A Simplified Life Cycle Approach for Assessing Greenhouse Gas Emissions of Wind Electricity
Article first published online: 27 MAR 2012
© 2012 by Yale University
Journal of Industrial Ecology
Special Issue: Meta-Analysis of Life Cycle Assessments
Volume 16, Issue Supplement s1, pages S28–S38, April 2012
How to Cite
Padey, P., Blanc, I., Le Boulch, D. and Xiusheng, Z. (2012), A Simplified Life Cycle Approach for Assessing Greenhouse Gas Emissions of Wind Electricity. Journal of Industrial Ecology, 16: S28–S38. doi: 10.1111/j.1530-9290.2012.00466.x
- Issue published online: 3 MAY 2012
- Article first published online: 27 MAR 2012
- environmental impact;
- industrial ecology;
- life cycle assessment (LCA);
A full life cycle assessment (LCA) is usually a time, energy, and data-intensive process requiring sophisticated methodology. Our meta-analysis of life cycle greenhouse gas (GHG) emissions of wind electricity highlights several key, sensitive parameters to provide a better understanding of the variability in LCA results, and then proposes a methodology to establish a simplified, streamlined approach based on regressions built on these key parameters. Wind electricity's environmental performance can be linked to three essential components: technological (e.g., manufacturing), geographical (e.g., wind speed), and LCA methodology (e.g., product lifetime).
A regression has been derived based on detailed LCA results from a representative sample of 17 industrial wind turbines manufactured and recently installed in Europe on average land configurations. Simple GHG performance (i.e., emissions) curves depending on average on-site wind speed and wind turbine lifetime are proposed. Whatever the system power, considering the full range of possible wind speeds in Europe (4 to 9 meters per second [m/s]) and a lifetime of 10 to 30 years, emissions vary from 8.7 to 76.7 grams of carbon dioxide equivalent per kilowatt-hour (g CO2-eq/kWh) when the wind speed is less than 6.5 m/s, and from 4.5 to 22.2 g CO2-eq/kWh when the wind speed is 6.5 m/s or greater. This second situation with a turbine lifetime of 20 years is assumed to be most realistic based on economic criteria.
This research presents simplified models as an alternative to detailed LCA. The methodology has been applied as a first trial to wind electricity and could be applied to other energy pathways.