KR20160055650A - Backlight unit for uniform brightness and liquid crystal display device having thereof - Google Patents

Abstract

The present invention relates to a backlight capable of supplying light of uniform brightness. The backlight arranges a hole of a circular shape in a central region of a reflection plate, which reflects light, and arranges a long hole of an elliptical shape in an outer region to be coupled to a protrusion formed in a lower cover so as to prevent movement of the reflection plate and forms the long hole in the elliptical shape so as to prevent wrinkles from being generated in the reflection plate in the outer region when the reflection plate is thermally expanded due to heat generated from a light source such as an LED.

Description

BACKLIGHT UNIT FOR UNIFORM BRIGHTNESS AND LIQUID CRYSTAL DISPLAY DEVICE HAVING THEREOF BACKGROUND OF THE INVENTION 1. Field of the Invention [0001]

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to a backlight and, more particularly, to a backlight capable of supplying uniform light over the entire liquid crystal panel by preventing a decrease in luminance in a region where holes and long holes are formed for fixing a reflection plate, Device.

2. Description of the Related Art Recently, various portable electronic devices such as a mobile phone, a PDA, and a notebook computer have been developed. Accordingly, there is a growing need for a flat panel display device for a light and small size. As such flat panel display devices, a liquid crystal display (LCD), a plasma display panel (PDP), a field emission display (FED), and a vacuum fluorescent display (VFD) have been actively studied. However, mass production technology, ease of driving means, , Liquid crystal display devices (LCDs) are mainly receiving the spotlight because of realization of a large-sized screen.

The liquid crystal display element is a transmissive display element, and displays a desired image on the screen by controlling the amount of light transmitted through the liquid crystal layer by refractive index anisotropy of liquid crystal molecules. Therefore, in a liquid crystal display element, a back light, which is a light source that transmits the liquid crystal layer for displaying an image, is provided. Generally, the backlight can be roughly divided into two types.

The first is a side-view backlight that is installed on the side of the liquid crystal panel to provide light to the liquid crystal layer, and the second is a direct-type backlight that provides light directly below the liquid crystal panel.

The side-type backlight is provided on the side surface of the liquid crystal panel and can supply light to the liquid crystal layer through the reflection plate and the light guide plate. Therefore, since the thickness can be made thinner, it is mainly used for a notebook or the like requiring a thin display device. However, since the light source for emitting light is located on the side surface of the liquid crystal panel, the side-type backlight is difficult to apply to a large-area liquid crystal panel, and light is supplied through the light guide plate. Therefore, there has been a problem in that it is not suitable for large-area liquid crystal panel for LCD TV, which has recently been spotlighted.

The direct-type backlight is mainly used for manufacturing a liquid crystal panel for an LCD TV because light emitted from a light source is directly supplied to the liquid crystal layer and thus can be applied not only to a large-area liquid crystal panel but also to a high-

Meanwhile, in recent years, a light source that emits light by itself such as a light emitting device instead of a fluorescent lamp has been used as a light source of a backlight. Since the light emitting device emits R, G, and B monochromatic light, the color reproduction ratio is good when applied to a backlight and the driving power can be reduced. Typically, when light emitted from a light emitting device is supplied to a liquid crystal panel, monochromatic light is not directly supplied but white light is supplied.

However, the direct-type backlight having the above-described LED has the following problems.

In the direct-type backlight, a plurality of LEDs are disposed under the liquid crystal panel, and light is directly supplied to the liquid crystal panel. In addition, a lower portion of the LED is disposed on the reflection plate to supply light to the liquid crystal panel, and the light incident on the reflection plate is reflected by the reflection plate and then supplied to the liquid crystal panel to improve the light efficiency. However, when the reflector is disposed below the LED, if the reflector is not aligned with the set area, an area not covered by the reflector, that is, an unreflected area is generated. There is a problem that the overall luminance of the liquid crystal panel is not uniform.

When the reflector is thermally expanded due to heat generated from the LED, wrinkles are generated in the reflector. Such wrinkles cause the brightness of the reflected light supplied to the liquid crystal panel to become uneven, so that the overall brightness of the liquid crystal panel is not uniform do.

