KR100672912B1 - Direct-light illuminating unit of lcd module having diffuser plate designated by surface function - Google Patents

Abstract

The present invention relates to a direct type back-light module for controlling by using a surface function, comprising: a frame, at least one fluorescent lamp installed on the frame, a reflecting plate installed on the frame and positioned below the fluorescent lamp, And a diffuser plate installed on the frame and positioned above the fluorescent lamp, wherein the diffuser plate has at least one floodlight plate, and a surface profile is directly formed on one side of the floodlight plate. The surface contour is composed of a plurality of optical conversion units to form a predetermined pattern, and the pattern is converted using a suitable surface function based on the relative spatial position of the diffuser plate, the fluorescent lamp, and the reflector plate. Obtained.

Frame, pedestal, top frame, fluorescent lamp, reflector, diffuser, side plate, floodlight, surface contour, optical conversion unit.

Description

DIRECT-LIGHT ILLUMINATING UNIT OF LCD MODULE HAVING DIFFUSER PLATE DESIGNATED BY SURFACE FUNCTION}

1 is an exploded view of a first preferred embodiment according to the present invention.

Figure 2 is a side sectional view of the first preferred embodiment according to the present invention.

Figure 3 is an enlarged side view of the diffuser plate of the first preferred embodiment according to the present invention.

4 is an enlarged perspective view of the diffusion plate of the first preferred embodiment according to the present invention.

Fig. 5 is a curve diagram of the viewing angle and light intensity of the first preferred embodiment according to the present invention.

Figure 6 is an enlarged side view of the diffuser plate of the second preferred embodiment according to the present invention.

Fig. 7 is a curve diagram of the viewing angle and light intensity of the second preferred embodiment according to the present invention.

Figure 8 is an enlarged side view of the diffuser plate of the third preferred embodiment according to the present invention.

9 is an enlarged side view of the diffuser plate of the fourth preferred embodiment according to the present invention.

* Brief description of symbols for the main parts of the drawings *

10: frame 12: pedestal

14: upper frame 18: fluorescent lamp

22: reflector plate 24, 32, 40, 46: diffuser plate

26: side plates 28, 34, 42, 44: floodlight

30, 43, 45, 48, 49, 50, 51: surface contour

31: optical conversion unit

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to liquid crystal displays, and more particularly to a direct back-light module that controls using surface functions.

Conventional liquid crystal display device is mainly composed of one liquid crystal panel and one back-light module, the liquid crystal panel itself does not emit light, the light source of the panel is provided by the back-light module. Conventional back-light modules fall into two categories, direct and side-by-side.

The direct back light module generally includes one frame, and installs one or a plurality of Cold Cathode Fluorescent Lamps (CCFLs) in the frame, and fixes one diffuser plate to the frame, It is located above, and one reflector is installed in the frame but below the fluorescent lamp. The diffusion plate serves to diffuse a light generated by the fluorescent lamp to form a uniform surface light source.

The purpose of providing the diffusion plate is to diffuse the light generated by the fluorescent lamp to form a uniform surface light source and project it onto the liquid crystal panel. However, the conventional diffusion plate is to install a non-translucent or semi-transmissive material (for example organic fillers) in one light transmitting plate to reflect or absorb light at a predetermined position.

The above-described diffusion principle covers a region of partial light of a region having a relatively high luminance among light generated by the fluorescent lamp. This technique degrades the brightness of light passing through the diffuser plate. This is contrary to the design principle of current back-light modules requiring high brightness.

It is a primary object of the present invention to provide a direct type back-light module that controls using surface functions, which can provide a relatively large brightness and viewing angle.

In order to achieve the above object, the present invention provides a direct back light module for controlling using a surface function, wherein the direct back light module includes a frame, at least one fluorescent lamp installed on the frame, and the frame. And a diffuser plate installed at a lower side of the fluorescent lamp, and a diffuser plate installed at the frame and positioned above the fluorescent lamp, wherein the diffuser plate has at least one floodlight plate and has a side surface of the floodlight plate. A surface profile is directly installed on the surface profile, and the surface profile is composed of a plurality of optical conversion units to form a predetermined pattern, the pattern being located at a relative spatial position of the diffusion plate, the fluorescent lamp, and the reflecting plate. On the basis of one appropriate surface function.

DETAILED DESCRIPTION Hereinafter, exemplary embodiments will be described in detail with reference to the accompanying drawings in order to describe the objects, features, and functions of the present invention in more detail.

Referring to FIG. 1, the direct type back-light module controlled by the surface function provided in the first preferred embodiment of the present invention includes one frame 10, three fluorescent lamps 18, and one reflector plate ( 22), one diffuser plate 24, and two side plates 26.

One frame 10 is composed of one pedestal 12 and one upper frame 14, the upper frame having one window 16.

The three fluorescent lamps 18 are represented as U-shaped Cold Cathode Fluorescent Lamps (CCFLs) in the embodiment of the present invention, which has advantages such as small diameter of tube, long life and high light effect. Have The fluorescent lamp 18 is fixed to the pedestal 12 and is also connected to a transformer (not shown) to provide the necessary power when the fluorescent lamp 18 generates light. In practice, the quantity and shape of the fluorescent lamp 18 and the transformer are determined based on the specifications of the backlight module.

The reflector plate 22 is fixed to the pedestal 12 and positioned below the fluorescent lamp 18.

The diffusion plate 24 is fixed to the pedestal 12 and positioned above the fluorescent lamp 18.

Two side plates 26 are provided on both sides of the fluorescent lamp 18 to fix the fluorescent lamp 18.

Referring to FIG. 3, the diffusion plate 24 has one floodlight plate 28, and a predetermined surface profile 30 is directly formed on one side of the floodlight plate 28. have.

The surface contour 30 has one predetermined pattern, which means that the diffusion plate 24 and other components (e.g .: the fluorescent lamp 18, the reflecting plate 22) of the backlight module Based on the relative spatial position, the projection on the convex set in numerical analysis based on the designer's own set of constraints (e.g., the luminance range and viewing angle range required by the back-light module). By using the set (POCS) method, the weight between parts conversion functions is adjusted to achieve the collection and optimization of design results in a cyclic structure method.

The diffusion plate 24 of the present invention adjusts the change of the optical path by the change of the surface contour 30, that is, the structural change of the surface contour 30 forms different surface depths on the surface of the floodlight plate 28. This is called an optical transform unit (31), and the amount of change in the optical path that can be changed by the diffusion plate 24 is determined by the size of the optical conversion unit 31 of the optical component structure ( Size). A more precise manufacturing method (smaller pixels) can be employed to increase the amount of change in the optical path to achieve light uniformity and high light transmissivity requirements of the diffusion plate 24.

However, as the pixels of the surface contour 30 are reduced, the optical path is satisfied only by the method of diffraction, not by the geometric optical method, and in the optical principle the diffraction can be approximated by the method of Fourier Transfer. Can be.

Each part of the back-light module does not change over time, so all parts are designed, merged and manufactured. This reduces installation space, installation difficulty, and reduces the attenuation of light energy, improving the diffraction efficiency of the entire back-light system.

In our practical experience, the Y-G algorithm can be used to obtain surface contours 30 that are relatively close to the actual phase. The surface contour 30 can be realized by etching, printing or electroforming.

