Yang, YifengMi, ChenhaoOu, BinjianWong, AnsonDuffy, John GordonWood, TimUtama, IKAPChen, WenchuangHuang, Luofeng2024-11-142024-11-142024-12Yang Y, Mi C, Ou B, et al., (2024) A comparative experimental study on the hydrodynamic performance of two floating solar structures with a breakwater in waves. Solar Energy, Volume 284, Decemebr 2024, Article number 1130290038-092Xhttps://doi.org/10.1016/j.solener.2024.113029https://dspace.lib.cranfield.ac.uk/handle/1826/23148Floating Photovoltaic (FPV) is considered as a highly promising clean energy solution. In recent years, FPV has been widely deployed in calm water around the world. However, to find available space for further expansion, FPV needs to be deployed in seas whilst the oceanic waves significantly influence the structural stability and energy performance. On one hand, wave loads may cause structural fatigue and damage. On the other hand, wave-induced rotations of a floating solar panel will vary its tilt angle to the sunlight and thus affect the power output. To explore the new research field of ocean-based FPV, this work first designed a novel catamaran FPV floater with a four-point mooring system. Comparative experiments were then conducted in a wave tank to compare its seakeeping ability with a conventional flat-plate floater. Besides, a breakwater structure was further introduced to enhance the stability of these two types of floaters. Detailed data on floater motions and mooring line forces were collected under monochromatic wave conditions. Extensive analysis was performed to evaluate the wave-mitigating performance of the breakwater, as well as the nonlinearity in the motion and force time histories. Overall, the work provides valuable experimental data and novel insights into the design of FPV floaters and breakwater protection, supporting long-term sustainability of FPV on the ocean.enAttribution 4.0 Internationalhttp://creativecommons.org/licenses/by/4.0/Energy33 Built environment and design40 EngineeringFloating solarBreakwaterHydrodynamic performance experimentsWave loadWave-induced motionArticle555813113029284