Full Text:   <1742>

Suppl. Mater.: 

CLC number: 

On-line Access: 2024-08-27

Received: 2023-10-17

Revision Accepted: 2024-05-08

Crosschecked: 2023-02-01

Cited: 0

Clicked: 1415

Citations:  Bibtex RefMan EndNote GB/T7714

 ORCID:

Xia YAN

https://orcid.org/0000-0002-9768-6293

-   Go to

Article info.
Open peer comments

Journal of Zhejiang University SCIENCE A 2023 Vol.24 No.1 P.37-55

http://doi.org/10.1631/jzus.A2200142


Effect of hydraulic fracture deformation hysteresis on CO2huff-n-puff performance in shale gas reservoirs


Author(s):  Xia YAN, Pi-yang LIU, Zhao-qin HUANG, Hai SUN, Kai ZHANG, Jun-feng WANG, Xia YAN

Affiliation(s):  School of Petroleum Engineering, China University of Petroleum (East China),, Qingdao 266580, China; more

Corresponding email(s):   RCOGFR_UPC@126.com

Key Words:  Enhanced gas recovery, CO2 huff-n-puff, Coupled geomechanics and multi-component flow, Hydraulic fracture deformation hysteresis, Embedded discrete fracture model (EDFM)


Xia YAN, Pi-yang LIU, Zhao-qin HUANG, Hai SUN, Kai ZHANG, Jun-feng WANG, Xia YAN. Effect of hydraulic fracture deformation hysteresis on CO2huff-n-puff performance in shale gas reservoirs[J]. Journal of Zhejiang University Science A, 2023, 24(1): 37-55.

@article{title="Effect of hydraulic fracture deformation hysteresis on CO2huff-n-puff performance in shale gas reservoirs",
author="Xia YAN, Pi-yang LIU, Zhao-qin HUANG, Hai SUN, Kai ZHANG, Jun-feng WANG, Xia YAN",
journal="Journal of Zhejiang University Science A",
volume="24",
number="1",
pages="37-55",
year="2023",
publisher="Zhejiang University Press & Springer",
doi="10.1631/jzus.A2200142"
}

%0 Journal Article
%T Effect of hydraulic fracture deformation hysteresis on CO2huff-n-puff performance in shale gas reservoirs
%A Xia YAN
%A Pi-yang LIU
%A Zhao-qin HUANG
%A Hai SUN
%A Kai ZHANG
%A Jun-feng WANG
%A Xia YAN
%J Journal of Zhejiang University SCIENCE A
%V 24
%N 1
%P 37-55
%@ 1673-565X
%D 2023
%I Zhejiang University Press & Springer
%DOI 10.1631/jzus.A2200142

TY - JOUR
T1 - Effect of hydraulic fracture deformation hysteresis on CO2huff-n-puff performance in shale gas reservoirs
A1 - Xia YAN
A1 - Pi-yang LIU
A1 - Zhao-qin HUANG
A1 - Hai SUN
A1 - Kai ZHANG
A1 - Jun-feng WANG
A1 - Xia YAN
J0 - Journal of Zhejiang University Science A
VL - 24
IS - 1
SP - 37
EP - 55
%@ 1673-565X
Y1 - 2023
PB - Zhejiang University Press & Springer
ER -
DOI - 10.1631/jzus.A2200142


Abstract: 
As a promising enhanced gas recovery technique, CO2 huff-n-puff has attracted great attention recently. However, hydraulic fracture deformation hysteresis is rarely considered, and its effect on CO2 huff-n-puff performance is not well understood. In this study, we present a fully coupled multi-component flow and geomechanics model for simulating CO2 huff-n-puff in shale gas reservoirs considering hydraulic fracture deformation hysteresis. Specifically, a shale gas reservoir after hydraulic fracturing is modeled using an efficient hybrid model incorporating an embedded discrete fracture model (EDFM), multiple porosity model, and single porosity model. In flow equations, Fick’s law, extended Langmuir isotherms, and the Peng-Robinson equation of state are used to describe the molecular diffusion, multi-component adsorption, and gas properties, respectively. In relation to geomechanics, a path-dependent constitutive law is applied for the hydraulic fracture deformation hysteresis. The finite volume method (FVM) and the stabilized extended finite element method (XFEM) are applied to discretize the flow and geomechanics equations, respectively. We then solve the coupled model using the fixed-stress split iterative method. Finally, we verify the presented method using several numerical examples, and apply it to investigate the effect of hydraulic fracture deformation hysteresis on CO2 huff-n-puff performance in a 3D shale gas reservoir. Numerical results show that hydraulic fracture deformation hysteresis has some negative effects on CO2 huff-n-puff performance. The effects are sensitive to the initial conductivity of hydraulic fracture, production pressure, starting time of huff-n-puff, injection pressure, and huff-n-puff cycle number.

