KR20090094683A - Liquid crystal display device - Google Patents

Abstract

An LCD device is provided to prevent a substrate from being detached from a lower cover during the mechanical vibration/impact test. A lower cover(100) includes a bottom frame and a side frame extended from at least one side of the bottom frame. The side frame has at least one through-hole(101) and at least one burring structure protruded from the side frame. On a substrate(141), a hole coupled with the burring structure is formed. A light source unit includes a light emitting unit for providing the light by being coupled with the through-hole of the lower cover. A fixing unit(145) fixes the substrate to the side frame by being coupled with the burring structure.

Description

Liquid crystal display {LIQUID CRYSTAL DISPLAY DEVICE}

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to a liquid crystal display device, and more particularly, to a liquid crystal display device in which a substrate is adhered to and fixed on a lower cover through a through hole and a burring structure formed on the lower cover.

In general, a liquid crystal display (LCD) is a typical flat panel display that displays an image by adjusting the amount of light transmitted to correspond to an image signal. However, the liquid crystal display device requires a separate light source to provide light from the back of the liquid crystal display in order to visually represent the image for the reason that it is not a self-luminous element that can emit light by itself.

At this time, the liquid crystal display device includes a power source circuit for driving the light source, including a light source itself, that is, a lamp to irradiate light from the rear surface of the liquid crystal module (LCM) to the liquid crystal panel of the front surface; It includes a backlight unit (Back-light Unit), which is an integral part composite to achieve a uniform planar light.

Such backlight devices are classified into two types, a direct type and an edge type according to a light irradiation method. In recent years, a backlight type employing a surface light source such as an LED (Light Emitting Diode) and Edge type flat panel backlights have also been studied.

Here, the edge type backlight device is a position of the light source is located on the side of the liquid crystal module, the light from the light source forms a planar light through the light guide plate. This type of backlight is difficult to avoid the degradation of the overall brightness. Therefore, in order to obtain uniformly distributed luminance, a more efficient light induction system, that is, a light induction system from a relatively long distance from a light source, is required, and to minimize losses in the light transmission process from a light source to a relatively long distance. Advanced optical technology has been required.

1 is a cross-sectional view of an edge-type LED liquid crystal display device according to the prior art.

As shown in FIG. 1, the edge type LED liquid crystal display device includes a liquid crystal panel 50 in which an image is realized, a light source means 20 provided under one side of the liquid crystal panel 50 to provide light, and the light source means. A light guide plate 31 for guiding light provided from 20, and an optical member 30 such as a diffusion sheet 33 and a prism sheet 35 to improve the optical characteristics of the light transmitted through the light guide plate 31. do.

Here, the light source means 20 is composed of a substrate 22 and a plurality of LEDs (24). At this time, the LED 24 is mounted in a row on the substrate 22 and is electrically connected to an external power source. In addition, the substrate 22 on which the plurality of LEDs 24 are mounted is fixed in the light source cover 26, more precisely, the lower cover 10 through the double-sided tape 28 on the inner side of the light source cover 26. It is fixed perpendicular to the bottom surface of the.

The light guide plate 31 is provided on the lower cover 10 to guide light provided from the LEDs 24 of the light source means 20 positioned at one side, and the light is entirely directed to the upper surface of the light guide plate 31. It serves to disperse. At this time, the reflector 15 disposed below the light guide plate 31 helps the light reflection efficiency.

The diffusion sheet 33 is disposed on the upper surface of the light guide plate 31 to uniformly distribute the light transmitted through the light guide plate 31.

In addition, a prism sheet 35 is disposed on an upper surface of the diffusion sheet 33, and the prism sheet 35 has a predetermined region, that is, an image, of the liquid crystal panel 50 in which the light from the diffusion sheet 33 is implemented. Guide into the area.

A protective sheet (not shown) may be disposed on the upper surface of the prism sheet 35 to protect the prism sheet 35 from scratches and the like.

In addition, the upper side of the prism sheet 35 is provided with a main frame 40 of the rectangular frame shape made of a synthetic resin or a stainless steel (Stainless STEEL) molded body is fastened.

The liquid crystal panel 50 is provided on the main support 40. The liquid crystal panel 50 includes a thin film transistor array substrate and a color filter substrate on which red (R), green (G), and blue (B) color filters are bonded to face each other so that a uniform cell gap is maintained. It consists of a liquid crystal layer formed between two substrates.

