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W3021495718 endingPage "107337" @default.
W3021495718 startingPage "107337" @default.
W3021495718 abstract "Abstract In the drilling and development of gas fields, gas exhibits good solubility in drilling fluids and in the formation water under high temperatures and pressures. Therefore, the prediction of the amount of dissolved gas in water plays a vital role in the development of natural gas. In this work, the principle of equal fugacity in a gas-liquid equilibrium, a non-iterative gas solubility prediction model was established. The gas-phase fugacity coefficient was calculated by the Peng-Robinson equation of state combined with the non-random mixing rule, and the liquid phase was calculated by Henry's law. The model can predict the solubility of CO2, CH4 and C2H6 in pure water at temperatures of 273–448 K and pressures of 0–100 MPa, with an error of less than 5.5%; however, the calculation accuracy for H2S was low. It is found that the effect of moisture in the gas phase of gas-liquid equilibrium cannot be ignored. Compared with the existing mixed gas solubility experimental data, this model could accurately calculate the solubility of non-polar mixed gases, such as CO2 + CH4, and CH4 + C2H6 mixture. For the mixtures containing a polar gas, the lower the polar gas content, the smaller was the prediction error of the model for the non-polar gas in the mixture. On the contrary, the higher the content of polar gas, the larger was the deviation in the prediction of non-polar gas in the mixture, but lower was the deviation in the prediction of polar gas. Finally, the ability of Krichevsky-Kasarnovsky equation to predict the solubility of pure gas was evaluated." @default.
W3021495718 created "2020-05-13" @default.
W3021495718 creator A5010508884 @default.
W3021495718 creator A5014809179 @default.
W3021495718 creator A5060068987 @default.
W3021495718 creator A5074798587 @default.
W3021495718 creator A5091143353 @default.
W3021495718 date "2020-09-01" @default.
W3021495718 modified "2023-09-24" @default.
W3021495718 title "A constitutive model for predicting the solubility of gases in water at high temperature and pressure" @default.
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W3021495718 doi "https://doi.org/10.1016/j.petrol.2020.107337" @default.
W3021495718 hasPublicationYear "2020" @default.
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