水力裂缝变形滞后对页岩气藏CO2吞吐的影响研究

作者:严侠1,刘丕养2,黄朝琴1,孙海1,张凯1,2,王俊锋3,姚军1
机构:1中国石油大学(华东),石油工程学院,中国青岛,266580;2青岛理工大学,土木工程学院,中国青岛,266520;3中国石油川庆钻探工程有限公司,川东钻探公司,中国重庆,40112
目的:在页岩气藏CO2吞吐过程中,水力裂缝处于循环载荷作用下时,极易发生不可逆变形(变形滞后),影响吞吐效果。本文旨在建立考虑水力裂缝变形滞后的页岩气藏CO2吞吐流固耦合模型,形成相应的高效求解方法,并开展流固耦合数值模拟研究,以揭示变形滞后对CO2吞吐的影响规律。
创新点:1.建立考虑水力裂缝变形滞后、复杂裂缝系统和特殊流动机理的页岩气藏多组分流固耦合模型,并形成相应的三维高效数值模拟技术;2.揭示水力裂缝变形滞后对页岩气藏CO2吞吐的影响规律。
方法:1.建立考虑水力裂缝变形滞后、复杂裂缝系统和特殊流动机理的页岩气藏多组分流固耦合模型;2.基于结构化网格构造高效稳定的多组分流固耦合模型数值求解算法;3.通过流固耦合数值模拟,揭示水力裂缝变形滞后对页岩气藏CO2吞吐的影响规律。
结论:1.水力裂缝变形滞后会阻碍CO2注入期间裂缝渗透率的恢复,对CO2吞吐有负面影响;2.较低的初始水力裂缝导流能力和生产压力、较晚的吞吐启动时间、较高的注入压力和较多的循环次数均会增强变形滞后的负面影响;3.CO2吞吐效果与初始水力裂缝导流能力、吞吐启动时间、注入压力和循环次数呈正相关,与生产压力呈负相关。

关键词:提高气体采收率;二氧化碳吞吐;流固耦合;水力裂缝变形滞后;嵌入式离散裂缝模型

Darkslateblue:Affiliate; Royal Blue:Author; Turquoise:Article

Reference

[1](Computer Modelling Group)CMG, 2015. GEM User’s Guide. Computer Modelling Group, Calgary, Canada.

[2]COMSOL, 1998. Introduction to COMSOL Multiphysics®. COMSOL, Burlington, USA.

[3]DuFS, NojabaeiB, 2019. A review of gas injection in shale reservoirs: enhanced oil/gas recovery approaches and greenhouse gas control. Energies, 12(12):2355.

[4]FanWP, SunH, YaoJ, et al., 2019. An upscaled transport model for shale gas considering multiple mechanisms and heterogeneity based on homogenization theory. Journal of Petroleum Science and Engineering, 183:106392.

[5]FathiE, AkkutluIY, 2014. Multi-component gas transport and adsorption effects during CO2 injection and enhanced shale gas recovery. International Journal of Coal Geology, 123:52-61.

[6]GalaD, SharmaM, 2018. Compositional and geomechanical effects in huff-n-puff gas injection IOR in tight oil reservoirs. SPE Annual Technical Conference and Exhibition, p.1-24.

[7]GaripovTT, Karimi-FardM, TchelepiHA, 2016. Discrete fracture model for coupled flow and geomechanics. Computational Geosciences, 20(1):149-160.

