On the ability of a Darcy-scale model to capture wormhole formation during the dissolution of a porous medium

F. GOLFIER; C. ZARCONE; B. BAZIN; R. LENORMAND; D. LASSEUX; M. QUINTARD

doi:10.1017/S0022112002007735

Abstract

Dissolution of a porous medium creates, under certain conditions, some highly conductive channels called wormholes. The mechanism of propagation is an unstable phenomenon depending on the microscopic properties at the pore scale and is controlled by the injection rate. The aim of this work is to test the ability of a Darcy-scale model to describe the different dissolution regimes and to characterize the influence of the flow parameters on the wormhole development. The numerical approach is validated by model experiments reflecting dissolution processes occurring during acid injection in limestone. Flow and transport macroscopic equations are written under the assumption of local mass non-equilibrium. The coupled system of equations is solved numerically in two dimensions using a finite volume method. Results are discussed in terms of wormhole propagation rate and pore volume injected.

Crossref Citations

This article has been cited by the following publications. This list is generated based on data provided by Crossref.

Panga, Mohan K. R. Ziauddin, Murtaza Gandikota, Ramakrishna and Balakotaiah, Vemuri 2004. A New Model for Predicting Wormhole Structure and Formation in Acid Stimulation of Carbonates.

Genthon, Pierre Bataille, Arnaud Fromant, André D'Hulst, Dominique and Bourges, Francois 2005. Temperature as a marker for karstic waters hydrodynamics. Inferences from 1 year recording at La Peyrére cave (Ariège, France). Journal of Hydrology, Vol. 311, Issue. 1-4, p. 157.

Panga, Mohan K. R. Ziauddin, Murtaza and Balakotaiah, Vemuri 2005. Two‐scale continuum model for simulation of wormholes in carbonate acidization. AIChE Journal, Vol. 51, Issue. 12, p. 3231.

Goldstein, R.J. Eckert, E.R.G. Ibele, W.E. Patankar, S.V. Simon, T.W. Kuehn, T.H. Strykowski, P.J. Tamma, K.K. Bar-Cohen, A. Heberlein, J.V.R. Davidson, J.H. Bischof, J. Kulacki, F.A. Kortshagen, U. Garrick, S. and Srinivasan, V. 2005. Heat transfer—a review of 2002 literature. International Journal of Heat and Mass Transfer, Vol. 48, Issue. 5, p. 819.

Monse, Karsten Koch, Markus and Walzel, Peter 2006. Migration der kontinuierlichen Phase beim Trocknen von Suspensionstropfen in einer Trocknungskammer. Chemie Ingenieur Technik, Vol. 78, Issue. 1-2, p. 78.

VERDON, JAMES and WOODS, ANDREW W. 2007. Gravity-driven reacting flows in a confined porous aquifer. Journal of Fluid Mechanics, Vol. 588, Issue. , p. 29.

Detwiler, Russell L. and Rajaram, Harihar 2007. Predicting dissolution patterns in variable aperture fractures: Evaluation of an enhanced depth‐averaged computational model. Water Resources Research, Vol. 43, Issue. 4,

Cohen, C. E. Ding, D. Bazin, B. and Quintard, M. 2007. A New Matrix-Acidizing Simulator Based on a Large-Scale Dual-Porosity Approach.

Ziauddin, Murtaza and Bize, Emmanuel 2007. The Effect of Pore-Scale Heterogeneities on Carbonate Stimulation Treatments.

Kalia, Nitika and Balakotaiah, Vemuri 2007. Modeling and analysis of wormhole formation in reactive dissolution of carbonate rocks. Chemical Engineering Science, Vol. 62, Issue. 4, p. 919.

Oltean, C. Golfier, F. and Buès, M.A. 2008. Experimental and numerical study of the validity of Hele–Shaw cell as analogue model for variable-density flow in homogeneous porous media. Advances in Water Resources, Vol. 31, Issue. 1, p. 82.

Genthon, P. and Ormond, A. 2008. Infiltrative instability near topography with implication for the drainage of soluble rocks. Hydrology and Earth System Sciences, Vol. 12, Issue. 6, p. 1285.

Cohen, Charles Edouard Ding, Didier Quintard, Michel and Bazin, Brigitte 2008. From pore scale to wellbore scale: Impact of geometry on wormhole growth in carbonate acidization. Chemical Engineering Science, Vol. 63, Issue. 12, p. 3088.

Kalia, Nitika and Glasbergen, Gerard 2009. Wormhole Formation in Carbonates Under Varying Temperature Conditions.

Golfier, Fabrice Wood, Brian D. Orgogozo, Laurent Quintard, Michel and Buès, Michel 2009. Biofilms in porous media: Development of macroscopic transport equations via volume averaging with closure for local mass equilibrium conditions. Advances in Water Resources, Vol. 32, Issue. 3, p. 463.

Szymczak, P. and Ladd, A. J. C. 2009. Wormhole formation in dissolving fractures. Journal of Geophysical Research: Solid Earth, Vol. 114, Issue. B6,

Glasbergen, Gerard Kalia, Nitika and Talbot, Malcolm 2009. The Optimum Injection Rate for Wormhole Propagation: Myth or Reality?.

Kalia, Nitika and Balakotaiah, Vemuri 2009. Effect of medium heterogeneities on reactive dissolution of carbonates. Chemical Engineering Science, Vol. 64, Issue. 2, p. 376.

Noiriel, Catherine Luquot, Linda Madé, Benoît Raimbault, Louis Gouze, Philippe and van der Lee, Jan 2009. Changes in reactive surface area during limestone dissolution: An experimental and modelling study. Chemical Geology, Vol. 265, Issue. 1-2, p. 160.

Szymczak, P. and Ladd, A.J.C. 2009. Comment on: “From pore scale to wellbore scale: Impact of geometry on wormhole growth in carbonate acidization by C.E. Cohen et al. [Chemical Engineering Science 63, 3088–3099, 2008]”. Chemical Engineering Science, Vol. 64, Issue. 12, p. 3029.

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On the ability of a Darcy-scale model to capture wormhole formation during the dissolution of a porous medium

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