KR20070076387A - Optical device capable of reducing brightness non-uniformity - Google Patents

Abstract

Optical devices capable of reducing brightness unevenness (Mura phenomenon) include a light incident surface and a light exit surface. Light passes through the optics from the light incident surface to the light exit surface. The optical device includes at least one microstructured layer located on one surface of the light incident surface or the light exit surface. The at least one microstructured layer has a plurality of first patterns comprising a plurality of discrete microelements and at least one second pattern comprising a single integrated element. The integrated element is larger than each of the separated microelements. The first pattern may cooperate with the second pattern to form a predetermined pattern for changing the transmittance of the optical device, thereby reducing brightness unevenness. The microstructured layer can also reflect back to the original light path to reuse some of the light to increase the overall luminous efficiency of the optics.

Description

Optical Device Capable of Reducing Brightness Non-uniformity

The present invention relates to an optical device such as a light diffusion film, a light diffusion plate and a light concentrating sheet, and more particularly, to an optical device including a microstructure capable of shielding, reflecting and diffusing light. Such optics are particularly suitable for optics, such as backlight modules, in which LEDs are used as light sources, to overcome the problem of bright-dark zones caused by the brightness of unevenly distributed light emitting surfaces in the optics. Do.

In the following description, the term "mura phenomenon" refers to the region of light and dark caused by the brightness of the light emitting surface which is unevenly distributed at the optical surface.

In the prior art illustrated in FIG. 1, the light diffusion sheet 1 includes a diffusion layer 2a disposed on one surface of the transparent substrate 2 and the transparent substrate 2, and an antistatic layer disposed on the other surface of the transparent substrate 2. (2b). Light enters the surface opposite the surface of the substrate 2 (light incident surface), passes through the transparent substrate 2 toward the diffusion layer 2a, and then the surface facing the surface of the substrate 2 (light exit) Surface) and towards the diffusion layer 2a. Light passing through the light diffusion sheet 1 is uniformly diffused because of the structure of the diffusion layer 2a.

Since the light diffusing sheet 1 is used in the backlight module for the actual design and structural operation of the backlight module, the generated light interference causes the uniformity of the light emitted from the light incident surface of the light diffusing sheet 1. Inconsistent throughout, dark and dark areas are formed. This problem is most severe in photometric backlight modules used in small liquid crystal displays (LCDs). However, at present, there is no related technology that can be used to overcome this problem.

In Fig. 2, the strip black shielding layer 2c printed in the light emitting area having no effect at the edge of the diffusion layer 2a (or antistatic layer 2b) of the light diffusion sheet 3 has a light leakage at the edge of the backlight module. It is used to mask or reduce the dark and dark areas. However, this cannot reduce the contrast zone in the effective light emitting zone, and only has a shielding function. It is not possible to control the luminance flux to reduce the overall luminous efficiency or to reflect the light back into the original path of light for reuse.

It is a main object of the present invention to provide an optical device capable of reducing brightness unevenness (e.g., a murah phenomenon). At least one micro structural layer is disposed in the optical device on the upper or lower surface of a region (visible region and invisible region) exhibiting unevenly distributed brightness, and the luminance passes through the microstructure layer. By reducing the luminous flux, an improved function of reducing and eliminating unevenly distributed brightness can be obtained. The microstructured layer may be applied to optical devices such as a light diffusing film, a light diffusing plate and a light concentrating sheet.

It is still another object of the present invention to increase the overall luminous efficiency of the optical device by reflecting the microstructured layer disposed in the optical device back to the path of the original light in order to reuse part of the light.

Another object of the present invention is that the microstructured layer disposed in the optical device has a transmittance, so that diffusion occurs when light passes through the microstructured layer so that the emission of the region is more uniformly distributed at every viewing angle. will be.

In one aspect of the invention, an optical device capable of reducing the dark and dark areas includes a light incident surface and a light exit surface. Light passes through the optics from the light incident surface to the light exit surface. The optical device includes at least one microstructured layer located on a light incident surface or a light exit surface. The at least one microstructured layer has a plurality of first patterns comprising a plurality of discrete micro elements and at least one second pattern comprising a single integral element. A single integrated element is larger than each microelement separated. The first pattern cooperates with the second pattern to form a predetermined pattern for changing the transmittance of the optical device to reduce the muura phenomenon.

Detailed Description of the Illustrated Embodiments

In Fig. 3, the light diffusion sheet 4 of the first embodiment of the present invention can reduce the murah phenomenon, and the substrate 2, the diffusion layer 2a and the substrate 2 disposed on one surface of the substrate 2 are reduced. An antistatic layer (2b) disposed on the other surface of the). The microstructured layer 2d disposed on the surface (light incidence surface) opposite to the surface of the substrate 2 faces the antistatic layer 2b or on the surface (light exit surface) facing the surface of the substrate 2. The disposed microstructured layer 2d faces the diffusion layer 2a.

The microstructured layer 2d is arranged according to the region where the actual mura is generated, and the microstructured layer 2d comprises a plurality of opaque or translucent first patterns 2e and a single integrated element comprising separate microelements. It has one opaque or translucent second pattern 2f. The plurality of first patterns 2e are arranged in a column from the bottom to the top. Each separated microelement has a circular shape and the same size. The distance between the adjacent first patterns 2e at each longitudinal end and the distance between two adjacent longitudinal ends of the first pattern 2e gradually change from the bottom to the top. The second pattern 2f is located between the two columns of the first pattern 2e, and the single integrated element is designed to be larger than each discrete microelement, so that the second pattern 2f and the plurality of agents One pattern 2e cooperates to form a specific pattern whose density is different.

