KR100243812B1 - Fpc structure of liquid crystal display device - Google Patents

Abstract

The present invention relates to a method of connecting a driving IC to an input wiring of a COG type liquid crystal display device.

In the conventional COG type liquid crystal display device, the driving IC and the input wiring are connected by using a flexible printed circuit (FPC). At this time, the input terminal of the drive IC was formed on the long axis surface of the drive IC, so that the width of the input wiring was large and the amount of FPC used was large.

The present invention has a structure in which an input terminal of the drive IC is formed on both short-side surfaces of the drive IC, and the FPC is connected to the drive IC by using an FPC composed of an input wiring portion and a lead portion branched from the input wiring portion. In this case, the input wiring portion is formed with an input wiring, and the lead portion is formed with a lead wire connected to the input terminal. That is, the input wire and the lead wire are connected, and the lead wire and the input terminal are connected. The input wiring and the lead wiring are both formed in the FPC.

The present invention can reduce the width of the input wiring portion as compared with the conventional, it is possible to prevent the parasitic capacitance generated at the intersection between the input wiring and the lead line. Therefore, the present invention can reduce the signal distortion caused by the parasitic capacitance and contribute to the manufacture of high-quality liquid crystal display device.

Description

Structure of FPC of LCD

SUMMARY OF THE INVENTION An object of the present invention is to minimize a pad region generated by input wiring of a scan line driver IC or a signal line driver IC in a COG type liquid crystal display device.

In general, as a means for displaying an image on a screen, a CRT CRT which performs image processing by an RGB electron gun is used. In order to display an image on the screen using this CRT CRT, sufficient distance must be secured between the electron gun and the surface of the CRT. Therefore, a large occupied space is required to widen the image display area on the screen using the CRT CRT.

As an image display device for replacing the disadvantages of the CRT CRT, the liquid crystal display device is at the most practical stage. The liquid crystal display is classified into a tape automated bonding (TAB) method and a chip on glass (COG) method according to a method of connecting a driving IC and a panel.

As shown in FIG. 1, a general COG type liquid crystal display device includes an upper plate 1, a lower plate 1, a PCB substrate 10, a flexible printed circuit (FPC) 20, and a data transmission cable 12. . Although the upper plate 1 is not shown in the figure, a polarizing plate is attached to one side, and a color filter and a common electrode are formed on the opposite side. The lower plate 2 has a larger area than the upper plate 1, and although not shown in the drawing, a polarizing plate is attached to one side thereof. On the lower plate, the opposite surface to which the polarizer is not attached is configured to face the common electrode of the upper plate 1, and as shown in FIG. 1, the scan line driver IC 30, the signal line driver IC 40, and the scan line 23. And a signal line 44 formed perpendicular to the scan line 23.

The signal line driver IC 40 includes an R, G, B (Red, Green, Blue) signal, an SSC (Source Shift Clock) signal, LP (Latch Pulse), and Gamma generated from a driving circuit of the PCB substrate 10. ), Various input signals such as an analog ground signal, a digital ground signal, a 3.3V digital power supply, a 4.2V analog power supply, a common voltage Vcom, and a storage voltage Vst are applied. At this time, the signal line driver input wiring 21 ′ through which the input signal flows is formed in the FPC 20 and connected to the input unit of the signal line driver IC 40. That is, the FPC 20 includes signal line drive input wiring. In addition, the output line 42 of the signal line driver IC 40 makes one-to-one connection with each line of the signal line 44.

The scan line driver IC 30 receives the scan input signal of the drive circuit of the PCB substrate 10 from the FPC 20 through the scan line drive input wiring 21 to generate and output a scan voltage for driving the liquid crystal display device. Output to the terminal. At this time, the output terminal of the scan line driver IC 30 makes one-to-one connection with each line of the scan line 23 through the scan line output wiring 32.

The data transmission cable 12 is installed to connect the PCB and the FPC in order to apply the signal generated in the driving circuit of the PCB to the signal line drive input wiring of the FPC 20. That is, the signal generated by the driving circuit of the PCB is applied to the signal line driving input wiring of the FPC via the data transmission cable.

However, the liquid crystal display device shown in Fig. 1 has a high manufacturing cost because the unit price of the FPC 20 is high. Therefore, in order to reduce the usage of the FPC, as shown in FIG. 2, an LCD having a structure in which input wirings of the signal line driver IC 40 and the scan line driver IC 30 are directly formed on the lower plate has also been developed. That is, the liquid crystal display shown in FIG. 2 includes a PCB substrate 10, an FPC 20 having a transmission line, an upper plate 1, and a lower plate 2. As shown in FIG. The lower plate includes an input line 71 of a scan line driver IC mounted directly on the lower plate, an input line 70 of a signal line driver IC mounted directly on the lower plate, and a common voltage wiring, a scan line driver IC 30, and a signal line driver IC ( 40), the scanning line 23, and the signal line 44. As shown in FIG. A common electrode is formed on the upper plate, and the common electrode is connected to the common voltage wiring of the lower plate through a wiring process. 2A is a plan view in which an upper plate and a lower plate are stacked, and FIG. 2B is a cross-sectional view in which an upper plate and a lower plate are stacked. As shown in FIG. 2B, the common electrode of the upper plate is connected to the common voltage wiring of the lower plate.

