▎ 摘　　要

NOVELTY - Composite infrared radiation heating material, comprises 30-40 pts. wt. high-molecular insulating polymer, 30-40 pts. wt. far-infrared nanoparticle-conductive composite polymer, 15-20 pts. wt. catalyst, 20-30 pts. wt. cetrimonium bromide (CATB) modified graphene oxide, 20-30 pts. wt. carbon nanofiber, 5-10 pts. wt. connecting material, 3-5 pts. wt. surface treatment agent and 3-5 pts. wt. curing agent. The heating material has a three-layer sandwich structure, which is divided into an upper layer, a middle layer and a lower layer. The upper layer and the lower layer are made of high molecular insulating polymer. The middle layer is made of far-infrared nanoparticle-conductive composite polymer, CATB modified graphene oxide and carbon nanofiber. USE - Used as composite infrared radiation heating material. ADVANTAGE - The heating material guarantees the insulation performance of heating materials, far-infrared nanoparticles have the effect of human health care, promotes the current response mechanism of the conductive composite polymer, assists the far-infrared nanoparticles to further act under the current, and avoids the waste of electrical energy. DETAILED DESCRIPTION - An INDEPENDENT CLAIM is also included for preparing the composite polymer, comprising (a) dissolving one-half of the weight component of the high-molecular insulating polymer in distilled water, stirring evenly and forming a semi-gel at 30-40 degrees C to obtain the upper pre-combined body of the heating material, (b) dissolving the far-infrared nanoparticle-conductive composite polymer of the weight component, CATB modified graphene oxide and the catalyst in distilled water at 35-45 degrees C, stirring evenly at 300-500 revolutions/minute for 10 minutes, adding the carbon nanofibers while stirring, and continuously stirring for 20-30 minutes, adding the curing agent, and allowing to stand at 25-27 degrees C for 20 minutes to obtain the intermediate layer of the heat-generating hybrid material, (c) dissolving the remaining half of the high-molecular insulating polymer of the weight component in distilled water, stirring evenly, and forming a semi-gel at 30-40 degrees C to obtain the lower pre-bonded layer of the heating material body, (d) combining the upper pre-combined body obtained in step (a), and coating the intermediate layer pre-bonded body and the lower-layer pre-bonded body obtained in the step (c) uniformly with the binder of the weight component in sequence, and stacking in sequence, melting and bonding at 70-80 degrees C under nitrogen conditions, (e) applying the surface treatment agent of the weight component uniformly on the surface of the fusion bonded body obtained in the step (d), and drying under vacuum conditions for 30 minutes to 1 hour to obtain final product.