Multi-level design optimization of cylindrical linear permanent magnet synchronous generator for wave energy conversion

This paper presents a multi-level optimization approach to optimize cylindrical permanent magnet linear synchronous generator (PMLSG) which is employed in a wave power take-off system. To improve the market competitiveness of wave energy compared to other renewable energy sources, power density, thrust ripple, and Total Harmonic Distortion (THD) of the Induced electromotive force (EMF) are chosen to be optimization objectives in the design process of the PMLSG. Firstly, the finite element analysis model of PMLSG is established based on the initial design theory of the permanent magnet linear machine, and the comprehensive sensitivity indicts are calculated based on the optimization objective, and the parameters are categorized into non-sensitivity, middle-sensitivity, and strong-sensitivity for the sensitivity to optimization objectives. Secondly, multi-level design optimization method is employed, and different optimization methods are used for different sensitive parameters. The non-sensitivity parameters keep the original design value, the middle-sensitive parameters are adopted the parametric analysis method, and strong-level sensitive parameters are optimized by NSGA-II. Then, a prototype was manufactured according to the optimization results. Finally, the accuracy of the PMLSG design is verified at constant speed. The wave parameters (wave height, frequency) are simulated by MTS100kN testing machine, and the experiment shows that the wave energy can be effectively converted into electric energy at random motion, and proved the correctness of the PMLSG design.