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Some numerical experiments on developing laminar flow in circular-sectioned bends

Published online by Cambridge University Press:  20 April 2006

J. A. C. Humphrey ,
H. Iacovides  and
B. E. Launder
J. A. C. Humphrey
Affiliation:
University of California, Berkeley, California
H. Iacovides
Affiliation:
UMIST, Manchester
B. E. Launder
Affiliation:
UMIST, Manchester
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Abstract

The paper reports numerical solutions to a semi-elliptic truncation of the Navier–Stokes equations for the case of developing laminar flow in circular-sectioned bends over a range of Dean numbers. The ratios of bend radius to pipe radius are 7:1 and 20:1, corresponding with the configurations examined experimentally by Talbot and his co-workers in recent years. The semi-elliptic treatment facilitates a much finer grid than has been possible in earlier studies. Numerical accuracy has been further improved by assuming radial equilibrium over a thin sublayer immediately adjacent to the wall and by re-formulating the boundary conditions at the pipe centre.

Streamwise velocity profiles at Dean numbers of 183 and 565 are in excellent agreement with laser-Doppler measurements by Agrawal, Talbot & Gong (1978). Good, albeit less complete, accord is found with the secondary velocities, though the differences that exist may be mainly due to the difficulty of making these measurements. The paper provides new information on the behaviour of the streamwise shear stress around the inner line of symmetry. Upstream of the point of minimum shear stress, our numerical predictions display a progressive shift towards the result of Stewartson, Cebici & Chang (1980) as the Dean number is successively raised. Downstream of the minimum, however, in contrast with the monotonic approach to an asymptotic level reported by Stewartson, the numerical solutions display a damped oscillatory behaviour reminiscent of those from Hawthorne's (1951) inviscid-flow calculations. The amplitude of the oscillation grows as the Dean number is raised.

Information

Type
Research Article
Information
Journal of Fluid Mechanics , Volume 154 , May 1985 , pp. 357 - 375
Copyright
© 1985 Cambridge University Press

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