Enhanced heat transfer characteristics of water based copper oxide nanofluid PCM (phase change material) in a spherical capsule during solidification for energy efficient cool thermal storage system

The present study aims to investigate the solidification characteristics of water based NFPCM (nanofluid phase change material). The NFPCM was prepared by dispersing copper oxide nanoparticles and a nucleating agent in the base PCM (phase change material). The experiments were conducted at various b...

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Bibliographic Details
Published in:Energy (Oxford) 2014-08, Vol.72, p.636-642
Main Authors: Chandrasekaran, P., Cheralathan, M., Kumaresan, V., Velraj, R.
Format: Article
Language:English
Subjects:
Applied sciences
COPPER OXIDE
Copper oxides
Energy
Energy conservation
Energy. Thermal use of fuels
Evaporation
Exact sciences and technology
FLUID FLOW
Heat transfer
MICROSTRUCTURES
Nanofluid phase change material
Nanofluids
Nanostructure
Nucleating agent
OXIDES
Phase change materials
PHASE TRANSFORMATIONS
PHASES
SOLIDIFICATION
Subcooling
Theoretical studies. Data and constants. Metering
Thermal energy storage
Transport and storage of energy
WATER
Water based
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Summary:The present study aims to investigate the solidification characteristics of water based NFPCM (nanofluid phase change material). The NFPCM was prepared by dispersing copper oxide nanoparticles and a nucleating agent in the base PCM (phase change material). The experiments were conducted at various bath temperatures and the NFPCM exhibited a significant reduction in solidification time of about 35% due to enhanced heat transport properties. Further, 50% of total mass solidified during 25% of total solidification time in both PCM and NFPCM. The presence of nucleating agent eliminated the ramifying problem of subcooling in the PCM and this will allow the evaporator to operate at a higher temperature in a chiller. The enhanced heat transfer rate of the NFPCM without subcooling is advantageous for many CTES (cool thermal energy storage) applications. It is construed from the experimental results that considerable energy saving potential is possible in the CTES system by operating the evaporator at a higher temperature. •Addition of CuO nanoparticle in water reduces solidification time by 35%.•Accelerated charging prevails during initial 25% of total solidified duration.•Considerable energy saving in CTES system by operating evaporator at higher temperature
ISSN:0360-5442
DOI:10.1016/j.energy.2014.05.089