Numerical study of hydrodynamic drag effects of streamwise riblet structures on SUBOFF bare hull model
This study performs a full-scale numerical simulation on meter-scale underwater vehicles (UWVs) with micrometer-scale V-type streamwise riblet structures, focusing on hydrodynamic drag using the SUBOFF model. The periodic simulation along the azimuthal direction enables the full-scale analysis. Two...
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Veröffentlicht in: | Ocean engineering 2024-10, Vol.310, p.118783, Article 118783 |
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Sprache: | eng |
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Zusammenfassung: | This study performs a full-scale numerical simulation on meter-scale underwater vehicles (UWVs) with micrometer-scale V-type streamwise riblet structures, focusing on hydrodynamic drag using the SUBOFF model. The periodic simulation along the azimuthal direction enables the full-scale analysis. Two main scenarios are discussed: (1) effect of riblet structure size on drag at a constant maneuvering speed and (2) effect of maneuvering speed on drag for representative riblet cases. In scenario (1), the average wall shear stress at the central region of the body exhibited significant reduction of approximately 50%. However, owing to larger effective area at the central surface of the body fixed with riblets, the friction drag may either decrease or increase depending on the riblet size. Consequently, R100 case showed maximum total drag reduction of ∼3%, whereas R500 case showed maximum increase in drag of ∼3%, where R100 and R500 indicate riblet-applied SUBOFF models with riblet heights of 100 and 500 μm, respectively. In scenario (2), friction drag in riblet-applied region exhibited smaller variations in R100 case, showing universal drag reduction effect at all speeds. In contrast, R500 case showed significant variations, with drag increments ranging from minimum of 1% to maximum of 12% at all speeds.
•Full-scale analysis for placing micrometer-scale riblet structures on meter-scale UWV.•Resolved RANS on riblet structures reveals feasibility of observing drag reduction.•Optimal riblet design ensures universal drag reduction across various flow speeds.•Inappropriate riblet design might lead to increased fuel consumption in UWV.•Insights on riblet design for diverse operational conditions in oceanic environments. |
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ISSN: | 0029-8018 |
DOI: | 10.1016/j.oceaneng.2024.118783 |