Petroleum Reservoir Evaluation and Development >
2025 , Vol. 15 >Issue 3: 515 - 521
DOI: https://doi.org/10.13809/j.cnki.cn32-1825/te.2025.03.019
Research and application of fiber fracturing and fiber temporary plugging technology for deep shale gas
Received date: 2024-11-05
Online published: 2025-05-28
With technological advancements, fibers now serve roles beyond proppant backflow prevention, including proppant transport, plugging, fracture morphology optimization, and other aspects, namely, fiber-network proppant fracturing technology. The fiber-based proppant transport and fiber temporary plugging technologies can effectively address issues currently faced by deep shale gas, such as proppant near-wellbore accumulation and insufficient temporary plugging effectiveness, thereby improving the effectiveness of volumetric fracturing stimulation. To this end, the study was conducted in a deep shale gas block in the southern Sichuan Basin, investigating fiber-based proppant transport and fiber temporary plugging mechanisms, as well as laboratory physical simulations to optimize and evaluate the performance of fiber materials. Based on the regional geological and engineering characteristics of the study area, fracturing software simulations were carried out to determine the hydraulic fracture width for deep shale gas. A field test plan was then developed, and the fracturing construction, flowback, plugging, and fracturing effectiveness of the test wells were monitored and evaluated. The research results indicated that fibers had strong proppant transport assistance and flexible bridging capabilities. By modifying the molecular structure of fiber materials and adding a certain amount of structural stabilizers, discontinuous cluster-like support structures can be formed, significantly enhancing the placement effect and conductivity of proppants. Based on fracture width simulation calculations, the hydraulic fracture width for deep shale gas is between 2 to 5 mm. By optimizing fiber types based on fracture width, proppant grain size, and concentration, full support of fractures can be achieved. Compared to conventional fracturing wells, the test wells with modified fiber + structural stabilizer for sand-carrying fracturing exhibited better production increase and proppant flowback prevention. Fibers can be used for temporary in-fracture plugging. During the construction process, the pressure response is evident, which may lead to excessively high pressure during subsequent operations, making proppant addition difficult. Optimizing the timing of fiber injection is beneficial for the subsequent overall sand addition process. Additionally, fibers can also be used to address the inter-well gas migration issue in deep shale gas wells by strengthening the temporary plugging of fracture openings and sealing natural fractures, thereby preventing further communication between hydraulic fractures and distant natural fractures. The study, based on the characteristics of deep shale reservoirs in the southern Sichuan Basin, has developed a set of performance indicators for fiber materials suitable for deep shale gas, including fiber length, stability, compatibility, and degradation rate. It also proposes a four-in-one fiber injection process and design method, focusing on “entry, distance, height, and prevention”. It provides strong support for the future economic development, technology optimization, and fracturing process adjustments of shale gas.
