喷漏异层井筒气液流动数值模拟研究

doi:10.3969/j.issn.2096-1693.2026.02.013

摘要/Abstract

摘要：

喷漏异层是井控中最复杂的情况，准确预测井筒中气液两相流的流动状态和压力分布是处理此类风险事故的关键。本文建立了喷漏同存条件下，井筒与地层耦合的一维气液两相流模型。通过调整孔隙压力和破裂压力的分布改变喷层和漏层的相对位置，模拟上喷下漏和下喷上漏。另外，通过设置不同的漏层破裂压力，模拟地层的不同抗钻井液漏失能力。本文采用有限差分数值模拟方法对模型进行求解，得到不同工况下井筒内部含气率、压力和速度沿井深的瞬时分布。数值模拟结果表明，漏失层位破裂压力的大小是井内出现不同流动状态的关键因素，破裂压力足够高时井内溢流不会向复杂情况发展。当破裂压力较低时，井内会出现溢漏转换。而如果存在破裂压力极低的薄弱井段，井内则会发生喷漏同存的地下井喷。在上喷下漏情况下，若井底漏层有较高的破裂压力，井内的溢流将停止，发展为停喷不漏的状态，关井套压持续增加。漏层破裂压力较低时，井内出现由喷转漏的状态，关井套压呈现先增大而后保持不变的变化规律。当漏层破裂压力更低时，井内会形成边喷边漏的地下井喷状态。关井套压先增大而后小幅上升，套压拐点小于喷转漏情况下的稳定值。上漏下喷情况下，随着漏层破裂压力的降低，井内出现的流动状态依次为停喷不漏、由喷转漏和边喷边漏。关井套压变化趋势与破裂压力相关。破裂压力越低，套压拐点值越低。停喷不漏和由喷转漏时，井内出现有限长污染钻井液段离底滑脱的现象。边喷边漏情况下，喷层以上形成连续污染段，在喷层之下则存在含气率为常数的高含气段。

关键词: 喷漏异层, 井控, 气液两相流, 井筒, 数值模拟

Abstract:

The coexistence of influx and loss in different formations represents the most complex scenario in well control. Accurate prediction of the gas-liquid two-phase flow behavior and pressure distribution within the wellbore is essential for effectively dealing with such high-risk incidents. In this study, a one-dimensional coupled gas-liquid two-phase flow model of the wellbore and the formation is developed under conditions of simultaneous influx and loss. By adjusting the distributions of pore pressure and fracture pressure to alter the relative positions of the influx and loss zones, the upper-influx/lower-loss and lower-influx/upper-loss scenarios are simulated. Additionally, by specifying different fracture pressures for the loss zone, the varying resistance of the formation to drilling fluid loss is simulated. The model is solved using a finite-difference numerical method, yielding the transient distributions of gas holdup, pressure, and velocity along the well depth under different operating conditions. The simulation results indicate that the fracture pressure of the loss zone is a key factor governing the flow regimes within the wellbore. When the fracture pressure is sufficiently high, the influx does not evolve into more complex conditions. At lower fracture pressures, a transition from influx to loss occurs within the wellbore. If a weak section with extremely low fracture pressure exists, a subsurface blowout characterized by the coexistence of influx and loss may develop. Under the upper-influx/lower-loss scenario, if the loss zone at the bottomhole has a relatively high fracture pressure, the influx within the wellbore ceases and the system evolves into a no-influx/no-loss state, with the shut-in casing pressure continuing to increase. When the fracture pressure of the loss zone is lower, a transition from influx to loss occurs, and the shut-in casing pressure first increases and then stabilizes. When the fracture pressure is further reduced, a subsurface blowout characterized by simultaneous influx and loss develops. The shut-in casing pressure initially increases and then rises slightly, and the inflection-point pressure is lower than the stabilized value in the influx-to-loss transition scenario. Under the lower-influx/upper-loss scenario, as the fracture pressure of the loss zone decreases, the flow regimes within the wellbore successively evolve from no-influx/no-loss, to influx-to-loss transition, and finally to simultaneous influx and loss. The variation of shut-in casing pressure is closely related to the fracture pressure. A lower fracture pressure corresponds to a lower inflection-point value of the casing pressure. In the no-influx/no-loss and influx-to-loss transition cases, a finite-length contaminated drilling fluid section detaches from the bottom and migrates upward. In contrast, under simultaneous influx and loss, a continuous contaminated section forms above the influx zone, while a high gas-fraction section with nearly constant gas holdup exists below it.

Key words: kick and loss in different formations, well control, gas-liquid two-phase flow, wellbore, numerical modeling

中图分类号:

TE249
X937

李轶明, 吕忠晋, 齐浩楠, 刘润宇, 梁翊, 张卓嘉, 张卓燚. 喷漏异层井筒气液流动数值模拟研究[J]. 石油科学通报, 2026, 11(2): 544-557.

