Ocean Systems Engineering

  • 제2권3호
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  • Pages.217-228
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  • 2012
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  • 2093-6702(pISSN)
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  • 2093-677X(eISSN)
테크노프레스 (Techno-Press)
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DOI QR코드

DOI QR Code

Hydrodynamic interactions and coupled dynamics between a container ship and multiple mobile harbors

  • Kang, H.Y. (Ocean Engineering Program, Department of Civil Engineering, Texas A&M University) ;
  • Kim, M.H. (Ocean Engineering Program, Department of Civil Engineering, Texas A&M University)
  • 투고 : 2012.06.30
  • 심사 : 2012.09.05
  • 발행 : 2012.09.25
⟨ 이전 논문 다음 논문 ⟩

초록

As the size of container ships continues to increase, not many existing harbors can host the super-container ship due to its increased draft and the corresponding dredging requires huge budget. In addition, the minimization of waiting and loading/offloading time is the most important factor in harbor competitiveness. In this regard, mobile-harbor concept has been developed in Korea to achieve much improved harbor capacity and efficiency. In developing the concept, one of the most important elements is the operability of crane between two or more floating bodies in side-by-side arrangement. The container ship is to be stationed through a hawser connection to an outside-harbor fixed-pile station with the depth allowing its large draft. The mobile harbors with smart cranes are berthed to the sides of its hull for loading/offloading containers and transportation. For successful operation, the relative motions between the two or more floating bodies with hawser/fender connections have to be within allowable range. Therefore, the reliable prediction of the relative motions of the multiple floating bodies with realistic mooring system is essential to find the best hull particulars, hawser/mooring/fender arrangement, and crane/docking-station design. Time-domain multi-hull-mooring coupled dynamic analysis program is used to assess the hydrodynamic interactions among the multiple floating bodies and the global performance of the system. Both collinear and non-collinear wind-wave-current environments are applied to the system. It is found that the non-collinear case can equally be functional in dynamics view compared to the collinear case but undesirable phenomena associated with vessel responses and hawser tensions can also happen at certain conditions, so more care needs to be taken.

키워드

참고문헌

  1. Buchner, B., Dijk, A. and Wilde, J. (2001), "Numerical multiple-body simulations of side-by-side mooring to an FPSO", Proceedings of the 11th International Offshore and Polar Engineering Conference, Stavanger, Norway.
  2. Buchner, B., Gerrit, B. and Jaap, W. (2004), "The interaction effects of mooring in close proximity of other structures", Proceedings of the 14th ISOPE Conference, Toulon, France.
  3. Choi, Y.R. and Hong, S.Y. (2002), "An analysis of hydrodynamic interaction of floating multi-body using higherorder boundary element method", Proceedings of the 12th International Offshore and Polar Engineering Conference, Kitakyushu, Japan.
  4. Gourlay, T. and Klara, K. (2007), "Full-scale measurements of containership sinkage, trim and roll", Austrailian Naval Architect., 11(2), 30-36
  5. Kang, H.Y., Kim, M.H., Kim, J.H., Park, W.S. and Chae, J.W. (2010), "Offloading from both sides of a supercontainer ship to land and floating harbor: Predicted vs Experimental results", Proceedings of the 2010 International Offshore and Polar Engineering Conference, China
  6. Kim, M.H., Koo, B.J., Mercier, R.M. and Ward, E.G. (2005), "Vessel/mooring/riser coupled dynamic analysis of a turret-moored FPSO compared with OTRC experiment", Ocean Eng., 32(14-15), 1780-1802. https://doi.org/10.1016/j.oceaneng.2004.12.013
  7. Kim, M.H., Ran, Z. and Zheng, W. (2001), "Hull/mooring coupled dynamic analysis of a truss spar in time domain", Int. J. Offshore Polar., 11(1), 42-54.
  8. Koo, B.J. and Kim, M.H. (2005), "Hydrodynamic interactions and relative motions of two floating platforms with mooring lines in side-by-side offloading operation", Appl. Ocean Res., 27(6), 295-310.
  9. Lee, D.H. and Kim, M.H. (2004), "Two body resonant interactions by fully coupled method and partially coupled method", Proceedings of the ASCE Civil Engineering in the Ocean Conf., Baltimore, Oct.
  10. Lee, C.H., Newman, J.N., Kim, M.H. and Yue, D.K.P. (1991), "The computation of second-order wave loads", Proceedings of the 10th OMAE, Stavanger, Norway.
  11. Ma, S., Kim, M.H. and Shi, S. (2009), "Second-order low-frequency wave forces on a SPM offloading tanker in shallow water", J. Offshore Mech. Arct., 131(4).
  12. Ran, Z. (2000), Coupled dynamic analysis of floating structures in waves and currents, Ph.D. Dissertation, Texas A&M University, College Station, TX.
  13. Tahar, A. and Kim, M.H. (2003), "Hull/mooring/riser coupled dynamic analysis and sensitivity study of a tankerbased FPSO", Appl. Ocean Res., 25(6), 367-382. https://doi.org/10.1016/j.apor.2003.02.001

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