考虑支撑剂运移的压裂停泵压降模型

doi:10.7623/syxb202304007

石油学报 ›› 2023, Vol. 44 ›› Issue (4): 647-656.DOI: 10.7623/syxb202304007

考虑支撑剂运移的压裂停泵压降模型

王飞¹, 周彤², 许佳鑫¹, 管晶晶¹, 索杰林¹, 张士诚¹, 廖凯¹, 邹雨时¹

1. 中国石油大学(北京)油气资源与探测国家重点实验室北京 102249;
2. 中国石油化工股份有限公司石油勘探开发研究院北京 100083

收稿日期:2022-05-28 修回日期:2023-02-04 出版日期:2023-04-25 发布日期:2023-05-05
通讯作者: 许佳鑫,男,1997年2月生,2022年获中国石油大学(北京)硕士学位,现为中国石油化工股份有限公司重庆涪陵页岩气勘探开发有限公司助理工程师,主要从事页岩气勘探开发工作。Email:xujxyx@163.com
作者简介:王飞,女,1982年10月生,2010年获英国Heriot-Watt大学博士学位,现为中国石油大学(北京)石油工程学院副教授、博士生导师,主要从事油气田开发方面的教学与科研工作。Email:wangfei@cup.edu.cn
基金资助:
国家自然科学基金面上项目(No.51974332)资助。

Fracturing pump-stopping pressure drop model considering proppant migration

Wang Fei¹, Zhou Tong², Xu Jiaxin¹, Guan Jingjing¹, Suo Jielin¹, Zhang Shicheng¹, Liao Kai¹, Zou Yushi¹

1. State Key Laboratory of Petroleum Resources and Prospecting, China University of Petroleum, Beijing 102249, China;
2. Sinopec Petroleum Exploration and Production Research Institute, Beijing 100083, China

Received:2022-05-28 Revised:2023-02-04 Online:2023-04-25 Published:2023-05-05

摘要/Abstract

摘要： 针对现有压裂停泵压降模型不考虑支撑剂运移、无法解释支撑剂铺置效果的难题,提出适用于主加砂压裂的停泵压降模型,模型考虑了裂缝系统中携砂液-支撑剂靠黏度和速度耦合的水平运移与沉降运动,以及基质系统中压裂液靠黏性力和重力作用的三维流动,通过将裂缝系统与基质系统耦合求解,实现了主加砂压裂停泵过程的支撑剂运移模拟计算,获得的井底压降导数双对数曲线呈现出"厂"字型的形态特征,并按照停泵时间顺序划分为支撑剂沉降、支撑剂水平运移、支撑剂减速运移、支撑剂压实和支撑剂停止运移5个主控阶段。研究结果表明:支撑剂铺置越均匀(主次裂缝内砂量越接近),压降导数曲线越平缓,支撑剂沉降控制期越长,支撑剂减速运移期越短,支撑剂压实控制阶段会呈现出1/4斜率段;支撑剂充填比例越大(缝网总体积越小),压降导数曲线越陡,支撑剂水平运移控制期越短,支撑剂运移控制阶段的压降及导数会呈现重合趋势。选取涪陵页岩气田一口典型压裂水平井逐段开展停泵压降曲线拟合,反演获得各加砂压裂段的支撑裂缝体积与铺砂均匀程度,为定量评价水力压裂加砂效果、认识压后支撑剂运移规律提供了理论依据。

关键词: 主压裂, 停泵压降模型, 支撑剂运移, 支撑裂缝体积, 铺砂效果, 压降曲线拟合

Abstract: In view of the problem that the current fracturing pump-stopping pressure drop model takes no account of proppant migration and cannot explain the proppant laying effect, the paper proposes a set of pump-stopping pressure drop model suitable for main sand fracturing. The model considers the horizontal shifting and settlement movement of sand carrying fluid-proppant relying on the coupling between viscosity and velocity in the fracture system, as well as the three-dimensional flow of fracturing fluid driven by viscous force and gravity in the matrix system. Based on the coupled solution of fracture system and matrix system, it achieves the simulated calculation of proppant migration in the pump-stopping process of main sand fracturing, and the double logarithmic curve of bottom-hole pressure drop derivative presents the morphological characteristics of L-shape. Moreover, it can be divided into five main control stages according to the pump-stopping time sequence, i.e., proppant settlement, horizontal proppant migration, proppant decelerated migration, proppant compaction and proppant stopping migration. Research shows that the more uniformly the proppant is laid (the closer the sand amount in both the primary and secondary fractures), the more gentle the pressure drop derivative curve, the longer the proppant settlement control period and the shorter the proppant deceleration migration period, and the proppant compaction control stage will show a 1/4 slope section; the larger the proppant filling ratio (the smaller the total volume of fracture network), the steeper the pressure drop derivative curve, the shorter the proppant horizontal migration control period, and the pressure drop and derivative in the proppant migration control stage will tend to coincide. A typical fractured horizontal well in Fuling shale gas field is selected to carry out pump-stopping pressure drop curve fitting in each section sequentially, and the prop-fracture volume and sanding uniformity coefficient of each sand fracturing section are obtained by inversion, thus providing a theoretical basis for quantitatively evaluating the hydraulic sand fracturing effect and understanding the proppant migration law after fracturing.

Key words: main fracturing, pump-stopping pressure drop model, proppant migration, propped fracture volume, sanding performance, falloff curve fitting

中图分类号:

TE357.1

王飞, 周彤, 许佳鑫, 管晶晶, 索杰林, 张士诚, 廖凯, 邹雨时. 考虑支撑剂运移的压裂停泵压降模型[J]. 石油学报, 2023, 44(4): 647-656.

Wang Fei, Zhou Tong, Xu Jiaxin, Guan Jingjing, Suo Jielin, Zhang Shicheng, Liao Kai, Zou Yushi. Fracturing pump-stopping pressure drop model considering proppant migration[J]. Acta Petrolei Sinica, 2023, 44(4): 647-656.