[8]GhanizadehA, ClarksonCR, DeglintH, et al., 2016. Unpropped/propped fracture permeability and proppant embedment evaluation: a rigorous core-analysis/imaging methodology. Proceedings of the SPE/AAPG/SEG Unconventional Resources Technology Conference, p.1824-1852.

[9]GigerF, ReissL, JourdanA, 1984. The reservoir engineering aspects of horizontal drilling. SPE Annual Technical Conference and Exhibition, p.1-8.

[10]GodecM, KopernaG, PetrusakR, et al., 2014. Enhanced gas recovery and CO2 storage in gas shales: a summary review of its status and potential. Energy Procedia, 63:5849-5857.

[11]HasanM, EliebidM, MahmoudM, et al., 2017. Enhanced gas recovery (EGR) methods and production enhancement techniques for shale & tight gas reservoirs. SPE Kingdom of Saudi Arabia Annual Technical Symposium and Exhibition, p.1-9.

[12]HuangJW, JinTY, BarrufetM, et al., 2020. Evaluation of CO2 injection into shale gas reservoirs considering dispersed distribution of kerogen. Applied Energy, 260:114285.

[13]HubbertM, WillisDG, 1957. Mechanics of hydraulic fracturing. Transactions of the AIME, 210(1):153-168.

[14]IEA (International Energy Agency), 2021. Levelised Cost of CO2 Capture by Sector and Initial CO2 Concentration, 2019. IEA, Paris, France. https://www.iea.org/data-and-statistics/charts/levelised-cost-of-co2-capture-by-sector-and-initial-co2-concentration-2019

[15]IEA (International Energy Agency), 2022. Natural Gas Prices in Europe, Asia and the United States, Jan 2020-February 2022. IEA, Paris, France. https://www.iea.org/data-and-statistics/charts/natural-gas-prices-in-europe-asia-and-the-united-states-jan-2020-february-2022

[16]JaegerJC, CookNGW, ZimmermanRW, 2007. Fundamentals of Rock Mechanics, 4th Edition. Blackwell Publishing, Oxford, UK, p.189-194.

[17]JiangJM, YangJ, 2018. Coupled fluid flow and geomechanics modeling of stress-sensitive production behavior in fractured shale gas reservoirs. International Journal of Rock Mechanics and Mining Sciences, 101:1-12.

[18]JiangJM, ShaoYY, YounisRM, 2014. Development of a multi-continuum multi-component model for enhanced gas recovery and CO2 storage in fractured shale gas reservoirs. SPE Improved Oil Recovery Symposium, p.1-17.

[19]KarlssonH, JacquesGE, HattenJL, et al., 1991. Method and Apparatus for Horizontal Drilling. US Patent 5074366.

[20]KhoeiAR, 2014. Extended Finite Element Method: Theory and Applications. John Wiley & Sons, Chichester, UK.

[21]KimJ, MoridisGJ, 2014. Gas flow tightly coupled to elastoplastic geomechanics for tight-and shale-gas reservoirs: material failure and enhanced permeability. SPE Journal, 19(6):1110-1125.

[22]KimJ, SonnenthalEL, RutqvistJ, 2012. Formulation and sequential numerical algorithms of coupled fluid/heat flow and geomechanics for multiple porosity materials. International Journal for Numerical Methods in Engineering, 92(5):425-456.

[23]KimTH, ChoJ, LeeKS, 2017. Evaluation of CO2 injection in shale gas reservoirs with multi-component transport and geomechanical effects. Applied Energy, 190:1195-1206.

[24]LiHL, LuYY, ZhouL, et al., 2017. A new constitutive model for calculating the loading-path dependent proppant deformation and damage analysis of fracture conductivity. Journal of Natural Gas Science and Engineering, 46:365-374.

[25]LiZY, ElsworthD, 2019. Controls of CO2–N2 gas flood ratios on enhanced shale gas recovery and ultimate CO2 sequestration. Journal of Petroleum Science and Engineering, 179:1037-1045.

[26]LiuFS, BorjaRI, 2010. Stabilized low-order finite elements for frictional contact with the extended finite element method. Computer Methods in Applied Mechanics and Engineering, 199(37-40):2456-2471.

