beads in the pattern scattering layer of FIG. 5; FIG.
FIG. 7 is a view showing a form in which scattering of light occurs according to the size of particles in the diffusion sheet of FIG. 5; FIG.
FIG. 8 shows a modified form of the pattern scattering layer of FIG. 5 in the diffusion sheet of FIG. 1; FIG.
FIG. 9 is a view showing a state in which a shielding layer is composed of multiple layers in the diffusion sheet of FIG. 1; FIG. And
10 is a view showing a pattern in which the pattern scattering layer in the diffusion sheet of FIG. 1 is composed of multiple layers.

DETAILED DESCRIPTION OF THE PREFERRED EMBODIMENTS Hereinafter, preferred embodiments of the present invention will be described with reference to the accompanying drawings. In describing the present embodiment, the same designations and the same reference numerals are used for the same components, and further description thereof will be omitted.

The diffusion sheet with improved shielding performance according to an exemplary embodiment of the present invention will be described as an example in which the diffusion sheet is applied to a backlight unit of a flat panel liquid crystal display device such as an LCD or an LED panel. However, the present invention is not limited to this, and may be used alone as a diffusion sheet with improved shielding performance, or may be a backlight unit applied to a mechanism other than that applied to a liquid crystal display, And any device that changes the path.

First, a configuration of a backlight unit according to the present invention will be schematically described with reference to FIGS. 1 to 4. FIG.

FIG. 1 is a schematic view of a backlight unit having a diffusion sheet with improved shielding performance according to an exemplary embodiment of the present invention, and FIG. 2 is a side view of the backlight unit of FIG.

And FIG. 3 is a schematic view of the structure of the diffusion sheet in the backlight unit of FIG. 1, and FIG. 4 is a view illustrating whether or not the lower pattern is visible depending on the presence or absence of the shielding layer in the diffusion sheet of FIG.

BACKGROUND ART [0002] Generally, a backlight unit (BLU) for providing light to a liquid crystal panel must be provided in a liquid crystal display device.

The backlight unit according to the present invention mainly includes a light source 100, a light guide unit 200, a light condensing sheet unit 300, and a diffusion sheet 400.

The light source 100 generates light at the side of the light guide unit 200 and transmits light to the light guide unit 200 to minimize the volume of the backlight unit. As the light source 100, a light emitting diode (LED) and a cold cathode fluorescent lamp (CCFL) may be selectively used.

In the present invention, the light source 100 is composed of at least one light source, and emits light toward the side of the light guide unit 200.

The light guiding portion 200 has a thickness and is formed in a flat plate shape to transmit the light incident through the side surface to the upper portion.

Specifically, the light incident on the light guide unit 200 is totally reflected in the light guide unit 200 and is emitted upward. At this time, the light guiding unit 200 moves the light transmitted from the light source 100 along a flat plate, and is transmitted as an upper surface light source.

In addition, the light guide unit 200 may include a reflection plate 210 at a lower portion thereof, and reflect the light transmitted through the light guide unit 200 to the lower portion.

The light collecting sheet unit 300 is stacked on the light guiding unit 200 and collects the light transmitted from the lower part and transmits the collected light to the upper part in the form of a surface light source.

Specifically, the light collecting sheet unit 300 is formed by stacking a plurality of sheets so as to condense light, or to form a single sheet, and to transmit the light transmitted from the lower portion to the upper portion.

In the embodiment of the present invention, the light collecting sheet unit 300 includes a pair of lower optical sheets 310 and an upper optical sheet 320, and the lower optical sheet 310 includes a first base film 312, 1 light collecting portion 314.

The first base film 312 is formed of a light transmitting material and has a predetermined thickness and is formed in a flat plate shape. The first light collecting part 314 is formed on the upper surface to condense the light transmitted from the lower part.

The first condensing unit 314 is formed on the upper surface of the first base film 312, and the first unit condenser is continuously and repeatedly formed with a decreasing cross sectional area.

Specifically, the first light collecting part 314 collects light transmitted through the first base film 312 and transmits the light to the upper part, and a plurality of first unit light collectors are formed.

