Synthesis and characterization of a water‐soluble sulfonates copolymer of acrylamide and <i>N</i>‐allylbenzamide as enhanced oil recovery chemical

Ye, Zhongbin; Gou, Guangjun; Gou, Shaohua; Jiang, Wenchao; Liu, Tongyi

doi:10.1002/app.38385

Cited by 54 publications

(46 citation statements)

References 31 publications

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“…110 Liu et al 111 synthesized a sulfonated copolymer of acrylamide (AM) and Nphenylmaleimide (N-PMI) and reported a 60% viscosity retention at 85 • C and a 9.5% additional oil recovery for the sulfonated copolymer. Ye et al 112 synthesized AM-Nallylbenzamide (NABI) copolymer of AM-NABI and AM-NABI-sodium (acrylamido) methanesulfonate (SAM) terpolymer, for which salt and temperature tolerance were better than HPAM but viscosity retention was only 25% at 120 • C. Poly (acrylic acid-st-1-vinyl-2-pyrrolidone) was synthesized using acrylic acid and N-vinyl-2-pyrrolidinone monomers instead of AM, 113 which showed a strong resistance to alkali and a better oil recovery compared to HPAM. Under similar conditions 47% recovery was reported compared to 41% recovery with HPAM.…”

Section: Other Acrylamide Based Copolymersmentioning

confidence: 97%

Review on Polymer Flooding: Rheology, Adsorption, Stability, and Field Applications of Various Polymer Systems

Kamal¹,

Sultan²,

et al. 2015

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Polymer flooding is one of the most promising techniques for the recovery of remaining oil from light oil reservoirs. Water soluble polymers are used to enhance the viscosity of displacing fluid and to improve the sweep efficiency. In this paper, water soluble polymers used for chemical enhanced oil recovery are reviewed. Conventional and novel modified polymers are discussed along with their limitations. The review covers thermal stability, rheology, and adsorption behavior of various polymer systems in sandstone and carbonate reservoirs. Field and laboratory core flooding data of several polymers are covered. The review describes the polymer systems that are successfully applied in low-temperature and low-salinity reservoirs. Comprehensive review of current research activities aiming at extending polymer flooding to high-temperature and high-salinity reservoirs is performed. The review has identified current and future challenges of polymer flooding.

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Section: Other Acrylamide Based Copolymersmentioning

confidence: 97%

Review on Polymer Flooding: Rheology, Adsorption, Stability, and Field Applications of Various Polymer Systems

Kamal¹,

Sultan²,

et al. 2015

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“…However, the current widely used polymers, polyacrylamide (PAM) and partially hydrolyzed polyacrylamide (HPAM), cannot completely meet the requirements due to the hydrolysis, degradation, and others under high temperature or high salinity [49]. Furthermore, PAM and HPAM have poor shear resistance [50][51][52][53].…”

Section: Polymermentioning

confidence: 99%

A review on applications of nanotechnology in the enhanced oil recovery part A: effects of nanoparticles on interfacial tension

2016

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Chemical enhanced oil recovery is another strong growing technology with the potential of a step change innovation, which will help to secure future oil supply by turning resources into reserves. While Substantial amount of crude oil remains in the reservoir after primary and secondary production, conventional production methods give access to on average only one-third of original oil in place, the use of surfactants and polymers allows for recovery of up to another third of this oil. Chemical flooding is of increasing interest and importance due to high oil prices and the need to increase oil production. Research in nanotechnology in the petroleum industry is advancing rapidly and an enormous progress in the application of nanotechnology in this area is to be expected. Nanotechnology has the potential to profoundly change enhanced oil recovery and to improve mechanism of recovery. This paper, therefore, focuses on the reviews of the application of nano technology in chemical flooding process in oil recovery and reviews the application nano in the polymer and surfactant flooding on the interfacial tension process.

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“…We obtained the relationship between the temperature and apparent viscosity by changing the temperature from 30 to 120 C under a constant shear rate of 170 s 21 , and we investigated the relationship between the shear rate and apparent viscosity at 30 C by varying the shear rate at a range of 7.34-1000 s 21 .…”

Section: Rheology Experimentsmentioning

confidence: 99%

“…30,38 Shear Tolerance of the Copolymers The shear tolerance of the copolymers (2.0 g/L) was investigated, as shown in Figure 7(a). It was clear that the apparent viscosity of the copolymers decreased sharply under a shear rate of 3.7-200 s…”

Section: Articlementioning

confidence: 99%

“…[24][25][26][27][28] Previous studies in our laboratory confirmed that sulfomethylation is an efficient way to introduce the ASO 3 2 group into copolymers because it can give the copolymer remarkable antishearing ability, temperature resistance, and salt tolerance with simple operation and economic feasibility. 29,30 Hence, in this study, N,N-diallyl nicotinamide (DANA) was synthesized as described in the literature; 31,32 it was copolymerized with sodium acrylate (NaAA) and AM to obtain an AM/AA/ DANA copolymer. Furthermore, the ASO 3 2 group was used in AM/AA/DANA via sulfomethylation with the aim of improving the temperature tolerance and shear tolerance of the copolymer (Scheme 1).…”

Section: Introductionmentioning

confidence: 99%

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Modification of a nicotinic acid functionalized water‐soluble acrylamide sulfonate copolymer for chemically enhanced oil recovery

Gou

Liu

et al. 2013

J of Applied Polymer Sci

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N,N-Diallyl nicotinamide (DANA) and acrylic acid (AA) were used to react with acrylamide (AM) and synthesize a novel nicotinic acid functionalized water-soluble copolymer AM/AA/DANA by redox free-radical polymerization. Then, the acrylamide/sodium acrylamido methanesulfonate/acrylic acid/N,N-diallyl nicotinamide (AM/AMS/AA/DANA) was obtained by the introduction of the ASO 3 2 group into AM/AA/DANA after sulfomethylation. The optimal reaction conditions, such as the monomer ratio, initiator concentration, reaction temperature, and pH of the copolymerization or sulfomethylation, were investigated. Both AM/AA/ DANA and AM/AMS/AA/DANA were characterized by IR spectroscopy, 1 H-NMR, scanning electron microscopy, and intrinsic viscosity testing. We found that the AM/AMS/AA/DANA had a remarkable temperature tolerance (120 C, viscosity retention rate 5 39.8%),shear tolerance (1000 s 21 , viscosity retention rate 5 23.3%), and salt tolerance (10 g/L NaCl, 1.5 g/L MgCl 2 , 1.5 g/L CaCl 2 , viscosity retention rates 5 37.4, 27.5, and 21.6%). In addition, the result of the core flood test showed that the about 13.1% oil recovery could be enhanced by 2.0 g/L AM/AMS/AA/DANA at 70

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Synthesis and characterization of a water‐soluble sulfonates copolymer of acrylamide and N‐allylbenzamide as enhanced oil recovery chemical

Cited by 54 publications

References 31 publications

Review on Polymer Flooding: Rheology, Adsorption, Stability, and Field Applications of Various Polymer Systems

Review on Polymer Flooding: Rheology, Adsorption, Stability, and Field Applications of Various Polymer Systems

A review on applications of nanotechnology in the enhanced oil recovery part A: effects of nanoparticles on interfacial tension

Modification of a nicotinic acid functionalized water‐soluble acrylamide sulfonate copolymer for chemically enhanced oil recovery

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