Another feature of the invention is that the height and width of each phase of the surface contour 30 of the diffuser plate 24 may not be equal to each other. The conventional method uses phase average distribution to obtain the actual phase. However, the present invention does not determine the etching depth by a conventional average distribution method. In the present invention, assuming that the etching depth and width of each step may be different, a positive-field Far-Field diffraction result is obtained in which any combination is positive under all combinations of height and width. The formula for calculating phase is as follows:

In FIG. 4, the surface contour 30 of the diffusion plate 24 under a microscope is shown, and the material of the floodlight plate 28 is a polymer copolymer (for example: polymethyl methacrylate). The thickness is about 2 mm. The surface contour 30 consists of a plurality of optical conversion units, each optical conversion unit having one predetermined height and width. The width of each optical conversion unit is about 0.5 μm to 10 μm, and the depth is 1 to 20 times the wavelength λ.

Figure 5 is the diffusion plate 24, the case with viewing angle, and display the optical distribution of the standing measured RGB 3 primary colors on the display panel over the entire surface of the use, all as can be seen by the above results the RGB 3 primary colors in the left and right 60 ^o A uniform and high light transmittance (greater than 60%) is obtained, of which the expressive properties of the R primary colors are relatively low in the case of PMMA materials.

The diffuser plate 32 provided in the second, relatively preferred embodiment of the present invention refers to the bar shown in FIG. 6, which has one surface profile 36, 38 on both sides of the floodlight plate 34. The two surface contours 36 and 38 each have one predetermined pattern. The formation method of the two surface contours 36 and 38 is the same as in the first preferred embodiment.

FIG. 7 illustrates the optical distribution state of the RGB three primary colors measured at the front of the display panel according to the viewing angle when the diffusion plate 32 is used. As can be seen, the RGB three primary colors pass through the two surface contours 36. After that, its light transmittance is increased to exceed 70%.

8 shows a diffuser plate 40 of a third preferred embodiment of the present invention, which has two floodlight plates 42 and 44, one surface contour 43 on each side of each floodlight plate 42 and 44, respectively. , 45) are installed. The surface contour 43 is located on one side facing the fluorescent lamp (not shown), and the other surface contour 45 is located on one side opposite to the fluorescent lamp.

9 shows a diffuser plate 46 of a fourth preferred embodiment of the present invention, which has two floodlight plates 48 and 50, one surface contour 49 on each side of each floodlight plate 48 and 50, respectively. , 41). The two surface contours 49 and 41 are both located on one side facing (or opposite) the fluorescent lamp.

The direct type back-light module controlled by using the surface function according to the present invention reduces the installation space and installation difficulty, reduces the attenuation of the light energy, and improves the diffraction efficiency of the entire back-light system. Have

Claims (9)

In a direct back-light module controlled using a surface function, frame, At least one fluorescent lamp installed in the frame, A reflector installed on the frame and positioned below the fluorescent lamp, and Diffusion plate installed on the frame and located above the fluorescent lamp Including; The diffusion plate includes at least one floodlight plate, and directly forms a surface profile on one side of the floodlight plate in which a plurality of optical conversion units having a predetermined depth and width are formed in a predetermined pattern. Changing the path of the ray after passing through the surface contour, The surface contour has a width of at least some of the optical conversion units smaller than 10 μm, so that when light generated by the fluorescent lamp passes through the surface contour, diffraction occurs, Said surface contour being controlled using a surface function, characterized in that the depth of at least some of the optical conversion units is between 1 and 20 times the wavelength [lambda]. The method of claim 1, And the floodlight plate of the diffuser plate is controlled by using a surface function, characterized in that the surface contour is formed on both surfaces, respectively. The method of claim 1, And said diffuser plate having two said floodlight plates, each having said surface contour on one side of each said floodlight plate. The method of claim 3, One of the surface contours on the two floodlight plates is located on the side facing the fluorescent lamp, the other is located on the opposite side to the fluorescent lamp, direct back light module controlled by using a surface function . The method of claim 3, And the surface contours on the two floodlight plates are each positioned on a side facing the plurality of fluorescent lamps. The method of claim 3, And the surface contours on the two floodlight plates are respectively located on opposite sides of the fluorescent lamp. delete delete The method of claim 1, And the surface contour is obtained by calculating using the Y-G algorithm.

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