Modeling of hydraulic fracturing in polymineralic rock with a grain-based DEM coupled with a pore network model

Li, Mengli; Wu, Jianfa; Li, Junfeng; Zhuang, Li; Wang, Shanyong; Zhang, Fengshou

Title: Modeling of hydraulic fracturing in polymineralic rock with a grain-based DEM coupled with a pore network model
Creator: Li, Mengli; Wu, Jianfa; Li, Junfeng; Zhuang, Li; Wang, Shanyong; Zhang, Fengshou
Relation: Engineering Fracture Mechanics Vol. 275, no. 108801
Publisher Link: http://dx.doi.org/10.1016/j.engfracmech.2022.108801
Publisher: Elsevier
Resource Type: journal article
Date: 2022
Description: Rock is a typical heterogeneous material composed of inherent microstructures at the grain scale. In this paper, a grain-based discrete element model (DEM) coupled with a pore network model is developed to study the interaction behavior between hydraulic fractures and the inherent microstructures of rocks. The numerical model parameters are calibrated using the experimental results on Pocheon granite, and then the model is validated by the plane strain Khristianovic-Geertsma-de Klerk (KGD) analytical solution. The fracture propagation in polymineralic rock involves many unique phenomena at the grain scale, such as intragranular fractures splitting grains, intergranular fractures along grain boundaries, fluid lag, and rock fragments. Compared with high viscosity fluid, supercritical carbon dioxide (SC-CO2) driven fractures tend to separate grain boundaries with low local resistance and propagate less smoothly and continuously, more asymmetrically and tortuously. Furthermore, the uniqueness of microstructures controlled by mineral distribution can lead to large variability in fracture paths, but the fracture properties at the macro-scale have not much difference. As the intergranular bonding strength or average grain size increases, a transition from intergranular fracture-dominated to intragranular fracture-dominated is reported. In addition, it is found that the existence of weak grains can result in more intragranular fractures within weak grains and fewer intergranular fractures associated with weak grains. Rock fragments are likely created as a result of the interaction between hydraulic fractures and weak grains and grain boundaries. Our results show that the low-viscosity fracturing fluid and the strong micro heterogeneity of microstructures are prone to result in complex fracture propagation.
Subject: hydraulic fracturing; grain-based model; pore network model; supercritical carbon dioxide; microstructure
Identifier: http://hdl.handle.net/1959.13/1492190
Identifier: uon:53272
Identifier: ISSN:0013-7944
Language: eng
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