JP4637868B2 - Image display device - Google Patents

Description

  The present invention relates to a liquid crystal display device, and more particularly to a liquid crystal display device in which a peripheral region surrounding an image display region is narrowed.

  A liquid crystal display device is known as an image display device. In particular, liquid crystal display devices using thin film transistors can display high-definition images, and are therefore used as image display devices for televisions, personal computer displays, and portable terminals.

  In recent years, the outer frame of an image display apparatus has been reduced in size, while the image display area has been expanded in order to improve information recognition. In addition, the number of pixels is increased and the number of gate lines and drain lines is increased due to high definition of a display image.

  FIG. 5 is a wiring diagram of a transparent substrate of a conventional liquid crystal display device and its periphery.

  The liquid crystal display device is formed with two transparent substrates facing each other with a liquid crystal layer interposed therebetween. The surface of the first transparent substrate PNL1 on the liquid crystal side extends in the X direction (horizontal direction) and is arranged in parallel in the Y direction (vertical direction), and is insulated from the gate lines and insulated in the Y direction. And a drain (or source) line DW arranged in parallel in the X direction. A counter electrode and a color filter are formed on the second transparent substrate.

  In a region surrounded by two adjacent gate lines GW and two adjacent drain lines DW, a switching element that is turned on by a scanning signal from the gate line, and a video signal from the drain line passes through the switching element. The pixel electrode supplied through the so-called pixel is formed to form a so-called pixel. A region where the plurality of pixels are formed is a pixel region AR.

  A peripheral area PA exists around the pixel area AR. Wirings for connecting the drain driving circuit and the gate driving circuit to the gate line and the drain line in the pixel region are provided in the peripheral region.

  The peripheral area of the liquid crystal display device for portable terminals is narrow. In the peripheral area of the liquid crystal display device, a circuit chip for driving liquid crystal (hereinafter referred to as a driver) and wiring for connection are arranged.

  The second transparent substrate is formed smaller than the first transparent substrate. In the first transparent substrate, a drain driver DDr and a gate driver GDr are installed in a region not facing the second transparent substrate.

  Since the liquid crystal display device having an enlarged image display area has a narrow peripheral area, it is not possible to secure a space for providing an inspection terminal for inspecting the liquid crystal display element by lighting it. Or, after the inspection, the inspection terminal was cut off. Therefore, the conventional liquid crystal display device has low mass productivity.

  Even when the inspection terminal is not provided, the connection terminal of the gate line to the gate driver and the connection terminal of the drain line to the drain driver can be used as the inspection terminals. However, in this case, it is difficult to align the terminals of the inspection device and the connection terminals.

  The liquid crystal display device of the present invention includes transparent substrates disposed to face each other with a liquid crystal interposed therebetween. One transparent substrate has a plurality of gate lines extending in the X direction (horizontal direction) and arranged in parallel in the Y direction (vertical direction), and is insulated from the plurality of gate lines and extends in the X direction to extend in the Y direction. And a plurality of drain (or source) lines arranged side by side. The transparent substrate has a peripheral region surrounding a pixel region formed by the plurality of gate lines and the plurality of drain lines.

  The first substrate has a pixel region in which a pixel electrode is formed and a peripheral region surrounding the pixel region, and a lighting inspection terminal of the liquid crystal display device is formed in the peripheral region. A semiconductor chip for driving a liquid crystal is disposed on the inspection terminal so as to be electrically insulated from the inspection terminal.

  The semiconductor chip is composed of two semiconductor chips, a drain driver and a gate driver, and the drain driver is disposed on the inspection terminal.

  The inspection terminals include a drain line inspection terminal and a gate line inspection terminal.

  As another structure of the present invention, the liquid crystal display device is a liquid crystal display device having a liquid crystal layer between a first substrate and a second substrate, and the first substrate has a pixel region having a pixel electrode. And a peripheral region surrounding the pixel region. In the peripheral region, three drain line inspection terminals and four gate line inspection terminals are arranged, and three drain line inspection terminals and four gate line inspection terminals are arranged. A semiconductor chip is disposed on the terminals.

  Further, the drain line inspection terminal includes a red drain line inspection terminal, a green drain line inspection terminal, and a blue drain line inspection terminal.

  Adjacent gate lines are connected to different gate line inspection terminals.

