论文信息 - Sailing yacht performance prediction based on coupled CFD and rigid body dynamics in 6 degrees of freedom

Sailing yacht performance prediction based on coupled CFD and rigid body dynamics in 6 degrees of freedom

Traditional Velocity Prediction Programs (VPPs) for sailing yachts rely on empirical relations, while modern techniques include CFD. Normally a multi-dimensional matrix of CFD results is pre-computed and forces and moments obtained by interpolation during a VPP execution. A more exact technique is to use the CFD code itself as a VPP, i.e. to simultaneously integrate the flow and rigid body equations in time. In the present paper a technique of this coupled type is introduced. An initial guess is required for speed and attitude, and by time integration in six degrees of freedom this guess is corrected to a steady state solution. Three phases are identified. First the attitude is kept constant over a period of time to stabilize the flow. Thereafter the different degrees of freedom are released successively and the rudder activated to achieve yaw balance. Finally, in the converged phase, the net forces and moments are zero in all degrees of freedom and the results reported. The performance prediction is carried out for a dinghy and a large high-performance racing yacht. Convergence of all variables is demonstrated and the results used for finding the optimum speed to windward and downwind. Details of the numerical setup are reported.

Lars Larsson | Rickard Lindstrand Levin

[1] Lars Larsson,et al. Numerical Ship Hydrodynamics - An Assessment of the Gothenburg 2010 Workshop , 2014 .

[2] Peter Ottosson,et al. The Effect of Pitch Radius of Gyration on Sailing Yacht Performance , 2002 .

[3] Rickard Lindstrand Levin. Strongly Coupled Performance Prediction for Sailing Yachts based on CFD , 2016 .

[4] Lars Larsson,et al. Principles of Yacht Design , 1994 .

[5] C. Boehm,et al. A Velocity Prediction Procedure for Sailing Yachts with a hydrodynamic Model based on integrated fully coupled RANSE-Free-Surface Simulations , 2014 .

[6] L. Larsson. Scientific Methods in Yacht Design , 1990 .

[7] Ignazio Maria Viola,et al. CFD analysis of the hydrodynamic performance of two candidate America's Cup AC33 hulls , 2012 .

[8] J. Brackbill,et al. A continuum method for modeling surface tension , 1992 .

[9] C. W. Hirt,et al. Volume of fluid (VOF) method for the dynamics of free boundaries , 1981 .

[10] Kai Graf,et al. Advancements in free surface RANSE simulations for sailing yacht applications , 2014 .

[11] F. Menter. Two-equation eddy-viscosity turbulence models for engineering applications , 1994 .

[12] Michel Visonneau,et al. Strongly coupled VPP and CFD RANSE code for sailing yacht performance prediction , 2008 .

[13] Christian Finnsgård,et al. Numerical Prediction of the Best Heel and Trim of a Laser Dinghy , 2016 .