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大庆致密油井页岩井壁稳定性实验研究

燕松兵 刘付臣 杨振周 刘永贵 吕萌 宋涛 周春

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文章导航 > 钻井液与完井液  > 2020 >  37(2): 140-147
燕松兵, 刘付臣, 杨振周, 刘永贵, 吕萌, 宋涛, 周春. 大庆致密油井页岩井壁稳定性实验研究[J]. 钻井液与完井液, 2020, 37(2): 140-147. doi: 10.3969/j.issn.1001-5620.2020.02.002
引用本文: 燕松兵, 刘付臣, 杨振周, 刘永贵, 吕萌, 宋涛, 周春. 大庆致密油井页岩井壁稳定性实验研究[J]. 钻井液与完井液, 2020, 37(2): 140-147. doi: 10.3969/j.issn.1001-5620.2020.02.002
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YAN Songbing, LIU Fuchen, YANG Zhenzhou, LIU Yonggui, LYU Meng, SONG Tao, ZHOU Chun. Experimental Study on Shale Borehole Wall Stability of Tight Oil Wells in Daqing Oilfield[J]. DRILLING FLUID & COMPLETION FLUID, 2020, 37(2): 140-147. doi: 10.3969/j.issn.1001-5620.2020.02.002
Citation: YAN Songbing, LIU Fuchen, YANG Zhenzhou, LIU Yonggui, LYU Meng, SONG Tao, ZHOU Chun. Experimental Study on Shale Borehole Wall Stability of Tight Oil Wells in Daqing Oilfield[J]. DRILLING FLUID & COMPLETION FLUID, 2020, 37(2): 140-147. doi: 10.3969/j.issn.1001-5620.2020.02.002
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大庆致密油井页岩井壁稳定性实验研究

doi: 10.3969/j.issn.1001-5620.2020.02.002

  • 1. 中国石油集团工程技术研究院有限公司, 北京 102206;

  • 2. 中国石油休斯敦技术研究中心, 北京 100028;

  • 3. 中国石油大庆钻探钻井工程技术研究院, 黑龙江大庆 163355

基金项目: 

中国石油天然气股份有限公司重大科技专项“油气开采降本增效技术研究与规模应用”(2016E-0212)

详细信息
    作者简介:

    燕松兵,2008年毕业于中国石油大学(华东)应用化学系,长期从事钻井液技术研究。电话13361529671;E-mail:songbing.yan@cnpc.com.cn

  • 中图分类号: TE254

Experimental Study on Shale Borehole Wall Stability of Tight Oil Wells in Daqing Oilfield

  • 1. CNPC Engineering Technology R&D Company Limited, Beijing 102206;

  • 2. CNPC USA Corporation, Beijing 100028;

  • 3. R&D Institute of Daqing Drilling Engineering Company, Daqing, Heilongjiang 163355

    摘要
  • 摘要: 大庆致密油区块青山口组、泉头组页岩容易发生井壁失稳情况。目前用于评价页岩井壁稳定性的常规方法为热滚分散和线性膨胀实验。此类实验通常存在人为缺陷,会误导对页岩膨胀活性的认识和配伍性流体的选择。采用更接近井下地层条件的3种实验方法(多级三轴应力实验、压力传递实验(PTT)、厚壁圆筒实验(TWC)),对大庆致密油页岩进行研究。通过多级三轴应力实验,绘制摩尔-库伦破坏包络线,确定了维持井壁稳定性所需钻井液密度。压力传递实验反映了特定流体系统中所预期的钻井液压力侵入速率和孔隙压力升高的延迟情况。厚壁圆筒实验研究了过平衡压力下暴露在钻井液中的岩心样品的破坏特性。这3种实验方法,模拟了在钻井过程中钻井液对井下页岩地层应力的影响,对研究井壁稳定性的影响因素更具指导意义。

     

    Abstract: Borehole wall instability has long been a problem in drilling the Qingshankou Formation and the Quantou Formation in the tight oil blocks in Daqing. Common methods of evaluating the stability of shale formations presently in use are hot rolling test and linear expansion test. These methods however, have defects caused by those who do the experiments, and the experimental results are therefore misleading in the understanding of the activity of the swelling shales and the selection of compatible drilling fluid. Multistage triaxial stress experiment, pressure transfer test (PTT) and thick-walled cylinder test (TWC), which can simulate more closely the downhole conditions, were used to study the stability of shale formations in tight oil wells in Daqing. Using the multi-stage triaxial stress test, the Mohr-Coulomb failure envelop of the formation rocks was drawn to determine the mud density enough to stabilize the borehole wall. PTT was conducted to understand the anticipated invasion rate of pressure caused by drilling fluid column in the hole and the delay in pore pressure increase for a specific fluid system. TWC experiment was used to study the failure characteristics of core samples exposed to drilling fluid under overbalanced pressure. These three test methods simulate the effects of drilling fluid on the stresses of downhole shale formation, and are instructive to the study on the factors affecting borehole wall stabilization.

