耐高温压裂液研究现状与发展趋势
|
摘要
通过对国内外耐高温压裂液体系的系统调研,从稠化剂改性、交联剂改进、温度稳定剂研发、纳米材料杂化等方面阐述了耐高温压裂液体系的研究进展及应用现状,并对耐高温压裂液体系的发展趋势进行了预测和展望。
Based on the systematic investigation into high temperature resistant fracturing fluid system in the world and in China,the research progress and application status of high temperature resistant fracturing fluid system are expounded from the aspects of thickening agent modification,crosslinking agent improvement,temperature stabilizer research and development and nano-material hybridization.The development trend of high temperature resistant fracturing fluid system in the future is predicted and prospected.
Based on the systematic investigation into high temperature resistant fracturing fluid system in the world and in China,the research progress and application status of high temperature resistant fracturing fluid system are expounded from the aspects of thickening agent modification,crosslinking agent improvement,temperature stabilizer research and development and nano-material hybridization.The development trend of high temperature resistant fracturing fluid system in the future is predicted and prospected.
引文
[1]唐燕祥.瓜尔胶与田菁胶化学改性的研究进展[J].矿冶,1995,4(3):67-72.
[2]Surana A,Mirza Z B,Grover P D.Hydroxypropylation of guar gum and the effect of various process parameters on the yield and quality of hydroxypropyl guar gum[J].1988,33(1):49-54.
[3]卢拥军,陈彦东.超深井压裂液体系研究与应用[J].钻井液与完井液,1999,16(3):12-16.
[4]郭建春,王世彬,伍林.超高温改性瓜胶压裂液性能研究与应用[J].油田化学,2011,28(2):201-205.
[5]Cawiezel K E,Elbel J L.A new system for controlling the crosslinking rate of borate fracturing fluids[J].SPE Production Engineering,1992,7(3):275-279.
[6]Brannon H D,Ault M G.New,delayed borate-crosslinked fluid provides improved fracture conductivity in high-temperature applications[C]//SPE Annual Technical Conference and Exhibition,1991.
[7]卢拥军,杜长虹.有机硼交联压裂液在高温深井中的应用[J].钻井液与完井液,1995,12(6):24-31.
[8]任占春,秦利平.聚丙烯酰胺/有机钛冻胶压裂液[J].油田化学,1995,12(4):328-332.
[9]严芳芳.有机锆交联聚合物和羟丙基瓜胶压裂液及流变动力学研究[D].上海:华东理工大学,2014.
[10]陈刚,汤颖,张洁,等.柠檬酸铝的合成与HPAM/柠檬酸铝弱凝胶体系的配制[J].钻采工艺,2010,33(5):89-92.
[11]郑延成,薛成,张晓梅.一种酸性压裂液用交联剂的合成及性能评价[J].钻井液与完井液,2013,30(6):68-70.
[12]王满学,陈茂涛,郭小莉,等.油基冻胶压裂液高温稳定剂PW-1的研究与应用[J].油田化学,2000,17(1):34-38.
[13]杨兵,黄贵存,李尚贵.川西高温压裂液室内研究[J].石油钻采工艺,2009,31(1):117-120.
[14]邹鹏,杨庭安,任秋军.复合压裂液耐温性的影响因素研究[J].石油化工应用,2015,(1):22-25.
[15]Huang T,Crews J B. Nanotechnology applications in viscoelastic surfactant stimulation fluids[C]//European Formation Damage Conference,2007.
[16]陈明贵,杨晓花,唐恒志,等.纳米技术在黏弹性表面活性剂增产流体中的应用[J].国外油田工程,2008,24(3):3-4.
[17]Fan H J,Luo M L,Jia Z L,et al.Effect of nano-SiO2on the rheology of anionic viscoelastic solutions formed by the biodegradable surfactant fatty acid methyl ester sulfonate[J].Materials Science Forum,2011,694:64-67.
[18]罗明良,高遵美,黄波,等.纤维基纳米复合清洁压裂液性能研究[J].应用化工,2012,41(12):2060-2063.
[19]雷小洋,唐善法,余吉良,等.GA 16复合清洁压裂液的制备及其性能研究[J].长江大学学报(自科版),2015,38(31):34-36.
