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Technical impact indicators for materials

Published online by Cambridge University Press:  28 September 2012

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Abstract

The impact of the use of particular materials on the environment and society can beassessed in a number of ways, including through the impact on natural resources,contribution to environmental burden and effects on the quality of human life. In thiscontext, indicators such as embodied energy, exergy, TMR (total material requirement),ecological footprint, social indicators (such as effects on human health) and LCA based onthese indicators, are available. We apply the concept of energy networks 1 (quoted in Appendix O), to explore the differences inenergy network impact due to processes for the production of various materials, each timewith an equivalent end-use in mind. The inventory analysis part of LCA has been carriedout on materials, as well as some work on impact assessment (LCIA) for resource use,pollution severity and health impact. The indicators proposed here aid the assessment ofthe energy system impact, particularly with regards to opportunity costs to society,impact on equity in society and the administrative burden on society due to the currentenergy networks. The indicators are: embodied energy, the maximum process temperature, theannual use energy, and network reliance. Three case studies are employed to explore theusefulness of the indicators, including a beverage container, a house window frame and abeverage bottle transport crate. These case studies show that for a particular end use,different materials can have wide differences in the proportion of energy sourced fromenergy networks (a factor of 95 observed in one case). The indicators also offer a quickerindication than life cycle assessment and allow deduction of impacts on a wider socialsystem. The indicators have the potential to change material development and processdesign trends towards processes which are less burdensome on energy networks.

Type
Research Article
Copyright
© EDP Sciences 2012

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References

Debeir et al., In the Servitude of Power : Energy and Civilization Through the Ages. Zed Books Ltd, London. Chapter 6 introduces energy networks, 1991
ISO, 2008. ISO standards available at http://www.iso.org/iso/catalogue_detail?csnumber=37456, accessed March 2008. International Standards Organisation, Geneva, Switzerland
Reddy, B.V.V., Jagadish, K.S., Energy and Buildings 35 (2003) 129-137
Encyclopedia of Earth, 2008. Exergy article, available at http://www.eoearth.org/article/Exergy, updated February 2008, accessed March 2008. 2008, The Encyclopedia of Earth www.eoearth.org.
S. Bringezu, H. Schutz, The Total Material Requirement of the European Union, European Environmental Agency, Technical report, 55, 2001
WWF, 2006. Humanity’s Ecological Footprint. Feature on the 2006 Living Planet Report http://www.panda.org/news_facts/publications/living_planet_report/footprint/index.cfm, published 2006, accessed March, 2008
FAO, 2002, Environmental and Energy Balances of Wood Products and Substitutes, by M. Scharai-Rad, J. Welling, available at http://www.fao.org/docrep/004/Y3609E/y3609e00.HTM, published 2002, accessed March 2008. United Nations Food and Agricultural Organisation
EC, 2007a. ELCD Data System, available at http://lca.jrc.ec.europa.eu/lcainfohub/datasetArea.vm. Published February 2007, accessed March 2008. European Commission, Directorate General, Joint Research Centre
EC, 2007b. Process or LCI result data set : Aluminium sheet; Primary production; Production mix, at plant (en)’, available at http://lca.jrc.ec.europa.eu/lcainfohub/datasets/elcd/processes/Aluminum_sheet_EAA_50f12420-8855-11db-b606-0800200c9a66__01.00.001.xml. Published February 2007, accessed March 2008. European Commission, Directorate General, Joint Research Centre
W.F. Hosford, J.L. Duncan, 1994. The Aluminium Beverage Can. Scientific American, September 1994. Available at http://www.gk-12.osu.edu/Docs/Hosford_AlumBeverageCan.pdf, accessed March, 2008
Helio International, 2006. Indicator Selection and Rationale document available as part of Helio International methodology at http://www.helio-international.org/energywatch/methodology.cfm, accessed March 2008
CMPBS, 1999. CARBON DIOXIDE INTENSITY RATIOS : A Method of Evaluating the Upstream Global Warming Impact of Long-Life Building Materials’ available at http://www.cmpbs.org/publications/T1.2-AD4.5-Up_Gbl_wrm.pdf, and also on page http://www.cmpbs.org/publications/BuildingProductDesign/index.html, accessed March 2008. 1999, Centre for Maximum Potential Building Systems
Williams, E., Environm. Sci. Technol. 38 (2004) 22
Alibaba, HDPE beverage bottle crate dimensions available at http://alfreddung.trustpass.alibaba.com/product/11988456/Beer_Crate_Bottle_Crate.html. Accessed March 2008. 2008, http://www.alibaba.com.
EC, 2007e. Process or LCI result data set : Timber pine (40% water content) (en). Available at http://lca.jrc.ec.europa.eu/lcainfohub/datasets/html/processes/Timber_pine__40__water_content__DE__621e64d0-f471-4023-9ebc-a52cd8ee573F__01.00.001.html, accessed March 2008. European Commission, Directorate General, Joint Research Centre
National Association of Manufacturers, Manufacturing multimedia for aluminium can and PET bottle available by search term at http://blog.nam.org/archives/coolstuffbeingmadecom_weekend_video/various post dates, accessed March 2008
Engineeringtoolbox, 2005a. Solids – Specific Heat Capacities available at http://www.engineeringtoolbox.com/specific-heat-solids-d_154.html, accessed March 2008.
EC, 2007d. Process or LCI result data set : Aluminium extrusion profile; Primary production; Production mix, at plant (en). Available at http://lca.jrc.ec.europa.eu/lcainfohub/datasets/elcd/processes/Aluminum_extrusion_profile_EAA_50f12421-8855-11db-b606-0800200c9a66__01.00.001.xml, accessed March 2008. European Commission, Directorate General, Joint Research Centre
EC, 2007c. Process or LCI result data set : Polyethylene Terephthalate (PET) granulate (bottle grade); Production mix (en). Available at http://lca.jrc.ec.europa.eu/lcainfohub/datasets/elcd/processes/Polyethylene_terephtalate_bottle_grade_d35f185d-0b43-498e-a963-237deb6ac82b_01.00.001.xml. Published February 2007, accessed March 2008. European Commission, Directorate General, Joint Research Centre
Wikipedia, 2008a. Polyethylene Terephthalate. Article, including properties of PET, bottle grade, at http://en.wikipedia.org/wiki/Polyethylene_terephthalate, accessed March 2008
F. Awaja, D. Pavel, Recycling of PET, available at www.sciencedirect.com, published online 16 March 2005, accessed December 2007
Engineerintoolbox, 2005b. Thermoplastics – Physical Properties. Available at http://www.engineeringtoolbox.com/physical-properties-thermoplastics-d_808.html, accessed March 2008
Wikipedia, 2008b : Polyvinyl chloride. Article, including material properties, available at http://en.wikipedia.org/wiki/Polyvinyl_chloride, accessed March 2008
Goodfellow, Polyethylene – High density (HDPE ) Material Properties. Available at http://www.goodfellow.com/csp/active/static/A/Polyethylene_-_High_density.HTML, publish date unknown, accessed March 2008
Dow Chemical, 1995. HDPE Resin Data Sheet. Available at http://www.dow.com/plasticpipes/prod/bg10150.htm, accessed March 2008. Dow Chemical Company
M.N. Haque, Performance of an Industrial Solar Kiln for Drying Timber. Report available at, http://www.nzsses.auckland.ac.nz/Conference/2004/manuscripts.htm, published 2004, accessed March 2008