TY - JOUR
T1 - A Virtual Free Surface (VFS) model for efficient wave-current CFD simulation of fully submerged structures
AU - Markus, D.
AU - Arnold, M.
AU - Wüchner, R.
AU - Bletzinger, K. U.
N1 - Funding Information:
This work was made possible in part by the German National Academic Foundation , the International Graduate School of Science and Engineering (IGSSE, project team 7.05) , and the Voith Hydro Ocean Current Technologies GmbH & Co. KG . Furthermore, the authors would like to acknowledge the contributions of Projektträger Jülich (PTJ) , the German Federal Ministry for the Environment, Nature Conservation and Nuclear Safety (funding code: 0325222 ), and STRABAG Offshore Wind (SOW) .
PY - 2014/7
Y1 - 2014/7
N2 - In ocean engineering, complex design problems are frequently analyzed by applying computational fluid dynamics (CFD). When these problems involve waves and currents, a CFD simulation of a multiphase flow is one possible approach to gain valuable information. However, in terms of the computational costs, free surface flow simulations are quite restrictive. Neglecting viscous effects, significantly simpler and faster models are available, but may not provide sufficient information regarding the true nature of the flow. As an alternative, a single phase Virtual Free Surface (VFS) model is introduced in this paper. The methodology allows for efficient CFD simulations of fully submerged structures subjected to pure waves and combined wave-current scenarios, under consideration of wave-current interaction. The velocities and pressures computed with the model are analyzed and compared to theoretical reference solutions. Then, a correction model is introduced that reduces deviations observed in the pressure solution. The model is applied to the investigation of a tidal turbine and its support structure. All results computed with the VFS model are compared to reference free surface computations. Overall the VFS results agree well with the reference solutions, at significantly lower computational cost. Therefore, the method is ideal for optimization problems involving a large number of structural variations subjected to specific offshore conditions.
AB - In ocean engineering, complex design problems are frequently analyzed by applying computational fluid dynamics (CFD). When these problems involve waves and currents, a CFD simulation of a multiphase flow is one possible approach to gain valuable information. However, in terms of the computational costs, free surface flow simulations are quite restrictive. Neglecting viscous effects, significantly simpler and faster models are available, but may not provide sufficient information regarding the true nature of the flow. As an alternative, a single phase Virtual Free Surface (VFS) model is introduced in this paper. The methodology allows for efficient CFD simulations of fully submerged structures subjected to pure waves and combined wave-current scenarios, under consideration of wave-current interaction. The velocities and pressures computed with the model are analyzed and compared to theoretical reference solutions. Then, a correction model is introduced that reduces deviations observed in the pressure solution. The model is applied to the investigation of a tidal turbine and its support structure. All results computed with the VFS model are compared to reference free surface computations. Overall the VFS results agree well with the reference solutions, at significantly lower computational cost. Therefore, the method is ideal for optimization problems involving a large number of structural variations subjected to specific offshore conditions.
KW - Computational fluid dynamics (CFD)
KW - Free surface
KW - Reduced modeling
KW - Shape optimization
KW - Tidal turbines
KW - Wave-current interaction
UR - http://www.scopus.com/inward/record.url?scp=84899812645&partnerID=8YFLogxK
U2 - 10.1016/j.coastaleng.2014.04.004
DO - 10.1016/j.coastaleng.2014.04.004
M3 - Article
AN - SCOPUS:84899812645
SN - 0378-3839
VL - 89
SP - 85
EP - 98
JO - Coastal Engineering
JF - Coastal Engineering
ER -