Thermal characterization of bio-based phase changing materials in decorative wood-based panels for thermal energy storage

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英文篇名：Thermal characterization of bio-based phase changing materials in decorative wood-based panels for thermal energy storage 作者：Damien ; Mathis ; Pierre ; Blanchet ; Véronic ; Landry ; Philippe ; Lagière 英文作者：Damien Mathis;Pierre Blanchet;Véronic Landry;Philippe Lagière;NSERC Industrial Research Chair on Ecoresponsible Wood Construction(CIRCERB) , Laval University;Engineering and Mechanics Institute, University of Bordeaux, Avenue D'Aquitaine; 英文关键词：PCM;;Wood;;Biosourced;;Fatty acids;;DHFMA 中文刊名：GENE 英文刊名：绿色能源与环境(英文) 机构：NSERC Industrial Research Chair on Ecoresponsible Wood Construction(CIRCERB) , Laval University;Engineering and Mechanics Institute, University of Bordeaux, Avenue D'Aquitaine; 出版日期：2019-01-15 出版单位：Green Energy & Environment 年：2019 期：v.4 基金：Natural Sciences and Engineering Research Council of Canada for the financial support through its ICP and CRD programs(IRCPJ 461745-12 and RDCPJ 445200-12)as well as the industrial partners of the NSERC industrial chair on eco-responsible wood construction(CIRCERB) 语种：英文; 页：GENE201901007 页数：10 CN：01 ISSN：10-1418/TK 分类号：60-69

摘要

Decorative wood panels containing pouches of bio-based phase changing materials(PCMs) were prepared. Three different PCM mixtures were used: a blend of capric and lauric acids as well as two commercial products, Puretemp?20 and Puretemp?23(Puretemp). The panels consist of engraved Medium Density Fiberboard(MDF) filled with a plastic pouch filled with PCM. High density fiberboard(HDF) was used on top of the panels to enclose the PCM pouches. PCM mixtures were first tested by differential scanning calorimetry(DSC). Phase change temperature and total heat storage of the panels were measured for both fusion and solidification with a Dynamic Heat-Flow Meter Apparatus(DHFMA). DSC and DHFMA results were compared, allowing a better understanding of results gathered from these two techniques. DSC calibration has been revealed important when assessing PCMs. The panels present a phase change temperature and a latent heat storage suitable for buildings applications. The panel made with Puretemp?23 presented the highest energy, with 57.1 J g~(-1). Thermal cycling was conducted on the panels to investigate thermal reliability, which revealed small modifications of thermal properties for two products. For all cases, latent heat was found stable. Hygro-mechanical behavior of the panels was also evaluated as these where designed to be esthetic decorative panels. This study exposes the potential of a new type of wood-based panels loaded with PCM for thermal energy storage and brings overall knowledge about PCM products thermal characterization.
        Decorative wood panels containing pouches of bio-based phase changing materials(PCMs) were prepared. Three different PCM mixtures were used: a blend of capric and lauric acids as well as two commercial products, Puretemp?20 and Puretemp?23(Puretemp). The panels consist of engraved Medium Density Fiberboard(MDF) filled with a plastic pouch filled with PCM. High density fiberboard(HDF) was used on top of the panels to enclose the PCM pouches. PCM mixtures were first tested by differential scanning calorimetry(DSC). Phase change temperature and total heat storage of the panels were measured for both fusion and solidification with a Dynamic Heat-Flow Meter Apparatus(DHFMA). DSC and DHFMA results were compared, allowing a better understanding of results gathered from these two techniques. DSC calibration has been revealed important when assessing PCMs. The panels present a phase change temperature and a latent heat storage suitable for buildings applications. The panel made with Puretemp?23 presented the highest energy, with 57.1 J g~(-1). Thermal cycling was conducted on the panels to investigate thermal reliability, which revealed small modifications of thermal properties for two products. For all cases, latent heat was found stable. Hygro-mechanical behavior of the panels was also evaluated as these where designed to be esthetic decorative panels. This study exposes the potential of a new type of wood-based panels loaded with PCM for thermal energy storage and brings overall knowledge about PCM products thermal characterization.

引文

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