COATING APPARATUS FOR COLOR FILTER SUBSTRATE AND COATING METHOD THEREOF

A coating apparatus for a color filter substrate, including a coating sprayer (1) configured to coat a first film layer on a color filter layer (03) formed on the color filter substrate (01); a grinding device (2) configured to grind the color filter layer (03) to eliminate a step formed by the color filter layer (03) covering a black matrix (02); and a detection control unit (3) configured to measure a height of the step, determine a grinding amount of the grinding device (2) according to the height of the step, and control an operation of the grinding device (2) such that the first film layer coated on the color filter layer (03) has a flat surface. Also disclosed is a coating method for a color filter substrate.

TECHNICAL FIELD

Embodiments of the present disclosure relate to a coating apparatus for a color filter substrate and a coating method thereof.

BACKGROUND

A liquid crystal display is a panel display device consisting of a color filter substrate, an array substrate, as well as a liquid crystal layer and a Polyimide (PI) alignment layer packaged between the color filter substrate and the array substrate, in which the PI layer is usually sprayed onto a surface of the color filter substrate by using an inkjet device to allow liquid crystal molecules of the liquid crystal layer between the color filter substrate and the array substrate to be arranged according to a certain rule; the spraying process for the PI layer has higher demand on a flatness of the color filter substrate, and if the flatness of the color filter substrate is poor, it's likely to result in non-uniform coating and dispersion, and finally influences a display quality of the display device.

A sectional view of the color filter substrate in the prior art is illustrated inFIG. 1. Referring toFIG. 1, the color filter substrate includes a substrate01, a black matrix02, a color filter layer03, a planarization layer04and a columnar spacer05, in which the black matrix02includes plural black matrix units alternately disposed on a substrate01at certain intervals, a spacing region is formed between two adjacent black matrixes, the color filter layer03is disposed in the spacing region and extending to the black matrix units on both sides to be overlapped with the black matrix units, so as to effectively avoid light leakage at an edge of a sub-pixel; at this point, since the color filter layer03and the black matrix units overlap with each other, a top height of the color filter layer03in an overlapping region is increased to form a step of the color filter layer03, which affects the flatness of the color filter substrate after the planarization layer04is sprayed, and thus affects the display quality of the display device.

SUMMARY

Embodiments of the present disclosure provide a coating apparatus for a color filter substrate and a coating method thereof, which can grind off a step of a color filter layer, reduces a coating thickness and saves a coating cost.

At least one embodiment of the present disclosure provides a coating apparatus for a color filter substrate, including a coating sprayer configured to coat a first film layer on a color filter layer of the color filter substrate; a grinding device configured to grind the color filter layer to eliminate a step formed by the color filter layer covering a black matrix; and a detection control unit configured to measure a height of the step, determine a grinding amount of the grinding device according to the height of the step, and control an operation of the grinding device such that the first film layer coated on the color filter layer has a flat surface.

In the coating apparatus for a color filter substrate according to the embodiments of the present disclosure, the detection control unit can measure the height of the step formed by the color filter layer covering the black matrix, and can further determine the grinding amount of the grinding device according to the height of the step, which allows the first film layer coated on the color filter layer having a flat surface. In this way, by determining the grinding amount of the grinding device, controlling the operation of the grinding device according to the grinding amount to eliminate the step of the color filter layer, and then coating a first film layer on the color filter layer of the color filter substrate by using a coating sprayer, the flatness of the color filter substrate is improved.

Compared with the prior art, by adopting the coating apparatus for a color filter substrate according to the embodiments of the present disclosure to coat the first film layer, the step of the color filter layer can be removed, the flatness of the color filter substrate can be improved, a height of the color filter layer can be reduced by removing the step of the color filter layer, and a coating thickness of the first film layer is reduced, thus saving a consumption amount of the material and also the cost for coating.