HU Junjie , LU Cong , GUO Jianchun , ZENG Bo , GUO Xingwu , MA Li , SUN Yuduo . Research and application of fiber fracturing and fiber temporary plugging technology for deep shale gas[J]. Petroleum Reservoir Evaluation and Development, 2025 , 15(3) : 515 -521 . DOI: 10.13809/j.cnki.cn32-1825/te.2025.03.019
| 1 | 付永强, 杨学锋, 周朗, 等. 川南页岩气体积压裂技术发展与应用[J]. 石油科技论坛, 2022, 41(3): 18-25. |
| FU Yongqiang, YANG Xuefeng, ZHOU Lang, et al. Development and application of shale gas volume fracturing technology in southern Sichuan Basin[J]. Petroleum Science and Technology Forum, 2022, 41(3): 18-25. | |
| 2 | 胡俊杰, 周小金, 周拿云, 等. 井筒听诊器技术在川南页岩气田的应用研究[J]. 钻采工艺, 2022, 45(6): 65-69. |
| HU Junjie, ZHOU Xiaojin, ZHOU Nayun, et al. Application and research of WellWatcher technology in southern Sichuan shale gas field[J]. Drilling & Production Technology, 2022, 45(6): 65-69. | |
| 3 | 桑宇, 周小金, 郭兴午, 等. 水平井压裂楔形缝内支撑剂输运特征数值模拟[J]. 科学技术与工程, 2023, 23(23): 9911-9917. |
| SANG Yu, ZHOU Xiaojin, GUO Xingwu, et al. Numerical simulation of proppant transport characteristics in horizontal well fracturing wedge fracture[J]. Science Technology and Engineering, 2023, 23(23): 9911-9917. | |
| 4 | BROWNE D J, WILSON B A. Proppant flowback control in deviated shallow gas wells[J]. The journal of Canadian Petroleum Technology, 2003, 42(11): 29-34. |
| 5 | 张朝举, 张绍彬, 谭明文, 等. 预防支撑剂回流的纤维增强技术实验研究[J]. 钻采工艺, 2005, 28(4): 90-91. |
| ZHANG Chaoju, ZHANG Shaobin, TAN Mingwen, et al. Lab study on fiber enhanced proppant to prevent flowback after fracturing[J]. Drilling & Production Technology, 2005, 28(4): 90-91. | |
| 6 | KIM J Y, ZHOU L, MORITA N. Study of degradable fibers with and without guar gum as a proppant transport agent using large-scale slot equipment[J]. SPE Journal. 2021, 26(1): 262-280. |
| 7 | 郭兴, 张建忠, 孙晓, 等. 纤维对高导流裂缝压裂影响的实验研究[J]. 钻探工程, 2021, 48(10): 13-20. |
| GUO Xing, ZHANG Jianzhong, SUN Xiao, et al. Effect of fiber on fracturing of high conductivity fractures[J]. Drilling Engineering, 2021, 48(10): 13-20. | |
| 8 | DENNEY D. Channel fracturing-paradigm shift in tight gas stimulation[J]. Journal of Petroleum Technology, 2011, 63(10): 82-85. |
| 9 | 蒋恕, 李园平, 杜凤双, 等. 提高页岩气藏压裂井射孔簇产气率的技术进展[J]. 油气藏评价与开发, 2023, 13(1): 9-22. |
| JIANG Shu, LI Yuanping, DU Fengshuang, et al. Recent advancement for improving gas production rate from perforated clusters in fractured shale gas reservoir[J]. Petroleum Reservoir Evaluation and Development, 2023, 13(1): 9-22. | |
| 10 | LYU M, GUO T, QU Z, et al. Experimental study on proppant transport within complex fractures[J]. SPE Journal, 2022, 27(5): 2960-2979. |
| 11 | 王庆群. 压裂液纤维水合混配装置的研制[J]. 石油机械, 2017, 45(5): 99-102. |
| WANG Qingqun. Fracturing fluid fiber hydration mixing device[J]. China Petroleum Machinery, 2017, 45(5): 99-102. | |
| 12 | 盖玉叶, 张贵玲, 宋时权, 等. 压裂用纤维携砂性能影响因素分析[J]. 石油工业技术监督, 2021, 37(3): 7-8. |
| GAI Yuye, ZHANG Guiling, SONG Shiquan, et al. Analysis of factors affecting sand-carrying performance of fiber for fracturing[J]. Technology Supervision in Petroleum Industry, 2021, 37(3): 7-8. | |
