Litcius/Paper detail

Cargo carrying with an inertial squirmer in a Newtonian fluid

Zhenyu Ouyang, Zhaowu Lin, Jianzhong Lin, Zhaosheng Yu, N. Phan‐Thien

2023Journal of Fluid Mechanics18 citationsDOI

Abstract

We numerically investigate the hydrodynamics of a spherical swimmer carrying a rigid cargo in a Newtonian fluid. This swimmer model, a ‘squirmer’, which is self-propelled by generating tangential surface waves, is simulated by a direct-forcing fictitious domain method (DF-FDM). We consider the effects of swimming Reynolds numbers ( Re ) (based on the radius and the swimming speed of the squirmers), the assembly models (related to the cargo shapes, the relative distances ( d s ) and positions between the squirmer and the cargo) on the assembly's locomotion. We find that the ‘pusher-cargo’ (pusher behind the cargo) model swims significantly faster than the remaining three models at the finite Re adopted in this study; the term ‘pusher’ indicates that the object is propelled from the rear, as opposed to ‘puller’, from the front. Both the ‘pusher-cargo’ and ‘cargo-pusher’ (pusher in front of the cargo) assemblies with an oblate cargo swim faster than the corresponding assemblies with a spherical or prolate cargo. In addition, the pusher-cargo model is significantly more efficient than the other models, and a larger d s yields a smaller carrying hydrodynamic efficiency η for the pusher-cargo model, but a greater η for the cargo-pusher model. We also illustrate the assembly swimming stability, finding that the ‘puller-cargo’ (puller behind the cargo) model is stable more than the ‘cargo-puller’ (puller in front of the cargo) model, and the assembly with a larger d s yields more unstable swimming.

Topics & Concepts

PhysicsMechanicsFront (military)Reynolds numberInertial frame of referenceNewtonian fluidSlosh dynamicsClassical mechanicsTurbulenceMeteorologyMicro and Nano RoboticsModular Robots and Swarm IntelligenceLattice Boltzmann Simulation Studies