Abstract
We present an asymptotic theory for analytical characterization of the high-Reynolds-number incompressible flow of a Newtonian fluid past a shear-free circular cylinder. The viscosity-induced modifications to this flow are localized and except in the neighbourhood of the rear stagnation point, behave like a linear perturbation of the inviscid flow. Our theory gives a highly accurate description of these modifications by including the contribution from the most significant viscous term in a correctional perturbation expansion about an inviscid base state. We derive the boundary layer equation for the flow and deduce a similarity transformation that leads to a set of infinite, shear-free-condition-incompatible, self-similar solutions. By suitably combining members from this set, we construct an all-boundary-condition-compatible solution to the boundary layer equation. We derive the governing equation for vorticity transport through the narrow wake region and determine its closed-form solution. The near and far-field forms of our wake solution are desirably consistent with the boundary layer solution and the well-known, self-similar planar wake solution, respectively. We analyse the flow in the rear stagnation region by formulating an elliptic partial integro-differential equation for the distortion streamfunction that specifically accounts for the fully nonlinear and inviscid dynamics of the viscous correctional terms. The drag force and its atypical logarithmic dependence on Reynolds number, deduced from our matched asymptotic analysis, are in remarkable agreement with the high-resolution simulation results. The logarithmic dependence gives rise to a critical Reynolds number below which the viscous correction term, counterintuitively, reduces the net dissipation in the flow field.
Highlights
Fluid flows over sheer-free surfaces are radically distinct from those over which the relative motion between the fluid and the adjoining surface is forbidden by a no-slip condition
We developed an asymptotic theory for the high-Reynolds-number flow past a shear-free circular cylinder
The simplest predictive theory for this flow, namely the classical irrotational potential flow theory, suffers from D’Alembert’s paradox as it predicts a fore-aft symmetric stress field for which the hydrodynamic resistance experienced by the shear-free cylinder must necessarily vanish. Attributing this paradoxical conclusion to a violation of the perfect slip boundary condition on the shear-free cylinder surface, we introduced viscous correctional terms to the irrotational potential flow that account for both the finite vorticity production over the shear-free cylinder surface and its highly efficient convection into the wake region
Summary
Fluid flows over sheer-free surfaces are radically distinct from those over which the relative motion between the fluid and the adjoining surface is forbidden by a no-slip condition. Our analysis relies on an asymptotic expansion about an inviscid, irrotational base state that follows from the potential flow theory This frictionless base state violates the shear-free boundary condition over a non-planar perfectly slipping surface at any finite Reynolds number. To examine the high-Reynolds-number boundary layer characteristics over a spherical shear-free surface, Moore (1963) developed an axisymmetric, asymptotic expansion about an inviscid base state that is given by potential flow theory. Simplifications are direct consequences of the formation of a relatively weak boundary layer over the shear-free surface Despite this apparent similarity in the analysis, numerous crucial differences do arise between axisymmetric spherical configuration considered by Moore (1963) and the cylindrical configuration analysed in our work.
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