Environmental Evaluation of Industry Cluster Strategies with a Life Cycle Perspective: Replacing Fossil Feedstock with Forest-Based Feedstock and Increasing Thermal Energy Integration

Symbiotic linkages in industry clusters in the form of interconnected materials, energy and information flows, and close proximity provide unique opportunities to develop efficient environmental strategies. The purpose of our study is to examine the practical potential of applying a life cycle approach in strategy evaluations, as the environmental impact caused by industrial symbiosis systems outside the company gates has been scarcely addressed.

Summary

Symbiotic linkages in industry clusters in the form of interconnected materials, energy and information flows, and close proximity provide unique opportunities to develop efficient environmental strategies. The purpose of our study is to examine the practical potential of applying a life cycle approach in strategy evaluations, as the environmental impact caused by industrial symbiosis systems outside the company gates has been scarcely addressed.

This is done by evaluating two strategies for an industry cluster in Sweden: (1) to replace a share of the fossil feedstock used in the industry cluster with forest-based feedstock and (2) to improve energy efficiency through thermal energy integration. The environmental impact reduction potential of the strategies is evaluated using life cycle assessment. The ratio between investment cost and reduced global warming potential is used as an indicator to evaluate the cost-effectiveness of the strategies. Results demonstrate the importance of applying a life cycle perspective as the assessment outcome depends heavily on whether only on-site consequences are assessed or if upstream and downstream processes are also included. 20 percent of the greenhouse gas emission reduction of the energy integration strategy occurs off-site, whereas the forest strategy has the largest reduction potential off-site, >80 percent.

Coworkers: Roman Hackl

Keywords: biobased materials, chemical manufacturing, global warming potential, heat integration, industrial symbiosis, life cycle assessment

Year: 2017.0

Report number: A2266

Authors: Roman Hackl, Røyne, F., Ringström, E., Berlin, J.

Published in: . Journal of Industrial Ecology. doi:10.1111/jiec.12620