International Journal of Renewable Energy Research-IJRER

Wind energy installations in Greece are increasing rapidly as a means to achieve the national goal for increasing the renewables’ share in the country’s energy balance. However, wind farm installations are not impact free from the environmental standpoint. The present study examines the cradle-to-grave impacts of a wind farm in central Greece composed of four, 850 MW each, wind turbines. Life cycle inventory data were obtained from secondary sources and the CML 2 baseline 2000 ready-made method was utilized for the environmental assessment in nine impact categories. The results indicate an intensity index of 4.1 kg CO₂ eq. per MWh along with an energy payback time of 7 months. Towers, nacelles and the foundations of the turbines are the wind farm components that cause the most environmental impacts. The major conclusion is that electricity generation from wind power is environmentally preferable compared to the current electricity generation mix in Greece.

life cycle assessment; wind energy; Greece.

Guezuraga B, Zauner R, Polz W (2012). Life cycle assessment of two different 2MW class wind turbines. Renewable Energy, 37, 37 – 44.

Raadal H.L., Gagnon L., Modahl I.S., Hanssen O.J. (2011). Life cycle greenhouse gas (GHG) emissions from the generation of wind and hydro power. Renewable and Sustainable Energy Reviews, 15, 3417-3422.

Varun, Bhat I. K, Prakash R. (2009). LCA of renewable energy for electricity generation systems – A review. Renewable and Sustainable Energy Reviews, 13, 1067 – 1073.

Wang Y., Sun T. (2012). Life cycle assessment of CO2 emissions from wind power plants: Methodology and case studies. Renewable Energy, 43, 30-36.

Ardente F, Beccali M, Cellura M, Lo Brano V (2008). Energy performances and life cycle assessment of an Italian wind farm. Renewable and Sustainable Energy Reviews, 12, 200 – 217.

Martínez E, Sanz F, Pellegrini S, Jiménez E, Blanco J (2009). Life cycle assessment of a multi-megawatt wind turbine. Renewable Energy, 34, 667 – 673.

Martínez E, Sanz F, Pellegrini S, Jiménez E, Blanco J (2009). Life cycle assessment of a 2-MW rated power wind turbine: CML method. International Journal of Life Cycle Assessment, 14, 52 – 63.

Martínez E, Jiménez E, Blanco J, Sanz F (2010). LCA sensitivity analysis of a multi-megawatt wind turbine. Applied Energy, 87, 2293 – 2303.

Tremeac B, Meunier F (2009). Life cycle analysis of 4.5MW and 250W wind turbines. Renewable and Sustainable Energy Reviews, 13, 2104 – 2110.

Crawford H.R (2009). Life cycle energy and greenhouse emissions analysis of wind turbines and the effect of size on energy yield. Renewable and Sustainable Energy Reviews, 13, 2653 - 2660.

Zhong W.Z, Song B, Loh E.P (2011). LCAs of a polycrystalline photovoltaic module and a wind turbine. Renewable Energy, 36, 2227 – 2237.

Wagner H.J, Baack C, Eickelkamp T, Epe A, Lohmann J, Troy S (2011). Life Cycle Assessment of the offshore wind farm alpha ventus. Energy, 36, 2459 – 2464.

Angelakoglou K., Botsaris P.N., Gaidajis G. (2014). Issues regarding wind turbines positioning: A benchmark study with the application of the life cycle assessment approach. Sustainable Energy Technologies and Assessments, 5, 7–18.

Weinzettel J., Reenas M., Solli C., Hertwich E.G. (2009). Life cycle assessment of a floating offshore wind turbine. Renewable Energy, 34, 742-747.

Hellenic Wind Energy Association (2014). Hellenic wind energy statistics 2013. Available from: http://eletaen.gr/wp-content/uploads/2014/01/2013_-HWEA_Statistics_Greece.pdf, Accessed 15/2/2014.

ISO 14044 (2006). Environmental management - Life cycle assessment - Requirements and guidelines. International Organisation for Standardisation (ISO), Geneva.

Wind Energy Market Portal (2014). http://www.wind-energy-market.com/en/homepage/, Accessed 15/2/2014.

Lydon D.F. (1987). Observations on the density and quality of concrete. The International Journal of Cement Composites and Lightweight Concrete, 9(4), 205-216.

Pettersen J., Hertwich E.G. (2008). Critical review: life-cycle inventory procedures for long-term release of metals. Environmental Science and Technology, 42, 4639-4647.

Kabir M.R., Rooke B., Bassanayake G.D.M., Fleck A.B. (2012). Comparative life cycle energy, emission, and economic analysis of 100kW nameplate wind power generation. Renewable Energy, 34, 133 – 141.

Theodosiou G., Koroneos C., Stylos N. (2014). Environmental impacts of the Greek electricity generation sector. Sustainable Energy Technologies and Assessments, 5, 19–27.