%0 Journal Article %1 citeulike:9051956 %A Liu, Shijie %A Masliyah, Jacob H. %D 1993 %J Journal of Fluid Mechanics %K 76d05-incompressible-navier-stokes-equations %P 315--353 %R 10.1017/s002211209300343x %T Axially Invariant Laminar Flow in Helical Pipes with a Finite Pitch %U http://dx.doi.org/10.1017/s002211209300343x %V 251 %X Steady axially invariant (fully developed) incompressible laminar flow of a Newtonian fluid in helical pipes of constant circular cross-section with arbitrary pitch and arbitrary radius of coil is studied. A loose-coiling analysis leads to two dominant parameters, namely Dean number, Dn = Reλ&half;, and Germano number, Gn = Reη, where Re is the Reynolds number, λ is the normalized curvature ratio and η is the normalized torsion. The Germano number is embedded in the body-centred azimuthal velocity which appears as a group in the governing equations. When studying Gn effects on the helical flow in terms of the secondary flow pattern or the secondary flow structure viewed in the generic (non-orthogonal) coordinate system of large Dn, a third dimensionless group emerges, γ = η&sol;(λDn)&half;. For Dn 0.039 for Dn 0.2 for Dn ≥ 20. For flows with fixed high Dean number and A, increasing the torsion has the effect of changing the relative position of the secondary flow vortices and the eventual formation of a flow having a Poiseuille-type axial velocity with a superimposed swirling flow. In the orthogonal coordinate system, however, the secondary flow generally has two vortices with sources and sinks. In the small-γ limit or when Dn is very small, the secondary flow is of the usual two-vortex type when viewed in the orthogonal coordinate system. In the large-γ limit, the appearance of the secondary flow in the orthogonal coordinate system is also two-vortex like but its orientation is inclined towards the upper wall. The flow friction factor is correlated to account for Dn, A and γ effects for Dn ≤ 5000 and γ < 0.1.

@article{citeulike:9051956, abstract = {{Steady axially invariant (fully developed) incompressible laminar flow of a Newtonian fluid in helical pipes of constant circular cross-section with arbitrary pitch and arbitrary radius of coil is studied. A loose-coiling analysis leads to two dominant parameters, namely Dean number, Dn = Reλ\&half;, and Germano number, Gn = Reη, where Re is the Reynolds number, λ is the normalized curvature ratio and η is the normalized torsion. The Germano number is embedded in the body-centred azimuthal velocity which appears as a group in the governing equations. When studying Gn effects on the helical flow in terms of the secondary flow pattern or the secondary flow structure viewed in the generic (non-orthogonal) coordinate system of large Dn, a third dimensionless group emerges, γ = η\&sol;(λDn)\&half;. For Dn 0.039 for Dn 0.2 for Dn ≥ 20. For flows with fixed high Dean number and A, increasing the torsion has the effect of changing the relative position of the secondary flow vortices and the eventual formation of a flow having a Poiseuille-type axial velocity with a superimposed swirling flow. In the orthogonal coordinate system, however, the secondary flow generally has two vortices with sources and sinks. In the small-γ limit or when Dn is very small, the secondary flow is of the usual two-vortex type when viewed in the orthogonal coordinate system. In the large-γ limit, the appearance of the secondary flow in the orthogonal coordinate system is also two-vortex like but its orientation is inclined towards the upper wall. The flow friction factor is correlated to account for Dn, A and γ effects for Dn ≤ 5000 and γ < 0.1.}}, added-at = {2017-06-29T07:13:07.000+0200}, author = {Liu, Shijie and Masliyah, Jacob H.}, biburl = {https://www.bibsonomy.org/bibtex/2c1a792b58348abb41af6bab9ce4da6df/gdmcbain}, citeulike-article-id = {9051956}, citeulike-linkout-0 = {http://journals.cambridge.org/action/displayAbstract?fromPage=online\&aid=349716}, citeulike-linkout-1 = {http://dx.doi.org/10.1017/s002211209300343x}, comment = {(private-note)cited by Roberts (2004)}, doi = {10.1017/s002211209300343x}, interhash = {6be54ba049c245e4db8d54c78c543f06}, intrahash = {c1a792b58348abb41af6bab9ce4da6df}, journal = {Journal of Fluid Mechanics}, keywords = {76d05-incompressible-navier-stokes-equations}, pages = {315--353}, posted-at = {2011-03-24 02:42:24}, priority = {2}, timestamp = {2017-06-29T07:13:07.000+0200}, title = {{Axially Invariant Laminar Flow in Helical Pipes with a Finite Pitch}}, url = {http://dx.doi.org/10.1017/s002211209300343x}, volume = 251, year = 1993 }