KR101658145B1 - Back light unit and method for assembling the same - Google Patents

Abstract

The present invention relates to a backlight unit and a method of assembling the backlight unit, which can make the assembling process of the backlight unit more easy and make the light emission luminance uniform. The backlight unit is mounted with a plurality of light sources, A plurality of array substrates arranged; A bottom cover having at least one guide pin in each of the divided regions to fix the array substrates to the respective divided regions; And a plurality of light guide plates formed corresponding to the respective array substrates and fixed together with the respective array substrates by the guide pins and converting the light traveling direction from the respective light sources.

Modular back-light unit, light-providing block,

Description

BACK LIGHT UNIT AND METHOD FOR ASSEMBLING THE SAME [0002]

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to a backlight unit and a method of assembling the backlight unit so that the assembling process of the backlight unit is facilitated and the light emission luminance thereof is made uniform.

In general, a liquid crystal display (LCD) is one of flat panel display devices for displaying images using liquid crystal. It is thin and light compared to other image display devices, has advantages of low driving voltage and low power consumption, It is widely used throughout.

Such a liquid crystal display device requires a backlight unit for supplying light since a liquid crystal display panel for displaying an image is a non-luminescent module that does not emit light by itself.

BACKGROUND ART [0002] A backlight unit is divided into a direct-type backlight unit and an edge-type backlight unit according to its structural difference. Recently, a liquid crystal display A modular back-light unit is used.

The modular backlight unit is designed so that a plurality of edge type backlights are arranged and can be dividedly driven according to the display region of an image, and both of the advantages of the edge type backlight unit and the direct type backlight unit can be utilized.

The modular backlight unit is configured by assembling a plurality of backlights, that is, a plurality of light emitting blocks, each having a light guide plate and the like arranged corresponding to each of the plurality of light source arrays divided and driven. These light emitting blocks are assembled to be coupled vertically, horizontally and vertically through a coupling screw or a screw.

However, since the conventional modular backlight unit as described above requires a plurality of light emitting blocks to be assembled and arranged, the assembling process is complicated. In other words, in the process of assembling and arranging a plurality of light emitting blocks, the light emitting blocks are often turned off, and the assembly process becomes complicated as the number of the light blocking blocks increases. Further, when the light emitting blocks are turned off, the uniformity of light emission of the backlight unit is lowered, which affects the image quality of the display image.

SUMMARY OF THE INVENTION It is an object of the present invention to provide a backlight unit and a method of assembling the backlight unit that can simplify the assembling process of the backlight unit and make the light emission luminance uniform. have.

According to an aspect of the present invention, there is provided a backlight unit including a plurality of array substrates mounted with a plurality of light sources, A bottom cover having at least one guide pin in each of the divided regions to fix the array substrates to the respective divided regions; And a plurality of light guide plates formed corresponding to the respective array substrates and fixed together with the respective array substrates by the guide pins and converting the light traveling direction from the respective light sources.

A reflective sheet formed on a front surface of each of the array substrate and the bottom cover excluding the plurality of light sources to be fixed by the guide pins and reflecting the light emitted from each of the light guide plates toward the light guide plate again, And a plurality of optical sheets formed on the light guide plate for condensing, diffusing and emitting light from the light guide plates.

Wherein the reflective sheet is formed with a plurality of first through holes through which the respective guide pins are inserted and fixed by the respective guide pins, and each of the light guide plates is provided with a plurality of guide pins Through holes are formed and fixed by the respective guide pins, and each of the array substrates is provided with a plurality of third through holes through which the respective guide pins are passed, and are fixed by the respective guide pins .

The guide pins are formed to be positioned between a plurality of light sources adjacent to each other among the light sources, and are positioned on the front surface or the rear surface of the light sources.

Wherein each of the guide pins is formed on each of the array substrates other than the bottom cover, and each of the array substrates is fixed to the bottom cover by fixing screws.

According to another aspect of the present invention, there is provided a method of assembling a backlight unit, comprising: preparing a plurality of array substrates so that a plurality of light sources are mounted on the substrate; Fixing each array substrate to each of the divided areas in a bottom cover having at least one guide pin in each of the divided areas; And forming a plurality of light guide plates to be fixed by the guide pins at respective positions corresponding to the respective array substrates.

