Nonlinear Flow Behavior in Packed Beds of Natural and Variably Graded Granular Materials

Lopik, Jan H. van; Zazai, L.; Hartog, Niels; Schotting, R. J.

doi:10.1007/s11242-019-01373-0

Cited by 17 publications

(21 citation statements)

References 56 publications

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“…Particularly for the determination of the performance and the capacity of production wells and injection wells, i.e. in the petroleum industry (Huang and Ayoub 2008;Barree and Conway 2004), in groundwater wells utilized for domestic and irrigational purposes (Houben et al 2018;Wen et al 2011;van Lopik et al 2019), and for groundwater heat pump applications (Gjengedal et al 2021).…”

Section: Introductionmentioning

confidence: 99%

Convective Acceleration in Porous Media

Gjengedal

2022

Transp Porous Med

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Convective acceleration occurs in porous media flows due to the spatial variations of the nonuniform flow channel geometry of natural pores. This article demonstrates that the influence of convective acceleration in a nonuniform a pore channel is analogous to that of a constricting pipe channel. Their fluid mechanical behaviour can be comparable, provided that their geometrical characteristics are described precisely in the same manner, and from the same point of reference with regards to the fluid velocity in the flow channels. The analogy of the dissipation mechanisms in nonlinear porous media flow to the "minor loss" approach in fluid mechanics of pipes is therefore appropriate. Conventional nonuniform pipe channel geometries obtain dissipation coefficients within the range 0 < CKL < 0.2. These pipe geometries are relevant reference points for natural porous media, and it is thus expected that most natural pore geometries will obtain values within this range. This assumption holds true for the nine different 3D porous media samples presented here. However, the results show that the rate of change in the pore geometry, and consequently the magnitude of induced convective acceleration, depends on: the area ratio a of the pore channel, the angle of approach θ and the rounding of the pore channel geometry. The rounding of the pore channel reduces the dissipation coefficient, as the rate of change becomes smoother along the channel length. The results also indicate that the pore tortuosity increase the magnitude of nonlinear dissipation, in good agreement with pipe flow behaviour. This knowledge can help improve our interpretation of experimental data and enhance the predictability of porous media equations that incorporate the appropriate dissipation coefficients CKL as a variable. Article Highlights The analogy of porous media flow to the "minor loss" approach in fluid mechanics of pipes is appropriate, and the angle of approach θ and the area ratio a of the pore channel govern the magnitude of induced convective acceleration in porous media The rounding of the pore channel geometry reduces the magnitude of induced convective acceleration The tortuosity of a pore influences the dissipation coefficient CKL and increase the magnitude of induced convective acceleration

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Section: Introductionmentioning

confidence: 99%

Convective Acceleration in Porous Media

Gjengedal

2022

Transp Porous Med

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“…The value of the kinetic constant B=δ/2π (λ=1 for packed conduits) in Quinn's Law, whereas it has the constant value of 1.75 in the Ergun equation. Figure 8, we have plotted the experimental results for 10 micron silica particles reported in the Farkas paper after the Q-modified Ergun equation (10). Note that in this straight line plot the intercept represents the value of A and the slope the value of B.…”

Section: Modeling Our Results After Ergunmentioning

confidence: 99%

“…In order to underscore the importance of our experimental protocol disclosed herein and to distinguish it from that used generally in the literature, we now focus on a worked example from a recent publication in the literature of a wellknown author of packed conduits, J. H. Van Lopik et al [9,10]. In both these papers, the authors are focused on the nonlinear flow behavior in packed conduits.…”

Section: A Worked Example From the Literaturementioning

confidence: 99%

Quinn’s Law of Fluid Dynamics: Supplement #2 Reinventing the Ergun Equation

Quinn¹

2020

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This paper is directed at the important contribution to fluid dynamics made by Sebri Ergun. In his three papers published in 1949, 1951 and 1952, using various gases as his percolating fluid, Ergun used his empirical permeability results of packing conduits with fractured coke (irregularly shaped particles), in combination with some theoretical concepts, to generate an equation which captured the viscous and kinetic contributions to packed conduit permeability in two separate terms in that equation, resulting in his now famous "Ergun Equation". In addition, he identified a discrete "constant" for each of the terms which we label herein the "viscous" and "kinetic" constants, respectively. We demonstrate herein, however, that the values assigned by Ergun to both his constants are not certifiable and, thus, are problematic in predicting the permeability of packed conduits. Moreover, since the publication of his 1952 paper, in which he disclosed the values of 150 and 1.75 for the viscous and kinetic constants, respectively, many scholarly works have been published which claim to validate these values. As a result, these values have become erroneously embedded in conventional folklore concerning fluid flow in closed conduits and have enjoyed widespread acceptance as being a legitimate feature of fluid dynamics dogma. With the advent recently of Quinn's Law, a novel approach to the understanding of fluid flow in closed conduits, we are able to articulate in a manner not heretofore possible, the significance of this discrepancy in Ergun's values of the constants, which we demonstrate is far too important to ignore.

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“…Applicability of this equation depends on the modelling accuracy of the Darcy and non-Darcy coefBcients. Extensive experimental studies have been reported in the literature on the behaviour of these coefBcients with different parameters such as media size (Huang et al 2013;Salahi et al 2015;van Lopik et al 2017), degree of packing (Boomsma and Poulikakos 2002;Dan et al 2016;Houben et al 2018), grain size distribution (van Lopik et al 2020), convergent angle (Thiruvengadam and Kumar 1997;Venkataraman and Rao 2000;Rao 2004, 2006;Pasupuleti et al 2014;, pore geometry (Macini et al 2011;Shao et al 2020) Reynolds number (Sidiropoulou et al 2007), maximum pore diameter (Huang et al 2020), etc.…”

Section: Introductionmentioning

confidence: 99%

Influence of fluid viscosity and flow transition over non-linear filtration through porous media

et al. 2021

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The present study investigates two important though relatively unexplored aspects of non-linear Bltration through porous media. The Brst aspect is the inCuence of viscosity variation over the coefBcients of the governing equations used for modelling non-linear Bltration through porous media. Velocity and hydraulic gradient data obtained for a wide range of Cuid viscosities (8.03E-07 to 3.72E-05 N/m 2 ) were studied. An increase in Cuid viscosity resulted in an increased pressure loss through packing which can be quantiBed using the coefBcients of the governing equations. CoefBcients of Forchheimer equation represent linearly increasing trend with the kinematic viscosity. On the other hand, coefBcient of Wilkins equation represents similar values for different Cuid viscosities and remained unaffected by the variation in packing properties. Obtained data were utilized to understand the nature of Cow transition in porous media. Behaviour of polynomial and Power-law coefBcient with variation in Cow velocity were also examined. Critical Reynolds number corresponding to the deviation of Cow from Darcy regime varies with the porous packing and was observed to be in the range of 0-100. CoefBcients of polynomial (Forchheimer) model were observed to be independent of the range of Cow velocity, whereas the Power law coefBcients are extremely sensitive to the data.

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Nonlinear Flow Behavior in Packed Beds of Natural and Variably Graded Granular Materials

Cited by 17 publications

References 56 publications

Convective Acceleration in Porous Media

Convective Acceleration in Porous Media

Quinn’s Law of Fluid Dynamics: Supplement #2 Reinventing the Ergun Equation

Influence of fluid viscosity and flow transition over non-linear filtration through porous media

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