Abstract
Electricity is perhaps the most versatile energy carrier in modern economies, and it is therefore fundamentally linked to human and economic development. Electricity growth has outpaced that of any other fuel, leading to ever-increasing shares in the overall mix. This trend is expected to continue throughout the following decades, with large – especially rural – segments of the world population in developing countries climbing the “energy ladder” and becoming connected to power grids (UNDP, World energy assessment: 2004 update. United Nations Development Programme, New York, 2004). Electricity therefore deserves particular attention with regard to its contribution to global greenhouse gas emissions, which is reflected in the ongoing development of low-carbon technologies for power generation. The main purpose of this chapter is to provide a bridge between detailed technical reports and broad resource and economic assessments on wind power. The following aspects of wind energy are covered: the global potential of the wind resource, technical principles of wind energy converters, capacity and load characteristics, life-cycle characteristics, current scale of deployment, contribution to global electricity supply, cost of electricity output, and future technical challenges. Wind power is the second-strongest-growing of renewable electricity technologies, with recent annual growth rates of about 34 %. The technology is mature and simple, and decades of experience exist in a few countries. Due to strong economies of scale, wind turbines have grown to several megawatts per device, and wind farms have now been deployed offshore. The wind energy industry is still small but competitive: 120 GW of installed wind power contributes only about 1.5 % or 260 TWh to global electricity generation at average capacity factors of around 25 % and levelized costs between 3 and 7 US¢/kWh, including additional costs brought about by the variability of the wind resource. The technical potential of wind is larger than current global electricity consumption, but the main barrier to widespread wind power deployment is wind variability, which poses limits to grid integration at penetration rates above 20 %. Life-cycle emissions for wind power alone are among the lowest for all technologies; however, in order to compare wind energy in a systems view, one needs to consider its low capacity credit: adding emissions from fossil-fuel balancing and peaking reserves that are required to maintain overall systems reliability places wind power at about 65 g/kWh. Wind power’s contribution to twenty-first-century emission abatement is potentially large at 450–500 Gt CO2.
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References
Ackermann T, Söder L (2002) An overview of wind energy – status 2002. Renew Sustain Energy Rev 6:67–128
Archer CL, Jacobson MZ (2003) Spatial and temporal distributions of U.S. winds and wind power at 80 m derived from measurements. J Geophys Res 108:1–20
Archer CL, Jacobson MZ (2005) Evaluation of global wind power. J Geophys Res 110:1–20
Archer CL, Jacobson MZ (2007) Supplying baseload power and reducing transmission requirements by interconnecting wind farms. J Appl Meteorol Climatol 46:1701–1717
AWEA (2009) Wind energy basics. American Wind Energy Association. www.awea.org/faq/wwt_basics.html
Benitez LE, Benitez PC, Van Kooten GC (2008) The economics of wind power with energy storage. Energy Econ 30:1973–1989
Blanco MI (2008) The economics of wind energy. Renew Sustain Energy Rev 13:1372–1382
Bolinger M, Wiser R (2009) Wind power price trends in the United States: struggling to remain competitive in the face of strong growth. Energy Policy 37:1061–1071
Carolin Mabel M, Fernandez E (2008) Growth and future trends of wind energy in India. Renew Sustain Energy Rev 12:1745–1757
Changliang X, Zhanfeng S (2009) Wind energy in China: current scenario and future perspectives. Renew Sustain Energy Rev 13:1966–1974