Forming a reflective sheet on the entire surface of each of the array substrate and the bottom cover excluding the plurality of light sources so as to be fixed by the guide pins, and projecting the light from the light guide plates, And forming a plurality of optical sheets on the substrate.

The reflective sheet forming step includes allowing each of the guide pins to pass through a plurality of first through holes provided in the reflective sheet, wherein each of the light guide plate forming steps includes a plurality of light guide plates, And each of the guide pins is passed through the first through hole and the second through hole, wherein each of the plurality of array through holes is formed in a plurality of third through holes formed in the array substrate, The method comprising the steps of:

The guide pins are formed to be positioned between a plurality of light sources adjacent to each other among the light sources, and are positioned on the front surface or the rear surface of the light sources.

The backlight unit and the method of assembling the same according to the embodiment of the present invention having the above characteristics can make the assembling process of the backlight unit easier and shorten the assembling time. Further, the light emission luminance from the backlight unit can be made more uniform.

Hereinafter, a backlight unit and an assembling method thereof according to an embodiment of the present invention will be described in detail with reference to the accompanying drawings.

FIG. 1 is a perspective view showing a liquid crystal display device according to an embodiment of the present invention, and FIG. 2 is a sectional view taken along a line I-I in FIG.

The liquid crystal display device shown in FIG. 1 includes a liquid crystal display panel 140 having a plurality of liquid crystal cells and displaying an image; A backlight unit 110 for emitting light to the liquid crystal display panel 140; A mold frame 142 for supporting the liquid crystal display panel 140 and a top case 144 for covering and fixing the periphery of the liquid crystal display panel 140 and the mold frame 142.

In the liquid crystal display panel 140, liquid crystal cells are arranged in an active matrix form between the upper and lower substrates, and a thin film transistor for switching video signals is formed in each of the liquid crystal cells. In this liquid crystal display panel 140, the refractive index of each liquid crystal cell changes according to the video signal, thereby displaying an image corresponding to the video signal.

The top case 144 is formed in the shape of a rectangular band having a flat portion bent at right angles and a side portion. The top case 144 surrounds the edge of the liquid crystal display panel 140 and is fastened to the side surface of the mold frame 142.

The mold frame 142 is made of a plastic material or an aluminum alloy, and the sidewall surface of the mold frame 142 is formed into a stepped step. The liquid crystal display panel 140 is seated on the stepped surface of the mold frame 142.

The backlight unit 110 shown in FIGS. 1 and 2 includes a plurality of array substrates 120 each having a plurality of light sources 122 mounted thereon and arranged in each of predetermined divided regions, at least one guide pin A bottom cover 124 for fixing each array substrate 120 to each of the divided regions by having the guide pins 302 of the array substrate 120, A plurality of light guide plates 114 that are fixed together with the light guide plate 120 and convert the light traveling direction from each light source 122, A reflection sheet 128 formed on the front surface of the bottom cover 124 and reflecting the light emitted from each light guide plate 114 toward the light guide plate 114 and a plurality of light guide plates 114 formed on the light guide plate 114, The light from the light source 114, And a optical sheet 134.

The plurality of light sources 122 are mounted on the array substrate 120 at least one by one, and receive driving power from a light source driving circuit (not shown) to generate light. Each of the light sources 122 includes a light emitting diode of a side view type in which the direction of light emission is directed to the side light incident portion of each light guide plate 114. In other words, the light source 122 may be a side emission type light emitting diode.

Each of the array substrates 120, which are fixed to at least one light source 122 and supply driving power to the light sources 122, may be any one of a flexible plastic substrate, a metal PCB substrate, and a FR4 substrate Lt; / RTI >

2, one of the array substrates 120 including at least one light source 122 and one of the light guide plates 114 corresponding to the one array substrate 120 may be combined into a pair of light providing blocks BL . 1, the liquid crystal display panel 140 may be divided into a display area corresponding to the number of the light providing blocks BL, that is, predetermined divided areas. At this time, Respectively. Each light providing block BL is dividedly driven to be driven by a local dimming method. For example, when the light sources 122 of any one of the light providing blocks BL are turned on, the light sources 122 of the remaining light providing blocks BL are turned off or turned on But may be turned on at a lower luminance than the light sources 122 of the light providing block BL.