参考文献

[1] 李国欣,吴志宇,李桢,等. 陆相源内非常规石油甜点优选与水平井立体开发技术实践——以鄂尔多斯盆地延长组7段为例[J].石油学报,2021,42(6):736-750.
LI Guoxin,WU Zhiyu,LI Zhen,et al.Optimal selection of unconventional petroleum sweet spots inside continental source kitchens and actual application of three-dimensional development technology in horizontal wells:a case study of the Member 7 of Yanchang Formation in Ordos Basin[J].Acta Petrolei Sinica,2021,42(6):736-750.
[2] 郭彤楼,王勇飞,叶素娟,等.四川盆地中江气田成藏条件及勘探开发关键技术[J].石油学报,2022,43(1):141-155.
GUO Tonglou,WANG Yongfei,YE Sujuan,et al.Accummulation conditions and key technologies for exploration and development of Zhongjiang gas field in Sichuan Basin[J].Acta Petrolei Sinica,2022,43(1):141-155.
[3] 姜鹏飞,吴建发,朱逸青,等.四川盆地海相页岩气富集条件及勘探开发有利区[J].石油学报,2023,44(1):91-109.
JIANG Pengfei,WU Jianfa,ZHU Yiqing,et al.Enrichment conditions and favorable areas for exploration and development of marine shale gas in Sichuan Basin[J].Acta Petrolei Sinica,2023,44(1):91-109.
[4] 梁兴,徐政语,张介辉,等.浅层页岩气高效勘探开发关键技术——以昭通国家级页岩气示范区太阳背斜区为例[J].石油学报,2020,41(9):1033-1048.
LIANG Xing,XU Zhengyu,ZHANG Jiehui,et al.Key efficient exploration and development technoloiges of shallow shale gas:a case study of Taiyang anticline area of Zhaotong national shale gas demonstration zone[J].Acta Petrolei Sinica,2020,41(9):1033-1048.
[5] MAYERHOFER M J,ECONOMIDES M J.Fracture-injection-test interpretation:leakoff coefficient vs.permeability[J].SPE Production & Facilities,1997,12(4):231-236.
[6] NOLTE K G,SMITH M B.Interpretation of fracturing pressures[J].Journal of Petroleum Technology,1981,33(9):1767-1775.
[7] CASTILLO J L.Modified fracture pressure decline analysis including pressure-dependent leakoff[R].SPE 16417,1987.
[8] 张士诚,王鸿勋.压降曲线三维分析方法及应用[J].石油学报,1990,11(3):60-71.
ZHANG Shicheng,WANG Hongxun.The P-3D analyzing method of fracturing pressure decline curve and its application[J].Acta Petrolei Sinica,1990,11(3):60-71.
[9] SOLIMAN M Y.Technique for considering fluid compressibility and temperature changes in mini-frac analysis[R].SPE 15370,1986.
[10] SOLIMAN M Y,MIRANDA C,WANG H M.Application of after-closure analysis to a dual-porosity formation,to CBM,and to a fractured horizontal well[J].SPE Production & Operations,2010,25(4):472-483.
[11] 毛国扬,杨怀成,张文正.裂缝性储层压降分析方法及其应用[J].石油天然气学报,2011,33(7):116-118.
MAO Guoyang,YANG Huaicheng,ZHANG Wenzheng.Pressure drowdown analysis method and its application in fractured reservoir[J].Journal of Oil and Gas Technology,2011,33(7):116-118.
[12] BACHMAN R C,WALTERS D A,HAWKES R A,et al.Reappraisal of the G time concept in mini-frac analysis[R].SPE 160169,2012.
[13] 刘书杰,蔡久杰,王飞,等.改进压裂压降曲线分析方法在海上低渗气田的应用[J].断块油气田,2015,22(3):369-373.
LIU Shujie,CAI Jiujie,WANG Fei,et al.Application of improved pressure decline analysis for fracturing in offshore low permeability gas field[J].Fault-Block Oil & Gas Field,2015,22(3):369-373.
[14] 李军龙,袁操,詹媛珍,等.缝洞型碳酸盐岩储层酸压停泵压降曲线分析[J].油气井测试,2017,26(5):24-27.
LI Junlong,YUAN Cao,ZHAN Yuanzhen,et al.Analysis of pump-stopping pressure drop curves of acid fracturing for fracture-cavity carbonate reservoir[J].Well Testing,2017,26(5):24-27.
[15] MOHAMED I M,NASRALLA R A,SAYAD M A,et al.Evaluation of after-closure analysis techniques for tight and shale gas formations[R].SPE 140136,2011.
[16] LIU Guoqing,EHLIG-ECONOMIDES C.Interpretation methodology for fracture calibration test before-closure analysis of normal and abnormal leakoff mechanisms[R].SPE 179176,2016.
[17] LIU Guoqing,EHLIG-ECONOMIDES C.Practical considerations for diagnostic fracture injection test (DFIT)analysis[J].Journal of Petroleum Science and Engineering,2018,171:1133-1140.
