Abstract
Both in rheometry and in fundamental fluid mechanics studies, the Taylor–Couette geometry is used frequently to investigate viscoelastic fluids. In order to ensure a constant shear rate in the gap between the inner and outer cylinders, such studies are usually restricted to the small-gap limit where the assumption of a linear velocity distribution is well justified. In conjunction with a sufficiently large aspect ratio$\unicode[STIX]{x1D6EC}$(i.e. ratio of cylinder height to gap), the flow is then assumed to be viscometric. Here we demonstrate, using a perturbation technique with the curvature ratio (i.e. ratio of the half-gap to the mid-radius of the cylinders) as the perturbation parameter, full nonlinear simulations using a finite-volume technique, and supporting experiments, that, even in the creeping-flow (inertialess) narrow-gap limit, for viscoelastic fluids end effects due to finite aspect ratio always give rise to a secondary motion. Using the constant-viscosity Oldroyd-B model we are able to show that this secondary motion, as has been observed in related pressure-driven flows with curvature, such as the viscoelastic Dean flow, is solely a consequence of the combination of gradients of the first normal-stress difference and curvature. Our results show that end effects can significantly change the flow characteristics, especially for small aspect ratios, and this may have important consequences in some situations such as the onset criteria for purely elastic instabilities.
Highlights
Beyond a critical flow rate such that the ratio of the inertial force to the viscous force is large enough, inertial instabilities can often be observed in Newtonian fluid flows
In this study we attempt to fill this gap by investigating finite end effects for the narrow-gap concentric-cylinder geometry under inertialess conditions for viscoelastic fluids using both an approximate analytical perturbation approach, full nonlinear simulations with the Oldroyd-B model and supporting experiments
According to the rectilinear flow theorem of viscoelastic fluids (Reiner 1945; Rivlin 1948; Rivlin & Ericksen 1955; Ericksen 1956; Green & Rivlin 1956; Rivlin 1957), this solution is valid for both Newtonian fluids and, due to its constant shear viscosity, the Oldroyd-B model
Summary
Beyond a critical flow rate such that the ratio of the inertial force to the viscous force is large enough, inertial instabilities can often be observed in Newtonian fluid flows. Fan, Tanner & Phan-Thien (2001), based on an order-of-magnitude analysis, derived an equation for the Oldroyd-B model in such curved pipe flows, showing a correlation between the so-called ‘hoop’ stress (the normal stress in the azimuthal direction) and centrifugal force They show that fluid inertia and hoop stress are two significant and competitive forces near the core region, which contribute to establishing a pressure gradient and the presence of secondary flow. Within a similar context, Robertson & Muller (1996) and Jitchote & Robertson (2000) captured combined effects of elastic force and centrifugal force in curved pipes In these papers, similar to the previous works by Dean (1927, 1928), a perturbation method was employed to show that, even in the absence of inertia, elastic normal stresses are able to create hoop stresses and generate secondary flows. In this study we attempt to fill this gap by investigating finite end effects for the narrow-gap concentric-cylinder geometry under inertialess conditions for viscoelastic fluids using both an approximate analytical perturbation approach, full nonlinear simulations with the Oldroyd-B model and supporting experiments
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