  The present invention can provide a liquid crystal display device capable of reliably inspecting image display even if the peripheral region is narrowed without cutting the peripheral region provided with the circuit for inspecting the liquid crystal display device.

  With the above configuration, the panel peripheral area surrounding the display area can be reduced.

  In addition, the panel peripheral region can be reduced, and an electrical short circuit between the gate lines GW and an electrical short circuit between the drain lines DW can be reliably detected.

  Positioning of the inspection terminal of the display device and the terminal of the inspection device is facilitated, and manufacturing of the display device is facilitated.

  Since the semiconductor chip is mounted on the inspection terminal via an anisotropic conductive film, the inspection terminal is not exposed to the outside air, and damage due to static electricity and corrosion of the electrode due to electric corrosion can be suppressed.

  Embodiments of the present invention will be described below with reference to the drawings.

  In each example, parts having the same function are denoted by the same reference numerals.

  FIG. 1 is a plan view of a liquid crystal display device 1 according to the present invention, showing wiring formed on a first substrate. FIG. 1 is a plan view of a liquid crystal display device for a portable terminal in which the effective screen has a diagonal dimension of about 5.08 cm, and is a plan view of a transparent substrate on which pixel electrodes are formed. The liquid crystal display device of FIG. 1 employs an active matrix system.

  The active matrix type liquid crystal display device includes rectangular substrates disposed opposite to each other, and has a liquid crystal layer between the first substrate PNL1 and the second substrate PNL2. The second substrate PNL2 is formed smaller than the first substrate PNL1.

  The liquid crystal side surface of the first substrate PNL1 extends in the X direction (horizontal direction) and juxtaposed in the Y direction (vertical direction), and is insulated from the gate line GW and extends in the X direction. And a drain line (or source line) DW arranged in parallel in the Y direction. A storage capacitor line SW is arranged in parallel with the gate line. FIG. 1 shows a part of a plurality of gate lines GW and drain lines.

  A switching element that is turned on by a scanning signal from the gate line, and a pixel electrode to which a video signal from the drain line is supplied via the switching element, in each region surrounded by the gate line and the drain line that intersect with each other Are formed to form a so-called pixel. As the switching element, there is a thin film transistor TFT.

  In the first substrate, the drain driver DDr and the gate driver GDr are installed in a region not facing the second transparent substrate. The gate driver GDr and the drain driver DDr are mounted on one side of the short side of the first substrate PNL1 by a flip chip method. The gate driver GDr is connected to the gate line GW, and the drain driver is connected to the drain line DW.

  A common electrode is formed on the second substrate PNL2. In addition, a capacitor is LC-formed by the common electrode and the pixel electrode, and holds a voltage.

  A common line Vcom connected to the common electrode is disposed on the first substrate.

  The wiring shown in FIG. 1 is a wiring formed on the first substrate PNL1.

  In the peripheral area PA, a gate line inspection transistor TG and a drain line inspection transistor TD are formed.

  The gate inspection transistor TG is provided on the long side of the first substrate PNL1, and is connected to one end of the gate line. The other end of the gate line is connected to the gate driver GDr.

  The odd-numbered gate line inspection transistor TG has one end connected to the odd-numbered gate line GW, and the other end connected to the odd-numbered gate line inspection terminal CGO.

  The even-numbered gate line inspection transistor TG has one end connected to the even-numbered gate line GW and the other end connected to the even-numbered gate line inspection terminal CGE.

  The drain line inspection transistor TD has one end connected to the drain line DW, and the other end is connected to any one of the red drain line inspection terminal CR, the green drain line inspection terminal CG, and the blue drain line inspection terminal CB. Is connected.

  The gates of the gate line inspection transistor TG and the drain line inspection transistor TD are connected to a common inspection switch S.

  Gate line inspection terminal CGO for odd rows, gate line inspection terminal CGE for even rows, red drain line inspection terminal CR, green drain line inspection terminal CG, blue drain line inspection terminal CB, inspection A drain driver DDr is disposed on the common terminal CV via an anisotropic conductive film. At this time, the drain driver DDr and the inspection terminal are electrically insulated.

  The inspection switch S is disposed below the gate driver. The gate driver is also fixed to the first substrate PNL via an anisotropic conductive film. At this time, the gate driver GDr and the inspection switch terminal are electrically insulated.

