Life Cycle Assessment for the Design of Chemical Processes, Products, and Supply Chains

Design in the chemical industry increasingly aims not only at economic but also at environmental targets. Environmental targets are usually best quantified using the standardized, holistic method of life cycle assessment (LCA). The resulting life cycle perspective poses a major challenge to chemical...

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Veröffentlicht in:	Annual review of chemical and biomolecular engineering 2020-06, Vol.11 (1), p.203-233
Hauptverfasser:	Kleinekorte, Johanna, Fleitmann, Lorenz, Bachmann, Marvin, Kätelhön, Arne, Barbosa-Póvoa, Ana, von der Assen, Niklas, Bardow, André
Format:	Artikel
Sprache:	eng
Schlagworte:	Chemical engineering Chemical industry Chemical Phenomena Chemical reactions Conservation of Natural Resources Decision support systems Design engineering eco-design Environment Equipment and Supplies Utilization LCA Life cycle analysis Life cycle assessment life cycle design Life cycle engineering Life cycles Marketing Neural Networks, Computer process systems engineering Supply chains sustainability Uncertainty Waste Management
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creator	Kleinekorte, Johanna Fleitmann, Lorenz Bachmann, Marvin Kätelhön, Arne Barbosa-Póvoa, Ana von der Assen, Niklas Bardow, André
description	Design in the chemical industry increasingly aims not only at economic but also at environmental targets. Environmental targets are usually best quantified using the standardized, holistic method of life cycle assessment (LCA). The resulting life cycle perspective poses a major challenge to chemical engineering design because the design scope is expanded to include process, product, and supply chain. Here, we first provide a brief tutorial highlighting key elements of LCA. Methods to fill data gaps in LCA are discussed, as capturing the full life cycle is data intensive. On this basis, we review recent methods for integrating LCA into the design of chemical processes, products, and supply chains. Whereas adding LCA as a posteriori tool for decision support can be regarded as established, the integration of LCA into the design process is an active field of research. We present recent advances and derive future challenges for LCA-based design.
doi_str_mv	10.1146/annurev-chembioeng-011520-075844
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subjects	Chemical engineering Chemical industry Chemical Phenomena Chemical reactions Conservation of Natural Resources Decision support systems Design engineering eco-design Environment Equipment and Supplies Utilization LCA Life cycle analysis Life cycle assessment life cycle design Life cycle engineering Life cycles Marketing Neural Networks, Computer process systems engineering Supply chains sustainability Uncertainty Waste Management
title	Life Cycle Assessment for the Design of Chemical Processes, Products, and Supply Chains
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