Design and Analysis of Cooling Cabinet for Vaccine Storage

N. Saravanan; R. Rathnasamy; V. Ananchasivan

doi:10.4028/www.scientific.net/AMR.984-985.1180

Paper Titles

Numerical Analysis to Study the Flow Pattern inside a Fin-Tube Heat Exchanger Navigation of a Mobile Robot
p.1150

Thermal Presentation of Two-Phase Congested Thermosyphon in Submission of Determined Thermoelectric Dominance Producer by Means of Phase Change Material Thermal Storage
p.1153

Optimization of MCHX Using CFD and Refrigeration Cycle Simulator
p.1163

Environment Friendly Mixed Refrigerant to Replace R-134a in a VCR System with Exergy Analysis
p.1174

Design and Analysis of Cooling Cabinet for Vaccine Storage
p.1180

Effect of Header Design on Pressure Drop in Microchannel Heat Sink for MEMS Applications
p.1184

Assessment of Air Quality in Commercial Places of Chennai through Air Quality Index
p.1190

Analysis of the Effects of Using Different Nozzles and Angle of Attack in Miniature Commercial Aircraft with Vertical Lift Using CFD
p.1195

Comparative Studies on Various Turbulent Models with Liquid Rocket Nozzle through Computational Tool
p.1204

HomeAdvanced Materials ResearchAdvanced Materials Research Vols. 984-985Design and Analysis of Cooling Cabinet for Vaccine...

Design and Analysis of Cooling Cabinet for Vaccine Storage

Abstract:

Solar powered adsorption refrigeration system is renewable source in the future energy demands and more useful for off-grid area. In this paper a mathematical model was developed to investigate the performance of a cooling cabinet of a activated carbon-ammonia adsorption refrigeration system, and a new effective method about the refrigeration studies. A brief thermodynamic study of the cooling cabinet is carried out and the effect of operating parameters such as temperature, pressure, cooling effect of the system is numerically analyzed. The impact of solar intensity on performance of the system is significant. The cooling cabinet model is completely analysied for varies capacity and it is able to calculate the cooling cabinet coil length .The designed mathematical model is analyzed by the use of coolpack software and the results are compared with ansys software. It is observed that the system operate more efficient while maximum solar intensity and the cooling effect. Key words: Solar, Adsorption Refrigeration, Mathematical model, Analysis, Solar intensity.

You might also be interested in these eBooks

Modern Achievements and Developments in Manufacturing and Industry

View Preview

Info:

Periodical:

Advanced Materials Research (Volumes 984-985)

Pages:

1180-1183

DOI:

https://doi.org/10.4028/www.scientific.net/AMR.984-985.1180

Citation:

Cite this paper

Online since:

July 2014

Authors:

N. Saravanan*, R. Rathnasamy, V. Ananchasivan

Keywords:

Adsorption Refrigeration, Analysis, Mathematical Models, Solar, Solar Intensity

Export:

RIS, BibTeX

Price:

Permissions CCC:

Request Permissions

Permissions PLS:

Request Permissions

Сopyright:

Citation:

* - Corresponding Author

References

[1] RUTHVEN, D. M. 1984. Principles of adsorption and adsorption processes. New York: John Wiley & Sons.

Google Scholar

[2] . TCHERNEV, D. I. 1978. Natural zeolites: Occurrence properties and use. London: Pergamon Press.

Google Scholar

[3] DUPONT, M., GUILLEMINOT, J. J., MENUIER, F., & NGUYEN, P. 1982. Study of solar ice conservators using day night intermittent zeolite 13X–water cycle in temperate and tropical climates. Paper presented at the International Institute of Refrigeration.

Google Scholar

[4] GRENIER, P. H., GUILLEMINOT, J. J., MESTER, M., MEUNIER, F., & PONS, M. 1983. Experimental Results on a 12 m3 Solar Powered Cold Store using the intermittent Zeolite 13X + H2O Cycle. Perth.

Google Scholar