Liquid crystal display device and thin film transistor substrate thereof

An LCD device comprises a plurality of transparent pixel electrodes, a first substrate, a second substrate, a liquid crystal material, and a light shield device. The first substrate has a plurality of terminals electrically connected to the transparent pixel electrodes via a plurality of outgoing lines, and the terminals are gathered to define a plurality of terminal groups, thereby defining a plurality of outgoing line groups. The second substrate has opposing electrodes opposite to the transparent pixel electrodes. The liquid crystal material is sealed between the first and second substrates. The light shield device is adjacent to the outgoing line groups and the terminal groups and adjacent to the outgoing lines within the outgoing line groups and the terminals within the terminal groups, but not touching the outgoing lines and the terminals for preventing the light leakage on the edge of the liquid crystal display.

BACKGROUND OF THE INVENTION

1. Field of the Invention

The present invention generally relates to a liquid crystal display device, and more particularly to a thin film transistor substrate of the liquid crystal display having light-shield device to prevent light leakage.

2. Description of the Related Art

Due to the advance of electronic technology, especially for the popularity of portable electronic products, the requirements of light, compact and low-energy consuming display are gradually increasing. With the advantages of low-energy consuming, low-heat dissipation, light-weight and non-luminescence, liquid crystal displays (LCD) have been widely used in the electronic products and even have replaced the traditional CRT displays.

An LCD basically consists of polarizers, glass electrodes and liquid crystal materials. The polarizers are made by sandwiching the polarizer material between two transparent films. The glass electrodes are made of high quality flat glass which is plated with a layer of conductive film of metallic oxidation. When the liquid crystal molecules are applied with electric field, they are easily re-arranged into a different alignment state, thereby resulting in different transmittance according to the electric field applied and displaying image in the LCD. The manufacturing process of LCD substantially includes the steps of injecting the liquid crystal material into the space between the two flat glasses with glass electrodes thereon, and adhering polarizer films onto the outer surfaces of the flat glasses so as to form the LCD cell. Then the driving circuits, controlling circuit, and backlight components, etc., will be assembled to constitute an LCD module.

Further, for conventional manufacturing processes of a thin film transistor (TFT) substrate, a tri-layer process or a back channel etch (BCE) process is employed for facilitating the TFT matrix. Conventionally, six to nine masking steps are required for both the BCE process and the tri-layer process so as to form a layered TFT structure on a glass substrate. In this TFT structure, disposed on the glass substrate are a first conductive layer and a second conductive layer in turn, and an insulation layer is sandwiched therebetween. The first conductive layer is used to form scan lines and gate electrodes of a TFT unit, and is generally referred to as “metal one”. The second conductive layer is used to form data lines and source/drain electrodes of a TFT unit, and is generally referred to as “metal two”.

The first and second conductive layers which are opaque are typically made of metal, such as chrome and aluminum, and cooperate with an Indium-Tin-Oxide (ITO) electrode on the perimeter (the out lead bonding region) of the TFT substrate to form terminals or leads. The first and second conductive layers are formed as parallel lines on the displaying region of the TFT substrate and the lines are gathered to form a plurality of terminal groups on the out lead region. The terminal groups are corresponding to tape carrier packages for electrically connecting to the driving circuits and/or the controlling circuits.

As shown inFIG. 1, it depicts a typical LCD module10provided with a metal frame12. The LCD module10substantially comprises an LCD panel14and a back light module16. The LCD panel14includes a TFT substrate18and a color filter (CF) substrate20. The back light module16comprises a light source (not shown), a light guiding plate22, and a multi-layer prismatic plate24.

As shown in the drawing, the TFT substrate18is illuminated with the back light module16and a differential distance Ws exists between the real width and the ideal width W of the black matrix layer of the CF substrate20. Therefore, the light may leak (shown by the arrow in the drawing) from the region between the metal frame12and the CF substrate20. When the LCD module10is observed with an angle larger than θ, the leaking light may cause visibly bright lines in the edge of the metal frame12. Also, on an outlead bonding region of the LCD module10, the metal terminals are opaque and are gathered to form a plurality of groups corresponding to the driving circuits and the controlling circuits, so the uneven luminance is formed on the perimeter (the outlead bonding region) of the LCD module10. This uneven luminance is corresponding to the location of the terminal groups. Further, because of the design of lightening the module and increasing the opening of the metal frame and the visible area, the problem of the light leakage became more serious.