[20]Liang F,Al-Muntasheri G A,Li L.Maximizing performance of residue-free fracturing fluids using nanomaterials at high temperatures[C]//SPE Western Regional Meeting,2016.
[21]Guzmn J D,Pineda D,Franco C A,et al.Effect of nanoparticle inclusion in fracturing fluids applied to tight gas-condensate reservoirs:Reduction of methanol loading and the associated formation damage[J]. Journal of Natural Gas Science&Engineering,2017,40:347-355.
[2]Surana A,Mirza Z B,Grover P D.Hydroxypropylation of guar gum and the effect of various process parameters on the yield and quality of hydroxypropyl guar gum[J].1988,33(1):49-54.
[3]卢拥军,陈彦东.超深井压裂液体系研究与应用[J].钻井液与完井液,1999,16(3):12-16.
[4]郭建春,王世彬,伍林.超高温改性瓜胶压裂液性能研究与应用[J].油田化学,2011,28(2):201-205.
[5]Cawiezel K E,Elbel J L.A new system for controlling the crosslinking rate of borate fracturing fluids[J].SPE Production Engineering,1992,7(3):275-279.
[6]Brannon H D,Ault M G.New,delayed borate-crosslinked fluid provides improved fracture conductivity in high-temperature applications[C]//SPE Annual Technical Conference and Exhibition,1991.
[7]卢拥军,杜长虹.有机硼交联压裂液在高温深井中的应用[J].钻井液与完井液,1995,12(6):24-31.
[8]任占春,秦利平.聚丙烯酰胺/有机钛冻胶压裂液[J].油田化学,1995,12(4):328-332.
[9]严芳芳.有机锆交联聚合物和羟丙基瓜胶压裂液及流变动力学研究[D].上海:华东理工大学,2014.
[10]陈刚,汤颖,张洁,等.柠檬酸铝的合成与HPAM/柠檬酸铝弱凝胶体系的配制[J].钻采工艺,2010,33(5):89-92.
[11]郑延成,薛成,张晓梅.一种酸性压裂液用交联剂的合成及性能评价[J].钻井液与完井液,2013,30(6):68-70.
[12]王满学,陈茂涛,郭小莉,等.油基冻胶压裂液高温稳定剂PW-1的研究与应用[J].油田化学,2000,17(1):34-38.
[13]杨兵,黄贵存,李尚贵.川西高温压裂液室内研究[J].石油钻采工艺,2009,31(1):117-120.
[14]邹鹏,杨庭安,任秋军.复合压裂液耐温性的影响因素研究[J].石油化工应用,2015,(1):22-25.
[15]Huang T,Crews J B. Nanotechnology applications in viscoelastic surfactant stimulation fluids[C]//European Formation Damage Conference,2007.
[16]陈明贵,杨晓花,唐恒志,等.纳米技术在黏弹性表面活性剂增产流体中的应用[J].国外油田工程,2008,24(3):3-4.
[17]Fan H J,Luo M L,Jia Z L,et al.Effect of nano-SiO2on the rheology of anionic viscoelastic solutions formed by the biodegradable surfactant fatty acid methyl ester sulfonate[J].Materials Science Forum,2011,694:64-67.
[18]罗明良,高遵美,黄波,等.纤维基纳米复合清洁压裂液性能研究[J].应用化工,2012,41(12):2060-2063.
[19]雷小洋,唐善法,余吉良,等.GA 16复合清洁压裂液的制备及其性能研究[J].长江大学学报(自科版),2015,38(31):34-36.
[20]Liang F,Al-Muntasheri G A,Li L.Maximizing performance of residue-free fracturing fluids using nanomaterials at high temperatures[C]//SPE Western Regional Meeting,2016.
[21]Guzmn J D,Pineda D,Franco C A,et al.Effect of nanoparticle inclusion in fracturing fluids applied to tight gas-condensate reservoirs:Reduction of methanol loading and the associated formation damage[J]. Journal of Natural Gas Science&Engineering,2017,40:347-355.
© 2004-2018 中国地质图书馆版权所有 京ICP备05064691号 京公网安备11010802017129号 地址:北京市海淀区学院路29号 邮编:100083 电话:办公室:(+86 10)66554848;文献借阅、咨询服务、科技查新:66554700 |