| Citation: |
ZHANG Dongqing, WAN Yunqiang, ZHANG Wenping, et al. Optimal and fast drilling technologies for stereoscopic development of the Fuling shale [J]. Petroleum Drilling Techniques,2023, 51(2):16-21. DOI: 10.11911/syztjs.2022097
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In order to further improve the recovery of the Fuling Shale Gas Field, stereoscopic development technologies, i.e. infill drilling in lower layers, appraising middle layers, and developing upper layers, were first studied and practiced. However, many problems were encountered during drilling, such as pressure system changing, serious fracturing interference, difficult anti-collision and obstacle bypassing, and the challenge of precise steering control and rate of penetration(ROP) increase. Therefore, researches on the engineering design of stereoscopic well group development, ROP increase, trajectory control based on logging while drilling(LWD), low-cost and high-performance shale drilling fluids, and long-term sealing and cementing technologies for shale gas wells were carried out, and the optimal and fast drilling technologies for stereoscopic development of the Fuling Shale Gas Field was developed, which was successfully applied in 185 wells in the field. Compared with previous wells, the ROP was increased by 25.5%, and the drilling duration was reduced by 27.8%. The optimal and fast drilling technologies for the stereoscopic development of the Fuling Shale Gas Field can serve as reference and instruction to the exploration and development of shale in other blocks in China.
| [1] |
吴西顺,孙张涛,杨添天,等. 全球非常规油气勘探开发进展及资源潜力[J]. 海洋地质前沿,2020,36(4):1–17. doi: 10.16028/j.1009-2722.2019.065
WU Xishun, SUN Zhangtao, YANG Tiantian, et al. Global progress in exploration and development of unconventional hydrocarbons and assessment of resources potential[J]. Marine Geology Frontiers, 2020, 36(4): 1–17. doi: 10.16028/j.1009-2722.2019.065
|
| [2] |
范红康,刘劲歌,臧艳彬,等. 涪陵页岩气田焦石坝区块调整井钻井技术[J]. 石油钻探技术,2021,49(3):48–54. doi: 10.11911/syztjs.2020122
FAN Hongkang, LIU Jinge, ZANG Yanbin, et al. Drilling technology for adjustment wells of the Jiaoshiba Block in the Fuling Shale Gas Field[J]. Petroleum Drilling Techniques, 2021, 49(3): 48–54. doi: 10.11911/syztjs.2020122
|
| [3] |
孙焕泉,周德华,蔡勋育,等. 中国石化页岩气发展现状与趋势[J]. 中国石油勘探,2020,25(2):14–26. doi: 10.3969/j.issn.1672-7703.2020.02.002
SUN Huanquan, ZHOU Dehua, CAI Xunyu, et al. Progress and prospect of shale gas development of Sinopec[J]. China Petroleum Exploration, 2020, 25(2): 14–26. doi: 10.3969/j.issn.1672-7703.2020.02.002
|
| [4] |
宋保健,孙凯,乐守群,等. 涪陵页岩气田钻井提速难点与对策分析[J]. 钻采工艺,2019,42(4):9–12. doi: 10.3969/J.ISSN.1006-768X.2019.04.03
SONG Baojian, SUN Kai, LE Shouqun, et al. Drilling acceleration challenges at Fuling Shale Gas Field and solutions[J]. Drilling & Production Technology, 2019, 42(4): 9–12. doi: 10.3969/J.ISSN.1006-768X.2019.04.03
|
| [5] |
贾利春,李枝林,张继川,等. 川南海相深层页岩气水平井钻井关键技术与实践[J]. 石油钻采工艺,2022,44(2):145–152. doi: 10.13639/j.odpt.2022.02.002
JIA Lichun, LI Zhilin, ZHANG Jichuan, et al. Key technology and practice of horizontal drilling for marine deep shale gas in southern Sichuan Basin[J]. Oil Drilling & Production Technology, 2022, 44(2): 145–152. doi: 10.13639/j.odpt.2022.02.002
|
| [6] |
王怡. 页岩气藏裂缝区地层孔隙压力准确求取方法[J]. 石油钻探技术,2020,48(3):29–34. doi: 10.11911/syztjs.2020056
WANG Yi. A method for accurate calculation of pore pressure in fractured formations of shale gas reservoirs[J]. Petroleum Drilling Techniques, 2020, 48(3): 29–34. doi: 10.11911/syztjs.2020056
|
| [7] |
陈星星. 混合钻头在涪陵页岩气田的应用[J]. 探矿工程(岩土钻掘工程),2019,46(10):34–39.
