Coupled Simulation of Fracture Propagation and Lagrangian Proppant Transport

SPE Journal Pub Date : 2024-07-01 DOI:10.2118/221483-pa
Zhicheng Wen, Huiying Tang, Liehui Zhang, Shengnan Chen, Junsheng Zeng, Jianhua Qin, Linsheng Wang, Yulong Zhao
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Abstract

The distribution of proppant within hydraulic fractures significantly influences fracture conductivity, thus playing an essential role in oil and gas production. Currently, small-scale and static fracture problems have been successfully simulated with high accuracy using Lagrangian proppant transport models. Field-scale problems are often simulated with the mixture model, the accuracy of which still requires improvement. In this work, a novel model that couples fracture propagation and proppant transport using an Eulerian-Lagrangian framework is proposed. The displacement discontinuity method (DDM), the extended Poiseuille’s equation, and the multiphase particle-in-cell (MP-PIC) method are used for fracture deformation and propagation, fluid flow, and proppant transport simulations, respectively. The fluid flow is fully coupled with the fracture equations and then coupled with the Lagrangian proppant model using a two-way coupling strategy. The proposed model is carefully validated against published numerical and experimental results. Then, we use the model to investigate the fracturing process in a layered reservoir. The impacts of fluid leakoff and proppant injection order are discussed. Special phenomena such as proppant bridging and tip screenout are captured. This study provides a novel and reliable way for simulating proppant transport in practical problems, which is of great importance to fracturing designs.
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裂缝扩展与拉格朗日支撑剂迁移耦合模拟
支撑剂在水力裂缝中的分布极大地影响着裂缝的传导性,因此在油气生产中起着至关重要的作用。目前,利用拉格朗日支撑剂传输模型已成功模拟了小规模和静态裂缝问题,精度很高。现场尺度的问题通常采用混合物模型进行模拟,其精度仍有待提高。在这项工作中,提出了一种使用欧拉-拉格朗日框架将裂缝扩展和支撑剂运移结合起来的新型模型。该模型采用位移不连续法(DDM)、扩展普瓦塞耶方程和多相颗粒-单元(MP-PIC)法,分别对压裂变形和扩展、流体流动和支撑剂运移进行模拟。流体流动与压裂方程完全耦合,然后采用双向耦合策略与拉格朗日支撑剂模型耦合。我们根据已公布的数值和实验结果对所提出的模型进行了仔细验证。然后,我们使用该模型研究了层状储层的压裂过程。讨论了流体漏失和支撑剂注入顺序的影响。我们还捕捉到了支撑剂架桥和顶端屏蔽等特殊现象。这项研究为模拟实际问题中的支撑剂输送提供了一种新颖可靠的方法,对压裂设计具有重要意义。
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