Fluid-driven fracture mechanisms in granular media: insights from grain-scale numerical modeling

Li Zihao; Espinoza D. Nicolas; Balhoff Matthew T.

首页> 外文期刊>Granular matter >Fluid-driven fracture mechanisms in granular media: insights from grain-scale numerical modeling

【24h】

Fluid-driven fracture mechanisms in granular media: insights from grain-scale numerical modeling

机译：Fluid-driven fracture mechanisms in granular media: insights from grain-scale numerical modeling

获取原文

获取原文并翻译 | 示例

掌桥外文数据库（机构版） >>

开具论文收录证明 >>

文献代查 >>

页面导航

摘要
著录项
相关主题

摘要

Fluid injection into porous media can initiate fluid-driven fractures. Unlike cohesive and homogeneous media, fluid-driven fractures in cohesionless granular media have complex fracture and leak-off morphologies. In this study, we investigate the mechanisms behind fluid-driven fractures in cohesionless granular media by coupling the discrete element method with computational fluid dynamics at the pore/grain scale. We perform numerical simulations of the injection of a fluid into a granular medium that is saturated with a second, immiscible fluid. Results show that fluid injection can initiate a fracture orthogonal to the minimum principal stress, as expected, through viscous drag forces. However, the displacement field around the fracture is much more complex than what is expected for a linear elastic solid, showing that (1) fracture propagation requires small leak-off (a few times the fracture width) and (2) localized shear deformation ahead of the fracture tip affects fracture morphology. The simulations support a transition from a leakoff-dominated fluid flow regime to a fracture-dominated regime, with the increase in characteristic time t(1) (ratio of permeability and injection rate per unit length) and decrease in t(2) (ratio of injected fluid viscosity and minimum total principal stress). We develop a correlation of the dimensionless initiation pressure P-D,P-peak and dimensionless stress S-D (upper bound: P-D,P-peak = 5.647S(D)(0.86), lower bound: P-D,P-peak = 0.567S(D)(0.83)) based on our grain-scale simulations, experimental data and field data from the literature, which can be used to predict the fracture initiation pressure in cohesionless granular media.

著录项

来源
《Granular matter》 |2021年第4期|87.1-87.18|共18页
作者
Li Zihao; Espinoza D. Nicolas; Balhoff Matthew T.;
展开▼
作者单位

Univ Texas Austin, Hildebrand Dept Petr & Geosyst Engn, 200 E Dean Keeton, Austin, TX 78712 USA|Univ Texas Austin, Ctr Subsurface Energy & Environm, 200 E Dean Keeton, Austin, TX 78712 USA;

展开▼
收录信息美国《科学引文索引》(SCI);美国《工程索引》(EI);
原文格式 PDF
正文语种英语
中图分类
关键词
Discrete element method; Computational fluid dynamics; Shear band; Fracture and leak-off morphology; Fracture initiation pressure;

Fluid-driven fracture mechanisms in granular media: insights from grain-scale numerical modeling

摘要

著录项

相关主题

期刊订阅