Effects of Poly(vinylpyrrolidone) on the Dynamic Viscosity of Methane Hydrate Systems at High-Pressure Driving Forces: Investigation of Concentration, Molecular Weight, and Shear Rate

The viscosity of methane hydrate slurries with poly(vinylpyrrolidone) (PVP) at 700 and 7000 ppm by weight, molecular weights of 40,000 (PVP40) and 360,000 (PVP360) Da, and shear rates of 400 and 80 1/s, were measured in a high-pressure rheometer with pressures up to 30 MPag and compared to pure wate...

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Veröffentlicht in:	arXiv.org 2023-02
Hauptverfasser:	Chong Yang Du, Guerra, André, McElligott, Adam, Marić, Milan, Rey, Alejandro D, Servio, Phillip
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Sprache:	eng
Schlagworte:	Additives Agglomeration Crystal growth High pressure Low concentrations Mechanical properties Methane hydrates Molecular weight Nucleation Physics - Applied Physics Physics - Soft Condensed Matter Polyvinylpyrrolidone Shear rate Slurries Viscosity
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description	The viscosity of methane hydrate slurries with poly(vinylpyrrolidone) (PVP) at 700 and 7000 ppm by weight, molecular weights of 40,000 (PVP40) and 360,000 (PVP360) Da, and shear rates of 400 and 80 1/s, were measured in a high-pressure rheometer with pressures up to 30 MPag and compared to pure water systems. The additives successfully reduced the formation of high-viscosity slurries, but at low concentrations were incapable of delaying hydrate agglomeration at the late growth stage. The average relative time required for PVP40 solutions at 700 ppm to grow to 50 mPa.s was 1.9 times the water reference value, but only 1.2 times to reach 200 mPa.s. Improved inhibition was observed for the higher concentration and higher molecular weight sets, where the relative time to reach 50 mPa.s were 8.2 and 2.6 times the water reference value, respectively. While the additives demonstrated anti-nucleation properties and suppressed crystal growth initially, they accelerated the hydrate clusters agglomeration rate, and potentially weakened the hydrate mechanical properties.
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The additives successfully reduced the formation of high-viscosity slurries, but at low concentrations were incapable of delaying hydrate agglomeration at the late growth stage. The average relative time required for PVP40 solutions at 700 ppm to grow to 50 mPa.s was 1.9 times the water reference value, but only 1.2 times to reach 200 mPa.s. Improved inhibition was observed for the higher concentration and higher molecular weight sets, where the relative time to reach 50 mPa.s were 8.2 and 2.6 times the water reference value, respectively. 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subjects	Additives Agglomeration Crystal growth High pressure Low concentrations Mechanical properties Methane hydrates Molecular weight Nucleation Physics - Applied Physics Physics - Soft Condensed Matter Polyvinylpyrrolidone Shear rate Slurries Viscosity
title	Effects of Poly(vinylpyrrolidone) on the Dynamic Viscosity of Methane Hydrate Systems at High-Pressure Driving Forces: Investigation of Concentration, Molecular Weight, and Shear Rate
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