CHEN Xingxing. Application of hybrid drill bits in Fuling Shale Gas Field[J]. Exploration Engineering(Rock & Soil Drilling and Tunneling), 2019, 46(10): 34–39.
|
| [8] |
李建亭,胡金建,罗恒荣. 低压耗增强型水力振荡器的研制与现场试验[J]. 石油钻探技术,2022,50(1):71–75. doi: 10.11911/syztjs.2021137
LI Jianting, HU Jinjian, LUO Hengrong. Development and field tests of an enhanced hydraulic oscillator with low pressure loss[J]. Petroleum Drilling Techniques, 2022, 50(1): 71–75. doi: 10.11911/syztjs.2021137
|
| [9] |
路保平,袁多,吴超,等. 井震信息融合指导钻井技术[J]. 石油勘探与开发,2020,47(6):1227–1234. doi: 10.11698/PED.2020.06.16
LU Baoping, YUAN Duo, WU Chao, et al. A drilling technology guided by well-seismic information integration[J]. Petroleum Exploration and Development, 2020, 47(6): 1227–1234. doi: 10.11698/PED.2020.06.16
|
| [10] |
吴宏杰. 定测录导一体化技术在涪陵页岩气田的应用[J]. 探矿工程(岩土钻掘工程),2019,46(8):10–14.
WU Hongjie. Integration of directional drilling, logging and rotary steering in Fuling Shale Gas Field[J]. Exploration Engineering (Rock & Soil Drilling and Tunneling), 2019, 46(8): 10–14.
|
| [11] |
赵福豪,黄维安,雍锐,等. 地质工程一体化研究与应用现状[J]. 石油钻采工艺,2021,43(2):131–138. doi: 10.13639/j.odpt.2021.02.001
ZHAO Fuhao, HUANG Weian, YONG Rui, et al. Research and application status of geology-engineering integration[J]. Oil Drilling & Production Technology, 2021, 43(2): 131–138. doi: 10.13639/j.odpt.2021.02.001
|
| [12] |
肖霞,许明标,由福昌,等. 不同油水比油基钻井液滤失性能的影响因素[J]. 油田化学,2018,35(4):577–581. doi: 10.19346/j.cnki.1000-4092.2018.04.002
XIAO Xia, XU Mingbiao, YOU Fuchang, et al. Influence factor of filtration property of oil-based drilling fluid with different oil-water ratio[J]. Oilfield Chemistry, 2018, 35(4): 577–581. doi: 10.19346/j.cnki.1000-4092.2018.04.002
|
| [13] |
何淼,施皓瀚,许明标. 水基钻井液高温高压流变动力学研究[J]. 钻井液与完井液,2021,38(3):271–279.
HE Miao, SHI Haohan, XU Mingbiao. Study of rheological dynamics of water-based drilling fluids at high temperature and high pressure[J]. Drilling Fluid & Completion Fluid, 2021, 38(3): 271–279.
|
| [14] |
刘智勤,管申,许明标,等. 硅酸盐钻井液用多功能润滑剂[J]. 钻井液与完井液,2021,38(2):158–163. doi: 10.3969/j.issn.1001-5620.2021.02.005
LIU Zhiqin, GUAN Shen, XU Mingbiao, et al. Laboratory study and application of a multifunctional lubricant for silicate drilling fluids[J]. Drilling Fluid & Completion Fluid, 2021, 38(2): 158–163. doi: 10.3969/j.issn.1001-5620.2021.02.005
|
| [15] |
于欣,张振,郭梦扬,等. 抗高温油基钻井液堵漏剂的研制与应用:以龙马溪组页岩气井W204H为例[J]. 断块油气田,2021,28(2):168–172.
YU Xin, ZHANG Zhen, GUO Mengyang, et al. Development and application of high temperature resistant oil-based drilling fluid plugging agent: taking shale gas well W204H of Longmaxi Formation as an example[J]. Fault-Block Oil & Gas Field, 2021, 28(2): 168–172.
|
| [16] |
李科,贾江鸿,于雷,等. 页岩油钻井漏失机理及防漏堵漏技术[J]. 钻井液与完井液,2022,39(4):446–450.
