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首页» 过刊浏览» 2019» Vol.4» Issue(1) 57-68     DOI : 10.3969/j.issn.2096-1693.2019.01.005
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页岩气水平井压裂过程中水泥环完整性分析
席岩1,李军1*,柳贡慧1,2,陶谦3,连威1
1 中国石油大学( 北京) 石油工程学院,北京 102249 2 北京工业大学机械工程与应用电子技术学院,北京 100124 3 中国石化石油工程技术研究院固井所,北京 100101
Research into cement sheath integrity during multistage hydraulic fracturing in shale gas wells
XI Yan1, LI Jun1, LIU Gonghui1,2, TAO Qian3, LIAN Wei1
1 College of Petroleum Engineering, China University of Petroleum- Beijing, Beijing 102249, China 2 College of Mechanical Engineering and Applied Electronics Technology, Beijing University of Technology, Beijing 100124, China 3 SINOPEC Research Institute of Petroleum Engineering Cementing Branch, Beijing 100101, China

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摘要  页岩气井工程实践表明套管压裂易导致水泥环完整性破坏,进而引发环空带压。统计数据表明:中国涪陵页岩气田投产井166 口,出现环空带压井占比达79.52%。进一步分析研究表明:一级套管头(生产套管和技术套管之间)压裂前后带压比例从14.85%提升至50.05%;二级套管头(技术套管和表层套管之间)压裂前后带压井比例从15.84% 提升至53.01%,充分说明页岩气井压裂对环空带压影响较大。
针对该问题,基于页岩气井压裂工程实际,在考虑压裂液摩擦生热和排量对换热系数影响的基础上,建立了压裂过程中井筒温度场模型和套管—水泥环—地层组合体有限元模型,采用解析法和数值法相结合的方式,计算了页岩气井压裂过程中瞬态温度—压力耦合作用下水泥环径向、切向应力变化规律,开展了井筒内压、压裂液排量、初始温度、弹性模量、泊松比对水泥环应力影响的敏感性分析,并基于Mohr-Coulomb准则对水泥环是否失效进行了分析。
研究结果表明:(1)页岩气井压裂过程中,水泥环温度随时间发生剧烈变化,且内外壁之间存在显著温差,该温差随压裂作业的进行先增大、后减小。(2)页岩气井压裂过程中,水泥环径向、切向应力随时间不断变化,径向应力先减小、后增大,切向应力先降低、后升高,然后再降低。依照Mohr-Coulomb准则分析可知,压裂过程中水泥环易发生拉伸破坏,压裂初期为水泥环失效的“风险段”。(3)降低井筒内压,可以显著降低水泥环径向、切向应力;降低压裂液排量,水泥环径向、切向应力有所降低,但降低幅度不明显;提升压裂液初始温度,将会提高水泥环径向应力、降低水泥环切向应力;水泥石弹性模量降低至4 GPa时,水泥环径向、切向应力低于水泥石抗拉、抗压强度,在压裂过程中有利于保持水泥环的完整性;提高水泥石泊松比,对径向应力影响极小,可忽略不计,但可以有效降低水泥环切向应力。依据计算结果设计了一种新型水泥浆体系,降低了水泥石弹性模量。应用该水泥桨的工程实践表明,压裂后并未出现环空带压情况,保证了分段压裂后页岩气井的安全生产。研究结果可为页岩气井压裂过程中水泥浆设计以及井筒完整性控制提供参考。
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关键词 : 页岩气;压裂;有限元;水泥环;完整性
Abstract

Shale gas well engineering practice demonstrates that volume fracturing easily leads to the integrity failure of cement sheaths, thus causing sustained casing pressure (SCP). According to statistics, the SCP wells account for as high as 79.52% among 166 brought in wells in China's Fuling shale gas field. The analysis has shown that the ratio of SCP is very low before fracturing, but it increases substantially after fracturing. The ratio of the first-grade casing head (between surface casing and intermediate casing) increases from 14.85% to 50.05%, meanwhile, that of the second-grade casing head (between intermediate casing and production casing) increases from 15.84% to 53.01%. This fully indicates that the influence of casing fracturing on sustained casing pressure of shale gas wells is relatively greater.
To address this problem, a wellbore temperature field model is established so as to obtain the required input parameters of the dynamic temperature boundary, considering the friction heat of liquid and the influence of fracturing fluid on heat exchange coefficient, and at the same time, a numerical model of casing-cement sheath-formation is proposed and analyzed. Sensitivity analysis is conducted on the influences of internal wellbore pressure, fracturing fluid displacement, initial temperature, Young's modulus as well as Poisson's ratio on the cement sheath stress. Furthermore, the cement sheath integrity is evaluated by using Mohr-Coulomb failure criteria.
The results show that: (1) during the fracturing of shale gas wells, the temperature of the cement sheaths change drastically with time. Besides, there exists a significant temperature difference between inner and outer walls, which increases at first and then decreases throughout the fracturing operation. (2) During the fracturing of shale gas wells, the radial and tangential stresses of the cement sheath continuously change over time. The radial stress decreases first and then increases. The tangential stress decreases first, then rises and finally decreases again. Judging from the Mohr-Coulomb failure criterion, cement sheaths are prone to tensile failure, and the initial stage of fracturing is the "risky phase" for the failure of cement sheaths. (3) Reducing internal wellbore pressure can effectively decrease the radial and tangential stresses of cement sheath. Besides, the reduction of fracturing fluid displacement decreases the radial and tangential stresses of the cement sheath, however, the decreases are not obvious. Elevation of initial fracturing fluid temperature can increase the radial stress of the cement sheath and decrease the tangential stress. In addition, reducing the Young's modulus significantly decreases the radial and tangential stresses of the cement sheath. When the Young's modulus reaches a certain value, the tangential stress is lower than the tensile strength. As well, the radial stress is lower than compressive strength. Elevation of the Poisson's ratio of the cement sheath can decrease the tangential stress.Based on the calculated results, a new cement slurry system was designed, which can decrease the Young's modulus of the cement sheath. Engineering practice demonstrates that there is no occurrence of SCP after multistage hydraulic fracturing, thus ensuring the safe production of shale gas wells. Besides, the results of this study can provide a reference for cement slurry design and wellbore integrity control during fracturing of shale gas wells.

Key words: shale gas; fracturing; finite element; cement sheath; integrity
收稿日期: 2017-06-06     
PACS:    
基金资助:国家自然科学基金—石油化工联合基金重点支持项目“页岩气水平井井筒完整性失效机理与控制方法”(U1762211) 和国家自然科学基金面上项目“长水平段非均质页岩储层非均匀分簇射孔优化研究”(51674272) 联合资助
通讯作者: * 通信作者, lijun446@vip.163.com
引用本文:   
席岩, 李军, 柳贡慧, 陶谦, 连威. 页岩气水平井压裂过程中水泥环完整性分析. 石油科学通报, 2019, 01: 57-68
链接本文:  
XI Yan, LI Jun, LIU Gonghui, TAO Qian, LIAN Wei. Research into cement sheath integrity during multistage hydraulic fracturing in shale gas wells. Petroleum Science Bulletin, 2019, 01: 57-68.
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