LI Yiming, LV Zhongjin, QI Haonan, LIU Runyu, LIANG Yi, ZHANG Zhuojia, ZHANG Zhuoyi. Numerical study of gas-liquid flow in wellbores during coexistence of kick and loss in different formations[J]. Petroleum Science Bulletin, 2026, 11(2): 544-557.

https://sykxtb.cup.edu.cn/CN/Y2026/V11/I2/544

图/表 12

图1 多流动通道井筒—地层物理模型

Fig. 1 Wellbore formation physical model with multiple flow channels

图2 计算网格

Fig. 2 Computational grid

表1 喷漏异层层位参数设置

Table 1 Parameter setting of different layer level of blowout leakage

喷漏类型	工况	漏失层位置/m	破裂压力/MPa(系数)	溢流层位置/m	孔隙压力/MPa(系数)
上喷下漏	1	2000	32 (1.626)	1800	30 (1.7)
	2		33 (1.677)
	3		36 (1.830)
上漏下喷	1	1800	36 (2.034)	2000	30 (1.5)
	2		32 (1.807)
	3		28 (1.580)
	4		25 (1.410)

图3 地层压力系统示意图

Fig. 3 Schematic diagram of formation pressure system

表2 365井参数

Table 2 Parameters of well 365

参数	数值	参数	数值
B₁储层垂深	1524 m	钻头尺寸	152 mm
B₁储层测深	2877 m	井深	2944 m
B₁储层压力	27.9 MPa	钻杆(OD)	88.9 mm
漏失压力	28.2 MPa	钻杆(ID)	70.2 mm
漏层位置	2904 m	原始钻井液密度	1.5 g/cm³
技术套管(ID)	157 mm	塑性粘度(PV)	22 cP
技术套管下深	2860 m	屈服应力(YP)	28 Pa

图4 套压随时间变化图

Fig. 4 Casing pressure vs. time

图5 上喷下漏井下气液流动示意图

Fig. 5 Schematic diagram of gas-liquid flow in downhole with upper blowout and lower leakage

图6 上漏下喷下气液流动示意图

Fig. 6 Schematic diagram of gas-liquid flow in upper leakage and lower blowout

图7 上喷下漏井筒压力变化图

Fig. 7 Wellbore pressure variation diagram of upper blowout and lower leakage

图8 上漏下喷井筒压力变化图

Fig. 8 Wellbore pressure variation diagram of upper leakage and lower blowout

图9 上喷下漏井筒截面含气率变化图

Fig. 9 Change diagram of gas holdup in wellbore section with upper blowout and lower leakage

图10 上漏下喷井筒截面含气率变化图

Fig. 10 Change diagram of gas holdup in wellbore section with upper leakage and lower blowout

