[1]鄢宇杰,付荣耀,李 楠,等.电弧压裂技术研究现状与发展[J].高压电器,2019,55(09):71-77.[doi:10.13296/j.1001-1609.hva.2019.09.010]
 YAN Yujie,FU Rongyao,LI Nan,et al.Research Status and Development of Arc Fracturing Technology[J].High Voltage Apparatus,2019,55(09):71-77.[doi:10.13296/j.1001-1609.hva.2019.09.010]
点击复制

电弧压裂技术研究现状与发展()
分享到:

《高压电器》[ISSN:1001-1609/CN:61-11271/TM]

卷:
第55卷
期数:
2019年09期
页码:
71-77
栏目:
综述
出版日期:
2019-09-30

文章信息/Info

Title:
Research Status and Development of Arc Fracturing Technology
作者:
鄢宇杰1 付荣耀23 李 楠1 孙鹞鸿23 严 萍23
(1. 中国石化西北分公司工程技术研究院, 乌鲁木齐 830011; 2. 中国科学院电工研究所 , 北京 100190; 3. 中国科学院 大学, 北京 100039)
Author(s):
YAN Yujie1 FU Rongyao23 LI Nan1 SUN Yaohong23 YAN Ping23
(1. Research Institute of Engineering Technology, Northwest Oilfield Branch Company, SINOPEC, Urumqi 830011, China; 2. Institute of Electrical Engineering, Chinese Academy of Sciences, Beijing 100190, China; 3. University of Chinese Academy of Sciences, Beijing 100039, China)
关键词:
液电效应 电弧压裂 解堵 脉冲放电
Keywords:
liquid electric effect arc fracturing plugging removal pulse discharge
DOI:
10.13296/j.1001-1609.hva.2019.09.010
摘要:
介绍了中国油气开采工程中使用的各种压裂技术优缺点,根据工程需要提出了电弧压 裂技术,分析了电弧压裂技术的工作原理以及国内外研究现状,并对目前电弧压裂工程应用进 行了分析,总结了电弧压裂技术对油气储层的适用性。根据目前电弧压裂装置深井下高温高压 的作业难点,并提出了井下压裂工具改进的实施方案和大面积储层改造的思路,为电弧压裂技 术的发展提供工程应用参考。
Abstract:
The advantages and disadvantages of using various fracturing technology for gas production engineering oil in China is introduced. According to the need of the project put forward arc fracturing technology, the working principle of arc fracturing technology and the research status at home and abroad are analyzed. The analysis for the engineering application of the engineering application is made. The applicability of arc fracturing technology to oil and gas reservoirs are summarized. According to the difficulty of high temperature and high pressure in deep well, the improved implementation plan of underground fracturing device and the idea of large area reservoir reconstruction are put forward. The technical solutions provide reference for engineering application in the development of arc fracturing technology.

参考文献/References:

[1] 董大忠,邹才能,杨 桦,等. 中国页岩气勘探开发进展与发展前景[J]. 石油学报, 2012,33(s1):107-114. DONG Dazhong,ZOU Caineng,YANG Hua,et al. Progress and prospects of shale gas exploration and development in China[J]. Acta Petrolei Sinica,2012,33(s1): 107-114.
[2] 贾承造,郑 民,张永峰. 中国非常规油气资源与勘探开发前景[J]. 石油勘探与 开发,2012,39(2):129-136. JIA Chengzao,ZHENG Min,ZHANG Yongfeng. Unconventional hydrocarbon resources in China and the prospect of exploration and development[J]. Petroleum Exploration and Development,2012,39(2): 129-136.
[3] 张金川,徐 波,聂海宽,等. 中国页岩气资源勘探潜力[J]. 天然气工业,2008 ,28(6):136-140. ZHANG Jinchuan,XU Bo,NIE Haikuan,et al. Exploration potential of shale gas resources in China[J]. Natural Gas Industry,2008,28(6): 136-140.
[4] 蒋裕强,董大忠,漆 麟,等. 页岩气储层的基本特征及其评价[J]. 天然气工 业,2010,30(10):7-12. JIANG Yuqiang,DONG Dazhong,QI Lin,et al. Basic features and evaluation of shale gas reservoirs[J]. Natural Gas Industry,2010, 30(10):7-12.
[5] 蒋金宝,林英松,阮新芳,等. 低渗透油藏改造技术的研究及发展[J]. 钻采工 艺,2005,28(5):50-53. JIANG Jinbao,LIN Yingsong,RUAN Xinfang,et al. Development of low permeability reservoir improvement[J]. Drilling & Production Technology,2005,28(5):50-53.
[6] 胡永全,林 辉,赵金洲,等. 重复压裂技术研究[J]. 天然气工业,2004,24(3) :72-75. HU Yongquan,LIN Hui,ZHAO Jinzhou,et al. Study on repetitive fracturing technology[J]. Natural Gas Industry,2004,24(3): 72-75.
[7] 杨丙秀,蒋廷学,丁云宏,等. 低孔低渗储集层探井低伤害压裂技术研究与应用 [J]. 石油勘探与开发,2005,32(2):119-122. YANG Bingxiu,JIANG Tingxue,DING Yunhong,et al. Low damage fracturing technology for explo-ration wells in low porosity and permeability reservoirs)[J]. Petroleum Exploration & Development, 2005,32(2):119-122.
[8] 唐 颖,唐 玄,王广源,等. 页岩气开发水力压裂技术综述[J]. 地质通报, 2011,30(s1):393-399. TANG Ying,TANG Xuan,WANG Guangyuan,et al. Summary of hydraulic fracturing technology in shale gas development[J]. Geological Bulletin of China,2011,30(s1):393-399.
[9] 唐远游,陶云奇. 应用水力压裂技术提高单一低渗煤层瓦斯抽采效果[J]. 煤矿安 全,2012,43(9):1-3. TANG Yuanyou,TAO Yunqi. Using hydraulic fracturing technology to improve gas extraction effect of single low-permeability coal seam [J]. Safety in Coal Mines,2012,43(9): 1-3.
[10] TOUYA G,REESS T,PéCASTAING L,et al. Development of subsonic electrical discharges in water and measurements of the associated pressure waves [J]. Journal of Physics D - Applied Physics,2006,39(9): 5236-5244.
[11] CHO S H,KANEKO K. Influence of the applied pressure waveform on the dynamic fracture processes in rock[J]. International Journal of Rock Mechanics and Mining Sciences,2004,41(5): 771-784.
[12] OSHITA D,HOSSEINI S,MIYAMOTO Y,et al. Study of underwater shock waves and cavitation bubbles generated by pulsed electric discharges[J]. IEEE Transactions on Dielectrics and Electrical Insulation,2013,20(4): 1273-1278.
[13] LAYCAK J F. The effects of hydrostatic pressure on the gas accumulation following a single spark discharge in a liquid dielectric [C]//Electrical Insulation Conference. [S.l.]:[s. n.],1967:277-280.