The upper cover 60 covers four edge regions of the liquid crystal panel 50 and is assembled and fastened to the main support 40.

However, in the above structure, the substrate attached to the inner surface of the light source cover through the double-sided tape is detached from the light source cover during the instrument test such as the vibration and impact test, or by the high heat of the LED in the temperature environment and the general environment. The adhesive strength of the double-sided tape is lowered, causing problems such as the substrate falling from the light source cover, thereby reducing the reliability of the product.

In addition, when attaching the substrate through the double-sided tape to the light source cover, a sufficient working space is not secured, and the work is cumbersome, and even if the work is made, defects frequently occur, which wastes time and money.

Accordingly, the present invention has been made to solve the above problems, the object of the present invention is to provide a substrate on the side frame through a through hole and a burring structure formed on the side frame of the lower cover, and a fixing means fastened to the burring structure. It is an object of the present invention to provide a liquid crystal display device fixed in close contact.

Liquid crystal display according to the present invention for achieving the above object is formed of a bottom frame and a side frame extending from at least one side of the bottom frame, the side frame is formed at least protruding from at least one through hole and the side frame A lower cover having one burring structure; A light source means comprising a substrate having a hole fastened to the burring structure and a light emitting means fixed on the substrate and fastened to a through hole of the lower cover to provide light; Fastening means fastened to the burring structure to fix the substrate in close contact with the side frame; It is characterized in that it comprises a liquid crystal panel provided on the upper side of the lower cover to receive light.

As a result of the above configuration, in the liquid crystal display according to the present invention, the substrate fixed to the lower cover is tightly coupled through the burring structure of the lower cover and the fixing means fastened to the burring structure, and thus the substrate is covered by the lower cover during the mechanical vibration and impact test. Desorption from the product does not occur and the reliability of the product will be secured.

If the substrate is fixed from the outside of the side frame of the lower cover, sufficient working space is secured, and work is performed according to a clear assembly standard through the burring structure of the lower cover and the hole of the substrate coupled to the burring structure. Improvements are expected, which will save some money.

In addition, by replacing the lower cover without a separate light source cover as compared to the prior art by replacing the role of the light source cover will be reduced somewhat accordingly.

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

FIG. 2 is an exploded perspective view of a liquid crystal display according to a first embodiment of the present invention, and FIG. 3 is a cross sectional view of FIG.

As shown in FIG. 2 and FIG. 3, the liquid crystal display according to the first exemplary embodiment of the present invention is provided with a liquid crystal panel 160 on which an image is implemented, and provided below the liquid crystal panel 160 to provide light. Consists of a backlight device, the backlight device is a light source means 140 is coupled through a through hole 101 formed on the side frame of the lower cover 100 and a burring structure 103 protruding from the side frame; Is fastened to the burring structure 103 is configured to include a fixing means 145 for fixing in close contact with the light source means 140 on the side frame of the lower cover.

First, the lower cover 100 is formed of an electro galvanized steel sheet (EGI) or aluminum (Al), etc., which is a bottom frame that forms a floor, and extends perpendicularly from at least one edge of the floor frame to form sidewalls. Consists of side frame.

At this time, the at least one side frame is formed in a 'c' shape, the plurality of through-holes 101 formed in a row at regular intervals are formed on the side frame forming the c-shape. Here, the c-shaped side frame serves to prevent the light provided from the light emitting means 143 inserted and fastened from the outside through the through hole 101 of the side frame to leak to the edge region of the liquid crystal panel 160. have.

Of course, the through-holes 101 formed on the side frame of the lower cover 100 to form a row as in the present invention are upper and lower sides according to the arrangement of the light emitting means 143 fixed on the substrate 141. It is possible to form a variety of modifications, such as formed in two rows, as well as the shape of the through hole 101 can be formed and varied in a variety of squares, circles, and triangles, depending on the shape of the light emitting portion of the light emitting means 143 .

In addition, a burring structure 103 is formed between the through holes 101 formed at regular intervals on a frame perpendicular to the bottom frame on the side frame of the lower cover 100, and the burring structure 103 is By alternately forming between the through holes 101 to the upper and lower sides, they form a zig-zag shape as a whole.

