Gasification of RDF and Its Components with Tire Pyrolysis Char as Tar-Cracking Catalyst

The composition of gas produced by the gasification of refuse-derived fuel (RDF) can be affected by the content of individual components of RDF and their mutual interactions. In this work, plastics, paper, wood, textile and RDF were gasified in a two-stage gasification system and the obtained tar yi...

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Bibliographic Details
Published inSustainability Vol. 12; no. 16; p. 6647
Main Authors Šuhaj, Patrik, Husár, Jakub, Haydary, Juma
Format Journal Article
LanguageEnglish
Published Basel MDPI AG 01.08.2020
Subjects
Biomass
Carbon dioxide
Catalysts
Composition effects
Cracking (chemical engineering)
Gas composition
Gases
Gasification
Hydrocarbons
Hydrogen
Lignocellulose
Moisture content
Municipal solid waste
Nuclear fuels
Oxygen demand
Plastics
Polymers
Pyrolysis
Reactors
Refuse derived fuels
Solid wastes
Sustainability
Synthesis gas
Tar
Temperature effects
Textiles
Waste to energy
Yield
Germany
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Summary:The composition of gas produced by the gasification of refuse-derived fuel (RDF) can be affected by the content of individual components of RDF and their mutual interactions. In this work, plastics, paper, wood, textile and RDF were gasified in a two-stage gasification system and the obtained tar yields and product gas quality were compared. The two-stage reactor consisted of an air-blown gasifier and a catalytic reactor filled with carbonized tire pyrolysis char as the tar-cracking catalyst. Tire pyrolysis char is a promising alternative to expensive catalysts. The impact of temperature and catalyst amount on the tar yield and gas composition was investigated. Theoretical oxygen demand for all material classes was calculated and its effect on gas composition and tar yield is discussed. The results indicate that the gasification of plastics produces the highest amount of tar and hydrocarbon gases, while the CO2 content of the product gas remains the lowest compared to all other materials. On the other hand, the paper fraction produced hydrogen-rich gas with low tar content. The gasification of RDF at 700 °C provided the lowest tar yield compared to all other materials, indicating positive synergic effects of lignocellulosic biomass and plastics in tar reduction. The significance of these interactions was suppressed at the highest temperature of 900 °C, as the thermal cracking of tar became dominant. For CO2 content, a negative synergic effect (higher CO2 concentration) was observed.
ISSN:2071-1050
2071-1050
DOI:10.3390/su12166647