  With this configuration, a liquid crystal display device can be manufactured without enlarging the peripheral area PA. In addition, since the anisotropic conductive film is in close contact with the inspection terminal portion, it is difficult to touch the outside air, so that the electrolytic corrosion of the terminal portion can be suppressed.

  Furthermore, it is not necessary to cut the portion where the inspection terminal of the substrate is formed, and the manufacturing process of the liquid crystal display device can be simplified. Moreover, since the cutting process of the inspection terminal can be omitted, chips on the substrate can be suppressed and display defects due to dust can be suppressed.

  Further, when the liquid crystal is driven, the gates of all the inspection transistors can be turned off by setting the inspection switch S to a low level. The substrate is provided with a terminal TV for supplying a voltage for turning off the gate of the inspection transistor.

  Next, the inspection method will be described.

  FIG. 2 is a driving waveform when displaying red, and is a waveform of a voltage input to each inspection terminal. FIG. 2A is a waveform input to the odd-numbered gate line inspection terminal CGO. 2B is a waveform input to the even-numbered gate line inspection terminal CGE, FIG. 2C is a waveform input to the red drain line inspection terminal CR, and FIG. 2D is green and blue. This is a waveform inputted to the drain line inspection terminals CG and CB for use. In this embodiment, a normally white liquid crystal display device was used.

  A pulse voltage having a period of Mms and a pulse width of N μs is supplied to the odd-numbered gate line inspection terminal CGO. On the other hand, a pulse voltage whose period is shifted from the pulse voltage applied to the odd-numbered row is applied to the gate line inspection terminal CGE in the even-numbered row. With such a configuration, a short circuit between the gate lines can be detected.

  A voltage whose polarity is inverted every Mms is supplied to the red drain line inspection terminal CR. A voltage whose polarity is inverted every Mms is supplied to the green and blue drain line inspection terminals CG and CB.

  Red can be displayed by decreasing the voltage supplied to the red drain line inspection terminal CR and increasing the voltages supplied to the green and blue drain line inspection terminals CG and CB. At this time, a short circuit with the drain line adjacent to the red drain line can be inspected.

  Similarly, a short circuit between adjacent drain lines can be inspected by displaying either green or blue.

  The gates of the gate line inspection transistor TG and the drain line inspection transistor TD are ON. After completion of the inspection, the gates of the gate line inspection transistor TG and the drain line inspection transistor TD are turned off by the inspection switch S. For example, when the liquid crystal is driven, the gates of all the inspection transistors can be turned off by setting the inspection switch S to a low level. Since the gate of the inspection transistor is always OFF when the liquid crystal is driven, an image can be displayed stably.

  In the liquid crystal display device of FIG. 1, since there is one inspection switch S, only one voltage supply terminal is required for driving.

  Further, after the inspection is completed, one end of each drain line is connected to the terminal of the drain driver DDr.

  FIG. 3 shows a liquid crystal display device comprising a first liquid crystal display device 1 provided with a gate driver GDr and a drain driver DDr, and a second liquid crystal display device 2 connected to the first liquid crystal display device by a flexible substrate FPC. is there. A part of the drain line DW is shared by the first liquid crystal display device and the second liquid crystal display device.

  A second common line Vcom2 used in the second liquid crystal display device is wired on the first substrate.

  In the liquid crystal display device of FIG. 3, a semiconductor chip for driving liquid crystal is provided on one substrate short side, and at the same time, a terminal for connecting to the second liquid crystal display device via a flexible substrate is formed on the other substrate short side. Is done. Therefore, the peripheral area is further narrowed. By applying the present invention to such a liquid crystal display device, the outer shape of the liquid crystal display device can be reduced.

  FIG. 4 shows a liquid crystal display device in which a gate driver and a drain driver are accommodated in one driver Dr. Parts having the same functions as those in FIG.

  There are a total of 398 drain lines DW from D0 to D397. There are a total of 178 gate lines GW from G0 to G177.

  In the liquid crystal display device of FIG. 4, the gate line that drives the side half region far from the driver is connected to the driver Dr through the right peripheral region, and the gate line that drives the side half region near the driver is the left side. The driver Dr is connected through the peripheral region. The drain line is connected to the driver in a region including the central part of the long side of the driver.

