Effective waste management through Co-pyrolysis of EFB and tire waste: Mechanistic and synergism analysis

Driven by the need for solutions to address the global issue of waste accumulation from human activities and industries, this study investigates the thermal behaviors of empty fruit bunch (EFB), tyre waste (TW), and their blends during co-pyrolysis, exploring a potential method to convert waste into...

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Veröffentlicht in:Journal of environmental management 2024-09, Vol.368, p.122172, Article 122172
Hauptverfasser: Mong, Guo Ren, Liew, Chin Seng, Idris, Rubia, Woon, Kok Sin, Chong, William Woei Fong, Chiong, Meng Choung, Lim, Jun Wei, Chong, Cheng Tung, Lee, Chew Tin, Wong, Keng Yinn, Ng, Andrew Kay Lup
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Sprache:eng
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Zusammenfassung:Driven by the need for solutions to address the global issue of waste accumulation from human activities and industries, this study investigates the thermal behaviors of empty fruit bunch (EFB), tyre waste (TW), and their blends during co-pyrolysis, exploring a potential method to convert waste into useable products. The kinetics mechanism and thermodynamics properties of EFB and TW co-pyrolysis were analysed through thermogravimetric analysis (TGA). The rate of mass loss for the blend of EFB:TW at a 1:3 mass ratio shows an increase of around 20% due to synergism. However, the blend's average activation energy is higher (298.64 kJ/mol) when compared with single feedstock pyrolysis (EFB = 257.29 kJ/mol and TW = 252.92 kJ/mol). The combination of EFB:TW at a 3:1 ratio does not result in synergistic effects on mass loss. However, a lower activation energy is reported, indicating the decomposition process can be initiated at a lower energy requirement. The reaction model that best describes the pyrolysis of EFB, TW and their blends can be categorised into the diffusion and power model categories. An equal mixture of EFB and TW was the preferred combination for co-management because of the synergistic effect, which significantly impacts the co-pyrolysis process. The mass loss rate experiences an inhibitive effect at an earlier stage (320 °C), followed by a promotional impact at the later stage (380 °C). The activation energy needed for a balanced mixture is the least compared to all tested feedstocks, even lower than the pyrolysis of a single feedstock. The study revealed the potential for increasing decomposition rates using lower energy input through the co-pyrolysis of both feedstocks. These findings evidenced that co-pyrolysis is a promising waste management and valorisation pathway to deal with overwhelming waste accumulation. Future works can be conducted at a larger scale to affirm the feasibility of EFB and TW co-management. •Co-pyrolysis of EFB and TW is the most effective at 1:1 mass ratio.•Interaction of components causes synergism and higher reaction rates.•Positive synergistic effect resulted in a lower energy requirement.•EFB:TW = 1:1 ratio gives the best conversion efficiency and lowest energy requirement.•Reaction model of blends are different from with single feedstock pyrolysis.
ISSN:0301-4797
1095-8630
1095-8630
DOI:10.1016/j.jenvman.2024.122172