[14] CHEN Wen,MAUREL O,REESS T,et al. Experimental study on an alternative oil stimulation technique for tight gas reservoirs based on dynamic shock waves generated by pulsed arc electrohydraulic discharges[J]. Journal of Petroleum Science and Engineering,2012,88-89(SI): 67-74.
[15] MARTIN J,REESS T,FERRON A D,et al. Influence of hydrostatic pressure and temperature on the water dielectric strength and on the dynamic pressure wave[C]//Power Modulator and High Voltage Conference. [S.l.]:IEEE, 2012:370-373.
[16] MAUREL O,REESS T,MATALLAH M,et al. Electrohydraulic shock wave Generation as a means to increase intrinsic permeability of mortar[J]. Cement and Concrete Research,2010,40(12): 1631-1638.
[17] CHEN Wen,MAUREL O,LA BORDERIE C,et al. Experimental and numerical study of shock wave propagation in water generated by pulsed arc electrohydraulic discharges[J]. Heat and Mass Transfer,2014,50(5): 673-684.
[18] 刘思维,刘 毅,李显东,等. 水间隙击穿放电模式对激波强度的影响分析[J]. 中国电机工程学报,2017,37(10):2807-2815. LIU Siwei,LIU Yi,LI Xiandong,et al. Effect of electrical breakdown discharge modes on shock wave intensity inwater[J]. Proceedings of the CSEE,2017,37(10): 2807-2815.
[19] 刘 毅,李志远,李显东,等. 水中大电流脉冲放电激波影响因素分析[J]. 中国 电机工程学报,2017,37(9):2741-2750. LIU Yi,LI Zhiyuan,LI Xiandong,et al. Effect factors of the characteristics of shock waves induced by underwater high current pulsed discharge[J]. Proceedings of the CSEE,2017,37(9): 2741-2750.
[20] 卢新培,张寒虹,潘 垣,等. 水中脉冲放电的压力特性研究[J]. 爆炸与冲击 ,2001,21(4):282-286. LU Xinpei,ZHANG Hanhong,PAN Yuan,et al. Study on the pressure characteristics of pulsed discharge in water[J]. Explosion & Shock Waves ,2001,21(4):282-286.
[21] 卢新培,潘 垣,张寒虹. 水中脉冲放电的电特性与声辐射特性研究[J]. 物理学 报,2002,51(7):1549-1553. LU Xinpei,PAN Yuan,ZHANG Hanhong. The electrical and acoustical characteristics of pulsed discharge in water[J]. Acta Physica Sinica,2002,51(7): 1549-1553.
[22] 卢新培,潘 垣,刘克富,等. 水中放电等离子体状态方程的理论研究[J]. 高 压物理学报,2001,15(2):103-110. LU Xinpei,PAN Yuan,LIU Kefu,et al. The state equations of plasma produced by pulse discharge in water[J]. Chinese Journal of High Pressure Physics,2001,15(2):103-110.
[23] 秦 勇,邱爱慈,张永民. 高聚能重复强脉冲波煤储层增渗新技术试验与探索 [J]. 煤炭科学技术,2014(6):1-7. QIN Yong,QIU Aici,ZHANG Yongmin. Experiment and discovery on permeability improved technology of coal reservoir based on repeated strong pulse waves of high energy accumulation[J]. Coal Science & Technology,2014(6):1-7.
[24] HAN Ruoyu,ZHOU Haibin,LIU Qiaojue,et al. Generation of electrohydraulic shock waves by plasma-ignited energetic materials: I. Fundamental mechanisms and processes[J]. IEEE Transactions on Plasma Science, 2015,43(12): 3999-4008.
[25] ZHOU Haibin,HAN Ruoyu,LIU Qiaojue,et al. Generation of electrohydraulic shock waves by plasma-ignited energetic materials: II. Influence of wire configuration and stored energy[J]. IEEE Transactions on Plasma Science, 2015,43(12): 4009-4016.
[26] ZHOU Haibin,ZHANG Yongmin,LI Hengle,et al. Generation of electrohydraulic shock waves by Plasma-Ignited energetic materials: III. Shock wave characteristics with three discharge loads[J]. IEEE Transactions on Plasma Science,2015,43(12): 4017-4023.
