Particle transport during asymmetric net-zero cyclic fluid flow: Flow in tubes and radial flow in fractures

被引:2
|
作者
Hafez, Ahmed [1 ,2 ]
Santamarina, J. Carlos [3 ]
机构
[1] KAUST, Earth Sci & Engn, Thuwal 239556900, Saudi Arabia
[2] Univ Sheffield, Dept Automatic Control & Syst Engn, Sheffield, England
[3] Georgia Inst Technol, Atlanta, GA USA
来源
POWDER TECHNOLOGY | 2024年 / 434卷
关键词
Particle-laden fluid flow; Cyclic fluid flow; Fines migration; Proppants; SOLUTE TRANSPORT; MODEL; EPIDEMIOLOGY; DEPOSITION; SPHERES; MOTION; SHALE; DRAG; SAND;
D O I
10.1016/j.powtec.2023.119306
中图分类号
TQ [化学工业];
学科分类号
0817 ;
摘要
Cyclic fluid flow enhances transport in porous media. We study particle transport during asymmetric net-zero cyclic fluid flow where the fluid injection rate is higher than the withdrawal rate. Inside a tube, the threshold fluid velocity required to mobilize a particle depends on the relative particle size: larger particles obstruct flow more effectively than small particles and require a smaller velocity to be transported. Then, flow rates can be selected so particles move forward during the injection phase and remain stationary during withdrawal. Similarly, asymmetric cyclic fluid flow transports particles radially along fractures despite the net-zero fluid flow. The flow velocity decreases away from the injection point and particles migrate to a characteristic "terminal radial distance". Unlike tube flow, a grain has a diminishing obstructing effect on the radial flow field, and the threshold flow rate required to mobilize grains increases with increasing particle size during radial flow.
引用
收藏
页数:9
相关论文
共 50 条
  • [41] FLUID TRANSPORT BY HIGH-FREQUENCY ASYMMETRIC OSCILLATORY AIR-FLOW
    GRUENAUER, LM
    GROTBERG, JB
    MILLER, IF
    YEATES, DB
    AMERICAN REVIEW OF RESPIRATORY DISEASE, 1986, 133 (04): : A74 - A74
  • [42] SIMULATION OF MIXING DURING NONSTEADY STATE PARTICLE FLOW IN STATIC MIXER TUBES
    GYENIS, J
    BLICKLE, T
    ACTA CHIMICA HUNGARICA-MODELS IN CHEMISTRY, 1992, 129 (05): : 647 - 659
  • [43] RADIAL-DISTRIBUTION OF WHITE CELLS DURING BLOOD-FLOW IN SMALL TUBES
    NOBIS, U
    PRIES, AR
    COKELET, GR
    GAEHTGENS, P
    MICROVASCULAR RESEARCH, 1985, 29 (03) : 295 - 304
  • [44] Mathematical Model of Fluid Flow and Solute Transport in Converging-diverging Permeable Tubes
    Varunkumar, M.
    Muthu, P.
    Srinivas, S.
    JOURNAL OF APPLIED AND COMPUTATIONAL MECHANICS, 2023, 9 (04): : 900 - 914
  • [45] X-ray Insights into Fluid Flow During Rock Failures: Nonlinear Modeling of Fluid Flow Through Fractures with Varied Roughness
    Sun, Huan
    Long, Qijian
    Ye, Zhenni
    Liu, Hao
    Meng, Zimin
    GEOTECHNICAL AND GEOLOGICAL ENGINEERING, 2024, 42 (05) : 4049 - 4067
  • [46] MEASUREMENTS OF GAS-TRANSPORT IN A BRANCHING NETWORK OF TUBES DURING OSCILLATORY FLOW
    COLLINS, J
    KAMM, RD
    SHAPIRO, AH
    DRAZEN, JM
    SLUTSKY, AS
    FEDERATION PROCEEDINGS, 1982, 41 (05) : 1746 - 1746
  • [47] NUMERICAL MODELING OF FLUID-FLOW AND PARTICLE-TRANSPORT IN CLEAN ROOMS
    BUSNAINA, AA
    ABUZEID, S
    SHARIF, MAR
    9TH INTERNATIONAL SYMPOSIUM ON CONTAMINATION CONTROL : EXPLORING WORLD PARTNERSHIPS IN TECHNOLOGY, 1988, : 600 - 607
  • [48] Analysis of fluid flow and particle transport in evaporating droplets exposed to infrared heating
    Thokchom, Ashish Kumar
    Gupta, Abhishek
    Jaijus, Pallippadan Johny
    Singh, Anugrah
    INTERNATIONAL JOURNAL OF HEAT AND MASS TRANSFER, 2014, 68 : 67 - 77
  • [49] An improved hydromechanical model for particle flow simulation of fractures in fluid-saturated rocks
    Zhang, Yulong
    Shao, Jianfu
    Liu, Zaobao
    Shi, Chong
    INTERNATIONAL JOURNAL OF ROCK MECHANICS AND MINING SCIENCES, 2021, 147
  • [50] CFD model of fluid flow and particle deposition during cryogenic condensation
    Hendry, James R.
    Lee, Jonathan G. M.
    Battrum, Michael J.
    CHEMICAL ENGINEERING RESEARCH & DESIGN, 2019, 143 : 201 - 214
12345