Gas Channeling Experiment of Cement Slurry in Different Solidification State
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摘要: 针对气体窜流问题,设计和开展了水泥浆不同凝固状态的气体窜流实验,观察了气体窜流现象,测量了气体窜流压力,分析了气体窜流形态及窜流路径,研究了气体窜流规律。研究表明,当水泥浆凝固时间较短(120 min和180 min)时,气体窜流压力较小(低于0.05 MPa),气体主要从水泥浆内部缓慢窜出,窜流通道尺寸总体较小但由下而上逐渐变大;当凝固时间增至200 min和220 min后,气体窜流压力增大至0.15 MPa和0.20 MPa,气体主要从内部突然大量猛烈窜出,窜流通道呈“糖葫芦”形和“裂缝”形且尺寸较大;凝固时间增至240 min后,窜流压力进一步增大至0.22 MPa,此时气体不能从水泥浆内部窜流,只能从水泥浆和井壁之间的胶结界面处窜出。建议针对水泥浆的不同凝固状态采用不同的策略来进行防窜设计。Abstract: Experiment on the gas channeling in different setting states of cement slurry was designed and conducted to deal with gas channeling. In the experiment, the gas channeling was observed, the gas channeling pressure measured, the form and path of gas channeling analyzed, and the pattern of gas channeling studied. The study results have shown that when the cement slurry sets in a short time (120 min and 180 min), the gas channeling pressure is low (<0.05 MPa), the gas channels slowly through the interior of the cement slurry, and the diameter of the channel is small but increases from the bottom to the top of the cement column. When the cement slurry sets in a longer time, say, 200 min and 220 min, the gas channeling pressure is increased to 0.15 MPa and 0.20 MPa, the gas channels abruptly in a high flow rate through the interior of the cement slurry, and the channel is in a shape of “serial bubbles” and “fractures” with big sizes. When the cement slurry sets in 240 min, the gas channeling pressure is increased to 0.22 MPa, and the gas can no longer channel through the interior of the cement slurry, it can only channel through the interface between the cement slurry and the borehole wall. It is thus recommended that anti-channeling measures should be designed in according with different setting states of the cement slurry.
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Key words:
- Cement slurry /
- Gas channeling /
- Static gel strength /
- Solidification State /
- Pattern of gas channeling
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[1] TINSLEY J M, MILLER E C, SABINS F L, et al. Study of the factors causing annular gas flow following primary cementing[R]. SPE 8257, 1979. [2] WEBSTER W W, EIKERTS J V. Flow after cementing--a field and laboratory study[R]. SPE 8259, 1979. [3] 西南石油学院钻井教研室. 油井水泥浆凝固过程中的失重和气窜[J]. 西南石油学院学报,1979(1):54-66.Drilling Teaching and Research Section Southwest Petroleum Institute. Weight loss and gas channeling during solidification of oil well cement slurry[J]. Journal of Southwest Petroleum Institute, 1979(1):54-66. [4] 郭小阳,刘崇建,谢应权,等. 大斜度及水平井中水泥浆的失重和气侵研究[J]. 西南石油学院学报,1996,18(2):25-34.GUO Xiaoyang, LIU Chongjian, XIE Yingquan, et al. Study of weightlessness and air cutting of cement slurry in hihgly derivated and horizontal well[J]. Journal of Southwest Petroleum Institute, 1996, 18(2):25-34. [5] 步玉环, 穆海朋, 姜林甫, 等. 水泥浆失重建模以及实验研究[J]. 钻井液与完井液, 2003, 20(6): 52-54.BU Yuhuan, MU Haipeng, JIANG Linpu, et al. Modeling and laboratory stduies on cement slurry weight loss[J]. Drilling Fluid &Completion Fluid, 2003, 20(6): 52-54. [6] 张兴国,刘崇建,杨远光,等. 水泥浆体系稳定性对水泥浆失重的重要影响[J]. 西南石油学院学报,2004,26(3):68-70.ZHANG Xingguo, LIU Chongjian, YANG Yuanguang, et al. The important influence of cement slurry’s stability on weight-loss[J]. Journal of Southwest Petroleum Institute, 2004, 26(3):68-70. [7] 方国伟. 固井水泥浆防气窜性能评价方法研究[D]. 青岛: 中国石油大学(华东), 2009.FANG Guowe. Research on gas-channeling prevention performance evaluation method of cement slurry [D]. Qingdao: China University of Petroleum (East China) , 2009. [8] 朱海金,王恩合,王学成,等. 水泥浆防窜性能实验评价及其应用[J]. 天然气工业,2013,33(11):79-85. doi: 10.3787/j.issn.1000-0976.2013.11.014ZHU Haijin, WANG Enhe, WANG Xuecheng, et al. Experimental evaluation of gas channeling prevention of cement slurries and its application[J]. Natural Gas Industry, 2013, 33(11):79-85. doi: 10.3787/j.issn.1000-0976.2013.11.014 [9] GONZALO V, AISKELY B, ALICIA C. A methodology to evaluate the gas migration in cement slurries[R]. SPE 94901, 2005. [10] SUTTON D L, RAVI K M. New method for determining downhole properties that affect gas migration and annular sealing[R]. SPE 19520, 1989. [11] 路飞飞,王永洪,刘云,等. 顺南井区高温高压防气窜尾管固井技术[J]. 钻井液与完井液,2016,33(2):88-91,95.LU Feifei, WANG Yonghong, LIU Yun, et al. Anti-channeling HTHP liner cementing technologies used in block Shunnan[J]. Drilling Fluid & Completion Fluid, 2016, 33(2):88-91,95. [12] 姚晓,吴叶成,黎学年. 国内外固井技术难点及新型水泥外加剂特性评析[J]. 钻井液与完井液,2005,22(2):11-16.YAO Xiao, WU Yecheng, LI Xuenian. Evaluation of the key cementing technology and the porperties of novel cement additives[J]. Drilling Fluid & Completion Fluid, 2005, 22(2):11-16. [13] 牛新明,张克坚,丁士东,等. 川东北地区高压防气窜固井技术[J]. 石油钻探技术,2008,36(3):10-15. doi: 10.3969/j.issn.1001-0890.2008.03.003NIU Xinming, ZHANG Kejian, DING Shidong, et al. Gas migration prevention cementing technologies in northeast Sichuan area[J]. Petroleum Drilling Techniques, 2008, 36(3):10-15. doi: 10.3969/j.issn.1001-0890.2008.03.003 [14] 王志刚,韩卫华,佟刚. 双级防气窜固井技术在也门Judayaah-1井中的应用[J]. 石油钻采工艺,2011,33(2):38-41. doi: 10.3969/j.issn.1000-7393.2011.02.010WANG Zhigang, HAN Weihua, TONG Gang. Application of two-stage gas block cementing technique on well Judayaah-1 in Yemen[J]. Oil Drilling & Production Technology, 2011, 33(2):38-41. doi: 10.3969/j.issn.1000-7393.2011.02.010 [15] 郭辛阳,宋雨媛,步玉环,等. 固井水泥浆凝固过程中地层水窜流模拟实验[J]. 实验技术与管理,2020,37(11):48-52.GUO Xinyang, SONG Yuyuan, BU Yuhuan, et al. Simulation experiment of formation water channeling during cementing slurry solidification[J]. Experimental Technology and Management, 2020, 37(11):48-52. -
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