Multidimensional velocity-based model of formation permeability damage

被引:0
|
作者
Mojarad, R.S. [1 ]
Settari, A. [1 ]
机构
[1] U. of Calgary, Calgary, Alta., Canada
来源
JPT, Journal of Petroleum Technology | 2006年 / 58卷 / 03期
关键词
The loss of injectivity in produced-water and seawater injectors results from formation plugging. Reliable modeling of the permeability loss is key to analysis of field data and to the design and economics of projects. Standard formulation of damage mechanics uses the concentration-based; classical deep-bed filtration (DBF) model; which is not easily implemented in reservoir simulators. This alternative damage-modeling approach is based on the formulation proposed by Bachman et al.: Coupled Simulation of Reservoir Flow; Geomechanics; and Formation Plugging With Application to High-Rate Produced-Water Reinjection; paper SPE 79695. The numerical implementation of this empirical; velocity-based damage model (VBDM) is extended to 2D flow and is validated by a comparison with the DBF model. The velocity model provides a remarkably accurate approximation of the more complex concentration model;
D O I
暂无
中图分类号
学科分类号
摘要
Journal article (JA)
引用
收藏
页码:68 / 69
相关论文
共 50 条
  • [21] Model uncertainty of shear wave velocity-based method for liquefaction potential evaluation
    Juang, CH
    Yang, SH
    Yuan, HM
    JOURNAL OF GEOTECHNICAL AND GEOENVIRONMENTAL ENGINEERING, 2005, 131 (10) : 1274 - 1282
  • [22] Modal Velocity-Based Multiaxial Fatigue Damage Evaluation Using Simplified Finite Element Models
    Kersch, Kurthan
    Woschke, Elmar
    JOURNAL OF APPLIED MECHANICS-TRANSACTIONS OF THE ASME, 2020, 87 (11):
  • [23] A Continuous Velocity-Based Friction Model for Dynamics and Control With Physically Meaningful Parameters
    Brown, Peter
    McPhee, John
    JOURNAL OF COMPUTATIONAL AND NONLINEAR DYNAMICS, 2016, 11 (05):
  • [24] A Velocity-Based Dynamic Model and Its Properties for Differential Drive Mobile Robots
    Martins, Felipe N.
    Sarcinelli-Filho, Mario
    Carelli, Ricardo
    JOURNAL OF INTELLIGENT & ROBOTIC SYSTEMS, 2017, 85 (02) : 277 - 292
  • [25] Adaptive Fuzzy Velocity-based Routing for MANET
    Li, Changle
    Zhang, Hanxiao
    Hao, Binbin
    Li, Jiandong
    MEASURING TECHNOLOGY AND MECHATRONICS AUTOMATION IV, PTS 1 AND 2, 2012, 128-129 : 46 - 49
  • [26] Velocity-Based Training-A Critical Review
    Guppy, Stuart N.
    Kendall, Kristina L.
    Haff, G. Gregory
    STRENGTH AND CONDITIONING JOURNAL, 2024, 46 (03) : 295 - 307
  • [27] The Improved Velocity-based Models for Pedestrian Dynamics
    Yang, Xiao
    Qin, Zheng
    Wan, Binhua
    Zhang, Renwei
    Wang, Huihui
    KSII TRANSACTIONS ON INTERNET AND INFORMATION SYSTEMS, 2017, 11 (09): : 4379 - 4397
  • [28] Group Modeling: A Unified Velocity-Based Approach
    Ren, Z.
    Charalambous, P.
    Bruneau, J.
    Peng, Q.
    Pettre, J.
    COMPUTER GRAPHICS FORUM, 2017, 36 (08) : 45 - 56
  • [29] Velocity-Based Training: From Theory to Application
    Weakley, Jonathon
    Mann, Bryan
    Banyard, Harry
    McLaren, Harry Shaun
    Scott, Tannath
    Garcia-Ramos, Amador
    STRENGTH AND CONDITIONING JOURNAL, 2021, 43 (02) : 31 - 49
  • [30] Velocity-Based Training With Weightlifting Derivatives: Barbell and System Velocity Comparisons
    Suchomel, Timothy J.
    Kissick, Cameron R.
    Techmanski, Baylee S.
    Mann, James Bryan
    Comfort, Paul
    JOURNAL OF STRENGTH AND CONDITIONING RESEARCH, 2025, 39 (02) : 135 - 146
12345