[1]周雷力,何颂根,陈迟.川南深层页岩压裂裂缝导流能力测试技术[J].油气井测试,2020,29(03):38-44.[doi:10.19680/j.cnki.1004-4388.2020.03.007]
ZHOU Leili,HE Songgen,CHEN Chi.Measurement of the conductivity of induced fractures in the deep shale in Southern Sichuan basin[J].Well Testing,2020,29(03):38-44.[doi:10.19680/j.cnki.1004-4388.2020.03.007]
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川南深层页岩压裂裂缝导流能力测试技术(
)
《油气井测试》[ISSN:1006-6977/CN:61-1281/TN]
- 卷:
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29卷
- 期数:
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2020年03期
- 页码:
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38-44
- 栏目:
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- 出版日期:
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2020-06-25
文章信息/Info
- Title:
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Measurement of the conductivity of induced fractures in the deep shale in Southern Sichuan basin
- 文章编号:
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1004-4388(2020)03-0038-07
- 作者:
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周雷力1; 何颂根2; 陈迟3
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1.营山县天然气公司 四川南充 637700
2.中国石化西南油气分公司石油工程技术研究院 四川德阳 618000
3.西南石油大学油气藏地质及开发工程国家重点实验室 四川成都 610500
- Author(s):
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ZHOU Leili1; HE Songgen2; CHEN Chi3
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1.Yingshan County Natural Gas Company, Nanchong, Sichuan 637700, China
2.Petroleum Engineering Technology Institute, Sinopec Southwest Oil and Gas Company, Deyang, Sichuan 618000, China
3.State Key Laboratory of Oil and Gas Reservoir Geology and Development Engineering, Southwest Petroleum University, Chengdu, Sichuan 610500, China
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- 关键词:
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川南龙马溪组; 深层页岩; 自支撑裂缝; 支撑裂缝; 导流能力; 主控因素; 适应性评价
- Keywords:
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Longmaxi Formation in Southern Sichuan basin; deep shale; selfsupporting fractures; supported fractures; conductivity; control factors; adaptability evaluation
- 分类号:
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TE357
- DOI:
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10.19680/j.cnki.1004-4388.2020.03.007
- 文献标志码:
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B
- 摘要:
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随着埋深增加,深层页岩压裂后,裂缝导流能力能否有效保持是个关键问题。以川南龙马溪组深层页岩为例,对比测试了支撑裂缝及自支撑裂缝的导流能力,开展了主控因素影响规律分析及适应性评价。结果表明,应力增加,支撑裂缝及自支撑裂缝导流能力均呈指数式下降;支撑裂缝受粗糙度、铺砂浓度、支撑剂类型、粒径等影响,在低铺砂浓度下受裂缝面粗糙度主控,在高铺砂浓度下受支撑剂铺置主控;自支撑裂缝受裂缝产状、粗糙度、滑移量、力学性质等影响;对深层页岩而言,垂直自支撑裂缝、石英砂及覆膜砂铺置的支撑裂缝满足生产初期需求,陶粒铺置的支撑裂缝更有利于生产后期的导流能力保持。形成的压裂缝导流能力测试方法可为深层页岩的压裂优化设计提供借鉴。
- Abstract:
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Whether the conductivity of induced fractures keeps stable as the burial depth of shale formation increases is very important. Taking the deep shale of the Longmaxi Formation in the southern Sichuan Basin as a case, this paper compares the conductivity of the supported fractures and the selfsupporting fractures, and analyzes the influencing law of control factors and adaptability. The results show that the conductivity of the supported fractures and selfsupporting fractures decreases exponentially with increasing stress; supported fractures are affected by their roughness, proppant concentration, proppant type, particle size, etc.; at low proppant concentration, fracture roughness is a dominant factor, while at high proppant concentration, proppant placement is dominant; selfsupporting fractures are affected by fracture occurrence, roughness, slippage, mechanical properties, etc. In the deep shale, vertical selfsupporting fractures, and the fractures supported by quartz sand and coated sand meet the requirement of initial production, and the fractures supported by ceramsite are more effective to maintain the conductivity in later production. The method for testing fracture conductivity is a reference to designing deep shale fracturing stimulation.
备注/Memo
- 备注/Memo:
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2020-02-03收稿,2020-05-03修回,2020-05-10接受,2020-06-20网络版发表
周雷力,男,1990年出生,工程师,2012年毕业于西南石油大学石油工程专业,现从事天然气相关的技术管理工作。电话:0817-8225379,13990715375;Email:276047612@qq.com。通信地址:四川省南充市营山县城南镇天长街营山县天然气公司,邮政编码:637700。
更新日期/Last Update:
2020-07-15