裂缝封堵层结构形成与演化机制

许成元; 张敬逸; 康毅力; 徐锋; 林冲; 闫霄鹏; 经浩然; 商翔宇

doi:10.11698/PED.2021.01.19

石油勘探与开发 >

2021 , Vol. 48 >Issue 1: 202 - 210

DOI: https://doi.org/10.11698/PED.2021.01.19

石油工程

裂缝封堵层结构形成与演化机制

许成元 ,
张敬逸 ,
康毅力 ,
徐锋 ,
林冲 ,
闫霄鹏 ,
经浩然 ,
商翔宇

展开

1.油气藏地质及开发工程国家重点实验室西南石油大学,成都 610500;
2.中国石油国际勘探开发有限公司,北京 100034;
3.中国石油勘探开发研究院,北京 100086;
4.深部岩土力学与地下工程国家重点实验室中国矿业大学,江苏徐州 221116

许成元（1988-）,男,河北沧州人,博士,西南石油大学石油与天然气工程学院副教授,主要从事储集层保护理论与技术、工作液漏失控制、颗粒物质力学与颗粒流领域的科研与教学工作。地址：四川省成都市新都区西南石油大学石油与天然气工程学院,邮政编码：610500。E-mail：chance_xcy@163.com

收稿日期: 2020-04-20

修回日期: 2020-10-15

网络出版日期: 2021-01-19

基金资助

国家自然科学基金“基于逾渗和固液两相流理论的裂缝性储集层工作液漏失损害预测与控制”（51604236）; 油气藏地质及开发工程国家重点实验室开放基金“深层裂缝漏失性储集层封堵层细观力链表征及结构失稳机理研究”（PLN201913）; 四川省科技计划项目“保护储集层并改善优势天然裂缝导流能力的钻井预撑裂缝堵漏基础研究”（2018JY0436）; 非常规油气层保护四川省青年科技创新研究团队项目（2016TD0016）

收起

Structural formation and evolution mechanisms of fracture plugging zone

XU Chengyuan ,
ZHANG Jingyi ,
KANG Yili ,
XU Feng ,
LIN Chong ,
YAN Xiaopeng ,
JING Haoran ,
SHANG Xiangyu

Expand

1. State Key Laboratory of Oil and Gas Reservoir Geology and Exploitation in Southwest Petroleum University, Chengdu 610500, China;
2. CNPC International Exploration and Development Corporation, Beijing 100034, China;
3. PetroChina Research Institute of Petroleum Exploration and Development, Beijing 100083, China;
4. State Key Laboratory for Geomechanics and Deep Underground Engineering, China University of Mining and Technology, Xuzhou, 221116

Received date: 2020-04-20

Revised date: 2020-10-15

Online published: 2021-01-19

Fold

摘要

采用耦合计算流体力学-离散元（CFD-DEM）方法模拟了裂缝封堵层结构形成过程,采用自主研制的表征封堵层细观力链网络的光弹实验系统模拟了裂缝封堵层结构承压演化过程,揭示了裂缝封堵层结构形成与演化机制,形成了堵漏材料优选与堵漏配方设计新方法,为提高裂缝性储集层漏失控制效果提供理论依据。CFD-DEM模拟结果表明,架桥概率是决定封堵层结构形成和裂缝封堵效率的关键因素。提出了临界架桥与绝对架桥加量指标,作为架桥材料加量设计的依据。随着绝对架桥加量的增加,架桥模式由材料粒径主导向粒径-摩擦力共同主导转变。光弹实验结果表明,细观力链网络是裂缝封堵层结构承压演化的内在机制并决定宏观封堵层强度,堵漏材料性能参数影响力链网络结构和强力链占比,进而影响封堵层承压稳定性。根据研究结果优选了新型高封堵强滞留堵漏材料、优化了堵漏配方,室内裂缝封堵实验结果表明可有效提高裂缝封堵效率与封堵强度。图16表3参30

关键词： 井漏; 储集层保护; 裂缝封堵层; 封堵层结构; 封堵强度; 封堵效率; CFD-DEM模拟; 光弹实验; 堵漏材料

本文引用格式

许成元 , 张敬逸 , 康毅力 , 徐锋 , 林冲 , 闫霄鹏 , 经浩然 , 商翔宇 . 裂缝封堵层结构形成与演化机制[J]. 石油勘探与开发, 2021 , 48(1) : 202 -210 . DOI: 10.11698/PED.2021.01.19

Abstract

A coupled CFD-DEM method is used to simulate the formation process of fracture plugging zone. A photo-elastic system characterizing mesoscale force chain network developed by our own is used to model the pressure evolution in fracture plugging zone to reveal the formation and evolution mechanisms of the structure of fracture plugging zone. A theoretical basis is provided for improving the lost circulation control effect in fractured reservoirs and novel methods are proposed for selecting loss control materials and designing loss control formula. CFD-DEM simulation results show that bridging probability is the key factor determining the formation of fracture plugging zone and fracture plugging efficiency. Critical and absolute bridging concentrations are proposed as the key indexes for loss control formula design. With the increase of absolute bridging concentration, the governing factor of bridging is changed from material grain size to the combination of material grain size and friction force. Results of photo-elastic experiments show that mesoscale force chain network is the intrinsic factor affecting the evolution of pressure exerting on the fracture plugging zone and determines the macroscopic strength of fracture plugging zone. Performance parameters of loss control material affect the force chain network structure and the ratio of stronger force chain, and further impact the stability and strength of fracture plugging zone. Based on the study results, the loss control formula is optimized and new-type loss control material is designed. Laboratory experiments results show that the fracture plugging efficiency and strength is effectively improved.

