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Added resistance, heave and pitch for the KVLCC2 tanker using a fully nonlinear unsteady potential flow boundary element method

Francesco Coslovich, Martin Kjellberg, Magnus Östberg, Carl-Erik Janson

2021Ocean Engineering19 citationsDOIOpen Access PDF

Abstract

In this paper, a fully nonlinear unsteady potential flow method is used to predict added resistance, heave and pitch for the KVLCC2 hull in regular head waves at design speed. The method presents a nonlinear decomposition of the velocity potential and the wave field and an adaptive grid refinement. A formulation for the acceleration potential is used to obtain the pressure. To improve computational efficiency, a Barnes-Hut algorithm is introduced. A grid dependency study and a study on the impact of different time steps on the solution are performed. Numerical results have been compared with experimental data for the design speed. A general good agreement is found for added resistance, especially for longer waves. Heave and pitch are properly computed for all wave lengths in the range λ/Lpp=0.4 to 1.4.

Topics & Concepts

Boundary element methodNonlinear systemPotential flowHullAccelerationEngineeringVelocity potentialFlow (mathematics)MechanicsHead (geology)Computational fluid dynamicsFinite element methodMarine engineeringBoundary value problemStructural engineeringAcousticsMathematicsGeologyPhysicsAerospace engineeringClassical mechanicsMathematical analysisGeomorphologyQuantum mechanicsShip Hydrodynamics and ManeuverabilityFluid Dynamics Simulations and InteractionsMaritime Transport Emissions and Efficiency
Added resistance, heave and pitch for the KVLCC2 tanker using a fully nonlinear unsteady potential flow boundary element method | Litcius