{"title":"Study on the Karman gait kinematics of an airfoil in an asymmetrical vortex street","authors":"Wenbo Wu, Runpeng Gu, Zhongming Hu, Yuankun Sun","doi":"10.1063/5.0228852","DOIUrl":null,"url":null,"abstract":"To understand fish swimming behavior in unsteady flows, this paper introduces the Kármán gait model to numerically investigate the hydrodynamics of fish-like swimming in an asymmetric vortex environment, specifically the P + S mode (a pair of vortices are shed from one side of the cylinder and a single vortex from the other side during one oscillation period) created by an oscillating cylinder. The immersed boundary method is employed to model both the fish-like airfoil and the vibrating cylinder. Through simulations across a broad range of controlling parameters, we analyze the advancement efficiency of the airfoil in the P + S mode, the force coefficients, Fourier spectra of hydrodynamic forces, and the interactions between the airfoil and vortices. Our findings reveal that the fundamental phase Φ0 is crucial, as it directly influences the airfoil's position relative to the vortex and affects the forces exerted. Other parameters play a secondary role, primarily reinforcing the effect of the fundamental phase on airfoil–vortex interactions. Furthermore, the vortex pair boosting effect, unique to the P + S mode, enhances the airfoil's thrust and swimming efficiency. The wake environment behind the airfoil is also vital for maximizing benefits from the P + S mode. When the fundamental mode fs, indicative of the airfoil's ability to extract energy from vortices, dominates the Fourier spectra of hydrodynamic forces, it supports the airfoil's motion in the P + S mode. Conversely, when the first harmonic mode 2fs dominates the drag spectrum, it hinders propulsion by reducing the airfoil's thrust in the swimming direction.","PeriodicalId":20066,"journal":{"name":"Physics of Fluids","volume":"1 1","pages":""},"PeriodicalIF":4.1000,"publicationDate":"2024-09-18","publicationTypes":"Journal Article","fieldsOfStudy":null,"isOpenAccess":false,"openAccessPdf":"","citationCount":"0","resultStr":null,"platform":"Semanticscholar","paperid":null,"PeriodicalName":"Physics of Fluids","FirstCategoryId":"5","ListUrlMain":"https://doi.org/10.1063/5.0228852","RegionNum":2,"RegionCategory":"工程技术","ArticlePicture":[],"TitleCN":null,"AbstractTextCN":null,"PMCID":null,"EPubDate":"","PubModel":"","JCR":"Q1","JCRName":"MECHANICS","Score":null,"Total":0}
引用次数: 0
Abstract
To understand fish swimming behavior in unsteady flows, this paper introduces the Kármán gait model to numerically investigate the hydrodynamics of fish-like swimming in an asymmetric vortex environment, specifically the P + S mode (a pair of vortices are shed from one side of the cylinder and a single vortex from the other side during one oscillation period) created by an oscillating cylinder. The immersed boundary method is employed to model both the fish-like airfoil and the vibrating cylinder. Through simulations across a broad range of controlling parameters, we analyze the advancement efficiency of the airfoil in the P + S mode, the force coefficients, Fourier spectra of hydrodynamic forces, and the interactions between the airfoil and vortices. Our findings reveal that the fundamental phase Φ0 is crucial, as it directly influences the airfoil's position relative to the vortex and affects the forces exerted. Other parameters play a secondary role, primarily reinforcing the effect of the fundamental phase on airfoil–vortex interactions. Furthermore, the vortex pair boosting effect, unique to the P + S mode, enhances the airfoil's thrust and swimming efficiency. The wake environment behind the airfoil is also vital for maximizing benefits from the P + S mode. When the fundamental mode fs, indicative of the airfoil's ability to extract energy from vortices, dominates the Fourier spectra of hydrodynamic forces, it supports the airfoil's motion in the P + S mode. Conversely, when the first harmonic mode 2fs dominates the drag spectrum, it hinders propulsion by reducing the airfoil's thrust in the swimming direction.
为了理解鱼类在非稳定流中的游动行为,本文引入了卡尔曼步态模型,对鱼类在非对称漩涡环境中游动的流体力学进行数值研究,特别是由振动圆柱体产生的 P + S 模式(在一个振动周期内,一对漩涡从圆柱体的一侧流出,另一个漩涡从另一侧流出)。采用沉浸边界法对鱼形机翼和振动圆柱体进行建模。通过在广泛的控制参数范围内进行模拟,我们分析了机翼在 P + S 模式下的推进效率、力系数、流体动力的傅里叶频谱以及机翼和涡流之间的相互作用。我们的研究结果表明,基本相位Φ0 至关重要,因为它直接影响机翼相对于涡旋的位置,并影响施加的力。其他参数起次要作用,主要是加强基本相位对机翼与涡旋相互作用的影响。此外,P + S 模式特有的涡对助推效应增强了机翼的推力和游动效率。机翼后的尾流环境对于最大限度地发挥 P + S 模式的优势也至关重要。当基本模式 fs(表明机翼从涡流中提取能量的能力)在流体动力的傅里叶频谱中占主导地位时,它将支持机翼在 P + S 模式下的运动。相反,当第一次谐波模式 2fs 在阻力谱中占主导地位时,则会减少机翼在游动方向上的推力,从而阻碍推进力。
期刊介绍:
Physics of Fluids (PoF) is a preeminent journal devoted to publishing original theoretical, computational, and experimental contributions to the understanding of the dynamics of gases, liquids, and complex or multiphase fluids. Topics published in PoF are diverse and reflect the most important subjects in fluid dynamics, including, but not limited to:
-Acoustics
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-Biofluid mechanics
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-Combustion flows
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-Compressible flow
-Computational fluid dynamics
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-Continuum mechanics
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-Droplets
-Electrical and magnetic effects in fluid flow
-Foam, bubble, and film mechanics
-Flow control
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-Flow orientation and anisotropy
-Flows with other transport phenomena
-Flows with complex boundary conditions
-Flow visualization
-Fluid mechanics
-Fluid physical properties
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-Free surface flows
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-Mathematics of fluids
-Micro- and nanofluid mechanics
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-Processing flows
-Relativistic fluid mechanics
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-Thermodynamics of flow systems
-Transonic flow
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-Viscous and non-Newtonian flow
-Viscoelasticity
-Vortex dynamics
-Waves