- Autor
- Marcinkowski Andrzej (Lodz University of Technology, Poland)
- Tytuł
- Environmental Efficiency of Industrial Symbiosis - LCA Case Study for Gypsum Exchange
- Źródło
- Multidisciplinary Aspects of Production Engineering, 2018, vol. 1, s. 793-800, rys., tab., bibliogr. 13 poz.
- Słowa kluczowe
- Ocena cyklu życia, Rozwój zrównoważony, Rynek gipsu, Produkcja przemysłowa, Studium przypadku
Life Cycle Assessment (LCA), Sustainable development, Plaster market, Industrial production, Case study - Uwagi
- streszcz., summ.
- Abstrakt
- A review of the available literature concerning environmental impact assessment for industrial symbiosis has been carried out. The authors have recommended the use of life cycle assessment method for this purpose. It was stated that so far few studies presenting LCA results of industrial symbiosis have been published. Among the factors which contribute to the success of symbiotic exchange, the close location of collaborating companies has been often mentioned. This paper presents LCA results concerning the environmental impact of symbiotic gypsum transmission. Concepts of relative distance and critical distance for the case of industrial symbiosis were proposed and defined. Significant difference between critical distance obtained for particular endpoints were observed (3.5-564 km). Application of Life Cycle Sustainability Triangle enabled the estimation of critical distance taking into account various impact categories. A sensitivity analysis indicated the relationship between critical distance and the means of transport which reflected the effect of scale. The critical distance determined for heavy trucks was 3.2 - 3.9 times longer than in case of lighter vehicles. (original abstract)
- Pełny tekst
- Pokaż
- Bibliografia
- Chertow, M.R. (2000). "Uncovering" Industrial Symbiosis. Journal of Industrial Ecology, 11(1), pp. 11-30.
- Daddi, T., Nucci, B., Iraldo, F. (2017). Using Life Cycle Assessment (LCA) to measure the environmental benefits of industrial symbiosis in an industrial cluster of SMEs. Journal of Cleaner Production 147, pp. 157-164.
- European Environment Agency, (2016). Circular economy in Europe. Developing the knowledge base, EEA Report No. 2/2016, Publications Office of the European Union, Luxembourg.
- International Organization for Standardization, (2006). ISO 14040 Environmental management - Life cycle assessment - Principles and framework.
- International Organization for Standardization, (2006). ISO 14044 Environmental management - Life cycle assessment - Requirements and guidelines.
- Lowe, E.A. (1997). Creating by-product resource exchanges: strategies for eco-industrial parks. Journal of Cleaner Production, 5(1-2), pp. 57-65.
- Mattila, T., Pakarinen, S., Sokka, L. (2010). Quantifying the Total Environmental Impacts of an Industrial Symbiosis A Comparison of Process-, Hybrid and Input-Output Life Cycle Assessment. Environmental Science and Technology, 44(11), pp. 4309-4314.
- Mattila, T., Lehtoranta, S., Sokka, L., Melanen, M., Nissinen, A. (2012). Methodological Aspects of Applying Life Cycle Assessment to Industrial Symbioses. Journal of Industrial Ecology, 16(1), pp. 51-60.
- Mauthoor, S. (2017). Uncovering industrial symbiosis potentials in a small island developing state: The case study of Mauritius. Journal of Cleaner Production, 147, pp. 506-513.
- Singh, A., Loua, H., Yawsa, C., Hopper, J., Pike, R. (2007). Environmental impact assessment of different design schemes of an industrial ecosystem. Resources, Conservation and Recycling 51, pp. 294-313.
- Sokka, L., Melanen, M., Nissinen, A. (2008). How can the sustainability of industrial symbioses be measured? Progress in Industrial Ecology An International Journal, 5(5/6), pp. 518-535.
- Sokka, L., Lehtoranta, S., Nissinen, A., Melanenet, M. (2010). Analyzing the Environmental Benefits of Industrial Symbiosis Life Cycle Assessment Applied to a Finnish Forest Industry Complex. Journal of Industrial Ecology, 15(1), pp. 137-155.
- Sokka, L., Pakarinen, S., Melanen M. (2011). Industrial symbiosis contributing to more sustainable energy use - an example from the forest industry in Kymenlaakso, Finland. Journal of Cleaner Production 19, pp. 285-293.
- Cytowane przez
- ISSN
- 2545-2827
- Język
- eng
- URI / DOI
- http://dx.doi.org/10.2478/mape-2018-0100