WO2014044166A1 - Display screen - Google Patents

Description

 Display Technical field

The utility model belongs to the technical field of display, in particular to an ultra-narrow side display screen.

Background technique

At present, in the field of display technology, the demand for ultra-narrow side and large-area display of display screens is increasing day by day. For example, the video wall splicing technology requires that each splicing screen reach an ultra-narrow side to achieve seamless splicing effect. The ultra-narrow bezel will significantly increase the display area and provide a better visual effect for the viewer. The narrow-edge design in the prior art is still focused on the modification of the shape of the frame, and the width of the narrow frame currently appearing is still greater than 5 Mm. Due to the presence of the row scanning and column scanning driving circuits at the edge of the display module, the frame of the display is difficult to be made narrower.

technical problem

The purpose of the utility model is to provide a display screen, which aims to overcome the influence of the line scanning and column scanning circuits on the edge of the display module on the width of the display frame border, and further reduce the width of the display frame border.

Technical solution

The present invention is implemented in such a manner that a display screen includes a display front plate and a thin film transistor back plate, and the thin film transistor back plate is provided with a row scan line, a column scan line and a thin film transistor for driving the display front plate. Array, The thin film transistor backplane is provided with via holes corresponding to the row scan lines and the column scan lines, and the row scan lines and the column scan lines are led to the thin film transistor backplane through corresponding via holes. The back is electrically connected to a scan driving module disposed on a back of the thin film transistor backplane.

As a preferred technical solution of the present invention:

The via hole is filled with a conductive medium, and the row scan line and the column scan line are both connected to a conductive medium in the corresponding via hole; the conductive medium is scanned with the back of the thin film transistor back plate The drive module is electrically connected.

The via holes corresponding to the row scan lines and the column scan lines are respectively located at edges of the thin film transistor backplane.

The via holes corresponding to the row scan lines and the column scan lines are located in an intermediate portion of the thin film transistor backplane.

Beneficial effect

The utility model provides a through hole on the back plate of the thin film transistor, and leads the row and column scan lines to the back of the display screen through the through hole, and connects the scan driving module on the back thereof to avoid occupying the space on the front side of the display screen. The width of the display reduces the width of the border of the display, achieving the ultra-narrow side of the display.

DRAWINGS

1 is a cross-sectional view of a display screen according to a first embodiment of the present invention;

2 is a front view of a thin film transistor backplane and a pixel in the first embodiment of the present invention;

3 is a front elevational view of a thin film transistor backplane in a first embodiment of the present invention;

Figure 4 is a rear elevational view of the thin film transistor backplate of the first embodiment of the present invention.

Figure 5 is a cross-sectional view of a display screen provided by a second embodiment of the present invention;

Figure 6 is a rear elevational view of a thin film transistor backplate in a second embodiment of the present invention.

Embodiments of the invention

In order to make the objects, technical solutions and advantages of the present invention more comprehensible, the present invention will be further described in detail below with reference to the accompanying drawings and embodiments. It is understood that the specific embodiments described herein are merely illustrative of the invention and are not intended to limit the invention.

The specific implementation of the present invention will be described in more detail below with reference to specific embodiments:

1 is a cross-sectional view of a display screen provided by a first embodiment of the present invention, and for convenience of explanation, only parts related to the present embodiment are shown.

As shown in FIG. 1, the display screen mainly includes a display front panel 1 and a thin film transistor backplane 2, and a thin film transistor backplane 2 is provided with a row scan line 21, a column scan line 22 and a thin film transistor 23, and the thin film transistor 23 passes through The electric signals transmitted by the scanning line 21 and the column scanning line 22 change their operational states, and further modulate the color, brightness, and the like of the pixels 11 of the display front panel 1 to output an image.

Further referring to FIGS. 1, 2, and 3, in order to achieve narrowing of the display screen, the present embodiment has a plurality of via holes 24, via holes 24 and row scan lines 21 and column scan lines on the thin film transistor backplane 2. In a one-to-one correspondence, the row scan line 21 and the column scan line 22 can be directed to the back of the thin film transistor backplane 2 through the corresponding via holes 24. In addition, the scan driving module 3 of the display screen is also disposed on the back of the thin film transistor backplane 2. After the row scan line 21 and the column scan line 22 are led to the back of the thin film transistor backplane 2, they can be electrically connected to the scan driving module 3 directly on the back thereof, and can be electrically connected to the scan driving module 3 through wires. In this way, the space on the front side of the display screen can be avoided, the width of the frame of the display screen is greatly reduced, and the ultra-narrow side of the display screen is realized.