参考文献 34

[1]	李照, 蒋林, 江迎军, 等. 四川多压力系统复杂深井控压钻井技术探讨[C]. 第32届全国天然气学术年会(2020)论文集. 重庆, 2020: 2423-2429.
	[LI Z, JIANG L, JIANG Y J, et al. Discussion on pressure control drilling technology for complex deep wells in Sichuan multi-pressure system[C]. Proceedings of the 32nd National Natural Gas Academic Conference. Chongqing, 2020: 2423-2429.]
[2]	NIE R G, XIA H W, MAO L J, et al. Research on conversion time between lost circulation and overflow for the fractured stratum[J]. Petroleum, 2020, 6(1): 98-105. doi: 10.1016/j.petlm.2019.06.007 URL
[3]	邓虎, 贾利春. 四川盆地深井超深井钻井关键技术与展望[J]. 天然气工业, 2022, 42(12): 82-94.
	[DENG H, JIA L C. Key technologies for drilling deep and ultra-deep wells in the Sichuan Basin: Current status, challenges and prospects[J]. Natural Gas Industry, 2022, 42(12): 82-94.]
[4]	贾红军, 孟英峰, 李皋, 等. 钻遇多压力系统气层溢漏同存规律研究[J]. 断块油气田, 2012, 19(3): 359-363.
	[JIA H J, MENG Y F, LI G, et al. Research on well kick accompanied with lost circulation during drilling of gas formation with multi-pressure system[J]. Fault-Block Oil & Gas Field, 2012, 19(3): 359-363.]
[5]	谭宾, 庞平, 胡旭光. 国内外井喷失控抢险技术现状与发展建议[J]. 钻采工艺, 2024, 47(4): 1-7.
	[TAN B, PANG P, HU X G. Current situation and development suggestions of uncontrolled blowout emergency response technologies at home and abroad[J]. Drilling & Production Technology, 2024, 47(4): 1-7.]
[6]	TUTTLE S G, FISHER B T, KESSLER D A, et al. Petroleum wellhead burning: A review of the basic science for burn efficiency prediction[J]. Fuel, 2021, 303: 121279. doi: 10.1016/j.fuel.2021.121279 URL
[7]	宋亚港. 碳酸盐岩地层溢漏同存井筒多相流状态及井筒压力控制方法研究[D]. 北京: 中国石油大学(北京), 2023.
	[SONG Y G. Study on multiphase flow state and control method of wellbore pressure in carbonate rock formation[D]. Beijing: China University of Petroleum (Beijing), 2023.]
[8]	舒刚, 孟英峰, 李皋, 等. 重力置换式漏喷同存机理研究[J]. 石油钻探技术, 2011, 39(1): 6-11.
	[SHU G, MENG Y F, LI G, et al. Mechanism of mud loss and well kick due to gravity displacement[J]. Petroleum Drilling Techniques, 2011, 39(1): 6-11.]
[9]	罗平亚, 孟英峰. 低压欠平衡钻井: 勘探钻井技术发展新动向(待续)[J]. 西南石油学院学报, 1998(2): 39-46.
	[LUO P Y, MENG Y F. Low pressure under-balanced drilling: A new approach in exploring drilling[J]. Journal of Southwest Petroleum Institute, 1998(2): 39-46.]
[10]	马宗金. 总结经验教训提高天然气井钻井井控能力[J]. 钻采工艺, 2004, 27(4): 1-5.
	[MA Z J. Summing up experience to improve well control ability of natural gas well[J]. Drilling & Production Technology, 2004, 27(4): 1-5.]
[11]	乐宏, 吴鹏程, 梁婕, 等. 裂缝发育页岩地层水平井钻井气液重力置换规律[J]. 天然气工业, 2021, 41(12): 90-98.
	[YUE H, WU P C, LIANG J, et al. Gas-liquid gravity displacement laws during horizontal well drilling in shale formations with developed fractures[J]. Natural Gas Industry, 2021, 41(12): 90-98.]
[12]	XIAO D, MENG Y F, ZHAO X Y, et al. Liquid-liquid gravity displacement in a vertical fracture during drilling: Experimental study and mathematical model[J]. Energy Exploration & Exploitation, 2020, 38(2): 533-554.
[13]	赵向阳, 孟英峰, 杨顺辉, 等. 钻井液液压作用下裂缝性定容封闭体地层压力的变化规律[J]. 天然气工业, 2018, 38(6): 91-96.
	[ZHAO X Y, MENG Y F, YANG S H, et al. Changing laws of formation pressure of constant-volume fractured enclosed reservoirs under the hydraulic pressure of drilling fluid[J]. Natural Gas Industry, 2018, 38(6): 91-96.]
[14]	BENNION D B. Underbalanced operations offer pluses and minuses[J]. Oil & Gas Journal, 1996, 94(1): 33-40.
[15]	张兴全, 周英操, 刘伟, 等. 欠平衡气侵与重力置换气侵特征及判定方法[J]. 中国石油大学学报(自然科学版), 2015, 39(1): 95-102.
	[ZHANG X Q, ZHOU Y C, LIU W, et al. A method for characterization and identification of gas kicks caused by underbalanced pressure and gravity displacement[J]. Journal of China University of Petroleum (Edition of Natural Science), 2015, 39(1): 95-102.]
[16]	伍贤柱, 胡旭光, 韩烈祥, 等. 井控技术研究进展与展望[J]. 天然气工业, 2022, 42(2): 133-142.
	[WU X Z, HU X G, HAN L X, et al. Research progress and prospect of well control technology[J]. Natural Gas Industry, 2022, 42(2): 133-142.]
[17]	PETERSEN J, ROMMETVEIT R, TARR B A. Kick with lost circulation simulator, a tool for design of complex well control situations[C]. SPE Asia Pacific Oil and Gas Conference and Exhibition. Perth: SPE, 1998: SPE-49956-MS.
[18]	张敬荣. 喷漏共存的堵漏压井技术[J]. 钻采工艺, 2008, 31(5): 30-33.
