Abstract-In order to improve the eco-efficiency at the end-of-life phase of consumer electronic products, comprehensive assessments should be made. The Quotes for environmentally WEighted RecyclabiliTY and Eco-Efficiency method (QW-ERTY/EE) developed at the Delft University of Technology is applied to aim at minimal end-of-life treatment costs against maximal environmental recovery. In this paper, the outcomes of this eco-efficiency concept are presented based on a range of improvement options like changing shredding and separation settings, plastic recycling, glass recycling, or separate sorting of certain products. The analysis of more than 75 different consumer electronic products clearly shows groups in state-of-the-art recycling performance in both environmental and economic terms and a substantial distinction between the various product categories. From there, the evaluation takes place of technical improvements in relation to current best-practice recycling. Even more, with the QWERTY/EE concept it is made possible to select and rank improvement options of current and future end-of-life processing and to determine which options bring substantial environmental gain in relation to financial investments made. For glass dominated products, an increase in glass recycling results in significant environmental improvements. The same counts for separate sorting and treatment of precious metal dominated products with a relatively high precious metal content like cellular phones. However, economies of scale are a major assumption that has to be fulfilled in this case. Other conclusions and outcomes are that plastic recycling seems only eco-efficient for large housings of appliances already undergoing disassembly due to the presence of a cathode ray tube (CRT) or liquid crystal display (LCD). For small and medium-sized housings, the extra costs of plastic recycling are high in relation to the environmental improvement realized. In most cases, dedicated shredding and separation of metal dominated products does not lead to substantial environmental or economic improvements. In general, it is shown that the various options to increase the eco-efficiency of end-of-life systems lead to very mixed environmental and economic results. As a consequence, end-of-life policy strategies should be evaluated, and in some cases revised, to support and enhance the most eco-efficient improvement options. Regarding the sensitivity of the results, it is shown that although the different environmental assessment models prioritize individual materials in a different order, the results for the improvement options on a system level are pointing in the same direction, except for plastic recycling scenarios.
No abstract
+49(0)30 46403-135Electronic products are so complex and fast evolving that specific life cycle analysis (LCA) during the product development are still not feasible. One successful alternative is a modular evaluation concept. The spectrum of companies in electronics -from the small, specialized company where one person handles all environmental affairs to the global players with their own environmental research departments -requires a flexible mixture of basic research and reliable data generation, contract R&D, and the transfer of results and methods into management workflows. Several electronic systems mainly from information and communications products have been assessed with a different number of modules, depending on the expected or necessary width and depth of results. For all examples optimization strategies and specific improvements will be shown.
Abstract-In order to improve the eco-efficiency at the end-of-life phase of consumer electronic products, comprehensive assessments should be made. The Quotes for environmentally WEighted RecyclabiliTY and Eco-Efficiency method (QW-ERTY/EE) developed at the Delft University of Technology is applied to aim at minimal end-of-life treatment costs against maximal environmental recovery. In this paper, the outcomes of this eco-efficiency concept are presented based on a range of improvement options like changing shredding and separation settings, plastic recycling, glass recycling, or separate sorting of certain products. The analysis of more than 75 different consumer electronic products clearly shows groups in state-of-the-art recycling performance in both environmental and economic terms and a substantial distinction between the various product categories. From there, the evaluation takes place of technical improvements in relation to current best-practice recycling. Even more, with the QWERTY/EE concept it is made possible to select and rank improvement options of current and future end-of-life processing and to determine which options bring substantial environmental gain in relation to financial investments made. For glass dominated products, an increase in glass recycling results in significant environmental improvements. The same counts for separate sorting and treatment of precious metal dominated products with a relatively high precious metal content like cellular phones. However, economies of scale are a major assumption that has to be fulfilled in this case. Other conclusions and outcomes are that plastic recycling seems only eco-efficient for large housings of appliances already undergoing disassembly due to the presence of a cathode ray tube (CRT) or liquid crystal display (LCD). For small and medium-sized housings, the extra costs of plastic recycling are high in relation to the environmental improvement realized. In most cases, dedicated shredding and separation of metal dominated products does not lead to substantial environmental or economic improvements. In general, it is shown that the various options to increase the eco-efficiency of end-of-life systems lead to very mixed environmental and economic results. As a consequence, end-of-life policy strategies should be evaluated, and in some cases revised, to support and enhance the most eco-efficient improvement options. Regarding the sensitivity of the results, it is shown that although the different environmental assessment models prioritize individual materials in a different order, the results for the improvement options on a system level are pointing in the same direction, except for plastic recycling scenarios.
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