KR100644804B1 - Liquid crystal display device and method for assembling the thereof - Google Patents

Abstract

The present invention relates to a liquid crystal display device and a method for assembling the same to allow the identification and performance inspection of foreign substances and defective products during assembly by sequentially stacking and assembling the components for allowing an image to be displayed from the bottom surface of the storage container. According to the present invention, by using a conductive container and a non-conductive storage container for storing the components of the liquid crystal display device, and storing the components of the liquid crystal display device inside the conductive storage container, the component is tested for normal operation. Reassembly does not occur by defective components after assembling, and the liquid crystal display panel, the diffusion sheet, the top chassis, the light guide plate, and the reflector are all composed of closed circuits to quickly remove static electricity by using the conductive and non-conductive storage containers together. And reduce harmful electromagnetic waves, remove conventional static electricity and harmful electromagnetic waves As the assembly is reduced because there is no need to use a conductive clip including reducing the assembly process to reduce the weight and volume is also reduced.

LCD, Monitor, Conductive Storage Container

Description

Liquid crystal display device and method for assembling the explanation

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

FIG. 2 is a cross-sectional view taken along line II ′ of FIG. 1.

3 is a cross-sectional view taken along line II-II 'of FIG. 1.

The present invention relates to a display device, and more particularly, to stack and assemble components that allow an image to be displayed from the bottom surface of a storage container to an upper side in order to identify foreign substances and defective products during assembly and to perform performance inspection. A display device and a method for assembling thereof are provided.

In addition, the present invention, after manufacturing the storage container insulated, by storing a separate conductive storage container in the interior of the storage container to minimize the harmful electromagnetic wave (EMI) of the components by grounding all the conductive storage container as well as components The present invention relates to a liquid crystal display device which reduces an assembly process number and a production cost by not using a separate grounding clip for grounding the same.

Recently, the liquid crystal display device which is rapidly developed is mainly applied to the portable computer which requires mobility because the overall size and weight is very small even though it has the same display area as the conventional CRT method. With the development and spread, the use area of desktop computers and wall-mounted TVs is increasing rapidly.

At this time, the liquid crystal display device used as a monitor of the desktop computer is composed of a liquid crystal display panel, optical sheets, light guide plate, and a case including a lamp unit, a top chassis, a rear case and a front case.

First, assembling order is to place the front case with the display area opened with an insulating material in the state inverted on the work table, and then fixed the liquid crystal display panel in which the image is first displayed inside the front case, and then the rear of the liquid crystal display panel. After fixing the optical sheets to scatter the light to make the brightness uniform through the front case, the light guide plate to which the lamp unit is coupled is fixed to the optical sheets through the front case.

Subsequently, the rear surface of the light guide plate is fixed via the front case in a state where the reflector is raised, and then the conductive rear case is coupled to the front case so that the components of the liquid crystal display module are firmly supported by the front case and the rear case.

The liquid crystal display panel, the light guide plate, and the diffusion sheet of the liquid crystal display device having such a configuration and assembly order are grounded to the conductive rear case with a conductive clip to prevent the liquid crystal display panel from being damaged by static electricity and harmful electromagnetic waves.

However, the liquid crystal display module having such a configuration and assembling order includes the following problems.

First, in the conventional liquid crystal display device, the liquid crystal display panel is first assembled to the front case, and then the diffusion sheet, the light guide plate to which the lamp unit is coupled, and the rear case are combined, and then the liquid crystal display is arbitrarily driven to drive the liquid crystal display panel. Of the lamp unit and the light guide plate, and whether or not the lamp unit and the light guide plate are normal, and the stains due to the contamination of the diffusion sheet are tested. The liquid crystal display panel is defective, or the lamp unit does not generate light having a specified luminance, If the shape is bad or there is contamination in the diffusion sheets, there is a problem in that the liquid crystal display is disassembled in the reverse order of assembly in order to replace the defective component, and then the assembly process is repeated after replacing the defective component.

