Assessment of the Environmental Efficiency of the Life Cycles of Energy Facilities Based on Renewable Energy Sources

There was considered Life Cycle Analysis (LCA) used in foreign practice to assess the negative effects during the life cycle of energy facilities (power plants) on the environment. There were presented results of calculations of pollutants emissions in the environment during life cycle of traditional and renewable energy. More detailed considered the application of the life cycle analysis tool for assessing the environmental efficiency of energy facilities based on renewable energy sources, in particular wind power plants and solar photovoltaic power plants.

1. Сидоренко Г.И., Михеев П.Ю. Оценка энергетической и экологической эффективности жизненных циклов энергетических технологий возобновляемой энергетики. Матер. XXI Междунар. науч.-практ. Конф. "Проблемы и перспективы инновационного развития экономики". М.: Изд-во: ООО "ЭкООнис-экологически чистые технологии". 2016. С.251-259.

2. Life Сycle Assessment Literature Review of Nuclear, Wind and Natural Gas Power Generation. Canadian Nuclear Association. Document № H345621-236-02 Rev. E. 2014. 103 p.

3. Baharwani V., Meena N., Dubey A. Life Cycle Analysis of Solar PV System: A Review. International Journal of Environmental Research and Development. 2014. Vol. 4. P.183-190.

4. Varun A., Bhat I., Prakash R. LCA of renewable energy for electricity generation system A review. Renewable and Sustainable Energy Reviews. 2009. Vol. 13. P.1067-1073.

5. Garrett P., Ronde K. Life Cycle Assessment of Electricity Production from a V80-2.0MW Gridstreamer Wind Plant. Vestas Wind Systems A/S. 2011. 104 p.

6. Garrett P., Ronde K. Life Cycle Assessment of Electricity Production from a V90-2.0MW Gridstreamer Wind Plant. Vestas Wind Systems A/S. 2011. 105 p.

7. Razdan P., Garrett P. Life cycle assessment of electricity production from an onshore V100-2.0 MW Wind Plant. Vestas Wind Systems A/S. 2015. 130 p.

8. Garrett P., Ronde K. Life Cycle Assessment of Electricity Production from an onshore V110-2.0 MW Wind Plant. Vestas Wind Systems A/S. 2015. 129 p.

9. Garrett P., Ronde K. Life Cycle Assessment of Electricity Production from an onshore V100-2.6 MW Wind Plant. Vestas Wind Systems A/S. 2013. 107 p.

10. Garrett P., Ronde K. Life Cycle Assessment of Electricity Production from an onshore V90-3.0MW Wind Plant. Vestas Wind Systems A/S. 2013. 106 p.

11. Souza N., Shonfield P. Life Cycle Assessment of Electricity Production from a V112 Turbine Wind Plant. Vestas Wind Systems A/S. 2011. 87 p.

12. Garrett P., Ronde K. Life Cycle Assessment of Electricity Production from an onshore V105-3.3 MW Wind Plant. Vestas Wind Systems A/S. 2014. 116 p.

13. Garrett P., Ronde K. Life Cycle Assessment of Electricity Production from an onshore V117-3.3 MW Wind Plant. Vestas Wind Systems A/S. 2014. 117 p.

14. Garrett P., Ronde K. Life Cycle Assessment of Electricity Production from an onshore V126-3.3 MW Wind Plant. Vestas Wind Systems A/S. 2014. 117 p.

15. Carrascal S.R. Life cycle assessment of 1 Kwh energy generated by Gamesa G114-2.0 MW On-shore wind farm. Gamesa Coporación Tecnológica. 2014. 45 p.

16. Environmental product declaration GAMESA G128 -5.0 MW onshore wind farm № S-P-00705. Gamesa Coporación Tecnológica. 2015. 33 p. URL: http:/www.gamesacorp.com (Дата обращения: 14.02.2017).

17. Environmental product declaration GAMESA G132 -5.0 MW onshore wind farm № S-P-00706. Gamesa Coporación Tecnológica. 2015. 33 p. URL: http:/www.gamesacorp.com (Дата обращения: 14.02.2017).

18. Masakazu I., Mitsuru K., Masahi N., Kosuke K. A comparative study on life cycle analysis of 20 different PV modules installed at the Hokuto mega-solar plant. Progress in Photovoltaic: Research and applications. 2011. Vol. 17. P.878-886.