Here, the first unit concentrator has an inclined surface, and the cross-sectional area of the first unit concentrator is reduced to the upper portion thereof, so that light is condensed through the inclined surface.

In this embodiment, the first unit condenser has a pair of inclined surfaces, and is formed in a prism shape having a triangular cross-section along the up-and-down direction.

Alternatively, a plurality of first unit condensers may be formed in a protrusion shape. Alternatively, as shown in this embodiment, each of the first unit condensers may be elongated in a strip shape to form the first base film 312 As shown in FIG.

That is, the first light collecting part 314 has a plurality of first unit collecting bodies formed so that the upper and lower end faces of the triangular shape extend along one direction, and light is condensed through the first unit collecting bodies.

The upper optical sheet 320 is stacked on the lower optical sheet 310 and includes a second base film 322 and a second light collecting part 324 to form the lower optical sheet 310, Converge the light together.

The second base film 322 is formed in a shape similar to that of the first base film 312, and a second light collecting portion 324 is formed on the upper surface.

The second light collecting part 324 is provided on the upper surface of the second base film 322 to condense the light transmitted from the lower part. Specifically, the second light collecting part 324 is formed in a shape similar to that of the first light collecting part 314, and the second unit light collecting material whose cross-sectional area decreases as it goes upward is continuously and repeatedly formed.

Here, the second unit condenser has a pair of inclined surfaces and is formed to have a triangular top and bottom surfaces to condense light through the inclined surfaces.

In the present embodiment, the second unit condensers are formed on the upper surface of the second base film 322, respectively, in the same manner as the first unit condensers.

The first and second light collecting parts 314 and 324 may be elongated to intersect with the first and second base films 312 and 322, do.

The light collecting sheet unit 300 includes the first base film 312 and the second base film 322, and collects light transmitted from the lower portion of the light collecting sheet unit 300 and transmits the collected light.

The diffusion sheet 400 is provided between the light collecting sheet unit 300 and the light guiding unit 200 to diffuse and shield the light transmitted to the upper part and transmit the light to the light collecting sheet unit 300.

At this time, the diffusion sheet 400 not only diffuses and diffuses the light transmitted from the lower part, but also shields the light to make it uniform.

Specifically, the diffusion sheet 400 according to the present invention includes a shielding layer 410 and a pattern scattering layer 420.

The shielding layer 410 is formed of a light transmitting material and has a predetermined thickness and is formed in a sheet shape to prevent the pattern of the light guide plate from being visible to a user by shielding the light transmitted from the lower portion and transmitting the light. .

And a plurality of particles 412 are dispersed therein to have a predetermined haze value.

The haze characteristic is a characteristic that, when light passes through a transparent material, it diffuses depending on the kind of the material, as well as reflection or absorption, depending on the intrinsic properties of the material.

In the present invention, the shielding layer 410 is formed in a shape in which the particles 412 are dispersed therein, and is formed in a sheet form at the lower portion of the light condensing sheet portion 300 and stacked.

At this time, the particles 412 are made of materials such as silica, PMMA, and PBMA and have a size of 1 to 9 탆 and have a refractive index of about 1.5 and are dispersed in the shielding layer 410. The particles 412 have a non-uniform size and scatter light transmitted from the lower part to shield the pattern of the light guide plate 200 from being visible.

Here, the shielding layer 410 according to the present invention has a thickness of 18 to 130 탆 and includes a plurality of the particles 412 therein.

As described above, the shielding layer 410 according to the present invention shields the pattern of the light guide plate 200 from being visually recognized by dispersing the particles uniformly dispersed in the inside of the shielding layer 410 and diffusing light transmitted from the bottom.

In the present embodiment, the shielding layer 410 is configured such that the particles 412 are dispersed therein to have a predetermined haze value. Alternatively, the shielding layer 410 may have a specific pattern on the surface of the shielding layer 410 It is possible.

The pattern scattering layer 420 is stacked or bonded to at least one of the upper surface and the lower surface of the shielding layer 410 and a scattering pattern 422 protruding at least partially is formed to diffuse the light transmitted from the lower portion. .