The bottom cover 124 is formed so as to engage with the mold frame 142 while covering the entire back direction of the backlight unit 110. On the inner surface of the bottom cover 124, at least one guide pin 302 is formed to correspond to the divided regions. Each of the guide pins 302 is formed to fix the array substrate 120 and the light guide plate 114 that are seated in the corresponding divided area. Here, each of the guide pins 302 may be integrally formed with the bottom cover 124, or may be separately formed and attached to each of the divided areas of the bottom cover 124. In addition, each guide pin 302 may be formed on each array substrate 120, rather than the bottom cover 124. In this case, each array substrate 120 is fixed to the bottom cover 124 by separate fixing screws. Hereinafter, as shown in FIG. 2, only the case where each guide pin 302 is formed integrally with the bottom cover 124 will be described as an example.

The reflective sheet 128 is formed on the entire surfaces of the array substrate 120 and the bottom cover 124 except for the plurality of light sources 122, that is, between the plurality of light guide plates 114 and the plurality of array substrates 120 do. At this time, the reflective sheet 128 is formed with a plurality of first through holes 304 through which the guide pins 302 are inserted, and are fixed by the respective guide pins 302. A plurality of light source receiving holes 118 through which the plurality of light sources 122 pass are formed in the reflective sheet 128 so that the plurality of light sources 122 protrude toward the light guide plate 114. The reflective sheet 128 thus configured reflects the light emitted from each of the light guide plates 114 toward the light guide plate 114 to prevent light loss.

Each of the light guide plates 114 is disposed for each of the divided regions so as to correspond to the respective light sources 122 mounted on the respective array substrates 120. Each of the light guide plates 114 guides light incident from each light source 122 toward the liquid crystal display panel 140. At this time, a plurality of second through-holes 306 are formed in the light guide plate 114 so that the respective guide pins 302 are penetrated, and are fixed by the respective guide pins 302.

The plurality of optical sheets 134 scatter and condense light emitted from the plurality of light guide plates 114 and increase the brightness, thereby improving light efficiency and supplying the light to the liquid crystal display panel 140. To this end, the plurality of optical sheets 134 include a light converging sheet, a diffusion sheet, and a polarizing sheet.

FIG. 3 is a detailed view showing the structure of the bottom cover and one array substrate of FIG. 1. FIG.

3, a plurality of light sources 122 are fixed to one surface of the array substrate 120. A plurality of light sources 122 are arranged on the other surface of the array substrate 120, Connectors may be provided.

A plurality of third through holes 301 through which the respective guide pins 302 are inserted may be formed on the respective array substrates 120 and may be fixed by the respective guide pins 302. Each guide pin 302 is first fitted into the third through hole 301 of each array substrate 120 so that the array substrate 120 is first fixed on the bottom cover 124. The remaining array substrates 120 are also fixed on the bottom cover 124 so as to be arranged for each of the divided regions.

The guide pins 302 are preferably positioned such that the direction of light generated from the plurality of light sources 122 does not change, that is, the influence of the light on the traveling direction of the light is minimized. Each of the guide pins 302 may be formed to be positioned between a plurality of light sources adjacent to each other among the light sources 122. The guide pins 302 may be formed on the front surface or the rear surface of the light sources 122 .

Fig. 4 is an assembled view showing the bottom cover and one array substrate of Fig. 1 in different directions. Fig.

4, the bottom cover 124 accommodates the above-described array substrate 120, the reflective sheet 128, and the plurality of light guide plates 114. Inside the bottom cover 124, The plurality of guide pins 302 formed on the surface of the light guide plate 114 are formed in the third through holes 301 of the array substrate 120, the first through holes 304 of the reflective sheet 128, and the second through holes 306 of the light guide plate 114 ) To fix the light-providing blocks (BL). At this time, each guide pin 302 is formed to be positioned between a plurality of light sources adjacent to each other among the light sources 122, and may be formed on the front side of each light source 122.

The method of assembling the backlight unit of the present invention constructed as described above will now be described.

