KR100682337B1 - LCD and manufacturing method for lamp reflector used for LCD - Google Patents

Abstract

The present invention relates to a liquid crystal display and a method of manufacturing a lamp reflector employed therein, and more particularly, a light reflecting film formed on an inner surface of a lamp reflector reflecting light of a lamp among components constituting a backlight assembly constituting the liquid crystal display. The present invention relates to a liquid crystal display device and a method of manufacturing a lamp reflector employed therein, which are formed by a deposition method such as sputtering so that the surface of the light reflection film has no particle formation due to photothermal deterioration and luminance is not deteriorated, thereby extending its life.

According to the present invention, even though the light and heat continuously emitted from the lamp accommodated in the lamp reflector does not generate particles due to photodegradation on the surface of the light reflector, it is possible to prevent a decrease in reflectance of the lamp reflector and thus maintain the luminance continuously. There is an effect that the life of the lamp reflector is extended.

In addition, since the cross-sectional structure of the lamp reflector is simplified, the manufacturing process is shortened, and manufacturing cost is reduced according to the use of inexpensive materials.

Backlight Assembly, Lamp Reflector, Vacuum Deposition

Description

LCD and manufacturing method for lamp reflector used for LCD}

1 is a partial cross-sectional view of a conventional lamp reflector.

2 is an exploded perspective view showing a liquid crystal display device according to the present invention.

3 is a partial cross-sectional view of a lamp reflector according to the present invention.

4 is a flowchart illustrating a method of manufacturing a lamp reflector according to the present invention.

The present invention relates to a liquid crystal display and a method of manufacturing a lamp reflector employed therein, and more particularly, light formed on an inner surface of a lamp reflector reflecting light of a lamp among components constituting a backlight assembly constituting the liquid crystal display. A reflective film is formed by a vacuum deposition method such as sputtering, and thus there is no particle formation due to photodegradation on the surface of a lamp reflection plate, thereby reducing the luminance and extending the life thereof, and a method of manufacturing the lamp reflection plate employed therein.

As is generally known, one of the display devices, CRT (cathode ray tube; CRT) has been mainly used for monitors such as televisions, measuring instruments, information terminal devices, etc. Due to its large weight and size, it was unable to actively meet the demand for miniaturization and lightening of electronic products.

In order to replace the CRT, the advantages of small size and light weight, and a liquid crystal display (hereinafter referred to as 'LCD') displayed by digital control have been actively developed, and in recent years, the role as a flat panel display device has been sufficiently developed. Beyond workable, it is widely used in various fields, and the demand is gradually increasing.

LCDs have been miniaturized and widely used because they do not emit light, unlike CRTs, and the backlight assembly is formed on the bottom of the liquid crystal panel to supply the light required to form the screen. do.

The light generated by the lamp of the backlight assembly for the first time passes through the lamp reflector, light guide plate, reflector, sheet, etc. in the process of being delivered to the liquid crystal panel forming the screen, and the light efficiency decreases by about 51%. It is reduced.

Among the factors of the above-mentioned deterioration of the light efficiency, the largest light loss is generated in the lamp reflector, and the light loss of the lamp reflector can be found in the structure and the material of the light reflector which is responsible for the light reflection.

Referring to the partial cross-sectional view of the conventional lamp reflector of Figure 1 will be described in more detail the light loss due to the structure and material of the lamp reflector.                         

The lamp reflector 100 is formed by sputtering a silver thin film 150 on a PET film (hereinafter referred to as 'PET') to form a light reflecting film, and then a support plate formed of brass, aluminum, stainless steel, or the like. After adhesive 110 is attached to 110, it is completed by hot-melting.

The lamp reflector 100 using the silver thin film 150 has a high reflectance of 94% or more, and the reflected light is generally used more widely than other materials because the reflected light is almost the most.

However, in the lamp reflector 100 having the above-described structure, when the silver thin film 150 and the PET film 170 are exposed to the light and heat of the fluorescent lamp for a long time, the silver thin film 150 formed on the PET film 170 is exposed to light. A photodeterioration phenomenon deteriorated by heat causes silver to agglomerate at the interface between the PET film 170 and the silver thin film 150, or silver penetrates into the PET film 170 to generate a plurality of particles.

