1 / 19

Extended life-cycle assessment for offshore wind power

Extended life-cycle assessment for offshore wind power. Anders Arvesen, Åsa Grytli Tveten, Edgar Hertwich, Anders Hammer Strømman. The Industrial Ecology Programme, Norwegian University of Science and Technology (NTNU). European Offshore Wind 2009 Conference & Exhibition.

kenton
Télécharger la présentation

Extended life-cycle assessment for offshore wind power

An Image/Link below is provided (as is) to download presentation Download Policy: Content on the Website is provided to you AS IS for your information and personal use and may not be sold / licensed / shared on other websites without getting consent from its author. Content is provided to you AS IS for your information and personal use only. Download presentation by click this link. While downloading, if for some reason you are not able to download a presentation, the publisher may have deleted the file from their server. During download, if you can't get a presentation, the file might be deleted by the publisher.

E N D

Presentation Transcript

  1. Extended life-cycle assessment for offshore wind power Anders Arvesen, Åsa Grytli Tveten, Edgar Hertwich, Anders Hammer Strømman The Industrial Ecology Programme, Norwegian University of Science and Technology (NTNU) European Offshore Wind 2009 Conference & Exhibition

  2. Wind power in a life-cycle perspective Iron Tower Installation Network expansion O&M Steel Nacelle Aluminium Rotor Wind turbine Wind farm Use End-of-life Copper Substructure Electrical connections Concrete Transformer Electricity to grid Glass fibre Cabling

  3. Wind power in a life-cycle perspective • The absence of in-plant combustion does not in itself justify claims of wind power as a ”clean” technology • Life-cycle assessment (LCA) can assist in: • Developing system designs and strategies for a truly sustainable wind power industry • Documenting the technology’s superiority over competing options

  4. Contents • Background Review of LCA literature • Environmental input-output analysis • Conclusions

  5. Review of LCA literature Review of 28 estimates originating from 18 studies • Published in 2000-2009 • 14 studies published in scientific journals • 2 studies by wind turbine manufacturer (Vestas) • 1 in LCA commercial database (Ecoinvent) • 1 EU-funded research project (ECLIPSE) • Turbine sizes < 500 kW excluded • 8 estimates for offshore wind farms • Mostly European conditions

  6. Life-cycle energy and global warming impacts for wind power Energy intensity (kWhin/kWhel) Global warming (g CO2/kWhel)

  7. Comparing offshore wind with natural gas combined cycle Wind power versus NGCC: + Small global warming impact ÷Greater toxicity impacts ? Marine ecotoxicity impacts Source: Weinzettel, J., M. Reenaas, C. Solli, and E. G. Hertwich. 2009. Life cycle assessment of a floating offshore wind turbine. Renewable Energy 34(3): 742-747

  8. Influencing factors • Capacity factor: 19 – 54 % • Onshore average: 29 % • Offshore average: 43 % • Lifetime: 20 years • Country of manufacture • Assumptions on recycling of metals and blade material • Large differences between studies • Offshore sites • Increased material and energy requirements • Improved wind conditions

  9. Analysis at component level

  10. Analysis at component level

  11. Do LCA studies provide the “full picture”? • In short: No • Noise and visual effects: Generally disregarded • Effects on bird and marine life: Disregarded • Marine ecotoxicity: Lack of evaluation method • System changes: Generally disregarded • However: • All but one study calculate CO2 • 2/3 studies calculate non-GHG emissions • Several studies cover a range of environmental impact categories

  12. Contents • Background • Review of LCA literature Environmental input-output analysis • Conclusions

  13. What is input-output analysis? • Economic method used to analyze the industry relationships in an economy • System of linear equations representing monetary flows • Developed by Wassily Leontief in the 1930s • Resurgence due to environmental applications

