화학공학소재연구정보센터
로그인 로그아웃 연락처 사이트맵
Journal of Industrial and Engineering Chemistry, Vol.18, No.6, 2051-2058, November, 2012
DOI10.1016/j.jiec.2012.05.026  Export Citation
Steam chamber evolution during SAGD and ES-SAGD in thin layer oil sand reservoirs using a 2-D scaled model
Nansuk You, Songhun Yoon, and Chul Wee Lee
  • Division of Green Chemistry and Engineering Research, KRICT, Daejeon 305-600, Republic of Korea
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Bitumen recovery from thin oil sand reservoirs was modeled on a 150:1 scale, two-dimensional apparatus based on the theory of steam assisted gravity drainage. Injections of only steam and of steam and organic solvent were compared at high temperature (180 ℃) and high pressure (686-882 kPa). Oil sand was simulated using homogeneously mixed extra heavy oil (<10 mPa s at 200 ℃) and glass beads (diameter 1.5 mm) to achieve a porosity of 0.3. Steam temperatures, pressures, flow rates, and the evolution of steam chambers were monitored during the extractions. Recovery factor and steam chamber growth rate were compared. Extraction using steam with 3.0-7.4 vol% hexane improved the bitumen recovery factor by at least 30%. The added solvent resulted in the steam chamber reaching its greatest area 1200 s sooner than when using steam alone, equivalent to 0.9 year in the field. The extra heavy oil was analyzed by HPLC before and after extraction and the relative compositions of SARA were compared. The oil’s asphaltene content was reduced from 17.6 wt% to 10.8 wt% and to 9.7 wt% by extraction without and with the added solvent, respectively. Amounts of aromatics and resin were increased by both extraction methods.
Keywords:Oil sand;Thin layer reservoir;ES-SAGD;Hexane;Steam chamber growth
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