TY - JOUR
T1 - Focused wave interactions with floating structures: A blind comparative study
AU - Ransley, Edward Jack
AU - Brown, Scott Andrew
AU - Hann, Martyn
AU - Greaves, Deborah M.
AU - Windt, Christian
AU - Ringwood, John
AU - Davidson, Josh
AU - Schmitt, Pal
AU - Yan, Shiqiang
AU - Wang, Junxian X.
AU - Wang, Jinghua H.
AU - Ma, Qingwei
AU - Xie, Zhihua
AU - Giorgi, Giuseppe
AU - Hughes, Jack
AU - Williams, Alison
AU - Masters, Ian
AU - Lin, Zaibin
AU - Chen, Hao
AU - Qian, Ling
AU - Ma, Zhihua
AU - Chen, Qiang
AU - Ding, Haoyu
AU - Zang, Jun
AU - Van Rij, Jennifer
AU - Yu, Yi-Hsiang
AU - Li, Zhaobin
AU - Bouscasse, Benjamin
AU - Ducrozet, Guillaume
AU - Bingham, Harry
PY - 2021/3
Y1 - 2021/3
N2 - The paper presents results from the Collaborative Computational Project in Wave Structure Interaction (CCP-WSI) Blind Test Series 2. Without prior access to the physical data, participants, with numerical methods ranging from low-fidelity linear models to fully nonlinear Navier-Stokes (NS) solvers, simulate the interaction between focused wave events and two separate, taut-moored, floating structures: a hemispherical-bottomed cylinder and a cylinder with a moonpool. The ‘blind’ numerical predictions for heave, surge, pitch and mooring load, are compared against physical measurements. Dynamic time warping is used to quantify the predictive capability of participating methods. In general, NS solvers and hybrid methods give more accurate predictions; however, heave amplitude is predicted reasonably well by all methods; and a WEC-Sim implementation, with CFD-informed viscous terms, demonstrates comparable predictive capability to even the stronger NS solvers. Large variations in the solutions are observed (even among similar methods), highlighting a need for standardisation in the numerical modelling of WSI problems.
AB - The paper presents results from the Collaborative Computational Project in Wave Structure Interaction (CCP-WSI) Blind Test Series 2. Without prior access to the physical data, participants, with numerical methods ranging from low-fidelity linear models to fully nonlinear Navier-Stokes (NS) solvers, simulate the interaction between focused wave events and two separate, taut-moored, floating structures: a hemispherical-bottomed cylinder and a cylinder with a moonpool. The ‘blind’ numerical predictions for heave, surge, pitch and mooring load, are compared against physical measurements. Dynamic time warping is used to quantify the predictive capability of participating methods. In general, NS solvers and hybrid methods give more accurate predictions; however, heave amplitude is predicted reasonably well by all methods; and a WEC-Sim implementation, with CFD-informed viscous terms, demonstrates comparable predictive capability to even the stronger NS solvers. Large variations in the solutions are observed (even among similar methods), highlighting a need for standardisation in the numerical modelling of WSI problems.
KW - Civil and Structural Engineering
KW - Mechanics of Materials
U2 - 10.1680/jencm.20.00006
DO - 10.1680/jencm.20.00006
M3 - Article
SN - 1472-4561
VL - 174
SP - 46
EP - 61
JO - Proceedings of the Institution of Civil Engineers: Water and Maritime Engineering
JF - Proceedings of the Institution of Civil Engineers: Water and Maritime Engineering
IS - 1
ER -