| 13 | 岳文翰, 肖勇军, 井翠, 等. 纤维滑溜水携砂技术研究及应用[J]. 钻采工艺, 2023, 46(5): 151-156. |
| YUE Wenhan, XIAO Yongjun, JING Cui, et al. Study and field application of fiber slickwater proppant carrying capacity[J]. Drilling & Production Technology, 2023, 46(5): 151-156. | |
| 14 | 杨兆中, 袁健峰, 张景强, 等. 四川盆地海相页岩水平井压裂裂缝研究进展及认识[J]. 油气藏评价与开发, 2024, 14(4): 600-609. |
| YANG Zhaozhong, YUAN Jianfeng, ZHANG Jingqiang, et al. Research progress and understanding of fracturing fractures in horizontal wells of marine shale in Sichuan Basin[J]. Petroleum Reservoir Evaluation and Development, 2024, 14(4): 600-609. | |
| 15 | 王艳林, 方正魁, 刘林泉, 等. 新型可降解纤维暂堵转向压裂技术研究及应用[J]. 钻采工艺, 2020, 43(6): 52-54. |
| WANG Yanlin, FANG Zhengkui, LIU Linquan, et al. Research and application of new degradable fiber temporary plugging and diversion fracturing technology[J]. Drilling & Production Technology, 2020, 43(6): 52-54. | |
| 16 | TABATABAEI M, TALEGHANI A D, LI G, et al. Shape memory polymers as lost circulation materials for sealing wide-opened natural fractures[J]. SPE Drilling & Completion, 2021, 36(4): 931-942. |
| 17 | YANG C, ZHOU F, FENG W, et al. Plugging mechanism of fibers and particulates in hydraulic fracture[J]. Journal of Petroleum Science and Engineering, 2019, 176: 396-402. |
| 18 | 刘颖, 杨晨, 史涛. 颗粒与纤维在水力裂缝内封堵机理的可视化实验研究[J]. 石油科学通报, 2022, 7(2): 196-203. |
| LIU Ying, YANG Chen, SHI Tao. Visualization study on the plugging mechanism of fibers and particulates in the hydraulic fracture[J]. Petroleum Science Bulletin, 2022, 7(2): 196-203. | |
| 19 | 胡小虎, 刘华, 何辉, 等. 考虑压裂缝网连通的页岩气井组试井分析方法[J]. 油气藏评价与开发, 2025, 15(1): 79-87. |
| HU Xiaohu, LIU Hua, HE Hui, et al. Well test analysis method of shale gas well groups considering fracture network connectivity[J]. Petroleum Reservoir Evaluation and Development, 2025, 15(1): 79-87. | |
| 20 | 张柟乔, 刘青, 王俐佳, 等. 深层页岩气防压窜工艺在L203H53-1井的应用[J]. 钻采工艺, 2023, 46(6): 158-164. |
| ZHANG Nanqiao, LIU Qing, WANG Lijia, et al. Application of deep shale gas frac-hit prevention countermeasures in well L203H53[J]. Drilling & Production Technology, 2023, 46(6): 158-164. | |
| 21 | 廖波兰, 卢亚平. 纤维压裂液性能的基础性研究[J]. 矿冶, 2014, 23(1): 37-42. |
| LIAO Bolan, LU Yaping. Fundamental study on fiber fracturing fluid properties[J]. Mining and Metallurgy, 2014, 23(1): 37-42. | |
| 22 | 吴鹏程, 汪瑶, 付利, 等. 深层页岩气水平井“一趟钻”技术探索与实践[J]. 石油机械, 2023, 51(8): 26-33. |
| WU Pengcheng, WANG Yao, FU Li, et al. Exploration and practice of “one trip” technology for deep shale gas horizontal wells[J].China Petroleum Machinery, 2023, 51(8): 26-33. | |
| 23 | 赵康, 陈民锋, 王艺文, 等. 四川盆地SZ页岩气藏气井产量变化规律及递减预测新模型[J]. 中国海上油气, 2024, 36(3):129-136. |
| ZHAO Kang, CHEN Minfeng, WANG Yiwen, et al. A new model for production variation patterns and decline prediction of SZ shale gas reservoir in Sichuan basin[J]. China Offshore Oil and Gas, 2024, 36(3): 129-136. | |
| 24 | 张皎生, 杨焕英, 王晶, 等. 基于复杂缝网精细刻画的致密油气藏水平井多段压裂数值模拟技术[J]. 中国海上油气, 2023, 35(4): 103-111. |
| ZHANG Jiaosheng, YANG Huanying, WANG Jing, et al. A method for numerical simulation of multi-stage fracturing of horizontal well in tight oil and gas reservoirs based on fine characterization of complex fracture network[J]. China Offshore Oil and Gas, 2023, 35(4): 103-111. |
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