渤海低渗储层缝网压裂粗糙缝内支撑剂运移特征研究

doi:10.11885/j.issn.1674-5086.2025.10.26.01

西南石油大学学报(自然科学版) ›› 2026, Vol. 48 ›› Issue (1): 61-70.DOI: 10.11885/j.issn.1674-5086.2025.10.26.01

• 海上大型压裂船技术专刊 • 上一篇下一篇

渤海低渗储层缝网压裂粗糙缝内支撑剂运移特征研究

罗少锋^1,2, 张超^1,2, 付建民^1,2, 丁海波^1,2, 徐延涛³, 颜菁菁^1,2

1. 中海石油(中国)有限公司天津分公司, 天津滨海新区 300459;
2. 海洋油气高效开发全国重点实验室, 北京朝阳 102209;
3. 中海油田服务股份有限公司, 天津滨海新区 300459

收稿日期:2025-10-26 发布日期:2026-03-09
通讯作者: 丁海波,E-mail:dinghb6@cnooc.com.cn
作者简介:罗少锋，1980年生，男，汉族，陕西宝鸡人，高级工程师，主要从事海上钻完井技术研究。E-mail： luoshf2@cnooc.com.cn
张超，1977年生，男，汉族，河北衡水人，高级工程师，主要从事海上钻完井装备技术研究及应用工作。E-mail： zhangchao7@cnooc.com.cn
付建民，1981年生，男，汉族，河北唐山人，高级工程师，主要从事海上钻完井技术研究及应用工作。E-mail： fujm@cnooc.com.cn
丁海波，1997年生，男，汉族，四川广安人，工程师，硕士，主要从事储层压裂改造研究工作。E-mail：dinghb6@cnooc.com.cn
徐延涛，1983年生，男，汉族，山东莱州人，硕士，主要从事储层改造技术研究及推广工作。E-mail：xuyt4@cosl.com.cn
颜菁菁，1983年生，女，汉族，天津人，硕士，高级工程师，主要从事钻修机建造技术研究及应用等方面的工作。E-mail：yanjj2@cnooc.com.cn

Study on Proppant Transport Characteristics in Rough Fractures of Fracture-network Fracturing in Bohai Low-permeability Reservoirs

LUO Shaofeng^1,2, ZHANG Chao^1,2, FU Jianmin^1,2, DING Haibo^1,2, XU Yantao³, YAN Jingjing^1,2

1. CNOOC China Limited, Tianjin Branch, Binhai New Area, Tianjin 300459, China;
2. State Key Laboratory of Offshore Oil and Gas Exploitation, Chaoyang, Beijing 102209, China;
3. China Oilfield Services Limited, Binhai New Area, Tianjin 300459, China

Received:2025-10-26 Published:2026-03-09

摘要/Abstract

摘要： 渤海油田低渗储量丰富，但受限于海上作业条件难以使用大规模缝网压裂工艺对低渗储层进行经济开发。随着大型压裂船的投入使用，大规模缝网压裂将成为海上低渗储层改造发展趋势。研究以渤海某低渗储层为目标，通过劈裂目的层岩芯扫描刻画粗糙裂缝壁面，基于压裂船作业能力建立复杂粗糙裂缝模型，开展了支撑剂运移的物理实验和数值模拟分析。研究结果表明，粗糙壁面会增加运移阻力，段塞打磨裂缝壁面是有必要的；滑溜水携砂运移机制为支撑剂重力沉降与流体拖曳共同作用下的动态平衡运移，应从提高支撑剂向裂缝深部运移能力方向提高铺砂效果；优化参数设计，使用滑溜水以12 m$^3$/min排量，携带40/70+30/50+20/40目混合支撑剂的泵注方式更有利于支撑剂在缝内铺置。研究结论能够科学指导压裂参数设计，对实现海上低渗油田的高效开发具有重要指导意义。

