西南石油大学学报(自然科学版) ›› 2026, Vol. 48 ›› Issue (3): 53-67.DOI: 10.11885/j.issn.1674-5086.2024.09.11.01
陈明君1, 李佩松1, 康毅力1, 陈掌星2,3, 游利军1, 颜茂凌1
收稿日期:2024-09-11
发布日期:2026-07-06
通讯作者:
陈明君,E-mail:chenmj1026@163.com
基金资助:CHEN Mingjun1, LI Peisong1, KANG Yili1, CHEN Zhangxing2,3, YOU Lijun1, YAN Maoling1
Received:2024-09-11
Published:2026-07-06
摘要: 常压页岩气地层能量弱,压后液相滞留易引发储层损害,加速单井产量递减,降低采收率。以渝东南常压页岩气为研究对象,基于压裂液损害机理,阐释了解堵增渗思路,进而提出页岩气层压裂液损害的亚临界或超临界水修复思路,将压后大量滞留于基质纳米孔和微裂缝的液相转化为亚临界或超临界水,提高水相流动性,并在水力裂缝周围溶孔促缝,提升气体流动能力。该方法充分考虑压后页岩气藏工程地质特征,可行性强。通过室内实验定量表征了亚临界或超临界水对页岩的溶孔促缝效果,可产生大量亚微米—微米级粒内和粒间溶蚀孔缝,孔隙度和渗透率大幅提升。论文揭示了该方法缓解压后页岩气藏水相圈闭损害的机理,包括高温热致裂和化学溶蚀作用。从与水力压裂产生协同效应和绿色低碳开发两方面,展望了该方法的矿场应用前景。
中图分类号:
陈明君, 李佩松, 康毅力, 陈掌星, 游利军, 颜茂凌. 常压页岩气层压裂液损害的亚临界或超临界水修复思路与机理[J]. 西南石油大学学报(自然科学版), 2026, 48(3): 53-67.
CHEN Mingjun, LI Peisong, KANG Yili, CHEN Zhangxing, YOU Lijun, YAN Maoling. The Remediation Mechanism of Subcritical or Supercritical Water for Fracturing Fluid Damage in Normal-pressure Shale Gas Formation[J]. Journal of Southwest Petroleum University(Science & Technology Edition), 2026, 48(3): 53-67.
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