Shear Degradation of Partially Hydrolyzed Polyacrylamide Solutions

Maerker, J.M.

doi:10.2118/5101-pa

Cited by 148 publications

(103 citation statements)

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“…51) also demonstrated that mechanical degradation of C1205 polymer solutions does not always increase with ionic strength. This finding contrasts with some of previous reports for polyacrylamide based polymers (Maerker et al 1975;Zaitoun et al 2011). At low and moderate fluxes, C1205 solutions with the highest ionic content experienced the least degradation in the presence of Ca …”

Section: Mechanical Degradation Of the Associative Polymer (C1205)contrasting

confidence: 99%

“…Our observations for C1205 contrast with those of Maerker et al (1975) and Zaitoun et al (2011) for HPAM solutions-that increasing ionic strength leads to more severe degradation of hydrolyzed polyacrylamides. , 25 o C, versus flux while injecting 1,000-ppm C1205 with 0.253%, 2.53% and 12.65% TDS through the 464-md polyethylene core, where the calcium chloride content was 1/10 the weight of sodium chloride.…”

Section: Mechanical Degradation Of the Associative Polymer (C1205)contrasting

confidence: 90%

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Use of Polymers to Recover Viscous Oil From Unconventional Reservoirs

Seright¹

2011

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Section: Mechanical Degradation Of the Associative Polymer (C1205)contrasting

confidence: 99%

Section: Mechanical Degradation Of the Associative Polymer (C1205)contrasting

confidence: 90%

Use of Polymers to Recover Viscous Oil From Unconventional Reservoirs

Seright¹

2011

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“…It must also be kept in mind that some authors also suggested that high shear could mechanically degrade the PAM chains [52][53][54][55] and reduce their average length and molecular weight, reducing their ability to bridge cement grains and increase yield stress. This decrease in molecular weight could also explain, through a reduction of the average size of the bridging coils, the measured decrease in critical strain.…”

Section: Effect Of Shear History On the Pam Contribution To The Yieldmentioning

confidence: 99%

Effect of polyacrylamide on rheology of fresh cement pastes

Bessaies-Bey¹,

Baumann²,

Schmitz³

et al. 2015

Cement and Concrete Research

116

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“…However, the physics of polymer flow in porous media is very rich and complex so that this apparent viscosity also includes a variety of other important, often even predominant, phenomena. These include non-Newtonian rheology, retention mechanisms (Huh et al 1990), thermochemical or mechanical degradation of polymer chains (Gao 2013;Maerker 1975) or inaccessible pore volume (Lund 1992). Due to the combined effects of these phenomena, µ app includes rock geometrical and structural effects and may be very different from the bulk viscosity µ bulk , with apparent thinning or thickening effects.…”

Section: Introductionmentioning

confidence: 99%

Polymer Flow Through Porous Media: Numerical Prediction of the Contribution of Slip to the Apparent Viscosity

et al. 2017

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OATAO is an open access repository that collects the work of Toulouse researchers and makes it freely available over the web where possible. This is an author-deposited version published in : http://oatao.univ-toulouse.fr/ Eprints ID : 18221 Abstract The flow of polymer solutions in porous media is often described using Darcy's law with an apparent viscosity capturing the observed thinning or thickening effects. While the macroscale form is well accepted, the fundamentals of the pore-scale mechanisms, their link with the apparent viscosity, and their relative influence are still a matter of debate. Besides the complex effects associated with the rheology of the bulk fluid, the flow is also deeply influenced by the mechanisms occurring close to the solid/liquid interface, where polymer molecules can arrange and interact in a complex manner. In this paper, we focus on a repulsive mechanism, where polymer molecules are pushed away from the interface, yielding a so-called depletion layer in the vicinity of the wall. This depletion layer acts as a lubricating film that may be represented by an effective slip boundary condition. Here, our goal is to provide a simple mean to evaluate the contribution of this slip effect to the apparent viscosity. To do so, we solve the pore-scale flow numerically in idealized porous media with a slip length evaluated analytically in a tube. Besides its simplicity, the advantage of our approach is also that it captures relatively well the apparent viscosity obtained from core-flood experiments, using only a limited number of inputs. Therefore, it may be useful in many applications to rapidly estimate the influence of the depletion layer effect over the macroscale flow and its relative contribution compared to other phenomena, such as nonNewtonian effects.

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Shear Degradation of Partially Hydrolyzed Polyacrylamide Solutions

Cited by 148 publications

References 0 publications

Use of Polymers to Recover Viscous Oil From Unconventional Reservoirs

Use of Polymers to Recover Viscous Oil From Unconventional Reservoirs

Effect of polyacrylamide on rheology of fresh cement pastes

Polymer Flow Through Porous Media: Numerical Prediction of the Contribution of Slip to the Apparent Viscosity

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