Thus, U.S. Pat. No. 5,850,275 entitled “Liquid Crystal Display” issued on Dec. 15, 1998 to Watanabe et al., incorporated herein by reference, discloses a liquid crystal display having a light shield material provided on regions adjacent to but not touching the terminal groups and the outgoing line groups to decrease this uneven luminance on the perimeter of the LCD. However, the light shield area is formed with the same materials as that of the terminals and the outgoing lines in the same process simultaneously, i.e. the light shield area, the terminals and the outgoing lines are constituted by the same metal layer. Therefore, the light shield area mentioned above cannot be formed between the lines, so the problem of the light leakage on the edge of the LCD module still has not been solved.

Accordingly, there exist needs for providing a suitable device for preventing the light from leaking through the out lead bonding region on a TFT substrate of an LCD, thereby providing the even luminance on the edge of the LCD.

SUMMARY OF THE INVENTION

It is a primary object of the present invention to provide a liquid crystal display device having two substrates and a back light module, wherein one of the two substrates is provided with a light shield device for effectively preventing the light leakage of the back light module.

It is another object of the present invention to provide a thin film transistor (TFT) substrate having a light shield device without any extra process.

In order to achieve the objects mentioned hereinabove, the present invention provides an LCD device comprising: transparent pixel electrodes, a first substrate, a second substrate, a liquid crystal material, and a light shield device. The first substrate has a plurality of terminals electrically connected to the transparent pixel electrodes via outgoing lines, and the terminals are gathered to define a plurality of terminal groups, thereby defining a plurality of outgoing line groups. The second substrate has opposing electrodes opposite to the transparent pixel electrodes. The liquid crystal material is sealed between the first and second substrates. The light shield device is adjacent to the outgoing line groups and the terminal groups and adjacent to the outgoing lines within the outgoing line groups and the terminals within the terminal groups, but not touching the outgoing lines and the terminals thereby preventing the light leakage on the edge of the liquid crystal display.

According to another aspect of the present invention, the first substrate further comprises a transparent substrate, a first conductive layer disposed on the transparent substrate, an insulation layer disposed on the first conductive layer, and a second conductive layer disposed on the insulation layer, wherein the outgoing lines and the terminals are formed by the second conductive layer, and the light shield device is formed by the first conductive layer.

According to a further aspect of the present invention, the light shield device is formed as a one-piece integral structure.

According to still another aspect of the present invention, the light shield device comprises a plurality of light shield strips and a plurality of light shield sheets disposed between the outgoing lines and between the terminals.

As mentioned above, the LCD device according to the present invention comprises the light shield devices disposed on the TFT substrate, so the light of the back light module can not pass through the TFT substrate, thereby preventing the light leakage on the area between the metal frame of the LCD and the CF substrate and maintaining the quality of the display.

DESCRIPTION OF THE PREFERRED EMBODIMENT

Now referring toFIGS. 2,3,4, and5, they depict a liquid crystal display panel54of a liquid crystal display (LCD) module50according to a preferred embodiment of the present invention. As shown inFIG. 2, the panel54comprises a thin film transistor (TFT) substrate58, and a color filter (CF) substrate60(shown inFIG. 5) disposed above the TFT substrate58and slightly smaller than the TFT substrate58. The TFT substrate58comprises a displaying portion61having a plurality of transparent pixel electrodes, and outgoing groups56electrically connected to the pixel electrodes, terminal groups55, and light shield devices73. The LCD panel54is connected to carrier tapes66through the respective terminal groups55such that the pixel electrodes are electrically connected to driving and/or controlling circuits63. The TFT substrate58further comprises a seal member87for cooperating with the CF substrate60to seal a liquid crystal material therebetween.

Now referring toFIG. 3, it depicts an enlarged view of the area3shown inFIG. 2. The TFT substrate58comprises a plurality of outgoing lines67extending outward to the perimeter of the TFT substrate58, thereby forming a plurality of terminals69. The plurality of outgoing lines67are gathered on the perimeter of the TFT substrate58to form a plurality of outgoing line groups56and the plurality of the terminals69are gathered as terminal groups55. The terminal groups55are connected to the carrier tapes66for electrically connecting to the driving and/or the controlling circuits63which is outside the TFT substrate58. These outgoing lines67and the terminals69are disposed on the perimeter of the TFT substrate58to define an out lead bonding region, which is substantially L-shaped, on the TFT substrate58.

