Simulations on traveling-plane-wave-based micropumps and microswimmers

A biologically-inspired micropropulsion method is studied via a series of CFD models managing time-irreversible inextensible wave propagation in a viscous medium. First pump effect of a fully submerged and anchored thin-film with time-irreversible plane-wave propagation is analyzed by means of resultant channel flow hydraulic power consumption and efficiency while performing in a microchannel. Next propulsion velocity power consumption and hydrodynamic efficiency of a fully submerged and untethered bio-inspired microswimmer employing single wave-propagating slender tail are analyzed with respect to parameterized design variables. All models are governed by dimensionless incompressible Navier-Stokes equations subject to conservation of mass and incorporated with the arbitrary Lagrangian-Eulerian mesh scheme simultaneously handling moving and stationary boundaries. The resultant rigid-body motion of the swimmer is modeled via incorporating interactions between surrounding viscous fluid and swimmer surface with the rigid-body kinematics in 3D. Numerical results are compared with the asymptotical results to analytical studies carried out earlier based on 2D flow assumptions.