At least one embodiment of the present disclosure further provides a coating method for a color filter substrate, including: measuring, by a detection control unit, a height of a step formed by a color filter layer formed on the color filter substrate covering a black matrix to obtain the height of the step, determining a grinding amount for the color filter layer according to the height of the step, and grinding the color filter layer at the grinding amount; and coating a first film layer on the color filter layer upon grinding.

DETAILED DESCRIPTION

In order to make one skilled person in the art better understand the technical solutions of the present disclosure, hereafter, a color filter substrate, display panel and display device of the present disclosure will be further described in detail with reference to the accompanying drawings and embodiments.

Referring toFIG. 2, which is a schematically structural diagram of a coating apparatus for a color filter substrate according to an embodiment of the present disclosure. The coating apparatus for a color filter substrate includes: a coating sprayer1configured to coat a first film layer on a color filter layer03of a color filter substrate01; a grinding device2configured to grind the color filter layer03to eliminate the step formed by the color filter layer03covering a black matrix02; and a detection control unit3capable of controlling an operation of the grinding device2, measuring a height of the step, and determining a grinding amount of the grinding device2according to the height of the step to allow the first film layer coated on the color filter layer03having a flat surface.

In the coating apparatus for a color filter substrate according to an embodiment of the present disclosure, the detection control unit3can measure the height of the step of the color filter layer03and can further determine the grinding amount of the grinding device according to the height of the step; in this way, the grinding amount of the grinding device2can be determined through the detection control unit3, the operation of the grinding device2can be controlled according to the grinding amount to remove the step of the color filter layer03, and then the coating sprayer1can be utilized to coat the first film layer on the color filter layer of the color filter substrate01to improve the flatness of the color filter substrate01. By coating the first film layer using the above coating apparatus for a color filter substrate, as compared with the prior art, the step of the color filter layer03can be eliminated, the flatness of the color filter substrate can be improved, the height of the color filter layer03can be reduced due to the removal of the step of the color filter layer03, and the coating thickness of the first film layer is reduced, thus saving a consumption amount of the material for the first film layer and reducing a coating cost of the first film layer.

In the embodiment of the present disclosure, the first film layer can be a planarization layer or an alignment film layer, which is not limited herein.

In order to realize the detection on the height of the step of the color filter layer03and realize the control over the grinding device2. For example, as illustrated in FIG.2, the detection control unit3can include an optical measuring system31and a control unit32; the optical measuring system31can scan and photograph the color filter substrate to obtain an overall profile of the color filter layer03; the control unit31is connected to the grinding device2and the optical measuring system31respectively; the control unit32obtains an average value of steps of the color filter layer03according to the overall profile of the color filter layer03to realize the detection on the height of the step of the color filter layer03, determines the average value of the steps of the color filter layer03as a grinding amount of the grinding device2, and further controls the grinding device2to grind the color filter layer03according to the determined grinding amount. In this way, the grinding amount can be determined precisely, thereby avoiding the problem that the step cannot be ground off due to insufficient grinding amount or the color filter layer03is made too thin caused by excessive grinding amount.

In order to enable the grinding device2to grind off the step formed by the color filter layer03covering the black matrix, referring toFIG. 3, the grinding device2includes a grinding cloth21and a first transfer device22; the grinding cloth21, serving as a grinding tool, can eliminate part of the step when contacting the step and making a relative movement with the step; and the first transfer device22enables the relative movement between the grinding cloth21and the step of the color filter layer03, which movement is parallel with the color filter substrate.