Second, the conventional liquid crystal display device connects the above-described components with a conductive clip in order to remove static electricity or harmful electromagnetic waves generated in the liquid crystal display panel, light guide plate, diffusion sheet, etc., and the overall thickness and There is a problem that the weight is increased, the configuration and shape are complicated, and the assembly process and the number of assembly parts are increased to assemble the conductive clip.

Accordingly, the present invention takes account of such conventional problems, and an object of the present invention is to sequentially stack components of a liquid crystal display device in a conductive case housed in a rear case, for example, combining a light guide plate and a lamp unit in a rear case. After the lamp unit is driven to prove the suitability of the light guide plate and the lamp unit, the diffusion sheet is fixed to the upper surface of the light guide plate to prove the suitability of the diffusion sheet again, and the liquid crystal display panel is fixed to the upper surface of the diffusion sheet. After demonstrating the suitability of the liquid crystal display panel by arbitrarily driving the display panel, the front case may be coupled to the rear case to assemble the components constituting the liquid crystal display and perform the performance test.

Another object of the present invention is to remove the static electricity and harmful electromagnetic waves generated in the components of the liquid crystal display device from the storage container without a separate conductive clip.

Still other objects of the present invention will become more apparent from the following detailed description of the present invention.

The liquid crystal display device according to the present invention for achieving the object of the present invention includes a non-conductive storage container, a conductive storage container, a light supply means, a display unit, a top chassis and a conductive protective case.
The non-conductive storage container has an opening formed in the bottom surface. The conductive storage container is housed inside the non-conductive storage container. The light supply means is accommodated in the conductive storage container. The display unit may be mounted on an upper portion of the light supply means to display an image by light supplied by the light supply means, and the display unit may be electrically connected to the liquid crystal display panel to provide a driving signal to the liquid crystal display panel. And a driving printed circuit board disposed below the nonconductive storage container. The conductive top chassis presses the display unit while being in contact with the conductive storage container. The conductive protective case is disposed under the non-conductive storage container and is in contact with the driving printed circuit board.

In addition, the method of assembling the liquid crystal display device according to the present invention for achieving another object of the present invention comprises the steps of accommodating the conductive storage container in the non-conductive storage container with an opening formed on the bottom surface, and the lamp inside the conductive storage container; After storing the unit and the light guide plate, driving the lamp unit to test whether the lamp unit and the light guide plate are in operation; and when the lamp unit and the light guide plate are normally operated, at least one sheet on the upper surface of the light guide plate. Storing the diffusion sheets, testing the diffusion sheets for contamination, and placing a display unit including a flexible printed circuit board and a driving printed circuit board on an upper surface of the diffusion sheets, and then operating the display unit. Testing whether or not, one side is in contact with the conductive housing and the other side is the display unit. A conductive top chassis for pressurizing the net is disposed on the upper portion of the display unit, the driving printed circuit board is brought into contact with the bottom surface of the conductive storage container, and a protective case which is in contact with the driving printed circuit board is placed in the non-conductive storage. Disposing at the bottom of the container.

Hereinafter, a liquid crystal display and an assembly method thereof according to the present invention will be described with reference to the accompanying drawings.

1 is an exploded perspective view of the liquid crystal display according to the present invention.

The liquid crystal display device 800 according to the present invention as a whole is stored in the non-conductive storage container 100, the conductive storage container 200 accommodated in the non-conductive storage container 100, and the conductive storage container 200. Combination with the diffusion sheet 300, the lamp unit 400, the light guide plate 450, the display unit 500, the display unit support frame 600 for supporting the display unit 500, non-conductive storage container 600 And a protection case 750 coupled to the top chassis 700 and the non-conductive storage container 100 to prevent the display unit 500 from being randomly separated.

More specific shapes and coupling relationships of these components will be described with reference to the accompanying drawings.

First, the non-conductive storage container 100 is made of a non-conductive material, for example, a synthetic resin having a high resistance in the shape of a rectangular box having an upper surface open.

