深层页岩气水平井“增净压、促缝网、保充填”压裂改造模式——以四川盆地东南部丁山地区为例
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摘要
由于埋藏深、地质特征复杂,致使针对中浅层页岩气藏的压裂工艺不能完全满足四川盆地东南部丁山地区上奥陶统五峰组—下志留统龙马溪组深层页岩气储层改造的需要。为此,将地质与工程研究紧密结合,优选页岩气"地质与工程双甜点"区,开展深层页岩气水平井压裂技术攻关研究,对以往仅适用于中浅层页岩气储层的压裂模式进行改进,并将改进后的压裂模式与工艺应用于丁山地区3口深层页岩气井。研究结果表明:①该区西北部深层页岩气储层具备地质、工程"双甜点"特性,天然裂缝、层理缝发育为压裂后复杂缝网的形成创造了有利条件;②基于"双甜点"区域,研究形成了"前置酸+胶液+滑溜水+胶液"混合压裂模式,采用高黏滑溜水以提高液体携砂能力及造缝效果、"控近扩远"压裂工艺以提高远井地带有效改造体积、超高压装置以提高施工排量和缝内净压力;③3口深层页岩气井经过储层改造后,增产效果显著,测试页岩气产量介于10.50×10~4~20.56×10~4 m~3/d。结论认为,改进后的压裂模式与工艺可以为该区深层页岩气储层改造提供技术途径,为深层页岩气勘探开发取得突破提供支持。
The deep shale gas reservoirs of Upper Ordovician Wufeng–Lower Silurian Longmaxi Formation in the Dingshan area of the southeastern Sichuan Basin have a great burial depth and complicated geologic features, so the fracturing technologies that are used for medium–shallow shale gas reservoirs are not suitable for their stimulation. In this paper, "double sweet spot" zones of shale gas were selected by combining engineering and geological research. The horizontal well fracturing technology suitable for deep shale gas reservoir was developed. And the fracturing mode suitable for medium–shallow shale gas reservoirs was improved. In addition, the improved fracturing mode and technology were applied in 3 deep shale gas wells in the Dingshan area. And the following research results were obtained. First, the deep shale gas reservoirs in the northwest of the Dingshan area have the characteristics of "double sweet spot" of geology and fracturing, and the development of natural fractures and bedding fractures provides a favorable condition for the formation of complex fracture networks after fracturing. Second, a combined fracturing mode of "pre acid + gel + slickwater + gel" was developed for the "double sweet spot" zones. In this mode, high-viscosity slickwater is adopted to increase the sand-carrying capacity of liquid and enhance the fracture-creating effect, the fracturing technology of "controlling the near and extending the far" can increase the effective stimulated reservoir volume far from the well, and the ultra-high pressure facility can increase the fracturing displacement and the net pressure in fractures. Third, after reservoir stimulation, 3 deep shale gas wells present remarkable stimulation results, and their shale gas production rate during the testing is in the range of 10.50×10~4–20.56×10~4 m~3/d. In conclusion, the improved fracturing mode and technology can provide a technical method for the stimulation of deep shale gas reservoirs in the Dingshan area, as well as a support for the breakthrough of exploration and development of deep shale gas reservoirs.
The deep shale gas reservoirs of Upper Ordovician Wufeng–Lower Silurian Longmaxi Formation in the Dingshan area of the southeastern Sichuan Basin have a great burial depth and complicated geologic features, so the fracturing technologies that are used for medium–shallow shale gas reservoirs are not suitable for their stimulation. In this paper, "double sweet spot" zones of shale gas were selected by combining engineering and geological research. The horizontal well fracturing technology suitable for deep shale gas reservoir was developed. And the fracturing mode suitable for medium–shallow shale gas reservoirs was improved. In addition, the improved fracturing mode and technology were applied in 3 deep shale gas wells in the Dingshan area. And the following research results were obtained. First, the deep shale gas reservoirs in the northwest of the Dingshan area have the characteristics of "double sweet spot" of geology and fracturing, and the development of natural fractures and bedding fractures provides a favorable condition for the formation of complex fracture networks after fracturing. Second, a combined fracturing mode of "pre acid + gel + slickwater + gel" was developed for the "double sweet spot" zones. In this mode, high-viscosity slickwater is adopted to increase the sand-carrying capacity of liquid and enhance the fracture-creating effect, the fracturing technology of "controlling the near and extending the far" can increase the effective stimulated reservoir volume far from the well, and the ultra-high pressure facility can increase the fracturing displacement and the net pressure in fractures. Third, after reservoir stimulation, 3 deep shale gas wells present remarkable stimulation results, and their shale gas production rate during the testing is in the range of 10.50×10~4–20.56×10~4 m~3/d. In conclusion, the improved fracturing mode and technology can provide a technical method for the stimulation of deep shale gas reservoirs in the Dingshan area, as well as a support for the breakthrough of exploration and development of deep shale gas reservoirs.
