Vibration control of jacket offshore platform through magnetorheological elastomer (MRE) based isolation system

Undesirable vibrations in offshore platforms due to ocean loadings may reduce platform productivity and increase the fatigue failure. This study proposes a magnetorheological elastomer (MRE) based isolation system to control the jacket platform oscillations and its effectiveness is numerically evaluated. The working principle and design method of MRE-based isolation system are proposed, and MRE materials with high magnetorheological effects are conceptually designed. Practical jacket offshore platforms are selected for case studies. Semi-active fuzzy controller (SFC) is utilized to achieve real-time non-resonance vibration control. The proposed fuzzy core is constructed conceptually by the dynamic analysis of object structure. Numerical results demonstrate that MRE isolation system with SFC significantly reduces the maximum, minimum and RMS of the deck displacement and acceleration under realistic irregular waves at different sea states. MRE system could also reduce the response spectrum peaks and present robustness under various deck's mass. The present study proves the feasibility of MRE isolation systems in the application of vibration control for marine structures.

Automated summary

This study proposes a magnetorheological elastomer (MRE) based isolation system for controlling offshore platform vibrations, and evaluates its effectiveness through numerical analysis. The use of a semi-active fuzzy controller enables real-time non-resonance vibration control, showing significant reduction in deck displacement and acceleration under realistic wave conditions. The study demonstrates the feasibility and robustness of MRE isolation systems in vibration control for marine structures.