With further reference to FIGS. 3 and 4, the via holes (the first via holes 241) corresponding to the row scanning lines 21 and the via holes (the second via holes 242) corresponding to the column scanning lines 22 are respectively located in the thin film transistor. At the edge of the backboard 2. In addition, on the back of the thin film transistor backplane 2, the two scan driving modules 3 can be electrically connected to all of the row scanning lines 21 and the column scanning lines 22 drawn from the via holes 24 through the wires 4, respectively.

With further reference to FIGS. 5 and 6, in the second preferred embodiment, unlike the first embodiment, the first via hole 241 and the second via hole 242 may be located at the center of the thin film transistor backplane 2, And the first via hole 241 and the second via hole 242 may be distributed in a crisscross shape or may be distributed in other shapes. Moreover, the display screen can be provided with four scan driving modules 3, and each scan driving module 3 can be electrically connected with 1/2 number of row scanning lines 21 or 1/2 number of column scanning lines 22, of course, Connect according to other ratios. This can reduce the length of the wires 4 for connecting the scan driving module 3 and the row scanning lines 21 and the column scanning lines 22, thereby reducing the resistance, increasing the driving speed, and facilitating faster display. Of course, the scan driving module 3 can also be provided with more, and the embodiment does not have to be strictly limited.

It can be understood that the above two embodiments only disclose the distribution of two different via holes 24, but the distribution form of the via holes 24 in the present invention is not necessarily strictly limited to the above two types, as long as the thin film transistor back plate 2, a via hole 24 is formed, and the row and column scan lines are led from the via hole to the back of the thin film transistor back plate 2, and connected to the scan driving module 3 at the back thereof, thereby achieving ultra narrow edge of the display screen. The opening position of the through hole 24 and the connection manner of the scan driving module 3 and the like may be other forms, and the present invention is not necessarily limited.

Further, the row scan line 21 and the column scan line 22 in the present invention may be led to the back of the thin film transistor backplane 2 through a conductive medium 5 (such as a metal having better conductivity), that is, filled in the via hole 24. The conductive medium connects the row scan line 21 and the column scan line 22 to the conductive medium in the corresponding via hole 24, and then, on the back of the thin film transistor back sheet 2, a conductive paste 6 (specifically, anisotropic conductive The conductive medium 5 is connected to the wire 4, and the wire 4 is connected to the scan driving module 3, thereby connecting the row scanning line 21 and the column scanning line 22 to the scan driving module 3.

Further, the front panel 1 can be displayed in various types, such as a liquid crystal display front panel, an OLED display front panel, an electronic ink display front panel, and the like, and the embodiment is not necessarily limited.

Further referring to FIGS. 1 and 5, the display screen may further include a package glass 7 mounted on the image output side of the display front panel 1. The package glass 7 may be fabricated together with the display front panel 1 or may be assembled with the thin film transistor backplane. 2, the package glass 7 is assembled after the front panel 1 is displayed, and the embodiment is not necessarily limited.

Of course, the display screen may further include other functional components, which have no influence on the narrow edge of the display, which is not described in this embodiment.

The utility model provides a through hole on the back plate of the thin film transistor, and leads the row and column scan lines to the back of the display screen through the through hole, and connects the scan driving module on the back thereof to avoid occupying the space on the front side of the display screen. The width of the display reduces the width of the border of the display, achieving the ultra-narrow design of the display.

The above is only the preferred embodiment of the present invention, and is not intended to limit the present invention. Any modifications, equivalent substitutions and improvements made within the spirit and principles of the present invention should be included in the present invention. The scope of protection of utility models.

Claims (4)

A display screen includes a display front panel and a thin film transistor backplane, and the thin film transistor backplane is provided with a row scan line, a column scan line and a thin film transistor array for driving the display front panel, wherein The thin film transistor backplane is provided with via holes corresponding to the row scan lines and the column scan lines, and the row scan lines and the column scan lines are led to the thin film transistor backplane through corresponding via holes. The back is electrically connected to a scan driving module disposed on a back of the thin film transistor backplane. The display screen according to claim 1, wherein the via hole is filled with a conductive medium, and the row scan line and the column scan line are both connected to a conductive medium in the corresponding via hole; A medium is electrically connected to the scan driving module on a back side of the thin film transistor backplane. A display screen according to claim 1 or 2, wherein said via holes corresponding to said row scanning lines and column scanning lines are respectively located at edges of said thin film transistor backplane. A display screen according to claim 1 or 2, wherein said via holes corresponding to said row scanning lines and column scanning lines are located in an intermediate portion of said thin film transistor backplane.

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