引文
[1]冉琦,陈勇,齐晴,董清源,付柘.丁山地区龙马溪组页岩气保存条件分析[J].石油地质与工程,2017,31(4):22-25.Ran Qi,Chen Yong,Qi Qing,Dong Qingyuan&Fu Tuo.Preservation conditions of shale gas in Longmaxi Formation of Dingshan area[J].Petroleum Geology and Engineering,2017,31(4):22-25.
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[6]李文锦,段华,代俊清.网络压裂技术在川东南涪陵地区页岩储层改造中的应用[J].天然气地球科学,2016,27(3):554-560.Li Wenjin,Duan Hua&Dai Junqing.Application of network fracturing technology to reconstruct shale reservoir in Fuling area of southeast Sichuan Basin[J].Natural Gas Geoscience,2016,27(3):554-560.
[7]黄仁春,魏祥峰,王强.四川盆地东南缘丁山地区页岩气成藏富集的关键控制因素[J].海相油气地质,2017,22(2):25-30.Huang Renchun,Wei Xiangfeng&Wang Qiang.Key factors of shale gas accumulation in Dingshan area of southeastern Sichuan Basin[J].Marine Origin Petroleum Geology,2017,22(2):25-30.
[8]曾义金,陈作,卞晓冰.川东南深层页岩气分段压裂技术的突破与认识[J].天然气工业,2016,36(1):61-67.Zeng Yijin,Chen Zuo&Bian Xiaobing.Breakthrough in staged fracturing technology for deep shale gas reservoirs in SE Sichuan Basin and its implications[J].Natural Gas Industry,2016,36(1):61-67.
[9]蒋廷学,卞晓冰,王海涛,李双明,贾长贵,刘红磊,等.深层页岩气水平井体积压裂技术[J].天然气工业,2017,37(1):90-96.Jiang Tingxue,Bian Xiaobing,Wang Haitao,Li Shuangming,Jia Changgui,Liu Honglei,et al.Volume fracturing of deep shale gas horizontal wells[J].Natural Gas Industry,2017,37(1):90-96.
[10]胡永全,贾锁刚,赵金洲,张烨,米强波.缝网压裂控制条件研究[J].西南石油大学学报(自然科学版),2013,35(4):126-132.Hu Yongquan,Jia Suogang,Zhao Jinzhou,Zhang Ye&Mi Qiangbo.Study on controlling conditions in network hydraulic fracturing[J].Journal of Southwest Petroleum University(Science&Technology Edition),2013,35(4):126-132.
[11]李勇明,彭瑀,王中泽.页岩气压裂增产机理与施工技术分析[J].西南石油大学学报(自然科学版),2013,35(2):90-96.Li Yongming,Peng Yu&Wang Zhongze.Analysis of shale fracture stimulation mechanism and operating techniques[J].Journal of Southwest Petroleum University(Science&Technology Edition),2013,35(2):90-96.
[12]衡帅,杨春和,郭印同,王传洋,王磊.层理对页岩水力裂缝扩展的影响研究[J].岩石力学与工程学报,2015,34(2):228-237.Heng Shuai,Yang Chunhe,Guo Yintong,Wang Chuanyang&Wang Lei.Influence of bedding planes on hydraulic fracture propagation in shale formations[J].Chinese Journal of Rock Mechanics and Engineering,2015,34(2):228-237.
[13]周健,蒋廷学.四川页岩压裂裂缝扩展实验及力学特性研究[J].中国科学:物理学力学天文学,2017,47(11):1-8.Zhou Jian&Jiang Tingxue.Experimental study and mechanical properties analysis of fracture propagation in shale formation,Sichuan Basin[J].Scientia Sinica(Physica,Mechanica&Astronomica),2017,47(11):1-8.
[14]赵金洲,任岚,沈骋,李勇明.页岩气储层缝网压裂理论与技术研究新进展[J].天然气工业,2018,38(3):1-14.Zhao Jinzhou,Ren Lan,Shen Cheng&Li Yongming.Latest research progresses in network fracturing theories and technologies for shale gas reservoirs[J].Natural Gas Industry,2018,38(3):1-14.
[15]贾长贵,李双明,王海涛,蒋廷学.页岩储层网络压裂技术研究与试验[J].中国工程科学,2012,14(6):106-112.Jia Changgui,Li Shuangming,Wang Haitao&Jiang Tingxue.Shale reservoir network fracturing technology research and experiment[J].Engineering Science,2012,14(6):106-112.
[2]魏祥峰,赵正宝,王庆波,刘珠江,周敏,张晖.川东南綦江丁山地区上奥陶统五峰组-下志留统龙马溪组页岩气地质条件综合评价[J].地质论评,2017,63(1):153-164.Wei Xiangfeng,Zhao Zhengbao,Wang Qingbo,Liu Zhujiang,Zhou Min&Zhang Hui.Comprehensive evaluation on geological conditions of the shale gas in upper Ordovician Wufeng Formation-Lower Silurian Longmaxi Formation in Dingshan area,Qijiang,Southeastern Sichuan[J].Geological Review,2017,63(1):153-164.