LI Ke, JIA Jianghong, YU Lei, et al. Mechanisms of lost circulation and technologies for mud loss prevention and control in shale oil drilling[J]. Drilling Fluid & Completion Fluid, 2022, 39(4): 446–450.
|
| [17] |
陈雷,陈会年,张林海,等. JY页岩气田水平井预防环空带压固井技术[J]. 石油钻采工艺,2019,41(2):152–159. doi: 10.13639/j.odpt.2019.02.006
CHEN Lei, CHEN Huinian, ZHANG Linhai, et al. A cementing technology for preventing the annulus pressure of horizontal wells in JY shale gasfield[J]. Oil Drilling & Production Technology, 2019, 41(2): 152–159. doi: 10.13639/j.odpt.2019.02.006
|
| 1. |
付海峰,刘鹏林,陈祝兴,翁定为,马泽元,李军. 基于避免断层激活机制的组合压裂模式研究. 石油机械. 2024(01): 88-97 .
| |
| 2. |
刘豪,刘怀亮,刘宇,曹伟,连威,李军. 页岩气多级压裂断层动态滑移规律研究. 石油机械. 2024(02): 65-74 .
| |
| 3. |
刘怀亮,樊子潇,刘宇,连威,席岩,张小军. 基于震源机制的断层滑移量计算方法. 世界石油工业. 2024(05): 40-47 .
| |
| 4. |
林魂,宋西翔,杨兵,袁勇,张健强,孙新毅. 温-压耦合作用下断层滑移对套管应力的影响. 石油机械. 2023(06): 136-142+158 .
| |
| 5. |
孟胡,吕振虎,王晓东,张辉,申颍浩,葛洪魁. 基于压裂参数优化的套管剪切变形控制研究. 断块油气田. 2023(04): 601-608 .
| |
| 6. |
张伟,李军,张慧,王典,李托,刘怀亮. 断层滑移对套管剪切变形的影响规律及防控措施. 断块油气田. 2023(05): 734-742 .
| |
| 7. |
文山师,尹陈,石学文,张洞君,韩福盛,熊财富. 天然裂缝主导模式下泸州龙马溪组页岩水力压裂多尺度破裂特征. 地球物理学进展. 2023(05): 2172-2181 .
| |
| 8. |
赵欢,李玮,唐鹏飞,王晓,张明慧,王剑波. 压裂工况下近井筒地应力及套管载荷分布规律研究. 石油钻探技术. 2023(05): 106-111 .
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| |
| 9. |
孟胡,申颍浩,朱万雨,李小军,雷德荣,葛洪魁. 四川盆地昭通页岩气水平井水力压裂套管外载分析. 特种油气藏. 2023(05): 166-174 .
| |
| 10. |
陈朝伟,周文高,项德贵,谭鹏,宋建,陈晓军,任乐佳,黄浩. 预防页岩气套变的橡胶组合套管研制及其抗剪切性能评价. 天然气工业. 2023(11): 131-136 .
| |
| 11. |
张旭,张哲平,杨尚谕,王雪刚,宋琳. 基于特征值和弧长法计算套管抗挤强度. 钻采工艺. 2022(01): 35-40 .
| |
| 12. |
陈朝伟,项德贵. 四川盆地页岩气开发套管变形一体化防控技术. 中国石油勘探. 2022(01): 135-141 .
| |
| 13. |
吴建忠,乔智国,慈建发,何龙,连威,李军. 基于震源机制的套管变形量控制方法研究. 石油管材与仪器. 2022(03): 24-31 .
| |
| 14. |
刘鹏林,李军,席岩,连威,张小军,郭雪利. 页岩断层滑移量计算模型及影响因素研究. 石油机械. 2022(08): 74-80 .
| |
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郭雪利,沈吉云,武刚,靳建洲,纪宏飞,徐明,刘慧婷,黄昭. 韧性材料对页岩气压裂井水泥环界面完整性影响. 表面技术. 2022(12): 232-242 .
| |
| 16. |
陈朝伟,黄锐,曾波,宋毅,周小金. 四川盆地长宁页岩气区块套管变形井施工参数优化分析. 石油钻探技术. 2021(01): 93-100 .