The conventional liquid crystal display shown in FIG. 2 has a structure in which various input signals necessary for driving the liquid crystal display in the driving circuit of the PCB substrate 10 are generated, and the input signals are input to the transmission line of the FPC 20. Each transmission line of the FPC 20 makes one-to-one connection to the input wiring 71 of the scan line driver IC mounted directly on the bottom plate and the input wiring 70 of the signal line driver IC mounted directly on the bottom plate.

Each input signal applied to the input wirings 70 and 71 serves as an input of the scan line driver IC 30 and the signal line driver IC 40, and the output signals of the drive ICs 30 and 40 are each scan line 23. ) And the signal line 44. The liquid crystal display is driven according to the signals of the scan line 23 and the signal line 44 to which the output signal is applied.

The problem to be solved by the COG type liquid crystal display device is to increase the ratio of the display area of the lower plate. That is, the ratio of the display area to the lower panel should be high.

However, the liquid crystal display shown in FIG. 2 has a disadvantage in that the pad area is wider at the edge of the lower plate so that the ratio of the display area in the lower plate is lowered. The reason is that as shown in Fig. 3, the first area occupied by the driving ICs 210 and 410 and the second area on which the FPCs 300 and 310 occupy the input wiring of the driving IC are attached to the edges of the lower plate. Because it is located.

In particular, the input wiring of the signal line driver IC is about 38 or more, much more than the input wiring of the scan line driver IC. Therefore, the influence of the display area on the lower panel due to the second area where the input wiring of the signal line driver IC is located is greater than that due to the second area where the input wiring of the scanning line driver IC is located.

Therefore, it is necessary to reduce the ratio of the second area occupying the lower plate so that the size of the lower plate does not increase and the ratio of the display area occupying the lower plate needs to be increased.

1 is a plan view illustrating a liquid crystal display device of a typical chip on glass (COG) method.

FIG. 2A is a plan view showing a COG type liquid crystal display device in which input wiring is directly mounted on a lower plate.

2B is a cross-sectional view illustrating a common electrode and a common voltage wiring in a COG type liquid crystal display device in which input wiring is directly mounted on a lower plate.

3 is a plan view showing a COG type liquid crystal display device of the present invention.

4 is a cross-sectional view showing the connection portion between the IC and the FPC in the COG type liquid crystal display device of the present invention.

5 is a plan view showing a pad formed on a short side of an IC in the liquid crystal display of the present invention.

<Explanation of symbols for main parts of drawing>

1: top plate 2: bottom plate

10: PCB board 12: data transmission line

17: pixel 20: FPC

21: input wiring 23: scanning line

30: scan line drive IC 32: scan line output terminal

40: signal line driver IC 42: signal line output terminal

44 signal line 50 common electrode

51: common electrode wiring 52: silver contact point (Ag dot)

70: signal line input wiring 70: scan line input wiring

100: top plate 200: bottom plate

210: signal line driver IC 300: wiring part of FPC

310: FPC lead-out part 410: scanning line drive IC

500: IC Pad

According to the present invention, an input wiring is formed on the FPC, and an input electrode is formed on the short axis of the driving IC, and a lead line connecting the input wiring formed on the FPC and the input electrode formed on the short surface of the driving IC is formed on the FPC. It is a liquid crystal display device.

The structure of the present invention shown in FIG. 3 includes a substrate 200; A first input wiring, a second input wiring is formed, a first region located outside the substrate, and a first lead wire branched from the first input wiring, and branched from the first region An FPC 300 including a second region overlapping a portion on the substrate and a second leader line branching off the second input wiring and branching from the first region and overlapping a portion on the substrate; Wow; A first input electrode connected to the first lead-out line, a second input electrode connected to the second lead-out line, and formed on a short side opposite to the short-axis surface on which the first input electrode is formed; The driving circuit includes an output electrode formed on one long axis surface and is mounted on a part of an edge of the substrate. The first leader line and the second leader line are connected to the first input electrode and the second input electrode by bumps. 4 is a cross-sectional view showing an FPC and an IC connected by bumps. The lead wire formed in the FPC is connected to the input pad of the IC by bumps. The input pad of the IC may be formed as shown in FIG. The short side of the IC has a narrow width, making it difficult to form many pads. Therefore, when the pad is formed in a zigzag on the short axis, more pads can be formed. The first input wiring formed on the FPC is connected to the first input electrode, and the second input wiring is connected to the second input electrode to increase the utilization of both short-side surfaces of the IC.

In the liquid crystal panel of the present invention, since both the input wiring and the lead wire are formed in the FPC, the input electrode of the driving IC is formed on the side of the driving IC, and the lead line is connected to the input electrode formed on the side of the driving IC. Compared to the LCD panel, the pad area of the lower plate occupied by the input wiring and the lead wire is reduced. Thus, the ratio of the display area to the lower panel is higher than that of the related art.

Claims (1)

A substrate; A first input wiring, a second input wiring is formed, a first region located outside the substrate, and a first lead wire branched from the first input wiring, and branched from the first region An FPC comprising a second region overlapped with a portion on the substrate and a second lead line branched from the second input wiring and branched from the first region and overlapping a portion on the substrate; A first input electrode connected to the first lead-out line, a second input electrode connected to the second lead-out line, and formed on a short side opposite to the short-axis surface on which the first input electrode is formed; And a driving IC including an output electrode formed on one long axis surface and mounted on a part of an edge of the substrate.

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