Computational Analysis of Fire Dynamics Inside a Wind Turbine

Wind turbines are generally considered cost-effective, reliable and sustainable energy sources. Fires are not common in wind turbines, but a significant number of fires occur every year due to the large number of turbines installed. Wind turbine fires are difficult to extinguish hence significant da...

Full description

Saved in:
Bibliographic Details
Published inFire technology Vol. 53; no. 5; pp. 1933 - 1942
Main Authors Rengel, B., Pastor, E., Hermida, D., Gómez, E., Molinelli, L., Planas, E.
Format Journal Article Publication
LanguageEnglish
Published New York Springer US 01.09.2017
Springer Nature B.V
Subjects
Aerogeneradors
Alternative energy
CFD
Characterization and Evaluation of Materials
Civil Engineering
Classical Mechanics
Compartment fires
Computer applications
Computer simulation
Emergency procedures
Energy sources
Engineering
Enginyeria química
Fire
Fire damage
Fire hazards
Fire protection
Fires
Foc
Hazard assessment
Impacte ambiental
Modelling
Physics
Renewable energy
Short Communication
Sustainability
Temperature effects
Turbines
Visibility
Wind power
Wind power generation
Wind turbines
Àrees temàtiques de la UPC
CFD
Compartment fires
Modelling
Online AccessGet full text

Cover

More Information
Summary:Wind turbines are generally considered cost-effective, reliable and sustainable energy sources. Fires are not common in wind turbines, but a significant number of fires occur every year due to the large number of turbines installed. Wind turbine fires are difficult to extinguish hence significant damage is expected. Due to the unmanned operation, the probability of a turbine being occupied during a fire is very low. However, operators can do several tasks every week, and hence be exposed to a certain risk. Moreover, there is a general lack of information about how a fire develops inside a wind turbine and the subsequent evolution of the tenability conditions during the time required for an eventual evacuation. Gamesa has been working on fire safety since 2013, using CFD fire modelling to provide insights on wind turbine fire development for the design of emergency procedures. The paper describes a fire hazard analysis performed in a Gamesa’s 2.5 MW turbine. A CFD simulation is carried out to estimate the effects during the first minutes of a typical wind turbine fire in an electrical cabinet. Results show that average oxygen concentration at the nacelle remains above 19.5% during the first 10 min; temperature remains below 60°C for 12 min if measured at 1.5 m; and visibility is on average assured at heights lower than 1.5 m, with values above 5 m during the first 8 min in worse locations, implying no danger for personnel. The potential of this type of analysis to design safer wind turbines under performance-based approaches is clearly demonstrated.
ISSN:0015-2684
1572-8099
DOI:10.1007/s10694-017-0664-0