Litcius/Paper detail

Enhanced Heat Transfer for NePCM-Melting-Based Thermal Energy of Finned Heat Pipe

Sameh E. Ahmed, Aissa Abderrahmane, Sorour Alotaibi, Obai Younis, Radwan A. Almasri, Wisam K. Hussam

2021Nanomaterials45 citationsDOIOpen Access PDF

Abstract

Using phase change materials (PCMs) in energy storage systems provides various advantages such as energy storage at a nearly constant temperature and higher energy density. In this study, we aimed to conduct a numerical simulation for augmenting a PCM’s melting performance within multiple tubes, including branched fins. The suspension contained Al2O3/n-octadecane paraffin, and four cases were considered based on a number of heated fins. A numerical algorithm based on the finite element method (FEM) was applied to solve the dimensionless governing system. The average liquid fraction was computed over the considered flow area. The key parameters are the time parameter (100 ≤t≤600 s) and the nanoparticles’ volume fraction (0%≤φ≤8%). The major outcomes revealed that the flow structures, the irreversibility of the system, and the melting process can be controlled by increasing/decreasing number of the heated fins. Additionally, case four, in which eight heated fins were considered, produced the largest average liquid fraction values.

Topics & Concepts

Materials scienceDimensionless quantityMechanicsThermodynamicsHeat transferPhase-change materialThermal energy storageHeat pipeVolume fractionConstant (computer programming)Flow (mathematics)Fraction (chemistry)Suspension (topology)ThermalEnergy (signal processing)Mass fractionWork (physics)Thermal energyProcess (computing)Finite element methodComputer simulationEnergy storageHeat transfer coefficientVolume (thermodynamics)Volumetric flow rateComposite materialPhase (matter)Mechanical engineeringTwo-phase flowPipe flowPhase Change Materials ResearchNanofluid Flow and Heat TransferSolar Thermal and Photovoltaic Systems