SUMMARY OF THE INVENTION The present invention has been made to solve the above-

In the present invention, circular holes are arranged in the central region of the reflection plate and elliptical slots are arranged in the outer region to prevent the reflection plate from flowing by engaging with projections formed on the lower cover. At this time, the elongated holes are formed in an elliptical shape, and it is possible to prevent the reflection plate from being wrinkled in the outer region when the reflector is thermally expanded by heat generated from a light source such as an LED.

The auxiliary reflector corresponding to the long hole is formed in a larger area than the long hole and the hole formed in the center area is formed to be equal to or larger than the short diameter of the long hole, The area of the elliptical long side of the elliptical shape can be covered to minimize the non-reflecting area of the light, so that the light of the uniform brightness can be supplied to the liquid crystal panel.

The auxiliary reflector may be formed in a circular shape, an elliptical shape, or a quadrangular shape. The auxiliary reflector may be made of the same material as the reflector, or may be made of another material.

1 is an exploded perspective view showing a structure of a liquid crystal display device according to the present invention.
2 is a sectional view showing a structure of a liquid crystal display device according to the present invention.
3 is a view showing a structure of a reflection plate according to the present invention.
4A is a view showing a shape of a first auxiliary reflector according to the present invention;
4B and 4C are views showing the shape of a second auxiliary reflector according to the present invention.
5A is a view showing another shape of a first auxiliary reflector according to the present invention;
5B and 5C are views showing another shape of a second auxiliary reflector according to the present invention;
6A and 6B are diagrams showing that the first sub reflector and the second sub reflector are disposed under the reflector, respectively.

Hereinafter, the present invention will be described in detail with reference to the accompanying drawings.

1 is a view showing a liquid crystal display device 101 according to the present invention.

1, a liquid crystal display device 101 according to the present invention includes a liquid crystal panel 110 in which pixels are arranged in a matrix form to implement an image, A driving unit 115 that applies various signals such as a scanning signal and a data signal to the panel 110 and a backlight 170 that is disposed on the back surface of the liquid crystal panel 110 and supplies light to the liquid crystal panel 110 do.

Although not shown in the figure, the liquid crystal panel 110 includes a first substrate and a second substrate and a liquid crystal layer therebetween, and implements an image as a signal is applied from the outside. A plurality of gate lines and data lines are vertically and horizontally arranged on the first substrate and define a plurality of pixel regions. A thin film transistor, which is a switching element, is formed in each pixel region, and a pixel electrode is formed on the pixel region. Though not shown in the drawing, the thin film transistor includes a gate electrode connected to a gate line, a semiconductor layer formed by stacking amorphous silicon or the like on the gate electrode, a source formed on the semiconductor layer and connected to the data line and the pixel electrode Electrode and a drain electrode.

Although not shown in the figure, the second substrate may include a color filter composed of a plurality of sub-color filters embodying colors of red (R), green (G) and blue (B) And a black matrix for separating the filters and shielding light transmitted through the liquid crystal layer.

The first substrate and the second substrate are bonded together to face each other by a sealant (not shown) formed on the periphery of the image display area to constitute a liquid crystal panel, And a cusped key formed on the first substrate or the second substrate.

The backlight 170 includes a light emitting device 172 disposed below the liquid crystal panel 110 to emit light and a liquid crystal panel 110 disposed between the liquid crystal panel 110 and the LED 172, An optical sheet 175 composed of a diffusing sheet and a prism sheet for diffusing and condensing light supplied to the LEDs 172 and a reflector 174 disposed below the LEDs 172 and reflecting the light guided downward.

A plurality of LEDs 172 are mounted on the LED substrate 173. Signal lines are provided on the LED substrate 173, and an external signal is input to the LED 172 through the LED substrate 173, thereby emitting light from the LED 172. A plurality of LEDs 173 are disposed on the lower cover 150 and a plurality of LEDs 172 are mounted on the LEDs 173 along the longitudinal direction of the LEDs 173, Is supplied to the liquid crystal panel (110).

When the LED 172 is disposed on the lower cover 150, the area corresponding to the position of the LED 172 is removed from the reflection plate 174 disposed on the lower cover 150, so that the window 174a . The LED 172 is exposed upward through the window 174a of the reflection plate 174 so that the light emitted from the LED 172 is supplied to the upper liquid crystal panel 110 through the window 174a.