[27]LiuJ, WangJG, GaoF, et al., 2019. A fully coupled fracture equivalent continuum-dual porosity model for hydro-mechanical process in fractured shale gas reservoirs. Computers and Geotechnics, 106:143-160.

[28]LiuJS, ChenZW, ElsworthD, et al., 2011. Interactions of multiple processes during CBM extraction: a critical review. International Journal of Coal Geology, 87(3-4):175-189.

[29]LiuLJ, YaoJ, SunH, et al., 2019. Compositional modeling of shale condensate gas flow with multiple transport mechanisms. Journal of Petroleum Science and Engineering, 172:1186-1201.

[30]LiuLJ, LiuYZ, YaoJ, et al., 2020a. Efficient coupled multiphase-flow and geomechanics modeling of well performance and stress evolution in shale-gas reservoirs considering dynamic fracture properties. SPE Journal, 25(3):‍1523-1542.

[31]LiuLJ, LiuYZ, YaoJ, et al., 2020b. Mechanistic study of cyclic water injection to enhance oil recovery in tight reservoirs with fracture deformation hysteresis. Fuel, 271:117677.

[32]LohrenzJ, BrayBG, ClarkCR, 1964. Calculating viscosities of reservoir fluids from their compositions. Journal of Petroleum Technology, 16(10):1171-1176.

[33]MahmoodpourS, SinghM, TuranA, et al., 2022a. Simulations and global sensitivity analysis of the thermo-hydraulic-mechanical processes in a fractured geothermal reservoir. Energy, 247:123511.

[34]MahmoodpourS, SinghM, BärK, et al., 2022b. Thermo-hydro-mechanical modeling of an enhanced geothermal system in a fractured reservoir using carbon dioxide as heat transmission fluid-a sensitivity investigation. Energy, 254:124266.

[35]MoinfarA, VaraveiA, SepehrnooriK, et al., 2012. Development of a novel and computationally-efficient discrete-fracture model to study IOR processes in naturally fractured reservoirs. SPE Improved Oil Recovery Symposium, p.1-17.

[36]NorbeckJH, McClureMW, LoJW, et al., 2016. An embedded fracture modeling framework for simulation of hydraulic fracturing and shear stimulation. Computational Geosciences, 20(1):1-18.

[37]PruessK, 1991. TOUGH2: a General-Purpose Numerical Simulator for Multiphase Fluid and Heat Flow. LBL-29400, Lawrence Berkeley Lab, Berkeley, USA.

[38]QiuYL, WuCJ, ChenWF, 2020. Local heat transfer enhancement induced by a piezoelectric fan in a channel with axial flow. Journal of Zhejiang University-SCIENCE A (Applied Physics & Engineering), 21(12):1008-1022.

[39]RenG, JiangJ, YounisRM, 2016. Fully coupled geomechanics and reservoir simulation for naturally and hydraulically fractured reservoirs. The 50th U.S. Rock Mechanics/Geomechanics Symposium, p.1-12.

[40]RyderRT, 1996. Fracture Patterns and Their Origin in the Upper Devonian Antrim Shale Gas Reservoir of the Michigan Basin: a Review. Open-File Report 96-23, U.S. Geological Survey, Reston, USA.

[41]ShahM, ShahS, SircarA, 2017. A comprehensive overview on recent developments in refracturing technique for shale gas reservoirs. Journal of Natural Gas Science and Engineering, 46:350-364.

[42]SongWH, YaoJ, LiY, et al., 2016. Apparent gas permeability in an organic-rich shale reservoir. Fuel, 181:973-984.

[43]StrioloA, ColeDR, 2017. Understanding shale gas: recent progress and remaining challenges. Energy & Fuels, 31(10):10300-10310.

[44]SunH, YaoJ, CaoYC, et al., 2017. Characterization of gas transport behaviors in shale gas and tight gas reservoirs by digital rock analysis. International Journal of Heat and Mass Transfer, 104:227-239.

[45]UrbanE, OrozcoD, FragosoA, et al., 2016. Refracturing vs. infill drilling–a cost effective approach to enhancing recovery in shale reservoirs. SPE/AAPG/SEG Unconventional Resources Technology Conference, p.2934-2953.

