Erosion of surfaces by trapped vortices

IF 1.4 4区 工程技术 Q2 ENGINEERING, MULTIDISCIPLINARY Journal of Engineering Mathematics Pub Date : 2024-09-13 DOI:10.1007/s10665-024-10396-6
Courteney Hirst, N. R. McDonald
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Abstract

Two two-dimensional free boundary problems describing the erosion of solid surfaces by the flow of inviscid fluid in the presence of trapped vortices are considered. The first problem tackles an initially flat, infinite fluid-solid interface with uniform flow at infinity and a vortex in equilibrium above the surface. The second involves flow around a finite body with a trailing Föppl-type vortex pair. The conformal invariance of the complex potential permits both problems to be formulated as a Polubarinova–Galin (PG) type equation in which the time-dependent eroding surface in the physical z-plane is mapped to the fixed boundary of the \(\zeta \)-disk. The Hamiltonian governing the equilibrium position of the vortex (or vortex pair in the second problem) is also found from the same map. In each problem, the PG equation giving the conformal map is found numerically and the time-dependent evolution of the interface and vortex location is determined. Different models governing the erosion of the interface are investigated in which the normal velocity of the boundary depends on some given function of the fluid flow velocity at the boundary. Typically, in the infinite surface case, erosion leads to the formation of a symmetric valley beneath the vortex which, in turn, moves downward toward the interface. A finite body undergoes erosion which is asymmetric in the flow direction leading to a flattening of the lee surface of the body so displaying some similarity to the experiments and associated viscous theory of Ristroph et al, Moore et al (Proc Natl Acad Sci 109(48):19606–19609, 2012, Phys Fluids 25(11):116602, 2013).

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被困涡流对表面的侵蚀
本研究考虑了两个二维自由边界问题,描述了在存在被困旋涡的情况下,不粘性流体的流动对固体表面的侵蚀。第一个问题涉及一个初始平坦的无限流固界面,该界面在无穷远处有均匀流动,表面上方有一个处于平衡状态的漩涡。第二个问题涉及一个有限体周围的流动,该有限体上有一个拖尾的 Föppl 型涡对。复势的保角不变性使得这两个问题都可以表述为波鲁巴里诺娃-加林(PG)型方程,其中物理z平面上与时间相关的侵蚀表面被映射到(\zeta \)盘的固定边界上。支配涡旋(或第二个问题中的涡旋对)平衡位置的哈密顿也是从同一映射中找到的。在每个问题中,给出保角图的 PG 方程都是数值求得的,界面和涡旋位置随时间的演变也是确定的。研究了控制界面侵蚀的不同模型,其中边界的法向速度取决于边界流体流速的给定函数。通常情况下,在无限表面的情况下,侵蚀会导致在涡旋下方形成一个对称的山谷,而涡旋又会向界面下方移动。有限体受到的侵蚀在流动方向上是不对称的,导致体的倾斜面变平,因此与 Ristroph 等人和 Moore 等人的实验和相关粘性理论(Proc Natl Acad Sci 109(48):19606-19609, 2012, Phys Fluids 25(11):116602, 2013)有一定的相似性。
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来源期刊
Journal of Engineering Mathematics
Journal of Engineering Mathematics 工程技术-工程:综合
CiteScore
2.10
自引率
7.70%
发文量
44
审稿时长
6 months
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