Key words： lost circulation; formation damage control; fracture plugging zone; plugging zone structure; plugging strength; plugging efficiency; CFD-DEM simulation; photo-elastic experiment; loss control material

参考文献

[1] 徐同台, 刘玉杰, 申威. 钻井工程防漏堵漏技术[M]. 北京: 石油工业出版社, 1997.
XU Tongtai, LIU Yujie, SHEN Wei. Technology of lost circulation prevention and control during drilling engineering[M]. Beijing: Petroleum Industry Press, 1997.
[2] 孙金声, 汪世国, 张毅, 等. 水基钻井液成膜技术研究[J]. 钻井液与完井液, 2003, 20(6): 6-10.
SUN Jinsheng, WANG Shiguo, ZHANG Yi, et al.Study on membrane generating technology of water based drilling fluid[J]. Drilling Fluid & Completion Fluid, 2003, 20(6): 6-10.
[3] 蒋官澄, 毛蕴才, 周宝义, 等. 保护油气层钻井液技术研究进展与发展趋势等[J]. 钻井液与完井液, 2018, 35(2): 1-16.
JIANG Guancheng, MAO Yuncai, ZHOU Baoyi, et al.Progress made and trend of development in studying on reservoir protection drilling fluids[J]. Drilling Fluid & Completion Fluid, 2018, 35(2): 1-16.
[4] XU Chengyuan, KANG Yili, YOU Zhenjiang, et al.Review on formation damage mechanisms and processes in shale gas reservoir: Known and to be known[J]. Journal of Natural Gas Science and Engineering, 2016, 36(1): 1208-1219.
[5] 康毅力, 王凯成, 许成元, 等. 深井超深井钻井堵漏材料高温老化性能评价[J]. 石油学报, 2019, 40(2): 215-223.
KANG Yili, WANG Kaicheng, XU Chengyuan, et al.High-temperature aging property evaluation of lost circulation materials in deep and ultra-deep well drilling[J]. Acta Petrolei Sinica, 2019, 40(2): 215-223.
[6] 康毅力, 许成元, 唐龙, 等. 构筑井周坚韧屏障: 井漏控制理论与方法[J]. 石油勘探与开发, 2014, 41(4): 473-479.
KANG Yili, XU Chengyuan, TANG Long, et al.Constructing a tough shield around the wellbore: Theory and method for lost-circulation control[J]. Petroleum Exploration and Development, 2014, 41(4): 473-479.
[7] 王贵, 蒲晓林. 提高地层承压能力的钻井液堵漏作用机理[J]. 石油学报, 2010, 31(6): 1009-1021.
WANG Gui, PU Xiaolin.Plugging mechanism of drilling fluid by enhancing wellbore pressure[J]. Acta Petrolei Sinica, 2010, 31(6): 1009-1021.
[8] 邱正松, 刘均一, 周宝义, 等. 钻井液致密承压封堵裂缝机理与优化设计[J]. 石油学报, 2016, 37(S2): 137-143.
QIU Zhengsong, LIU Junyi, ZHOU Baoyi, et al.Tight fracture-plugging mechanism and optimized design for plugging drilling fluid[J]. Acta Petrolei Sinica, 2016, 37(S2): 137-143.
[9] 李志勇, 鄢捷年, 王友兵, 等. 保护储层钻井液优化设计新方法及其应用[J]. 钻采工艺, 2006, 29(2): 85-87.
LI Zhiyong, YAN Jienian, WANG Youbing, et al.New optimized design method and application of drilling fluid used for formation damage control[J]. Drilling and Production Technology, 2006, 29(2): 85-87.
[10] 闫丰明, 康毅力, 孙凯. 裂缝-孔洞型碳酸盐岩储层暂堵性堵漏机理研究[J]. 石油钻探技术, 2011, 39(2): 81-85.
YAN Fengming, KANG Yili, SUN Kai.Mechanism of temporary sealing for fractured-vuggy carbonate reservoir[J]. Petroleum Drilling Techniques, 2011, 39(2): 81-85.
[11] KANG Yili, XU Chengyuan, YOU Lijun, et al.Temporary sealing technology to control formation damage induced by drill-in fluid loss in fractured tight gas reservoir[J]. Journal of Natural Gas Science and Engineering, 2014, 20(1): 67-73.
[12] 苏晓明, 练章华, 方俊伟, 等. 适用于塔中区块碳酸盐岩缝洞型异常高温高压储集层的钻井液承压堵漏材料[J]. 石油勘探与开发, 2019, 46(1): 165-172.
SU Xiaoming, LIAN Zhanghua, FANG Junwei, et al.Loss control material for fractured-vuggy carbonate reservoirs of high temperature and pressure in Tazhong block, Tarim Basin, NW China[J]. Petroleum Exploration and Development, 2019, 46(1): 165-172.
[13] KANG Yili, XU Chengyuan, YOU Lijun, et al.Comprehensive evaluation of formation damage induced by working fluid loss in fractured tight gas reservoir[J]. Journal of Natural Gas Science and Engineering, 2014, 18(1): 353-359.
