页岩储层多簇水力裂缝非对称扩展机理研究

doi:10.13809/j.cnki.cn32-1825/te.2025251

摘要/Abstract

摘要： 在多簇水力裂缝扩展规律中,传统重点强调其应力阴影导致的簇非均衡扩展。但理论与现场监测发现,非均衡扩展还包括空间非对称扩展的内涵,特别是压裂工艺走向密切割+限流射孔工艺后。水力裂缝空间非对称扩展效应,对有效改造体积识别、井间窜扰判断、限流射孔工艺优化等具有显著影响。研究以复兴区块凉高山组页岩油为例,结合三维离散格子模拟方法,建立了水平井密切割段内多簇尺度非对称扩展模型,分析了影响其对称性的敏感性因素,形成了优化方案。结果显示: ①由于缝间应力阴影导致水力裂缝非对称扩展与形态互补,随着密切割程度增加,非对称扩展现象显著,主要发生在中间簇,与微地震监测结果一致;②随着前置液从低黏变为冻胶,非对称指数呈降低趋势,均衡指数呈明显的增加趋势,但裂缝转向严重,复杂度增加,缝长可能受限,需要进一步强化规模;③限流射孔起裂均衡性显著提升,但非对称更为严重,中间簇裂缝转向严重,尤其在簇间距小于等于6 m时;当簇间距大于等于8 m时,限流射孔不仅能提升起裂均衡程度,同时降低了水力裂缝非对称性。后续应在充分考虑对称性与均衡性的基础上,合理配置簇间距、黏度、排量等参数,辅以暂堵、限流射孔等工艺,提高水力缝网改造体积。

关键词: 页岩, 水力压裂, 非对称扩展, 三维离散格子法, 应力阴影, 凉高山组

Abstract: In studies of multi-cluster hydraulic fracture propagation patterns, traditional research has emphasized inter-cluster competitive and unbalanced propagation caused by stress shadowing effects. However, theoretical analysis and field monitoring reveal that unbalanced propagation should also include the concept of spatial asymmetry, especially as fracturing processes evolve toward dense-cluster spacing and extreme limited-entry perforation techniques. The spatially asymmetric propagation of hydraulic fractures significantly affects the identification of effective stimulated volume, assessment of inter-well interference, and optimization of extreme limited-entry perforation techniques. Taking the Lianggaoshan Formation shale oil in the Fuxing block as an example, this study established an asymmetric propagation model for multi-cluster fractures in horizontal wells with dense-cluster spacing using a three-dimensional discrete lattice simulation method. The model precisely characterized the spatial evolution of hydraulic fractures , analyzed sensitivity factors influencing symmetry, and proposed optimization strategies. The results showed that: (1) stress shadowing between fractures led to asymmetric propagation and complementary morphologies. As cluster density increased, asymmetric propagation became more pronounced, primarily in middle clusters, consistent with microseismic monitoring results. (2) As the pad fluid changed from low viscosity to gelled fluid, the asymmetry index showed a decreasing trend, and the equilibrium index showed a significant increasing trend. Increasing pad fluid viscosity enhanced fracture initiation and propagation uniformity while reducing asymmetry to some extent. However, severe fracture deflection occurred and complexity increased, limiting fracture length and requiring further scale enhancement. (3) Limited-entry perforation significantly improved initiation uniformity but exacerbated asymmetry, with severe deflection in middle-cluster fractures, particularly when cluster spacing was ≤6 m. However, when cluster spacing was ≥8 m, limited-entry perforation not only enhanced initiation uniformity but also effectively reduced the asymmetry of hydraulic fractures. In subsequent operations, based on full consideration of symmetry and uniformity, cluster spacing, fluid viscosity, and injection rate should be reasonably configured, supplemented by temporary plugging and limited-entry perforation techniques, to improve the stimulated volume of the hydraulic fracture network. This study provides a novel perspective on asymmetric fracture propagation for optimizing multi-cluster fracturing and perforation design in unconventional reservoirs.

Key words: shale, hydraulic fracturing, asymmetric propagation, three-dimensional discrete lattice method, stress shadow, Lianggaoshan Formation

中图分类号:

TE35

朱柏宇,张凡,朱志芳, 等. 页岩储层多簇水力裂缝非对称扩展机理研究[J]. 油气藏评价与开发, 0, (): 251011-.

ZHU BAIYU,ZHANG FAN,ZHU ZHIFANG, et al. Study on asymmetric propagation mechanisms of multi-cluster hydraulic fractures in shale reservoirs[J]. Petroleum Reservoir Evaluation and Development, 0, (): 251011-.

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