Journal of Korean Society for Atmospheric Environment

Korean Society for Atmospheric Environment (한국대기환경학회)
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A Study on Thermodynamic Properties of Ethylene Gas Hydrate

  • Lim, Gye-Gyu (Chemical and Industrial Technology R & D Center, Department of Chemical Engineering, Hoseo University)
  • Published : 2007.06.30
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Abstract

The gas hydrates are probably most sensitive to climate change since they are stable only under specific conditions of high pressure and low temperature. One of the main factors responsible for formation of gas hydrates is the saturation of the gases with water vapor. Quantitative phase equilibrium data and understanding of the roles of water component in the phase behavior of the heterogeneous water-hydrocarbon-hydrate mixture are of importance and of engineering value. In this study, the water content of ethylene gas in equilibrium with hydrate and water phases were analyzed by theoretical and experimental methods at temperatures between 274.15 up to 291.75 K and pressures between 593.99 to 8,443.18 kPa. The experimental and theoretical enhancement factors (EF) for the water content of ethylene gas and the fugacity coefficients of water and ethylene in gas phase were determined and compared with each other over the entire range of pressure carried out in this experiment. In order to get the theoretical enhancement factors, the modified Redlich-Kwong equation of state was used. The Peng-Robinson equations and modified Redlich-Kwong equations of state were used to get the fugacity coefficients for ethylene and water in the gas phase. The results predicted by both equations agree very well with the experimental values for the fugacity coefficients of the compressed ethylene gas containing small amount of water, whereas, those of water vapor do not in the ethylene rich gas at high temperature for hydrate formation locus.

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References

  1. Akiya, T., M. Owa, M. Nakaiwa, T. Tanii, K. Nakazawa, and Y. Ando (1991) Phase Equilibria of Some alternative refrigerants hydrates and their mixtures using for cool storahe materals, 26th Ann. IECEC
  2. Dipen, G.A.M. and F.E.C. Scheffer (1950) The solubility of water in supercritical ethane, RECUEIL, 69, 593-603
  3. Dipen, G.A.M. and A.V. Cleef (1962) Ethylene hydrate at jogi pressires, RECUEIL, 81, 425-429
  4. Gnanendran, N. and R. Amin (2003) The effect of hydrotropes on gas hydrate formation, J. of Petroleum Science and Engineering, 40, 37-46 https://doi.org/10.1016/S0920-4105(03)00082-2
  5. Hornbach, M.J., D.M. Saffer, and H.W. Steven (2004) Critically pressured free-gas reservoirs below gas-hydrate provinces, Nature, 427(6970), 142-144 https://doi.org/10.1038/nature02172
  6. Katz, D.L., D. Conell, R. Kobayashi, F.H. Poettmann, and C.F. Weinaug (2004) Handbook of Natural Gas Engineering, Chapter 5, McGraw-Hill Book Company, New York
  7. Kobayashi, R. and D.L. Katz (2004) Methane hydrate at high pressure, petroleum transactions, AIME, 186, 66-70
  8. Kvenvolden, K.A. and T.D. Lorenson (2001) Natural Gas Hydrates, Occurrence, Distribution, and Detection, Earth and planetary science letters, 156(3), 3-18
  9. Lim, G.G. (2006) A Study on thermodynamic properties of gas hydrates, Proceeding of the 41th Meeting of Korean Society for Atmospheric Environment, Suwoon University, 121-122
  10. Lu, H., T. Uchida, R. Matsumoto, H. Tomaru, and H. Oda (2000) Anion plays a more important role than cation in affecting gas hydrate stability in electrolyte solution?-a recognition from exper-imental results, Western Pacific Geophys. Meeting, 59
  11. Redlich, O., F.J. Ackerman, R.D. Gunn, M. Jacobson, and S. Lau (1965) Thermodynamics of solutions, Industrial and Engineering Chemistry Fundamentals, 4(369), 369-373 https://doi.org/10.1021/i160016a001
  12. Sloan, E.D., F.M. Khoury, and R. Kobayashi (1976) Water content of methane gas in equilibrium with hydrates, Industrial and Engineering Chemistry Fundamentals, 15(4), 318-323 https://doi.org/10.1021/i160060a016
  13. Sugahara, T., K. Morita, and K. Ohgaki (2000) Satability boundaries and small hydrate-cage occupancy of ethylene hydrate system, Chemical Engineering Science, 55, 6015-6020 https://doi.org/10.1016/S0009-2509(00)00226-8