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Structural control of a steel jacket platform

  • Published : 1996.03.25

Abstract

This paper deals with the application of certain active and passive control mechanisms to control the dynamic response of a steel jacket platform due to wave-induced forces. The forces are estimated using the nonlinear Morison equation which provides nonlinear self-excited hydrodynamic forces. The influence of these forces on the response of a structure without and with vibration control mechanisms is demonstrated using a steel jacket platform as a simple example.

Keywords

References

  1. Abdel-Rohman, M. and Leipholz, H. H. (1978), "Structural control by pole assignment method", Journal of Engineering Mechanics, ASCE, 104, EM5, 115-1175.
  2. Chakrabarti, S. K. (1987), Hydrodynamics of Offshore Structures, Springer-Verlag, Berlin, Heidelberg.
  3. Gosh, D. and Meirovitch, L. (1985), "Optimal control of wave-induced vibrations in semisubmersible structures with flexible superstructures", Presented at AIAA Symposium 1-14.
  4. Gudmestad, O.T. and Connor, J.H. (1983), "Linearization methods and the influence of current on the nonlinear hydrodynamic drag force", Applied Ocean Research, 5(4), 184-194. https://doi.org/10.1016/0141-1187(83)90032-9
  5. Haritos, N. and Karadeniz (1993), "A frequency domain approach for modeling the dynamic response of offshore structures to hydrodynamic loading in the Morison regime", Proceedings of 3rd ISOPE, Singapore, 6-11 June 1993, 3, 613-620.
  6. Karunakaran, D. Leira, B.J. and Moan, T. (1993), "Reliability analysis of drag-dominated offshore structure", Proceedings of 3rd ISOPE, Singapore, 6-11 June, 4, 660-605.
  7. Kawano, K. (1993), "Active control effects on dynamic response of offshore structure", Proceedings of 3rd ISOPE, Singapore, 6-11 June, 3, 594-498.
  8. Leipholz, H.H. and Abdel-Rohman, M. (1986), Control of Structures, Martinus Nijhoff Publishers.
  9. Patel, M. H. (1989), Dynamics of Offshore Structures, Butterworth & Co. Publishers.
  10. Rajagopalan, K. (1993), "Reliability of offshore jackets using point estimation" Proceedings of 3rd ISOPE. Singapore, 6-11 June 4, 606-612.
  11. Reinhorn, A.M., Manolis, G.D., and Wen, V.Y. (1987), "Active control of inelastic structures", Journal of Engineering Mechanics, ASCE, EM3, 113, 315-333. https://doi.org/10.1061/(ASCE)0733-9399(1987)113:3(315)
  12. Reinhorn, A.M., Soong, T.T. and Manolis, G.D. (1986), "Disaster prevention of deep water offshore structures by means of active control", Proceedings of ASME 5th Int. OAME Conference, Tokyo, Japan, 1989, 39-44.

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