The present application claims priority to Chinese patent application No. 201620514549.7 titled “Mask Plate” filed on May 30, 2016, the disclosure of which is incorporated herein in its entirety by reference.
The present disclosure relates to the field of display technology, and more particularly to a mask plate.
During a manufacturing process of a display panel, an organic resin material will be used to form a resin layer. At some regions of the resin layer, such as a location of a FPC IC (a drive circuit on a flexible printed circuit board), the resin layer needs to be hollowed-out, which will result in exposing of a metal line below the resin layer. The resin layer needs to be provided with an electrode layer of indium tin oxide (ITO), even having a metal line thereon to improve a resistance of the ITO or to be used as lead wires. Residual metal remained at a boundary between a hollowed-out region of the resin layer will lead to a short circuit of circuit traces below the resin layer, so that the display panel cannot display normally.
At present, in order to solve the above problem, usually an ashing time of photoresists of the metal layer is increased to implement a process correcting measurement. However, since the resin is relatively thick and the boundary of the hollowed-out region of the resin layer has a relatively steep slope, the effect of the process correcting measurement is poor, which has a significant adverse affect on a critical dimension (CD).
An object of the present disclosure is to provide a mask plate. By improving the mask plate, for example, a slope profile of a boundary of a hollowed-out region of a resin layer formed by using the mask plate can be improved, thus avoiding an occurrence of a short circuit between upper-layer metal and lower-layer metal of the resin layer.
The technical solution provided by the present disclosure is as follows.
A mask plate including a completely transparent region and a completely nontransparent region, wherein a semi-transparent structure is provided at a boundary between the completely transparent region and the completely nontransparent region, and has a light transmittance that decreases gradually from a side near the completely transparent region to a side near the completely nontransparent region.
Optionally, the semi-transparent structure comprises a plurality of light shielding blocks at the boundary of the completely transparent region and the completely nontransparent region, and the plurality of light shielding blocks is arranged at intervals along a boundary line between the completely transparent region and the completely nontransparent region.
Further, a gap between two adjacent light shielding blocks is of a pre-determined value so as to enable a light diffraction to occur between the two adjacent light shielding blocks, and/or a pre-determined gap between two adjacent light shielding blocks has a width that is less than a resolution of an exposure machine adopted in a mask process.
Further, each gap between any two adjacent light shielding blocks of the plurality of light shielding blocks has an identical width.
Further, each of the plurality of light shielding blocks is a rectangular block which is completely nontransparent.
Further, light transmittances of gaps between any two adjacent light shielding blocks of the plurality of light shielding blocks decrease gradually from a side near the completely transparent region to a side near the completely nontransparent region.
Further, each of the plurality of light shielding blocks and the completely nontransparent region of the mask plate are made of an identical material, and are integrally connected with each other.
Optionally, the mask plate is configured for a mask process at a resin layer, the resin layer comprises a hollowed-out region corresponding to the completely transparent region and a non-hollowed-out region corresponding to the completely nontransparent region, and a metal layer is formed in a first boundary region of the non-hollowed-out region at a boundary between the non-hollowed-out region and the hollowed-out region of the resin layer; and the boundary between the completely transparent region and the completely nontransparent region of the mask plate is provided with a plurality of boundary lines, and the plurality of boundary lines comprises at least a first boundary line corresponding to the first boundary region, and the semi-transparent structure is arranged at a location corresponding to the first boundary line.
Optionally, the completely transparent region comprises at least two completely transparent sub-regions, and the semi-transparent structure is provided at a boundary between each of the at least two completely transparent sub-regions and the completely nontransparent region.
Optionally, the two completely transparent sub-regions comprise a first completely transparent sub-region and a second completely transparent sub-region, an area of the first completely transparent sub-region is different from that of the second completely transparent sub-region, a plurality of first light shielding blocks is provided at a boundary between the first completely transparent sub-region and the completely nontransparent region, and a plurality of second light shielding blocks is provided at a boundary between the second completely transparent sub-region and the completely nontransparent region.
Further, the area of the first completely transparent sub-region is greater than that of the second completely transparent sub-region.
Further, a size of the first light shielding block is equal to or greater than that of the second light shielding block.
The beneficial effects of the present disclosure are as follows.
According to the mask plate provided by the present disclosure, the boundary between the completely transparent region and the completely nontransparent region is provided with the semi-transparent structure having the light transmittance that decreases gradually from the side near the completely transparent region to the side near the completely nontransparent region, so as to control and improve the gradient of the slope of the boundary of the hollowed-out region formed on the resin layer by using the mask plate. The gradient of the slope becomes gentler, thus avoiding the occurrence of the short circuit between upper-layer metal and lower-layer metal of the resin layer due to the steep slope of the boundary of the hollowed-out region of the resin layer.
In order to make the objects, the technical solutions and the advantages of the present disclosure more apparent, the present disclosure will be described hereinafter in a clear and complete manner in conjunction with the drawings and embodiments. Obviously, the following embodiments are merely a part of, rather than all of, the embodiments of the present disclosure, and based on these embodiments, a person skilled in the art may obtain the other embodiments, which also fall within the scope of the present disclosure.
In a related art, exemplarily, as shown in
In a related art, a transparent region and a nontransparent region on the mask plate are a region that has a light transmittance of 100% and a region that has light transmittance of 0, respectively. A contrast ratio between the transparent region and the nontransparent region is high, and a thickness of the resin layer is large, which causes a large slope at the boundary of the hollowed-out region of the resin layer after the resin layer being exposed and developed. Since the slope of the boundary is steep, the photoresist may hardly be exposed and developed sufficiently during the subsequent coating process.
