生物启发鲨鱼齿状体减阻实验研究

IF 2.2 3区 生物学 Q1 ZOOLOGY Integrative and Comparative Biology Pub Date : 2024-09-27 DOI:10.1093/icb/icae086
Marshall T Graybill, Nicole W Xu
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引用次数: 0

摘要

鲨鱼皮肤由小齿或复杂的鳞片状特征组成,这些特征已被证明可以减少湍流和层流中的阻力。小齿冠上的波状结构被称为波纹,它们与湍流边界层相互作用,从而减少阻力。有两种机制被认为有助于波纹的阻力降低特性,包括提升流向涡和阻碍跨向涡相互作用以减少横流,这可能转化为类似于齿粒的流动机制。由于不同鲨鱼物种的真皮小齿的形态各异,而且还取决于身体位置,因此这些小齿的几何形状对流动的影响引起了生物学界的兴趣,包括流体力学和海洋学等相关领域。这篇综述重点介绍了过去 15 年中的制造技术以及对齿状体启发表面结构阻力的实验测量,包括真实的鲨鱼皮肤样本以及工程齿状体和波纹管。最先进的增材制造技术和其他技术主要局限于毫米长的齿粒尺度,这些齿粒在较低流速(1 米/秒-1 以下)下可减少阻力。新的制造方法可以制造出毫米以下长度的微粒和纳米纹理表面结构,据报道,这些微粒和结构可将阻力降低 31%。我们综合了文献中的研究结果,说明了生物启发微粒和波纹管根据其几何形状和流动条件所具有的阻力降低特性。利用这些趋势,我们提出了未来研究的设计特点和重点领域,例如增加对不同齿粒形态、疏水性、防污特性和降噪性能的研究。继续研究生物启发的齿粒以减少阻力,在比较生物学和应用设计更节能、更持久的环境监测飞行器方面具有更广泛的意义。
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Experimental Studies of Bioinspired Shark Denticles for Drag Reduction.

Shark skin is composed of denticles, or complex scale-like features, which have been shown to reduce drag in turbulent and laminar flow. The denticle crown features undulating structures called riblets that interact with the turbulent boundary layer to reduce drag. Two mechanisms thought to contribute to the drag-reducing properties of riblets include the lifting of streamwise vortices and the hampering of spanwise vortex interactions to reduce crossflow, which could translate to similar flow mechanisms for denticles. Because of the varied morphologies of dermal denticles on different shark species, which also depend on body location, the impact of these denticle geometries on flow is of interest to the biology community, including related fields such as fluid mechanics and oceanography. This review highlights the past 15 years of manufacturing techniques and experimental measurements of drag over denticle-inspired surface structures, including real shark skin samples and engineered denticles and riblets. State-of-the-art additive manufacturing and other techniques are primarily limited to mm-length denticle scales, which have demonstrated drag reduction in lower flow speeds, under 1 m s-1. New manufacturing approaches can create sub-mm length denticles and nanotextured surface structures, which have achieved reported drag reductions of up to 31%. We synthesize results from the literature to illustrate the drag reduction properties of bioinspired denticles and riblets according to their geometry and flow conditions. Using these trends, we suggest design features and focus areas for future research, such as increasing studies of different denticle morphologies, hydrophobicity, antifouling properties, and acoustic noise reduction. Continued work on bioinspired denticles for drag reduction has wider implications in comparative biology and applications to design more energy-efficient, persistent vehicles for environmental monitoring.

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来源期刊
CiteScore
4.70
自引率
7.70%
发文量
150
审稿时长
6-12 weeks
期刊介绍: Integrative and Comparative Biology ( ICB ), formerly American Zoologist , is one of the most highly respected and cited journals in the field of biology. The journal''s primary focus is to integrate the varying disciplines in this broad field, while maintaining the highest scientific quality. ICB''s peer-reviewed symposia provide first class syntheses of the top research in a field. ICB also publishes book reviews, reports, and special bulletins.
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