A Rayleigh--Ritz method for Navier--Stokes flow through curved ducts

We present a Rayleigh–Ritz method for the approximation of fluid flow in a curved duct, including the secondary cross-flow, which is well known to develop for nonzero Dean numbers. Having a straightforward method to estimate the cross-flow for ducts with a variety of cross-sectional shapes is important for many applications. One particular example is in microfluidics where curved ducts with low aspect ratio are common, and there is an increasing interest in nonrectangular duct shapes for the purpose of size-based cell separation. We describe functionals which are minimized by the axial flow velocity and cross-flow stream function which solve an expansion of the Navier–Stokes model of the flow. A Rayleigh–Ritz method is then obtained by computing the coefficients of an appropriate polynomial basis, taking into account the duct shape, such that the corresponding functionals are stationary. Whilst the method itself is quite general, we describe an implementation for a particular family of duct shapes in which the top and bottom walls are described by a polynomial with respect to the lateral coordinate. Solutions for a rectangular duct and two nonstandard duct shapes are examined in detail. A comparison with solutions obtained using a finite-element method demonstrates the rate of convergence with respect to the size of the basis. An implementation for circular cross-sections is also described, and results are found to be consistent with previous studies.

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Bifurcation in steady laminar flow through curved tubes

Journal of Fluid Mechanics ◽

10.1017/s002211208200144x ◽

1982 ◽

Vol 119 ◽

pp. 475-490 ◽

Cited By ~ 73

Author(s):

K. Nandakumar ◽

Jacob H. Masliyah

Keyword(s):

Stokes Equations ◽

Outer Wall ◽

Dual Solutions ◽

Navier Stokes ◽

Dean Number ◽

Navier Stokes Equations ◽

Vortex Solution ◽

Duct Geometry ◽

Flow Through ◽

Curved Ducts

The occurrence of dual solutions in curved ducts is investigated through a numerical solution of the Navier-Stokes equations in a bipolar-toroidal co-ordinate system. With the shape of duct being the region formed by the natural co-ordinate surfaces, it was possible to alter the duct geometry gradually and preserve the prevailing form of the velocity field, in a manner suggested by Benjamin (1978).In addition to the Dean number Dn = Re/Rc½, a geometrical parameter that defines the shape of the duct was also varied systematically to study the bifurcation of a two-vortex solution into a two- and four-vortex solution. Dual solutions have been found for all geometrical shapes investigated here. Of particular interest are the shapes of a full circle and a semicircle with a curved outer wall.

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Adaptive Navier Stokes Flow Solver for Aerospace Structures

10.21236/ada424479 ◽

2004 ◽

Author(s):

R. P. Selvam ◽

Zu-Qing Qu

Keyword(s):

Stokes Flow ◽

Navier Stokes ◽

Aerospace Structures ◽

Flow Solver

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Transient Pressure-Driven Electroosmotic Flow through Elliptic Cross-Sectional Microchannels with Various Eccentricities

Computation ◽

10.3390/computation9030027 ◽

2021 ◽

Vol 9 (3) ◽

pp. 27

Author(s):

Nattakarn Numpanviwat ◽

Pearanat Chuchard

Keyword(s):

Laplace Transform ◽

Electroosmotic Flow ◽

Stokes Equations ◽

Navier Stokes ◽

Mathieu Functions ◽

Navier Stokes Equations ◽

Flow Rates ◽

Elliptic Cross ◽

Flow Through ◽

Relative Errors

The semi-analytical solution for transient electroosmotic flow through elliptic cylindrical microchannels is derived from the Navier-Stokes equations using the Laplace transform. The electroosmotic force expressed by the linearized Poisson-Boltzmann equation is considered the external force in the Navier-Stokes equations. The velocity field solution is obtained in the form of the Mathieu and modified Mathieu functions and it is capable of describing the flow behavior in the system when the boundary condition is either constant or varied. The fluid velocity is calculated numerically using the inverse Laplace transform in order to describe the transient behavior. Moreover, the flow rates and the relative errors on the flow rates are presented to investigate the effect of eccentricity of the elliptic cross-section. The investigation shows that, when the area of the channel cross-sections is fixed, the relative errors are less than 1% if the eccentricity is not greater than 0.5. As a result, an elliptic channel with the eccentricity not greater than 0.5 can be assumed to be circular when the solution is written in the form of trigonometric functions in order to avoid the difficulty in computing the Mathieu and modified Mathieu functions.

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The Differentiability of the Drag with Respect to the Variations of a Lipschitz Domain in a Navier--Stokes Flow

SIAM Journal on Control and Optimization ◽

10.1137/s0363012994278213 ◽

1997 ◽

Vol 35 (2) ◽

pp. 626-640 ◽

Cited By ~ 45

Author(s):

Juan Antonio Bello ◽

Enrique Fernández-Cara ◽

Jérôme Lemoine ◽

Jacques Simon

Keyword(s):

Stokes Flow ◽

Lipschitz Domain ◽

Navier Stokes

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On LES Methods Applied to Seal Geometries

Volume 8: Turbomachinery, Parts A, B, and C ◽

10.1115/gt2012-68840 ◽

2012 ◽

Cited By ~ 2

Author(s):

James Tyacke ◽

Richard Jefferson-Loveday ◽

Paul Tucker

Keyword(s):

Maximum Error ◽

Labyrinth Seal ◽

Navier Stokes ◽

Final Solution ◽

Complex Flow ◽

Eddy Simulation ◽

Wide Range ◽

Large Eddy ◽

Rans Models ◽

Flow Through

Nine Large Eddy Simulation (LES) methods are used to simulate flow through two labyrinth seal geometries and are compared with a wide range of Reynolds-Averaged Navier-Stokes (RANS) solutions. These involve one-equation, two-equation and Reynolds Stress RANS models. Also applied are linear and nonlinear pure LES models, hybrid RANS-Numerical-LES (RANS-NLES) and Numerical-LES (NLES). RANS is found to have a maximum error and a scatter of 20%. A similar level of scatter is also found among the same turbulence model implemented in different codes. In a design context, this makes RANS unusable as a final solution. Results show that LES and RANS-NLES is capable of accurately predicting flow behaviour of two seals with a scatter of less than 5%. The complex flow physics gives rise to both laminar and turbulent zones making most LES models inappropriate. Nonetheless, this is found to have minimal tangible results impact. In accord with experimental observations, the ability of LES to find multiple solutions due to solution non-uniqueness is also observed.

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