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水下航行器仿生沟槽表面减阻研究

Drag reduction using bionic groove surface for underwater vehicles.

作者信息

Zheng Shihao, Liang Xi, Li Jiayong, Liu Yanyan, Tang Jun

机构信息

School of Civil Engineering, Tianjin University, Tianjin, China.

Library of the People's Public Security University of China, Beijing, China.

出版信息

Front Bioeng Biotechnol. 2023 Aug 25;11:1223691. doi: 10.3389/fbioe.2023.1223691. eCollection 2023.

DOI:10.3389/fbioe.2023.1223691
PMID:37691898
原文链接:https://pmc.ncbi.nlm.nih.gov/articles/PMC10492569/
Abstract

The reduction of drag is a crucial concern within the shipping industry as it directly influences energy consumption. This study addresses this issue by proposing a novel approach inspired by the unique ridge structure found on killer whale skin. The objective is to develop a non-smooth surface drag reduction method that can effectively decrease drag and improve energy efficiency for ships. The study introduces a technique involving the creation of transverse bionic groove surfaces modeled after the killer whale skin's ridge structure. These grooves are aligned perpendicular to the flow direction and are intended to modify the behavior of turbulent boundary layer flows that form around the ship's hull. Numerical simulations are employed using the Shear Stress Transport k-ω model to analyze the effects of the proposed groove surface across a wide range of flow conditions. The research investigates the impact of various parameters, such as the width-to-depth ratio (λ/A), groove depth, and inlet velocity, on the drag reduction performance of the bionic groove surface. The study reveals several key findings. Optimal shape parameters for the bionic groove surface are determined, enabling the most effective drag reduction. The numerical simulations demonstrate that the proposed groove surface yields notable drag reduction benefits within the velocity range of 2∼12 m/s. Specifically, the friction drag reduction ratio is measured at 26.91%, and the total drag reduction ratio at 9.63%. These reductions signify a substantial decrease in the forces opposing the ship's movement through water, leading to enhanced energy efficiency. Comparative analysis is conducted between the performance of the bionic groove surface and that of a smooth surface. This investigation involves the examination of velocity gradient, streamwise mean velocity, and turbulent intensity. The results indicate that the bionic groove structure effectively mitigates viscous stress and Reynolds stress, which in turn reduces friction drag. This reduction in drag is attributed to the alteration in flow behavior induced by the non-smooth surface. The study proposes a novel approach for drag reduction in the shipping industry by emulating the ridge structure of killer whale skin. The transverse bionic groove surface, aligned perpendicular to flow direction, demonstrates promising drag reduction outcomes across diverse flow conditions. Through systematic numerical simulations and analysis of key parameters, the research provides insights into the drag reduction mechanism and identifies optimal design parameters for the groove surface. The potential for significant energy savings and improved fuel efficiency in maritime transportation underscores the practical significance of this research.

摘要

阻力的降低是航运业的一个关键问题,因为它直接影响能源消耗。本研究通过提出一种受虎鲸皮肤独特脊状结构启发的新方法来解决这个问题。目标是开发一种非光滑表面减阻方法,该方法可以有效降低船舶阻力并提高能源效率。该研究引入了一种技术,即创建模仿虎鲸皮肤脊状结构的横向仿生凹槽表面。这些凹槽垂直于流动方向排列,旨在改变围绕船体形成的湍流边界层流动的行为。使用剪切应力输运k-ω模型进行数值模拟,以分析所提出的凹槽表面在广泛流动条件下的效果。该研究调查了各种参数的影响,如宽深比(λ/A)、凹槽深度和入口速度,对仿生凹槽表面的减阻性能的影响。该研究揭示了几个关键发现。确定了仿生凹槽表面的最佳形状参数,从而实现最有效的减阻。数值模拟表明,所提出的凹槽表面在2至12米/秒的速度范围内产生了显著的减阻效果。具体而言,摩擦阻力降低率为26.91%,总阻力降低率为9.63%。这些降低表明阻碍船舶在水中移动的力大幅减少,从而提高了能源效率。对仿生凹槽表面和平滑表面的性能进行了对比分析。该研究涉及检查速度梯度、流向平均速度和湍流强度。结果表明,仿生凹槽结构有效地减轻了粘性应力和雷诺应力,进而降低了摩擦阻力。这种阻力的降低归因于非光滑表面引起的流动行为的改变。该研究通过模仿虎鲸皮肤的脊状结构提出了一种航运业减阻的新方法。垂直于流动方向排列的横向仿生凹槽表面在各种流动条件下都显示出有希望的减阻效果。通过系统的数值模拟和关键参数分析,该研究深入了解了减阻机制,并确定了凹槽表面的最佳设计参数。海上运输中显著节能和提高燃油效率的潜力突出了这项研究的实际意义。

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Bioinspired surfaces with special micro-structures and wettability for drag reduction: which surface design will be a better choice?具有特殊微观结构和润湿性的仿生物表面用于减阻:哪种表面设计是更好的选择?
Nanoscale. 2021 Feb 18;13(6):3463-3482. doi: 10.1039/d0nr07664c.
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Aquatic animal colors and skin temperature: Biology's selection for reducing oceanic dolphin's skin friction drag.
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J Therm Biol. 2019 Aug;84:292-310. doi: 10.1016/j.jtherbio.2019.07.018. Epub 2019 Jul 15.
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How smooth is a dolphin? The ridged skin of odontocetes.海豚有多光滑?齿鲸的有脊皮肤。
Biol Lett. 2019 Jul 26;15(7):20190103. doi: 10.1098/rsbl.2019.0103. Epub 2019 Jul 17.
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Shark skin-inspired designs that improve aerodynamic performance.鲨鱼皮启发式设计,提升空气动力学性能。
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