Open Access
Oil & Gas Science and Technology - Rev. IFP
Volume 55, Numéro 1, January-February 2000
Page(s) 35 - 66
Publié en ligne 1 novembre 2006
  • Agar, J.,Morgenstern, N. et Scott, J. (1987) Shear Strength and Stress-Strain Behaviour of Athabasca Oil Sand at Elevated Temperatures and Pressures. Can. Geotech. J., 24, 1-10. [CrossRef] [Google Scholar]
  • Betata, S. (1998) Les écoulements polyphasiques aux abords des puits dans les gisements d’hydrocarbures. Thèse, université Paris VI. [Google Scholar]
  • Bora, R., Maini, B. et Chakma, A. (1997) Flow Visualization Studies of Solution Gas Drive Process in Heavy Oil Reservoirs Using a Glass Micromodel. SPE 37519. [Google Scholar]
  • Cerasi, P. (1996) Étude de la croissance d’une instabilité d’érosion dans un milieu poreux non consolidé. Application à l’angiogenèse. Thèse, Paris VII. [Google Scholar]
  • Claridge, E. et Prats, M. (1995) A Proposed Model and Mechanism for Anomalous Foamy Heavy Oil Behavior. SPE 29243. [Google Scholar]
  • Coombe, D. et Maini, B. (1994) Workshop on Foamy Oil Flow Held at the Petroleum Recovery Institute. [Google Scholar]
  • Dusseault, M. et Morgenstern, N. (1978) Shear Strength of Athabasca Oil Sands. Can. Geotech. J., 15, 216-238. [CrossRef] [Google Scholar]
  • Dusseault, M. et Van Domselaar, H. (1982) Unconsolidated Sand Sampling in Canadian and Venezuelan Oil Sands. 2nd Unitar Conf. [Google Scholar]
  • Dusseault, M. (1993) Cold Production and Enhanced Oil Recovery. JCPT, 32, 9. [CrossRef] [Google Scholar]
  • Dusseault, M., Geilikman, M. et Roggensack, W. (1995) Practical Requirements for Sand Production Implementation in Heavy Oil. SPE 30250. [Google Scholar]
  • Dusseault, M., Geilickman, M. et Spanos, T. (1998a) Mechanisms of Sand Production. SPE 27343. [Google Scholar]
  • Dusseault, M. (1998b) Canadian Heavy Oil Production Experience Using Cold Production. Trinidad and Tobago SPE Conf. [Google Scholar]
  • Elkins, L., Morton, D. et Blackwell, W. (1972) Experimental Fireflood in a Very Viscous Oil-Consolidated Sand Reservoir. SPE 4086. [Google Scholar]
  • Firoozabadi, A. Pooladi-Darvish, M. et Eleri, V. (1997a) Gas and Liquid Mobilities in Cold Production of Heavy Oil Reservoirs. SPE 38873. [Google Scholar]
  • Firoozabadi et al. (1997b) Solution Gas Drive in Heavy Oil Reservoirs. CIM 97-113. [Google Scholar]
  • Geilikman, M., Dusseault, M. et Dullien, F. (1994a) Fluid Production Enhancement by Exploiting Sand Production. SPE/DOE 27797. [Google Scholar]
  • Geilikman, M., Dusseault, M. et Dullien, F. (1994b) Sand Production as a Viscoplastic Granular Flow. SPE 27343. [Google Scholar]
  • Geilikman, M., Dusseault, M. et Dullien, F. (1994c) Fluid- Saturated Solid Flow with Propagation of a Yielding Front. Eurock ’94, SPE/ISRM Conf. [Google Scholar]
  • Geilikman, M., Dusseault, M. et Dullien, F. (1994d) Sand Production and Yield Propagation around Wellbores. CIM 94-89. [Google Scholar]
  • Geilikman, M., Dusseault, M. et Dullien, F. (1995a) Dynamic Effects of Foamy Fluid Flow in Sand Production Instability. SPE 30251. [Google Scholar]
  • Geilikman, M., Dusseault, M. et Dullien, F. (1995b) Fluid Rate in Flowing Granular Medium with Moving Boundary. ECMOR Conf. [Google Scholar]
  • Geilikman, M., Dullien, F. et Dusseault, M. (1997a) Erosional Creep of Fluid-Saturated Granular Medium. J. of Eng. Mech. [Google Scholar]
  • Geilikman, M. et Dusseault, M. (1997b) Dynamics of Wormholes and Enhancement of Fluid Production. 48th Annual Technical Meeting of the Petroleum Society in Calgary. [Google Scholar]
  • Gonzalez, R. et Brunings, C. (1996) Influence of Increased Pump Frequency in the Production of the Orinoco Belt Foamy Extra Heavy Crude Oil. ESP Workshop. [Google Scholar]
  • Huang. B., Marcum, B., Chase, M. et Yu, C. (1997) Cold Production of Heavy Oil From Horizontal Wells in the Frog Lake Field. SPE 37545. [Google Scholar]
