KR20060000811A - Structure of flexable printed circuit applied liquid crystal display device - Google Patents

Abstract

The present invention relates to a structure of an FPC that connects a liquid crystal display panel and a system. The present invention provides an array substrate comprising a pixel region and a non-pixel region; A color filter substrate corresponding to the pixel region of the array substrate; A driver IC formed in the non-pixel region; A system unit formed at an outer side of the liquid crystal display panel formed by bonding the array substrate and the color filter substrate to apply a signal to the liquid crystal display panel; A first FPC unit connected to the liquid crystal display panel; A second FPC unit connected to the system unit; And a first pad part electrically connected to the first FPC part and the second FPC part and formed on the first FPC part. As a result, the FPC can be manufactured separately, increasing the unit yield and lowering the cost of the FPC.

FPC, Separation, Pad, Application

Description

Structure of flexible printed circuit (FCC) of liquid crystal display device {STRUCTURE OF FLEXABLE PRINTED CIRCUIT APPLIED LIQUID CRYSTAL DISPLAY DEVICE}

1 is a partial plan view showing a schematic structure of a COG type liquid crystal display panel.

Figure 2a, 2b is a plan view showing the structure of the FPC applied to the conventional application medium model.

3 is a rear view of a liquid crystal display panel showing a state in which a conventional FPC and a liquid crystal display panel are combined.

4A and 4B are plan views showing the FPC structure of the present invention.

5 is a rear view of a liquid crystal display panel showing a state in which the FPC and the liquid crystal display panel of the present invention are combined;

Figure 6a is a conventional FPC arrangement.

Figure 6b is an arrangement of the FPC of the present invention.

****** Description of the symbols for the main parts of the drawings *******

401: First FPC 402: Second FPC

403: first pad portion 404: second pad portion

405: third pad portion

The present invention relates to a structure of a flexible printed circuit (FPC) of a COG type liquid crystal display panel, and more particularly, to a structure of an FPC of an application medium model in which the FPC is directly connected to a system.

TFT-LCD, the flagship product of flat panel display, is now rapidly growing in size and resolution due to mass production technology and R & D. As a result, it is not only used for laptop computers but also for large monitors. It is also developed as an application product, and gradually replaces existing CRT (Cathode Ray Tube) products, and its portion in the display industry is gradually increasing.

In recent information society, the importance of display is more important as a visual information transmission medium. In particular, with the trend of light, thin, short, and small in all electronic products, the importance of low power consumption, thinness, light weight, high definition, and portability is increasing. Liquid crystal displays are not only capable of satisfying these conditions of flat panel displays but also mass-produced display devices, which are rapidly creating various new products using them, and have a ripple effect over semiconductors in the electronics industry.

The driving circuit of the liquid crystal display panel includes a plurality of driver ICs for inputting a signal capable of driving a liquid crystal cell to the liquid crystal display panel, and generates an electric signal for controlling the image and inputs an image from a computer. A timing controller for controlling information and a circuit component for generating different liquid crystal voltages for each gray-scale in a liquid crystal cell are mounted on a printed circuit board (PCB). Consists of.

In order to effectively apply the driving signals of the multi-output driver IC through the gate and data signal wirings drawn to the periphery of the TFT-Array substrate, each signal wiring is connected to hundreds of pads. It is grouped.

The method of connecting the driver IC to the pad includes a chip-on-glass (COG) mounting method in which the driver IC chip is directly connected to the pad and a tape carrier package (TCP) mounting method using tape-automated bonding (TAB) technology.

In the past, many TAB methods with good connectivity and easy to improve have been used, but as the micro-mounting technology is developed, it is tending to move to the COG method which is easy to miniaturize and has low manufacturing cost.

A general COG type liquid crystal display panel is composed of a top plate and a bottom plate formed of a transparent substrate as shown in FIG.

The lower plate 100 may be divided into a first region 105 corresponding to the upper plate 110 and a second region 115 not corresponding to the upper plate. The data line 120 and the gate line 130 are orthogonal to each other in the first region 105. In addition, a gate driver IC 140 connected to the gate wiring 130 and a data driver IC 150 connected to the data wiring 120 are attached to the second region 115.

