Comparison of Numerical Analyses and Model Test for Evaluation on Hydroelastic and Higher-order Springing Responses of Fixed Cylindrical Structure |
Kim, Hyun-Sung
(Offshore Platform Research Division, Korea Research Institute of Ships and Ocean Engineering)
Won, Younguk (Offshore Platform Research Division, Korea Research Institute of Ships and Ocean Engineering) Oh, Young Jae (Offshore Platform Research Division, Korea Research Institute of Ships and Ocean Engineering) Lee, Kangsu (Offshore Platform Research Division, Korea Research Institute of Ships and Ocean Engineering) Kim, Byoung Wan (Offshore Platform Research Division, Korea Research Institute of Ships and Ocean Engineering) |
1 | Price, W.G., & Wu, Y. (1985). Structural Responses of a SWATH of Multi-Hulled Vessel Traveling in Waves. Proceedings of International Conference on SWATH Ships and Advanced Multi-hulled Vessels. Royal Institution of Naval Architects, London. |
2 | Bishop, R.E.D., & Price, W.G. (1977). The Generalized Antisymmetric Fluid Forces Applied to a Ship in a Seaway. International Shipbuilding Progress, 24(269), 3-14. https://www.doi.org/10.3233/ISP-1977-2426901 DOI |
3 | Bishop, R.E.D., Price, W.G., & Wu, Y. (1986). A General Linear Hydroelasticity Theory of Floating Structures Moving in a Seaway. Philosophical Transactions of Royal Society, London, A316. https://doi.org/10.1098/rsta.1986.0016 |
4 | Andrianov, A.I. (2005). Hydroelasitc Analysis of Very Large Floating Structures (Doctorial Thesis). Delft University of Technology, Delft, Netherlands. |
5 | Bathe, K.J. (1996). Finite Element Procedure. Prentice Hall. |
6 | Hong, S.Y., Kim, J.H., Cho, S.K., Choi, Y.R., & Kim, Y.S. (2005). Numerical and Experimental Study on Hydrodynamic Interaction of Side-by-Side Moored Multiple Vessels. Ocean Engineering, 32(7), 783-801. https://doi.org/10.1016/j.oceaneng.2004.10.003 DOI |
7 | Hong, S.Y., & Kim, B.W. (2014). Experimental Investigations of Higher-order Springing and Whipping-WILS Project. International Journal of Naval Architecture and Ocean Engineering, 6(4), 1160-1181. https://doi.org/10.2478/IJNAOE-2013-0237 DOI |
8 | Betts, C.V., Bishop, R.E.D., & Price, W.G. (1977). The Symmetric Generalized Fluid Forces Applied to a Ship in a Seaway. Transactions of the Royal Institution of Naval Architecture, 119, 265-278. |
9 | Choi, Y.R., Hong, S.Y., & Choi, H.S. (2000). An Analysis of Second-order Wave Forces on Floating Bodies by Using a Higher-Order Boundary Element Method. Ocean Engineering, 28(1), 117-138. https://doi.org/10.1016/S0029-8018(99)00064-5 DOI |
10 | Heller, S.R., & Abramson, H.N. (1959). Hydroelasticity: A New Naval Science. Journal of America Society of Naval Engineers, 71(2), 205-209. https://doi.org/10.1111/j.1559-3584.1959.tb02326.x DOI |
11 | Jensen, J.J., & Pedersen, P.T. (1981). Bending Moments and Shear Forces in Ships Sailing in Irregular Waves. Journal of Ship Research, 25(4), 243-251. DOI |
12 | Shuku, M., Shin, H., Inoue, S., Kobayashi, E., & Simamune, S. (2001). Overview of Mega-Float and Its Utilization. Mitsubishi Heavy Industries, Ltd. Technical Review, 38(2), 39-46. |
13 | Kim, B.W., Cho, S.K., & Sung, H.G. (2018). Time Domain Full Ship Finite Element Analysis with or Without Scattering or Radiation Potential. Proceedings of 2018 Joint Conference of the Korean Association of Ocean Science and Technology Societies, 97-100. |
14 | Kim, H.S., Kim, B.W., Won, Y., Oh, Y.J., & Lee, K. (2020). Numerical and Experimental Evaluation on Wave-Induced Responses of Cylindrical Structure with or without Hydroelastic Effect. Proceedings of 2020 Joint Conference of the Korean Association of Ocean Science and Technology Societies, 869-872 |
15 | Kim, J.G., Cho, S.P., Kim, K.T., & Lee, P.S. (2014). Hydroelastic Design Contour for the Preliminary Design of Very Large Floating Structures. Ocean Engineering, 78, 112-123. https://doi.org/10.1016/j.oceaneng.2013.11.006 DOI |
16 | Rognaas, G., Xu, J., Lindseth, S., & Rosendahl, F. (2001). Mobile Offshore Base Concepts: Concrete Hull and Steel Topsides. Marine Structure, 14(1-2), 5-23. https://doi.org/10.1016/S0951-8339(00)00019-8 DOI |
17 | Wu, Y. (1984). Hydroelasticity of Floating Bodies (Ph D. Thesis). Brunel University, UK. |
18 | Lakshmynarayanana, P.A., Temarel, P., & Chen, Z. (2015). Coupled Fluid-Structure Interaction to Model Three-Dimensional Dynamic Behaviour of Ship in Waves. Proceedings of 7th International Conference on Hydroelasticity in Marine Technology, Split, Croatia, 623-636. |
19 | Shin, K.H., Jo, J.W., Hirdaris, S.E., Jeong, S.G., Park, J.B., Lin, F., Wang, Z., & White, N. (2015). Two- and Three- Dimensional Springing Analysis of a 16,000 TEU Container Ship in Regular Waves. Ships and Offshore Structures, 10(5), 498-509. https://doi.org/10.1080/17445302.2015.1014255 DOI |