As the water drive reservoir enters extra high water cut stage (greater than 80%), remaining oil distribution becomes increasingly dispersed. Research on micro residual oil in pore appears particularly important for reservoir development at extra high water cut stage. Oil occurrence characteristics recognition helps to understand the distribution of remaining oil and the mechanical characteristics of oil is the guide for tapping the remaining oil. On the basis of pore scale oil-water two phase flow experiments, micro distribution of remaining oil is divided into four occurrence states in accordance with oil features at different stage of water flooding, the flake of remaining oil, oil column, oil droplet and oil film. A quantitative characterization method of remaining oil occurrence states is established. By using micro numerical simulation method, change rules of four occurrence states of remaining oil during the process of water displacement and the mechanical characteristics of different occurrence state of remaining oil are analyzed. Results show that the continuous oil phase gradually transforms to discontinuous phase and even to dispersed phases during the water flooding process. At extra high water cut stage, most of remaining oil are dispersed oil columns, oil droplets and oil films, which are the main target of remaining oil to be tapped. By changing water flow direction or increasing the displacement pressure gradient, the surface adsorption force acting on oil columns are overcome, and then the oil columns begin to move and finally to be produced out. Oil droplets in pore-throat center are scoured and carried out by water as the increase of the injection volume, while the oil droplets in blind ends and the oil films are extracted out by adding chemicals to reduce the interfacial tension, so as to enhance oil recovery. For water flooding reservoir, the corresponding tapping measures for four types of oil occurrence states brought forward have great meanings of improving reservoir recovery at high water cut stage.
Acknowledgments
This research was Supported by SINOPEC Major Projects, (J08).
| [1] |
Gongjian Guo, Changchun Gu, Experimental study of active pore distribution during water driving by using NMR, J. Xian Shiyou Univ. Sci. Ed. 20 (5) (2005) 45-48.
|
| [2] |
Haohan Liu, Study on Remaining Oil Droplet Dynamic Conditions and Water Flood Efficiency Changing Mechanisms in the Ultra-high Water Cut Period, Southwest Petroleum University, 2013.
|
| [3] |
Xiongzhi Liu, Zhaoping Yang, Xuezhi Hui, et al., Force analysis of the remained oil in the small pores and improvement of the mathematical model, Pet. Geol. Oilfield Dev. Daqing 33 (2) (2014) 77-82.
|
| [4] |
Chunsheng Wang, Shuren Yang, Lili Liu, Micro force calculation of residual oil displacement of viscoelastic fluid, J. Xian Shiyou Univ. Nat. Sci. Ed. 33 (4) (2011) 135-138.
|
| [5] |
M. Blunt, Effects of heterogeneity and wetting on relative permeability using pore level modeling, Soc. Pet. Eng. J. (2) (1997) 70-87.
|
| [6] |
M. Blunt, Pore level modeling of the effects of wettability, Soc. Pet. Eng. J. (2) (1997) 494-510.
|
| [7] |
R.G. Hughes, M.J. Blunt, Pore scale modelling of rate effects in imbibition, Transp. Porous Media (40) (2000) 295-322.
|
| [8] |
M. Piri, M.J. Blunt, Pore-scale modeling of three-phase flow in mixed-wet systems, in: Proceedings of the SPE Annual Meeting, SPE 77726, San Antonio, Texas, 2002.
|
| [9] |
P. Mostaghimi, B. Bijeljic, M.J. Blunt, Simulation of flow and dispersion on pore-space images, Soc. Pet. Eng. J. (40) (2012) 1131-1141.
|
| [10] |
Jianjun Liu, Rui Song, Mengmeng Cui, Improvement of predictions of petrophysical transport behavior using three-dimensional finite volume element model with micro-CT images, J. Hydrodyn. 27 (2) (2015) 234-241.
|
| [11] |
Yuan Shao, Visual microcosmic physical displacement model, Nei Jiang Technol. 10 (2010) 124.
|
| [12] |
Shunkang Zhang, The Microscopic Experiments and Modeling for Residual Oil Distribution after Water Flooding, China University of Petroleum, Huang Dao, 2007.
|
| [13] |
Qingxi Hu, Jun Guo, Yuan Yao, Bionic bone scaffold design method based on pore network Model, China Patent, CN102087676A. 2011.
|
| [14] |
Shaokai Li, Huimin Xu, AD 200 two seater light aircraft aerodynamic characteristics research, Jiangsu Aviat. 4 (2012) 17-19.
|
| [15] |
Xiaodong Zhao, Hailong Wang, Yongming Shen, Optimization on 2D unstructured mesh generation based on GIS, Geogr. Geo Inf. Sci. 26 (2010) 46-48.
|
| [16] |
Hongxia Sun, New views on water displacement curves rising at high water cut stage, Special Oil Gas Reserv. 23 (1) (2016) 92-95.
|
| [17] |
Xudong Huang, VOF method based on un-structured quadrilateral mesh, Ocean. Technol. 27 (2008) 57-61.
|
| [18] |
Meng Jiang, Residual Oil Microscopic Distribution Physical Simulation for Waterflooding Reservoir Research, Chengdu University of Technology, Cheng Du, 2007.
|
| [19] |
Guoliang Yan, Jianmeng Sun, Xuefeng Liu, et al., Characterization of microscopic pore structure of reservoir rock and its effect on permeability, Well Logging Technol. 38 (1) (2014) 28-32.
|
| [20] |
Heming Wang, The Study on Fractal Characteristics and Net-work Model of Pore C Structure of Porous Media, Dalian University of Technology, 2013.
|
PDF
