Method for the preparation of biofilm carrier with biochar fixed by thermoplastic resin

We claim: 1. A method for the preparation of biofilm carrier with biochar fixed by thermoplastic resin, comprising: (1) biochar functional material is ground to powder and dried to a constant weight at ≤80° C.; surface of the biochar functional material comprises oxygen-containing functional groups having a function of redox mediator; (2) biochar functional material powder, which is pretreated according to step (1), is blended into thermoplastic resin particles and stirred evenly; a mass percentage of the biochar functional material powder to the thermoplastic resin particles is 20%-50%; (3) a solid mixture obtained from step (2) is melt extruded into strips by a screw extruder and mechanically cut to obtain a granular blend; a processing temperature of each section of the screw extruder is 130-190° C. to ensure that the thermoplastic resin particles are fully mixed with the biochar functional material powder in a molten state; (4) a granular blend prepared in step (3) and the thermoplastic resin particles are mechanically stirred evenly, and then added to the screw extruder for co-mixing and extrusion, carrier pipes of different shapes are obtained, according to a design of a mould; a ratio of a mass of the biochar functional material powder to a total mass of the thermoplastic resin particles in granular blends is less than 20%; (5) the carrier pipes prepared in step (4) are cut mechanically and biological carriers are obtained according to a required size, the biological carriers are used in a biological treatment of sewage, wherein the biochar functional material is grass biochar, straw biochar, rice husk biochar, nut shell biochar, sludge biomass biochar, animal excrement biochar, or a combination thereof, wherein the thermoplastic resin particles are extruded grade polyethylene particles or extruded grade polypropylene particles. 2. The method for the preparation of biofilm carrier according to claim 1 , wherein the screw extruder is heated in four sections, and a temperature range and effects of each section heating are as follows: (1) the temperature is 120-140° C., and the thermoplastic resin reaches a semi-molten state, which is conducive to a continuity of solid transport; (2) the temperature is 130-160° C., which accelerates a transformation of the thermoplastic resin from the semi-molten state to the molten state, and is conducive to a homogeneous mixing of blends in a heating section; (3) the temperature is 140-170° C., which makes the blends in a solid-liquid mixing state, so that the thermoplastic resin in the molten state and the biochar functional material are fully mixed, which is conducive to a uniform distribution of the biochar functional material and the thermoplastic resin in the molten state; (4) the temperature is 115-145° C. to ensure a quantitative and constant pressure outflow of the blends, and to ensure stability and continuity of extrusion and subsequent smooth shaping. 3. The method for the preparation of biofilm carrier according to claim 1 , wherein the screw extruder is heated in four sections, and a temperature range and effects of each section heating are as follows: (1) the temperature is 120-140° C., and the thermoplastic resin reaches a semi-molten state, which is conducive to a continuity of solid transport; (2) the temperature is 130-160° C., which accelerates a transformation of the thermoplastic resin from the semi-molten state to the molten state, and is conducive to a homogeneous mixing of blends in a heating section; (3) the temperature is 140-170° C., which makes the blends in a solid-liquid mixing state, so that the thermoplastic resin in the molten state and the biochar functional material are fully mixed, which is conducive to a uniform distribution of the biochar functional material and the thermoplastic resin in the molten state; (4) the temperature is 115-145° C. to ensure a quantitative and constant pressure outflow of the blends, and to ensure stability and continuity of extrusion and subsequent smooth shaping.