Abstract
Phase change materials (PCM) utilization in energy storage systems represents a point of interest and attraction for the researchers to reduce greenhouse gas emissions. PCM have been used widely on the interior or exterior walls of the building application to optimize the energy consumption during heating and cooling periods. Meanwhile, ground source heat pump (GSHP) gained its popularity because of the high coefficient of performance (COP) and low running cost of the system. However, GSHP system requires a stand-by heat pump during peak loads. This study will present a new concept of energy piles that used PCM in the form of enclosed tube containers. A lab-scaled foundation pile was developed to examine the performance of the present energy pile, where three layers of insulation replaced the underground soil to focus on the effect of PCM. The investigation was conducted experimentally and numerically on two identical piles with and without PCM. Moreover, a flow rate parametric study was conducted to study the effect of the working fluid flow rate on the amount of energy stored and released at each model. Finally, a comprehensive Computational fluid dynamic (CFD) model was developed and compared with the experimental results. There was a good agreement between the experimental measurements and the numerical predictions. The results revealed that the presence of PCM inside the piles increased not only the charging and discharging capacity but also the storage efficiency of the piles. It was found that PCM enhances the thermal response of the concrete during cooling and heating processes. Although increasing the flow rate increased charging and discharging capacity, the percentage of energy stored/released was insignificant compared to the flow rate increasing percentage.
Highlights
Ground source heat pump (GSHP) represents a green sustainable technique for heating and cooling the building compared to conventional heat pumps
GSHP utilizes the underground soil as a heat source/sink which has a less variable temperature than that of the atmospheric air used as a heat source/sink for the conventional heat pumps
GSHP consists of two main parts: the conventional heat pump and the ground heat exchanger (GHE)
Summary
Ground source heat pump (GSHP) represents a green sustainable technique for heating and cooling the building compared to conventional heat pumps. The larger the temperature difference between the heat pump’s working fluid and the heat source/sink, the higher the overall COP, resulting in less energy consumption and fewer greenhouse gases (GHG) emissions [1,2,3]. GSHP consists of two main parts: the conventional heat pump and the ground heat exchanger (GHE). The working fluids coming from the GHE, usually water, exchange their energy with the refrigerator at the evaporator of the conventional heat pump (HP), which decreases the temperature of the water and evaporates the refrigerator. The cold water goes back to the underground soil and extracts an amount of heat, which leaves the underground soil colder after each cycle of the water throughout the winter season. The cycle is Energies 2020, 13, 4699; doi:10.3390/en13184699 www.mdpi.com/journal/energies
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