Multi-Scale Investigations on the Geometries of Hydraulic Fractures in Conglomerate Reservoirs

Haipeng Liang, Huiying Tang, Jianhua Qin, Yang Li, Liehui Zhang
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引用次数: 1

Abstract

Currently, the research on hydraulic fracture geometries is mainly focused on tight sandstone and shale. The investigations on the conglomerate tight reservoirs, e.g., Mahu Oilfield in Junggar Basin, China, is still lacking due to its uniqueness and late discovery time. The strong heterogeneity and the existence of gravels in conglomerate tight reservoirs put great challenges on the study of hydraulic fracture geometries. In this paper, a whole field cohesive zone model in finite element method is used to model the fracture nucleation and propagation in rock matrix (sand) and gravels in lab scale. The numerical model is validated against some published experimental results. Based on the analysis of numerical results, a mathematical model for quantitative characterization of fracture growth speed in conglomerate reservoir is proposed. This model is critical to connect the fracture propagation behaviors in lab-scale with the hundreds of meters field-scale hydraulic fractures. For the field scale fracturing simulations, the UFM (unconventional fracture model), which is based on boundary element method, has been widely used. Considering the similarity of crossing behaviors between hydraulic fracture-gravels and hydraulic fracture -natural fractures in conglomerate and shale respectively, a series of natural fractures are used to equivalent the impact of gravels in lab scale in the field scale simulations. The parameters of the equivalent natural fractures are determined according to the propagation model extracted from the lab-scale numerical simulations. The multi-scale research on fracture geometries and methods for field scale fracturing simulations for Mahu conglomerate reservoir could provide important guidance for the future design and optimizations of hydraulic fracturing.
砾岩储层水力裂缝几何形状的多尺度研究
目前,水力裂缝几何形状的研究主要集中在致密砂岩和页岩上。以准噶尔盆地马湖油田为例,砾岩致密储层由于其独特性和发现时间较晚,目前对该储层的研究还比较欠缺。砾岩致密储层具有较强的非均质性和砾石的存在,对水力裂缝几何形状的研究提出了较大的挑战。本文采用有限元法中的全场内聚带模型,模拟了实验室尺度下岩石基质(砂)和砾石中裂缝的成核和扩展。数值模型与一些已发表的实验结果进行了对比验证。在对数值结果分析的基础上,提出了砾岩储层裂缝发育速度定量表征的数学模型。该模型是将实验室尺度裂缝扩展行为与数百米现场尺度水力裂缝联系起来的关键。在现场压裂模拟中,基于边界元法的非常规裂缝模型(UFM)得到了广泛应用。考虑到砾岩和页岩中水力裂缝-砾石和水力裂缝-天然裂缝的交叉行为具有相似性,在现场模拟中采用一系列天然裂缝来等效实验室尺度下砾石的影响。根据室内数值模拟的扩展模型,确定了等效天然裂缝的参数。麻湖砾岩储层裂缝几何形态的多尺度研究与现场压裂模拟方法的研究,对今后水力压裂设计与优化具有重要指导意义。
本文章由计算机程序翻译,如有差异,请以英文原文为准。
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