The reflection plate 174 is formed by coating silver, titanium or polymer on a base such as stainless steel, brass, aluminum, or polyethylene terephthalate (PET), but is not limited thereto.

A hole 176a and a long hole 176b are formed in the reflection plate 174. The holes 176a are formed in a circular shape and disposed in a central region of the reflection plate 174 and the elongated holes 176b are formed in an elliptical shape and formed in at least two corner areas of the reflection plate 174. [

On the other hand, the first cover 152a and the second cover 152b are formed on the lower cover 150. The first protrusion 152a is formed at a position corresponding to the hole 176a and the second protrusion 152b is formed at a position corresponding to the elongated hole 176b. At this time, the first protrusions 152a and the second protrusions 152b are formed in a circular shape similar to each other. The first protrusions 152a and the second protrusions 152b are inserted into the holes 176a and the elongated holes 176b to align the reflection plate 174 and simultaneously fix the reflection plate 174 so that the reflection plate 174 To prevent the reflection plate 174 from being misaligned.

A first auxiliary reflector 177a and a second auxiliary reflector 177b are disposed below the reflector 714. [ The first auxiliary reflector 177a is disposed at a position corresponding to the first protrusion 152a and the hole 176a and is aligned with the first protrusion 152a and the hole 176a and the second auxiliary reflector 177b, Is arranged at a position corresponding to the second projection 152b and the long hole 176b and is aligned with the second projection 152b and the long hole 176b.

The first auxiliary reflector 177a and the second auxiliary reflector 177b are formed by coating silver, titanium or polymer on the base of stainless steel, brass, aluminum, PET or the like. At this time, the first auxiliary reflector 177a and the second auxiliary reflector 177b may be formed of the same material as the reflector 174 or may be formed of different materials.

The optical sheet 175 is supplied to the liquid crystal panel 110 by improving the efficiency of light output from the LED 172. [ The optical sheet 175 includes a diffusion sheet for diffusing light output from the LED 172 and a prism sheet for condensing the light diffused by the diffusion sheet to supply uniform light to the liquid crystal panel 110. At this time, the diffusion sheet is provided with one sheet or two sheets, and the prism sheet is composed of two sheets of prisms crossing vertically in the x- and y-axis directions to refract light in the x- and y-axis directions to improve the straightness.

The driving unit 115 is coupled with the liquid crystal panel 110 in various forms to supply a scanning signal and image information to gate lines and data lines formed on the liquid crystal panel 110 to drive pixels of the liquid crystal panel 110 .

The driving unit 115 includes a flexible printed circuit board (FPC) 115a and a printed circuit board 115b. A driving element such as a data driving element and a gate driving element for applying a signal to the liquid crystal panel through a gate line and a data line are mounted on the FPC 115a. Various wiring lines are formed on the printed circuit board 115b, To the electric wiring of the system fastened to the liquid crystal display device 101.

The printed circuit board 115b is disposed on the bottom surface or the side surface of the lower cover 150. At this time, since the FPC 115a is flexible, the printed circuit board 115b is folded back on the liquid crystal panel 110 so that the printed circuit board 115b is disposed on the side surface or the bottom surface of the lower cover 150.

When the printed circuit board 115b is disposed on the bottom surface of the lower cover 150, a cover shield 155 is installed on the lower cover 150. [ The cover shield 155 is folded to the bottom of the lower cover 150 to be fastened to the bottom surface of the lower cover 150 in a state that the printed circuit board 115b is covered, (150) and protects the printed circuit board (115b).

Although the printed circuit board 115b is formed on only one side of the liquid crystal panel 110 and the cover shield 155 is attached to only one side of the lower cover 150, The printed circuit board 115b may be formed on both sides of the liquid crystal panel 110 and the cover shield 155 may be attached to both sides of the lower cover 150. [

The liquid crystal panel 110 and the backlight 170 are assembled by the guide panel 140, the lower cover 150, and the upper cover 160. At this time, the liquid crystal panel 110 is placed on the guide panel 140, and the guide panel 140 is assembled by being fastened to the lower cover 150 and the upper cover 160.