[3]周德华,焦方正,贾长贵,蒋廷学,李真祥.JY1HF页岩气水平井大型分段压裂技术[J].石油钻探技术,2014,42(1):75-80.Zhou Dehua,Jiao Fangzheng,Jia Changgui,Jiang Tingxue&Li Zhenxiang.Large-scale multi-stage hydraulic fracturing technology for shale gas horizontal well JY1HF[J].Petroleum Drilling Techniques,2014,42(1):75-80.
[4]蒋廷学,贾长贵,王海涛,孙海成.页岩气网络压裂设计方法研究[J].石油钻探技术,2011,39(3):36-40.Jiang Tingxue,Jia Changgui,Wang Haitao&Sun Haicheng.Study on network fracturing design method in shale gas[J].Petroleum Drilling Techniques,2011,39(3):36-40.
[5]王志刚.涪陵焦石坝地区页岩气水平井压裂改造实践与认识[J].石油与天然气地质,2014,35(3):425-430.Wang Zhigang.Practice and cognition of shale gas horizontal well fracturing stimulation in Jiaoshiba of Fuling area[J].Oil&Gas Geology,2014,35(3):425-430.
[6]李文锦,段华,代俊清.网络压裂技术在川东南涪陵地区页岩储层改造中的应用[J].天然气地球科学,2016,27(3):554-560.Li Wenjin,Duan Hua&Dai Junqing.Application of network fracturing technology to reconstruct shale reservoir in Fuling area of southeast Sichuan Basin[J].Natural Gas Geoscience,2016,27(3):554-560.
[7]黄仁春,魏祥峰,王强.四川盆地东南缘丁山地区页岩气成藏富集的关键控制因素[J].海相油气地质,2017,22(2):25-30.Huang Renchun,Wei Xiangfeng&Wang Qiang.Key factors of shale gas accumulation in Dingshan area of southeastern Sichuan Basin[J].Marine Origin Petroleum Geology,2017,22(2):25-30.
[8]曾义金,陈作,卞晓冰.川东南深层页岩气分段压裂技术的突破与认识[J].天然气工业,2016,36(1):61-67.Zeng Yijin,Chen Zuo&Bian Xiaobing.Breakthrough in staged fracturing technology for deep shale gas reservoirs in SE Sichuan Basin and its implications[J].Natural Gas Industry,2016,36(1):61-67.
[9]蒋廷学,卞晓冰,王海涛,李双明,贾长贵,刘红磊,等.深层页岩气水平井体积压裂技术[J].天然气工业,2017,37(1):90-96.Jiang Tingxue,Bian Xiaobing,Wang Haitao,Li Shuangming,Jia Changgui,Liu Honglei,et al.Volume fracturing of deep shale gas horizontal wells[J].Natural Gas Industry,2017,37(1):90-96.
[10]胡永全,贾锁刚,赵金洲,张烨,米强波.缝网压裂控制条件研究[J].西南石油大学学报(自然科学版),2013,35(4):126-132.Hu Yongquan,Jia Suogang,Zhao Jinzhou,Zhang Ye&Mi Qiangbo.Study on controlling conditions in network hydraulic fracturing[J].Journal of Southwest Petroleum University(Science&Technology Edition),2013,35(4):126-132.
[11]李勇明,彭瑀,王中泽.页岩气压裂增产机理与施工技术分析[J].西南石油大学学报(自然科学版),2013,35(2):90-96.Li Yongming,Peng Yu&Wang Zhongze.Analysis of shale fracture stimulation mechanism and operating techniques[J].Journal of Southwest Petroleum University(Science&Technology Edition),2013,35(2):90-96.
[12]衡帅,杨春和,郭印同,王传洋,王磊.层理对页岩水力裂缝扩展的影响研究[J].岩石力学与工程学报,2015,34(2):228-237.Heng Shuai,Yang Chunhe,Guo Yintong,Wang Chuanyang&Wang Lei.Influence of bedding planes on hydraulic fracture propagation in shale formations[J].Chinese Journal of Rock Mechanics and Engineering,2015,34(2):228-237.
[13]周健,蒋廷学.四川页岩压裂裂缝扩展实验及力学特性研究[J].中国科学:物理学力学天文学,2017,47(11):1-8.Zhou Jian&Jiang Tingxue.Experimental study and mechanical properties analysis of fracture propagation in shale formation,Sichuan Basin[J].Scientia Sinica(Physica,Mechanica&Astronomica),2017,47(11):1-8.
[14]赵金洲,任岚,沈骋,李勇明.页岩气储层缝网压裂理论与技术研究新进展[J].天然气工业,2018,38(3):1-14.Zhao Jinzhou,Ren Lan,Shen Cheng&Li Yongming.Latest research progresses in network fracturing theories and technologies for shale gas reservoirs[J].Natural Gas Industry,2018,38(3):1-14.
[15]贾长贵,李双明,王海涛,蒋廷学.页岩储层网络压裂技术研究与试验[J].中国工程科学,2012,14(6):106-112.Jia Changgui,Li Shuangming,Wang Haitao&Jiang Tingxue.Shale reservoir network fracturing technology research and experiment[J].Engineering Science,2012,14(6):106-112.
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