Optimized SMA Dampers in Vibration Control of Jacket-type Offshore Structures (Regular Waves)

Authors

1 Department of Civil Engineering, University of Sistan & Baluchestan

2 School of Civil Engineering, Iran University of Science & Technology

Abstract

Undesired oscillations of jacket platform may influence the structural functionality and sometimes fatigue occurs. The main objective of this research is to control wave-induced vibrations of fixed jacket platforms with the use of optimized shape memory alloys dampers. To model the hysteretic behavior of SMA elements and performing dynamic analysis an efficient isothermal idealized constitutive model is developed in this research and direct integration time history analysis is carried out. Dynamic responses of multi-degree of freedom system of jacket platform, with 90 m height and equipped with SMA dampers, is estimated and compared with the bare jacket. Furthermore, an optimization algorithm such as Ideal Gas Molecules Movements (IGMM) is implemented in this research to improve the efficiency of the dampers and minimize the deck displacements under the action of extreme wave. The results show that the optimized SMA dampers can improve the structural response by decreasing 47.5 percent of deck displacement, 56.5 percent of deck acceleration and finally 28 percent of base shear. In an SMA damper-equipped platform, reduced wave intensity will reduce the damper efficiency.
 

Keywords

References

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International Journal Of Coastal, Offshore And Environmental Engineering(ijcoe)
Volume 4, Issue 4 - Serial Number 16
November 2019
Pages 25-35

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