In order to enable the relative movement between the grinding cloth21and the color filter substrate03in parallel with the color filter substrate so as to eliminate the step formed by the color filter layer03covering the black matrix, the grinding cloth21can be fixed while the color filter substrate is moved along a direction parallel with the grinding cloth21, or the color filter substrate can be fixed while the grinding cloth21is moved along a direction parallel with the color filter substrate. When the former is adopted, all the steps on the color filter substrate can be ground off only if the color filter substrate is moved quickly and significantly, which involves larger movement space, higher movement frequency, higher energy consumption and lower efficiency. In order to avoid this problem, in an embodiment of the present disclosure, the color filter substrate is fixed, and the step is ground off by moving the grinding cloth21along a direction parallel with the color filter substrate. For example, a soft grinding cloth21can be sleeved on a rotary shaft, and the rotary shaft is driven to rotate to drive the grinding cloth21to grind circularly, so that the step of the color filter layer03can be ground off by only moving the rotary shaft sleeved with the grinding cloth21towards the color filter substrate to be in contact with the step of the color filter substrate, which involves smaller movement space, lower movement frequency, decreased energy consumption, larger rotary speed of the rotary shaft and improved grinding efficiency of the grinding cloth21. In such case, the transfer device includes a first transfer device22, which can drive the grinding cloth21to move along a direction parallel with the color filter substrate.

In an embodiment of the present disclosure, in order to drive the grinding cloth21to move along a direction parallel with the color filter substrate, the first transfer device22can include a single transfer shaft, and an axis of the transfer shaft is parallel with the color filter substrate; the grinding cloth21is wound around and fixed on the transfer shaft, and the transfer shaft is connected to a rotary motor which can drive the transfer shaft to rotate around an axis thereof, such that the grinding cloth21is driven to rotate around the axis and hence move along a direction parallel with the color filter substrate.

In an embodiment of the present disclosure, in order to drive the grinding cloth21to move along a direction parallel with the color filter substrate, the first transfer device22includes at least two transfer shafts disposed in parallel, and a plane where the at least two transfer shafts are located is parallel with the color filter substrate; the grinding cloth21is connected end to end to form an annular structure, then the grinding cloth21with the annular structure is sleeved on the at least two transfer shafts and is tensioned by the transfer shafts; at least one of the transfer shafts is connected to a rotary motor which can drive the transfer shaft to rotate around an axis thereof such that the grinding cloth21is driven to rotate around the transfer shaft.

Compared with the first transfer device including a single transfer shaft, the first transfer device22including two transfer shafts disposed in parallel can increase a grinding area of the grinding cloth21, such that the grinding cloth21can grind all steps on the color filter substrate at the same time, and the grinding efficiency is improved to the greatest extent; moreover, with a plurality of transfer shafts, a tensile force of the grinding cloth21on the transfer shaft can be improved. Therefore, with the use of the first transfer shaft22including two transfer shafts disposed in parallel, it can improve the grinding efficiency and increase the tensile force. For example, as illustrated inFIG. 3, the first transfer device22includes two transfer shafts221disposed in parallel, and a plane where the two transfer shafts221are located is parallel with the color filter substrate01; the grinding cloth21is connected end to end to form an annular structure, then the grinding cloth21with the annular structure is sleeved on the two transfer shafts221and is tensioned by the transfer shafts221; one of the transfer shafts221is connected to a rotary motor222which can drive the transfer shaft22to rotate around an axis thereof, so as to drive the grinding cloth21to rotate around the transfer shaft221; a plane between the two transfer shafts221is an effective grinding surface; when the color filter substrate is placed on a bearing platform100and located right below the grinding surface, a grinding region of the grinding cloth21can completely cover the upper surface of the color filter substrate, such that the grinding efficiency is improved to the greatest extent.

In an embodiment of the present disclosure, the color filter substrate can be placed manually right below the grinding surface. In another embodiment of the present disclosure, the color filter substrate can be conveyed to be right below the grinding surface through a conveyor belt. When the color filter substrate is placed manually right below the grinding surface, the process of placing-onto and taking-down spends much time and involves lower efficiency. By placing a plurality of color filter substrates on the conveyor belt at intervals and conveying the color filter substrate to be right below the grinding surface through the conveyor belt, the transfer time is saved and the transfer efficiency is improved.

