Abstract
Biofouling is the accumulation of unwanted material on surfaces submerged or semi submerged over an extended period. This study investigates the antifouling performance of a new bioinspired topography design. A shark riblets inspired topography was designed with Solidworks and CFD simulations were antifouling performance. The study focuses on the fluid flow velocity, the wall shear stress and the appearance of vortices are to be noted to determine the possible locations biofouling would most probably occur. The inlet mass flow rate is 0.01 kgs-1 and a no-slip boundary condition was applied to the walls of the fluid domain. Simulations indicate that Velocity around the topography averaged at 7.213 x 10-3 ms-1. However, vortices were observed between the gaps. High wall shear stress is observed at the peak of each topography. In contrast, wall shear stress is significantly low at the bed of the topography. This suggests the potential location for the accumulation of biofouling. Results show that bioinspired antifouling topography can be improved by reducing the frequency of gaps between features. Linear surfaces on the topography should also be minimized. This increases the avenues of flow for the fluid, thus potentially increasing shear stresses with surrounding fluid leading to better antifouling performance.
Highlights
The accumulation of unwelcomed biological organisms on a surface due to prolonged fluid flow is called biofouling
Wall shear stress is important in this simulation, inflation around the walls are created with 2 layers inflation of elements size 0.1 mm
The results indicate that fluid flow is slow around the topographies
Summary
The accumulation of unwelcomed biological organisms on a surface due to prolonged fluid flow is called biofouling. There are many industries that still face challenges because of this natural phenomenon [1]. Methods to prevent biofouling far have shown less than satisfactory effects. The nature and effects of biofouling come in different forms: biofouling in medical devices presents in layers of biofilms only; biofouling in marine and industrial applications contains layers of biofilm together with macrofouling and inorganic fouling. Macrofouling is similar as biofilm, it is caused by the accumulation of macro sized organisms. Inorganic fouling on the other hand is caused by the accumulation of non-
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