Enhancement of thermal properties of bio-based microcapsules intended for textile applications

Enhancement of thermal properties of bio-based microcapsules intended for textile applications

The thermal properties of bio-based phase change material (PCM) microcapsules and their separate components, core and shell, were investigated considering the influence of used thermal enhancer. As a core, bio-based PCM, capric acid (CA), was used. Biodegradable material, such as polylactic acid (PL...

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Main Authors: Skurkytė-Papievienė Virginija, Abraitienė Aušra, Sankauskaitė Audronė, Rubežienė Vitalija, Dubinskaitė Kristina
Format: Article
Language:English
Published: De Gruyter 2020-06-01
Series:Open Chemistry
Subjects:
textiles
bio-based pcm
carbon nanotubes
heat storage
heat release
differential scanning calorimetry
Online Access:https://doi.org/10.1515/chem-2020-0064
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spelling doaj-2012d18d2b244ebba870ff4f3c5ff8352021-09-06T19:19:37ZengDe GruyterOpen Chemistry2391-54202020-06-0118166968010.1515/chem-2020-0064chem-2020-0064Enhancement of thermal properties of bio-based microcapsules intended for textile applicationsSkurkytė-Papievienė Virginija0Abraitienė Aušra1Sankauskaitė Audronė2Rubežienė Vitalija3Dubinskaitė Kristina4Department of Textiles Technologies, Center for Physical Sciences and Technology, Demokratu str. 53, LT-48485 Kaunas, LithuaniaDepartment of Textiles Technologies, Center for Physical Sciences and Technology, Demokratu str. 53, LT-48485 Kaunas, LithuaniaDepartment of Textiles Technologies, Center for Physical Sciences and Technology, Demokratu str. 53, LT-48485 Kaunas, LithuaniaDepartment of Textiles Physical – Chemical Testing, Center for Physical Sciences and Technology, Demokratu str. 53, LT-48485 Kaunas, LithuaniaDepartment of Textiles Physical – Chemical Testing, Center for Physical Sciences and Technology, Demokratu str. 53, LT-48485 Kaunas, LithuaniaThe thermal properties of bio-based phase change material (PCM) microcapsules and their separate components, core and shell, were investigated considering the influence of used thermal enhancer. As a core, bio-based PCM, capric acid (CA), was used. Biodegradable material, such as polylactic acid (PLA), was used as a shell. To improve the thermal conductivity of PLA/CA microcapsules, the multiwall carbon nanotubes (MWCNTs) were used as a thermal enhancer. Composites of PCM with different concentrations of MWCNT as well as composites of PLA with these carbon compounds were prepared and investigated to assess how MWCNT influences the thermal conductivity of the core and the shell. The heat storage and release capacity, as well as the phase change temperatures of CA/MWCNT composites and manufactured PCM microcapsules, were determined using differential scanning calorimetry. To evaluate the thermal conductivity of prepared composites and to compare it with the conductivity of pure materials (without MWCNT), their thermal resistance was measured using the guarded-hotplate test method. To obtain the supplementary information and to assess the dynamic behavior of used PCM during the temperature changes, another technique, such as monitoring of a cold/hot plate with an IR camera, was used. The results of these measurements showed that introduced MWCNT increases the thermal conductivity of PCM used for the core and the conductivity of films prepared from PLA. Consequently, with reference to the results obtained, it could be stated that the introduction of MWCNT into PLA/CA microcapsules improved the thermal properties of these microcapsules. However, it was determined that too large concentration of MWCNT reduces an enthalpy of melting and crystallization of tested PCM and PCM microcapsules. Therefore, during the investigation, an optimal concentration of MWCNT additives has been determined.https://doi.org/10.1515/chem-2020-0064textilesbio-based pcmcarbon nanotubesheat storageheat releasedifferential scanning calorimetry
collection DOAJ
language English
format Article
sources DOAJ
author Skurkytė-Papievienė Virginija
Abraitienė Aušra
Sankauskaitė Audronė
Rubežienė Vitalija
Dubinskaitė Kristina
spellingShingle Skurkytė-Papievienė Virginija
Abraitienė Aušra
Sankauskaitė Audronė
Rubežienė Vitalija
Dubinskaitė Kristina
Enhancement of thermal properties of bio-based microcapsules intended for textile applications
Open Chemistry
textiles
bio-based pcm
carbon nanotubes
heat storage
heat release
differential scanning calorimetry
author_facet Skurkytė-Papievienė Virginija
Abraitienė Aušra
Sankauskaitė Audronė
Rubežienė Vitalija
Dubinskaitė Kristina
author_sort Skurkytė-Papievienė Virginija
title Enhancement of thermal properties of bio-based microcapsules intended for textile applications
title_short Enhancement of thermal properties of bio-based microcapsules intended for textile applications
title_full Enhancement of thermal properties of bio-based microcapsules intended for textile applications
title_fullStr Enhancement of thermal properties of bio-based microcapsules intended for textile applications
title_full_unstemmed Enhancement of thermal properties of bio-based microcapsules intended for textile applications
title_sort enhancement of thermal properties of bio-based microcapsules intended for textile applications
publisher De Gruyter
series Open Chemistry
issn 2391-5420
publishDate 2020-06-01
description The thermal properties of bio-based phase change material (PCM) microcapsules and their separate components, core and shell, were investigated considering the influence of used thermal enhancer. As a core, bio-based PCM, capric acid (CA), was used. Biodegradable material, such as polylactic acid (PLA), was used as a shell. To improve the thermal conductivity of PLA/CA microcapsules, the multiwall carbon nanotubes (MWCNTs) were used as a thermal enhancer. Composites of PCM with different concentrations of MWCNT as well as composites of PLA with these carbon compounds were prepared and investigated to assess how MWCNT influences the thermal conductivity of the core and the shell. The heat storage and release capacity, as well as the phase change temperatures of CA/MWCNT composites and manufactured PCM microcapsules, were determined using differential scanning calorimetry. To evaluate the thermal conductivity of prepared composites and to compare it with the conductivity of pure materials (without MWCNT), their thermal resistance was measured using the guarded-hotplate test method. To obtain the supplementary information and to assess the dynamic behavior of used PCM during the temperature changes, another technique, such as monitoring of a cold/hot plate with an IR camera, was used. The results of these measurements showed that introduced MWCNT increases the thermal conductivity of PCM used for the core and the conductivity of films prepared from PLA. Consequently, with reference to the results obtained, it could be stated that the introduction of MWCNT into PLA/CA microcapsules improved the thermal properties of these microcapsules. However, it was determined that too large concentration of MWCNT reduces an enthalpy of melting and crystallization of tested PCM and PCM microcapsules. Therefore, during the investigation, an optimal concentration of MWCNT additives has been determined.
topic textiles
bio-based pcm
carbon nanotubes
heat storage
heat release
differential scanning calorimetry
url https://doi.org/10.1515/chem-2020-0064
work_keys_str_mv AT skurkytepapievienevirginija enhancementofthermalpropertiesofbiobasedmicrocapsulesintendedfortextileapplications
AT abraitieneausra enhancementofthermalpropertiesofbiobasedmicrocapsulesintendedfortextileapplications
AT sankauskaiteaudrone enhancementofthermalpropertiesofbiobasedmicrocapsulesintendedfortextileapplications
AT rubezienevitalija enhancementofthermalpropertiesofbiobasedmicrocapsulesintendedfortextileapplications
AT dubinskaitekristina enhancementofthermalpropertiesofbiobasedmicrocapsulesintendedfortextileapplications
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