FIG. 2 is a cross-sectional view illustrating an assembled structure of a liquid crystal display device according to the present invention, and the liquid crystal display device according to the present invention will be described in detail with reference to the drawings.

2, a plurality of LEDs 172 are disposed on the lower cover 150, a reflective plate 174 is disposed on the LEDs 172, and a plurality of LEDs 172 are disposed on the LEDs 172, An optical sheet 175 is disposed.

The lower cover 150 is assembled with the upper cover 160 and the guide panel 140 and the liquid crystal panel 110 is placed on the guide panel 140 so as to be spaced apart from the optical sheet 175 by a predetermined distance. Although not shown in the drawing, the upper cover 160 and the guide panel 140 may be assembled by fastening means such as a screw.

An FPC 115a is attached to one side of the liquid crystal panel 110. A plurality of data driving elements 115c are mounted on the back surface of the FPC 115a, that is, the surface of the FPC 115a, which is attached to the liquid crystal panel 110. [ Although not shown in the drawing, a plurality of pads are formed on the FPC 115a to be electrically connected to the pads of the liquid crystal panel 110, and a signal output from the data driving device 115c is supplied to the liquid crystal panel 110 . 1, a plurality of FPCs 115a are attached to the liquid crystal panel 110, and one or a plurality of data driving devices 115c are mounted on the respective FPCs 115a.

Although not shown in the figure, a printed circuit board is connected to the FPC 115a, and the printed circuit board is attached to the lower cover 150.

A window 174a is formed in the reflector 174 so that the LED 172 protrudes above the reflector 174 through the window 174a so that the light emitted from the LED 172 is transmitted through the window 174a to the liquid crystal panel 110). The LEDs 172 may be disposed on the reflector 174. At this time, the LED substrate on which the LEDs 172 are mounted will also be disposed on the reflection plate 174. [

The first cover 152a and the second cover 152b are formed on the lower cover 150 and the hole 176a and the slot 176b are formed on the reflection plate 174. The first projections 152a and the second projections 152b are aligned with the holes 176a and the long holes 176b so that when the reflector 174 is attached to the lower cover 150, And the second projection 152b are inserted into the hole 176a and the long hole 176b.

The first projection 152a and the second projection 152b are inserted into the hole 176a and the long hole 176b by aligning and fixing the reflection plate 174 to the lower cover 150 to fix the reflection plate 714 by an external force, So as to prevent the reflector 174 from deviating from the set position, thereby preventing luminance unevenness due to unevenness of the reflected light.

3 is a plan view showing the structure of a reflection plate according to the present invention. 3, a plurality of windows 174a protruding from the LED 172 are formed in a matrix shape, and a hole 176a and a long hole 176b are formed in the reflector 174, respectively, A central region and an outer region. The hole 176a and the hole 176b are formed in the reflection plate 174 to distinguish the shape of the hole into which the protrusions 152a and 152b are inserted. Therefore, the hole of the present invention is not limited to the specific term of the hole 176a and the long hole 176b, but may be called various terms. For example, in the present invention, the hole 176a and the long hole 176b may be represented by a first hole, a second hole, or the like.

As described above, in the present invention, holes 176a and elongated holes 176b having different shapes are formed in the reflection plate 174, for the following reason.

As shown in FIG. 2, the first protrusion 152a and the second protrusion 152b are inserted into the holes 176a and 176b to fix the reflection plate 174, respectively. Therefore, in order to prevent the reflection plate 174 from moving or rotating due to external external force, a plurality of holes 176a or long holes 176b are required.

The LED 172 is coupled to the reflection plate 174 so that light generated from the LED 172 is incident on the reflection plate 174 and reflected. At this time, when heat is generated in the LED 174, the generated heat is transmitted to the reflection plate 174, and the reflection plate 174 is expanded by heat.

The thermal expansion of the reflection plate 174 is isotropic in the central region of the reflection plate 174, while it is anisotropically performed in the outer region. Therefore, when the circular hole 176a is formed not only in the center region but also in the outer region of the reflection plate 174, the circular hole 176a is isotropically contracted by the thermal expansion in the central region, , The circular hole 176a contracts anisotropically due to thermal expansion in the outer region, and as a result, the luminance of the reflected light reflected from the reflection plate 174 is not uniform, and the luminance of the liquid crystal panel is not uniform It causes.

