▎ 摘　　要

NOVELTY - Method for processing antistatic nylon fabric, involves (i) blending and granulating 50-60 pts. wt. nylon chips, 2-3 pts. wt. triallyl isocyanurate, and 8-12 pts. wt. functional nanoparticles in a twin-screw extruder to obtain a first masterbatch, (ii) mixing 6-11 pts. wt. graphene, 32-46 pts. wt. nylon chips, and 4-10 pts. wt. oily agent, and melt granulating to obtain a second master batch, (iii) melt spinning the first master batch and the second master batch to obtain a graphene nylon fiber, where the weight ratio of the first master batch and the second master batch is (3-4):1, (iv) soaking the bamboo pulp fiber in a soaking solution at 30-32℃ for 3-4 hours to obtain a modified bamboo pulp fiber, and (v) twisting the graphene nylon fiber and the modified bamboo pulp fiber to synthesize yarn, and warp-knitting the yarn to obtain the antistatic nylon fabric, where the functional nanoparticles comprise nano-indium oxide and nano-silica. USE - The method is used for processing anti-static nylon fabric in clothing for clothes adhered to body to make people feel uncomfortable, even when the human body contact static metal object, and human body is easy to receive electrostatic stimulation. ADVANTAGE - The method improves the antistatic durability of the anti-static fabric. The first master batch and the second master batch melt spinning graphite graphite chinlon fiber has antiistatic capability, graphite nylon fiber further has good toughness, nano indium oxide and nano-silicon dioxide in functional nano-particles in the secondary master batch in graphene, on one hand, it can effectively reduce the resistivity of the prepared graphene chinlon fibre, so that the ant-static performance of the fabric on the other hand, improving the wear resistance and continuity of the graphene chainlon fiber, and improving the antistatic performance. The graphene is not easy to happen fiber breaking and fiber stretching deformation in the using process and washing process. DETAILED DESCRIPTION - Method for processing antistatic nylon fabric, involves (i) blending and granulating 50-60 pts. wt. nylon chips, 2-3 pts. wt. triallyl isocyanurate, and 8-12 pts. wt. functional nanoparticles in a twin-screw extruder to obtain a first masterbatch, (ii) mixing 6-11 pts. wt. graphene, 32-46 pts. wt. nylon chips, and 4-10 pts. wt. oily agent, and melt granulating to obtain a second master batch, (iii) melt spinning the first master batch and the second master batch to obtain a graphene nylon fiber, where the weight ratio of the first master batch and the second master batch is (3-4):1, (iv) soaking the bamboo pulp fiber in a soaking solution at 30-32℃ for 3-4 hours to obtain a modified bamboo pulp fiber, and (v) twisting the graphene nylon fiber and the modified bamboo pulp fiber to synthesize yarn, and warp-knitting the yarn to obtain the antistatic nylon fabric, where the functional nanoparticles comprise nano-indium oxide and nano-silica, the mass ratio of nano-indium oxide and nano-silica is 1:(2-3), and the soaking solution is made up of 15-20 pts. wt. hydrogen-terminated silicone oil, 10-12 pts. wt. tridecanol polyoxyethylene ether, 10-16 pts. wt. bisallyl polyether, 3-5 pts. wt. bisallyl amine, 4-8 pts. wt. isopropanol and 1-2 pts. wt. chloroplatinic acid.