Early- and late-time prediction of counter-current spontaneous imbibition, scaling analysis and estimation of the capillary diffusion coefficient
Abstract
Solutions are investigated for 1D linear counter-current spontaneous imbibition (COUSI). The diffusion problem is scaled to depend only on a normalized coefficient n (Sn ) with mean 1 and no other parameters. A dataset of 5500 functions n was generated using combinations of (mixed-wet and strongly water-wet) relative permeabilities, capillary pressure and mobility ratios. Since the possible variation in n appears limited (mean 1, positive, zero at Sn=0, one maximum) the generated functions span most relevant cases. The scaled diffusion equation was solved for all 5500 cases and recovery profiles were analyzed in terms of time scales and early- and late time behavior. Scaled recovery falls exactly on the square root curve RF=Tn0.5 at early time. The scaled time Tn=t/τTch accounts for system length L and magnitude D of the unscaled diffusion coefficient via τ=L2/D, and Tch accounts for n. Scaled recovery was characterized by RFtr (highest recovery reached as Tn0.5) and lr, a parameter controlling the decline in imbibition rate afterwards. This correlation described the 5500 recovery curves with mean R2=0.9989. RFtr was 0.05 to 0.2 units higher than recovery when water reached the no-flow boundary. The shape of n was quantified by three fractions z(a,b). The parameters describing n and recovery were correlated which permitted to (1) accurately predict full recovery profiles (without solving the diffusion equation); (2) predict diffusion coefficients explaining experimental recovery; (3) explain the combined impact of interactions between wettability / saturation functions, viscosities and other input on early- and late time recovery behavior.
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