However, in the present invention, an elliptical long hole 176b is formed in the outer region of the reflection plate 174. At this time, since the major axis of the elongated hole 176b is formed in a direction with a high degree of thermal expansion, contraction of the elongated hole 176b of the reflector in the longitudinal direction of the reflector 174 during anisotropic thermal expansion of the reflector 174 in this region, The wrinkles do not occur due to the shrinkage and the shape of the long diameter 176b becomes similar to the circular shape.

The ratio of the major axis to the minor axis of the elongated hole 176b is determined by the thermal expansion coefficient of the reflector 174, the temperature of the heat generated by the LED 172, the distance between the LED 172 and the reflector 174, will be.

Referring to FIG. 2 again, a first auxiliary reflector 177a and a second auxiliary reflector 177b are disposed on the lower cover 150 near the holes 176a and the long holes 176b. At this time, a reflection plate 174 is disposed on the first auxiliary reflection plate 177a and the second auxiliary reflection plate 177b, and holes are formed in the first auxiliary reflection plate 177a and the second auxiliary reflection plate 177b, Holes 176a and 176b aligned with the holes 176a and 176b of the first protrusions 174 and aligned with the holes 176a through which the first protrusions 152a are aligned and the holes 176b and holes 176b through which the second protrusions 152b are aligned, .

Figs. 4A to 4C are diagrams showing the structures of the first auxiliary reflector 177a and the second auxiliary reflector 177b, respectively.

As shown in FIG. 4A, the first auxiliary reflection plate 177a has a circular shape having a diameter of c2, and a hole 178a having a predetermined diameter c1 is formed in a central region thereof. That is, the first auxiliary reflector 177a has a donut shape having a predetermined thickness. 2, the diameter c1 of the hole 178a is formed to be smaller than or substantially similar to the diameter a of the hole 176a (c1≥a), and the diameter of the lower substrate 150, When the auxiliary reflecting plate 177a and the reflecting plate 174 are assembled, the hole 178a of the first auxiliary reflecting plate 177a and the hole 176a of the reflecting plate 174 are aligned and then the first projection 152a is aligned And inserted into the hole 178a and the hole 176a to fix the reflection plate 174. [

4B, the second auxiliary reflection plate 177b has a circular shape of c3, and a hole 178b having a predetermined diameter c1 is formed in a central region thereof. That is, the second auxiliary reflector 177b has a donut shape having a predetermined thickness. 2, when the lower substrate 150, the second auxiliary reflecting plate 177b, and the reflecting plate 174 are assembled, the diameter c3 of the second auxiliary reflecting plate 177b is larger than the diameter of the long hole 176b b, the region exposed in the longitudinal direction of the elongated hole 176a is covered by the second auxiliary reflecting plate 177b. Since the diameter c1 of the hole 178b of the auxiliary reflecting plate 177b is smaller than the diameter b of the long hole 176b (c1 <b), the second projection 152b Holes 178b and holes 176b to fix the reflecting plate 174. [

4C, the second auxiliary reflection plate 177b may have an elliptical shape similar to the shape of the elongated hole 176b formed in the reflection plate 174. As shown in FIG. The second auxiliary reflector 177b has substantially the same shape as the elongated hole 176b but has a longer diameter and a shorter diameter than the elongated hole 176b and a diameter c1 of the hole 178b is substantially the same as that of the structure of FIG. The second protrusion 152b can be inserted through the hole 178b while covering the harbor cover 150 exposed by the long hole 176b.

Meanwhile, the first auxiliary reflector 177a and the second auxiliary reflector 177b are not limited to a circular or elliptical shape but may have various shapes.

5A to 5C are views showing examples of various shapes of the first auxiliary reflector 177a and the second auxiliary reflector 177b.

As shown in FIG. 5A, the first auxiliary reflection plate 177a may be formed in a square shape having one side length d1. The length d1 of the side of the first auxiliary reflector 177a is greater than the diameter of the hole 176b of the reflector 174. [ A hole 178a is formed in a central region of the first auxiliary reflection plate 177a and the diameter of the hole 178a is formed to be smaller than or similar to the diameter of the hole 176a of the reflection plate 174, The first protrusion 152a of the lower cover 150 protrudes through the first protrusion 178a.

