Numerical simulation on ferrofluid flow in fractured porous media based on discrete-fracture model

• Main Authors: Huang Tao, Yao Jun, Huang Zhaoqin, Yin Xiaolong, Xie Haojun, Zhang Jianguang
• Format: Article
• Language: English
• Published: De Gruyter 2017-06-01
• Series: Open Physics
• Subjects: ferrofluid flow; fractured porous media; discrete fracture model; numerical simulation; enhance oil recovery; 47.11.df; 47.54.bd; 47.65.cb
• Online Access: https://doi.org/10.1515/phys-2017-0041

Water flooding is an efficient approach to maintain reservoir pressure and has been widely used to enhance oil recovery. However, preferential water pathways such as fractures can significantly decrease the sweep efficiency. Therefore, the utilization ratio of injected water is seriously affected. How to develop new flooding technology to further improve the oil recovery in this situation is a pressing problem. For the past few years, controllable ferrofluid has caused the extensive concern in oil industry as a new functional material. In the presence of a gradient in the magnetic field strength, a magnetic body force is produced on the ferrofluid so that the attractive magnetic forces allow the ferrofluid to be manipulated to flow in any desired direction through the control of the external magnetic field. In view of these properties, the potential application of using the ferrofluid as a new kind of displacing fluid for flooding in fractured porous media is been studied in this paper for the first time. Considering the physical process of the mobilization of ferrofluid through porous media by arrangement of strong external magnetic fields, the magnetic body force was introduced into the Darcy equation and deals with fractures based on the discrete-fracture model. The fully implicit finite volume method is used to solve mathematical model and the validity and accuracy of numerical simulation, which is demonstrated through an experiment with ferrofluid flowing in a single fractured oil-saturated sand in a 2-D horizontal cell.