Numerical study of parameters affecting pressure drop of power-law fluid in horizontal annulus for laminar and turbulent flow
Type : Publication
Auteur(s) : , , ,
Année : 2019
Domaine : Génie mécanique
Revue : Journal of Petroleum Exploration and Production Technology
Résumé en PDF :
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Mots clés : Computational fluid dynamics (CFD) · Power-law fluid · Pressure drop · Secondary flow
Auteur(s) : , , ,
Année : 2019
Domaine : Génie mécanique
Revue : Journal of Petroleum Exploration and Production Technology
Résumé en PDF :
Fulltext en PDF :
Mots clés : Computational fluid dynamics (CFD) · Power-law fluid · Pressure drop · Secondary flow
Résumé :
Efficient hydraulics program of oil and gas wells has a crucial role for the optimization of drilling process. In the presentpaper, a numerical study of power-law fluid flow through concentric (E = 0.0) and eccentric annulus (E = 0.3, E = 0.6 andE = 0.9) was performed for both laminar and turbulent flow regimes utilizing a finite volume method. The effects of innerpipe rotation, flow behavior index and diameter ratio on the pressure drop were studied; furthermore, the appearance anddevelopment of secondary flow as well as its impact on the pressure drop gradient were evaluated. Results indicated thatthe increment of the inner pipe rotation from 0 to 400 rpm is found to decrease pressure drop gradient for laminar flow inconcentric annulus while a negligible effect is observed for turbulent flow. The beginning of secondary flow formation in thewide region part of the eccentric annulus (E = 0.6) induces an increase of 9% and a slight increase in pressure drop gradientfor laminar and turbulent flow, respectively. On the other hand, the variation of the flow behavior index and diameter ratiofrom low to high values caused a dramatic increase in the pressure drop. Streamlines in the annulus showed that the secondary flow is mainly induced by eccentricity of the inner pipe where both high values of diameter ratio and low values of flowbehavior index tend to prevent the secondary flow to appear.