Many of the particles caused by photodegradation are 90% metal silver and about 10% silver oxide, which hinders the accurate reflection of the light, so that the reflectance of the lamp reflector 100 reached 94% at the initial level of about 70.8%. The deterioration is slowed, and the progress of photodegradation is accelerated in proportion to the irradiation intensity of light and the temperature of heat.

When the reflectance of the lamp reflector 100 decreases due to the light deterioration, the brightness of the backlight assembly is lowered and the screen display quality of the liquid crystal display is reduced. When the brightness is lowered to 50% of the initial brightness, the backlight assembly needs to be replaced. This shortens the problem.                         

In addition, as shown in FIG. 1, the cross-sectional structure of the lamp reflector 100 is complicated, which makes the manufacturing process complicated, thereby increasing the manufacturing cost.

An object of the present invention is to improve the structure and manufacturing method of the lamp reflector constituting the backlight assembly of the liquid crystal display device so that the light reflector does not deteriorate the light by the heat and light continuously generated in the lamp to reduce the brightness of the lamp reflector To extend life.

Other objects of the present invention will be described in more detail in the configuration and operation described below.

The liquid crystal display device according to the present invention comprises a display unit, a backlight assembly, a mold frame, and a top chassis. The display unit includes a liquid crystal panel formed by injecting liquid crystal between a color filter substrate and a TFT substrate, and a predetermined side portion of the liquid crystal panel. A printed circuit board spaced apart from each other, and a tape carrier package connected between the two members between the liquid crystal panel and the printed circuit board, wherein the backlight assembly comprises a lamp and a semicircular shape that encloses the lamp in a longitudinal direction as a feature of the present invention. The lamp reflector, the light guide plate disposed on the side of the lamp reflector, a plurality of sheets arranged on the upper part of the light guide plate, and the reflective sheet disposed on the lower part of the light guide plate, the mold frame is formed with a storage space for storing the backlight assembly The top chassis is mounted on top of the panel assembly, It is combined with a mold frame receiving.                     

 In this case, the light reflecting film formed on the inner surface of the lamp reflecting plate reflecting the light of the lamp in the backlight assembly is formed by a vacuum deposition method, the method of manufacturing a lamp reflecting plate employed in the liquid crystal display according to the present invention is a lamp reflecting plate The vacuum evaporation method is used as a method of forming the light reflection film of the.

Hereinafter, with reference to the drawings will be described in more detail.

Referring to FIG. 2, the liquid crystal display 200 according to the present invention includes a display unit 20, a backlight assembly 30 disposed under the display unit 20 to transmit light to the display unit 20, and a backlight. It consists of a mold frame 70 in which a storage space for receiving the assembly 30 is formed and a top chassis 10 mounted on the upper portion of the display unit 20 and coupled to the mold frame 70.

Specifically, the display unit 20 includes a liquid crystal panel 21 formed by injecting liquid crystal between a color filter substrate and a TFT (Thin Flim Transistor) substrate, and a predetermined edge portion of the liquid crystal panel 21. It consists of a printed circuit board 23 and a plurality of tape carrier packages 25 spaced apart from each other.

A plurality of liquid crystal capacitors (not shown) are formed in a matrix form on the TFT substrate of the liquid crystal panel 21, and TFT arrays (not shown) corresponding to the liquid crystal capacitors are formed on the liquid crystal capacitors. It is configured to share a power line in one row or column.

In order to connect the printed circuit board 23 on which the control signal for driving the TFT array is generated with the liquid crystal panel 21, a plurality of tape carrier packages 25 are formed on the printed circuit board 23 and the liquid crystal panel 21. Physically and electrically connected between them.

The backlight assembly 30 disposed below the display unit 20 to provide light includes a lamp 55, a lamp reflector 50, and a quadrangle disposed horizontally on an open side of the lamp reflector 50. The light guide plate 40 which is a flat plate on a top surface, the sheet | seats 37 arrange | positioned and laminated on the light guide plate 40, and the reflective sheet 60 arrange | positioned under the light guide plate 40 are comprised.