At this time, the burring structure 103 may be formed through a separate burring process after injection molding of the lower cover 100 to form a reverse burring protruding from the inside of the side frame to the outside, that is, the burring structure 103 ) May be formed to be smaller or lower than the thickness of the substrate 141 constituting the light source unit 140. This will be described later, but may be considered in view of the receiving groove of the substrate 141 fastened to the burring structure 103.

In addition, a hole is formed inside the burring structure 103, and a screw thread is formed on the side wall of the inside where the hole is formed to form a screw structure. In addition, in the present invention, for example, a thread is formed outside the burring structure 103 to form a bolt structure.

Above all, in the present invention, the burring structure 103 is formed in a zigzag shape on the side frame of the lower cover 100 so that the substrate 141 fastened through the burring structure 103 is This is to release the heat generated from the light source means 140 easily to the outside by being firmly fixed to the side frame.

Therefore, the burring structure 103 may be formed in various ways on the side frame in a range that facilitates the heat dissipation. That is, it may be formed to correspond to the holes formed on each side of each of the substrate 141 only one, and in addition to the holes formed in the center area to correspond to the holes, as well as two rows in the upper and lower portions It may be formed respectively.

Furthermore, a separate thermal conductive material such as grease or a double-sided tape may be additionally used between the side frame of the lower cover 100 and the substrate 141 constituting the light source unit 140 to help thermal conduction more efficiently. It may be.

The reflective plate 110 is attached to the bottom frame of the lower cover 100. Such a reflector 110 may be a film coated with a white polyester film or metal (Ag, Al), etc., the light reflectance of the visible light in the reflector 110 is about 90 ~ 97% and the coated film The thicker it is, the higher the reflectance is.

In addition, the light source means 140 is provided on the outside of the side frame forming the U-shape in the lower cover 100. At this time, the light source means 140 includes a substrate 141, such as a printed circuit board (PCB) or a metal PCB, and light emitting means 143, such as an LED package, formed and arranged at regular intervals on the substrate 141. have.

Between the fixing of the light emitting means 143 on the substrate 141, holes are formed in the upper and side portions, respectively, to form a zig-zag shape. Through this, the light emitting means 143 on the substrate 141 is The through holes 101 of the lower cover 100 are fastened, and the holes of the substrate 141 are fastened correspondingly to the burring structure 103 of the lower cover 100, respectively. When the assembling-fixing of the burring structure 103 and the substrate 141 of the lower cover 100, the operation is made easier according to the clear assembly standard when assembling the substrate 141 to the lower cover 100. As a result, workability for assembly may be improved, and thus costs may be saved.

In addition, the substrate 141 in which the hole is formed may be additionally formed with a concave receiving groove in a range smaller than the thickness of the substrate 141 around the hole, which will be described later, but is fixed to the burring structure 103. It is contemplated that the head portion of the means 145 is received.

Regarding the light emitting means 143, LED elements of R, G, and B may be manufactured separately and fixed on the substrate 141, but a cluster of LED chips of R, G, and B may be fixed. It is also possible to form an LED package to implement white light as much as possible. Furthermore, the present invention implements white light using a yellow phosphor on a chip providing blue light, or R and G phosphors are applied to a chip providing blue light, or green on a chip providing blue and red light. It may include a light emitting means 143 for applying white phosphor to implement white light. In addition, since the light emitting means 143 such as OLED (Organic Light Emitting Diode) is possible as well as LED, it is not particularly limited thereto.

A fixing means 145 such as a screw is fastened to the inside of the hole of the burring structure 103 exposed through the substrate 141 coupled to the outside of the side frame of the lower cover 100 to the outside. At this time, as described above, when the burring structure 103 formed on the side frame of the lower cover 100 is in the form of a bolt, the fixing means 145 may be a nut structure.

Furthermore, since the fixing means 145 may include a head portion of a constant thickness, in this case, the head portion is mentioned above for flexible fastening with the structure to be fastened later, for example, the main support 150. As described above, it may be stored in a concave storage groove formed on the substrate 141.

When the fixing means 145 is fastened to the burring structure 103 of the lower cover 100, the substrate 141 in the present invention is detached from the side frame of the lower cover 100 when an impact is applied from the outside. Not only does not occur, the substrate 141 is in close contact with the side frame of the lower cover 100 to increase the thermal conductivity between the lower cover 100 and the substrate 141 generated from the light emitting means 143 Heat may be easily released to the outside through the substrate 141.