More specifically, the non-conductive storage container 100 includes four sidewalls 10, 20, 30, and 40 and one bottom surface 50, and the bottom surface 50 has a conductive storage container 200 to be described later. The opening 55 is formed so that the remaining portion except for the area to be supported is removed.

In addition, a plurality of through holes 22 and 44 are formed at both ends of the upper surface of the two side walls 20 and 40 which are short in length and oppose each other among the four side walls 10, 20, 30 and 40 of the non-conductive storage container 100. ) Is formed, and bosses of protrusions 24 and 46 spaced apart from each other at predetermined intervals are formed in the yarns of the through holes 22 and 44 and the through holes 22 and 44.

In addition, of the four side walls (10, 20, 30, 40) of the non-conductive storage container 100 through holes 15, 35 having a predetermined shape penetrating the outer and inner sides of the long side walls (10, 30) As it is formed, the through holes 15 and 35 are heat radiating holes for radiating heat generated from the lamp of the lamp unit 400 to be described later to the outside.

The conductive storage container 200 made of a conductive material is inserted and supported inside the non-conductive storage container 100 having such a configuration.

Referring to the shape and configuration of the conductive storage container 200 in more detail as follows.

The conductive storage container 200 is made of a metal plate having a thin thickness and good workability, and performs a complex function as described below.

In detail, the shape of the conductive storage container 200 will be described. The conductive storage container 200 has a conductive bottom surface 210 having an area inserted into the interior of the non-conductive storage container 100 and the non-conductive storage container. From the two conductive first sidewalls 230,250 and the conductive bottom surface 210 of the long sidewalls 10,20,30,40 of the (100), which are long and are in close contact with the inner side surfaces of the opposite sidewalls 10,30. It consists of the inner side surfaces of the remaining two side walls 20 and 40 of the non-conductive storage container 100 and the second conductive side wall 260 and 270 extending to the top surface of the side walls 20 and 40 of the non-conductive storage container 100. .

More specifically, the conductive bottom surface 210 surrounds the bottom surface 50 of the non-conductive storage container 100 through the opening 55 of the bottom surface 50 of the non-conductive storage container 100 to be described later. The driving printed circuit board may be in contact with the driving printed circuit board connected to the liquid crystal display panel of FIG. 500 to ground the driving printed circuit board.

In order to implement this, a plurality of ground grooves 215 pressed out from the inside of the conductive bottom surface are formed in the portion corresponding to the opening of the non-conductive storage container 100 of the conductive bottom surface 210.

Meanwhile, since the first sidewalls 230 and 250 of the conductive storage container 200 mentioned above have good thermal conductivity, the first sidewalls 230 and 250 serve as a heat sink to radiate heat generated from the lamp unit 400 to the outside. The second sidewalls 260 and 270 serve as a passage for contacting and grounding the conductive top chassis 700 to be described later while fixing the conductive storage container 200. More specifically, for example, the conductive storage container 200 may be formed of a first heat sink for contacting the lamp unit 400 to emit heat to the outside and an agent for emitting heat to the outside by contacting an end of the light guide plate 450. 2 Include a heat sink. At this time, the first and second heat dissipation holes are formed in the non-conductive storage container 200 which is in contact with the first and second heat sinks, respectively. Here, the second heat sink and the second heat sink may be omitted.

The second sidewalls 260 and 270 extending to the top surface of the sidewalls 20 and 40 of the nonconductive storage container 100 of the conductive storage container 200 configured to implement this are the side walls 20 of the nonconductive storage container 100. The second side walls 260 and 270 extend to overlap with the through holes 22 and 44 formed in the 40 and overlap the through holes 22 and 44 formed in the side walls 20 and 40 of the non-conductive storage container 100. Through holes 262 and 272 are formed.

The conductive storage container 200 having such a configuration is inserted into the non-conductive storage container 100 and supported by the bottom surface 50 of the non-conductive storage container 100.

