Experimental evaluation of porosity, axial and radial thermal conductivity, of an adsorbent material composed by mixture of activated carbon, expanded graphite and lithium chloride

•Porosity, axial-radial thermal conductivity of an adsorbent mixture are obtained.•Particle size, compaction pressure and composition are the experimental factors.•Axial thermal conductivity is 10 times greater than radial one, regardless of factors.•Maximum values for axial and radial thermal condu...

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Bibliographic Details
Published in:Applied thermal engineering 2019-03, Vol.150, p.456-463
Main Authors: Carmona, Mauricio, Pérez, Eduar, Palacio, Mario
Format: Article
Language:English
Subjects:
Activated carbon
Adsorbents
Composite materials
Design of experiments
Design optimization
Expanded graphite
Graphite
Heat conductivity
Heat transfer
Hot wire method
Lithium chloride
Mixture adsorbent material
Porosity
Thermal conductivity
Thermodynamic properties
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Summary:•Porosity, axial-radial thermal conductivity of an adsorbent mixture are obtained.•Particle size, compaction pressure and composition are the experimental factors.•Axial thermal conductivity is 10 times greater than radial one, regardless of factors.•Maximum values for axial and radial thermal conductivity are 76.5 and 13.8 W/m K. In this study, an adsorbent material made up of a mixture of activated carbon, expanded graphite and lithium chloride, is proposed to evaluate its thermal properties. Ratio effect between mixing components, component particle size, and compaction pressure on porosity and thermal conductivity of composite material was experimentally evaluated. Axial and radial thermal conductivity were evaluated by ASTM C177-13 standard using the hot plate and hot wire method for the respective axial and radial conductivities. Experimental results indicate that the highest porosity reaches 0.78 and is produced with a 70% mixing ratio of activated carbon mass, 10% of LiCl mass, and 20% of expanded graphite mass. With the levels used in experimental design, axial and radial thermal conductivity obtain maximum values of 51.2 W/m K and 11.9 W/m K, respectively. After optimization process based on design of experiments for mixtures, axial and radial conductivity reach their highest values of 76.5 W/m K and 13.8 W/m K, respectively, when mixture is elaborated with a proportion of 30% activated carbon, 40% expanded graphite and 30% Lithium Chloride. This study shows that conductivity results do not vary significantly due to tests temperature.
ISSN:1359-4311
1873-5606
DOI:10.1016/j.applthermaleng.2019.01.021