Notice: Undefined index: linkPowrot in C:\wwwroot\wwwroot\publikacje\publikacje.php on line 1275
Publikacje
Pomoc (F2)
[55350] Artykuł:

Calculation of heat transfer in fluid around gas-vapour bubbles

Czasopismo: Metallurgical and Mining Industry   Tom: 11, Strony: 105-110
ISSN:  2076-0507
Opublikowano: Listopad 2016
Liczba arkuszy wydawniczych:  0.60
 
  Autorzy / Redaktorzy / Twórcy
Imię i nazwisko Wydział Katedra Procent
udziału
Liczba
punktów
Anatoliy Pavlenko orcid logoWiŚGiEKatedra Fizyki Budowli i Energii Odnawialnej*50.00  
Hanna Koshlak50.00  

Grupa MNiSW:  Pozostałe publikacje (niepunktowane)
Punkty MNiSW: 0


Pełny tekstPełny tekst     DOI LogoDOI    
Słowa kluczowe:

heatand masstransfer  mathematical model  thermal conditivity  heatinsulation 


Keywords:

heatand masstransfer  mathematical model  thermal conditivity  heatinsulation 



Streszczenie:

Marine gas hydrates are considered the most probable alternative fuel in many countries. Their
exploration actively engages specialists from France, Germany, the USA, Canada and Japan
[1-9]. The Japanese plan to start commercial production of methane from the “Ice fuel” around
their islands in the basin Nyanhay in 2016. However, effective technology acquisition, storage and
transport of methane gas hydrates is still in the development stage [10-15]




Abstract:

Marine gas hydrates are considered the most probable alternative fuel in many countries. Their
exploration actively engages specialists from France, Germany, the USA, Canada and Japan
[1-9]. The Japanese plan to start commercial production of methane from the “Ice fuel” around
their islands in the basin Nyanhay in 2016. However, effective technology acquisition, storage and
transport of methane gas hydrates is still in the development stage [10-15]



B   I   B   L   I   O   G   R   A   F   I   A
1. Takeya S., Ebinuma Т., Uchida Т. (2002)
Self-preservation effect and dissociation rates
of CH4 hydrate. Crystal Growth. Vol. 237-239,
p.p. 379-382.
2. Stem L.A., Circone S., Kirby S.H. , Durham
W.B. (2003) Temperature, pressure and composition
effects on anomalous or «self preservation
of gas hydrates. Can. J. Phys. Vol. 81,
p.p. 271-283.
3. Wenfeng Hao, Jinqu Wang, Shuanshi Sfan,
Wenbin Hao (2008) Evaluation and analysis
method for natural gas hydrate storage and
transportation processes. Energy Conversion
and Management. Vol. 49, p.p. 2546–2553.
4. Belosludov V.R., Suhbotion O.S., Krupskii D.S.,
Ikeshoji Т., Belosludov R.V., Kawazone Y. Kudoh
J. (2005) Structural and thermodynamic
properties of gas hydrate phases immersed in the
ice phase. Proceed. 5-th Intern. Conf. on gas hydrates.
Trondheim, Norway, Vol. 2, p.p. 631-637.
5. Gudmundsson J., Parlaktuna M., Khokhar A.
(1994) Storing natural gas as frozen hydrate.
SPE Production and Facilities, February. p.p.
69-73.
6. Economides M.J., Sun Kai, Subero G.U. (2006)
Compressed Natural Gas (CNG): An Alternative
to Liquefied Natural Gas (LNG). Journal
SPE Production & Operations. Vol. 21(2), p.p.
318 – 324.
7. Chuvilin E.M., Kozlova E.V., Makhonina N.A.,
Yakushev V.S. (2003) Experimental investigation
of gas hydrate and ice formation in methane-saturated
sediments. Proceed. 8-th Intern.
Conf on permafrost. Zurich, Switzerland.Vol.
1, p.p. 145-150.
8. Chuvilin Е.М., Makhonina N.A., Titenskaya
О.А., Boldina О.М. (2002) Petrophysical
investigations on frozen sediments artificially
saturated by hydrate. Proceed. 4-th Intern.
Conf on gas hydrates. Yokohama, Japan. Vol.
2, p.p. 734-739.
9. . Kim H. C. (1987) Fugacity Model of Gas Hydrate
Dissociation in Three Phases. Chem.
Eng. Sci. Vol. 42, p.p. 1645-1653.
10. Komai T., Sakamoto Y., Kawamura Т., Yamamo-
to Y. (2005) Dissociation Rate of Methane Hydrates
Occupied in Pore Space of Marine Sediments.
Proceeding of the Sixth (2005) ISOPE
Ocean Mining Symposium Changsha. Human,
China, October 9 – 13.
11. Levik O.I. (2000) Thermophysical and Compositional
Properties of Natural Gas Hydrate.
Dr.Ing. Thesis. Department of Petroleum Engineering
and Applied Geophysics, NTNU.
Trondheim. 164 p.
12. Norvegian Patent No 172080. Method and for
production of gas hydrates / J.S. Gudmundsson

inventor J.S.Gudmundsson. 1990. 9 p.
13. Istomin V.A. (1999) On Possibilitty of Superheating
of Natural Gas Hydrate and Other
Aqueous Crystalline Structures. Russian Journal
of Physical Chemistry. Vol. 73, No 11.
14. Gudmundsson J.S., Parlaktuna M. (1991) Gasin-ice:
Concept evaluation. Technical report,
Department of Petroleum Engineering and
Applied Geophysics, Norwegian University of
Science and Technology.
15. Gudmundsson J.S., Parlactuna M., Levik O.I.,
Andersson V. Storing Natural Gas as Frozen
Hydrate. SPE Production & Facilities. No.1
(Feb.), p.p. 69-73.
16. Aktershev S.P., Ovchinnikov V.V. (2013) Modeling
of boiling of metastable liquid in the
presence of evaporation fronts. Sovremennaja
nauka: issledovanija, idei, rezultaty, tehnologii
[Modern science: studies, ideas, results, technologies].
Novosibirsk: Kutateladze Institute
of Thermophysics RAS. No 1, p.p. 77–82.
17. Avramenko A.A, Sorokina T.V. (2005) The instability
of vapor bubble. Institute of Technical
Thermophysics of NASU. Kyiv: Promyshlennaja
teplotehnika. Vol. 27, No 6, p.p. 12–15.
18. Pavlenko A., Usenko B., Koshlak A. (2014)
Analysis of thermal peculiarities of alloying
with special properties. Metallurgical and
Mining Industry. No 2, p.p. 15-19.
19. Pavlenko A.M., Basok B.I. (2005) Regularities
of boiling-up of emulsified liquids. Heat
Transfer Research. No 36 (5), p.p. 419.
20. Nigmatulin R.I., Habeev N.S. (1978) The dynamics
and heat and mass transfer of gas-vapor
bubbles with the liquid. Nekotorye voprosy
mehaniki sploshnoj sredy. Moscow: Institute
of Mechanics, Moscow State University.
P.p.229–243.