Specifically, the pattern scattering layer 420 is formed on the upper surface or the lower surface of the shielding layer 410 as shown in FIG.

At this time, the pattern scattering layer 420 has a refractive index different from that of the shielding layer 410 and is laminated or bonded. Here, the pattern scattering layer 420 diffuses light through the scattering pattern 422.

In this embodiment, the pattern scattering layer 420 is laminated on the upper and lower surfaces of the shielding layer 410, and the scattering patterns 422 are protruded in the upper and lower directions.

Here, the scattering pattern 422 has a curved surface in a spherical shape, and a plurality of the scattering patterns 422 are protruded and formed with nonuniform density and size.

As described above, the diffusion sheet 400 according to the present invention includes the shielding layer 410 and the pattern scattering layer 420, and the particles 412 dispersed in the shielding layer 410 and the pattern scattering The layer 420 may shield and diffuse light transmitted from below.

Here, the shielding layer 410 diffuses the light transmitted from the lower portion through a unique haze value and maintains the pattern scattering layer 420 like the base film.

The pattern scattering layer 420 diffuses the light transmitted from the lower portion together with the shielding layer 410 to prevent the diffusion sheet 400 and the light guide plate 200 from being attracted to each other or from being abraded.

The shield layer 410 and the pattern scattering layer 420 are formed to have different materials and refractive indices.

4, a diffusion sheet 400 is stacked on top of a general pattern to photograph an image to be transmitted. In the diffusion sheet 400, a lower pattern is visible depending on the presence or absence of the shielding layer 410 Can be confirmed.

4 (a), the shielding layer 410 does not have a haze value. Here, when the shielding layer 410 does not have a haze value equal to or higher than a certain level, it can be confirmed that scattering occurs, but the lower pattern is visible.

In the case where the shielding layer 410 has no haze value, the light transmitted from the lower portion is diffused by the pattern scattering layer 420, but the light is not dispersed by the shielding layer 410, ) Is visible to the user.

Therefore, when the shielding layer 410 and the pattern scattering layer 420 are not provided, the light transmitted from the light guide plate 200 does not have a sufficient diffusion effect, so that the pattern of the light guide plate 200, And can be projected and recognized by the user in the form of a spot, a pattern, or the like.

However, as shown in FIG. 4B, the diffusion sheet 400 according to the present invention is arranged in a laminated structure on a specific pattern as in FIG. 4A.

Here, the shielding layer 410 is configured to have a predetermined haze value or more, and in such a case, the lower pattern is diffused to such an extent that it can not be recognized.

This is because the shielding layer 410 scattering and diffusing the light transmitted from the lower portion together with the pattern scattering layer 420 increases the overall shielding performance, So that the luminance reduction of the light can be minimized.

At this time, the luminance can be minimized as the light transmitted from the lower portion is transmitted to the upper portion of the scattered light in the course of passing through the shielding layer 410 and the pattern scattering layer 420, have.

The shape of the scattering layer 420 can be adjusted by using structural deformations of the pattern scattering layer 420 and a separate bead 424, and a specific structure thereof will be described later with reference to FIG.

As described above, the diffusion sheet 400 according to the present invention not only diffuses light, but also increases the shielding performance of the light transmitted by the shielding layer 410 so that it can be diffused evenly.

Next, a modified form of the diffusion sheet 400 according to the present invention will be described with reference to FIGS. 5 to 7. FIG.

5 is a view showing a configuration in which a separate bead 424 is included in the pattern scattering layer 420 in the diffusion sheet 400 of FIG. 1, and FIG. 6 is a schematic view of a pattern scattering layer according to the arrangement of beads in the pattern scattering layer of FIG. FIG. 7 is a view showing a form in which scattering of light occurs according to the size of the particles 412 in the diffusion sheet 400 of FIG. 5. FIG.

Referring to the drawing, the basic structure of the diffusion sheet 400 is similar to that described above, but further includes a separate bead 424 inside the pattern scattering layer 420.

Specifically, the pattern scattering layer 420 is formed on at least one of the upper surface and the lower surface with respect to the shielding layer 410.

