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水下减阻技术研究综述 被引量:33
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作者 柯贵喜 潘光 +2 位作者 黄桥高 胡海豹 刘占一 《力学进展》 EI CSCD 北大核心 2009年第5期546-554,共9页
在简要回顾早期减阻研究的基础上,对现有典型水下湍流减阻技术进行了较深入地分析。重点介绍了脊状表面减阻、微气泡减阻和疏水/超疏水表面减阻的研究现状。分别从实验研究和理论研究两方面对其进行了阐述,并着重强调了各自的减阻机理... 在简要回顾早期减阻研究的基础上,对现有典型水下湍流减阻技术进行了较深入地分析。重点介绍了脊状表面减阻、微气泡减阻和疏水/超疏水表面减阻的研究现状。分别从实验研究和理论研究两方面对其进行了阐述,并着重强调了各自的减阻机理。此外,还简要介绍了柔顺壁面减阻、壁面振动减阻等其它减阻技术。展望了水下减阻技术今后的研究重点及其应用前景。 展开更多
关键词 水下减阻技术 湍流边界层 脊状表面减阻 微气泡减阻 疏水/超疏水表面减阻 减阻机理
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Water-trapping and drag-reduction effects of fish Ctenopharyngodon idellus scales and their simulations 被引量:7
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作者 WU LiYan JIAO ZhiBin +3 位作者 SONG YuQiu REN WenTao NIU ShiChao HAN ZhiWu 《Science China(Technological Sciences)》 SCIE EI CAS CSCD 2017年第7期1111-1117,共7页
In the last decades, surface drag reduction has been re-emphasized because of its practical values in engineering applications,including vehicles, aircrafts, ships, and fuel pipelines. The bionic study of drag reducti... In the last decades, surface drag reduction has been re-emphasized because of its practical values in engineering applications,including vehicles, aircrafts, ships, and fuel pipelines. The bionic study of drag reduction has been attracting scholars' attentions. Here, it was determined that the delicate microstructures on the scales of the fish Ctenopharyngodon idellus exhibit remarkable drag-reduction effect. In addition, the underlying drag-reduction mechanism was carefully investigated. First,exceptional morphologies and structures of the scales were observed and measured using a scanning electron microscope and3-dimensional(3D) microscope. Then, based on the acquired data, optimized 3D models were created. Next, the mechanism of the water-trapping effect of these structures was analyzed through numerical simulations and theoretical calculations. It was determined that there are many microcrescent units with certain distributions on its surface. In fact, these crescents are effective in generating the "water-trapping" effect and forming a fluid-lubrication film, thus reducing the skin friction drag effectively.Contrasting to a smooth surface, the dynamics finite-element analysis indicated that the maximum drag-reduction rate of a bionic surface is 3.014% at 0.66 m/s flow rate. This study can be used as a reference for an in-depth analysis on the bionic drag reduction of boats, underwater vehicles, and so forth. 展开更多
关键词 water trapping structure drag reduction surface fish scales simulations bionic surface and interface
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