This study is to investigate on the piezoelectric vibration energy harvesting system for rotational motion applications. Based on the characteristic of passive self-tuning, the resonance frequency of optimized piezoelectric resonator can track and match the driving frequency over a wide frequency range to perform broadband mechanism. Instead of our group’s research in piezoelectric energy harvester under translational motion, the piezoelectric cantilever beam is mounted radially on a rotating body in three ways, such as case A, B and C. The distributed parameter and Rayleigh-Ritz method are proposed to derive the ordinary differential equations in the first mode using Hamiltonian principle. This article also presents numerical simulation to comprehend the piezoelectric system behavior by using MATLAB SIMULINK. According to the simulation results, we find that the resonance frequency of energy harvester passively tunes due to centrifugal force, which are divided into two types. One is along the axial direction of beam, and the other is parallel to transverse direction. The centrifugal force along the axis leading to tensile stress effectively stiffens the composite beam. The results of softening characteristic attributed to compressive stress has been observed in inward rotation. On the other hand, the centrifugal force parallel to transverse direction existed in the prototype of transverse vibration perpendicular to the rotation axis, actually decreasing the resonance frequency. The simulation results also provide the guidelines for design of the piezoelectric energy harvester outwardly mounted on rotating body, which is utilized in the tire pressure monitoring system, and demonstrate significant improved bandwidth and sufficient power output. Further more, the model of inward rotation is successfully applied to lower the resonance frequency of piezoelectric beam to satisfy the environment with low operation frequency.