In detail, as illustrated in FIG. 1, the reflective housing 350, the light guide plate 450, the lamp unit 400, the diffusion sheet 300, and the display unit 500 are sequentially stored in the conductive storage container 200. Then, the conductive protective case 750 is installed on the outer bottom surface of the non-conductive storage container 200.

More specifically, the bottom surface 210 of the conductive storage container 200 is selectively accommodated with a thinner reflective plate 350, the upper surface of the reflecting plate 350, the light guide plate 450 to which the lamp unit 400 is coupled is designated Is seated on.

The lamp unit 400 is again composed of a lamp cover 410 and at least one cold cathode ray tube lamp 420.

The lamp cover 410 collects the light emitted radially from the cold cathode ray tube lamp 420 in one direction so that the light is focused to increase the luminous flux and facilitates the light propagation direction to facilitate the direction control of the light.

The lamp cover 410 which serves as described above is coupled to both ends of the light guide plate 450 which changes the traveling angle of the light while inducing the light focused in one direction from the lamp cover 410 in one embodiment. .

The light guide plate 450 has a size to be accommodated in the conductive storage container 200, and the shape of the light guide plate 450 may be a rectangular wedge type or a rectangular flat type. The light guide plate 450 may scatter light incident on the bottom surface of the light guide plate 450 to propagate light. Many reflective dots (not shown) for changing the direction are formed in a predetermined pattern.

At least one diffusion sheet 300 is accommodated on the upper surface of the light guide plate 450 formed as described above so as to uniformly scatter the light that is roughly scattered from the light guide plate 450.

The diffusion sheets 300 serve to scatter the light once again so that the incident light is emitted while having a very uniform brightness.

The diffusion sheets 300 are also shaped to have an area to be accommodated in the conductive storage container 200. The diffusion sheets 300 are combined with the coupling protrusions 24 and 46 as described above on shorter short sides of the diffusion sheets 300. A predetermined area is protruded so that the sheets 300 are firmly coupled, and a through hole 310 is formed at the protruding portion so as to be coupled to the coupling protrusions 24 and 46.

As such, when the diffusion sheet 300 is installed on the upper surface of the light guide plate 450, light leakage phenomenon is prevented from the light guide plate 450 and the diffusion sheet 300, and the lamp cover 410 is pressed to press the light guide plate 450 and the light guide plate 450. The display unit support frame 600 is installed on the upper surface of the light guide plate 450 to limit the movement of the lamp unit 400 and to support the display unit 500 to be described later in detail.

The display unit support frame 600 is firmly seated on the stepped portions formed on the sidewalls 10, 20, 30, and 40 of the non-conductive storage container 100.

The display unit 500 is mounted on the display unit support frame 600. The display unit 500 includes a liquid crystal display panel 510, a driving printed circuit board 508, and a flexible circuit board 506.

The liquid crystal display panel 510 includes a TFT substrate 502 having a thin film transistor and a pixel electrode to which power is applied by turn-on of the thin film transistor, a color filter substrate 504 facing the pixel electrode and having a common electrode formed thereon; And liquid crystal (not shown) injected between the TFT substrate 502 and the color filter substrate 504. The driving printed circuit board 508 is electrically connected to the liquid crystal display panel 510 to provide a driving signal to the liquid crystal display panel 510. The flexible circuit board 506 is disposed between the liquid crystal display panel 510 and the driving printed circuit board 510 to electrically connect the liquid crystal display panel 510 and the driving printed circuit board 510.
In more detail, the driving printed circuit board 508 is electrically connected to the TFT substrate 502 by the flexible printed circuit board 506 to selectively turn the thin film transistor formed on the TFT substrate 502 at an appropriate timing. -Turn it on. On the other hand, the driving printed circuit board 508 is disposed on the lower portion of the non-conductive storage container 100 is bent the flexible circuit board 506.

In this case, the flexible circuit board 506 may be specifically used a tape carrier package (TCP), a chip-on flexible circuit (COF) and the like.

