Surfactant-polymer flooding technology which used in J oilfield is still the first time in Bohai bay, the reference materials are very seldom for its response characteristic and project optimization. Since there’s no blank water flooding stage between polymer flooding and surfactant-polymer flooding in J oilfield, it’s difficult to accurately judge the response characteristic of production wells and injection wells by the conventional method; on the other side, as surfactant-polymer flooding gradually entered the end stage, the effect of decrease water and increase oil became worse, there’s urgently need to improve the effect of chemical flooding. Thus, the research of response characteristic and mobility optimization are conducted in this article. The water cut funnel method is used for the first time to recognize the response of the production wells in J oilfield, and to use the Hall curve method to recognize the response of the injection wells. Meanwhile, based on the idea of mobility control, the minimum polymer concentration which is needed to control the mobility of surfactant-polymer flooding is studied, and establish the mobility control template, the effect of the surfactant-polymer flooding is improved effectively by use of the template to guide the optimization of the polymer concentration, and daily production increase about 15% of J oilfield. The research can be used to guide and refer to other similar offshore oilfield development.

Song, H. B. (2014). Research of surfactant-polymer flooding response characteristics and influencing factors-case of Gudong Oilfield. Natural Gas Geoscience, 25(S1), 98-106.

Xia, H. F., Huang, Q. J., & Ma, W. G., et al. (2010). The effect of polymer/ betaine surfactant compound system on residual oil after polymer flooding in Daqing oilfield. Oilfield Chemistry, 27(2), 162-165.

Xia, H. F., Jia, Y., & Wang, G. (2010). Study on enhancing the recovery factor of residual oil by polymer/ surfactant compound system after polymer flooding. Journal of Xi’an Shiyou University (Natural Science Edition), 25(1), 45-49.

Wang, R. J., Lu, X. G., & Niu, L. W., et al. (2009). Study on surfactant/ polymer flooding technology for under-productive oil layers in development zone of the north Saertu of Daqing Oilfield. Offshore Oil, 29(3), 57-62.

Zhou, S. W., Han, M., & Zhang, J. (2007). Study on polymer for chemical flooding in offshore oilfield of China. China Offshore Oil & Gas, 19(1), 25-29.

Zhang, X. S., Sun, F. J., & Feng, G. Z. (2007). A research on influence factors of polymer flooding and its field testing in Bohai heavy oil fields. China Offshore Oil & Gas, 19(1), 30-34.

Jiang, H. Q., Liu, R., & Zhang, X. S. (2009). An application of Type C water-drive curve to evaluation of early plymer flooding effects in offshore fields. China Offshore Oil & Gas, 21(6), 383-387.

Zhou, F. J., Zhang, L. F., & Wang, H. J. (2010). Experimental study on relative permeability curve of polymer flooding. Petroleum Geology & Engineering, 24(6), 117-119.

Wang, F., Ren, S., & Dai, C. L. (2005). Study on profile control by water injection wells in offshore oilfields at middle-water-cut stage. Petroleum Drilling Techniques, 33(3), 58-60.

Zhao, F. L., Dai, C. L., & Wang, Y. F. (2006). Water control technique of enhanced oil recovery for offshore oil field. Journal of China University of Petroleum, 30(2), 53-58.

Yang, R. F., & Yang, L. (2012). Study on new forecasting model of water cut in water-flood reservoirs. Chinese Journal of Hydrodynamics, 27(11), 713-718.

Zhao, M., Zhao, W., & Liu, H. C. (2011). Study on the mobility design method for combination flooding. Journal of Southwest Petroleum University (Science & Technology Edition), 33(6), 131-134.

Zhu, W. Y. (1996). A compositional simulator for channeling-control and oil-displacement with cross-linking polymer. Petroleum Exploration & Development, 23(1), 43-46.

Hou, J., Wang, Y. D., & Chen, Y. M. (2002). A streamline method for studying mathematical mode of polymer drive. Journal of Hydrodynamics, 17(3), 343-351.

Shao, Z. B., Chen, G., & Sun, G. (2008). A new mathematical model for polymer flooding. Acta Petrolei Sinica, 29(3), 409-413.