Polyacrylamide and its derivatives for oil recovery

200 
14. Evani, S.: Water soluble polymer, surfactant, and salt-used in enhanced oil recovery. 
Google Patents, 1984. 
15. Sydansk, R. D.: Enhanced oil recovery. Google Patents, 1989. 
16. Taylor, K. C.; Nasr-El-Din, H. A.: Water-soluble hydrophobically associating 
polymers for improved oil recovery: A literature review. Journal of Petroleum 
Science and Engineering 1998, 19, 265-280. 
17. Evani, S.: Enhanced oil recovery process using a hydrophobic associative 
composition containing a hydrophilic/hydrophobic polymer. Google Patents, 1989. 
18. Shashkina, Y. A.; Zaroslov, Y. D.; Smirnov, V.; Philippova, O.; Khokhlov, A.; 
Pryakhina, T.; Churochkina, N.: Hydrophobic aggregation in aqueous solutions of 
hydrophobically modified polyacrylamide in the vicinity of overlap concentration. 
Polymer 2003, 44, 2289-2293. 
19. Moffitt, P.: Long-Term Production Results of Polymer Treatments on Producing 
Wells in Western Kansas. Journal of Petroleum Technology 1993, 45, 356-362. 
20. Levitt, D.; Pope, G. A.: Selection and screening of polymers for enhanced-oil 
recovery. In SPE Symposium on Improved Oil Recovery; Society of Petroleum 
Engineers, 2008. 
21. (21)Mortimer, D. A.: Synthetic polyelectrolytes—a review. Polymer International 
1991, 25, 29-41. 
22. (22)Ding, W.; Zhu, H.-q.; Yu, T.: Synthesis of a new type of zwitterionic-comb-like 
polyacrylamide. JOURNAL-DAQING PETROLEUM INSTITUTE 2007, 31, 55. 
23. (23)LUO, J.-H.; PU, R.-Y.; WANG, P.-M.; BAI, F.-L.; ZHANG, Y.; YANG, J.-B.; 
LIU, Y.-Z.: Performance properties of salt tolerant polymer KYPAM for EOR. 
Oilfield Chemistry 2002, 1, 64-67. 
24. (24)Li, H.; Long, J.; Xu, Z.; Masliyah, J. H.: Novel polymer aids for low
‐
grade oil 
sand ore processing. The Canadian Journal of Chemical Engineering 2008, 86, 168-
176. 
25. (25)McInerney, M.; Duncan, K.; Youssef, N.; Fincher, T.; Maudgalya, S.; 
Folmsbee, M.; Knapp, R.; Simpson, R. R.; Ravi, N.; Nagle, D.: Development of 
microorganisms with improved transport and biosurfactant activity for enhanced oil 
recovery. Report to the Department of Energy, DE-FE-02NT15321, Washington DC 
2005. 

201 
26. Lai, T.-W.; Vijayendran, B. R.: Acidized fracturing fluids containing high molecular 
weight poly (vinylamines) for enhanced oil recovery. Google Patents, 1989. 
27. Biggs, S.; Selb, J.; Candau, F.: Copolymers of acrylamideN-alkylacrylamide in 
aqueous solution: the effects of hydrolysis on hydrophobic interactions. Polymer 
1993, 34, 580-591. 
28. Winnik, M. A.; Yekta, A.: Associative polymers in aqueous solution. Current 
opinion in colloid & interface science 1997, 2, 424-436. 
29. Zhou, C.; Yang, W.; Yu, Z.; Zhou, W.; Xia, Y.; Han, Z.; Wu, Q.: Synthesis and 
solution properties of novel comb-shaped acrylamide copolymers. Polymer bulletin 
2011, 66, 407-417. 
30. Luo, J.-h.; Bu, R.-y.; Zhu, H.-j.; Wang, P.-m.; Liu, Y.-z.: Property and application of 
comb-shape polyacrylamide. Acta Petrolei Sinica 2004, 25, 65-68. 
31. Yuan, S.; Luo, J.; Pu, R.; Liu, Y.; Zhu, H.; Wang, P.; Xiong, C.; Zhang, Y.; Bai, F.; 
Yang, J.: Braided comb-shaped salt-resistant polymer thickening agent. Google 
Patents, 2007. 
32. Sabhapondit, A.; Borthakur, A.; Haque, I.: Water soluble acrylamidomethyl propane 
sulfonate (AMPS) copolymer as an enhanced oil recovery chemical. Energy & fuels 
2003, 17, 683-688. 
33. Noelle, C. D.: Anionic, low molecular weight polyelectrolyte; froth flotation. 
Google Patents, 1982. 
34. Chang, Y.; McCormick, C. L.: Water-soluble copolymers. 49. Effect of the 
distribution of the hydrophobic cationic monomer dimethyldodecyl (2-
acrylamidoethyl) ammonium bromide on the solution behavior of associating 
acrylamide copolymers. Macromolecules 1993, 26, 6121-6126. 
35. Deng, Y.; Dixon, J. B.; White, G. N.; Loeppert, R. H.; Juo, A. S.: Bonding between 
polyacrylamide and smectite. Colloids and Surfaces A: Physicochemical and 
Engineering Aspects 2006, 281, 82-91. 
36. Güngör, N.; Karaoğlan, S.: Interactions of polyacrylamide polymer with bentonite in 
aqueous systems. Materials Letters 2001, 48, 168-175. 
37. Bai, B.; Li, L.; Liu, Y.; Wang, Z.; Liu, H.: Preformed particle gel for conformance 
control: factors affecting its properties and applications. In SPE/DOE Symposium 
on Improved Oil Recovery; Society of Petroleum Engineers, 2004. 

202 
38. Sydansk, R.; Southwell, G.: More than 12 years of experience with a successful 
conformance-control polymer gel technology. In SPE/AAPG Western Regional 
Meeting; Society of Petroleum Engineers, 2000. 
39. Seright, R.; Lane, R.; Sydansk, R.: A strategy for attacking excess water production. 
In SPE Permian Basin Oil and Gas Recovery Conference; Society of Petroleum 
Engineers, 2001. 
40. Bai, B.; Liu, Y.; Coste, J.-P.; Li, L.: Preformed particle gel for conformance control: 
transport mechanism through porous media. In SPE/DOE Symposium on Improved 
Oil Recovery; Society of Petroleum Engineers, 2004. 
41. Moradi-Araghi, A.; Beardmore, D.; Stahl, G.: The application of gels in enhanced 
oil recovery: theory, polymers and crosslinker systems. In Water-Soluble Polymers 
for Petroleum Recovery; Springer, 1988; pp 299-312. 
42. Reddy, B.; Eoff, L.; Dalrymple, E. D.; Black, K.; Brown, D.; Rietjens, M.: A natural 
polymer-based cross-linker system for conformance gel systems. SPE Journal 2003, 
8, 99-106. 
43. Bai, B.; Zhang, H.: Preformed-particle-gel transport through open fractures and its 
effect on water flow. SPE Journal 2011, 16, 388-400. 
44. Bai, B.; Huang, F.; Liu, Y.; Seright, R. S.; Wang, Y.: Case study on prefromed 

Download 4,02 Mb.

Do'stlaringiz bilan baham: