Comparative study of prediction methods of power increase and propulsive performances in regular head short waves of KVLCC2 using CFD |
Lee, Cheol-Min
(Department of Naval Architecture and Ocean Engineering, Pusan National University)
Seo, Jin-Hyeok (Department of Naval Architecture and Ocean Engineering, Pusan National University) Yu, Jin-Won (Global Core Research Center for Ships and Offshore Plants, Pusan National University) Choi, Jung-Eun (Global Core Research Center for Ships and Offshore Plants, Pusan National University) Lee, Inwon (Department of Naval Architecture and Ocean Engineering, Pusan National University) |
1 | Journee, J.M.J., 1976a. Report 428, May 1976. Motions, Resistance and Propulsion of a Ship in Regular Head Waves, vol. 2. Delft University of Technology, Ship Hydromechanics Laboratory, Mekelweg, CD Delft, The Netherlands, p. 2628. |
2 | Journee, J.M.J., 1976b. Prediction of speed and behaviour of a ship in a seaway. Int. Shipbuild. Prog. 23 (265), 1-24. |
3 | Kayano, J., Yabuki, H., Sasaki, N., Hiwatashi, R., 2013. A study on the propulsion performance in the actual sea by means of full-scale experiments. The International Journal on Marine Navigation and Safety of Sea Transportation 7 (4), 521-526. DOI |
4 | Kim, M., Hizirb, O., Turana, O., Incecika, A., 2017a. Numerical studies on added resistance and motions of KVLCC2 in head seas for various ship speeds. Ocean Eng. 140, 466-476. DOI |
5 | Kim, M., Hizirb, O., Turana, O., Incecika, A., 2017b. Estimation of added resistance and ship speed loss in a seaway. Ocean Eng. 141, 465-476. DOI |
6 | Kim, W.J., Van, D.H., Kim, D.H., 2001. Measurement of flows around modern commercial ship models. Exp. Fluid 31, 567-578. DOI |
7 | McCarthy, J.H., Norley, W.H., Ober, G.L., 1961. The Performance of a Submerged Propeller in Regular Waves. David Taylor Model Basin, Washington DC, USA. |
8 | MEPC 66/21 Annex 5, 2014. Guidelines on the Method of Calculation of the Attained Energy Efficiency Design Index (EEDI) for New Ships. |
9 | Nakamura, S., Naito, S., 1975. Propulsive performance of a container ship in waves. J. Kansai Soc. Nav. Archit. Jpn. 158, 24-47. |
10 | Prpic-Orsic, J., Faltinsen, O.M., 2009. Speed loss calculation in a seaway. In: Proceedings of the 13th Congress. International Maritime Association of the Mediterranean (IMAM), p. 393-400. |
11 | Prpic-Orsic, J., Faltinsen, O.M., 2012. Estimation of ship speed loss and associated CO2 emissions in a seaway. Ocean Eng. 44, 1-10. DOI |
12 | Rathje, H., Schellin, T.E., Brehm, A., 2011. Speed loss in waves and wave-induced torsion of a wide-breadth containership. Journal of Engineering for the Maritime Environment 225, 387-401. |
13 | Seo, J.H., Seol, D.M., Lee, J.H., Rhee, S.H., 2010. Flexible CFD meshing strategy for prediction of ship resistance and propulsion performance. International Journal of Naval Architecture and Ocean Engineering 2, 139-145. DOI |
14 | Taskar, B., Yum, K.K., Steen, S., Pedersen, E., 2016. The effect of waves on enginepropeller dynamics and propulsion performance of ships. Ocean Eng. 122, 262-277. DOI |
15 | Valanto, P., Hong, Y., 2017. Wave added resistance and propulsive performance of a cruise ship in waves. In: Proceedings of the 27th International Ocean and Polar Engineering Conference (ISOPE), 25-30 June, San Francisco, California, USA. |
16 | Yu, J.W., Lee, C.M., Choi, J.E., Lee, I.W., 2017. Effect of ship motions on added resistance in regular head waves of KVLCC2. Ocean Eng. 146, 375-387. DOI |
17 | Gerritsma, J., Beukelman, W., 1972. Analysis of the resistance increase in waves of a fast cargo ship. Int. Shipbuild. Prog. 19, 285-293. DOI |
18 | Arribas, F.P., 2007. Some methods to obtain the added resistance of a ship advancing in waves. Ocean Eng. 34, 946-955. DOI |
19 | Baree, M.S., 2010. An investigation of ship performance in seas. In: Proceedings of the International Conference on Marine Technology (MARTEC), 11-12, December 2010, BUET, Dhaka, Bangladesh. |
20 | Carrica, P.M., Castro, A.M., Stern, F., 2010. Self-propulsion computations using a speed controller and a discretized propeller with dynamic overset grids. J. Mar. Sci. Technol. 15, 316-330. DOI |
21 | Choi, J.E., Min, K.-S., Kim, J.H., Lee, S.B., Seo, H.W., 2010. Resistance and propulsion characteristics of various commercial ships based on CFD results. Ocean Eng. 37, 549-566. DOI |
22 | Castro, A.M., Carrica, P.M., Stern, F., 2011. Full scale self-propulsion computations using discretized propeller for the KRISO container ship KCS. Comput. Fluids 51, 35-47. DOI |
23 | CD Adapco, 2016. STAR-CCM+ User Guide, version 11.04. |
24 | Choi, J.E., Kim, J.H., Lee, H.G., Choi, B.J., Lee, D.H., 2009. Computational predictions of ship-speed performance. J. Mar. Sci. Technol. 14 (3), 322-333. DOI |
25 | Chuang, Z., Steen, S., 2011. Prediction of speed loss of a ship in waves. In: Proceedings of the 2nd International Symposium on Marine Propulsors (SMP), M. Abdel-Maksoud. Hamburg, Germany, 1: 8. |
26 | Chuang, Z., Steen, S., 2013. Speed loss of a vessel sailing in oblique waves. Ocean Eng. 64, 88-99. DOI |
27 | Eide, E., 2015. Calculation of Service and Sea Margins. Master thesis. Institute for Marine Technology Norwegian University of Science and Technology. |
28 | Faltinsen, O.M., 1990. Sea Loads on Ships and Offshore Structures. Cambridge University Press, Cambridge. |
29 | Faltinsen, O.M., Minsaas, K.J., Liapis, N., Skjordal, S.O., 1980. Prediction of resistance and propulsion of a ship in a seaway. In: Proceedings of the 13th Symposium on Naval Hydrodynamics (SNH), pp. 505-529. |
30 | Guo, B., Steen, S., Deng, G.B., 2012. Seakeeping prediction of KVLCC2 in head waves with RANS. Appl. Ocean Res. 35, 56-67. DOI |