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Effect of connectivity and wettability on the relative permeability of NAPLs

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Environmental Geology

Abstract

The characteristic relationships among relative permeability (K r ), saturation (S) and capillary pressure (P) of NAPLs are the important constitutive laws to simulate the NAPLs flow in the subsurface. In this study, a micro model was used to obtain the values of permeability, saturation for the multi-phase flow of five fluid-pairs. The perspective micro model allows one to clearly observe the multiphase flow and allow this study to precisely measure the fluid saturation by digital image analysis. The experimental results showed hysteresis phenomenon of relative permeability versus saturation and that was not interpreted by previous studies. By carefully examining the recorded images, this study found that the degree of the connectivity for the micro channel occupied by wetting phase fluid could influence the relative permeability. Therefore, for the same saturation, the relative permeability in the imbibition is higher than that in the drainage. The results of the K r S experiments for five fluid-pairs also showed that the residual saturation of wetting phase fluid decreased with the wettability increasing but increased with the interfacial tension increasing. Those interpretations and experimental results are valuable references for groundwater remediation and oil reservoir development.

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Authors and Affiliations

  1. Department of the Civil Engineering, National Chiao Tung University, Hsin Chu, Taiwan

    Liang-Cheng Chang, Hung-Hui Chen, Hsin-Yu Shan & Jui-Pin Tsai

  2. Department of the Civil Engineering, Min Hsin University Science Technology, Hsin Chu, Taiwan

    Hung-Hui Chen

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  1. Liang-Cheng Chang
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  2. Hung-Hui Chen
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Correspondence to Liang-Cheng Chang.

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Chang, LC., Chen, HH., Shan, HY. et al. Effect of connectivity and wettability on the relative permeability of NAPLs. Environ Geol 56, 1437–1447 (2009). https://doi.org/10.1007/s00254-008-1238-8

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  • DOI: https://doi.org/10.1007/s00254-008-1238-8

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