Experimental and Numerical-Driven Prediction of Automotive Shredder Residue Pyrolysis Pathways toward Gaseous Products

Rafał Ślefarski; Joanna Jójka; Paweł Czyżewski; Michał Gołębiewski; Radosław Jankowski; Jarosław Markowski; Aneta Magdziarz

doi:10.3390/en14061779

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Title

Experimental and Numerical-Driven Prediction of Automotive Shredder Residue Pyrolysis Pathways toward Gaseous Products

Authors

Rafał Ślefarski (WIŚiE) ^{[ 1 ][ 2.10 ][ P ]}
Joanna Jójka (WIŚiE) ^{[ 1 ][ 2.10 ][ P ]}
Paweł Czyżewski (WIŚiE) ^{[ 1 ][ 2.10 ][ P ]}
Michał Gołębiewski (WIŚiE) ^{[ 1 ][ 2.10 ][ P ]}
Radosław Jankowski (WIŚiE) ^{[ 1 ][ 2.10 ][ P ]}
Jarosław Markowski (WIM) ^{[ 2 ][ 2.9 ][ P ]}
Aneta Magdziarz

^{[ 1 ]} Instytut Energetyki Cieplnej, Wydział Inżynierii Środowiska i Energetyki, Politechnika Poznańska | ^{[ 2 ]} Instytut Konstrukcji Maszyn, Wydział Inżynierii Mechanicznej, Politechnika Poznańska | ^{[ P ]} employee

Scientific discipline (Law 2.0)

[2.9] Mechanical engineering
[2.10] Environmental engineering, mining and energy

Year of publication

2021

Published in

Energies

Journal year: 2021 | Journal volume: vol. 14 | Journal number: no. 6

Article type

scientific article

Publication language

english

Keywords

EN

pyrolysis of RDF
thermal pyrolysis of plastics
ASR recycling
numerical modelling of pyrolysis process
thermogravimetric analysis

Abstract

EN There has been a gradual increase in the field of parts recovery from cars that are withdrawn from use. However, the disposal of automotive shredder residue (ASR) still remains a significant problem. ASR is refuse derived fuel (RDF), which contains mainly plastics, fiber sponges, and rubbers in different proportions, and therefore a thermal treatment of selected waste samples is applied. The presented research includes thermogravimetry (TG) analysis and differential thermogravimetric (DTG) analysis, as well as a proximate and an ultimate analysis of the ASR samples. The obtained results were processed and used as an input for modelling. The numerical calculations focused on the identification of the ASR’s average composition, the raw pyrolysis process product, its dry pyrolytic gas composition, and the combustible properties of the pyrolytic gases. The TGA analysis with three heating rate levels covered the temperature range from ambient to 800 °C. The thermal decomposition of the studied samples was in three stages confirmed with three peaks observed at the temperatures 280, 470, and 670 °C. The amount of solid residue grew with the heating rates and was in the range of 27–32 wt%. The numerical calculation of the pyrolysis process showed that only 0.46 kg of dry gas were formed from 1 kg of ASR. The gas yield increased with the rising temperature, and, at the same time, its calorific value decreased from 19.22 down to 14.16 MJ/m3. This is due to the decomposition of C6+ hydrocarbons and the promotion of CO formation. The thermodynamic parameters of the combustion process for a pyrolytic gas air mixture, such as the adiabatic flame temperature and laminar flame speed, were higher than for methane and were, respectively, 2073 °C and 1.02 m/s.

Pages (from - to)

1779-1 - 1779-15

DOI

10.3390/en14061779

URL

https://www.mdpi.com/1996-1073/14/6/1779

Comments

article number: 1779

License type

CC BY (attribution alone)

Open Access Mode

open journal