The driving printed circuit board 508 connected to the flexible circuit board 506 of the display unit 500 while the display unit 500 configured as described above is seated on the display unit support frame 600 is a non-conductive storage container 100. While wrapping the outside of the bent is in close contact with the bottom surface of the outer surface of the non-conductive storage container (100).

At this time, one side of the driving printed circuit board 508 is a ground groove 215 of the conductive storage container 200 formed inside the non-conductive storage container 100 through the opening 55 of the non-conductive storage container 100. Grounded in contact with

Meanwhile, in order to prevent the display unit 500 mounted on the display unit support frame 600 from being separated from the outside, the top chassis 700 is covered with the display chassis 500, but the top chassis 700 is formed in a cramped shape. The side surface covers an invalid display area of the display unit 500, and the other side surface of the display unit 500 is coupled to the outer surface of the non-conductive storage container 100 by a hook or the like.

On the other hand, the protective case 750, for example, the non-conductive storage container 100 in the protective bottom 751, the protective side walls 752, 753 and the protective bottom 751 extending from the edge of the protective bottom 751. It may include a second ground groove 755 projecting toward). At this time, the second ground groove 755 is in contact with the driving printed circuit board 508 is grounded. The protective case 750 may be coupled to the conductive storage container 200 or the non-conductive storage container 100 through hooks and screws.

Hereinafter, the assembling procedure of the liquid crystal display according to the present invention having such a configuration will be described with reference to FIGS. 1 to 3.

First, the conductive storage container 200 is inserted into the non-conductive storage container 100 in a state where the non-conductive storage container 100 described above is seated at a work surface or a flat surface position, and then the conductive storage container 200 is made of the conductive storage container 200. 2 side wall 260 is fixed to the non-conductive storage container (100).

Subsequently, a reflecting plate 350, a light guide plate 450 coupled to the lamp unit 400, and diffusion sheets 300 are sequentially received on the bottom surface of the conductive storage container 200, and penetrates formed in the diffusion sheets 300. The ball 310 is coupled to and fixed to the engaging protrusions 24 and 46 formed on the upper surface of the non-conductive storage container 100.

More specifically, after the lamp unit 400 and the light guide plate 450 are accommodated in the conductive storage container 200, the lamp unit 400 is driven to check whether the lamp unit 400 and the light guide plate 450 are abnormal. The diffusion sheet 300 is stored in the state in which the unit 400 is driven to check whether the diffusion sheet 300 is abnormal.

Subsequently, when the diffusion sheet 300 operates normally, the display unit 500 is mounted on the upper surface of the diffusion sheet 300, and then the display unit 500 is arbitrarily driven to determine whether the display unit 500 operates normally. Check it.

Subsequently, the display unit support frame 600 is seated on the top surface of the diffusion sheet 300, and the top chassis 700 is seated on the top surface of the display unit support frame 600, and the top chassis 700 is a display unit ( While pressing 500, the second sidewall 260 of the conductive storage container 200 is contacted.

Thereafter, the flexible printed circuit board 506 and the driving printed circuit board 508 of the display unit 500 are bent and wrapped around the outside of the non-conductive storage container 100 to be bent to the bottom surface of the non-conductive storage container 100. Afterwards, the opening 55 contacts the ground groove 215 of the conductive storage container 200 exposed through the opening 55 formed on the bottom surface of the non-conductive storage container 100.

Subsequently, the protective case 750 is disposed under the non-conductive storage container 100 to be in contact with the driving printed circuit board 508. In this case, the protective case 750 may be coupled to the conductive storage container 200 or the non-conductive storage container 100 through a hook and a screw.

As described above in detail, the container containing the components of the liquid crystal display device is used as the conductive container and the non-conductive storage container, and the components of the liquid crystal display device are accommodated inside the conductive storage container. By testing the operation, there is an effect that reassembly by a bad component does not occur after assembly.

