Selective Inhibition of Paraffin Deposition under High Flow Rate as a Function of the Crude Oil Paraffin Type and Content by Fluorescence Depolarization:  Polypropylene and High-Density Polyethylene

Quintella, Cristina M.; Lima, Angelo Marcos Vieira; Silva, Eduardo Benes da

doi:10.1021/jp055934u

Cited by 5 publications

(9 citation statements)

References 26 publications

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“…11 For instances, high-density polyethylene and polypropylene were studied to identify tailor-made materials for walls of pipelines and ducts for crude paraffinic oil that inhibit paraffin depositions. 12,13 Copolymers of alkyl acrylates [14][15][16] have been found to act either as wax growth inhibitors or promoters with different degrees of polymerization. Poly(ethylene-butene) random copolymers were reported to co-crystallize with waxes into thin platelets so as to modify the wax crystal morphology through microscopy and calorimetric studies 17,18 and small-angle neutron scattering (SANS) techniques.…”

Section: Introductionmentioning

confidence: 99%

“…Owing to the wide variety of oil components, many kinds of polymers were developed as PPD additives to affect the flow property of oil via adjusting the precipitation of wax crystals , C opolymers of alkyl acrylates − have been found to act either as wax growth inhibitors or promoters with different degrees of polymerization. Poly(ethylene−butene) random copolymers were reported to co-crystallize with waxes into thin platelets so as to modify the wax crystal morphology through microscopy and calorimetric studies , and small-angle neutron scattering (SANS) techniques .…”

Section: Introductionmentioning

confidence: 99%

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Theoretical Study of the Prohibited Mechanism for Ethylene/Vinyl Acetate Co-polymers to the Wax Crystal Growth

Zhang

Wan

et al. 2007

J. Phys. Chem. B

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To understand the effect of pour point depressants (PPD) on the wax growth is important for designing PPD additives for use with different oils with high efficiency and good economics. In our current study, molecular mechanics, molecular dynamics, and quantum mechanics calculations were performed to investigate the prohibited mechanism of ethylene/vinyl acetate (EVA) additives on the paraffin deposition in oils. On the wax surface, a single C18 molecule and clusters were preferably deposited on the wax surface (010) in a parallel conformation, which resulted in the formation of large blocks of wax crystal. MD simulation indicated that the linear conformation of EVA was more favorable to be adsorbed onto the carbon backbone of the wax surface (010) with the polar fragments of vinyl acetate staying upside of the surface. Furthermore, four EVA molecules can efficiently optimize the inhibition effect for the deposition of the solute C18 molecules over 10x8 size wax surface (010). According to the simulation results, a simplified rational model was established to estimate the minimum dosage of EVA-type PPD for fuels with different paraffin contents. In a certain degree, this simplified model has provided an effective route to correlate microstructures and the properties of polymer-involving systems, which will shed light on the application of theoretical studies in industries.

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Section: Introductionmentioning

confidence: 99%

Section: Introductionmentioning

confidence: 99%

Theoretical Study of the Prohibited Mechanism for Ethylene/Vinyl Acetate Co-polymers to the Wax Crystal Growth

Zhang

Wan

et al. 2007

J. Phys. Chem. B

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“…In the past, several research groups dedicated time and effort to investigate the physicochemical mechanisms that lead to the formation of paraffinic deposits, as well as to develop methods to prevent the formation of these crystals and the consequent stagnation of oil production and transport [2][3][4][5]. Several techniques have been used to determine the properties such as thermal diffusivity, heat capacity, (paraffin) molecular diffusion coefficient, and kinematic viscosity, with the aim of developing alternative methods to characterize the types of oil [6][7][8].…”

Section: Introductionmentioning

confidence: 99%

Effects of paraffin chain size on the oil outflow investigated by a combination of thermal lens and laser-induced fluorescence spectrometries

Watanabe

Lima

Quintella

2015

Fuel

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“…They may be used either as coatings or linings for metallic ducts or as massive ducts. Although they cannot stand high temperatures and their low mechanical resistance is a concern, they have the advantage of impeding the formation of paraffin deposits − and a much lower corrosion rate than unlined metallic ducts. They are already being used to recuperate condemned metallic ducts by insertion of a plastic layer as inner lining, thus reducing the costs of welding and equipment maintenance or replacement.…”

Section: Introductionmentioning

confidence: 99%

“…Recently, it was observed that θc could not discriminate between the interactions with polyethylene surfaces with different branching degrees. 16 It was also shown 3,4,[17][18][19][20] that θc characterization cannot be applied straightforwardly to interactions between walls and liquids flowing at high rates as it becomes unreliable due to not taking into account flow effects within the liquid like molecular chains orientation.…”

Section: Introductionmentioning

confidence: 99%

Wettability under Imposed Flow as a Function of the Baking Temperatures of a DGEBA Epoxy Resin Used in the Crude Oil Industry

et al. 2007

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The baking temperature (Tb) of an epoxy resin was optimized in order to decrease the dynamic interfacial tension, identifying the lowest wettability conditions for liquids flowing at a high rate. The dependence of dynamic interfacial tension on Tb was evaluated for the diglycidyl ether of bisphenol A. This resin was used to coat a sucking rod at the oil field of Bacia de Sergipe/Alagoas, Brazil in order to reduce blockage occurrences, maintenance stops, and the pumping capacity required. The samples were baked for 24 h between 100 and 180°C. Their color and absorption spectra showed progressive dependence of Tb, indicating a migration from polymerization, through polymer network degradation, until carbonization. Spectrofluorimetry showed an initial increase in the energy gap between absorption and emission followed by a decrease that was attributed to changes of the chemical environment isotropy. Fourier transform infrared spectroscopy showed that the maximum polymerization occurred at 140°C. Dynamic interfacial tension was evaluated by fluorescence depolarization of induced flowing liquids, using polarized laser-induced fluorescence within induced liquid flows and was clearly dependent on Tb. The lowest dynamic wettability was at 120°C, just before full polymerization, which was attributed to two competing effects as Tb increased: polymerization and progressive yielding of compounds from the epoxy degradation. This points to the need to review the standard application procedures of these resins.

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Selective Inhibition of Paraffin Deposition under High Flow Rate as a Function of the Crude Oil Paraffin Type and Content by Fluorescence Depolarization: Polypropylene and High-Density Polyethylene

Cited by 5 publications

References 26 publications

Theoretical Study of the Prohibited Mechanism for Ethylene/Vinyl Acetate Co-polymers to the Wax Crystal Growth

Theoretical Study of the Prohibited Mechanism for Ethylene/Vinyl Acetate Co-polymers to the Wax Crystal Growth

Effects of paraffin chain size on the oil outflow investigated by a combination of thermal lens and laser-induced fluorescence spectrometries

Wettability under Imposed Flow as a Function of the Baking Temperatures of a DGEBA Epoxy Resin Used in the Crude Oil Industry

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