The light guide plate 40 is a flat rectangular flat plate which is horizontally disposed on the open side of the lamp reflector 50 described above. For example, a light guide plate 40 of a silk printing type is used, and is diffused to be silk-printed in a matrix form on the bottom surface thereof. As the dots (not shown) are farther from the lamp reflector 50, each dot size is larger, so that the distance between the dots is narrower. As the dots are closer to the lamp reflector 50, each dot size is smaller so that the dots are smaller than each other. The distance is formed far.

The sheet 37 is formed by sequentially stacking the diffusion sheet 31, the polarizing sheet 33, and the protective sheet 35 on the light guide plate 40, and the reflective sheet 60 is disposed below the light guide plate 40. Is placed on.

In addition, the lamp reflector 50 of the present invention has a semicircular shape surrounding the lamp 55 in a longitudinal direction, and the side opposite to the light guide plate 50 based on the lamp 55 surrounds the lamp 55 largely. The upper and lower extension portions of the semicircle extend a predetermined length in the same horizontal direction as the light guide plate 50 to guide the light of the lamp 55 to the light guide plate 50 and form a body of the lamp reflection plate 50. And a light reflecting film 230 formed on the inner surface of the support plate 210 by vacuum deposition.

At this time, the support plate 210 is a metal plate formed of a metallic material such as a brass plate or stainless steel, brass is used to facilitate soldering with a ground wire, and stainless steel is selectively used to increase rigidity. The thickness of the metal plate is 0.3 to 0.5. mm is preferred.

In addition, the light reflecting film 230 is formed on the inner surface of the support plate 210 forming the shape of the lamp reflecting plate 50 as shown in FIG. 3 by a deposition process, and the material used for forming the light reflecting film 230 is light. It should have excellent reflectivity and adhesion by deposition and have low thermal expansion.

As an example of the light reflection film 230, aluminum is used. Although the light reflecting film made of aluminum has a slightly lower light reflectance than the light reflecting film made of silver, an adhesive is required because it has excellent adhesion when deposited on the support plate 210. Compared with silver, light deterioration due to light and heat is less than that of particles, which does not generate particles on the surface that cause a decrease in luminance.

In addition, the thickness of the light reflecting film 230 should be formed to reflect light at least, and becomes thicker or thinner in proportion to the time progressed in the vacuum chamber (not shown) in which the deposition process proceeds.

The liquid crystal display 200 according to the present invention having the configuration as described above has the following functions.

First, when AC power is applied to the lamp 55 from an inverter circuit (not shown), the lamp 55 emits light, and the emitted light is mirrored by the light reflecting film 230 formed on the inner surface of the lamp reflector 50. It is reflected and reflected to the light guide plate 40 with directivity in the front direction.

The light guide plate 40 changes the direction of the applied light in the vertical direction and enters the sheets 37, and the reflective sheet 60 disposed below the light guide plate 40 reflects the light passing through the light guide plate 40. The polarization sheet 31 and the diffusion sheet 33 of the sheet 37 change the incident light into the light in the front direction to improve the front brightness and convert the light into a narrow viewing angle. To improve the front brightness.

In addition, the protective sheet 35 passes through the light between the diffusion sheet 33 and the liquid crystal panel 21 on the upper portion of the diffusion sheet 33 and at the same time physically protects each other.

Each of the liquid crystal pixels (not shown) formed in the liquid crystal panel 21 has an optical shutter function that blocks and passes light applied as described above, and the printed circuit board 23 disposed on the side portion of the liquid crystal panel 21. The drive IC (not shown) formed on the VE is converted into a gate control signal and a source data signal by applying a signal applied from the timing controller (not shown) and applied to each liquid crystal pixel (not shown). Determination of blocking is performed, and the entire liquid crystal pixels block or pass light, respectively, to form the entire screen.

Light and heat are continuously generated in the lamp 55 during the operation of the backlight assembly 30 having the light generation process as described above, so that light and heat are continuously applied to the lamp reflector 50 surrounding the lamp 55. The light reflecting film 230 formed on the inner surface of the lamp reflecting plate 50 is applied to the place where light and heat are applied.

