New model for single spherical particle settling velocity in power law (visco-inelastic) fluids

Shah, Subhash; Fadili, Youness El; Chhabra, R.P.

doi:10.1016/j.ijmultiphaseflow.2006.06.006

Cited by 83 publications

(39 citation statements)

References 16 publications

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“…the steady state velocity reached by a particle falling freely in a liquid) can be found in several papers for different fluids [21,32]. In particular, Shah [33] proposed an estimation of the terminal velocity in power law fluids characterized by the following value of the (non linear) viscosity…”

Section: Computation Of the Drag Force F D I For Non-newtonian Fluidsmentioning

confidence: 99%

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A FEM-DEM technique for studying the motion of particles in non-Newtonian fluids. Application to the transport of drill cuttings in wellbores

et al. 2015

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We present a procedure for coupling the finite element method (FEM) and the discrete element method (DEM) for analysis of the motion of particles in non-Newtonian fluids. Particles are assumed to be spherical and immersed in the fluid mesh. A new method for computing the drag force on the particles in a non-Newtonian fluid is presented. A drag force correction for non-spherical particles is proposed. The FEM-DEM coupling procedure is explained for Eulerian and Lagrangian flows and the basic expressions of the discretized solution algorithm are given. The usefulness of the FEM-DEM technique is demonstrated in its application to the transport of drill cuttings in wellbores.

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Section: Computation Of the Drag Force F D I For Non-newtonian Fluidsmentioning

confidence: 99%

“…Compute the drag coefficient for spherical (ϕ = 1) and non-spherical (ϕ = 1) particles via Eqs. (33) or (34) using the Reynolds number of Eq.(29). 3.…”

Section: Accounting For the Effect Of The Non Sphericity Of The Partimentioning

confidence: 99%

A FEM-DEM technique for studying the motion of particles in non-Newtonian fluids. Application to the transport of drill cuttings in wellbores

et al. 2015

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“…There exists a wide range of opinions among investigators with respect to Power-law fluid applications and, unlike Newtonian fluids, there is no universally accepted general model for determining the settling velocities of spherical particles in Power law type fluids. Two different opinions prevail among researchers regarding the use of Newtonian drag curve for non-Newtonian fluid and on the dependency of drag coefficient on flow behavior index, n. Shah et al (2007), Dallon (1967), Prakash (1983, Reynolds and Jones (1989), Peden and Luo (1987), Koziol and Glowacki (1988), Machac et al (1995), Shah (1982, and Shah (1986) have all observed the strong dependency of drag coefficient on n. On the other hand, studies by Lali et al (1989), Chhabra (1990), Chhabra (2002), and Kelessidis (2004) have shown that the use of Newtonian drag curve for Power-law fluid yields equally good results.…”

Section: Introductionmentioning

confidence: 99%

“…Different concentrations of CMC-water mixtures (0.14-0.28 wt%) are used as test fluids for the experiments. A new empirical equation, which is an improved version of the Shah et al (2007) model, for predicting the settling velocity of a spherical particle in Power-law fluid is proposed. The new empirical model is found to give an average error of 10% in predicting the settling velocity.…”

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confidence: 99%

Experimental investigation of the settling velocity of spherical particles in Power-law fluids using particle image shadowgraph technique

Shahi

Kuru

2016

International Journal of Mineral Processing

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“…Curve-fitting models were previously derived for predicting proppant settling rates, including the effects of the particle concentration in the fluid and the relative size of the fracture width relative to the proppant diameter. For proppant settling in pipes and narrow slots, existing experimental correlations relate average slurry settling velocity to a single particle settling velocity based on particle concentrations assuming uniform spatial distribution in the fluid (Hannah and Harrington 1981;Harrington et al 1979;Novotny 1977;Shah 1982Shah , 1993Shah and Lee 1986;Shah and Lord 1990;Shah et al 2007). Particle agglomerations and irregular particle motions were previously observed in several experimental studies on flow of particle-fluid mixtures in pipes and slot flow apparatus.…”

Section: Introductionmentioning

confidence: 99%

Micromechanics of proppant agglomeration during settling in hydraulic fractures

Tomac

Gutierrez

2015

J Petrol Explor Prod Technol

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The micromechanics of proppant settling in quiescent fluid in a rough and relatively narrow rock fracture is investigated. The study focuses on particleparticle and particle-wall interactions in a dense-phase particle settling. The study used a coupled discrete element method and computational fluid dynamics (DEM-CFD) code because DEM-CFD is the most suitable computational method for modeling the frequent interactions of dense assembly of rigid particles and enables modeling of two-way solid-fluid interactions. Due to frequent particleparticle interactions of grains submerged in fluids, the particle interaction model in DEM is improved by the incorporation of the effects of lubrication due to a layer of fluid surrounding particles. Results of the numerical study are compared to previous experimental and theoretical relationships. The findings of the study highlight conditions that lead to proppant aggregation due to the fluid viscosity and fracture width in relation to particle diameter ratio. In the light of the DEM-CFD results, it was found that published relationships are inadequate in describing the settling rates for proppant in a rough and narrow hydraulic fracture and high fluid viscosity. Micromechanical particle interactions during settling and erratic upward and fluid counter-flow may cause proppant trajectories that are not always in the direction of gravity in a rough fracture resulting in clogging of the fracture or forming faster settling particle agglomerates. The maximum packing density 0.3-0.4 (3.9-5.9 lbs/gal) of proppant in a narrow and rough hydraulic fracture was obtained in this study, which is lower than the usually assumed one of 0.5 (9.8 lbs/gal) for any given fracture roughness.Keywords DEM-CFD Á Lubrication Á Fluid-solid coupling Á Dense-phase flow Á Proppant settling Á Hydraulic fracture List of symbols

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New model for single spherical particle settling velocity in power law (visco-inelastic) fluids

Cited by 83 publications

References 16 publications

A FEM-DEM technique for studying the motion of particles in non-Newtonian fluids. Application to the transport of drill cuttings in wellbores

A FEM-DEM technique for studying the motion of particles in non-Newtonian fluids. Application to the transport of drill cuttings in wellbores

Experimental investigation of the settling velocity of spherical particles in Power-law fluids using particle image shadowgraph technique

Micromechanics of proppant agglomeration during settling in hydraulic fractures

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