Measuring material cycling in industrial systems

Proceedings of the 2001 IEEE International Symposium on Electronics and the Environment. 2001 IEEE ISEE (Cat. No.01CH37190) Pub Date : 2001-05-07 DOI:10.1109/ISEE.2001.924494

R. Bailey, B. Bras, J. Allen

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引用次数: 34

Abstract

As the negative environmental implications of a modern industrial economy have begun to be recognized, a growing comprehension of the key role of material flows in industrial systems has developed. To this end, several indices characterizing material cycling have been developed. Current indices of material cycling for industrial systems, however, do not effectively measure cycling due to the lack of consideration of both direct and indirect flows in a system. A physical flow modeling approach from ecology, input-output flow analysis, is used in this study to develop cycling indices to address the limited scope of existing measures. The input-output cycling metrics, by definition, measure the percent of flows in a system or in a particular process that are cycled. The input-output cycling indices are compared to traditional industrial cycling metrics in this paper with a set of hypothetical cases. From these comparisons, the traditional cycling metrics are shown to not effectively measure cycling in complex material flow systems.

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测量工业系统中的物料循环

随着人们开始认识到现代工业经济对环境的负面影响，人们对工业系统中物质流动的关键作用的理解也日益加深。为此，开发了几个表征材料循环的指标。然而，由于缺乏对系统中直接和间接流动的考虑，目前工业系统的物质循环指标并不能有效地衡量循环。本研究采用了生态学的物理流建模方法，即投入产出流分析，来开发循环指数，以解决现有措施范围有限的问题。根据定义，输入-输出循环度量衡量系统或特定过程中循环的流的百分比。本文通过一系列假设情况，将投入产出循环指标与传统的产业循环指标进行了比较。从这些比较中，传统的循环指标被证明不能有效地测量复杂物料流系统中的循环。

本文章由计算机程序翻译，如有差异，请以英文原文为准。

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Proceedings of the 2001 IEEE International Symposium on Electronics and the Environment. 2001 IEEE ISEE (Cat. No.01CH37190)

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