  14. Capital Raw Raw Capital Capital Capital Capital Raw Energy Energy Raw Capital Raw Raw Energy Capital Capital Raw Energy Energy Raw Capital Raw Energy Capital Capital Raw Raw Raw Energy Capital Raw Energy Capital Raw Energy Capital Energy Raw Energy Capital Raw Capital Energy Energy Capital Raw Capital Capital Raw Capital Raw Raw Raw Energy Raw Energy Capital Energy Energy Raw Raw Raw Raw Capital Raw Energy Energy Energy Capital Capital Energy Raw Raw Capital Capital Capital Energy Energy Raw Capital Capital Capital Capital Raw Raw Raw B Raw A Capital Capital Capital Capital Raw Raw Energy Raw Energy Capital Capital Raw Raw Energy Raw Raw Raw Energy Capital Capital Energy Raw Capital Raw Raw Raw Capital Capital Energy Manuf. Capital Raw Energy Raw Energy Raw Capital Capital Capital Capital Capital Raw Raw Raw Energy Capital Energy Energy Energy Capital Capital Energy Use Raw Capital Capital Raw Capital Raw Raw Capital Energy Capital Energy Capital Capital Raw Energy Raw Raw Energy Raw Raw Energy Raw Capital Capital Capital Capital Raw Capital Raw Capital Raw Disp. Raw Energy Capital Capital Energy Raw Energy Raw Capital Energy Raw Capital Capital Raw Capital Capital Raw Raw Raw Energy Raw Energy Capital Energy Raw Energy Raw Energy Capital Capital Capital Raw Raw Raw Raw Raw Raw Raw Raw Raw Raw Raw Raw Raw Raw Raw Raw Raw Raw Raw Raw Raw Raw Raw Raw Raw Raw Raw Raw Raw Raw Energy Capital Energy Energy Energy Energy Energy Energy Energy Energy Energy Energy Energy Energy Energy Energy Energy Energy Energy Energy Energy Energy Energy Energy Energy Energy Energy Energy Energy Energy Energy Energy Energy Energy Capital Energy Energy Energy Energy Energy Energy Energy Energy Energy Energy Energy Energy Energy Energy Energy Energy Energy Energy Energy Energy Energy Energy Energy Energy Energy Energy Energy Energy Energy Energy Capital Capital Capital Capital Capital Capital Capital Capital Capital Capital Capital Capital Capital Capital Capital Capital Capital Capital Capital Capital Capital Capital Capital Capital Capital Capital Capital Capital Capital Capital Capital Capital Raw Raw Raw Raw Raw Raw Raw Raw Raw Raw Raw Raw Raw Raw Raw Raw Raw Raw Raw Raw Raw Raw Raw Raw Raw Raw Raw Raw Raw Raw Raw Raw Capital Capital Capital Capital Capital Capital Capital Capital Capital Capital Capital Capital Capital Capital Capital Capital Capital Capital Capital Capital Capital Capital Capital Capital Capital Capital Capital Capital Capital Capital Capital Capital Raw Energy Capital Energy Energy Raw Raw Raw Raw Raw Raw Raw Raw Raw Raw Raw Raw Raw Raw Raw Raw Raw Raw Raw Raw Raw Raw Raw Raw Raw Raw Raw Raw Raw Raw Raw Capital Capital Everything is connected

  15. How is input-output analysis relevant for LCA? • Complete system coverage • Possibility for tracking all repercussions in the economy • Generic data as proxy for process-specific data • Drawback: High aggregation levels • Hybrid IO/LCA: Exploiting the advantages of both methods

  16. Preliminary IO calculations Data and assumptions • Multi-regional input-output model • 64x64 IO tables for 23 European countries • 57x57 IO tables for 8 rest of the world regions • Cost assumptions of offshore wind power • Investment costs: 2200 €/kW • Capacity factor: 38% • Lifetime: 25 years • Variable costs: 1.5 €cent/kWh • Cost breakdown based on external cost studies

  17. Preliminary IO calculations

  18. Conclusions • The reviewed LCA studies agree that wind power does indeed represent a clean alternative to fossil power • Applies to onshore and offshore wind farms alike • Recycling of metals and blade material may yield considerable emissions savings and reduce waste

  19. Conclusions (2) • System changes should be taken into consideration • Grid upgrades • Altered operation of thermal plants • Assessments can be further developed using IO techniques • Avoid truncation errors • Trace all economic repercussions • Marine ecotoxicity: Inadequately investigated

More Related