A flux switching electromagnetic wave energy harvester with a novel speed amplified mechanism has been proposed and simulated. The novelty of the design is the relative speed of the translator with respect to the stator being doubled through a fixed pulley wheel mechanism. The output power was simulated by the ANSYS Maxwell module from input design parameters. The relationship between the input design parameters and target peak power output has been established through the simulation to understand the science. The sensitivity of the design parameters and their interactions has been studied through the Taguchi method (Design of Experiment) and response surface methodology (RSM). The design parameters of the stator and arrangement of the magnet configuration have been optimized for the maximum peak output power. The RSM model has been validated by the analysis of the variance method. The optimal results of the RSM model have been verified by the ANSYS simulation results. The RSM is proven to be a useful tool for design and optimization of the linear generator take-off unit. The cogging force has also been minimized by optimizing the dimensions of the feet on the stators using the RSM. The analysis and simulation methods have contributed to new knowledge of the flux switching electromagnetic wave energy harvester.

提出并仿真了一种具有新型速度放大机制的磁通切换电磁波能量收集器。该设计的新颖之处在于通过固定滑轮机构使平移器相对于定子的相对速度加倍。ANSYS Maxwell 模块根据输入设计参数模拟输出功率。输入设计参数和目标峰值功率输出之间的关系已经通过模拟建立起来，以了解科学。已经通过田口方法（实验设计）和响应面方法（RSM）研究了设计参数的敏感性及其相互作用。定子的设计参数和磁铁配置的布置已经针对最大峰值输出功率进行了优化。RSM 模型已通过方差分析法得到验证。ANSYS仿真结果验证了RSM模型的优化结果。RSM 被证明是设计和优化线性发电机输出装置的有用工具。通过使用 RSM 优化定子上支脚的尺寸，齿槽力也被最小化。分析和仿真方法为磁通开关电磁波能量收集器的新知识做出了贡献。