[18] WANG Hanyi,ELLIOTT B,SHARMA M.Estimating reservoir and fracture properties from stage-by-stage pressure decline analysis in horizontal well[R].SPE 201672,2020.
[19] 周彤,苏建政,李凤霞,等.基于停泵压力降落曲线分析的压后裂缝参数反演[J].天然气地球科学,2019,30(11):1646-1654.
ZHOU Tong,SU Jianzheng,LI Fengxia,et al.An approach to estimate hydraulic fracture parameters with the pressure falloff data of main treatment[J].Natural Gas Geoscience,2019,30(11):1646-1654.
[20] TALLEY G R,SWINDELL T M,WATERS G A,et al.Field application of after-closure analysis of fracture calibration tests[R].SPE 52220,1999.
[21] SOLIMAN M Y,MIRANDA C,WANG H M.After closure analysis for unconventional reservoirs and completion[R].SPE 124135,2009.
[22] BARREE R D,BARREE V L,CRAIG D P.Holistic fracture diagnostics:consistent interpretation of prefrac injection tests using multiple analysis methods[J].SPE Production & Operations,2009,24(3):396-406.
[23] MARONGIU-PORCU M,EHLIG-ECONOMIDES C A,ECONOMIDES M J.Global model for fracture falloff analysis[R].SPE 144028,2011.
[24] 王飞,张士诚,蔡久杰.一种简便的测试压裂压力递减分析方法[J].西南石油大学学报:自然科学版,2014,36(3):115-120.
WANG Fei,ZHANG Shicheng,CAI Jiujie.Fast pressure decline analysis of fracture calibration tests[J].Journal of Southwest Petroleum University:Science & Technology Edition,2014,36(3):115-120.
[25] ZANGANEH B,CLARKSON C R,HAWKES R V.Reinterpretation of fracture closure dynamics during diagnostic fracture injection tests[R].SPE 185649,2017.
[26] ZANGANEH B,CLARKSON C R,JONES J R.Reinterpretation of flow patterns during DFITs based on dynamic fracture geometry,leakoff and afterflow[R].SPE 189840,2018.
[27] ZOU Yushi,MA Xinfang,ZHANG Shicheng.Numerical modeling of fracture propagation during temporary-plugging fracturing[J].SPE Journal,2020,25(3):1503-1522.
[28] WANG Xu,WINTERFELD P,MA Xu,et al.Simulation of coupled hydraulic fracturing propagation and gas well performance in shale gas reservoirs[R].SPE 168967,2014.
[29] ROOSTAEI M,NOURI A,FATTAHPOUR V,et al.Numerical simulation of proppant transport in hydraulic fractures[J].Journal of Petroleum Science & Engineering,2018,163:119-138.
[30] STABEN M E,ZINCHENKO A Z,DAVIS R H.Motion of a particle between two parallel plane walls in low-Reynolds-number Poiseuille flow[J].Physics of Fluids,2003,15(6):1711-1733.
[31] SHARMA M M.Advanced fracturing technology for tight gas:an east Texas field demonstration[R].Texas:University of Texas,2005.
[32] MCCABE W L,SMINTH J C,HARRIOTT P.Unit operations of chemical engineering[M].6th ed.New York:McGraw-Hill,2003:166-170.
[33] SANO O,HASIMOTO H.The effect of two plane walls on the motion of a small sphere in a viscous fluid[J].Journal of Fluid Mechanics,1978,87(4):673-694.
[34] HOUZÉ O,VITURAT D,FJAERE O S,et al.Dynamic data analysis,V5.12.01,p.563.2017[EB/OL].https://www.kappaeng.com/.
[35] WANG Hanyi,ELLIOTT B,SHARMA M.Pressure decline analysis in fractured horizontal wells:comparison between diagnostic fracture injection test,flowback,and main stage falloff[J].SPE Drilling & Completion,2021,36(3):717-729.
[36] 邹雨时,石善志,张士诚,等.薄互层型页岩油储集层水力裂缝形态与支撑剂分布特征[J].石油勘探与开发,2022,49(5):1025-1032.
ZOU Yushi,SHI Shanzhi,ZHANG Shicheng,et al.Hydraulic fracture geometry and proppant distribution in thin interbedded shale oil reservoirs[J].Petroleum Exploration and Development,2022,49(5):1025-1032.
[37] 潘林华,张烨,王海波,等.页岩复杂裂缝支撑剂分流机制[J].中国石油大学学报:自然科学版,2020,44(1):61-70.
PAN Linhua,ZHANG Ye,WANG Haibo,et al.Mechanism study on proppants' division during shale complex fracturing of shale rocks[J].Journal of China University of Petroleum:Edition of Natural Science,2020,44(1):61-70.

考虑支撑剂运移的压裂停泵压降模型

Fracturing pump-stopping pressure drop model considering proppant migration

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