First, a plurality of array substrates 120 on which at least one light source 122 is mounted are prepared. At the same time, a bottom cover 124 having at least one guide pin 302 formed in each of the divided areas is prepared.

Next, each array substrate 120 is fixed to each divided region of the bottom cover 124 so that the at least one guide pin 302 passes through the third through holes 301 of each array substrate 120 .

The reflective sheet 128 is fixed to the front surface of the bottom cover 124 so that the at least one guide pin 302 penetrates the first through holes 304 of the reflective sheet 128. At this time, the respective light sources 122 protrude into the respective light source receiving holes 118.

Next, a plurality of light guide plates 114 corresponding to the number of the array substrates 120 are prepared, and the light guide plates 114 are installed on one side of each array substrate 120. At this time, the light guide plates 114 are fixed so that the at least one guide pin 302 passes through the second through holes 306 of the light guide plate 114. Thereafter, at least one optical sheet 134 may be disposed on the entire surface of the light guide plate 114 so as to be assembled with the liquid crystal display panel 114 together with the mold frame 142.

As described above, in the backlight unit and the assembling method thereof according to the present invention, each of the light providing blocks BL can be easily assembled by the plurality of guide pins 302. Therefore, the assembling process of the backlight unit as a whole becomes easier, so that the assembling time can be shortened. It is also possible to prevent the light guide plate (302) from being tilted by the respective guide pins (302), that is, the array substrate (120), the reflective sheet (128) and the light guide plate (114) The light emission luminance becomes more uniform.

It will be apparent to those skilled in the art that various modifications and variations can be made in the present invention without departing from the spirit or scope of the general inventive concept as defined by the appended claims and their equivalents. Will be clear to those who have knowledge of.

1 is a perspective view illustrating a liquid crystal display device according to an embodiment of the present invention.

2 is a cross-sectional view taken along a line I-I in Fig.

3 is a detailed view showing the structure of the bottom cover and one array substrate of FIG. 1;

Fig. 4 is an assembly drawing showing the bottom cover and one array substrate of Fig. 1 in different directions. Fig.

Claims (9)

A plurality of array substrates mounted with a plurality of light sources and arranged for each of the predetermined division regions; And at least one guide pin disposed between adjacent light sources of the plurality of light sources, wherein the guide pins are inserted into third through holes provided in the array substrate to fix the array substrates to the divided areas, ; A plurality of light guide plates arranged corresponding to the array substrate and provided with a plurality of second through holes to be fixed by the guide pins together with the array substrate, and converting a light traveling direction from each light source; A reflective sheet which reflects light emitted from the light source toward the light guide plate and has a plurality of first through holes through which the guide pins are inserted and is fixed by the guide pins on the bottom cover; And And a plurality of optical sheets arranged on the light guide plate for condensing and diffusing the light from the light guide plate and emitting the light. delete delete The method according to claim 1, Each of the guide pins Wherein the backlight unit is located at a front side or a rear side of the light sources. The method according to claim 1, Each of the guide pins Wherein each of the array substrates is provided on each of the array substrates and is fixed to the bottom cover by fixing screws. Preparing a plurality of array substrates so that a plurality of light sources are mounted and arranged in each of the predetermined division regions; Fixing the array substrate to the bottom cover with at least one guide pin disposed between adjacent ones of the plurality of light sources in each of the divided regions; Coupling a plurality of light guide plates to be fixed by the guide pins to positions corresponding to the respective array substrates; Coupling the reflective sheet to the entire surface of the array substrate and the bottom cover excluding the plurality of light sources to be fixed by the guide pins; And And coupling the plurality of optical sheets onto the plurality of light guide plates so as to condense and diffuse the light from the light guide plate and emit the light, Wherein the step of joining the reflective sheet includes a step of allowing the guide pin to pass through the plurality of first through holes provided in the reflective sheet, wherein the step of joining the light guide plate includes a step of joining the plurality of second through holes provided in the light guide plate, Wherein the step of assembling the array substrate includes a step of allowing the guide pin to pass through the plurality of third through holes provided in the array substrate. delete delete The method according to claim 6, Each of the guide pins Wherein the light sources are located on the front side or the rear side of the light sources.

Images