Simultaneous HPAM/SDS Injection in Heterogeneous/Layered Models

Although lots of experiments have been done in enhanced oil recovery, the number of experiments which consider the effects of local and global heterogeneity on efficiency of enhanced oil recovery based on the polymer-surfactant flooding is low and rarely done. In this research, we have done numerous experiments of water flooding and polymer-surfactant flooding on a five spot glass micromodel in different conditions such as different positions of layers. In these experiments, five different micromodels with three different pore structures are designed. Three models with different layer orientation, one homogenous model and one heterogeneous model are designed. In order to import the effect of heterogeneity of porous media, three types of pore structures are distributed accidentally and with equal ratio throughout heterogeneous micromodel network according to random normal distribution. The results show that maximum EOR recovery factor will happen in a situation where the layers are orthogonal to the path of mainstream and the minimum EOR recovery factor will happen in a situation where the model is heterogeneous. This experiments show that in polymer-surfactant flooding, with increase of angles of layers the EOR recovery factor will increase and this recovery factor is strongly affected by local heterogeneity around the injection zone.





References:
[1] Dosher, T.M., Wise, F.A., 1976. Enhanced oil recovery potential. An
estimate. Paper SPE 5800. Journal of Petroleum Technology 575.
[2] Mohanty, K.K., Davis, H.T. & Scriven, L.E. 1987. Physics of Oil
Entrapment in Water-Wet Rock. SPE Res. Eng., 2: 113-128. SPE 9406-
PA. doi: 10.2118/9406-PA.
[3] Hallam R.J., Plekenbrock E.J., Abou-Sayed A.S., Garon A.M., Putnam
T.W., Weggeland M.C., Webb K.J. 1992. Resource Description and
Development Potential of the Ugnu Reservoir, North Slope, Alaska. SPE
Form Eval, 7 (3): 211-218. SPE-21779-PA. doi: 10.2118/21779-PA.
[4] Thomas S., Farouq Ali S.M. 2001. Miceller Flooding and ASP-Chemical
Methods for Enhanced Oil Recovery. J.Cdn.Pet.Tech, 40 (2).
[5] Martin, F.D. and Oxley, J.C. 1985. Effect of Various Alkaline Chemicals
on Phase Behavior of Surfactant/Brine/Oil Mixtures. Paper SPE 13575 presented at the International Symposium on Oilfield and Geothermal
Chemistry, Phoenix, AZ, USA, 9-11 April. doi: 10.2118/13575-MS.
[6] Rekvig, L., Kranenberg, M., Hafskjold, B., Smit, B. 2003. Effect of
Surfactant Structure on Interfacial Properties. Euro physics Letters, 63
(6) 902-907.
[7] Nelson, R.C., Lawson, J.B., Thigpen, D.R., Stegemeier, G.L. 1984.
Cosurfactant-Enhanced Alkaline Flooding. Paper SPE 12672 presented
at the SPE Enhanced Oil Recovery Symposium, Tulsa, Oklahoma, 15-18
April. doi: 10.2118/12672-MS.
[8] Van Poollen, H.K. (1980). Fundamentals of Enhanced Oil Recovery.
PennWell Books, Tulsa, Oklahoma.
[9] Emami Meybodi, H., Kharrat, R., Ghazanfari, m. H., Effect of
Heterogeneity of Layered Reservoirs on Polymer Flooding: An
Experimental Approach Using Five-Spot Glass Micromodel, SPE
Europec/EAGE Annual Conference and Exhibition, Rome, Italy, 9–12
June 2008.
[10] Sedaghat, M.H., Ghazanfari, M.H., Parvazdavani, M., Morshedi, S..
Experimental Investigation of Polymer Flooding in Fractures Heavy Oil
Five Spot Systems, Journal of Energy Resources Technology.