关键词: 渤海低渗储层, 压裂船, 大型压裂, 粗糙复杂裂缝, 支撑剂运移铺置

Abstract: The Bohai Oilfield possesses abundant low-permeability reserves. However, their economic development has been constrained by offshore operational limitations that hinder the application of large-scale network fracturing techniques. With the recent deployment of large fracturing vessels, large-scale network fracturing is poised to become a key trend for developing offshore low-permeability reservoirs. The study focuses on a low-permeability reservoir in the Bohai Sea. We characterizes rough fracture surfaces by splitting and scanning core samples from the target layer, establish a complex fracture model based on the operational capacity of fracturing vessels, and carry out physical experiments and numerical simulation analysis of proppant transport. Key findings include: rough fracture walls increase transport resistance, making it necessary to use slug flow to polish fracture surfaces; the transport mechanism of sand-carrying slickwater follows a dynamic equilibrium under the influence of gravity settling and fluid drag. Therefore, to improve placement efficiency, the strategy should focus on enhancing the proppant$'$s ability to migrate into the deeper sections of the fracture; through optimized parameter design, slickwater injection at 12 m$^3$/min with a staged proppant blend 40/70 + 30/50 + 20/40 mesh can significantly enhance intra-fracture proppant placement. These results provide scientific guidance for fracturing parameter design and hold critical implications for the efficient development of offshore low-permeability oilfields.

Key words: Bohai low-permeability reservoirs, fracturing vessel, large-scale fracturing, rough and complex fractures, proppant transport and placement

中图分类号:

TE357

罗少锋, 张超, 付建民, 丁海波, 徐延涛, 颜菁菁. 渤海低渗储层缝网压裂粗糙缝内支撑剂运移特征研究[J]. 西南石油大学学报(自然科学版), 2026, 48(1): 61-70.

LUO Shaofeng, ZHANG Chao, FU Jianmin, DING Haibo, XU Yantao, YAN Jingjing. Study on Proppant Transport Characteristics in Rough Fractures of Fracture-network Fracturing in Bohai Low-permeability Reservoirs[J]. Journal of Southwest Petroleum University(Science & Technology Edition), 2026, 48(1): 61-70.