	[ZHANG J R. Well killing technology for wells with blowout and lost circulation coexisting[J]. Drilling & Production Technology, 2008, 31(5): 30-33.]
[19]	MAHRY A, SURYADI D, SUFIADI E, et al. Well control in carbonate zone-total loss and kick in gas reservoir[C]. Offshore Technology Conference. Houston, Texas, USA, 2016: D021S017R004.
[20]	江朝, 张华卫, 黄在福, 等. 雅达油田F13井沥青层喷漏同存复杂情况的处理[J]. 石油钻采工艺, 2017, 39(4): 528-532.
	[JIANG Z, ZHANG H W, HUANG Z F, et al. Handing of influx-leakage coexisting complication in asphalt formation of Well F13 at the Yadavaran Oilfield[J]. Oil Drilling & Production Technology, 2017, 39(4): 528-532.]
[21]	NASSAB K K, TING S Z, BUAPHA S, et al. How to improve accuracy of a kick tolerance model by considering the effects of kick classification, frictional losses, pore pressure profile, and influx temperature[J]. SPE Drilling & Completion, 2022, 37(1): 15-25.
[22]	邓虎, 唐贵, 张林. 超深井高温高压井筒复杂流动压力演变规律研究[J]. 西南石油大学学报(自然科学版), 2023, 45(4): 111-120. doi: 10.11885/j.issn.1674-5086.2022.09.17.01
	[DENG H, TANG G, ZHANG L. A study on evolution law of complex flow pressure in ultra-deep wells with high temperature and high pressure[J]. Journal of Southwest Petroleum University (Science & Technology Edition), 2023, 45(4): 111-120.]
[23]	ZHANG G, LI J, YANG H W, et al. A new detection method of co-existence of well kick and loss circulation based on thermal behavior of wellbore-formation coupled system[J]. International Journal of Hydrogen Energy, 2024, 58: 239-258. doi: 10.1016/j.ijhydene.2024.01.167 URL
[24]	YU X, GAO Y H, ZHAO X X, et al. Research on heat transfer law of multiphase flow in wellbore under coexistence of overflow and lost circulation in deepwater drilling[J]. Case Studies in Thermal Engineering, 2024, 55: 104103. doi: 10.1016/j.csite.2024.104103 URL
[25]	郭海清, 魏军会, 王鹏程, 等. 高温高压气井酸性气体溢流运移规律[J]. 石油钻采工艺, 2025, 47(2): 168-178.
	[GUO H Q, WEI J H, WANG P C, et al. Research on the migration law of acid gas overflow in high temperature and high pressure gas wells[J]. Oil Drilling & Production Technology, 2025, 47(2): 168-178.]
[26]	孙宝江, 王春生, 辛桂振, 等. 复杂压力体系地层钻探溢流压井技术研究[J]. 钻采工艺, 2024, 47(4): 42-50, I0016.
	[SUN B J, WANG C S, XIN G Z, et al. Research on well killing technology in drilling complex pressure system formation[J]. Drilling & Production Technology, 2024, 47(4): 42-50, I0016.]
[27]	ZUBER N, FINDLAY J A. Average volumetric concentration in two-phase flow systems[J]. Journal of Heat Transfer, 1965, 87(4): 453-468. doi: 10.1115/1.3689137 URL
[28]	SHI H, HOLMES J A, DURLOFSKY L J, et al. Drift-flux modeling of two-phase flow in wellbores[J]. SPE Journal, 2005, 10(1): 24-33. doi: 10.2118/84228-PA URL
[29]	HIBIKI T, ISHII M. One-dimensional drift-flux model and constitutive equations for relative motion between phases in various two-phase flow regimes[J]. International Journal of Heat and Mass Transfer, 2003, 46(25): 4935-4948. doi: 10.1016/S0017-9310(03)00322-3 URL
[30]	CHOI J, PEREYRA E, SARICA C, et al. An efficient drift-flux closure relationship to estimate liquid holdups of gas-liquid two-phase flow in pipes[J]. Energies, 2012, 5(12): 5294-5306. doi: 10.3390/en5125294 URL
[31]	BHAGWAT S M, GHAJAR A J. A flow pattern independent drift flux model based void fraction correlation for a wide range of gas-liquid two phase flow[J]. International Journal of Multiphase Flow, 2014, 59: 186-205. doi: 10.1016/j.ijmultiphaseflow.2013.11.001 URL
[32]	TANG H W, BAILEY W, STONE T, et al. A unified gas-liquid drift-flux model for coupled wellbore-reservoir simulation[C]. SPE Annual Technical Conference and Exhibition, Calgary, Alberta, Canada, 2019: D021S024R005.
[33]	TABJULA J L, WEI C, SHARMA J, et al. Well-scale experimental and numerical modeling studies of gas bullheading using fiber-optic DAS and DTS[J]. Geoenergy Science and Engineering, 2023, 225: 211662. doi: 10.1016/j.geoen.2023.211662 URL
[34]	KRIVOLAPOV D, MASALIDA I, POLYARUSH A, et al. Successful implementation of the PMCD technology for drilling and completing the well in incompatible conditions at Severo-Danilovskoe oil & gas field[C]. SPE Russian Petroleum Technology Conference. Virtual, 2021: SPE-206456-MS.

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