The light guide plate 147 is provided on the lower cover 100 to which the reflective plate 110 is attached. The light guide plate 147 is formed of a polymethymethacrylate (PMMA) material. The light guide plate 147 of the PMMA material has the highest transparency and gloss since it has the least absorption of light in the visible light region among polymer materials. In addition, high mechanical strength does not break or deform, light and strong chemical resistance. In addition, the visible light transmittance of about 90 to 91%, the internal loss is very low, and has a very strong characteristics such as mechanical properties and chemical resistance, such as tensile strength, bending strength, elongation strength.

On the upper side of the light guide plate 147, an optical member 149 is mounted to compensate for the optical characteristics of the light provided through the light guide plate 147. At this time, the optical member 149, although not shown in the drawing, for example, a diffusion sheet formed with a diffusion pattern for mitigating nonuniformity of light, and a prism sheet and a prism sheet having a condensing pattern for increasing the front luminance of the light. It may include a protective sheet to protect the from scratches.

In addition, the upper side of the optical member 149 is fastened to the main frame 150 of the rectangular frame shape made of a synthetic resin or a stainless steel mold. Of course, the main support 150 serves to maintain the balance of the overall force in the liquid crystal display device, and in consideration of the liquid crystal panel 160 is loaded on the front surface of the inside and the outside of the upper surface thereof. The frame is formed so that the edge areas are stepped with each other. In this case, the main support 150 receives light from the light emitting unit 143 to open an image in the liquid crystal panel 160 to form an image of a rectangular frame, for example, a frame.

The liquid crystal panel 160 is mounted on the main support 150. The liquid crystal panel 160 includes a thin film transistor array substrate 160a and a color filter substrate having red (R), green (G), and blue (B) color filters bonded to each other to maintain a uniform cell gap. 160b, and a liquid crystal layer formed between the two substrates.

The upper cover 170 covers four edge regions of the liquid crystal panel 160 and is assembled and fastened to the main support 150.

4 is an exploded perspective view of a liquid crystal display according to a second exemplary embodiment of the present invention.

As shown in FIG. 4, the liquid crystal display according to the second exemplary embodiment of the present invention is a liquid crystal panel 260 in which an image is implemented and a backlight device provided under the liquid crystal panel 260 to provide light. The backlight device includes a light source means 240 coupled to a through hole 201 formed on both side frames of the lower cover 200 and a burring structure 203 protruding from the side frame, and the burring structure. Is fastened to 203 is configured to include a fixing means 245 for fixing the light source means 240.

The lower cover 200 formed of an electro galvanized steel sheet (EGI) or aluminum (Al) may be a bottom frame forming a floor, and a side frame extending vertically from both edges of the floor frame to form sidewalls. Consists of.

At this time, the side frames respectively formed on both sides are formed by forming a 'c' shape, the plurality of through holes 201 formed in a row at regular intervals formed on the side frame forming the c-shape as described above It is. Here, the U-shaped side frame serves to prevent the light provided from the light emitting means 243 inserted and fastened from the outside through the through hole 201 of the side frame to leak to the edge region of the liquid crystal panel 260. .

In addition, a burring structure 203 is formed between the through holes 201 formed at regular intervals on a frame perpendicular to the bottom frame on both side frames of the lower cover 200, and the burring structure 203 is provided. Is alternately formed between the through holes 201 up and down, respectively, to form a zig-zag shape as a whole.

At this time, the burring structure 203 may be formed through a separate burring process after the injection molding of the lower cover 200, and forms a reverse burring protruding outward from the inside of the side frame, the burring structure 203 A hole is formed in the inside, and a thread is formed in the side wall of the inside where the hole is formed to form a screw structure.

In the present invention, the burring structure 203 is formed by forming a jig-zag shape on both side frames of the lower cover 200, so that the substrate 241 fastened through the burring structure 203 is formed on the lower cover 200. In order to be relatively in close contact with and fixed to the side frame, through which the heat generated from the light source means 240 can be easily released to the outside.

In this case, the present invention further provides a separate heat conductive material such as grease to help more effectively conduct heat between the side frames of the lower cover 200 and the substrate 241 constituting the light source unit 240. Or double sided tape.