     

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    • 参考文献(15)
  • [1] VAN OORT E. A novel technique for the investigation of drilling f luid induced borehole instability in shales[C]//Rock Mechanics in Petroleum Engineering.Delf t, Netherlands:Society of Petroleum Engineers, 1994:29-31.
    [2] MESE ALI I. Clay-water interaction, intermolecular forces and acoustic velocity[C]//2008 SEG Annual Meeting. Las Vegas, Nevada:Society of Exploration Geophysicists, 2008:9-14.
    [3] CH EN EVER T M E, AM ANULL AH M. Shale preservation and testing techniques for borehole-stability studies[J]. SPE Drilling & Completion, 2001, 16(3):146-149.
    [4] VAN OORT E. How to test for compatibility between fluids and shales[C]//IADC/SPE Drilling Conference and Exhibition. Fort Worth, Texas, USA:Society of Petroleum Engineers, 2018:6-8.
    [5] VAN OORT E, CHRISTIAN PASTUREL, JEDRZEJ BRYLA, et al. Improved wellbore stability in Tor/Ekofisk wells through shale-fluid compatibility optimization[C]//SPE/IADC Drilling Conference and Exhibition.The Hague, The Netherlands:Society of Petroleum Engineers, 2017:14-16.
    [6] 陈金霞, 适用于硬脆性泥页岩的钻井液井壁稳定性评价方法[J]. 油田化学, 2018, 35(3):527-532.

    CHEN Jinxia. Well stability evaluation method for hard and brittle shale drilling fluid[J]. Oilfield Chemistry, 2018, 35(3):527-532.
    [7] 赵虎, 司西强, 王善举, 等. 钻井液对页岩井壁的稳定性能评价方法探讨[J]. 石油工业技术监督, 2019, 35(2):12-15.

    ZHAO Hu, SI Xiqiang, WANG Shanju, et al. Discussion on shale well stability evaluation method for drilling fluid[J]. Technical Supervision in Petroleum Industry, 2019, 35(2):12-15.
    [8] 杨明合, 石建刚, 李维轩, 等. 泥页岩水化导致油气井井壁失稳研究进展[J]. 化学工程师, 2018(10):44-47. YANG Minghe, SHI Jiangang, LI Weixuan, et al. Research progress of shale hydration lead to wellbore instability[J]. Chemical Engineer, 2018

    (10):44-47.
    [9] ALSALMAN M E, MYERS M T, SHARF-ALDIN M H. Comparison of multistage to single stage Triaxial tests[C]//49th U.S. Rock Mechanics/Geomechanics Symposium.San Francisco, California:American Rock Mechanics Association, 2015.
    [10] BOL G M, WONG S W, DAVIDSON C J, et al. Borehole stability in shales[J].SPE Drilling & Completion, 1994, 9(2):87-94.
    [11] 宋碧涛, 马成云, 徐同台, 等. 硬脆性泥页岩钻井液封堵性评价方法[J]. 钻井液与完井液, 2016, 33(4):51-55.

    SONG Bitao, MA Chengyun, XU Tongtai, et al.Methods for evaluating the performance of drilling fluids plugging fractures in hard and brittle shales[J].Drilling Fluid & Completion Fluid, 2016, 33(4):51-55.
    [12] VAN OORT E, HALE A H, MODY F K, et al. Transport in shales and the design of improved waterbased shale drilling fluids[J].SPE Drilling & Completion, 1996, 11(3):137-146.
    [13] HEMPHILL TERRY, LARSEN T I.Hole-cleaning capabilities of water-and oil-based drilling fluids:a comparative experimental study[J].SPE Drilling & Completion, 1996, 11(4):201-207.
    [14] BYBEE KAREN.Chemical and thermal effects on wellbore stability of shale formations[J].Journal of Petroleum Technology, 2002, 54(2):51.
    [15] VAN OORT E, RIPLEY D, WARD I, et al.Silicatebased drilling fluids:competent, cost-effective and benign solutions to wellbore stability problems[C]//IADC/SPE Drilling Conference.New Orleans, Louisiana:Society of Petroleum Engineers, 1996:12-15.
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出版历程
  • 收稿日期:  2019-12-05
  • 刊出日期:  2020-04-28

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