3 shows a second pattern 2f cooperating with a plurality of first patterns 2e. However, two or more second patterns may be used in response to actual needs, and the shape or size of the second pattern or the distance between adjacent first patterns of each of the second patterns may be changed to form various specific patterns having different densities. .

Therefore, by changing the arrangement density of the first pattern 2e and the second pattern 2f in the microstructured layer 2d, the microstructured layer 2d has a set transmittance for changing the luminance flux, thereby reducing and eliminating muura. In order to achieve the object of improvement, the transmittance can be changed to control the brightness distribution of the mura region. In addition to this, by changing the transparency of the first pattern 2e and the second pattern 2f or changing their density and transparency, the same purpose can also be achieved.

The first pattern 2e and the second pattern 2f use, but are not limited to, opaque or translucent anti-ultraviolet (UV) inks by dot printing, or by coating, vacuum evaporation or ion sputtering. It may be formed using a translucent material comprising polycarbonate (PC).

Second, since the microstructured layer 2d is not a completely black shielding material, a portion of the light reflects as it passes through, and the light returns to the original light path for reuse, thereby reducing the overall luminous efficiency of the light diffusion sheet 4. Increase. When light passes through the microstructured layer 2d formed of the first pattern 2e and the second pattern 2f, diffusion may occur to more uniformly distribute light at each viewing angle.

FIG. 4 shows a light diffusing sheet 5 which can reduce the muura phenomenon of the second embodiment in the present invention. The main difference between FIG. 3 and FIG. 4 is that the microstructured layer 2d has a plurality of first patterns 2e comprising separated microelements arranged longitudinally from left to right, with the first adjacent adjacent at each longitudinal end. The size of the patterns gradually changes from left to right, and the distance between the adjacent first patterns 2h in each longitudinal stage and the distance between two adjacent longitudinal ends of the first patterns 2h gradually increase from left to right. It changes. The second pattern 2i is located on the right side of the plurality of first patterns 2h and a single integrated element is designed to be larger than each of the separate microelements. The second pattern 2i cooperates with the plurality of first patterns 2h to form a specific pattern of varying density, so that the transmittance can be changed to control the light distribution in the mura region, thereby improving the reduction or elimination of the mura. The purpose can be achieved.

Although the present invention has been disclosed in detail with the foregoing preferred embodiments, it is not to be used to limit the present invention. The present invention can be changed or improved under the premise of maintaining its spirit and scope. Accordingly, the subject matter of the present invention is defined by the following claims.

The invention provides an improved function of reducing and eliminating unevenly distributed brightness by placing at least one microstructured layer in an optical device to reduce the luminance flux through the microstructured layer. It can be widely used for optical devices such as a diffusion film, a light diffusion plate, and a light concentrating sheet.

1 is a schematic view of a conventional light diffusion sheet.

2 is a schematic view of a conventional light diffusion sheet having an edge shielding layer.

3 is a schematic diagram of a light diffusing sheet capable of reducing the muura phenomenon in the first embodiment.

4 is a schematic diagram of a light diffusion sheet capable of reducing the muura phenomenon in the second embodiment.

Claims (7)

An optical device comprising a light incidence surface and a light exit surface, wherein light is passed from the light incidence surface to the light exit surface and capable of reducing brightness inequality. The optical device includes at least one microstructured layer located on one surface of the light incident surface or the light exit surface, wherein the at least one microstructured layer includes a plurality of first patterns including a plurality of separated microelements. And at least one second pattern comprising a single integrated element larger than each of the separated microelements, wherein the first pattern cooperates with the second pattern to form a predetermined pattern for changing the transmittance of the optical device. Optical device that forms to reduce brightness unevenness. The method of claim 1, And the density of the predetermined pattern is designed to change the transmittance of the optical device to reduce brightness unevenness. The method of claim 2, The density design is achieved by changing the shape or size of each pattern or the distance between adjacent patterns. The method of claim 1, And the transparency of each pattern is formed by varying the material of the pattern in order to change the transmittance of the optical device to reduce brightness unevenness. The method of claim 1, Each microelement is printed with dots formed of anti-ultraviolet ink. The method according to any one of claims 1 to 5, The optical device is a light diffusing device, Board; A diffusion layer disposed on one surface of the substrate, wherein one surface of the substrate is a surface opposite to the surface of the diffusion layer, and the surface of the diffusion layer is used as a light exit surface facing one surface of the substrate; And An antistatic layer disposed on the other surface of the substrate, wherein the other surface of the substrate is a surface opposite to the surface of the antistatic layer, and the surface of the antistatic layer is used as a light incident surface facing the other surface of the substrate Antistatic layer Including; Wherein the at least one microstructure layer is disposed on one surface of the diffusion layer used as the light exit surface or on one surface of the antistatic layer used as the light incident surface. The method according to any one of claims 1 to 5, The optical device is a light concentrator, A substrate on which one surface is used as a light incident surface; And A light concentrating layer disposed on the other surface of the substrate, wherein the other surface of the substrate is a surface opposite to the surface of the light concentrating layer, and the surface of the light concentrating layer is opposite to the other surface of the substrate; Light Concentrating Layer Used As Including; Wherein the at least one microstructure layer is disposed on a substrate used as one of a light concentrating layer or a light incident surface used as the light exit surface.