The need of renewable energy sources is growing. Wind energy is the important sources of renewable energy. In the wind energy sector Horizontal axis wind turbines are the major devices used for the production of electricity. Blade is the most important part of HAWT. Blade material is the most important factor in the performance of HAWT. The major structural properties are influenced in a wind turbine blade are Rigidity, fatigue and flexibility of materials and optimum aerodynamic shape. The main objective of this work is to optimize the blade material properties by finite element analysis with the structural factors in the risk area. The factors such as dynamic and elastic center of blades, positioning of center of gravity has been considered for the structural analysis. In this research the blade structure is consisted with 8, 10, 12, 14 layers of the fiber glass fabric and epoxy resin as matrix of composite reinforced polymer. In this research the fiber glass fabric and epoxy resin as matrix of composite reinforced polymer are consisted with 8, 10, 12, 14 layers. The maximum values of normal and tangential stress are considered for the static analysis. It was originated that when the risk area carries more number of layers and decreased the blade tip leads to increase resistance to static and dynamic loads. The aim of this study is to apply the finite element method on the wind turbine blade and enlightening the structure and reducing their cost of production.