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Experimental study of convective heat transfer coefficients of CO2 hydrate slurries in a secondary refrigeration loop

•Heat transfer coefficients of CO2 hydrate slurries were measured in a heating tube.•Convective heat transfer coefficients increase with hydrate particle fraction.•Heat transfer coefficients at 14vol.% hydrates are 2.5times higher than water.•Laminar-Turbulent transition regime is observed for a Met...

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Published in:Applied thermal engineering 2017-05, Vol.118, p.630-637
Main Authors: Oignet, Jérémy, Hoang, Hong Minh, Osswald, Véronique, Delahaye, Anthony, Fournaison, Laurence, Haberschill, Philippe
Format: Article
Language:English
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Summary:•Heat transfer coefficients of CO2 hydrate slurries were measured in a heating tube.•Convective heat transfer coefficients increase with hydrate particle fraction.•Heat transfer coefficients at 14vol.% hydrates are 2.5times higher than water.•Laminar-Turbulent transition regime is observed for a Metzner-Reed Re of 1500. Conventional refrigerant fluids can be harmful to the environment due to their strong GWP. One of the solutions to reduce their impact could be the use of secondary refrigerant fluids, such as hydrate slurry in refrigeration devices. Gas hydrates are solid structures able to trap gas molecules and have a high dissociation enthalpy so that they can store and transport huge quantities of cold energy. The aim of the present work is to determine the thermal behavior of CO2 hydrate slurry based on a heating tube method. A secondary refrigeration loop composed of a tank in which the slurry is formed by subcooling and a loop with a heating tube has been used to determine convective heat transfer coefficients. The results have been obtained for CO2 hydrate slurries with solid fractions between 0 and 14vol.%. In this range of solid fractions, convective heat transfer coefficients of hydrate slurries are nearly 2.5times greater than that of liquid water.
ISSN:1359-4311
1873-5606
DOI:10.1016/j.applthermaleng.2017.02.117