Unzipped multiwalled carbon nanotube oxide / PEG based phase change composite for latent heat energy storage

Unzipped multiwalled carbon nanotube oxide / PEG based phase change composite for latent heat energy storage

•Synthesized PCMs with unzipped multiwalled carbon nanotube oxides (UMCNOs) and PEG.•Thermal conductivity enhanced by 111.7 % with 6 wt% UMCNOs addition.•Heat storage and release times reduced up to 40 % and 30 %, respectively.•Thermally and chemically reliable for over 100 thermal cycles. Polyethyl...

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Bibliographic Details
Published in:International journal of heat and mass transfer Vol. 220; p. 124908
Main Authors: Chitriv, Shubham P., Dharmadhikari, Ketaki, A., Nithin, Archak, Akshay S., R.P., Vijayakumar, DSouza, Glen Cletus
Format: Journal Article
Language:English
Published: Elsevier Ltd 01-03-2024
Subjects:
Latent heat energy storage
Phase change material
Thermal conductivity
Unzipped multiwalled carbon nanotube oxides
Latent heat energy storage
Thermal conductivity
Phase change material
Unzipped multiwalled carbon nanotube oxides
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Summary:•Synthesized PCMs with unzipped multiwalled carbon nanotube oxides (UMCNOs) and PEG.•Thermal conductivity enhanced by 111.7 % with 6 wt% UMCNOs addition.•Heat storage and release times reduced up to 40 % and 30 %, respectively.•Thermally and chemically reliable for over 100 thermal cycles. Polyethylene glycol (PEG) as a phase change material (PCM) is being explored for latent heat energy storage systems due to its high thermal storage capacity. In the current study, PCM composites were synthesized with different mass fractions of unzipped multiwalled carbon nanotube oxides (UMCNOs) in PEG by melt mixing method. The influence of UMCNOs loading on the thermal conductivity (TC), phase change properties such as temperatures and latent heats of melting and solidifying, thermal energy storage and release rates were investigated. At a loading of 6 mass% of UMCNOs, the TC of the prepared PCM composite increased by 2.1 times as compared to that of pure PEG (0.21 W/m-K). Differential scanning calorimetry analysis showed that as the concentration of UMCNOs increased, there was a slight decrease in the melting temperature. Additionally, the latent heats of melting were found to be reduced by 1.11–9.46 % with the addition of 0.5–6 mass% UMCNOs. Further, the thermal energy storage and release rates were improved with the addition of UMCNOs in PCM composites. In addition, there was negligible change in phase change properties after 100 melting and solidifying cycles of PCM composite, indicating the great prospects for the latent heat energy storage application.
ISSN:0017-9310
1879-2189
DOI:10.1016/j.ijheatmasstransfer.2023.124908