In recent years, there has been a trend towards the elongation and lightweight design of wind turbine blades. However, this may result in more intense vibrations, potentially causing flutter phenomena and exacerbating material fatigue issues, significantly impacting the reliability and lifespan of wind turbines. This study aims to establish a highly reliable one-dimensional thin-walled beam (TWB) model for the vibration analysis of laminate blades under wind loading, thereby improving the design and performance of wind turbines. Initially, this study employs a simple rectangular hollow thin-walled beam model. Utilizing the geometric properties of the model, the stress state of the beam could be simplified and the coupling motion of multi-degree of freedom could be considered. Through the Hamilton's principle, the equations of motion including bending, twist, and extension of the beam could be derived. The laminate material was selected to be unidirectional fiber-reinforced, possessing transverse isotropy, with an adjustable ply angle. A simplified case of a single-layer rectangular cantilever beam was then investigated and the equivalent mass and stiffness quantities for each degree of freedom was established. Subsequently, the extended Galerkin method was employed to solve for the mode shapes and corresponding natural frequencies along the axial direction under free vibration, followed by a series of verifications of the numerical results obtained. The results indicate that the natural stiffness quantities remain unaffected by the orientations of the ply angles. However, the coupling stiffness quantities, mode shapes, and natural frequencies are significantly influenced by the orientations of the ply angles. The ply angle orientations can also determine the occurrence of decoupling phenomena, causing multi-degree of freedom coupling modes to transform into natural modes. Additionally, the findings demonstrate that natural frequencies generally increase with the ply angle. The outcomes of this research are expected to provide a reliable foundation for vibration and flutter analysis of composite material blades. Future research may expand to consider more complex blade geometries and introduce wind-induced loading. Leveraging the low computational cost and high reliability of TWB, enhancing the feasibility of integration with large and complex turbulent wind field simulations will enable more accurate assessments of fatigue effects and performance of large-scale wind turbine blades.