Experimental investigations on the thermal performance of an ice storage system using twin concentric helical coil
Applied Thermal Engineering • 2020
Publication Information
Authors
H.E. Abdelrahman, H.A. Refaey, A. Alotaibi, Ali A. Abdel-Aziz, M.F. Abd Rabbo
Keywords
Cool thermal energy storage; Ice-on-coil; Twin concentric helical coil;
Internal melt
Journal
Applied Thermal Engineering
Publisher
PERGAMON - ELSEVIER SCIENCE LTD
Volume
179
Issue
Not Available
Pages
Article No. 115737
publication.type
International
Paper Link
Open Link
Supplementary Materials
Not Available
Abstract
The cool thermal energy storage (CTES) offers a big advantage for peak shift of high electrical power consumed
by air conditioning systems. An experimental analysis for studying the thermal performance of ice storage
system with twin concentric helical coil (TCHC) is conducted in the present work. Effects of operating conditions
such as the heat transfer fluid (HTF) inlet temperature and flow rate on the solidified/melted mass fraction,
percentage energy stored/regained, and average charging/discharging rate during charging and discharging
processes are investigated. An experimental setup composed of TCHC immersed in distilled water as a phase
change material (PCM) in an insulated tank is used in the present study. Three different HTF inlet temperatures
of (−8,−10, and −12 °C) and (10, 12, and 14 °C) for charging and discharging processes, respectively and HTF
volume flow rates (5.0, 7.5, and 10 l/min) are investigated. The results show that, about 90% of the energy
stored is achieved at 59–74% of the complete charging time according to the tested parameter range in the
current study. Moreover, the HTF volume flow rates have a relatively small effect on the percentage energy
stored and seems to be less effective compared to the inlet HTF temperature during charging process.
by air conditioning systems. An experimental analysis for studying the thermal performance of ice storage
system with twin concentric helical coil (TCHC) is conducted in the present work. Effects of operating conditions
such as the heat transfer fluid (HTF) inlet temperature and flow rate on the solidified/melted mass fraction,
percentage energy stored/regained, and average charging/discharging rate during charging and discharging
processes are investigated. An experimental setup composed of TCHC immersed in distilled water as a phase
change material (PCM) in an insulated tank is used in the present study. Three different HTF inlet temperatures
of (−8,−10, and −12 °C) and (10, 12, and 14 °C) for charging and discharging processes, respectively and HTF
volume flow rates (5.0, 7.5, and 10 l/min) are investigated. The results show that, about 90% of the energy
stored is achieved at 59–74% of the complete charging time according to the tested parameter range in the
current study. Moreover, the HTF volume flow rates have a relatively small effect on the percentage energy
stored and seems to be less effective compared to the inlet HTF temperature during charging process.
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