Analysis of the unsaturated hydraulic properties of rocks using multiple laboratory methods

Zhuang, Luwen; Hoerlle, Fernanda O.; Chen, Hao; Pontedeiro, Elizabeth M.; van Genuchten, Martinus Th.; Couto, Paulo; Qin, Chao-Zhong; Lin, Kairong

doi:10.2478/johh-2024-0012

Abstract

Proper characterization of the unsaturated hydraulic properties in rocks is significant for predicting fluid flow in soil, hydrogeologic, and petroleum science and engineering problems. In this study, we contributed rigorous analysis of the unsaturated hydraulic properties of three reservoir rock samples (Berea Sandstone, Guelph Dolomite, and Indiana Limestone). An improved version of the standard evaporation method (HYPROP) was developed to cater specifically to rock samples. The improved HYPROP setup enables measurements of local water pressures within rock samples without disturbing the upper portion of the samples. The obtained results were compared with those obtained using the conventional pressure plate method and a state-of-the-art nuclear magnetic resonance (NMR) method. Observed data were analyzed in terms of four different unimodal and bimodal hydraulic functions. The HYPROP data were found to be relatively close to the pressure plate data of two carbonate rocks. The NMR-based data were reasonably consistent with the HYPROP data, with differences likely due in part to the fact that they were obtained using two different 5-cm long plugs taken from the same core. Heterogeneity along the rock cores from which the samples were taken could be a major reason for the observed differences, and hence should be considered in reservoir analyses.

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Analysis of the unsaturated hydraulic properties of rocks using multiple laboratory methods

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