[27] 周海滨,刘巧珏,赵有志,等. 脉冲大电流放电引爆含能材料产生冲击波的储层 改造[J]. 强激光与粒子束,2016,28(4):202-206. ZHOU Haibin,LIU Qiaojue,ZHAO Youzhi,et al. Transformation of oil-and-gas reservoir with shock waves by high current pulsed discharge ignited energetic materials explosion[J]. High Power Laser and Particle Beams,2016,28(4): 202-206.
[28] 孙凤举,曾正中,邱毓昌,等. 一种用于油水井解堵的脉冲大电流源[J]. 高电压 技术,1999,25(2):47-49. SUN Fengju,ZENG Zhengzhong,QIU Yuchang,et al. Pulse high current power supply used for dredging oil & water wells[J]. High Voltage Engineering,1999,25(2): 47-49.
[29] 孙鹞鸿,孙广生,严 萍,等. 高压电脉冲采油技术发展[J]. 高电压技术,2002 ,28(1):41-42. SUN Yaohong,SUN Guangsheng,YAN Ping,et al. The development of the electric pulse oil-mining technology,high voltage engineering[J]. High Voltage Engineering,2002,28(1): 41-42.
[30] 金明剑,孙鹞鸿. 不同参数条件下水中脉冲放电的电学特性研究[J]. 高电压技 术,2004,30(7):46-49. JIN Mingjian,SUN Yaohong. Electrical characteristics of underwater pulsed discharge under different experiment parameters[J]. High Voltage Engineering,2004,30(7):46-49.
[31] 付荣耀,周 健,孙鹞鸿,等. 无围压下高电压脉冲放电在岩石压裂中的应用 [J]. 高电压技术,2015,41(12):4055-4059. FU Rongyao,ZHOU Jian,SUN Yaohong,et al. Application of high voltage pulse discharge in rock fracturing without confining pressure[J]. High Voltage Engineering,2015,41(12):4055-4059.
[32] FU Rongyao,SUN Yaohong,FAN Ailong,et al. The research of high voltage power power supply with a high-energy arc fracturing device[C]//IEEE Pulsed-Power-Conference(PPC). Austin,TX,USA:IEEE,2015:1-4.
[33] SUN Yaohong,FU Rongyao,FAN Ailong,et al. Study of rock fracturing generated by pulsed discharging under confining pressure[C]//IEEE Pulsed Power Conference(PPC). Austin,TX,USA:IEEE,2015:1-4.
[34] 贾少华,赵金昌,尹志强,等. 基于高压电脉冲煤体增透的水激波波前时间变化 规律研究[J]. 太原理工大学学报,2015(6):680-684. JIA Shaohua,ZHAO Jinchang,YIN Zhiqiang,et al. Research on change laws of front time in water shock-wave based on pulsed high-voltage discharge in permeability enhancement in coal seams[J]. Journal of Taiyuan University of Technology,2015(6): 680-684.
[35] 闫 东,卞德存,阙梦辉. 水中高压放电基本现象分析[J]. 煤炭技术,2014, 33(7):294-296. YAN Dong,BIAN Decun,QUE Menghui. Basic phenomenon analysis of high voltage discharge in water[J]. Coal Technology,2014,33(7): 294-296.
[36] 鲍先凯,杨东伟,段东明,等. 高压电脉冲水力压裂法煤层气增透的试验与数值 模拟[J]. 岩石力学与工程学报,2017,36(10):2415-2423. BAO Xiankai,YANG Dongwei, DUAN Dongming,et al. The experiment and numerical simulation of coalbed methane penetration by hydraulic fracturing with hing-voltage electric pulse[J]. Chinese Journal of Rock Mechanics and Engineering,2017,36(10): 2415-2423.

备注/Memo

备注/Memo:
收稿日期:2019-06-22; 修回日期:2019-08-24 基金项目:中石化西北油田分公司调研项目(高能电弧压裂破岩实验及评价)。 Reseach Project of sinopec northwest oilfield branch(Experiment and Evaluation on High Energy Arc fracturing Rock Breaking).鄢宇杰(1986—),男,工程师,现从事储层改造研究工作。 付荣耀(1986—),男,博士,助理研究员,研究方向为脉冲功率以及应用(通讯作者) 。
更新日期/Last Update: 2019-09-10