Method for manufacturing COA array substrate and COA array substrate

What is claimed is: 1. A method for manufacturing a COA array substrate, comprising following steps: step 1 , providing a TFT substrate, the TFT substrate comprising a base substrate, a TFT layer disposed on the base substrate, and a pixel electrode layer disposed on the TFT layer, wherein the pixel electrode layer comprises a plurality of red sub-pixel electrodes, green sub-pixel electrodes and blue sub-pixel electrodes disposed alternately; black matrixes formed in interval regions of the plurality of red, green, blue sub-pixel electrodes on the TFT layer; step 2 , providing a counter electrode, a first electrolyte, a second electrolyte, and a third electrolyte; the counter electrode comprising an insulating substrate, and a plurality of counter electrode units disposed on the insulating substrate, the plurality of counter electrode units disposed correspondingly to the plurality of red, green, blue sub-pixel electrodes on the TFT substrate; the first electrolyte being a weak acidic solution containing a mixture of red quantum dots and chitosan, the second electrolyte being a weak acidic solution containing a mixture of green quantum dots and chitosan, the third electrolyte being a weak acidic solution containing a mixture of scattering particles and chitosan; step 3 , immersing the counter electrode and the TFT substrate into the first electrolyte altogether, forming a connecting circuit by linking the red sub-pixel electrodes on the TFT substrate and counter electrode units corresponding to the red sub-pixel electrodes on the counter electrode with a first wire and a first power source, the TFT substrate being an anode, the counter electrode being a cathode; after being electrified, a pH value of the first electrolyte close to the red sub-pixel electrodes on the TFT substrate increasing, making chitosan in the first electrolyte deposit on the red sub-pixel electrodes, the red quantum dots accompanied the chitosan depositing on the red sub-pixel electrodes, forming a plurality of red filter layers on the plurality of red sub-pixel electrodes respectively; controlling time of electrochemical deposition, disconnecting from the first power source when thickness of the red filter layers accumulated to be a certain value, taking out and cleaning the TFT substrate and the counter electrode; step 4 , immersing the TFT substrate and the counter electrode into the second electrolyte altogether, forming a connecting circuit by linking the green sub-pixel electrodes on the TFT substrate and counter electrode units corresponding to the green sub-pixel electrodes on the counter electrode with a second wire and a second power source, the TFT substrate being an anode, the counter electrode being a cathode; after being electrified, a pH value of the second electrolyte close to the green sub-pixel electrodes on the TFT substrate increasing, making chitosan in the second electrolyte deposit on the green sub-pixel electrodes, the green quantum dots accompanied the chitosan depositing on the green sub-pixel electrodes, forming a plurality of green filter layers on the plurality of green sub-pixel electrodes respectively; controlling time of electrochemical deposition, disconnecting from the second power source when thickness of the green filter layers accumulated to be a certain value, taking out and cleaning the TFT substrate and the counter electrode; step 5 , immersing the TFT substrate and the counter electrode into the third electrolyte altogether, forming a connecting circuit by linking the blue sub-pixel electrodes on the TFT substrate and counter electrode units corresponding to the blue sub-pixel electrodes on the counter electrode with a third wire and a third power source, the TFT substrate being an anode, the counter electrode being a cathode; after being electrified, a pH value of the third electrolyte close to the blue sub-pixel electrodes on the TFT substrate increasing, making chitosan in the third electrolyte deposit on the blue sub-pixel electrodes, the blue quantum dots accompanied the chitosan depositing on the blue sub-pixel electrodes, forming a plurality of blue filter layers on the plurality of blue sub-pixel electrodes respectively; controlling time of electrochemical deposition, disconnecting from the third power source when thickness of the blue filter layers accumulated to be a certain value, taking out and cleaning the TFT substrate and the counter electrode; the step 3 , the step 4 , and the step 5 processed randomly; after the steps 3 - 5 , a quantum dot color filter film comprising a plurality of red filter layers, green filter layers, and blue filter layers formed on the pixel electrode layer to manufacture a COA array substrate. 2. The method for manufacturing a COA array substrate according to claim 1 , wherein mass fractions of the chitosan in the first electrolyte, the second electrolyte, and the third electrolyte are 0.001%˜10%; concentration of the red quantum dots in the first electrolyte and that of the green quantum dots in the second electrolyte are 10 −6 M˜1M; concentration of the scattering particles in the third electrolyte is 10 −6 M˜1M; pH values of the first electrolyte, the second electrolyte, and the third electrolyte are 2.0˜7.0. 3. The method for manufacturing a COA array substrate according to claim 2 , wherein a mass fraction of the chitosan in the first electrolyte, the second electrolyte and the third electrolyte is 1%; concentration of the red quantum dots in the first electrolyte and the green quantum dots in the second electrolyte is 0.5 mM; concentration of the scattering particles in the third electrolyte is 0.5 mM; a pH value of the first electrolyte, the second electrolyte, and the third electrolyte is 5.2. 4. The method for manufacturing a COA array substrate according to claim 1 , wherein particle sizes of the red quantum dots, the green quantum dots and the scattering particles are 2 nm˜10 nm. 5. The method for manufacturing a COA array substrate according to claim 1 , wherein the red quantum dots are InP quantum dots coated with ZnS; the green quantum dots are InAs quantum dots coated with ZnS; the scattering particles are white, blue or transparent particles. 6. The method for manufacturing a COA array substrate according to claim 1 , wherein in the steps 3 - 5 , voltages applied between the red, green, blue sub-pixel electrodes on the TFT substrate and the corresponding counter electrode units on the counter electrodes are 0.01V˜30V, time of electrifying is within a range from 0.01 s to 1 h. 7. The method for manufacturing a COA array substrate according to claim 6 , wherein in the steps 3 - 5 , a voltage applied between the red, green, blue sub-pixel electrodes on the TFT substrate and the corresponding counter electrode units on the counter electrodes is 2V, time of electrifying is 150 s. 8. The method for manufacturing a COA array substrate according to claim 1 , wherein a material of the counter electrode units is indium tin oxide, aluminum doped zinc oxide, nickel, stainless steel, silver, gold or platinum. 9. The method for manufacturing a COA array substrate according to claim 1 , wherein a material of the counter electrode units is gold or platinum. 10. A method for manufacturing a COA array substrate, comprising the following steps: step 1 , providing a TFT substrate, the TFT substrate comprising a base substrate, a TFT layer disposed on the base substrate, and a pixel electrode layer disposed on the TFT layer, wherein the pixel electrode layer comprises a plurality of red sub-pixel electrodes, green sub-pixel electrodes and blue sub-pixel electrodes disposed alternately; black matrixes formed in interval regions of the plurality of red, green, blue sub-pixel