In addition, the light source means 240 is provided on the outside of the side frame forming a U-shape on both sides of the lower cover 200, respectively. In this case, the light source means 240 includes a substrate 241 such as a PCB or a metal PCB, and light emitting means 243 such as an LED package formed on the substrate 241 at regular intervals.

Holes are formed in the upper and side portions of the light emitting means 243 on the substrate 241 to form a zig-zag shape as a whole. As a result, the light emitting means 243 on the substrate 241 is formed. Is inserted into and fastened to the through hole 201 of the lower cover 200, and the holes of the substrate 241 are fastened to correspond to the burring structure 203 of the lower cover 200, respectively. By assembling-fixing the burring structure 203 of the lower cover 200 and the substrate 241, a clear assembly criterion is secured when assembling the substrate 241 to the lower cover 241 so that the operation is easier. By doing so, the workability for the assembly is improved, and the cost can be saved.

In addition, although the LEDs of R, G, and B may be manufactured separately and fixed on the substrate 241, the light emitting unit 243 may form LEDs of R, G, and B into a cluster to implement white light. Packages are also available. Furthermore, the present invention implements white light using a yellow phosphor on a chip providing blue light, or R and G phosphors are applied to a chip providing blue light, or green on a chip providing blue and red light. It may include a light emitting means 243 to implement a white light by applying a phosphor. In addition to the LED, any number of light emitting means 243 such as an OLED is possible, and therefore, the present invention will not be limited thereto.

The fixing means 245 such as a screw is fastened to the inside of the hole of the burring structure 203 exposed to the outside through the substrate 241 coupled to the outside of the side frame of the lower cover 200.

When the fixing means 245 is fastened to the burring structure 203 of the lower cover 200, the substrate 241 according to the present invention is detached from the side frame of the lower cover 200 even if an impact is applied from the outside. Since the substrate 241 is in close contact with and fastened to the side frame of the lower cover 200, the thermal conductivity between the lower cover 200 and the substrate 241 is increased to generate heat generated from the light emitting means 243. Heat may be easily released to the outside through the substrate 241.

In addition, other details related to the reflective plate 210, the light guide plate 247, the main support 250, and the liquid crystal panel 260 other than the above description will be replaced by the above contents.

Meanwhile, in the present invention, the burring structures 103 and 203 formed on the lower covers 100 and 200 described above are not integrally formed on the lower covers 100 and 200, but formed of other materials such as rubber. And the substrates 141 and 241 are temporarily fixed on the side frames on which the burring structures 103 and 203 are formed, and then the fixing means 145 and 245 are separately attached to the side frames of the lower covers 100 and 200. It may also be possible that the substrates 141 and 241 are in close contact with and fixed to the side frames of the lower covers 100 and 200.

1 is a cross-sectional view of an edge-type LED liquid crystal display device according to the prior art

2 is an exploded perspective view of a liquid crystal display according to a first embodiment of the present invention.

3 is a cross-sectional view of the fastening of FIG.

4 is an exploded perspective view of a liquid crystal display according to a second exemplary embodiment of the present invention.

Claims (7)

A lower cover having a bottom frame and a side frame extending from at least one side of the bottom frame, wherein the side frame has at least one through hole and at least one burring structure formed to protrude from the side frame; A light source means comprising a substrate having a hole fastened to the burring structure and a light emitting means fixed on the substrate and fastened to a through hole of the lower cover to provide light; Fastening means fastened to the burring structure to fix the substrate in close contact with the side frame; And a liquid crystal panel provided on an upper side of the lower cover to receive light. The liquid crystal display of claim 1, wherein the burring structure includes a hole having a thread formed on an inner sidewall thereof. The liquid crystal display device according to claim 1, wherein the fixing means is a screw which is engaged with an internal thread of a burring structure. The liquid crystal display device according to claim 1, wherein when the burring structure is formed in plural on the side frame of the lower cover, it is formed in a zig-zag shape as a whole. The liquid crystal display device according to claim 1, wherein the burring structure is in the form of a bolt having a screw thread formed on the outside thereof. The liquid crystal display device according to claim 1, wherein the fixing means is a nut coupled to a bolt-type burring structure. The liquid crystal display device according to claim 1, wherein the light emitting means is made of any one of a light emitting diode (LED) and an organic light emitting diode (OLED).

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