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http://dx.doi.org/10.5574/JAROE.2017.3.2.083

Numerical Analysis of Added Resistances of a Large Container Ship in WavesNumerical Analysis of Added Resistances of a Large Container Ship in Waves  

Lee, Jae-Hoon (Department of Naval Architecture and Ocean Engineering, Seoul National University)
Kim, Beom-Soo (Department of Naval Architecture and Ocean Engineering, Seoul National University)
Kim, Yonghwan (Department of Naval Architecture and Ocean Engineering, Seoul National University)
Publication Information
Journal of Advanced Research in Ocean Engineering / v.3, no.2, 2017 , pp. 83-101 More about this Journal
Abstract
In this study, the added resistances of the large container ship in head and oblique seas are evaluated using a time-domain Rankine panel method. The mean forces and moments are computed by the near-field method, namely, the integration of the second-order pressure directly on the ship surface. Furthermore, a weakly nonlinear approach in which the nonlinear restoring and Froude-Krylov forces on the exact wetted surface of a ship are included in order to examine the effects of amplitudes of waves on ship motions and added resistances. The computation results for various advance speeds and heading angles are validated by comparing with the experimental data, and the validation shows reasonable consistency. Nevertheless, there exist discrepancies between the numerical and experimental results, especially for a shorter wave length, a higher advance speed, and stern quartering seas. Therefore, the accuracies of the linear and weakly nonlinear methods in the evaluation of the mean drift forces and moments are also discussed considering the characteristics of the hull such as the small incline angle of the non-wall-sided stern and the fine geometry around the high-nose bulbous bow.
Keywords
Large containership; Added resistance in waves; Rankine panel method; Weakly nonlinear approach;
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Times Cited By KSCI : 1  (Citation Analysis)
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1 Pinkster, J., 1979. Mean and low frequency wave drifting forces on floating structures. Ocean Engineering, 6, 593-615.   DOI
2 Sadat-Hosseini, H., Wu, P., Carrica, P.M., Kim, H., Toda, Y., and Stern, F., 2013. CFD verification and validation of added resistance and motions of KVLCC2 with fixed and free surge in short and long head waves. Ocean Engineering, 59, 240-273.   DOI
3 Salvesen, N., 1978. Added resistance of ships in waves. Journal of Hydronautics, 12 (1), 24-34.   DOI
4 Seo, M.G., Park, D.M., Yang, K.K., and Kim, Y., 2013. Comparative study on computation of ship added resistance in waves. Ocean Engineering, 73, 1-15.   DOI
5 Seo, M.G., Yang, K.K., Park, D.M., and Kim, Y., 2014. Numerical analysis of added resistance on ships in short waves. Ocean Engineering, 87, 97-110.   DOI
6 Sprenger, F., Maron, A., Delefortrie, G., Hochbaum, A.C., and Fathi D., 2015. Mid-term review of tank test results. SHOPERA project deliverable D3.2.
7 Yang, K.K., Kim, Y., and Nam, B.W., 2015. Cartesian-Grid-Based Computational Analysis for Added Resistance in Waves. Journal of Marine Science and Technology, 20 (1), 155-170.   DOI
8 Zhang, S., Weems, K.M., and Lin, W.M., 2009. Investigation of the Horizontal Drifting Effects on Ships with Forward Speed. In: Proceedings of the ASME 2009 28th International Conference on Ocean, Offshore, and Artic Engineering, Honolulu, Hawaii, USA.
9 Newman, J.N., 1967. The drift force and moment on ships in waves. Journal of Ship Research, 11, 51-60.
10 Bunnik, T., 1999. Seakeeping Calculations for Ships, Taking into Account the Nonlinear Steady Waves. Ph.D. Thesis. Delft University of Technology, Netherlands.
11 Faltinsen, O.M., Minsaas, K.J., Liapis, N., and Skjordal, S.O., 1980. Prediction of resistance and propulsion of a ship in a seaway. In: Proceedings of the 13th Symposium on Naval Hydrodynamics, Tokyo, Japan, 505-529.
12 Fujii, H., and Takahashi, T., 1975. Experimental study on the resistance increase of a ship in regular oblique waves. In: Proceedings of the 14th ITTC, Ottawa, Canada, 351-360.
13 Grue, J., and Biberg, D., 1993. Wave forces on marine structures with small speed in water of restricted depth. Applied Ocean Research, 15, 121-135.   DOI
14 Guo, B.J., Steen, S., and Deng, G.B., 2012. Seakeeping prediction of KVLCC2 in head waves with RANS. Applied Ocean Research, 35, 56-67   DOI
15 Hermans, A. J., 2005. Added Resistance by Means of Time Domain Models in Seakeeping. Journal of Ship Research, 49 (4), 252-262.
16 Jensen, J.J., Beck, R.F., Du, S., Faltinsen, O.M., Fonseca, N., Rizzuto, E., Stredulinsky, D., and Watanabe, I., 2000. Extreme hull girder loading. In: Proceedings of the 14th International Ship and Offshore Structures Congress, Elsevier Science, New York, USA, 2, 263-320.
17 Joncquez, S.A.G., 2009. Second-Order Forces and Moments Acting on Ships in Waves. Ph.D. thesis. Technical University of Denmark, Copenhagen, Denmark.
18 Kashiwagi, M., 1992. Added resistance, wave-induced steady sway force and yaw moment on an advancing ship. Ship Technology Research, (Schiffstechnik) 39, 3-16.
19 Kim, K.H., and Kim, Y., 2011. Numerical study on added resistance of ships by using a time-domain Rankine panel method. Ocean Engineering, 38, 1357-1367.   DOI
20 Kim, Y., Kim, K.H., Kim, J.H., Kim, T.Y., Seo, M.G., and Kim, Y., 2011. Time-domain Analysis of Nonlinear Motion Responses and Structural Loads on Ships and Offshore Structures: Development of WISH Programs. International Journal of Naval Architecture and Ocean Engineering, 3 (1), 37-52.   DOI
21 Kuroda, M., Tsujimoto, M., and Fujiwara, T., 2008. Investigation on components of added resistance in short waves. Journal of the Japan Society of Naval Architects and Ocean Engineers, 8, 171-176.   DOI
22 Ley, J., Sigmund, S., and el Moctar, O., 2014. Numerical prediction of the added resistance of ships in waves. In: Proceedings of the ASME 2014 33rd International Conference on Ocean, Offshore, and Artic Engineering, San Francisco, USA.
23 Liu, S., Papanikolaou, A., and Zaraphonitis, G., 2011. Prediction of added resistance of ships in waves. Ocean Engineering, 38, 641-650.   DOI
24 Maruo, H., 1960. The drift of a body floating on waves. Journal of Ship Research, 4 (3), 1-10.
25 Orihara, H., Matsumoto, K., Yamasaki, K., and Takagishi, K., 2008. CFD simulations for development of high-performance hull forms in a seaway. In: Proceedings of the 6th Osaka colloquium on seakeeping and stability of ship, Osaka, Japan, 58-65.