2015 1(16)

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Pages:

119 - 123

Language:

RU

Ref.:

10


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TRANSPORTATION OF NATURAL GAS IN THE GAS HYDRATE STATE

Nakoryakov V.E.1, Mezentsev I.V.1, Meleshkin A.V.1, Elistratov D.S.1, Mezentseva N.N.1, Sadykova I.2

1 Institute of Thermophysics SB RAS, Novosibirsk, Russia
2 National Research Tomsk Polytechnic University, Tomsk, Russia


Citation:

Nakoryakov, V.E., Mezentsev, I.V., Meleshkin, A.V., Elistratov, D.S., Mezentseva, N.N. and Sadykova, I., (2015) Transportation of natural gas in the gas hydrate state, Modern Science: Researches, Ideas, Results, Technologies, Iss. #1(16), PP. 119 - 123.


Keywords:

natural gas; gas hydrates; transportation and storage of gas


Abstracts:

In this paper, we consider the problem of transportation, accumulation and storage of natural gas in the case, when traditional technologies of pipeline transportation or in the form of liquefied or compressed gas are ineffective. Gas hydrates at low pressures and temperatures below 273 K can be stable during relatively long time. At that, the losses of gas are significantly slowed down by the effect of self-preservation or forced conservation by the ice crust. The study of some technological elements is important for this. At that, the important factor is the choice of the method of gas hydrates production.
This work suggests the technology for production of natural gas hydrates by the effect of high-amplitude pressure pulses on water saturated with the bubbles of methane. The advantages of this method over the other is intensification of the process of gas hydrates production due to a significant increase in the interface by crushing bubbles in the wave relative to the motion of gas bubbles in liquid and turbulizing the liquid motion behind the shock wave. This method skips the volumetric-diffusion stage of gas hydrate growth that allows an order gain in the rate of intensifying the process of hydrate formation in comparison with the similar processes.


References:

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  2. Y.F.Makogon. Hydrates of Hydrocarbons. Tulsa, Oklahoma. Pennwell publishing company.1997.

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  7. Nakoryakov, V.E., Dontsov, V.E., Chernov, A.A. (2006), "Formation of gas hydrates in the gas-liquid mixture behind the shock wave", Doklady RAN, Vol.411, No. 2, pp. 190-193.

  8. Mesentsev I.V., Meleshkin A.V. (2011), "Shock-wave processes of the impact on two-phase medium at gas hydrate production", Materials of All-Russian Conference of scientific youth "EREL - 2011", Vol.1, pp. 115-116.

  9. Meleshkin A.V., Mesentsev I.V. (2011), "Shock-wave influence on the gas-liquid mixture at gas hydrate production", Proc. of the All-Russian Conference of scientific youth "Modern problems of mathematics and mechanics", pp. 333-336.

  10. V.E. Nakoryakov, A.N. Tsoi, I.V. Mezentsev and A.V. Meleshkin. Explosive Boiling of Liquid Nitrogen Jet in Water // Journal of Engineering Thermophysics. 2014, Vol.23. № 1, pp. 1-8.

 

 
     

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