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参考文献

[1] 孙福街.中国海上油田高效开发与提高采收率技术现状及展望[J].中国海上油气， 2023， 35（5）： 91-99. doi： 10.11935/j.issn.1673-1506.2023.05.009 SUN Fujie. Status and prospects of efficient development and EOR technologies in China offshore oilfields[J]. China Offshore Oil and Gas, 2023, 35(5): 91-99. doi: 10.11935/j.issn.1673-1506.2023.05.009
[2] 马英文，曹砚锋，邱浩，等.中国海油中深层油气田完井技术现状及展望[J].中国海上油气， 2024， 36（5）： 146-156. doi： 10.11935/j.issn.1673-1506.2024.05.015 MA Yingwen, CAO Yanfeng, QIU Hao, et al. Status and prospects of well completion technologies for middle-todeep oil and gas fields of CNOOC[J]. China Offshore Oil and Gas, 2024, 36(5): 146-156. doi: 10.11935/j.issn.1673-1506.2024.05.015
[3] 王欣然，王艳霞，王晓超，等.海上油田“双高”阶段低效井综合治理研究[J].西南石油大学学报（自然科学版）， 2024， 46（2）： 125-134. doi： 10.11885/j.issn.1674-5086.2022.06.23.02 WANG Xinran, WANG Yanxia, WANG Xiaochao. A study on comprehensive treatment of low efficiency wells in offshore oilfield with high water cut and high recovery stage[J]. Journal of Southwest Petroleum University (Science & Technology Edition), 2024, 46(2): 125-134. doi: 10.11885/j.issn.1674-5086.2022.06.23.02
[4] 范廷恩.中国海上低渗油气田开发历程、关键技术及攻关方向[J].中国海上油气， 2024， 36（3）： 95-109. doi： 10.11935/j.issn.1673-1506.2024.03.009 FAN Ting'en. Development process, key technologies and research directions of China's offshore low-permeability oil and gas fields[J]. China Offshore Oil and Gas, 2024, 36(3): 95-109. doi: 10.11935/j.issn.1673-1506.2024.03.-009
[5] 徐长贵.双碳背景下中国海油三个万亿大气区勘探战略思考[J].中国海上油气， 2023， 35（6）： 1-12. doi： 10.11935/j.issn.1673-1506.2023.06.001 XU Changgui. Strategic thinking on exploration of three trillion cubic meters gas provinces of CNOOC under the dual carbon target background[J]. China Offshore Oil and Gas, 2023, 35(6): 1-12. doi: 10.11935/j.issn.1673-1506.-2023.06.001
[6] 刘建忠，徐文江，姜维东，等.中国海油海上油田采油工程技术进展与展望[J].中国海上油气， 2024， 36（5）： 128-136. doi： 10.11935/j.issn.1673-1506.2024.05.013 LIU Jianzhong, XU Wenjiang, JIANG Weidong, et al. Progress and prospects of oil production engineering technologies in offshore oilfields of CNOOC[J]. China Offshore Oil and Gas, 2024, 36(5): 128-136. doi: 10.11935/-j.issn.1673-1506.2024.05.013
[7] 张健，李保振，周文胜，等.中国海上气田开发与提高采收率技术[J].天然气工业， 2023， 43（1）： 132-140. doi： 10.3787/j.issn.1000-0976.2023.01.013 ZHANG Jian, LI Baozhen, ZHOU Wensheng, et al. Development and EGR technologies of offshore gas fields in China[J]. Natural Gas Industry, 2023, 43(1): 132-140. doi: 10.3787/j.issn.1000-0976.2023.01.013
[8] 刘义刚.渤海油田低渗储层开采技术研究进展与展望[J].中国海上油气， 2024， 36（1）： 117-124. doi： 10.11935/j.issn.1673-1506.2024.01.012 LIU Yigang. Research progress and prospect of low permeability reservoir exploitation technologies in Bohai Oilfield[J]. China Offshore Oil and Gas, 2024, 36(1): 117-124. doi: 10.11935/j.issn.1673-1506.2024.01.012
[9] 范白涛，陈峥嵘，姜浒，等.中国海油非常规和海上低渗储层压裂技术现状与展望[J].中国海上油气， 2021， 33（4）： 112-119. doi： 10.10935/j.issn.1673-1506.-2021.04.014 FAN Baitao, CHEN Zhengrong, JIANG Hu, et al. Status and prospect of fracturing technology for CNOOC unconventional and offshore low permeability reservoirs[J]. China Offshore Oil and Gas, 2021, 33(4): 112-119. doi: 10.10935/j.issn.1673-1506.2021.04.014