The light reflecting film 230 according to the present invention has a structure attached to the surface of the support plate 210 by vacuum deposition, as shown in FIG. 3, and the light reflecting film 230 causes photothermal degradation due to light and heat generated from the lamp reflector. As a result, silver particles do not occur, and a decrease in luminance does not occur, so that the luminance of the liquid crystal display 200 is improved to provide a uniform surface light source.

And since the cross-sectional structure is a simple structure which consists only of the support plate 210 and the light reflection film 230, the manufacturing process and manufacturing cost are reduced.

 As a method of forming the light reflection film 230, a deposition process by vacuum deposition is used as an example, as shown in FIG.

First, the support plate 210 in a flat state is bent to form an outer shape of the lamp reflector 50. (S1)

In step S1, the support plate 210 having the outer shape is connected to the cathode in the vacuum chamber (not shown) and loaded.

An anode in the vacuum chamber (not shown) is connected by loading a target of a predetermined metal material to be the light reflecting film 230 and grounded (S5).

The vacuum in the vacuum chamber (not shown) is exhausted to a predetermined pressure to form a vacuum (S7).

A predetermined amount of gas for the discharge catalyst is injected into the vacuum chamber (S9).

²~ 10

⁴ Pa가 바람직하며, 방전 촉매용 가스로는 바람직하게 Ar(아르곤)가스가 이용될 수 있다.The predetermined pressure of the vacuum is 10

² ~ 10

Pa is preferred, and Ar (argon) gas may be preferably used as the gas for the discharge catalyst.

Plasma discharge starts when a high voltage is applied to the cathode in the vacuum chamber (not shown).

The cations of the gas for the discharge catalyst are accelerated by the electrical energy to strike the target, and the light reflection film 230 is formed on the support plate 210 in which the atoms separated by the impact are connected to the cathode.

The light reflecting film 230 unloads the support plate 210 formed on the upper surface of the vacuum chamber (not shown).

As described above, the vacuum deposition used to form the light reflection film 230 may be used as a sputtering method, and preferably considering the melting point of the support plate 210 which is the target on which the light reflection film is to be formed by the deposition process. Low temperature heating may be preferably used.

On the upper surface of the light reflecting film 230, a visible light transmitting infrared reflecting film formed of a multilayer film of high refractive index metal oxide TiO 2 and low refractive index metal oxide SiO 2 is formed to transmit visible light and reflect infrared light to thereby reflect the lamp reflector 50. Embodiments of further reducing the heating energy applied to the?) Are possible, and the film quality is optically low in absorption and high in reflectance, thereby further improving the brightness of the backlight assembly.

As described in detail above, the present invention has been described in detail with respect to preferred embodiments, but those skilled in the art to which the present invention pertains, various embodiments of the present invention without departing from the spirit and scope of the present invention It will be appreciated that the present invention may be modified or modified as described above.

As described above, according to the present invention, even though light and heat continuously emitted from the lamp accommodated inside the lamp reflector do not generate particles due to photodeterioration in the light reflecting film, the lowering of the reflectance can be prevented and the luminance is maintained continuously. It has the effect of extending the life.

In addition, since the cross-sectional structure of the lamp reflector is simplified, the manufacturing process is shortened, and manufacturing cost is reduced according to the use of inexpensive materials.

Claims (5)

A lamp reflector roundly extending in a longitudinal direction in an open state and reflecting light emitted from the lamp toward an open side; A light guide plate disposed on an open side of the lamp reflection plate to guide the reflected light to the inside; A reflection sheet disposed under the light guide plate to reflect light directed to the inside of the light guide plate to the top; A sheet stacked on top of the light guide plate and configured to polarize and diffuse light applied from the light guide plate and transmit the light to the top; A display unit disposed on the sheets to form a screen using light transmitted from the sheets, And the lamp reflector comprises a support plate forming the shape of the lamp reflector and an aluminum light reflector formed on the inner surface of the support plate by vacuum deposition. delete 2. The liquid crystal display device according to claim 1, further comprising a visible light transmitting infrared reflecting film formed of a multilayer film of TiO2, which is a high refractive index metal oxide film, and SiO2, which is a low refractive index metal oxide film. delete delete

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