Litcius/Paper detail

Dynamics of PCM melting driven by a constant heat flux at the free surface in microgravity

R. García-Roco, P. Sánchez, A. Bello, Karl Olfe, J. Rodríguez

2024Thermal Science and Engineering Progress15 citationsDOIOpen Access PDF

Abstract

In this work, we analyze the thermocapillary-enhanced melting of n-octadecane driven by a constant heat flux, applied at the free surface, in microgravity. The material is enclosed in an open rectangular container of dimensions 2L×H, and its solid-to-liquid transition is described using the enthalpy-porosity formulation of the Navier–Stokes equations, assuming laminar and incompressible flow. We study the influence of key governing parameters, including the effect of the heated length l̂ϕ∈(0,1], the applied flux ϕ̂∈(0,8], and the container aspect ratio Γ∈[1.5,22.8]. Heat transport is analyzed by comparing the thermocapillary-enhanced process with that driven solely by conduction, and quantified by the enhancement ratio G, which simply compares melting times in each scenario. We find that G increases with ϕ̂ and Γ, and is maximum at an optimal heated length l̂ϕ≃0.5. Compared to previous works on the melting of n-octadecane in microgravity, the associated enhancement G is more moderate in this system, and oscillatory thermocapillary convection is not observed over the range of parameters explored.

Topics & Concepts

ThermodynamicsHeat fluxMaterials scienceLaminar flowMechanicsFree surfaceThermal conductionFlux (metallurgy)Constant (computer programming)Work (physics)ConvectionEnthalpyNatural convectionHeat transferPhysicsMetallurgyComputer scienceProgramming languagePhase Change Materials ResearchFluid Dynamics and Thin FilmsNanofluid Flow and Heat Transfer
Dynamics of PCM melting driven by a constant heat flux at the free surface in microgravity | Litcius