As shown in FIG. 4B, the second auxiliary reflection plate 177b may be formed in a square shape having one side length d2. At this time, the length d2 of the side of the second auxiliary reflector 177b is formed to be larger than the long diameter of the slot 176b formed in the reflector 174. [ A hole 178b is formed in a central area of the second auxiliary reflector 177b and the diameter of the hole 178b is smaller than the long diameter of the elongated hole 176b of the reflector 174, And the second protrusion 152b of the lower cover 150 protrudes through the hole 178b.

Also, as shown in FIG. 4C, the second auxiliary reflection plate 177b may be formed in a rectangular shape. The length d3 of the long side of the second auxiliary reflecting plate 177b is larger than the long side of the long hole 176b of the reflector 174 and the length d4 of the short side is larger than the short side of the long hole 176b. The diameter of the hole 178b is smaller than or similar to the minor axis of the slot 176b and larger than the second projection 152b.

Therefore, the bottom cover 150 exposed by the long hole 176b is mostly covered by the second auxiliary reflector 177b and the second protrusion 152b is inserted through the hole 178b, .

6A and 6B are partial enlarged views of the reflector 174, the first sub reflector 177a and the second sub reflector 177b, respectively, and FIGS. 6A and 6B and FIG. 174, the first auxiliary reflection plate 177a and the second auxiliary reflection plate 177b will be described.

The hole 176a of the reflection plate 174 and the hole 178a of the first auxiliary reflection plate 177a are aligned so that the hole 176a and the hole 178a are arranged at the same position as shown in Figures 2 and 6A And the first protrusion 152 protrudes through the aligned hole 176a and the hole 178a.

Since the diameter c2 of the first auxiliary reflection plate 177a is larger than the diameter a of the hole 176a so that the whole of the hole 176a of the first auxiliary reflection plate 177a It is possible to cover it. The diameter c1 of the hole 178a of the first auxiliary reflection plate 177a is smaller than or equal to the diameter a of the hole 176a The first protrusion 152a of the first protrusion 152 protrudes and the peripheral area of the first protrusion 152a is exposed through a part of the hole 178a.

Therefore, since the area of the lower cover 150 at least around the hole 178a is exposed to the outside through the hole 176a, the light that is not reflected from the reflection plate 174 by the hole 178a can be minimized do. Particularly, when the diameter c1 of the hole 178a of the first auxiliary reflection plate 177a is made smaller than the diameter a of the hole 176a, the area of the lower cover 150 exposed by the hole 176a A part of the light incident on the region exposed by the holes 176a is reflected by the first auxiliary reflector 177a so that the reflectance of the non- The area is relatively reduced, and as a result, light of uniform luminance can be supplied to the liquid crystal panel.

As shown in Figs. 2 and 6B, the reflection plate 174 and the second auxiliary electrode 177b are aligned with each other. Since the diameter c3 of the second auxiliary electrode 177b is larger than the long diameter b of the elongated hole 176b formed in the reflective plate 174, the reflective plate 174 and the second auxiliary electrode 174b 177b are aligned, the lower cover 150 exposed by the elongated hole 176b is covered by the second auxiliary electrode 177b.

Since the diameter c1 of the hole 178b formed in the second auxiliary electrode 177b is smaller than or equal to the short diameter a of the elongated hole 176b formed in the reflection plate 174 (c1? A) The second protrusions 152b of the lower cover 150 protrude through the first protrusions 178b and the peripheral area of the second protrusions 152b is exposed through the holes 178b. That is, the second auxiliary electrode 177b covers most of the lower cover 150 exposed by the elongated hole 176b, and only the region of the second projection 152b and its periphery is exposed by the hole 178b.

The light emitted from the LED 172 and incident on the elongated hole 176b is transmitted through the second auxiliary electrode 177b so that the light emitted from the LED 172 and incident on the elongated hole 176b is transmitted through the second auxiliary electrode 177b, So that the non-reflection area due to the elongated hole 176b can be minimized, so that light of a uniform luminance can be supplied to the liquid crystal panel.

