1 |
Wilcox, D.C. (1998), Turbulence Modeling for CFD, 2nd ed. La Canada, California: DCW Industries.
|
2 |
Salvesen, N., Tuck, E. and Faltinsen, O. (1970), "Ship motions and sea loads", The Society of Naval Architects and Marine Engineers, 78, 250-287.
|
3 |
Irkal, M A.R., Nallayarasu, S. and Bhattacharyya, S.K. (2016), "CFD approach to roll damping of ship with bilge keel with experimental validation", Appl. Ocean Res., 55, 1-17.
DOI
|
4 |
Islam, H., Rahaman, M. and Akimoto, H. (2019), "Added Resistance Prediction of KVLCC2 in Oblique Waves", Am. J. Fluid Dynam., 9(1), 13-26.
|
5 |
Jiao, J. and Huang, S. (2020), "CFD simulation of ship seakeeping performance and slamming loads in Bidirectional cross wave", J. Mar. Sci. Eng., 8(5), 1-24.
DOI
|
6 |
Jin, Y., Chai, S., Duffy, J., Chin, C. and Bose, N. (2017), "URANS predictions of wave induced loads and motions on ships in regular head and oblique waves at zero forward speed", J. Fluid. Struct., 74, 178-204.
DOI
|
7 |
Journee, J.M.J. (1992), "Experiments and calculations on 4 Wigley hull forms in head waves", Delft University of Technology Report, no. May 1992, 1-99.
|
8 |
Kashiwagi, M. (2013), "Hydrodynamic study on added resistance using unsteady wave analysis", J. Ship Res., 57(4), 220-240.
DOI
|
9 |
Kim, J., O'Sullivan, J. and Read, A. (2012), "Ringing analysis of a vertical cylinder by Euler overlay method", Proceedings of the 31st International Conference on Ocean, Offshore & Arctic Engineering, Rio de Janeiro, Brazil.
|
10 |
Kim, K. H., and Kim, Y. (2010), "Comparative study on ship hydrodynamics based on Neumann-Kelvin and double-body linearizations in time-domain analysis," International Journal of Offshore and Polar Engineering, vol. 20, no. 4, pp. 265-274.
|
11 |
Muzaferija, S. and Peric, M. (2017), "Computation of free-surface flows using interface-tracking and interface- capturing methods", Fluid Dynamics and Ship Theory Section, Technical University of Hamburg, Hamburg.
|
12 |
Kashiwagi, M. (1995), "Prediction of Surge and its Effect on Added Resistance by Means of the Enhanced Unified Theory", Trans West-Japan Society of Naval Architects, 89, 77-89.
|
13 |
Kim, S.J. and Koo, W. (2019), "Development of a three-dimensional fully non-linear potential numerical wave tank for a heaving buoy wave energy converter", Math. Probl.Eng., 2019(1).
|
14 |
Bakti, F.P. and Kim, M.H. (2020), "Second Order Difference Frequency Wave-Current Loading Using Neumann-Kelvin Approximation", Proceedings of the 39th International Conference on Ocean, Offshore & Arctic Engineering, Virtual Online, OMAE2020.
|
15 |
Orihara, H. (2011), "Comparison of CFD simulations with experimental data for a tanker model advancing in waves", Int. J. Naval Archit. Ocean Eng., 3(1), 1-8.
DOI
|
16 |
Papanikolaou, A. and Schellin, T. (1992), "A three-dimensional panel method for motions and loads of ships with forward speed", Ship Technol. Res.(Schiffstechnik), 39(4), 145-155.
|
17 |
Sadat-Hosseini, H., Wu, P.C., 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 Eng., 59, 240-273.
DOI
|
18 |
Arjen, K., et al. (2020), "Development and Verification of Modeling Practice for CFD Calculations to Obtain Current Loads on FPSO", Proceedings of the 39th International Conference on Ocean, Offshore & Arctic Engineering.
|
19 |
Bihs, H., Kamath, A., Alagan Chella, M., Aggarwal, A. and Arntsen, O.A. (2016), "A new level set numerical wave tank with improved density interpolation for complex wave hydrodynamics", Comput. Fluid., 140, 191-208.