[10] 王云海.海洋油气压裂增产作业船技术现状及展望[J].石油机械， 2024， 52（5）： 71-77， 115. doi： 10.16082/j.-cnki.issn.1001-4578.2024.05.010 WANG Yunhai. Offshore fracturing vessels: Review and prospect[J]. China Petroleum Machinery, 2024, 52(5): 71-77, 115. doi: 10.16082/j.cnki.issn.1001-4578.2024.-05.010
[11] 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. doi： 10.3969/j.issn.1671-1815.2023.23.019 SANG Yu, ZHOU Xiaojin, GUO Xingwu, et al. Numeral simulation of proppant transport characteristics in horizontal well fracturing wedge fracture[J]. Science Technology and Engineering, 2023, 23(23): 9911-9917. doi： 10.3969/-j.issn.1671-1815.2023.23.019
[12] 唐堂，郭建春，翁定为，等.基于PIV/PTV的平板裂缝支撑剂输送试验研究[J].石油钻探技术， 2023， 51（5）： 121-129. doi： 10.11911/syztjs.2023083 TANG Tang, GUO Jianchun, WENG Dingwei, et al. Experimental study of proppant transport in flat fracture based on PIV/PTV[J]. Petroleum Drilling Techniques, 2023, 51(5): 121-129. doi: 10.11911/syztjs.2023083
[13] 郭建春，唐堂，张涛，等.深层页岩压裂多级裂缝内支撑剂运移与分布规律[J].天然气工业， 2024， 44（7）： 1-11. doi： 10.3787/j.issn.1000-0976.2024.07.001 GUO Jianchun, TANG Tang, ZHANG Tao, et al. Migration and distribution laws of proppant in multi-scale fractures during deep shale fracturing[J]. Natural Gas Industry, 2024, 44(7): 1-11. doi： 10.3787/j.issn.1000-0976.2024.-07.001
[14] HUANG Hai, BABADAGLI T, LI H A, et al. Effect of injection parameters on proppant transport in rough vertical fractures: An experimental analysis on visual models[J]. Journal of Petroleum Science and Engineering, 2019, 180: 380-395. doi: 10.1016/j.petrol.2019.05.009
[15] YAMASHIRO B D, TOMAC I. Fracture roughness effects on slickwater proppant slurry settling attenuation[J]. Powder Technology, 2022, 395: 516-533. doi: 10.1016/j.-powtec.2021.10.002
[16] 黄海，郑永，王毅，等.粗糙壁面压裂裂缝内支撑剂运移铺置特征[J].石油勘探与开发， 2024， 51（2）： 399-408. doi： 10.11698/PED.20230545 HUANG Hai, ZHENG Yong, WANG Yi, et al. Characteristics of proppant transport and placement within rough hydraulic fractures[J]. Petroleum Exploration and Development, 2024, 51(2): 399-408. doi: 10.11698/PED.-20230545
[17] 郭天魁，吕明锟，陈铭，等.体积压裂多分支裂缝支撑剂运移规律[J].石油勘探与开发， 2023， 50（4）： 832844. doi： 10.11698/PED.20220767 GUO Tiankui, LÜ Mingkun, CHEN Ming, et al. Proppant transport law in multi-branched fractures induced by volume fracturing[J]. Petroleum Exploration and Development, 2023, 50(4): 832-844. doi: 10.11698/PED.-20220767
[18] 刘善勇，尹彪，楼一珊，等.粗糙裂缝内支撑剂运移与展布规律数值模拟[J].石油钻探技术， 2024， 52（4）： 104-109. doi： 10.11911/syztjs.2024057 LIU Shanyong, YIN Biao, LOU Yishan, et al. Numerical simulation of migration and placement law of proppants in rough fractures[J]. Petroleum Drilling Techniques, 2024, 52(4): 104-109. doi: 10.11911/syztjs.2024057
[19] 胡晓东，张鹏天，周福建，等.迂曲裂缝内支撑剂运移数值模拟[J].中国石油大学学报（自然科学版）， 2024， 48（3）： 111-118. doi： 10.3969/j.issn.1673-5005.-2024.03.012 HU Xiaodong, ZHANG Pengtian, ZHOU Fujian, et al. Numerical simulation of proppant transport in tortuous fractures[J]. Journal of China University of Petroleum (Edition of Natural Science), 2024, 48(3): 111-118. doi: 10.3969/-j.issn.1673-5005.2024.03.012