As shown in the drawing, there is a transparent glass substrate71of the TFT substrate58between the respective terminals69and the outgoing lines67, so the light leaks therefrom. Thus, the TFT substrate58according to the present invention comprises a light shield device73to avoid the light leakage. The light shield device73is a one-piece integral structure covering the entire out lead bonding region.

Now referring toFIG. 4a,it depicts a partial cross-sectional view of the TFT substrate58according to the present invention. As mentioned above, the TFT substrate58substantially has a laminated structure, and substantially comprises the transparent glass substrate71with a first conductive layer81, an insulation layer82, a second conductive layer83, an insulation layer84, and transparent electrode layer85disposed thereon in turn. In a preferred embodiment according to the present invention, the outgoing lines67and the terminals69are formed by the second conductive layer83, and are electrically connected to the transparent electrode layer85on the outer surface of the TFT substrate58. The light shield device73is formed by the first conductive layer81to prevent the light from leaking. Alternatively, as shown inFIG. 4b,the light shield device73also can be formed by the second conductive layer83, and the outgoing lines67and the terminals69are formed by the first conductive layer81.

It will be appreciated by those skilled in this art that, as mentioned above, the light shield device73and the outgoing lines67and the terminals69are made of different conductive layers, so the light shield device73can be formed as an integral structure and overlap with the outgoing lines67and the terminals69, thereby providing a complete light shield effect.

Again, as shown inFIG. 5, it depicts a partial cross-sectional view of the LCD module50according to the present invention. The LCD module50comprises a back light module53including a light source (not shown), a light guiding plate62, and a multi-layer prismatic plate64. The light shield device73is positioned on the TFT substrate58, so the light of the back light module53will not pass through the TFT substrate58, thereby preventing the light leakage on the area between the metal frame86and the CF substrate60and improving the display quality. It will be appreciated by those skilled in the art that the CF substrate60further comprise an opposing electrode for cooperating with the pixel electrode on the TFT substrate to control the displaying of the LCD device.

Now referring toFIG. 6, it depicts a view of a TFT substrate58′ according to another embodiment of the present invention similar to that inFIG. 3, wherein like reference numerals refer to corresponding parts. The TFT substrate58comprises a one-piece integral light shield device73, but the integral light shield device73is easy to cooperate with the terminals69and the outgoing lines67and cause the short-circuit and capacitive reactance, thereby affecting the performance of the TFT substrate58. Therefore, the TFT substrate58′ is provided with a plurality of separate light shield devices73′ divided by the outgoing lines67and the terminals69. The light shield devices73′ substantially comprise a plurality of light shield strips75and a plurality of light shield sheets76. The light shield strips75are located between the respective outgoing lines67and between the respective terminals69. The light shield sheets76are located between the respective outgoing line groups56and between the respective terminal groups55. As shown inFIG. 7, which depicts a partial enlarged view of the area7inFIG. 6, the light shield strips75and the light shield sheets76are spaced apart from the outgoing lines67and the terminals69.

Now referring toFIG. 8, it depicts a view of a TFT substrate58″ according to another embodiment of the present invention similar to that inFIG. 3, wherein like reference numerals refer to corresponding parts. The TFT substrate58″ is provided with a plurality of separate light shield devices73″ divided by the outgoing lines67and the terminals69. The light shield devices73″ substantially comprise a plurality of light shield strips77and a plurality of light shield sheets78. The light shield strips77are located between the respective outgoing lines67and between the respective terminals69. The light shield sheets78are located between the respective outgoing line groups56and between the respective terminal groups55. The edge regions of the light shield strips77and the light shield sheets78are overlapped with the edge regions of the outgoing lines67and the terminals69.

As mentioned above, the TFT substrates according to the present invention take advantage of the first conductive layer and the second conductive layer of the substrate for forming the light shield device, and thus the leakage of the light of the back light module can be effectively prevented without any extra process. Further, the light shield device is adjacent to the outgoing line groups and the terminal groups and adjacent to the outgoing lines of the outgoing line groups and the terminals of the terminal groups, but not contacting the outgoing lines and the terminals, thereby completely preventing the light leakage of the back light module.