  • Huerta, M., Otero, C., Rico, A., Jimenez, I., Mirabal, M. de et Rojas, G. (1996) Understanding Foamy Oil Mechanisms for Heavy Oil Reservoirs during Primary Production. SPE 36749. [Google Scholar]
  • Karyampudi, S. (1993) Evaluation of Cyclic Steam Performance and Mechanisms in Mobile Heavy Oil Reservoir at Elk Point Thermal Pilot. CIM 93-48. [Google Scholar]
  • Kashchiev, D. et Firoozabadi, A. (1993) Kinetics of the Initial Stage of Isothermal Gas Phase Formation. J. Chem. Phys., 98, 6, 4690-4699. [CrossRef] [Google Scholar]
  • Kraus, W., McCaffrey, W. et Boyd, G. (1993) Pseudo-Bubble Point Model for Foamy Oils. CIM 93-45. [Google Scholar]
  • Lea, J., Anderson, P. et Anderson, D. (1987) Optimization of Progressive Cavity Pump Systems in the Development of the Clear-Water Heavy Oil Reservoir. CIM 87-38. [Google Scholar]
  • Lebel, J.P. (1994) Performance Implications of Various Reservoir Access Geometries. 11th Annual Heavy Oil & Oil Sands Symposium. [Google Scholar]
  • Loughead, D. et Saltuklaroglu, M. (1992) Lloydminster Heavy Oil Production - Why so Unusual? 9th Heavy Oil Symposium. [Google Scholar]
  • Maini, B.,Sarma, H. et George, A. (1993) Significance of Foam- Oil Behaviour in Primary Production of Heavy Oils. JCPT, 32, 9. [CrossRef] [Google Scholar]
  • Maini, B. et Sarma, H. (1994) Role of Nonpolar Foams in Production of Heavy Oils. Advances in Chem. Series, 242, 405-420. [CrossRef] [Google Scholar]
  • Maini, B. (1995) Laboratory Investigation of Foamy Oil Flow for Improved Primary Production, Canmet. [Google Scholar]
  • Maini, B. (1996) Foamy Oil Flow in Heavy Oil Production. JCPT, 35, 6, 21-24. [CrossRef] [Google Scholar]
  • Metwally, M. et Solanki, S. (1995) Heavy Oil Reservoir Mechanisms, Lindbergh and Frog Lake Fields, Alberta – Part I: Field Observations and Reservoir Simulation. CIM 95-63. [Google Scholar]
  • Metwally, M. (1996) Pressure Cycling Process for Depleted Heavy Oil Reservoirs. CIM 96-68. [Google Scholar]
  • Mirabal, M. de (1996a) Integrated Study for the Characterization and Development of the MFB-53 Reservoir, North Hamaca- Orinoco Belt, Venezuela. SPE 36095. [Google Scholar]
  • Mirabal, M. de (1996b) Impact of Foamy Oil Mechanism on the Hamaca Oil Reserves Orinoco Belt, Venezuela. SPE 36140. [Google Scholar]
  • Mirabal, M. de, Rodriguez, H. et Gordillo, R. (1997) Production Improvement Strategy for Foamy Hamaca Crude Oil: A Field Case. SPE 37544. [Google Scholar]
  • Monnet, A. (1998) Boulance, érosion interne, renard. Les instabilités sous écoulement. Revue Francaise de Géotechnique, 82, 3-10. [CrossRef] [Google Scholar]
  • Moulu, J.C. et Longeron, D. (1989) Solution Gas Drive: Experiments and Simulation. 5th Eur. Symp. on IOR. [Google Scholar]
  • Rodriguez, H., Sliva, R., Zerpa, L., Fung, L. et Camino, M. (1996) Stability Analysis of Horizontal Wells in Orinoco Belt, Venezuela. SPE 36076. [Google Scholar]
  • Rodriguez, H., Vaca, P., Gonzalez, O. et Mirabal, M. de (1997) Integrated Study of a Heavy Oil Reservoir in the Orinoco Belt: a Field Case Simulation. SPE 38015. [Google Scholar]
  • Sarma, H. et Maini, B. (1993) An Experimental Evaluation of Viscosity Grading for Controlling Fingering in Miscible Displacements. JCPT, 32, 1. [CrossRef] [Google Scholar]
  • Shen, C. et Batycky, J. (1996) Some Observations of Mobility Enhancement of Heavy Oils Flowing Through Sand Pack Under Solution Gas Drive. CIM 96-27. [Google Scholar]
  • Sheng, J., Hayes, R., Tortike, W. et Maini, B. (1995a) A Proposed Dynamic Model for Foamy Oil Properties. SPE 30253. [Google Scholar]
  • Sheng, J., Maini. B., Hayes, R. et Tortike, W. (1995b) A Non- Equilibrium Model to Calculate Foamy Oil Properties. CIM 95-19. [Google Scholar]
  • Sheng, J., Hayes, R., Maini, B. et Tortike, W. (1996) A Dynamic Model to Simulate Foamy Oil Flow in Porous Media. SPE 36750. [Google Scholar]
  • Sheng, J.,Hayes, R. et Maini, B. (1997a) Experimental Study of Foamy Oil Stability. JCPT, 36, 4. [CrossRef] [Google Scholar]