DOI
|
20 |
Heilskov, N.F. and Petersen, O.S. (2016), "Non-Linear 3D Hydrodynamics of Floating Wind Turbine Compared Against Wave Tank Tests", Proceedings of the 35th International Conference on Ocean, Offshore & Arctic Engineering, Busan, South Korea.
|
21 |
Bakti, F.P., Jin, C. and Kim, M.H. (2021), "Practical Approach of Linear Hydro-elasticity Effect on Vessel with Forward Speed in the Frequency Domain", J. Fluid. Struct., 101, 103204, doi: 10.1016/j.jfluidstructs.2020.103204.
DOI
|
22 |
Adapco, C.D. (2020), "STAR CCM+ User's Manual", http://www.cd-adapco.com/products/star-ccm.
|
23 |
Bakti, F.P., Kim, M.H., Park, J.C. and Kim, K.S. (2016), "Comparative study of standard WC-SPH and MPS solvers for free surface academic problems", Int. J. Offshore Polar Eng., 26(3), 235-243.
DOI
|
24 |
Bandringa, H. and Helder, J.A. (2020), "On the Validity of CFD for Simulating Extreme Green Water Loads", Proceedings of the 39th International Conference on Ocean, Offshore & Arctic Engineering, Virtual, Online, OMAE2020.
|
25 |
Beck, R.F. and Loken, A.E. (1989), "Three-dimensional effects in ship relative-motion problems", J. Ship Res., 33(4), 261-268.
DOI
|
26 |
Flock, A.K., Guildenbecher, D.R., Chen, J., Sojka, P.E. and Bauer, H.J. (2012), "Experimental statistics of droplet trajectory and air flow during aerodynamic fragmentation of liquid drops", Int. J. Multiphase Fl., 47, 37-49.
DOI
|
27 |
Bouscasse, B., Bockman, A. and Ducrozet, G. (2020), "Development of A Protocol to Couple Wave and CFD Solvers Towards Potential Wave Kinematic Solver", Virtual, Online, OMAE2020.
|
28 |
Brard, R. (1972), "Representation of a given ship form by singularity distributions when the boundary condition on the free surface is linearized", J. Ship Res., 16(1), 79-92.
DOI
|
29 |
Celebi, M.S., Kim, M.H. and Beck, R.F. (1998), "Fully nonlinear 3D numerical wave tank simulations", J. Ship Res., 42(1), 33-45.
|
30 |
Guha, A. and Falzarano, J. (2015), "The effect of hull emergence angle on the near field formulation of added resistance", Ocean Eng., 105, 10-24.
DOI
|
31 |
Guha, A. and Falzarano, J. (2016), "Estimation of hydrodynamic forces and motion of ships with steady forward speed", Int. Shipbuild. Progress, 62(3-4), 113-138.
DOI
|
32 |
Hadzic, H. (2005), "Development and Application of a Finite Volume Method for the Computation of Flows Around Moving Bodies on Unstructured, Overlapping Grids", Dissertation, Technische Universitat Hamburg.
|
33 |
Vigsnes, J.T. (2018), "Seakeeping Analysis Comparison between Viscous and Inviscid CFD", Dissertation, Norwegian University of Science and Technology, Dept. of Marine Engineering.
|
34 |
White, F.M. (2006), Viscous fluid flow, 3rd ed. New York: McGraw-Hill.
|
35 |
Wu, C.S., Zhou, D.C., Gao, L. and Miao, Q.M. (2011), "CFD computation of ship motions and added resistance for a high speed trimaran in regular head waves", Int. J. Naval Architect. Ocean Eng., 3(1), 105-110.
DOI
|
36 |
Ogilvie, T. and Tuck, E. (1969), "A rational strip theory of ship motions: part I", Naval Ship Systems Command General Hydromechanics Research Program Subproject SR 009 01 01 Report, no. N00014-67-A-0181-0016.
|