The Numerical Simulation of Flow Patterns Generated by the Hydromedusa Aequorea Victoria Using an Arbitrary Lagrangian-Eulerian Formulation

Abstract

A new geometrically conservative arbitrary Lagrangian-Eulerian (ALE) formulation in the swirl-free cylindrical coordinates has been developed to solve the o w patterns generated by the hydromedusa Aequorea victoria. The governing equations are multiplied with the radial distance and integrated over arbitrary moving Lagrangian-Eulerian quadrilateral elements. Therefore, the continuity and the geometric conservation equations take very simple form similar to those of the Cartesian coordinates. The continuity equation is satised exactly within each element and a special attention is given to satisfy the geometric conservation law (GCL) at the discrete level. The equation of motion of a deforming body is solved in addition to the Navier-Stokes equations in fully-coupled form. The mesh deformation is achieved by solving the linear elasticity equation at each time level while avoiding remeshing in order to enhance numerical robustness. The resulting algebraic linear systems are solved using an ILU(k) preconditioned GMRES method provided by the PETSc library. The present ALE method is validated for the steady and oscillatory o w around a sphere in a cylindrical tube and applied to the investigation of the o w patterns around a free-swimming hydromedusa Aequorea victoria (crystal jellysh). The calculations for the hydromedusa indicate the shed of the opposite signed vortex rings very close to each other and the formation of large induced velocities along the line of interaction while the ring vortices moving away from the hydromedusa.