Julia Mühl, Simon Hofer, Dominik Blasenbauer, Jakob Lederer
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引用次数: 0
Abstract
To foster a circular economy, the EU will increase recycling targets for packaging materials, including aluminum, ferrous metals and glass. Recovery of packaging metals from incineration bottom ashes (IBA) from municipal solid waste incineration can contribute to achieving these targets. Nevertheless, recoverable metal and glass amounts from IBA, and in particular IBA from fluidized bed combustion, are rarely investigated. Therefore, this work aims to assess the recoverable amounts of aluminum, magnetic ferrous metals and glass > 4 mm from different types of IBA through enhanced treatment. In an industrial-scale treatment experiment with one batch of IBA from grate and one from fluidized bed combustion, masses and compositions of all output flows of the treatment plant were determined. Material flow analysis was used to study the distribution of the investigated materials during the treatment process. Results show that glass separation was not feasible for the grate IBA, which only contained 7 % glass > 4 mm. The fluidized bed IBA contained 42 % glass > 4 mm, of which 72 % were recovered. More aluminum and magnetic ferrous metals > 4 mm were found in the fluidized bed IBA, also exhibiting less mineral agglomeration compared to those from grate IBA. The study demonstrated that enhanced industrial IBA treatment can recover > 95 % of aluminum and magnetic ferrous metals > 4 mm, not observing significant differences between these metals. Thus, a cutting-edge IBA treatment can enable the recovery of recyclable material from IBA and therefore contribute to a circular economy. Furthermore, fluidized bed IBA shows advantages regarding its recycling options compared to grate IBA.
为了促进循环经济,欧盟将提高包装材料的回收目标,包括铝、黑色金属和玻璃。从城市固体垃圾焚烧产生的焚烧底灰(IBA)中回收包装金属有助于实现这些目标。然而,从 IBA(尤其是流化床焚烧产生的 IBA)中可回收的金属和玻璃数量却很少得到研究。因此,本研究旨在评估通过强化处理从不同类型的 IBA 中可回收的铝、磁性黑色金属和大于 4 毫米的玻璃的数量。在一次工业规模的处理实验中,一批 IBA 来自炉排,一批来自流化床燃烧,确定了处理厂所有输出流的质量和成分。采用物质流分析法研究了所研究物质在处理过程中的分布情况。结果表明,炉排 IBA 无法进行玻璃分离,其中仅有 7% 的玻璃 > 4 毫米。流化床 IBA 含有 42% > 4 毫米的玻璃,其中 72% 被回收。在流化床 IBA 中发现了更多大于 4 毫米的铝和磁性黑色金属,与炉排 IBA 中的铝和磁性黑色金属相比,流化床 IBA 中的矿物团聚也更少。研究表明,强化工业 IBA 处理可回收大于 95% 的铝和大于 4 毫米的磁性黑色金属,而且这些金属之间没有明显差异。因此,先进的 IBA 处理技术可以从 IBA 中回收可回收材料,从而促进循环经济的发展。此外,流化床 IBA 与炉排 IBA 相比,在回收利用方面具有优势。
期刊介绍:
Waste Management is devoted to the presentation and discussion of information on solid wastes,it covers the entire lifecycle of solid. wastes.
Scope:
Addresses solid wastes in both industrialized and economically developing countries
Covers various types of solid wastes, including:
Municipal (e.g., residential, institutional, commercial, light industrial)
Agricultural
Special (e.g., C and D, healthcare, household hazardous wastes, sewage sludge)