Traditional carbon fiber polymer composite materials are merely single structural materials, serving only to bear loads in aircraft structures and wind turbine blade constructions. However, the requirements for materials within components are complex; they not only need to withstand loads but may also require flame retardancy, anti-static discharge properties, or resistance to higher temperatures. Often, the production of composites necessitates fulfilling structural performance while additionally incorporating these functions through structure. This approach not only wastes material but is more importantly, the addition of other structures can increase manufacturing costs and complexity. Therefore, the functionalization of structural materials holds significant economic and social value. The three industrializable structural-functional integrated composite materials developed in this project—'Anti-Static Discharge Carbon Fiber Polymer Composite Material,' 'Flame Retardant Carbon Fiber Polymer Composite Material,' and 'High Heat Resistance Carbon Fiber Polymer Composite Material'— The aforementioned difficulties can be effectively resolved by integrating the structural and functional design of composite materials, allowing structure and function to be realized together within the same material. This results in a situation where structure promotes function and function enhances structure, achieving an integrated structure-function approach that maximizes the effective utilization of raw materials. The project will develop preparation technologies for multifunctional nanomodifiers and structurally functionalized carbon fiber/epoxy resin composites as well as carbon fiber/bismaleimide composites, providing three standards for the preparation processes of structurally functionalized composite materials for development and utilization in fields such as aerospace, new energy, and modern transportation.