As shown in the figure, the pattern scattering layer 420 includes a plurality of beads 424 therein, and further increases the shielding performance by further scattering and diffusing the light transmitted from the bottom by the beads 424, At the same time, the decrease in luminance is reduced.

The beads 424 are added to the pattern scattering layer 420 to further diffuse and scatter light due to the main purpose of increasing the shielding performance of light transmitted from the bottom.

In the present invention, the beads 424 have a spherical shape and are uniformly dispersed in the pattern scattering layer 420, and a plurality of the beads 424 are formed to have a non-uniform size. At this time, the beads 424 are formed to have a different material or refractive index from the pattern scattering layer 420, so that light scattering occurs in the pattern scattering layer 420.

That is, since the pattern scattering layer 420 includes the beads 424 therein, light scattered from the bottom of the bead 424 as well as the scattering pattern 422 can be scattered and diffused.

At this time, the beads 424 have a size that causes mie-scattering corresponding to the wavelength of the light transmitted from the lower part, and the beads 424 are relatively smaller than the particles 412 contained in the shield layer 410 .

The size of the beads 424 according to the present invention has a fine size of several hundreds of nanometers to several micrometers, and is configured so that scattering of light transmitted from below can occur.

In general, scattering is a phenomenon in which light collides with a specific particle and is scattered in various directions. It refers to a phenomenon in which waves or high-speed particle beams collide with many molecules, atoms, and particles to change direction of motion and scatter. Gas, liquid, and solid. However, in solid or liquid, scattered light is synthesized and is more likely to be refracted or reflected.

Representative scattering includes Rayleigh scattering and Mie-scattering.

First, Rayleigh scattering refers to scattering occurring when the size of particles causing scattering is very small and is smaller than the wavelength of light, which is inversely proportional to the fourth power of the wavelength of light. That is, the amount of scattered light decreases sharply as the wavelength becomes longer.

Such Rayleigh scattering scatters light both forward and backward when light collides against a specific particle as shown in FIG. 7 (a).

On the contrary, non-scattering occurs when the size of a specific particle colliding with light is similar to the wavelength of light, and forward scattering is remarkable and relatively small energy is scattered backward as shown in FIG. 7 (b).

Such scattering is influenced by the density, size and shape of the particles, and particularly scattering occurs in spherical particles.

Accordingly, it is preferable that the bead 424 according to the present invention is configured such that no scattering occurs in which forward scattering occurs in order to diffuse and transmit the light transmitted from the light source 100 in the upward direction.

In this embodiment, the beads 424 have a spherical shape and are configured to have a size corresponding to the wavelength of the visible light region so that the light generated from the light source 100 can be scattered forward.

Specifically, the beads 424 may be formed of at least one of Alumina, TiO 2, Melamine, Silica, PMMA, PBMA, and PDMS, and may be formed in a spherical shape. The refractive index of the bead 424 is preferably 1.67.

The beads 424 are formed to have a size of 0.1 to 1 탆 and maximize the mie scattering effect of the light of the visible light wavelength band emitted from the light source 100, 424 in the forward direction.

If the bead 424 is more than 1000 nm in size, the bead 424 is fragile due to breaking or being touched upon contact with the light guide plate 200, resulting in deterioration of quality.

Accordingly, the bead 424 according to the present invention can scatter the light transmitted from the lower portion and is not damaged by the interference with the light guide plate 200, thereby diffusing the light transmitted from the lower portion.

Accordingly, the pattern scattering layer 420 according to the present invention can efficiently transmit the light transmitted from the lower light guide plate 200 to the upper portion by including the beads 424 therein, The decrease in luminance due to the layer 410 can be minimized.

Meanwhile, in the present invention, the beads 424 are arranged such that the distribution density is relatively increased in the pattern scattering layer 420 so as to be closer to the shielding layer 410, thereby reducing light directivity transmitted from the lower portion, The shielding performance of the diffusion sheet 400 may be increased.

5, the pattern scattering layer 420 is formed on the upper and lower surfaces of the shielding layer 410, and the beads 424 are contained therein. The pattern scattering layer 420 can be divided into an A region along the vertical direction and a B region adjacent to the shielding layer 410. The scattering pattern 422 is formed in the A region and the shielding layer 410 In the direction away from the center.

