Pyrolytic Conversion of Plastic Waste to Value-Added Products and Fuels: A Review

Plastic production has been rapidly growing across the world and, at the end of their use, many of the plastic products become waste disposed of in landfills or dispersed, causing serious environmental and health issues. From a sustainability point of view, the conversion of plastic waste to fuels o...

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Main Authors: Sadegh Papari, Hanieh Bamdad, Franco Berruti
Format: Article
Language:English
Published: MDPI AG 2021-05-01
Series:Materials
Subjects:
Online Access:https://www.mdpi.com/1996-1944/14/10/2586
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spelling doaj-981f3625b83e485ea244199547bf71ac2021-06-01T00:10:49ZengMDPI AGMaterials1996-19442021-05-01142586258610.3390/ma14102586Pyrolytic Conversion of Plastic Waste to Value-Added Products and Fuels: A ReviewSadegh Papari0Hanieh Bamdad1Franco Berruti2Department of Chemical and Biochemical Engineering, Institute for Chemicals and Fuels from Alternative Resources (ICFAR), Western University, London, ON N6A 3K7, CanadaDepartment of Chemical and Biochemical Engineering, Institute for Chemicals and Fuels from Alternative Resources (ICFAR), Western University, London, ON N6A 3K7, CanadaDepartment of Chemical and Biochemical Engineering, Institute for Chemicals and Fuels from Alternative Resources (ICFAR), Western University, London, ON N6A 3K7, CanadaPlastic production has been rapidly growing across the world and, at the end of their use, many of the plastic products become waste disposed of in landfills or dispersed, causing serious environmental and health issues. From a sustainability point of view, the conversion of plastic waste to fuels or, better yet, to individual monomers, leads to a much greener waste management compared to landfill disposal. In this paper, we systematically review the potential of pyrolysis as an effective thermochemical conversion method for the valorization of plastic waste. Different pyrolysis types, along with the influence of operating conditions, e.g., catalyst types, temperature, vapor residence time, and plastic waste types, on yields, quality, and applications of the cracking plastic products are discussed. The quality of pyrolysis plastic oil, before and after upgrading, is compared to conventional diesel fuel. Plastic oil yields as high as 95 wt.% can be achieved through slow pyrolysis. Plastic oil has a heating value approximately equivalent to that of diesel fuel, i.e., 45 MJ/kg, no sulfur, a very low water and ash content, and an almost neutral pH, making it a promising alternative to conventional petroleum-based fuels. This oil, as-is or after minor modifications, can be readily used in conventional diesel engines. Fast pyrolysis mainly produces wax rather than oil. However, in the presence of a suitable catalyst, waxy products further crack into oil. Wax is an intermediate feedstock and can be used in fluid catalytic cracking (FCC) units to produce fuel or other valuable petrochemical products. Flash pyrolysis of plastic waste, performed at high temperatures, i.e., near 1000 °C, and with very short vapor residence times, i.e., less than 250 ms, can recover up to 50 wt.% ethylene monomers from polyethylene waste. Alternatively, pyrolytic conversion of plastic waste to olefins can be performed in two stages, with the conversion of plastic waste to plastic oil, followed by thermal cracking of oil to monomers in a second stage. The conversion of plastic waste to carbon nanotubes, representing a higher-value product than fuel, is also discussed in detail. The results indicate that up to 25 wt.% of waste plastic can be converted into carbon nanotubes.https://www.mdpi.com/1996-1944/14/10/2586pyrolysisplastic wastecarbon nanotubesplastic oilfuelsmonomer recovery
collection DOAJ
language English
format Article
sources DOAJ
author Sadegh Papari
Hanieh Bamdad
Franco Berruti
spellingShingle Sadegh Papari
Hanieh Bamdad
Franco Berruti
Pyrolytic Conversion of Plastic Waste to Value-Added Products and Fuels: A Review
Materials
pyrolysis
plastic waste
carbon nanotubes
plastic oil
fuels
monomer recovery
author_facet Sadegh Papari
Hanieh Bamdad
Franco Berruti
author_sort Sadegh Papari
title Pyrolytic Conversion of Plastic Waste to Value-Added Products and Fuels: A Review
title_short Pyrolytic Conversion of Plastic Waste to Value-Added Products and Fuels: A Review
title_full Pyrolytic Conversion of Plastic Waste to Value-Added Products and Fuels: A Review
title_fullStr Pyrolytic Conversion of Plastic Waste to Value-Added Products and Fuels: A Review
title_full_unstemmed Pyrolytic Conversion of Plastic Waste to Value-Added Products and Fuels: A Review
title_sort pyrolytic conversion of plastic waste to value-added products and fuels: a review
publisher MDPI AG
series Materials
issn 1996-1944
publishDate 2021-05-01
description Plastic production has been rapidly growing across the world and, at the end of their use, many of the plastic products become waste disposed of in landfills or dispersed, causing serious environmental and health issues. From a sustainability point of view, the conversion of plastic waste to fuels or, better yet, to individual monomers, leads to a much greener waste management compared to landfill disposal. In this paper, we systematically review the potential of pyrolysis as an effective thermochemical conversion method for the valorization of plastic waste. Different pyrolysis types, along with the influence of operating conditions, e.g., catalyst types, temperature, vapor residence time, and plastic waste types, on yields, quality, and applications of the cracking plastic products are discussed. The quality of pyrolysis plastic oil, before and after upgrading, is compared to conventional diesel fuel. Plastic oil yields as high as 95 wt.% can be achieved through slow pyrolysis. Plastic oil has a heating value approximately equivalent to that of diesel fuel, i.e., 45 MJ/kg, no sulfur, a very low water and ash content, and an almost neutral pH, making it a promising alternative to conventional petroleum-based fuels. This oil, as-is or after minor modifications, can be readily used in conventional diesel engines. Fast pyrolysis mainly produces wax rather than oil. However, in the presence of a suitable catalyst, waxy products further crack into oil. Wax is an intermediate feedstock and can be used in fluid catalytic cracking (FCC) units to produce fuel or other valuable petrochemical products. Flash pyrolysis of plastic waste, performed at high temperatures, i.e., near 1000 °C, and with very short vapor residence times, i.e., less than 250 ms, can recover up to 50 wt.% ethylene monomers from polyethylene waste. Alternatively, pyrolytic conversion of plastic waste to olefins can be performed in two stages, with the conversion of plastic waste to plastic oil, followed by thermal cracking of oil to monomers in a second stage. The conversion of plastic waste to carbon nanotubes, representing a higher-value product than fuel, is also discussed in detail. The results indicate that up to 25 wt.% of waste plastic can be converted into carbon nanotubes.
topic pyrolysis
plastic waste
carbon nanotubes
plastic oil
fuels
monomer recovery
url https://www.mdpi.com/1996-1944/14/10/2586
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