DeCarolis JF, Keith DW (2006) The economics of large-scale wind power in a carbon constrained world. Energy Policy 34:395–410
Diesendorf M (2007) The base-load fallacy. www.energyscience.org.au
Firestone J, Kempton W (2007) Public opinion about large offshore wind power: underlying factors. Energy Policy 35:1584–1598
Focken U, Lange M. German forecasting company. Energy & Meteo systems. Accessed on 23 March 2015. www.energymeteo.de
Golding EW (1997) The generation of electricity by wind power. E & FN Spon, London
GWEC (2008) Global wind energy outlook. Global Wind Energy Council, Brussels
Hirst E, Hild J (2004) The value of wind power as a function of wind capacity. Electr J 17:11–20
Holttinen H (2008) Estimating the impacts of wind power on power systems – summary of IEA wind collaboration. Environ Res Lett 3:1–6
Holttinen H, Milligan M, Kirby B, Acker T, Neimane V, Molinski T (2008) Using standard deviation as a measure of increased operational reserve requirement for wind power. Wind Eng 32:355–378
Holttinen H, Meibom P, Orths A, van Hulle F, Lange B, Malley MO, Pierik J, Ummels B, Olav Tande J, Estanqueiro A, Matos M, Gomez E, Söder L, Strbac G, Shakoor A, Ricardo J, Charles Smith J, Milligan M, Ela E (2009) Design and operation of power systems with large amounts of wind power, VTT research notes, 2493. VTT Technical Research Centre of Finland, Espoo
Hoogwijk MM, De Vries BJM, Turkenburg WC (2004) Assessment of the global and regional geographical, technical and economic potential of onshore wind energy. Energy Econ 26:889–919
Hoogwijk MM, Van Vuuren D, De Vries BJM, Turkenburg WC (2007) Exploring the impact on cost and electricity production of high penetration levels of intermittent electricity in OECD Europe and the USA, results for wind energy. Energy 32:1381–1402
IEA (2008a) Energy technology perspectives. International Energy Agency, Paris
IEA (2008b) Wind renewable energy essentials. OECD/IEA, Paris
Ilex X, Strbac G (2002) Quantifying the system cost of additional renewables in 2020. Ilex Energy Consulting, Oxford
Jha A (2009) Brawny wind turbines set for German offshore debut. The Guardian Weekly, 30 Jan 2010
Joselin Herbert GM, Iniyan S, Sreevalsan E, Rajapandian S (2007) A review of wind energy technologies. Renew Sustain Energy Rev 11:1117–1145
Kempton W, Archer CL, Dhanju A, Garvine RW, Jacobson MZ (2007) Large CO2 reductions via offshore wind power matched to inherent storage in energy end-uses. Geophys Res Lett 34:1–5
Lenzen M (2010) Current state of development of electricity-generating technologies: a literature review. Energies 3(3):462–591
Lenzen M, Badcock J (2009) Current state of development of electricity-generating technologies – a literature review. Centre for Integrated Sustainability Analysis, The University of Sydney, Sydney. www.aua.org.au/Content/Lenzenreport.aspx
Lenzen M, Munksgaard J (2002) Energy and CO2 analyses of wind turbines – review and applications. Renew Energy 26:339–362
Lenzen M, Wachsmann U (2004) Wind energy converters in Brazil and Germany: an example for geographical variability in LCA. Appl Energy 77:119–130
Lund H (2005) Large-scale integration of wind power into different energy systems. Energy 30:2402–2412
Lund H, Kempton W (2008) Integration of renewable energy into the transport and electricity sectors through V2G. Energy Policy 36:3578–3587
Martin B, Diesendorf M (1980) Calculating the capacity credit of wind power. In: Proceedings of the Fourth Biennial Conference of the Simulation Society of Australia, Brisbane, 27-29
Martin B, Diesendorf M (1982) Optimal mix in electricity grids containing wind power. Electr Power Energy Syst 4:155–161
Milligan M, Porter K (2008) Determining the capacity value of wind: an updated survey of methods and implementation. In: Conference paper, NREL/CP-500-43433. National Renewable Energy Laboratory, Golden
NREL (2001) The history and state of the art of variable-speed wind turbine technology. Technical report, NREL/TP-500-28607. National Renewable Energy Laboratory
