A comprehensive experimental investigation of plastic waste pyrolysis oil quality and its dependence on the plastic waste composition

A comprehensive experimental investigation of plastic waste pyrolysis oil quality and its dependence on the plastic waste composition

Pyrolysis of plastic packaging waste yields a liquid product that can be processed in steam crackers producing light olefins and hence closing the loop towards new virgin plastics. However, there is a lack of knowledge on how the plastic waste composition affects the pyrolysis oil quality regarding...

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Bibliographic Details
Published in:Fuel processing technology Vol. 227; p. 107090
Main Authors: Kusenberg, Marvin, Zayoud, Azd, Roosen, Martijn, Thi, Hang Dao, Abbas-Abadi, Mehrdad Seifali, Eschenbacher, Andreas, Kresovic, Uros, De Meester, Steven, Van Geem, Kevin M.
Format: Journal Article
Language:English
Published: Amsterdam Elsevier B.V 01-03-2022
Elsevier Science Ltd
Subjects:
Alkenes
Chlorine
Contaminants
Gas chromatography
Packaging
Paraffins
Plastic waste
Polyethylenes
Polyolefins
Pyrolysis
Steam cracking
Thermochemical recycling
Two dimensional analysis
Two-dimensional gas chromatography
Pyrolysis
Thermochemical recycling
Contaminants
Steam cracking
Two-dimensional gas chromatography
Plastic waste
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Summary:Pyrolysis of plastic packaging waste yields a liquid product that can be processed in steam crackers producing light olefins and hence closing the loop towards new virgin plastics. However, there is a lack of knowledge on how the plastic waste composition affects the pyrolysis oil quality regarding hydrocarbon composition and contaminant concentrations. The associated uncertainty is a key reason why thermochemical recycling of contaminated plastic waste is not yet industrially established. In this study, post-consumer plastic packaging waste fractions, namely mixed polyolefins (MPO), polyethylene (PE), and polypropylene (PP) were processed in a continuous pilot-scale pyrolysis unit and the pyrolysis oils subsequently characterized using advanced analytical techniques such as two-dimensional gas chromatography. Substantial amounts of branched olefins (~63 wt%) and diolefins (~20 wt%) were detected in the pyrolysis oil of PP-rich waste, while PE-rich waste produced high amounts of linear paraffins (~34 wt%) and olefins (~26 wt%). Furthermore, significant amounts of nitrogen, oxygen, chlorine, iron, sodium and silicon were detected in the pyrolysis oils exceeding feedstock specifications for industrial steam crackers by orders of magnitude. The results show that next to improved waste sorting and separation processes, pre- and post-treatment techniques are required to produce pyrolysis products suitable for chemical processing. [Display omitted] •Pyrolysis of polyolefinic post-consumer plastic packaging waste.•Comprehensive two-dimensional gas chromatography coupled to various detectors.•PP-pyrolysis yields highly branched olefins, PE-pyrolysis mostly linear compounds.•Nitrogen, oxygen, chlorine, iron, sodium and silicon most important contaminants.•Upgrading or dilution needed when using pyrolysis oils as steam cracker feedstocks.
ISSN:0378-3820
1873-7188
DOI:10.1016/j.fuproc.2021.107090