本站查看
| |
| 17. |
李军,赵超杰,柳贡慧,张辉,张鑫,任凯. 页岩气压裂条件下断层滑移及其影响因素. 中国石油大学学报(自然科学版). 2021(02): 63-70 .
| |
| 18. |
张平,何昀宾,刘子平,童亨茂,邓才,任晓海,张宏祥,李彦超,屈玲,付强,王向阳. 页岩气水平井套管的剪压变形试验与套变预防实践. 天然气工业. 2021(05): 84-91 .
| |
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李晓蓉,古臣旺,冯永存,丁泽晨. 考虑井筒加载历史的压裂过程中套管剪切变形数值模拟研究. 石油科学通报. 2021(02): 245-261 .
| |
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张鑫,李军,刘鹏林,郭雪利,韩葛伟. 断层滑移条件下页岩气井套管变形影响因素分析. 科学技术与工程. 2021(16): 6651-6656 .
| |
| 21. |
陈朝伟,张浩哲,周小金,曹虎. 四川长宁页岩气套管变形井微地震特征分析. 石油地球物理勘探. 2021(06): 1286-1292+1198 .
| |
| 22. |
张慧,李军,张小军,张鑫,连威. 页岩气井压裂液进入断层的途径及防控措施. 断块油气田. 2021(06): 750-754+760 .
| |
| 23. |
林志伟,钟守明,宋琳,王雪刚,林铁军,于浩,史涛. 体积压裂改造非对称性对套管损坏影响机理. 特种油气藏. 2021(06): 158-164 .
| |
| 24. |
陈朝伟,房超,朱勇,项德贵. 四川页岩气井套管变形特征及受力模式. 石油机械. 2020(02): 126-134 .
| |
| 25. |
连威,李军,柳贡慧,席岩,韩葛伟. 水力压裂过程中页岩强度折减对套管变形的影响分析. 石油管材与仪器. 2020(04): 46-50 .
| |
| 26. |
蒋振源,陈朝伟,张平,张丰收. 断块滑动引起的套管变形及影响因素分析. 石油管材与仪器. 2020(04): 30-37 .
| |
| 27. |
范宇,黄锐,曾波,陈朝伟,周小金,项德贵,宋毅. 四川页岩气水力压裂诱发断层滑动和套管变形风险评估. 石油科学通报. 2020(03): 366-375 .
| |
| 28. |
陈朝伟,曹虎,周小金,苟其勇,张浩哲. 四川盆地长宁区块页岩气井套管变形和裂缝带相关性. 天然气勘探与开发. 2020(04): 123-130 .
| |
| 29. |
席岩,李军,柳贡慧,曾义金,李剑平. 页岩气水平井多级压裂过程中套管变形研究综述. 特种油气藏. 2019(01): 1-6 .
| |
| 30. |
乔磊,田中兰,曾波,杨恒林,付盼,杨松. 页岩气水平井多因素耦合套变分析. 断块油气田. 2019(01): 107-110 .
| |
| 31. |
高德利,刘奎. 页岩气井井筒完整性若干研究进展. 石油与天然气地质. 2019(03): 602-615 .
| |
| 32. |
罗庆,黄华,徐菲,张立. 新型组合井况监测仪在普光高含硫气井的应用. 断块油气田. 2019(02): 240-243 .
| |
| 33. |
陈朝伟,项德贵,张丰收,安孟可,尹子睿,蒋振源. 四川长宁—威远区块水力压裂引起的断层滑移和套管变形机理及防控策略. 石油科学通报. 2019(04): 364-377 .
| |
| 34. |
周波,毛蕴才,查永进,汪海阁. 体积压裂水锤效应对页岩气井屏障完整性影响及对策. 石油钻采工艺. 2019(05): 608-613 .
| |
| 35. |
郭雪利,李军,柳贡慧,陈朝伟,任凯,来东风. 基于震源机制的页岩气压裂井套管变形机理. 断块油气田. 2018(05): 665-669 .
|
Supervisor:SINOPEC GROUP
Sponsor:Sinopec Research Institute of Petroleum Engineering
Serial Number:CN 11-1763/TE, ISSN 1001-0890
Chief Editor: WANG Minsheng
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