Abstract
Wind energy is considered a clean energy source, but produces negative impacts regarding avian mortality. The Barão de São João wind farm in Portugal’s Sagres region is part of an important migratory flyway, crossed by 5000 individuals of 30 soaring bird species every autumn. The wind farm’s licensing was conditioned to the implementation of rigorous mitigation procedures, namely a Radar Assisted Shutdown on Demand (RASOD) protocol to reduce the probability of bird casualties. A security perimeter with observers was aided by a radar system, detecting soaring birds approaching the wind farm. Turbines were to be turned-off when pre-defined criteria of intense migration or presence of threatened species were met. Turbine shutdown was operated by the wind farm staff after a request from the monitoring team (MT), or directly by the MT. Of the soaring birds crossing the wind farm, 55% were recorded at altitudes associated with high collision risk. However, due to RASOD, no soaring birds died from collisions during five consecutive autumns. The average annual shutdown period decreased continuously after the first year (105 h) reaching only 15 h when the MT was given direct access to shut down operations through SCADA (the remote system to monitor and control wind turbines). Shutdown period corresponded only to 0.2–1.2% of the equivalent hours in a year’s wind farm activity. The use of radar, direct access to SCADA and cumulative experience by the MT improved the procedure’s efficiency, allowing better judgments on the application of shutdown orders. Our results indicate that RASOD may be an essential tool in reconciling wind energy production with the conservation of soaring birds.
Keywords
- Shutdown
- Wind farm
- Turbine shutdown
- Collision risk
- Radar
- Soaring birds
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References
Atienza JC, Fierro IM, Infante O et al (2011) Directrices para la evaluación del impacto de los parques eólicos en aves y murciélagos (guidelines for assessing the impact of wind farms on birds and bats). SEO/BirdLife, Madrid
Barrios L, Rodríguez A (2004) Behavioural and environmental correlates of soar ing-bird mortality at on-shore wind turbines. J Appl Ecol 41:72–81. doi:10.1111/j.1365-2664.2004.00876.x
Bellebaum J, Korner-Nievergelt F, Dürr T, Mammen U (2013) Wind turbine fatalities approach a level of concern in a raptor population. J Nat Conserv 21:394–400. doi:10.1016/j.jnc.2013.06.001
Bernis F (1980) La migración de aves en el Estrecho de Gibraltar. Volumen I: Aves planeadoras. Universidad Complutense, Madrid
Bright J, Langston R, Bullman R et al (2008) Map of bird sensitivities to wind farms in Scotland: a tool to aid planning and conservation. Biol Conserv 141:2342–2356. doi:10.1016/j.biocon.2008.06.029
Canário F, Leitão AH, Tomé R (2012) Predation attempts by short-eared and long-eared owls on migrating songbirds attracted to artificial lights. J Raptor Res 46:232–234
Costa PAS (2004) Atlas do potencial eólico para Portugal Continental. Dissertation, Universidade de Lisboa, Lisbon
Dahl EL, Bevanger K, Nygård T et al (2012) Reduced breeding success in white-tailed eagles at Smøla wind farm, western Norway, is caused by mortality and displacement. Biol Conserv 145:79–85. doi:10.1016/j.biocon.2011.10.012
de la Cruz A, Onrubia A, Perez B et al (2011) Seguimiento de la migración de las aves en el estrecho de Gibraltar: resultados del Programa Migres 2009. Migres 2:65–78
de Lucas M, Janss GFE, Whitfield DP, Ferrer M (2008) Collision fatality of raptors in wind farms does not depend on raptor abundance. J Appl Ecol 45:1695–1703. doi:10.1111/j.1365-2664.2008.01549.x
de Lucas M, Ferrer M, Bechard MJ, Muñoz AR (2012) Griffon vulture mortality at wind farms in southern Spain: distribution of fatalities and active mitigation measures. Biol Conserv. doi:10.1016/j.biocon.2011.12.029
Drewitt AL, Langston RHW (2006) Assessing the impacts of wind farms on birds. Ibis 148:29–42. doi:10.1111/j.1474-919x.2006.00516.x
