Environmental Assessment of Metal Chip Recycling – Quantification of Mechanical Processing's Global Warming Potential

Chantal Rietdorf , Sonja Ziehn , Sophia Marie Giunta , Robert Miehe , Alexander Sauer
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Abstract

Material recycling is an essential lever for improving the sustainability of production processes. One way of reusing metal chips that occur as waste in machining or other subtractive manufacturing processes is to mechanically pretreat and remelt them. In mechanical pretreatment, the chips are separated from the cutting fluid by a centrifuge and then briquetted directly on site. This simplifies the handling and makes the transport and subsequent remelting more efficient than in thermal processing alone. The main objective of this work is to quantitatively assess the environmental impacts of the described recycling process, focusing on the global warming potential. Furthermore, recycling by means of mechanical chip processing is compared with alternatives such as thermal drying and primary material extraction. A parametric life cycle assessment (LCA) model has been developed for this purpose. The model considers equipment, material, throughput and location variations to analyze different use cases. The results of the LCA of an exemplary use case show that environmental benefits result from a higher bulk density during transport and a lower energy input during remelting due to a lower liquid content.

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金属片回收利用的环境评估--量化机械加工的全球升温潜能值
材料回收利用是提高生产工艺可持续性的重要手段。重新利用机械加工或其他减材制造过程中产生的金属屑废料的一种方法是对其进行机械预处理和再熔化。在机械预处理中,切屑通过离心机从切削液中分离出来,然后直接在现场压块。与单纯的热处理相比,这种方法简化了处理过程,并提高了运输和后续重熔的效率。这项工作的主要目的是对所述回收工艺对环境的影响进行定量评估,重点是全球升温潜能值。此外,还将机械切屑加工的回收方法与热干燥和原始材料提取等替代方法进行了比较。为此开发了一个参数化生命周期评估(LCA)模型。该模型考虑了设备、材料、产量和地点的变化,以分析不同的使用情况。一个示例使用案例的生命周期评估结果表明,运输过程中容积密度较高,以及重熔过程中由于液体含量较低而导致的能源投入较少,都能带来环境效益。
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Editorial Preface Editorial Editorial Off-axis monitoring of the melt pool spatial information in Laser Metal Deposition process
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