The corrosion behavior of 16Mn steel knee plates under marine salt-spray conditions was investigated using a coupled experimental and finite-element modeling approach. Controlled salt-fog exposures varying humidity, chloride concentration and applied tensile stress were performed and analyzed by a Box–Behnken design to quantify main and interaction effects. Electrochemical measurements yielded corrosion current densities that were used to develop a quadratic prediction model via response surface methodology. Finite-element simulations implemented in COMSOL Multiphysics reproduced local stress concentrations and electrochemical fields, and identified right-angled corners and curved edges as zones of localized severe attack. Statistical analysis indicates that ambient humidity is the dominant factor influencing corrosion rate, with a significant humidity–stress interaction. The regression model achieved R² = 0.9841, demonstrating strong agreement with experiments. These results clarify the coupling mechanism between environmental and mechanical factors and provide a practical predictive tool for optimizing material selection, geometric design, and maintenance prioritization for offshore structural components.
Ling et al. (Thu,) studied this question.