Amirhossein Mostafavi scite author profile

For the last few years, molten salt nanomaterials have attracted many scientists for their enhanced specific heat by doping a minute concentration of nanoparticles (up to 1% by weight). Likewise, enhancing the specific heat of liquid media is important in many aspects of engineering such as engine oil, coolant, and lubricant. However, such enhancement in specific heat was only observed for molten salts, yet other engineering fluids such as water, ethylene glycol, and oil have shown a decrease of specific heat with doped nanoparticles. Recent studies have shown that the observed specific heat enhancement resulted from unique nanostructures that were formed by molten salt molecules when interacting with nanoparticles. Thus, such enhancement in specific heat is only possible for molten salts because other fluids may not naturally form such nanostructures. In this study, we hypothesized such nanostructures can be mimicked through in situ formation of fabricated nano-additives, which are putative nanoparticles coated with useful organic materials (e.g., polar-group-ended organic molecules) leading to superstructures, and thus can be directly used for other engineering fluids. We first applied this approach to polyalphaolefin (PAO). A differential scanning calorimeter (DSC), a rheometer, and a customized setup were employed to characterize the heat capacity, viscosity, and thermal conductivity of PAO and PAO with fabricated nano-additives. Results showed 44.5% enhanced heat capacity and 19.8 and 22.98% enhancement for thermal conductivity and viscosity, respectively, by an addition of only 2% of fabricated nanostructures in comparison with pure PAO. Moreover, a partial melting of the polar-group-ended organic molecules was observed in the first thermal cycle and the peak disappeared in the following cycles. This indicates that the in situ formation of fabricated nano-additives spontaneously occurs in the thermal cycle to form nanostructures. Figure of merit analyses have been performed for the PAO superstructure to evaluate its performance for heat storage and transfer media.

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Thermal Energy Storage Module Design Using Energy and Exergy Analysis

Keshavarz

Ghassemi

Mostafavi

2003

Heat Transfer Engineering

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Theoretical modeling and optimization of fin-based enhancement of heat transfer into a phase change material

Mostafavi

Parhizi

Jain

2019

International Journal of Heat and Mass Transfer

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Availability (exergy) analysis in a thermal energy storage system with the phase change materials arranged in series

Keshavarz

Mehrabian

Abolghasemi

et al. 2011

Proceedings of the Institution of Mechanical Engineers, Part A:

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In this article, a thermal energy storage system is studied from the irreversibility point of view. The system consists of some phase change materials arranged in series. The phase change materials are located in the annular space between two concentric cylinders while the working fluid is flowing in the inner cylinder. Charging and discharging processes occur periodically. The conservation equations of energy for the working fluid and the phase change materials are solved numerically. The numerical results are validated when compared with available experimental results. The effect of different physical and geometrical factors on the irreversibility of the system is studied. The results show that the number of phase change materials and their arrangement have great influence on the irreversibility of the system. The temperature distribution inside the phase change materials affects the availability of the system. The proper arrangement of the phase change materials can reduce the irreversibility or increase the availability of the system.

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