In addition, the liquid crystal display panel may include a printed circuit board 160 separately installed on the outside of the lower plate 100 and a data transmission line 170 and a flexible printed circuit 180 to connect the input terminal. ; FPC) below. The FPC 180 has output wirings connected to input terminals of the data driver IC 150 and the gate driver IC 140. In addition, the FPC 180 has an input terminal connected to an output terminal of the PCB 160 on which a timing controller or the like is formed to bridge the PCB 160 and the driver ICs 140 and 150.

The above is a description of the combined structure of a liquid crystal display panel, a PCB, and an FPC in a conventional liquid crystal display device. In the case of a medium application model, the structure of the FPC is different.

The FPC, which is applied to a medium sized application, is connected to a liquid crystal display panel at one end thereof and directly connected to a system for providing information to the liquid crystal display panel. Therefore, in order to directly connect the FPC to the system, the FPC has a protruding end extended at one end.

2A shows the structure of an FPC applied to a medium application model. As shown in FIG. 2A, the FPC may be divided into a first FPC unit 201 connected to a liquid crystal display panel and a second FPC unit 202 protruding from the first FPC unit 201.

The protruding second FPC unit 202 is directly connected to a system for providing information to the liquid crystal display panel.

After the FPC 200 is connected to the liquid crystal display panel, the FPC 200 is folded to be connected to a system unit that may be formed outside the liquid crystal display panel.

2B illustrates a state in which the FPC 200 is folded. The folded FPC 200 is connected to the system 210 by a second FPC unit 201.                         

FIG. 3 illustrates a state after the FPC 200 is coupled to the liquid crystal display panel 300. After the FPC 200 is coupled to the liquid crystal display panel 300, the second FPC unit 202 is folded and protrudes downward. You can check it.

By the way, FPC as a module of the liquid crystal display device is an expensive component. Therefore, it is an essential task to effectively produce the FPC. In the current structure in which the first FPC part and the second FPC part are integrally formed in order to directly connect the structure of the FPC to the liquid crystal display panel and the system, the FPC is produced in the unit area. The amount of FPC is small. Therefore, the price of FPC rises further.

As described above, the object of the present invention is to reduce the unit cost by increasing the amount of FPC that can be produced per unit area by modifying the structure of the FPC applied to the medium application model. In addition, it is an object to modify the structure of the FPC so that the FPC can be freely coupled to the system according to the user's choice.

The present invention is characterized in that it comprises a first FPC portion and a second FPC portion separated from each other to achieve the above object. The application medium model is connected to the system via the FPC, for which the FPC has protrusions. As a result, the FPC has a "T" shape, and as a result, the amount of FPC that can be produced per unit area is reduced. Therefore, the FPC of the present invention is divided into two parts of the FPC part and configured to allow the separated FPCs to be bonded to each other by pads.                     

Therefore, the FPC of the present invention is characterized by having a first FPC unit having an output terminal connected to the driver IC, and a second FPC unit separated from the first FPC unit and connected to the system. The first FPC unit may include a pad unit electrically connected to the second FPC unit on a surface of the first FPC unit. The second FPC unit may include a second pad unit connected to the first pad unit formed on the surface of the first FPC unit and a third pad unit to which the system is connected.

The FPC can be called a wire bundle that can be bent. A polymer such as polyimide is stacked on both sides, and a metal thin film or the like is formed therebetween. FPC connects the devices at both ends through the metallization. The application medium model has a structure in which the FPC is in direct contact with a system that applies a signal to a liquid crystal display panel, thereby forming a “T” shape. However, the present invention provides a segmented FPC.

Below with reference to Figure 4a looks at the structure of the FPC of the present invention.

As shown in FIG. 4A, the FPC of the present invention is divided into a first FPC portion 401 and a second FPC portion 402. The first FPC unit 401 is connected to a liquid crystal display panel, and in particular, to a driver IC formed in a non-pixel area of the liquid crystal display panel. That is, 401a of FIG. 4A illustrates a connection terminal connected to the driver IC. The connection terminal may be configured to protrude one-to-one with a driver IC formed in the non-pixel region.

In addition, the first FPC portion 401 further includes a first pad portion 403 on its surface. The first pad part 403 is for electrically connecting with the second FPC part 402 separated from the first FPC part 401. Therefore, the metal wiring formed inside the first FPC unit 401 needs to be designed to be concentrated on the first pad unit 403.

On the other hand, the second FPC unit 402 separated from the first FPC unit 401 has a second pad portion 404 and the third pad portion 405 at both ends. The second pad part 404 is in electrical contact with the first pad part 403.