  A gate line connected to the driver Dr through the peripheral region on the right side of the substrate is connected to a gate line inspection transistor formed on the left side of the substrate.

  A gate line connected to the driver Dr through a peripheral region on the left side of the substrate is connected to an inspection transistor formed on the right side of the substrate.

  In the center, a drain line inspection switch terminal S1, a red drain line inspection terminal CR, a green drain line inspection terminal CG, and a blue drain line inspection terminal CB are arranged. The drain line inspection switch terminal S1 is connected to the gate of the drain line inspection transistor TD.

  On the left side of the drain inspection terminal, a gate line inspection terminal connected to the driver Dr through the peripheral region on the right side of the substrate is arranged. The gate line inspection terminals include an odd-numbered gate line inspection terminal CGO1, an even-numbered gate line inspection terminal CGE1, and a gate line inspection switch terminal S2.

  On the right side of the drain inspection terminal, a gate line inspection terminal connected to the driver Dr through the peripheral region on the left side of the substrate is arranged. The gate line inspection terminals include an odd-numbered gate line inspection terminal CGO2, an even-numbered gate line inspection terminal CGE2, and a gate line inspection switch terminal S3.

  A driver Dr is fixed on these inspection terminals via an anisotropic conductive film. At this time, the driver Dr and the inspection terminal are electrically insulated.

It is a top view of the board | substrate of the liquid crystal display device by this invention. It is a figure which shows the waveform for a test | inspection of the liquid crystal display device by this invention. It is a board | substrate top view of the other structure of the liquid crystal display device of this invention. It is a board | substrate top view of the other structure of the liquid crystal display device of this invention. It is a top view of the board | substrate of the conventional liquid crystal display device.

Explanation of symbols

  PNL ... substrate, AR ... pixel area, AP ... peripheral area, GW ... gate line, DW ... drain line, GDr ... gate driver, DDr ... ..Drain driver, TD ... Drain line inspection transistor, TG ... Gate line inspection transistor, CR ... Red drain line inspection terminal, CG ... Green drain line inspection Terminal for CB,..., Blue drain line inspection terminal, CGO,... Odd line gate line inspection terminal, CGE,... Even line gate line inspection terminal.

Claims (8)

A substrate having a plurality of scanning signal lines, a plurality of video signal lines, and a plurality of pixels;
An image display device having two driver chips mounted on the substrate,
One of the two driver chips has a video signal output terminal for supplying a video signal to the video signal line,
The substrate is provided between the video signal line connection terminal to which the video signal output terminal is connected, and the video signal line inspection terminal, the video signal line connection terminal and the video signal line inspection terminal, normal image Turned on by a voltage from a terminal on the substrate, which is turned off at the time of display and below one of the two driver chips at the time of inspection, to control the connection between the video signal line connection terminal and the video signal line inspection terminal A video signal line inspection transistor
The driver chip having the video signal output terminal is disposed on the video signal line inspection transistor,
One of the two driver chips is disposed on the video signal line inspection terminal.
An image display device characterized by that. The substrate has a scanning signal line inspection terminal;
One of the two driver chips is disposed on the scanning signal line inspection terminal.
The image display apparatus according to claim 1. The scanning signal line inspection terminal has a first scanning signal line inspection terminal and a second scanning signal line inspection terminal,
One of the two adjacent scanning signal lines is connected to the first scanning signal line inspection terminal, and the other of the two adjacent scanning signal lines is connected to the second scanning signal line inspection terminal. The image display device according to claim 2, wherein the image display device is connected.   4. The image display device according to claim 1, wherein the video signal line inspection terminal is electrically insulated from an input terminal and an output terminal of the driver chip during normal image display.   The image display device according to claim 1, wherein the pixel includes a switching element. The plurality of pixels are formed in a pixel region,
6. The image display device according to claim 1, wherein the video signal line inspection terminal and the video signal line inspection transistor are formed outside the pixel region.   7. The video signal line inspection terminal includes a video signal line inspection terminal for red, a video signal line inspection terminal for green, and a video signal line inspection terminal for blue. Any one of the image display apparatuses.   2. The image display device includes: a second substrate disposed opposite to the substrate; and a liquid crystal layer disposed between the substrate and the second substrate. 8. The image display device according to any one of items 1 to 7.

Images