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Utilising Polyester and Steel Slag-Derived Metal/Carbon Composites as Catalysts in Biodiesel Productionopen access

Authors
Lee, SangyoonKim, MinyoungKim, Jee YoungSong, HocheolNam, In-HyunKwon, Eilhann E.
Issue Date
Nov-2024
Publisher
John Wiley & Sons Inc.
Keywords
biodiesel; metal/carbon composite; steel slag; textile waste; transesterification; waste valorisation
Citation
International Journal of Energy Research, v.2024, no.1, pp 1 - 13
Pages
13
Indexed
SCIE
SCOPUS
Journal Title
International Journal of Energy Research
Volume
2024
Number
1
Start Page
1
End Page
13
URI
https://scholarworks.bwise.kr/hanyang/handle/2021.sw.hanyang/212154
DOI
10.1155/2024/1925113
ISSN
0363-907X
1099-114X
Abstract
Synthetic textiles such as polyesters are essential for daily life. However, large-scale production generates large amounts of waste. This study introduces a new approach for valorising polyester textile waste (PTW) by transforming it into a catalyst for biodiesel production via pyrolysis. Specifically, a metal/carbon composite (PTW + steel slag [SS] composite—PSC) with enhanced catalytic properties was prepared by pyrolysing PTW with SS. The alkaline metals in SS facilitate the carbonisation of PTW via decarboxylation, resulting in a PSC rich in carbon, iron, and alkaline compounds. This composite featured mesopores that were larger than the micropores (MPs) typically found in PTW char. The use of porous material (silica) in thermally induced transesterification has been proven to be an efficient method for biodiesel production, achieving a yield of 97.20 wt.% in 1 min (faster than the 93.82 wt.% yields in 60 min observed from conventional alkali-catalysed transesterification). However, the high reaction temperature (≥ 360°C) poses economic/technical challenges. To overcome this, PSC has been employed as a catalyst in thermally induced transesterification, leveraging its mesoporous structure and high alkaline content, particularly calcium oxide. The PSC achieved a biodiesel yield of 98.10 wt.% at a markedly lower reaction temperature of 120°C within 1 min. This performance was not attainable using silica or PTW char under similar conversion conditions. These findings highlight the potential of PSC produced through the pyrolysis of PTW and SS as effective catalysts for biodiesel production. This process is a promising strategy for converting waste into valuable resources and mitigating the environmental impacts associated with polyester waste.
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Song, Hocheol
COLLEGE OF ENGINEERING (DEPARTMENT OF EARTH RESOURCES AND ENVIRONMENTAL ENGINEERING)
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