[46]VermylenJP, 2011. Geomechanical Studies of the Barnett Shale, Texas, USA. PhD Thesis, Stanford University, California, USA.

[47]VersteegHK, MalalasekeraW, 1995. An Introduction to Computational Fluid Dynamics: the Finite Volume Method. Longman Scientific & Technical, New York, USA.

[48]WangDY, YaoJ, ChenZX, et al., 2019. Image-based core-scale real gas apparent permeability from pore-scale experimental data in shale reservoirs. Fuel, 254:115596.

[49]WebbSW, PruessK, 2003. The use of Fick’s law for modeling trace gas diffusion in porous media. Transport in Porous Media, 51(3):327-341.

[50]WuYS, LiJF, DingDY, et al., 2014. A generalized framework model for the simulation of gas production in unconventional gas reservoirs. SPE Journal, 19(5):845-857.

[51]XuRN, ZengKC, ZhangCW, et al., 2017. Assessing the feasibility and CO2 storage capacity of CO2 enhanced shale gas recovery using triple-porosity reservoir model. Applied Thermal Engineering, 115:1306-1314.

[52]YanX, HuangZQ, YaoJ, et al., 2016. An efficient embedded discrete fracture model based on mimetic finite difference method. Journal of Petroleum Science and Engineering, 145:11-21.

[53]YanX, HuangZQ, YaoJ, et al., 2018a. An efficient hydro-mechanical model for coupled multi-porosity and discrete fracture porous media. Computational Mechanics, 62(5):943-962.

[54]YanX, HuangZQ, YaoJ, et al., 2018b. An efficient numerical hybrid model for multiphase flow in deformable fractured-shale reservoirs. SPE Journal, 23(4):‍1412-1437.

[55]YanX, HuangZQ, ZhangQ, et al., 2020. Numerical investigation of the effect of partially propped fracture closure on gas production in fractured shale reservoirs. Energies, 13(20):5339.

[56]YeX, TonmukayakulP, WeaverJD, et al., 2012. Experiment and simulation study of proppant pack compression. SPE International Symposium and Exhibition on Formation Damage Control, p.1-12.

[57]YuW, SepehrnooriK, 2014. Simulation of gas desorption and geomechanics effects for unconventional gas reservoirs. Fuel, 116:455-464.

[58]ZengQD, YaoJ, ShaoJF, 2018. Numerical study of hydraulic fracture propagation accounting for rock anisotropy. Journal of Petroleum Science and Engineering, 160:422-432.

[59]ZengQD, YaoJ, ShaoJF, 2019. Study of hydraulic fracturing in an anisotropic poroelastic medium via a hybrid EDFM-XFEM approach. Computers and Geotechnics, 105:51-68.

[60]ZhangQ, BorjaRI, 2021. Poroelastic coefficients for anisotropic single and double porosity media. Acta Geotechnica, 16(10):3013-3025.

[61]ZhangQ, YanX, ShaoJL, 2021. Fluid flow through anisotropic and deformable double porosity media with ultra-low matrix permeability: a continuum framework. Journal of Petroleum Science and Engineering, 200:108349.

[62]ZhangQ, YanX, LiZH, 2022. A mathematical framework for multiphase poromechanics in multiple porosity media. Computers and Geotechnics, 146:104728.

[63]ZhuGP, KouJS, YaoBW, et al., 2019. Thermodynamically consistent modelling of two-phase flows with moving contact line and soluble surfactants. Journal of Fluid Mechanics, 879:327-359.

[64]ZienkiewiczOC, TaylorRL, 2000. The Finite Element Method: Solid Mechanics. Butterworth-Heinemann, Oxford, UK.

[65]ZuloagaP, YuW, MiaoJJ, et al., 2017. Performance evaluation of CO2 huff-n-puff and continuous CO2 injection in tight oil reservoirs. Energy, 134:181-192.

Open peer comments: Debate/Discuss/Question/Opinion

<1>

Please provide your name, email address and a comment





Journal of Zhejiang University-SCIENCE, 38 Zheda Road, Hangzhou 310027, China
Tel: +86-571-87952783; E-mail: cjzhang@zju.edu.cn
Copyright © 2000 - 2024 Journal of Zhejiang University-SCIENCE