The third pad part 405 is connected to a system for applying a signal to the liquid crystal display panel. Therefore, according to the present invention, the first FPC 401 is first connected to the liquid crystal display panel, and the second FPC unit 402 which is independently present is combined with the first FPC 401 to expose the outside of the liquid crystal display panel region. An area where the second FPC 402 and the first FPC part 401 are coupled is a first pad part 403 and a second pad part 404.

The second and third pad parts 404 and 405 formed on the second FPC part 402 may have pads on both sides thereof to be freely combined with the first pad part 403 and the system. However, in order to prevent external static electricity, pads may be formed on one surface of the second and third pad parts 404 and 405, and the other surface may be covered by an insulating material such as a polymer.

Forming the FPC having the above structure can form a large amount of FPC per unit area. In the present invention, since the FPC is divided into two parts, the first FPC part and the second FPC part may be separately manufactured, and then the FPC may be obtained by bonding.

4B illustrates an example in which the second FPC unit 402 is configured to face downward in combination with the first FPC unit 401. However, the second FPC unit may be modified by design modification of the first pad unit 403. Reference numeral 402 may be directed to the left and right of the liquid crystal display panel.                     

Next, the structure of the FPC of the present invention combined with the liquid crystal display panel will be described.

FIG. 5 illustrates a rear surface of the liquid crystal display panel. The first FPC unit 401 is connected to a driver IC unit (not shown) formed on the front surface of the liquid crystal display panel 400 and then moved to the rear surface of the liquid crystal display panel 400. Folded In this case, the first pad part 403 formed on the surface of the first FPC part 401 is formed on the surface of the first FPC part 401 to be exposed to the outside.

Subsequently, the second pad portion 404 and the first pad portion 403 of the second FPC portion 402 are coupled to expose the second FPC portion 402 out of the liquid crystal display panel. A system is connected to the exposed second FPC unit 402 to drive the liquid crystal display panel.

Next, with reference to Figures 6a and 6b looks at the state in which the FPC is efficiently produced by the present invention.

6A shows a state in which a conventional integrated FPC is produced. As shown in FIG. 6A, since the conventional FPC is integrally formed in a T-shape, the number of FPCs formed in a unit area is small.

However, in the present invention, since the FPC is configured as a separate type, it can be seen that the amount of FPC produced per unit area is large. In the module of the liquid crystal display device, the cost of the FPC is considerable, and the cost of manufacturing the FPC can be reduced by separating the components as described above.

The present invention, as described above, in the liquid crystal display device of the application medium-size model, it is possible to form a completed FPC by separating and forming the FPC connecting the liquid crystal display panel and the system, and then combined. Therefore, the FPC of the present invention can form a large amount per unit area, thereby reducing the cost of expensive FPC. In addition, the conventional FPC must be folded to be combined with the system, the present invention can prevent the disconnection of the wiring by essentially removing the folded portion.

Claims (9)

An array substrate having a pixel region and a non-pixel region; A color filter substrate corresponding to the pixel region of the array substrate; A driver IC formed in the non-pixel region; A system unit formed at an outer side of the liquid crystal display panel formed by bonding the array substrate and the color filter substrate to apply a signal to the liquid crystal display panel; A first FPC unit connected to the liquid crystal display panel; A second FPC unit connected to the system unit; And a first pad part electrically connected to the first FPC part and the second FPC part and formed on the first FPC part. The liquid crystal display of claim 1, wherein the first FPC is connected to the liquid crystal display panel through the driver IC. The liquid crystal display of claim 1, wherein the second FPC includes a second pad portion and a third pad portion at both ends thereof. The liquid crystal display of claim 3, wherein the second FPC unit is connected to the first pad unit through the second pad unit. The liquid crystal display of claim 3, wherein the second FPC is connected to the system unit through the third pad unit. A liquid crystal display panel having a pixel region; A system unit for applying a signal to the liquid crystal display panel; And an FPC unit separated from each other and connected through a pad, wherein the FPC unit electrically connects the liquid crystal display panel and the system unit. The liquid crystal display of claim 6, wherein the FPC unit includes a first FPC unit connected to the liquid crystal display panel and a second FPC unit connected to the system unit. 7. The liquid crystal display device according to claim 6, wherein the second FPC portion has pad portions on both sides thereof. The liquid crystal display device of claim 7, further comprising a first pad part connected to the second pad part on a surface of the first pad part.

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