Capric-stearic acid mixture impregnated carbonized waste sugar beet pulp as leak-resistive composite phase change material with effective thermal conductivity and thermal energy storage performance

The present investigation aims to develop a potential composite phase change material (PCM) with leak-resistive and high thermal conductivity. Sugar beet pulp (CSBP) as an industrial waste was carbonized to produce a porous framework and used for solving leakage issue and boosting thermal conductivi...

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Bibliographic Details
Published in:Energy (Oxford) 2022-05, Vol.247, p.123501, Article 123501
Main Authors: Sarı, Ahmet, Hekimoğlu, Gökhan, Karabayır, Yasemin, Sharma, R.K., Arslanoğlu, Hasan, Gencel, Osman, Tyagi, V.V.
Format: Article
Language:English
Subjects:
Capric acid
Carbonized sugar beet pulp
Composite PCM
Eutectic mixture
Stearic acid
Thermal conductivity
Thermal energy storage
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Summary:The present investigation aims to develop a potential composite phase change material (PCM) with leak-resistive and high thermal conductivity. Sugar beet pulp (CSBP) as an industrial waste was carbonized to produce a porous framework and used for solving leakage issue and boosting thermal conductivity of capric-stearic acid eutectic mixture (CSEM) used as PCM. FTIR and XRD results proved that the integration of CSEM and CSBP was carried out physically. The SEM analysis demonstrated that the CSEM was well uniformly impregnated within the pores of CSBP scaffold. DSC analysis revealed that the CSBP/CSEM (70 wt%) composite showed melting enthalpy and temperature as 117 J/g and 24 °C. The TGA measurements demonstrated that the produced composite was thermally stable. The incorporation of CSEM with CSBP leaded to a 79% increase in its thermal conductivity and this improvement was proved by comparing heating-cooling periods of CSEM and the composite PCM. The latent heat of the composite PCM was reduced less than 3% as its melting temperature was almost constant after 1000 thermal cycles. All findings of this work disclosed that the developed CSBP/CSEM as cost-effective and environmentally friendly composite PCM can be handled potential TES material for temperature controlling of buildings. •CSBP was evaluated for avoiding leakage problem and boosting thermal conductivity of CSEM used as PCM.•High amount (70%) of molten CSEM was successfully impregnated into pores of CSBP.•CSBP/CSEM (70 wt%) showed melting enthalpy and temperature as 117 J/g and 24 °C.•The integration of CSEM with CSBP leaded to a significantly increase in its thermal conductivity as 79%.•CSBP/CSEM can be evaluated as cost-effective and eco-friendly friendly composite PCM for temperature controlling in buildings.
ISSN:0360-5442
DOI:10.1016/j.energy.2022.123501