Regarding an abnormal display that caused by the occurrence of the short circuit between the upper-layer metal trace and the lower-layer metal trace due to the steep slope of the boundary of the hollowed-out region of the resin layer, in the present disclosure, the key of solving the above problem is shifted to an improvement of a structure of the mask plate from a processing adjustment, so as to improve the slope of the boundary of the hollowed-out region of the resin layer.
The mask plate provided by the present disclosure is capable of improving such as the slope profile of boundary of the hollowed-out region of the resin layer formed using the mask plate, by improving the mask plate, thus avoiding the occurrence of the short circuit between the upper-layer metal and the lower-layer metal of the resin layer.
As shown in
According to the mask plate provided by the present disclosure, the boundary of the completely transparent region 100 and the completely nontransparent region 200 is provided with the semi-transparent structure 300, and the light transmittance of the semi-transparent structure 300 decreases gradually form the side near the completely transparent region 100 to the side near the completely nontransparent region 200. As shown in
In the mask plate provided by the present disclosure, as shown in
By adopting the above solution, the semi-transparent structure 300 may be formed by arranging the plurality of light shielding blocks 301 having a pre-determined length successively at the boundary between the completely transparent region 100 and the completely nontransparent region 200. As shown in
It should be understood that, the above solution merely provides an optional embodiment of the semi-transparent structure 300. In other embodiments of the present disclosure, the semi-transparent structure 300 may also be implemented in a different manner. For example, the semi-transparent structure 300 may be a one-piece light shielding plate having a light transmittance decreases gradually from the side near the completely transparent region 100 to the side near the completely nontransparent region 200.
In addition, in an embodiment provided by the present disclosure, optionally, a gap between two adjacent light shielding blocks 301 is of a pre-determined value so as to enable a light diffraction to occur between the two adjacent light shielding blocks 301. Optionally, the pre-determined gap has a width that is less than a resolution of an exposure machine used in a mask process.
In the above solution, the gap between two adjacent light shielding blocks 301 is less than the resolution of the exposure machine. Owing to a diffraction effect, the light shielding block 301 has a certain light transmittance therebelow, and the photoresists will not be developed completely, thus substantially forming three sections of slope (i.e., a complete developing section, a partial developing section and a complete non-developing section) at the boundary of the hollowed-out region of the resin layer 500. Moreover, the light transmittances of the gaps between light shielding blocks 301 gradually decreases from the side near the completely transparent region 100 to the side near the completely nontransparent region 200, so that the slope 501 for connection is gentle.
In addition, in an embodiment provided by the present disclosure, optionally, as shown in
In addition, in an embodiment provided by the present disclosure, optionally, the light shielding block 301 may be a rectangular block which is completely nontransparent. Optionally, the light shielding block 301 and the completely nontransparent region 200 of the mask plate are made of a same material, and integrally connected with each other. By adopting the above solution, the manufacturing process of the mask plate is simple.
It should be understood that, in other embodiments of the present disclosure, other structures may also be adopted in the light shielding block 301, which shall not be limited herein.
In addition, it should be noted that, the hollowed-out region on the resin layer 500 on the display substrate usually is defined by the completely transparent region 100 on the mask plate, and the non-hollowed-out region on the resin layer 500 usually is defined by the completely nontransparent region 200 on the mask plate, and a metal layer is formed in a first boundary region of the non-hollowed-out region at a boundary between the non-hollowed-out region and the hollowed-out region of the resin layer 500.
In an embodiment provided by the present disclosure, optionally, the boundary between the completely transparent region 100 and the completely nontransparent region 200 of the mask plate is provided with a plurality of boundary lines, and the plurality of boundary lines includes at least a first boundary line corresponding to the first boundary, and the semi-transparent structure 300 is only arranged at a location corresponding to the first boundary line.
That is, the mask plate provided by the embodiment may provide the semi-transparent structure 300 only arranged at a location corresponding to a side of the resin layer 500 where the metal traces need to be formed subsequently, while other boundary lines at the boundary between the completely transparent regions 100 and the completely nontransparent region 200 may not be provided with the semi-transparent structure 300.
In addition, in an embodiment provided by the present disclosure, optionally, the completely transparent region 100 includes at least two completely transparent sub-regions, and each boundary of the completely transparent sub-region and the completely nontransparent region 200 is provided with the semi-transparent structure 300.
Optionally, as shown in
By adopting the above solution, each light shielding block 301 may be adaptively adjusted. The light shielding blocks 301 arranged at the completely transparent sub-regions 100 with different areas may have the same size or may have different sizes. Optionally, the area of the first completely transparent sub-region 101 is greater than that of the second completely transparent sub-region 102, and a size of the first light shielding block 311 is equal to or greater than that of the second light shielding block 312.
The above are merely the optional embodiments of the present disclosure. It should be noted that, a person skilled in the art may make improvements and modifications without departing from the principle of the present disclosure, and these improvements and modifications shall also fall within the scope of the present disclosure.
Number | Date | Country | Kind |
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201620514549.7 | May 2016 | CN | national |
Filing Document | Filing Date | Country | Kind |
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PCT/CN2017/077812 | 3/23/2017 | WO | 00 |