Abstract
In this study, we investigated the applicability of an automobile shredder residue (ASR) as an energy and recycling resource. First, ASR gasification was conducted in a fixed-bed reactor (throughput = 1 kg/h) at different temperatures (800, 1000, and 1200 °C) and an equivalence ratio of 0.1–0.5. Clay bricks were prepared with the solid residue obtained from the gasification process to address the issue of solid-residue production in pyrolysis. The syngas (H2 + CO) from ASR gasification had maximum and minimum yields of approximately 86 and 40 vol.%, respectively. Furthermore, the yield of syngas increased with the temperature and equivalence ratio (ER); therefore, the optimum conditions for the ASR gasification were determined to be a temperature of 1200 °C and an ER of 0.5. In addition, solid residues, such as char and ash, began to melt due to thermal heating in the range of 1300–1400 °C and were converted into melting slag, which was subsequently used to manufacture clay bricks. The absorption ratios and compressive strengths of the clay bricks were compared to those set by Korean Industrial Standards to evaluate the quality of the clay bricks. As a result, the manufactured clay bricks were estimated to have a compressive strength of over 22.54 N/mm2 and an absorption ratio of less than 10%. Additionally, greenhouse gas (GHG) emissions from the melting–gasification process were estimated and compared with those from ASR incineration, calculated using the greenhouse gas equations provided by the Korean Ministry of Environment. As a result, it was revealed that the GHG emissions from the combined melting–gasification process (gasification, melting system, and clay-brick manufacturing) were approximately ten times higher than those from the ASR-incineration process. Thus, in terms of operation cost on the carbon capture process for GHG reduction, the combined melting–gasification process would be a more efficient process than that of incineration.
Highlights
Waste-to-energy technology using municipal solid waste has been widely applied in renewable energy production, which is an alternative to fossil fuels [1]
Gasireactions cannot be summarized by specific equations because of their complexity; fication reactions cannot be summarized by specific equations because of their complexthe results obtained from the automobile shredder residues (ASR) gasification can be explained using the main equations ity; the results obtained from the ASR gasification can be explained using the for general gasification
It was observed that carbon monoxide and hydrogen are predominant, and reactants are more prevalent with the increasing temperature in an exothermic reaction, whereas products are more prevalent with the increasing temperature in an endothermic reaction [47]
Summary
Waste-to-energy technology using municipal solid waste has been widely applied in renewable energy production, which is an alternative to fossil fuels [1]. Municipal solid waste is heterogeneous and typically contains a high level of moisture. Recent studies have focused on developing technologies to produce a more efficient and sustainable form of renewable energy from solid and other types of waste. The annual cumulative production of plastics by 2015 was approximately. 8300 Mt worldwide, and a proportion (7 wt.%) is used in the vehicle-manufacturing process. It has been found that automobile shredder residues (ASR), containing various metal and non-metal materials, are more stable and homogeneous than municipal solid waste, and ASR contain more combustible compounds that can be used as fuel.
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