Wind turbine blades are long, thin, composite structures and therefore will have bending deflection in the flapwise direction as well as foil-section twist during rotational motion. The twist phenomenon accompanies the change of flow filed around blades and then leads to the change of loading condition on blades. The blade design without considering the aerodynamic and aeroelastic effect makes a wind turbine could not performance the best power generation efficiency. Otherwise, blades are usually built by the vacuum assisted resin transfer molding method. The successful manufacture depends on the proper infusion strategy and well realization of permeated characteristics of various laminates. Large-scale blades make the complicated permeated behavior of laminates and increase the infusion difficulty. First, the study confirmed the relationship between fiber orientation angle and structural response by the bend-twist experiments of small wind turbine blades. Then the calculating procedure of fluid-structure interaction with considering the aerodynamic effect was established by calculating attack angles of a blade (BEM), pressure distribution on the foil sections (2D flow field analysis), and structural analyses (FEM). The fluid-structure coupling effect was specifically discussed by calculating the power efficiency of a wind turbine. The adjustment of fiber orientation angle in the blade laminates was also utilized to improve the operating efficiency of wind turbines. The mold-flow manufacturing analyses focused on discussing the permeating characteristics of composite laminates under the VARTM process. The operation of 3D model composed of 1D pipe elements and laminates simulated the groove-flowing behavior of sandwich laminates and then substituted for complicated infusion experiments. The idea of equivalent thickness contributed to derive the permeability of sandwich laminates. The permeability predictive equations that were derived on the basis of the infusion experiments produced permeability of various laminates conveniently and were beneficial for the numerical analyses of large structures manufactures under the VARTM process.