Sustainable Hydrogen Production from Plastic Waste: Optimizing Pyrolysis for a Circular Economy

Sustainable Hydrogen Production from Plastic Waste: Optimizing Pyrolysis for a Circular Economy

Hydrogen is a clean, non-polluting fuel and a key player in decarbonizing the energy sector. Interest in hydrogen production has grown due to climate change concerns and the need for sustainable alternatives. Despite advancements in waste-to-hydrogen technologies, the efficient conversion of mixed p...

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Bibliographic Details
Main Authors: Fiyinfoluwa Joan Medaiyese, Hamid Reza Nasriani, Khalid Khan, Leila Khajenoori
Format: Article
Language:English
Published: MDPI AG 2025-03-01
Series:Hydrogen
Subjects:
hydrogen
pyrolysis
pyrolysis and in-line reforming
steam reforming
plastic wastes
waste plastics
Online Access:https://www.mdpi.com/2673-4141/6/1/15
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Summary:Hydrogen is a clean, non-polluting fuel and a key player in decarbonizing the energy sector. Interest in hydrogen production has grown due to climate change concerns and the need for sustainable alternatives. Despite advancements in waste-to-hydrogen technologies, the efficient conversion of mixed plastic waste via an integrated thermochemical process remains insufficiently explored. This study introduces a novel multi-stage pyrolysis-reforming framework to maximize hydrogen yield from mixed plastic waste, including polyethylene (HDPE), polypropylene (PP), and polystyrene (PS). Hydrogen yield optimization is achieved through the integration of two water–gas shift reactors and a pressure swing adsorption unit, enabling hydrogen production rates of up to 31.85 kmol/h (64.21 kg/h) from 300 kg/h of mixed plastic wastes, consisting of 100 kg/h each of HDPE, PP, and PS. Key process parameters were evaluated, revealing that increasing reforming temperature from 500 °C to 1000 °C boosts hydrogen yield by 83.53%, although gains beyond 700 °C are minimal. Higher reforming pressures reduce hydrogen and carbon monoxide yields, while a steam-to-plastic ratio of two enhances production efficiency. This work highlights a novel, scalable, and thermochemically efficient strategy for valorizing mixed plastic waste into hydrogen, contributing to circular economy goals and sustainable energy transition.
ISSN:2673-4141

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