The beads 424 are distributed in the A region and the B region as shown in the region adjacent to the shielding layer 410, but the beads 424 are distributed in the region B more than the A region, Is distributed.

As described above, the beads 424 are distributed more in the region B than the region A in the region B adjacent to the shielding layer 410 in the pattern scattering layer 420, thereby increasing the shielding performance of the diffusion sheet 400.

6, when the beads 424 are distributed in the pattern scattering layer 420, the light passing through the shielding layer 410 is scattered in the pattern scattering layer 420, Scattering occurs inside the bead 424.

6A shows a state in which the beads 424 are uniformly distributed in the pattern scattering layer 420 and FIG. 6B shows a state in which the beads 424 are scattered in the pattern scattering layer 420, And the distribution density increases in the vicinity of the shielding layer 410.

As shown in the drawing, the probability that the beads 424 are adjacent to the shielding layer 410 and the light transmitted from the lower part increases, thereby causing a difference in scattering degree of light.

When the beads 424 are uniformly distributed on the pattern scattering layer 420 as shown in FIG. 6A, a path from the light passing through the shielding layer 410 until the beads 424 meet The amount of light scattering and diffusing due to the bead 424 is relatively reduced.

6 (b), when the bead 424 is disposed adjacent to the shielding layer 410 in the pattern scattering layer 420, light passing through the shielding layer 410 The path itself to meet the bead 424 is shortened, and accordingly, a relatively large scattering occurs in the bead 424.

That is, the distribution density of the beads 424 is relatively higher in a region adjacent to the shielding layer 410 than in a uniform shape, so that light transmitted from the lower portion passes through the beads 424.

6B, the beads 424 are arranged such that the distribution density is relatively larger in the region adjacent to the shielding layer 410 than in the remaining regions, as shown in FIG. 6B, It is possible to increase diffusion and scattering of the transmitted light.

As described above, the pattern scattering layer 420 according to the present invention is formed such that the distribution density of the beads 424 is increased toward the shielding layer 410 and the diffusion effect of light transmitted from the lower part is increased, .

Here, the beads 424 have a nonuniform size in a spherical shape as described above, and are formed to have a size such that light transmitted from the lower portion is not scattered.

Next, a structure in which the pattern scattering layer 420 described above with reference to FIG. 8 is formed on the upper and lower portions of the shielding layer 410 and the distribution of the beads 424 included in the pattern scattering layer 420 is different will be described. Respectively.

FIG. 8 is a view showing a modified form of the pattern scattering layer 420 of FIG. 5 in the diffusion sheet of FIG.

5, the basic structure is similar to that of FIG. 5, but the arrangement of the beads 424 provided in the pattern scattering layer 420 is different.

Specifically, the pattern scattering layer 420 is formed on the upper and lower surfaces with respect to the shielding layer 410. In the upper pattern scattering layer 420, the bead 424 has a density (density) closer to the shielding layer 410, Is increased.

Unlike the upper pattern scattering layer 420, the beads 424 are uniformly distributed in the lower pattern scattering layer 420.

In the case of the upper pattern scattering layer 420, the beads 424 are dispersed therein as described above with reference to FIG. 4, and the density of the scattered light increases while being adjacent to the shielding layer 410, To maximize scattering and diffusion effects.

Accordingly, the light passing through the shielding layer 410 is diffused and scattered by the upper pattern scattering layer 420 to improve the shielding performance.

Unlike the upper pattern scattering layer 420, the lower pattern scattering layer 420 uniformly distributes the beads 424 therein, thereby maximizing the non-scattering effect due to the beads 424. [ have.

Since the upper pattern scattering layer 420 and the shielding layer 410 may have a sufficient shielding capability, the lower pattern scattering layer 420 may be formed using the bead (424) are uniformly distributed.

In addition, since the scattering pattern of the lower pattern scattering layer 420 protrudes downward, even if the scattering pattern is stacked on the light guide plate 200, mutual shotting or scratching does not occur, have.

