Syngas Production from Protective Face Masks through Pyrolysis/Steam Gasification

Kiminaitė, Ieva; González-Arias, Judith; Striūgas, Nerijus; Eimontas, Justas; Seemann, Martin

doi:10.3390/en16145417

Cited by 9 publications

(2 citation statements)

References 36 publications

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“…The model will seek to provide an understanding of emerging opportunities and their underlying challenges for solid waste management companies, and the applicability of the model will be demonstrated with a case study focusing on new markets for MSW's operations. An integrated analytical framework will also be applied to comparing the results with the recent literature [24]. However, several barriers [25] to the integration of the process model must first be identified including by using recommendations provided to develop integrated process models in other parts of Canada by policy makers wishing to facilitate the development of novel biomass or other paper waste in other parts of Canada.…”

Section: Introductionmentioning

confidence: 99%

Integrated Waste-to-Energy Process Optimization for Municipal Solid Waste

A. Gabbar,

Ahmad

2024

Energies

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Within the past few decades, thousands of experiments have been performed to characterize urban waste and biomass to estimate their bioenergy potential and product identification. There is a need to develop an integrated process model based on the experimental literature, as well as simulations to obtain suitable products. In this study, municipal solid waste (MSW), including paper and plastic characterization and an integrated process model, were developed to optimize the final products in a reactor system. The process model has two modes, R&D and reactor control (RC), to obtain suitable products including bio-oil, char, and gases. A database was integrated based on thermokinetics, machine learning, and simulation models to optimize product efficiency. The experimental data include those obtained by thermogravimetric analysis and Fourier-transform infrared spectroscopy, which were linked to a pyrolysis experimental setup. Feedstock product mapping models were incorporated into the database along with the temperature, heating rates, elemental analysis, and final product concentration, which were utilized for the pyrolysis reactor setup. Product feasibility was conducted based on life cycle cost, affordability, and product efficiency. The present work will bridge the gap between experimental studies and decision-making based on obtained products under several experimental conditions around the world.

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Section: Introductionmentioning

confidence: 99%

Integrated Waste-to-Energy Process Optimization for Municipal Solid Waste

A. Gabbar,

Ahmad

2024

Energies

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“…Thermochemical conversion processes such as pyrolysis and gasification are one of the possible solutions to address the problems related to PW by upcycling it into valuable products. Many research studies have shown that PW are easily converted into gaseous or liquid energy and chemical products via the aforementioned processes [4][5][6][7]. When plastic thermally degrades, it releases high contents of volatile matter, consequently, the main products are VOC (volatile organic compounds), while the composition of evolved chemical species mainly depends on selected process conditions.…”

Section: Introductionmentioning

confidence: 99%

Comparison of Chemical and Thermal Oxidation Stabilization Influence on Pyrolytic Char Formation from PE and PVC Plastic Wastes

Kiminaitė,

Striūgas,

Baltušnikas

et al. 2024

Preprint

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Plastic waste accumulation poses significant environmental challenges, underscoring the importance of closing the plastic life cycle by converting waste into valuable products. Pyrolytic char, a promising byproduct, offers diverse industrial applications. However, little attention has been given to converting hydrocarbon-based plastics into solid carbon due to their low fixed carbon content. This study compares sulfonation and thermal oxidation stabilization techniques for carbonizing waste polyethylene and polyvinyl chloride. Results indicate sulfonation yields higher pyrolytic char formation and improves surface properties, surpassing Al2O3 in catalyst support characteristics. Thermal oxidation increases fixed carbon content but adversely affects char yield and surface properties. Both methods effectively enhance fixed carbon content, but sulfonation emerges as more advantageous, suggesting potential use of plastic-derived char as a catalyst support material, contributing to circular economy development.

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