TY - EJOU AU - Yin, Qian AU - Li, Xiaojing AU - Yu, Liyuan AU - He, Ming AU - Liu, Richeng TI - Solute Removal Analysis of a Large-scale Fracture Plane Considering Different Flow Paths and Different Hydraulic Head Differences T2 - Computer Modeling in Engineering \& Sciences PY - 2020 VL - 124 IS - 1 SN - 1526-1506 AB - An experimental and numerical study was carried out to investigate the solute removal process through a large-scale fracture plane considering different flow paths and hydraulic head differences. The visualization techniques were utilized in the experiment to capture the removal process images, which were then transferred to binary images. The variations in dimensionless concentration, which is defined as saturation of solute phase, were analyzed. With increasing hydraulic head difference, the speed of solute removal increases and the dimensionless concentration decreases. The flow paths result in different solute distribution patterns and different mechanisms for solute removal such as advection and diffusion, thus the curves of dimensionless concentration versus time are different. The dimensionless concentration over time decreases from approximately 1, which is smaller than 1 due to the existence of bubbles, to approximately 0, which is larger than 0 because the folds of the background are dealt as “solute”. A significant longer time is needed to achieve a certain fixed dimensionless concentration for a smaller hydraulic head difference. With the finite element software COMSOL multiphysics, the solute removal process, flow velocity fields, flow streamlines, as well as the hydraulic pressure fields were analyzed, which shows a good consistency with the experimental results. In practical engineering, when the solute pollutes the underground environment, the removal ability can be more significantly enforced by immediately applying a larger hydraulic head difference along a longer distance between the inlet and outlet boundaries. KW - Solute removal; rock fracture; visualization; hydraulic head difference; flow path; numerical simulation DO - 10.32604/cmes.2020.08204