Of course, the beads 424 inside the lower pattern scattering layer 420 may not be distributed evenly, and may be configured to have a relatively high density at a specific position.

In order to maximize the shielding performance, the diffusion sheet 400 according to the present invention includes the pattern scattering layer 420 on the upper surface of the shielding layer 410, The bead 424 has a relatively high distribution density in the B region.

Here, the beads 424 should be formed to have a size capable of causing non-scattering as described above, so that the brightness is not reduced.

Accordingly, even if the overall thickness of the backlight is limited due to the thinning of the LCD, which is a recent trend, the diffusion and shielding of light can be performed only with the diffusion sheet 400 according to the present invention without lowering the brightness.

Next, referring to FIG. 9, a state in which a plurality of shielding layers 410 are formed in the diffusion sheet 400 according to the present invention will be described.

FIG. 9 is a view showing a state in which the shielding layer 410 in the diffusion sheet 400 of FIG. 1 is composed of multiple layers.

As shown in the figure, the shielding layer 410 is composed of a plurality of sheets and each has a predetermined haze value.

Specifically, the shielding layer 410 is not a single layer, but a plurality of sheets are stacked. In this embodiment, the shielding layer 410 is composed of a first sheet 410a and a second sheet 410b.

The first sheet 410a has a first haze value as a light transmitting material, and the second sheet 410b has a second haze value. Here, the first sheet 410a and the second sheet 410b may have different thicknesses.

As described above, the first sheet 410a and the second sheet 410b have mutually different haze values and are stacked and bonded together to form the shielding layer 410, thereby increasing the shielding performance of light transmitted from the lower portion .

In this embodiment, the first sheet 410a has a thickness L1 and the second sheet 410b has a thickness L2. As described above, the first sheet 410a and the second sheet 410b are configured to have a first haze value and a second haze value, respectively. The first sheet 410a and the second sheet 410b may include the particles 412, And is configured to have a different haze value.

The pattern scattering layer 420 is coupled to an upper portion of the shielding layer 410 including the first sheet 410a and the second sheet 410b.

The shielding layer 410 may be formed of a plurality of sheets and may have different thicknesses or different haze values to increase the shielding performance of light transmitted from the lower portion of the shielding layer 410, ) The entire thickness can be adjusted.

In this case, although not shown in the drawing, the pattern scattering layer 420 may further include the beads 424, and the light transmitted from the lower portion may be diffused by the beads 424, .

Likewise, the beads 424 have a non-uniform size in a spherical shape and are dispersed in the pattern scattering layer 420. In addition, it is preferable that the distribution density of the beads 424 in the pattern scattering layer 420 increases as the shielding layer 410 is closer to the shielding layer 410.

As described above, in the diffusion sheet 400 according to the present invention, the shielding layer 410 may be configured to have a plurality of layers and have different haze values, thereby increasing the shielding performance of light .

Referring to FIG. 10, a structure in which the pattern scattering layer 420 is formed of multiple layers in the diffusion sheet 400 of the present invention will be described.

FIG. 10 is a diagram showing a pattern scattering layer 420 in the diffusion sheet of FIG. 1, which is composed of multiple layers.

The pattern scattering layer 420 is formed on the first layer 420a having the scattering pattern 422 and the first layer 420a having the scattering pattern 422. However, And a second layer 420b disposed between the first electrode layer 420 and the shielding layer 410.

The first layer 420a is continuously formed in the second layer 420b, and the scattering pattern 422 protruding upward is formed. The scattering pattern 422 is the same as the structure described above with reference to FIG. 1, and scatters light transmitted from the bottom in a nonuniform form.

At this time, as shown in the drawing, the bead 424 is not included in the first layer 420a. Alternatively, the bead 424 may be formed at a relatively lower density than the second layer 420b, 424 may be provided.

Meanwhile, the second layer 420b is formed in a sheet shape, and a plurality of the beads 424 are dispersed therein, and the beads 424 spread and scatter light.

Here, the second layer 420b is laminated on the upper surface of the shielding layer 410 in a sheet form, and the first layer 420a is laminated on the upper layer.