Ferrer M, De Lucas M, Janss GFE et al (2012) Weak relationship between risk assessment studies and recorded mortality in wind farms. J Appl Ecol 49:38–46. doi:10.1111/j.1365-2664.2011.02054.x
Finlayson C (1992) Birds of the strait of Gibraltar. Academic Press Inc., San Die go, California
Guil F, Fernández-Olalla M, Moreno-Opo R et al (2011) Minimising mortality in endangered raptors due to power lines: the importance of spatial aggregation to optimize the application of mitigation measures. PLoS ONE 6:1–9. doi:10.1371/journal.pone.0028212
IUCN (2015) IUCN red list of threatened species. Version 2.1. Available via http://www.iucnredlist.org. Accessed on 01 April 2015
Johnson GD, Strickland MD, Erickson WP et al (2008) Use of data to develop mitigation measures for wind power development impacts to birds. In: de Lucas M, Janss GFE, Ferrer M (eds) Birds and wind farms: risk assessment and mitigation. Quercus, Madrid, Spain
Kaldellis JK, Zafirakis D (2011) The wind energy (r)evolution: a short review of a long history. Renew Energy 36:1887–1901. doi:10.1016/j.renene.2011.01.002
Kuvlesky WP, Brennan LA, Morrison ML et al (2007) Wind energy development and wildlife conservation: challenges and opportunities. J Wildl Manage 71:2487–2498. doi:10.2193/2007-248
Lekuona JM, Ursúa C (2007) Avian mortality in wind power plants of Navarra (northern Spain). In: Birds and wind farms: risk assessment and mitigation. pp 177–192
Marques AT, Batalha H, Rodrigues S et al (2014) Understanding bird collisions at wind farms: an updated review on the causes and possible mitigation strategies. Biol Conserv 179:40–52. doi:10.1016/j.biocon.2014.08.017
Martin GR, Portugal SJ, Murn CP (2012) Visual fields, foraging and collision vulnerability in Gyps vultures. Ibis (Lond 1859) 154:626–631. doi:10.1111/j.1474-919X.2012.01227.x
Mellone U, Limiñana R, Mallia E, Urios V (2011) Extremely detoured migration in an inexperienced bird: interplay of transport costs and social interactions. J Avian Biol 42:468–472. doi:10.1111/j.1600-048X.2011.05454.x
Moreau JA, Monk J (1957) Autumn migration in south-west Portugal. Ibis 99:500–508
Newton I (2008) The migration ecology of birds. Academic Press, London
Orloff S, Flannery A (1992) Wind turbine effects on avian activity, habitat use, and mortality in Altamont Pass and Solano County Wind Resource Areas: 989–1991. California Energy Commission, Golden, CO, USA
Pires NM (2008) The use of radar as tool for studying bird migration and its role in environmental impact assessment—a pilot study in Portugal. Dissertation, Lisbon University, Lisbon
Redlinger RY, Dannemand P, Morthorst E (2002) Wind energy in the 21st century. Palagrave MacMillan, New York
Strandberg R, Klaassen RHG, Thorup K (2009) Spatio-temporal distribution of migrating raptors: a comparison of ringing and satellite tracking. J Avian Biol 40:500–510. doi:10.1111/j.1600-048X.2008.04571.x
Thelander CG, Smallwood KS (2007) The Altamont Pass wind resource area’s effect on birds: a case history. In: de Lucas M, Janss GFE, Ferrer M (eds) Birds and wind farms: risk assessment and mitigation. Quercus, Madrid
Tomé R, Costa H, Leitão D (1998) A migração outonal de aves planadoras na região de Sagres—resultados da campanha de 1994. SPEA, Lisbon
Vardanis Y, Klaassen RHG, Strandberg R, Alerstam T (2011) Individuality in bird migration: routes and timing. Biol Lett 7:502–505. doi:10.1098/rsbl.2010.1180
Zalles JL, Bildstein K (2000) Raptor watch: a global directory of raptor migration sites. BirdLife Conserv, London
Acknowledgements
We would like to thank the owner company of BSJ wind farm, E-ON, and all the collaborators that helped during fieldwork throughout this study.
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Tomé, R., Canário, F., Leitão, A.H., Pires, N., Repas, M. (2017). Radar Assisted Shutdown on Demand Ensures Zero Soaring Bird Mortality at a Wind Farm Located in a Migratory Flyway. In: Köppel, J. (eds) Wind Energy and Wildlife Interactions. Springer, Cham. https://doi.org/10.1007/978-3-319-51272-3_7
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