Experimental Study on Two-Step Pyrolysis of Automotive Shredder Residue
Authors: Letizia Marchetti, Federica Annunzi, Federico Fiorini, Cristiano Nicolella
Abstract:
Automotive shredder residue (ASR) is a mixture of waste that makes up 20-25% of end-of-life vehicles. For many years, ASR was commonly disposed of in landfills or incinerated, causing serious environmental problems. Nowadays, thermochemical treatments are a promising alternative, although the heterogeneity of ASR still poses some challenges. One of the emerging thermochemical treatments for ASR is pyrolysis, which promotes the decomposition of long polymeric chains by providing heat in the absence of an oxidizing agent. In this way, pyrolysis promotes the conversion of ASR into solid, liquid, and gaseous phases. This work aims to improve the performance of a two-step pyrolysis process. After the characterization of the analysed ASR, the focus is on determining the effects of residence time on product yields and gas composition. A batch experimental setup that reproduces the entire process was used. The setup consists of three sections: the pyrolysis section (made of two reactors), the separation section, and the analysis section. Two different residence times were investigated to find suitable conditions for the first sample of ASR. These first tests showed that the products obtained were more sensitive to residence time in the second reactor. Indeed, slightly increasing residence time in the second reactor managed to raise the yield of gas and carbon residue and decrease the yield of liquid fraction. Then, to test the versatility of the setup, the same conditions were applied to a different sample of ASR coming from a different chemical plant. The comparison between the two ASR samples shows that similar product yields and compositions are obtained using the same setup.
Keywords: Automotive shredder residue, experimental tests, heterogeneity, product yields, two-step pyrolysis.
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[1] R. Cossu, “Review of Italian experience on automotive shredder residue characterization and management,” in Waste Management, volume 34, Issue 10, 2014, pp. 1752-1762.
[2] S. Yang, F. Zhong, M. Wang, S. Bai, Q. Wang, “Recycling of automotive shredder residue by solid state shear milling technology,” in Journal of industrial and engineering chemistry, volume 57, 2018, pp.143-153.
[3] S. Galvagno, F. Fortuna, G. Cornacchia, S. Casu, T. Coppola, V.K. Sharma, “Pyrolysis process for treatment of automobile shredder residues: preliminary experimental results,” in Energy Conversion and Management, volume 42, 2001, pp. 573–586.
[4] A. Antelava, N. Jablonska, A. Constantinou, G. Manos, S.A. Salaudeen, A. Dutta, S. Al-Salem, “Energy Potential of Plastic Waste Valorization: A Short Comparative Assessment of Pyrolysis versus Gasification,” in Energy Fuels, volume 35, 2021.
[5] Q. Xiong, Y. Zhang, Y. Huang, J. Li, W. Zhang, “Fundamental study of the integrated process of heavy oil pyrolysis and coke gasification. Part Ⅰ: Effect of CO and H2 in syngas atmosphere on heavy oil pyrolysis,” in Fuel, volume 324, 2021.
[6] M. Zolezzi, C. Nicolella, S. Ferrara, C. Iacobucci, M. Rovatti, “Conventional and fast pyrolysis of automobile shredder residues (ASR),” in Waste Management, volume 24, 2004, pp. 691–699.
[7] J. Solar, I. de Marco, B.M. Caballero, A. Lopez-Urionabarrenechea, N. Rodriguez, I. Agirre, A. Adrados, “Influence of temperature and residence time in the pyrolysis of woody biomass waste in a continuous screw reactor,” in Biomass and Bioenergy, volume 95, 2016, pp. 416-423.
[8] S. Ma, H. Leong, L. He, X. Ze, H. Han, L. Jiang, W. Yi, S. Hu, S. Su, J. Xiang, “Effects of pressure and residence time on limonene production in waste tires pyrolysis process,” in Journal of Analytical and Applied Pyrolysis, volume 151, 2020.
[9] T. Shudo, T. Nagano, M. Kobayashi, “Combustion characteristics of waste-pyrolysis gases in an internal combustion engine,” in International Journal of Automotive Technology,” volume 4, No. 1, 2003 pp. 1−8.
[10] V. Sandhya Kuruvalan, K. Mahmud Arman, B. Sankar, “A Study on Pyrolysis of Pretreated Automotive Shredder Residue—Thermochemical Calculations and Experimental Work,” in Frontiers in Sustainability, volume 3, 2022.
[11] V. Sandhya Kuruvalan, K. Mahmud Arman, B. Sankar, “Insights into the options of energy and metal recovery from automotive shredder residue: A review,” in Resources, Conservation & Recycling Advances, volume 15, 2022.