The beads 424 provided in the second layer 420b have a size smaller than that of the particles 412 as described above and are formed to have a size capable of scattering light transmitted from below.

That is, as the pattern scattering layer 420 is composed of the first layer 420a and the second layer 420b and the bead 424 is included in the second layer 420b, The beads 424 are concentratedly distributed on the entire surface of the substrate 420 adjacent to the shielding layer 410.

The distribution density of the beads 424 increases as the shielding layer 410 is closer to the shielding layer 410, thereby increasing diffusion and scattering effect of light transmitted from the lower portion.

As described above, the diffusion sheet 400 having improved shielding performance according to the present invention and the backlight unit including the diffusion sheet 400 have been described. The diffusion sheet 400 includes a shielding layer 410 having a predetermined haze value, It is possible not only to diffuse the light to be scattered but also to increase the shielding performance through scattering.

Accordingly, by increasing the shielding performance of the light in the diffusion sheet 400, the light can be uniformly transmitted by preventing the pattern of the light guide plate 200 from being transmitted to the upper portion, and the bead 424 is not scattered It is possible to minimize the luminance drop due to diffusion and scattering of light.

It will be apparent to those skilled in the art that the present invention can be embodied in other specific forms without departing from the spirit or scope of the invention as defined in the appended claims. It is obvious to them. Therefore, the above-described embodiments are to be considered as illustrative rather than restrictive, and the present invention is not limited to the above description, but may be modified within the scope of the appended claims and equivalents thereof.

100: Light source
200: light-
300: condensing sheet portion
310: Lower optical sheet
320: upper optical sheet
400: diffusion sheet
410: Shielding layer
420: pattern scattering layer

Claims (12)

A shielding layer made of a light-transmitting material and formed to have a constant thickness, and including a plurality of particles therein according to a preset haze value; And
And a pattern scattering layer formed on at least one of an upper surface and a lower surface of the shield layer and including a scattering pattern partially protruding and dispersing a plurality of beads in the lower part to diffuse light transmitted from the lower part,
Wherein the beads are formed in a size relatively smaller than the particles contained in the shielding layer. The method according to claim 1,
The shielding layer
Wherein the particles having a predetermined size are uniformly dispersed in the inside of the diffusion sheet. The method according to claim 1,
The shielding layer
A first sheet having a first haze value as a light transmitting material; And
And a second sheet laminated to the first sheet and having a second haze value as a light-transmitting material. The method of claim 3,
Wherein the first sheet and the second sheet have different thicknesses. The method according to claim 1,
The pattern scattering layer may be formed,
And the distribution density of the beads is relatively higher in the vicinity of the shield layer along the vertical direction. The method according to claim 1,
The pattern scattering layer may be formed,
And a shield layer formed on the upper and lower surfaces of the shield layer,
In the pattern scattering layer formed on the upper surface of the shield layer, the distribution density of the beads is formed to be higher toward the shield layer,
And the beads are uniformly distributed in the pattern scattering layer formed on the lower surface of the shielding layer. The method according to claim 1,
The bead
Wherein the diffusion sheet is formed to have a size of 0.1 to 1 μm and minimizes the luminance degradation by mie-scattering the light of the visible light wavelength range transmitted from the lower part. The method according to claim 1,
The bead
And is made of at least one material selected from the group consisting of Alumina, TiO ₂ , Melamine, Silica, PMMA, PBMA, and PDMS,
Wherein the diffusion sheet has a refractive index of 1.45 to 2.50. The method according to claim 1,
The particles may be,
And is made of at least one material selected from the group consisting of silica, PMMA, and PBMA,
Wherein the diffusion sheet has a diameter of 1 to 9 mu m. The method according to claim 1,
The pattern scattering layer may be formed,
A first layer comprising the projected scattering pattern; And
And a second layer comprising the plurality of beads between the shielding layer and the first layer. The method according to claim 1,
The protruding scattering pattern may be formed,
Wherein the diffusing sheet has a non-uniform size and is formed on at least a part of one surface of the pattern scattering layer. A backlight unit comprising the diffusion sheet of any one of claims 1 to 11.

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