NREL (2006) Wind turbine design cost and scaling model. Technical report, NREL/TP-500-40566. National Renewable Energy Laboratory
Østergaard PA (2003) Transmission grid requirements wit scattered and fluctuating renewable electricity-sources. Appl Energy 76:247–255
Østergaard PA (2008) Geographic aggregation and wind power output variance in Denmark. Energy 33:1453–1460
Oswald J, Raine M, Ashraf-Ball H (2008) Will British weather provide reliable electricity? Energy Policy 36:3212–3225
Pavlak A (2008) The economic value of wind energy. Electr J 21:46–50
Pehnt M, Oeser M, Swider DJ (2008) Consequential environmental system analysis of expected offshore wind electricity production in Germany. Energy 33:747–759
Peterson EW, Hennessey JP (1978) On the use of power laws for estimates of wind power potential. J Appl Meteorol 17:390–394
Resch G, Held A, Faber T, Panzer C, Toro F, Haas R (2008) Potentials and prospects for renewable energies at global scale. Energy Policy 36:4048–4056
Rohrig K. Fraunhofer Institut für Windenergie und Energiesystemtechnik. IWES. www.iwes.fraunhofer.de
Roth H, Brückl O, Held A (2005) Windenergiebedingte CO2-Emissionen konventioneller Kraftwerke, lfE-Schriftenreihe, Heft 50. Lehrstuhl für Energiewirtschaft und Anwendungstechnik, München
Sahin AD (2004) Progress and recent trends in wind energy. Prog Energy Combust Sci 30(5):501–543
Sesto E, Casale C (1998) Exploitation of wind as an energy source to meet the world’s electricity demand. J Wind Eng Ind Aerodyn 74–76:375–387
Shackleton J (2009) World first for Scotland gives engineering student a history lesson. The Robert Gordon University. www.rgu.ac.uk/pressrel/BlythProject.doc
Smit T, Junginger M, Smits R (2007) Technological learning in offshore wind energy: different roles of the government. Energy Policy 35:6431–6444
Smith JC, Milligan M, DeMeo EA, Parsons B (2007) Utility wind integration and operating impact state of the art. IEEE Trans Power Syst 22:900–908
Snyder B, Kaiser MJ (2009) Ecological and economic cost-benefit analysis of offshore wind energy. Renew Energy 34:1567–1578
Söder L (2004) On limits for wind power generation. Int J Global Energy Issues 21:243–254
Söder L, Hofmann L, Orths A, Holttinen H, Y-h W, Tuohy A (2007) Experience from wind integration in some high penetration areas. IEEE Trans Energy Convers 22:4–12
Sovacool BK, Lindboe HH, Odgaard O (2008) Is the Danish wind energy model replicable for other countries? Electr J 21:27–28
Strbac G, Shakoor A, Black M, Pudjianto D, Bopp T (2007) Impact of wind generation on the operation and development of the UK electricity systems. Electr Power Syst Res 77:1214–1227
Tavner P (2008) Wind power as a clean-energy contributor. Energy Policy 36:4397–4400
Thresher R, Dodge D (1998) Trends in the evolution of wind turbine generator configurations and systems. Wind Energy 1:70–85
U.S. Department of Energy, Black & Veatch and AWEA (2008) 20 % Wind energy by 2030. DOE/GO-102008-2567, U.S. Department of Energy, Oak Ridge
UNDP (2004) World energy assessment: 2004 update. United Nations Development Programme, New York
Wagner H-J, Pick E (2004) Energy yield ratio and cumulative energy demand for wind energy converters. Energy 29:2289–2295
Weigt H (2008) Germany’s wind energy: the potential for fossil capacity replacement and cost saving. Appl Energy 86:1857–1863
Welch JB, Venkateswaran A (2008) The dual sustainability of wind energy. Renew Sustain Energ Rev 12(9):2265–2300
WWEA (2008) World wind energy report. World Wind Energy Association, Bonn. www.wwindea.org
Wyatt A (1986) Electric power: challenges and choices. Book Press, Toronto
Zoellner J, Schweizer-Ries P, Wemheuer C (2008) Public acceptance of renewable energies: results from case studies in Germany. Energy Policy 36:4136–4141
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Lenzen, M., Baboulet, O. (2017). Wind Energy. In: Chen, WY., Suzuki, T., Lackner, M. (eds) Handbook of Climate Change Mitigation and Adaptation. Springer, Cham. https://doi.org/10.1007/978-3-319-14409-2_34
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