[20] 张涛，蹇胤霖，何乐，等.压裂复杂裂缝中支撑剂输送数值模拟研究[J].油气地质与采收率， 2024， 31（3）： 123-136. doi： 10.13673/j.pgre.202307026 ZHANG Tao, JIAN Yinlin, HE Le, et al. Numerical simulation study of proppant transport in complex hydraulic fractures[J]. Petroleum Geology and Recovery Efficiency, 2024, 31(3): 123-136. doi: 10.13673/j.pgre.202307026
[21] 尹邦堂，张超，王志远，等.非常规油气储集层粗糙压裂裂缝内支撑剂运移机理[J].石油勘探与开发， 2023， 50（3）： 624-632. doi： 10.11698/PED.20220761 YIN Bangtang, ZHANG Chao, WANG Zhiyuan, et al. Proppant transport in rough fractures of unconventional oil and gas reservoirs[J]. Petroleum Exploration and Development, 2023, 50(3): 624-632. doi: 10.11698/PED.-20220761
[22] WANG Fei, LI Baoman, CHEN Qiaoyun, et al. Simulation of proppant distribution in hydraulically fractured shale network during shut-in periods[J]. Journal of Petroleum Science and Engineering, 2019, 178: 467-474. doi: 10.-1016/j.petrol.2019.03.046
[23] GONG Yiwen, MEHANA M, EL-MONIER I, et al. Proppant placement in complex fracture geometries: A computational fluid dynamics study[J]. Journal of Natural Gas Science and Engineering, 2020, 79: 103295. doi: 10.1016/j.jngse.2020.103295
[24] 汪杰，赵康佳，付珊珊，等.非常规储层压裂支撑剂多级裂缝运移和沉降规律[J].天然气工业， 2024， 44（7）： 109-119. doi： 10.3787/j.issn.1000-0976.2024.07.009 WANG Jie, ZHAO Kangjia, FU Shanshan, et al. Migration and settlement laws of proppant in multi-scale fractures during the fracturing in the unconventional reservoirs[J]. Natural Gas Industry, 2024, 44(7): 109-119. doi: 10.-3787/j.issn.1000-0976.2024.07.009
[25] 崔传智，李景林，吴忠维，等.复杂裂缝内支撑剂铺置规律及有效支撑面积[J].科学技术与工程， 2023， 23（30）： 12926-12935. doi： 10.3969/j.issn.1671-1815.-2023.30.019 CUI Chuanzhi, LI Jinglin, WU Zhongwei, et al. Proppant placement rule and effective supporting area in complex fractures[J]. Science Technology and Engineering, 2023, 23(30): 12926-12935. doi： 10.3969/j.issn.1671-18-15.2023.30.019
[26] 郭慧娟，高畅，韩金井，等.基于CFD-DEM算法的压裂支撑剂缝内铺砂规律[J].石油机械， 2023， 51（6）： 104-111. doi： 10.16082/j.cnki.issn.1001-4578.2023.06.-014 GUO Huijuan, GAO Chang, HAN Jinjing, et al. Investigation on proppant placement in hydraulic fractures based on CFD-DEM[J]. China Petroleum Machinegy, 2023, 51(6): 104-111. doi: 10.16082/j.cnki.issn.1001-4578.2023.06.-014
[27] 祁生金.裂缝延伸方向对水平井主压裂缝内支撑剂运移规律的影响[J].特种油气藏， 2025， 32（1）： 167-174. doi： 10.3969/j.issn.1006-6535.2025.01.020 QI Shengjin. Impact of fracture propagation direction on proppant transport patterns within the main hydraulic fractures of horizontal wells[J]. Special Oil & Gas Reservoirs, 2025, 32(1): 167-174. doi: 10.3969/j.issn.1006-65-35.2025.01.020
[28] LI Jun, HE Siyuan, WU Mingyi, et al. A comprehensive review of the proppant transportation in different simplified fracture models: Experimentation, modeling, and prospects[J]. Geoenergy Science and Engineering, 2023, 228: 211974. doi: 10.1016/j.geoen.2023.211974
[29] ZHANG Bo, GAMAGE R P, ZHANG Chengpeng, et al. Hydrocarbon recovery: Optimized CFD-DEM modeling of proppant transport in rough rock fractures[J]. Fuel, 2022, 311: 122560. doi: 10.1016/j.fuel.2021.122560

渤海低渗储层缝网压裂粗糙缝内支撑剂运移特征研究

Study on Proppant Transport Characteristics in Rough Fractures of Fracture-network Fracturing in Bohai Low-permeability Reservoirs

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