[14] XU Chengyuan, YOU Zhenjiang, KANG Yili, et al.Stochastic modelling of particulate suspension transport for formation damage prediction in fractured tight reservoir[J]. Fuel, 2018, 221: 476-490.
[15] KLOSS C, GONIVA C, HAGER A, et al.Models, algorithms and validation for open source DEM and CFD-DEM[J]. Progress in Computational Fluid Dynamics, 2012, 12(2/3): 140-152.
[16] HAGER A.CFD-DEM on multiple scales: An extensive investigation of particle-fluid interactions[D]. Linz: Johannes Kepler University Linz, 2014.
[17] SHIRGAONKAR A A, MACIVER M A, PATANKAR N A.A new mathematical formulation and fast algorithm for fully resolved simulation of self-propulsion[J]. Journal of Computational Physics, 2009, 228(7): 2366-2390.
[18] WANG Z, TENG Y, LIU M.A semi-resolved CFD-DEM approach for particulate flows with kernel based approximation and Hilbert curve based searching strategy[J]. Journal of Computational Physics, 2019, 384: 151-169.
[19] CONCHA A F.Settling velocities of particulate systems[J]. Kona Powder and Particle Journal, 2009, 27: 18-37.
[20] LAPPLE C E, SHEPHERD C B.Calculation of particle trajectories[J]. Industrial & Engineering Chemistry, 1940, 32(5): 605-617.
[21] MONDAL S, WU C H, SHARMA M M.Coupled CFD-DEM simulation of hydrodynamic bridging at constrictions[J]. International Journal of Multiphase Flow, 2016, 84: 245-263.
[22] SUN H, XU S, PAN X, et al.Investigating the jamming of particles in a three-dimensional fluid-driven flow via coupled CFD-DEM simulations[J]. International Journal of Multiphase Flow, 2019, 114: 140-153.
[23] XU Chengyuan, YAN Xiaopeng, KANG Yili, et al.Friction coefficient: A significant parameter for lost circulation control and material selection in naturally fractured reservoir[J]. Energy, 2019, 174: 1012-1025.
[24] XIE Changhua, MA Huaqing, ZHAO Yongzhi.Investigation of modeling non-spherical particles by using spherical discrete element model with rolling friction[J]. Engineering Analysis with Boundary Elements, 2019(105): 207-220.
[25] 许成元, 闫霄鹏, 康毅力, 等. 深层裂缝性储集层封堵层结构失稳机理与强化方法[J]. 石油勘探与开发, 2020, 47(2): 430-440.
XU Chengyuan, YAN Xiaopeng, KANG Yili, et al.Structural failure mechanism and strengthening method of fracture plugging zone for lost circulation control in deep naturally fractured reservoirs[J]. Petroleum Exploration and Development, 2020, 47(2): 430-440.
[26] 孙其诚, 金峰, 王光谦. 密集颗粒物质的多尺度结构[J]. 力学与实践, 2010, 33(1): 10-15.
SUN Qicheng, JIN Feng, WANG Guangqian.The multiscale structure of dense granular matter[J]. Mechanics and Practice, 2010, 33(1): 10-15.
[27] XU Chengyuan, KANG Yili, YOU Lijun, et al.Lost-circulation control for formation-damage prevention in naturally fractured reservoir: Mathematical model and experimental study[J]. SPE Journal, 2017, 22(5): 1654-1670.
[28] YAN Xiaopeng, XU Chengyuan, KANG Yili, et al.Mesoscopic structure characterization of plugging zone for lost circulation control in fractured reservoirs based on photoelastic experiment[J]. Journal of Natural Gas Science and Engineering, 2020, 79: 103339.
[29] MULLIN T.Mixing and de-mixing[J]. Science, 2002, 295(5561): 1851-1858.
[30] XU Chengyuan, XIE Zhichao, KANG Yili, et al.A novel material evaluation method for lost circulation control and formation damage prevention in deep fractured tight reservoir[J]. Energy, 2020, 210: 118574.

Options

文章导航

模态框（Modal）标题

摘要

本文引用格式

Abstract

参考文献