As described above, in the present invention, holes 176a are formed in the central region of the reflector 174 and a plurality of elongated holes 176b are formed in the outer region so that the first projections 152a and the second projections 152a formed on the lower cover 150, The reflection plate 174 is fixed to the lower cover 150 by inserting the protrusions 152b into the holes 176a and the long holes 176b, respectively. The elongated holes 176b are formed in an elliptic shape so that the holes 176a are circular and the elongated holes 176b are formed in the direction in which the reflective plate 174 thermally expands by heat from the LEDs 172. Thus, It is possible to prevent the reflection plate 174 from being wrinkled.

In the present invention, the first auxiliary reflector 177a and the second auxiliary reflector 177b are disposed in the holes 176a and 176b and the second auxiliary reflector 177a disposed in the elongated hole 176b. It is possible to cover the area of the lower cover 150 exposed by the elongated hole 176b excluding the second protrusion 152b so that the light in the lower cover 150 exposed to the elongated hole 176b passes through the non- It is possible to remove the dark spot caused by the non-reflection area of the long hole 176b on the screen of the liquid crystal display element.

Although the first auxiliary reflector 177a and the second auxiliary reflector 177b are disposed below the reflector 174 in the above description, the first auxiliary reflector 177a and the second auxiliary reflector 177b May be disposed on the upper side of the reflection plate 174. The holes 178a and 178b of the first auxiliary reflector 177a and the second auxiliary reflector 177b are aligned with the holes 176a and 176b and protrusions 152a and 152b of the lower cover 150, Is inserted through the holes to fix the reflection plate 174 and minimize the non-reflection area exposed by the slot 176b.

Although the liquid crystal display element having the specific structure has been described in the above-mentioned detailed description, it is for convenience of explanation and not for limiting the present invention. It will be understood by those skilled in the art that various changes in form and details may be made therein without departing from the spirit and scope of the invention as defined by the appended claims. Accordingly, the scope of the present invention should not be determined by the foregoing detailed description, but should be determined by the appended claims.

110: liquid crystal panel 150: bottom cover
152a, 152b: projection 172: LED
174: reflector 176a: positive hole
176b: long holes 177a, 177b: auxiliary reflector
178a, 178b: holes

Claims (10)

At least one light source disposed on the lower cover;
A reflection plate for reflecting light emitted from the light source;
A hole and a slot formed in the reflector to receive the protrusion of the lower cover to fix the reflector; And
A first auxiliary reflector and a second auxiliary reflector disposed on a lower portion or an upper portion of the reflector,
Wherein the first auxiliary reflector and the second auxiliary reflector cover the regions exposed by the holes and the elongated holes, respectively. The backlight according to claim 1, wherein the holes are circular, the elongated holes are elliptical, and the long diameter of the elongated holes is arranged in the thermal expansion direction of the reflector. The backlight according to claim 2, wherein the holes are disposed in a central region of the reflector, and the elongated holes are disposed in an outer region of the reflector. The backlight according to claim 2, wherein each of the first and second auxiliary reflection plates has a hole and is aligned with the holes and the long holes. The backlight according to claim 4, wherein a diameter of the hole of the second sub reflector is equal to or smaller than a minor axis of the slot. The backlight according to claim 1, wherein the first and second auxiliary reflectors are respectively circular or square. The backlight according to claim 1, wherein the second auxiliary reflector is elliptical or rectangular. The backlight according to claim 1, wherein the first auxiliary reflector and the second auxiliary reflector are made of the same material as the reflector. The backlight according to claim 1, wherein the first auxiliary reflector and the second auxiliary reflector are made of a material different from that of the reflector. A liquid crystal panel;
A light source for supplying light to the liquid crystal panel;
A reflection plate disposed under the light source and reflecting the light emitted from the light source;
Circular holes and elliptical slots provided in the central area and the outer area of the reflector, respectively, for inserting the projections of the lower cover to fix the reflector; And
And a first auxiliary reflector and a second auxiliary reflector disposed on a lower portion or an upper portion of the reflection plate and each having holes aligned with the holes and the long holes,
And the diameter of the hole of the second sub reflector is equal to or smaller than the minor axis of the slot, thereby covering the area exposed by the slot.

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