Turbulent pipe flow of dilute polymer solutions
TLDR
In this article, the authors present a list of the most cited works in the field of chemistry and physics of carbon, including the work of M. Dubinin, M. M. and V. A. Romankov.Abstract:
Literature Cited 1) Astakhov, V.A., M. M. Dubinin and P. G. Romankov: Theor. Osn. Khim. Techn., 3, 292 (1969) 2) Dubinin, M. M.: Chem. Rev., 60, 235 (1960) 3) Dubinin, M. M. : \"Chemistry and Physics of Carbon\", Vol. 2 (P. L. Walker ed.) p. 51, Marcel Dekker (1966) 4) Dubinin, M. M.: \"Adsorption-Desorption Phenomena\" (Ricca ed.), p. 3, Academic Press (1972) 5) Dubinin, M. M. and V. A. Astakhov: \"Molecular Sieve Zeolites II\", Adv. Ser. 102, p 69 (1971) 6) Eguchi, Y.: Kagaku Kojo, 13, No. 9, 45 (1969) 7) Eguchi, Y.: /. Japan Petrol Inst., 13, 106 (1970) 8) Kawazoe, K., Y. A. Astakhov, T. Kawai and Y. Eguchi: Kagaku Kogaku, 35, 1006 (1971) 9) Kawazoe, K. and T. Kawai: Seisan Kenkyu, 25, 513 (1973)read more
Citations
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Book ChapterDOI
Non-Newtonian Fluids in Circular Pipe Flow
Young I. Cho,James P. Harnett +1 more
TL;DR: In this paper, the heat transfer behavior of viscoelastic fluid in turbulent pipe flow is investigated analytically, and the usual and simplest method is to solve the uncoupled energy equation using the empirically determined velocity profile.
Journal ArticleDOI
Turbulent pipe flow predictions with a low Reynolds number k–ε model for drag reducing fluids
D. O. A. Cruz,Fernando T. Pinho +1 more
TL;DR: In this article, a low Reynolds number k-e turbulence model is developed for predicting turbulent wall flows of viscoelastic fluids, and a new damping function is introduced to account for near-wall effects.
Journal ArticleDOI
A GNF framework for turbulent flow models of drag reducing fluids and proposal for a k–ε type closure
TL;DR: In this paper, a closed model for the time-average viscosity is proposed that takes into account its nonlinearity and dependence on the second and third invariants of the fluctuating rate of deformation tensor.
Journal ArticleDOI
On pipe diameter effects in surfactant drag-reducing pipe flows
TL;DR: In this article, a turbulent eddy diffusivity model based on the Maxwell model was employed to estimate the drag reduction of surfactant solutions, which has resulted in a reliable estimation of the pipe diameter effect in surfactants over pipe diameter range from 11 to 150mm.
Journal ArticleDOI
A Reynolds stress model for turbulent flows of viscoelastic fluids
TL;DR: In this paper, a second-order closure is developed for predicting turbulent flows of viscoelastic fluids described by a modified generalised Newtonian fluid model incorporating a nonlinear viscosity that depends on a strain-hardening Trouton ratio as a means to handle some of the effects of viscocelasticity upon turbulent flows.
References
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Book ChapterDOI
Viscous Drag Reduction Examined in the Light of a New Model of Wall Turbulence
TL;DR: In this paper, the effect of soluble polymer additives on the structure of wall turbulence is examined in the light of a new theoretical model, and explained in terms of the ability of the polymer macromolecules to substantially increase the hydrodynamic stability of the viscous sublayer flow.
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Turbulent pipe flow predictions with a low Reynolds number k–ε model for drag reducing fluids
D. O. A. Cruz,Fernando T. Pinho +1 more