西南石油大学学报(自然科学版) ›› 2026, Vol. 48 ›› Issue (3): 98-110.DOI: 10.11885/j.issn.1674-5086.2024.11.27.02

• 石油与天然气工程 • 上一篇    下一篇

温差效应下页岩力学劣化特征及损伤演化机制

周成香, 李成赢, 高茂萍   

  1. 中国石化重庆页岩气有限公司, 重庆 南川 408400
  • 收稿日期:2024-11-27 发布日期:2026-07-06
  • 通讯作者: 周成香,E-mail:278738690@qq.com

Mechanical Deterioration Characteristics and Damage Evolution Mechanism of Shale Under Thermal Gradient Effects

ZHOU Chengxiang, LI Chengying, GAO Maoping   

  1. Sinopec Chongqing Shale Gas Co. Ltd., Nanchuan, Chongqing 408400, China
  • Received:2024-11-27 Published:2026-07-06

摘要: 页岩气开发面临储层改造难度大、渗透率低等挑战,液氮压裂作为无水化储层改造技术可规避传统水力压裂的水敏损害和环境污染问题,但其热冲击效应对页岩力学劣化的影响机制尚不明晰。为研究液氮冻结作用下深层页岩气储层的力学强度变化规律和裂缝形态特征,通过单轴压缩实验与模拟测试了页岩温度、液氮循环次数及层理倾角下页岩的力学强度与破坏模式,分析了液氮冻结前后微观结构变化。结果表明,页岩劣化损伤特征受冷却时间、温差效应度及循环次数控制,表现为微裂纹扩展、裂纹网络复杂化及力学强度下降。高温差可以增强液氮对岩石力学强度的劣化作用。循环次数增加进一步加剧岩石基质损伤和强度弱化,但效应逐步减弱并趋于稳定。不同层理倾角显著影响页岩破坏模式,倾角60°时抗压强度最低,而倾角90°时表现出更高的力学强度。页岩非均质较强的情况,液氮作用能有效形成复杂缝网,降低力学强度。研究建立的“温度-循环-结构”协同损伤模型,为深层页岩储层液氮压裂的时间调控、循环参数优化、层理方位及非均质性效果提供了关键理论支撑。

关键词: 液氮压裂, 深层页岩, 温差效应, 力学强度, 损伤演化

Abstract: Shale gas development is faced with challenges such as difficulties in reservoir stimulation and low permeability. Liquid nitrogen fracturing, as a waterless reservoir stimulation technology, can circumvent the water sensitivity damage and environmental pollution issues associated with traditional hydraulic fracturing. However, the mechanism by which its thermal shock effect influences the mechanical degradation of shale remains unclear. To investigate the mechanical strength variation and fracture morphology characteristics of deep shale gas reservoirs under liquid nitrogen freezing, uniaxial compression experiments were conducted to measure the mechanical strength of shale at different temperatures and liquid nitrogen cycling times. The failure modes of shale at various temperatures were compared, and microstructural changes before and after liquid nitrogen freezing were analyzed. The results show that the deterioration and damage characteristics of shale are governed by cooling time, preheating temperature, and thermal gradient effects, manifested as microcrack propagation, increased fracture network complexity, and reduced mechanical strength. A higher thermal gradient enhances the deterioration effect of liquid nitrogen on the mechanical strength of the rock. Increased cycling times further exacerbate matrix damage and strength weakening, although the effect diminishes and stabilizes over time. The failure mode of shale is significantly influenced by bedding angles, with a minimum compressive strength observed at 60°, and a 90° bedding angle exhibits higher mechanical strength. In the case of strong non-homogeneity of shale, liquid nitrogen can effectively form a complex network of seams and reduce the mechanical strength. The synergistic damage model of “temperature-circulation-structure” established in this study provides a key theoretical support for the time regulation, optimization of circulation parameters, orientation of layers and non-homogeneous effect of liquid nitrogen fracturing in deep shale reservoirs.

Key words: liquid nitrogen fracturing, deep shale, temperature effect, mechanical strength, damage evolution

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