  • Sheng, J. (1997b) Foamy Oil Flow in Porous Media. Thèse, universités Edmonton, Alberta. [Google Scholar]
  • Smith, G. (1988) Fluid Flow and Sand Production in Heavy Oil Reservoirs Under Solution Gas Drive. SPEPE, 3, 2, 169-180. [CrossRef] [Google Scholar]
  • Solanki, S. et Metwally, M. (1995) Heavy Oil Reservoir Mechanisms, Lindbergh and Frog Lake Fields, Alberta - Part. II: Geomechanical Evaluation. SPE 30249. [Google Scholar]
  • Squires, A. (1993) Inter-Well Tracer Results and Gel Blocking Program. 10th Annual Heavy Oil & Oil Sands Symposium. [Google Scholar]
  • Treinen, R., Ring, W., Spence, A., Mirabal, M. de et Huerta, M. (1997) Hamaca: Solution Gas Drive Recovery in a Heavy Oil Reservoir, Experimental Results. SPE 39031. [Google Scholar]
  • Tremblay, B., Sedgwick, G. et Forshner, K. (1995) Imaging of Sand Production in Horizontal Packs by X-ray Computer Tomography. 6th Unitar Conf. [Google Scholar]
  • Tremblay, B., Sedgwick, G. et Forshner, K. (1996a) Modelling of Sand Production from Wells on Primary Recovery. CIM 96-26. [Google Scholar]
  • Tremblay, B., Sedgwick, G. et Forshner, K. (1996b) Simulation of Cold Production in Heavy Oil Reservoirs: Wormholes Dynamics. SPE 35387. [Google Scholar]
  • Tremblay, B., Oldakowski, K. et Settari, A. (1997) Geomechanical Properties of Oil Sands at Low Effective Stress. 48th Annual Technical Meeting of the Petroleum Society. [Google Scholar]
  • Tremblay, B., Sedgwick, G. et Vu, D. (1998) CT Imaging of Wormhole Growth under Solution Gas Drive. SPE 39638. [Google Scholar]
  • Tremblay, B., Sedgwick, G., Vu, D., Lillico, D., Jossy, E., Yuan, J.Y., Babchin, A. et Sawatzky, R. (1998a) Cold Production in Heavy Oil Reservoirs. Poster, 15th World Petroleum Congress. [Google Scholar]
  • Tremblay, B., Sedgwick, G. et Vu, D. (1998b) CT Imaging of Sand Production in a Horizontal Sand Pack Using Live Oil. 49th Annual Technical Meeting of the Petroleum Society. [Google Scholar]
  • Vaziri, H., Phillips, R. et Hurley, P. (1997) Physical Modeling of Sand Production. Int. J. Rock Mech. & Min. Sci., 34, 3-4, article 323. [Google Scholar]
  • Wang, Y. et Dusseault, M. (1995) Response of a Circular Opening in a Friable Low-Permeability Medium to Temperature and Pore Pressure Changes. Int. J. Num. Anal. Meth. Geom., 19, 157-179. [CrossRef] [Google Scholar]
  • Wang, Y. et Dusseault, M. (1996a) Sand Production Potential near Inclined, Perforated Wellbores. CIM 96-70. [Google Scholar]
  • Wang, Y. (1996b) The Effect of a Nonlinear Mohr-Coulomb Criteria on the Stresses and Plastic Deformation near a Circular Opening in Poorly Consolidated Permeable Medium. Int. J. Rock Mech. & Min. Eng. Geomec. Abs., 33 (2), 197-203. [CrossRef] [Google Scholar]
  • Xuehai, L. et Yortsos, Y. (1993) Critical Gaz Saturation: Modelling and Sensitivities Studies. SPE 26662. [Google Scholar]
  • Yuan, J., Babchin, A. et Tremblay, B. (1998) Modeling Wormhole Flow in Cold Production. 49th Annual Technical Meeting of the Petroleum Society. [Google Scholar]
  • Yuan, J., Tremblay, B. et Babchin, A. (1999) A Wormhole Network Model of Cold Production in Heavy Oil. SPE 54097. [Google Scholar]
  • Yeung, K. et Adamson, M. (1992) Burnt Lake Project - Bitumen Production from the Cold Lake Oil Sands Deposit Without Steam. CIM 92. [Google Scholar]
  • Yeung, K. (1995) Cold Flow Production of Crude Bitumen at the Burnt Lake Project, Northeastern Alberta. 6th Unitar Conf. [Google Scholar]

Les statistiques affichées correspondent au cumul d'une part des vues des résumés de l'article et d'autre part des vues et téléchargements de l'article plein-texte (PDF, Full-HTML, ePub... selon les formats disponibles) sur la platefome Vision4Press.

Les statistiques sont disponibles avec un délai de 48 à 96 heures et sont mises à jour quotidiennement en semaine.

Le chargement des statistiques peut être long.