In order to realize feeding the grinding cloth, it's possible to cause the grinding cloth21to be contacted with the step of the color filter layer03for grinding. In an embodiment of the present disclosure, referring toFIG. 4, the grinding device2further includes a second transfer device23, the second transfer device23can drive both the grinding cloth21and the first transfer device22to move along a direction perpendicular to the color filter substrate; during grinding operation, the second transfer device23can drive the grinding cloth21and the first transfer device22to move towards the color filter substrate01to realize feeding of grinding cloth, such that the step of the color filter layer03is ground off; after the grinding operation is finished, in order to realize a spray-coating operation for the first film layer at a next step, both the grinding cloth21and the first transfer device22can be lifted to a certain height to reserve an enough space for the spray-coating operation.

In an embodiment of the present disclosure, the second transfer device23can include a guide rail231and a sliding support232, the guide rail231is disposed along a direction vertical to the substrate, the sliding support232is matched and connected with the guide rail231, and the sliding support232is connected to a driving component which can drive the sliding support232to slide along the slide rail; the grinding cloth21and the first transfer device22are disposed on the sliding support232, such that the driving component drives the grinding cloth21and the first transfer device22to slide along the slide rail, and hence driving the grinding cloth21and the first transfer device22slide along a direction perpendicular to the substrate.

The driving component can include a screw rod and a screw nut matched with each other, the screw rod is disposed in parallel with the guide rail231, and the screw nut is connected to the sliding support232; the screw rod is connected to a rotary motor, which can drive the screw rod to rotate around an axis thereof such that the screw nut on the screw rod is driven to move up and down, and which can further drive the sliding support232connected to the screw nut to move up and down to realize up-down movement of the sliding support232relative to the guide rail231.

The optical measuring system31is configured to measure profile characters of a surface of the color filter layer03; for example, the optical measuring system31can be a three-dimensional profilometer.

At least one embodiment of the present disclosure provides a coating method for a color filter substrate, including steps of: measuring, by a detection control unit3, a height of a step formed by a color filter layer03covering a black matrix to obtain the height of the step, and controlling the grinding device2to grind the color filter substrate03at a grinding amount according to the height of the step; and after the grinding device2finishes grinding, coating a first film layer on the color filter layer03of the substrate by operating a coating sprayer1.

In the coating method for a color filter substrate according to an embodiment of the present disclosure, the detection control unit3firstly measures a height of a step formed by a color filter layer03covering a black matrix to obtain the height of the step, determines a grinding amount of the grinding device2according to the height of the step, and then controls the grinding device2to grind the color filter layer03to eliminate the step of the color filter layer03, and finally controls and operates the coating sprayer1to coat a first film layer on a substrate01to finish the coating operation of the first film layer of the color filter substrate. Compared with the prior art, by adopting the coating apparatus for a color filter substrate according to the embodiments of the present disclosure to coat the first film layer on the substrate, the step of the color filter layer can be removed, the flatness of the color filter substrate can be improved, a height of the color filter layer can be reduced by removing the step of the color filter layer, and a coating thickness of the first film layer is reduced, thus saving a consumption amount of the material for the first film layer and reducing a cost for coating the first film layer.

In the embodiments above, measuring, by the detection control unit3, a height of step formed by a color filter layer03covering a black matrix to obtain the height of the step, includes: scanning and photographing, by an optical measuring system31, the color filter substrate to obtain an overall profile of the color filter layer03; and obtaining, by a control unit32, an average value of steps of the color filter layer03according to the overall profile of the color filter layer03so as to obtain a grinding amount for the step of the color filter layer03. Values of the steps at respective points on the color filter substrate03are not the same, thus in order to obtain a proper grinding amount, in an embodiment of the present disclosure, an average value of the steps at respective points on every color filter layer03is calculated to ensure that the grinding device2can grind off most of the steps of the color filter layer03.

The foregoing are merely specific embodiments of the invention, but not limitative to the protection scope of the present disclosure. Therefore, the protection scope of the invention should be defined by the accompanying claims.

The present disclosure claims the benefits of Chinese patent application No. 201510574035.0, which was filed on Sep. 10, 2015 and is fully incorporated herein by reference as part of this application.