Annabelle Joulin scite author profile

International audienceComparison exercises have been carried out by different research teams to study the sensitivity of the natural convection occurring in a vertical asymmetrically heated channel to four sets of open boundary conditions. The dimensionless parameters have been chosen so that a return flow exists at the outlet. On the whole, results provided by the partners are in good agreement; benchmark solutions are then defined for each of the boundary conditions. Whilst the local and average Nusselt numbers based on the entrance temperature do not depend much on conditions applied in the aperture sections, the net fluid flow rates crossing the channel and the characteristics of the recirculation cells are highly influenced. But we proved that these modifications of flow patterns do not alter significantly the fluid flow rates leaving the channel through the exit section

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Experimental and numerical investigation of a phase change material: Thermal-energy storage and release

Joulin

et al. 2011

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Modeling phase change materials behavior in building applications: Comments on material characterization and model validation

et al. 2014

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International audienceIn a recent meeting of IEA’s Annex 23, several members presented their conclusions on the modeling of phase change materials behavior in the context of building applications. These conclusions were in agreement with those of a vast review, involving the survey of more than 250 journal papers, undertaken earlier by the group of École de technologie supérieure. In brief, it can be stated that, at this point, the confidence in reviewed models is too low to use them to predict the future behavior of a building with confidence. Moreover, it was found that overall thermal behaviors of phase change material are poorly known, which by itself creates an intrinsic unknown in any model. Models themselves are most of time suspicious as they are often not tested in a very stringent or exhaustive way. In addition, it also appears that modeling parameters are somewhat too simplified to realistically describe the complete physics needed to predict the real life performance of PCMs added to a building. As a result, steps are now taken to create standard model benchmarks that will improve the confidence of the users. Hopefully, following these efforts, confidence will increase and usage of PCM in buildings should be eased

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Experimental investigation of thermal characteristics of a mortar with or without a micro-encapsulated phase change material

Joulin

Zalewski

Lassue

et al. 2014

Applied Thermal Engineering

112

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Superficial heat transfer by forced convection and radiation in a horizontal channel

Chérif¹,

Joulin²,

Zalewski³

et al. 2009

International Journal of Thermal Sciences

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Modeling a triple-glazed supply-air window

Gloriant

Tittelein

Joulin

et al. 2015

Building and Environment

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A Novel Technique for Experimental Thermophysical Characterization of Phase-Change Materials

et al. 2010

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The major objective of this project is to use phase-change materials (PCMs) as integrated components in passive solar heat recovery systems. The suggested approach involves experimental investigations and characterization of the global behavior of a parallelepiped "material wrap" filled with the PCM. The experimental apparatus permits simultaneous measurements of heat fluxes and temperatures. It also allows imposing and measuring temperatures variations with respect to selected time scales between the two predominant faces of the sample. The instantaneous heat flux measurements allow the determination of the "apparent" or overall heat storage capacities and thermal conductivities of the PCM-in the solid and liquid states-and that of the latent heat of melting. Results were found to be very satisfactory.

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