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Towards biomimetic air retaining ship hull surfaces - AIRCOAT and its experimental and computational validation methods

Presentation held at VIII International Conference on Computational Methods in Marine Engineering, MARINE 2019, Göteburg, 13 May 2019
 
: Oeffner, Johannes

2019, 17 Folien
International Conference on Computational Methods in Marine Engineering (MARINE) <8, 2019, Göteborg>
Englisch
Vortrag
Fraunhofer IML ()
AIRCOAT; Reibungsreduktion; CFD; numerische Simulation; Validierung
Anfrage beim Institut / Available on request from the institute bibliothek@iml.fraunhofer.de

Abstract
Air lubrication has a high potential to reduce skin friction of ship hulls. Active air lubrication system are already available on the market and initial results could show significant long-term energy savings of 4 %. The EU project AIRCOAT (Air Induced friction Reducing ship Coating) aims to develop a passive air lubrication technology inspired by Salvinia molesta, a floating water fern that forms a permanent air layer when submerged in water. AIRCOAT will technologically implement this natural phenomenon to produce a biomimetic hull surface with a high potential to significantly reduce the frictional resistance of ships. The air retaining surfaces based on the Salvinia effect rely on a complex micro- and nanostructured surface with hydrophobic and hydrophilic characteristics. Transferring such characteristics onto sea going ships (e.g. container ships) – which are the largest maritime macrostructures – and demonstrating its effectivity within a three-year project is an ambitious task that involves a well-defined validation method. The AIRCOAT project does this by means of combining experimental and numerical methods to upscale results from laboratory prototypes to application of full-scale solutions in operational environments. Small- and large- scale laboratory experiments will investigate the air retaining and friction reducing capabilities of the surface. Visualisation techniques will be used to determine the phenomena occurring at the ship-air-water interface. In parallel a set of numerical studies at different levels (small, large and full scale) will be carried out to estimate the drag reduction for a sea going ship virtually coated with AIRCOAT. This contribution will introduce into the AIRCOAT project, elaborate on biomimetic air-retaining surfaces and outline the validation concept developed to quantify potential friction reduction.

: http://publica.fraunhofer.de/dokumente/N-577724.html