In addition, by using a conductive storage container, the display unit, the diffusion sheet, the top chassis, the light guide plate, and the reflector are all composed of closed circuits to quickly remove static electricity and reduce harmful electromagnetic waves, and to remove conventional static electricity and reduce harmful electromagnetic waves. Since there is no need to use such as, there is an effect that the assembly parts are reduced and the assembly process is reduced, so that the weight and volume are also reduced.

In addition, the conductive container is wrapped around the non-conductive container, and the flexible printed circuit board and the driving printed circuit board of the display unit are bent to the outer side of the non-conductive container, thereby eliminating the need for expensive insulating members. .

Claims (9)

A non-conductive storage container having an opening formed in the bottom surface thereof; A conductive storage container accommodated in the non-conductive storage container; Light supply means housed in the conductive storage container; A liquid crystal display panel mounted on an upper portion of the light supply means and displaying an image through light supplied by the light supply means, and electrically connected to the liquid crystal display panel to provide a driving signal to the liquid crystal display panel, A display unit including a driving printed circuit board disposed under the malleable storage container; A conductive top chassis which presses the display unit while being in contact with the conductive storage container; And And a conductive protective case disposed under the non-conductive storage container and in contact with the driving printed circuit board. The method of claim 1, wherein the light supply means is a lamp unit consisting of a light source and a cover for concentrating radially emitted light from the light source, coupled to the lamp unit to guide the concentrated light to the path of light toward the display unit A light guide plate configured to change a light guide plate, and diffusion sheets provided on an upper surface of the light guide plate to uniform brightness of light emitted from the light guide plate, The diffusion sheet has a protrusion protruding a predetermined length so as to overlap the non-conductive storage container, a through hole formed in the protrusion is formed, the through hole is coupled to the coupling projection formed on the upper surface of the non-conductive storage container, And the protrusion is in contact with the conductive top chassis. According to claim 2, wherein the conductive container is in contact with the lamp unit includes a heat sink for dissipating heat generated in the lamp unit to the outside, And a heat dissipation hole for dissipating heat from the heat sink in the non-conductive storage container in contact with the heat sink. According to claim 2, wherein the conductive storage container includes a first heat sink for contacting the lamp unit for dissipating heat to the outside and a second heat sink for contacting the end of the light guide plate for dissipating heat to the outside, And a first and a second heat dissipation hole, respectively, in the non-conductive storage container in contact with the first and second heat sinks. The method of claim 1, wherein the conductive housing is formed with at least one first ground groove having a predetermined depth in the direction toward the driving printed circuit board, And the first ground groove is in contact with the driving printed circuit board through an opening of the non-conductive storage container. The method of claim 5, wherein the protective case is formed with at least one second ground groove having a predetermined depth in the direction toward the driving printed circuit board, And the second ground groove is in contact with the driving printed circuit board. The liquid crystal display device according to claim 1, further comprising a display unit support frame disposed between the liquid crystal display panel and the light supply means to fix the liquid crystal display panel. The display apparatus of claim 1, wherein the display unit further comprises a flexible circuit board disposed between the liquid crystal display panel and the driving printed circuit board to electrically connect the liquid crystal display panel and the driving printed circuit board. The driving printed circuit board of claim 1, wherein the flexible printed circuit board is bent and disposed below the non-conductive storage container. Storing the conductive storage container in the non-conductive storage container having an opening formed in the bottom surface thereof; Storing a lamp unit and a light guide plate in the conductive storage container, and then driving the lamp unit to test whether the lamp unit and the light guide plate are operated; When the lamp unit and the light guide plate operate normally, accommodating at least one or more diffusion sheets on an upper surface of the light guide plate and testing whether the diffusion sheets are contaminated; Mounting a display unit including a flexible printed circuit board and a driving printed circuit board on an upper surface of the diffusion sheet, and then testing whether the display unit is operated; And A conductive top chassis having one side in contact with the conductive housing and the other side pressing the display unit is disposed on the upper portion of the display unit, and the drive printed circuit board is in contact with the bottom surface of the conductive storage container. Disposing a protective case in contact with a printed circuit board under the non-conductive storage container.

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