Free Standard AU & NZ Shipping For All Book Orders Over $80!
Register      Login
International Journal of Wildland Fire International Journal of Wildland Fire Society
Journal of the International Association of Wildland Fire
RESEARCH ARTICLE (Open Access)

Wildland firefighters’ thermal exposure in relation to suppression tasks

Belén Carballo-Leyenda A , José G. Villa A , Jorge López-Satué B and Jose A. Rodríguez-Marroyo A C
+ Author Affiliations
- Author Affiliations

A VALFIS Research Group, Institute of Biomedicine (IBIOMED), University of León, Campus de Vegazana s/n, 24071, León, Spain.

B Empresa de Transformación Agraria (TRAGSA), Maldonado, 58, 28006, Madrid, Spain.

C Corresponding author. Email: j.marroyo@unileon.es

International Journal of Wildland Fire 30(7) 475-483 https://doi.org/10.1071/WF20076
Submitted: 29 May 2020  Accepted: 20 April 2021   Published: 14 May 2021

Journal Compilation © IAWF 2021 Open Access CC BY-NC-ND

Abstract

The main purpose of this study was to characterise the thermal environment and risk of heat burns of wildland firefighters in relation to the suppression tasks performed in real wildland fires. Measurements of air temperature and heat flux were performed by affixing heat flux and ambient temperature sensors on the outer and inner surface of the wildland firefighters’ protective garments. Suppression time was divided according to the task performed in direct attack, backfire, mop-up and patrol. These tasks accounted for 95.2 ± 78.4, 103.3 ± 41.7, 80.5 ± 24.8 and 71.3 ± 53.0 min, respectively. Overall, the mean heat flux was higher during backfire (2165 ± 1604 W m−2) than in direct attack (558 ± 344 W m−2), mop-up (371 ± 254 W m−2) and patrol (354 ± 307 W m−2). However, during the direct attack, average and maximum thermal dose was ~94 and ~110 (kW m−2)4/3 s, respectively. These values are within the threshold of pain and first-degree burns. However, no first-degree burns were reported for the sample. Overall, the thermal exposure measured may be considered light. However, high thermal exposure values may be obtained at specific moments, which may cause first-degree burns in wildland firefighters.

Keywords: wildland fire, heat flux, thermal dose, heat stress, skin burns, thermal environment, firefighters, exposure.


References

Albini FA (1986) Wildland fire spread by radiation – a model including fuel cooling by natural convection. Combustion Science and Technology 45, 101–113.
Wildland fire spread by radiation – a model including fuel cooling by natural convection.Crossref | GoogleScholarGoogle Scholar |

Alexander ME, De Groot WJ (1988) Fire behavior in jack pine stands as related to the Canadian Forest Fire Weather Index (FWI) System. Canadian Forest Service North (Edmonton, Alberta).

Anderson WR, Catchpole EA, Butler BW (2010) Convective heat transfer in fire spread through fine fuel beds. International Journal of Wildland Fire 19, 284–298.
Convective heat transfer in fire spread through fine fuel beds.Crossref | GoogleScholarGoogle Scholar |

Apud E, Meyer F, Maureira F (2002) ‘Ergonomía en el combate de incendios forestales.’ (Universidad de Concepción: Chile).

Arnaldos Viger J, Navalón Novell X, Pastor Ferrer E, Planas Cuchi E, Zárate López L (2004) ‘Manual de ingeniería básica para la prevención y extinción de incendios forestales.’ (Institut d’Edicions de la Diputació de Barcelona, Mundi-Prensa: Barcelona)

Bröde P, Kuklane K, Candas V, Hartog EA, Den , Griefahn B, Holmér I, Meinander H, Nocker W, Richards M, Havenith G (2010) Heat gain from thermal radiation through protective clothing with different insulation, reflectivity and vapour permeability. International Journal of Occupational Safety and Ergonomics 16, 231–244.
Heat gain from thermal radiation through protective clothing with different insulation, reflectivity and vapour permeability.Crossref | GoogleScholarGoogle Scholar | 20540842PubMed |

Brotherhood JR, Budd GM, Hendrie AL, Jeffery SE, Beasley FA, Costin BP, Zhienl W, Baker MM, Cheney NP, Dawson MP (1997) Project Aquarius 3. Effects of work rate on the productivity, energy expenditure, and physiological responses of men building fireline with a rakehoe in dry eucalypt forest. International Journal of Wildland Fire 7, 87–98.
Project Aquarius 3. Effects of work rate on the productivity, energy expenditure, and physiological responses of men building fireline with a rakehoe in dry eucalypt forest.Crossref | GoogleScholarGoogle Scholar |

Bruce-Low SS, Cotterrell D, Jones GE (2007) Effect of wearing personal protective clothing and self-contained breathing apparatus on heart rate, temperature and oxygen consumption during stepping exercise and live fire training exercises. Ergonomics 50, 80–98.
Effect of wearing personal protective clothing and self-contained breathing apparatus on heart rate, temperature and oxygen consumption during stepping exercise and live fire training exercises.Crossref | GoogleScholarGoogle Scholar | 17178653PubMed |

Budd G, Brotherhood J, Hendrie A, Jeffery S, Beasley F, Costin B, Zhien W, Baker M, Cheney N, Dawson M (1997) Project Aquarius 6. Heat load from exertion, weather, and fire in men suppressing wildland fires. International Journal of Wildland Fire 7, 119–131.
Project Aquarius 6. Heat load from exertion, weather, and fire in men suppressing wildland fires.Crossref | GoogleScholarGoogle Scholar |

Butler BW (2014) Wildland firefighter safety zones: a review of past science and summary of future needs. International Journal of Wildland Fire 23, 295–308.
Wildland firefighter safety zones: a review of past science and summary of future needs.Crossref | GoogleScholarGoogle Scholar |

Butler BW, Cohen JD (1998) Firefighter safety zones: A theoretical model based on radiative heating. International Journal of Wildland Fire 8, 73–77.
Firefighter safety zones: A theoretical model based on radiative heating.Crossref | GoogleScholarGoogle Scholar |

Butler BW, Cohen J, Latham D, Schuette RD, Sopko P, Shannon KS, Jimenez D, Bradshaw LS (2004) Measurements of radiant emissive power and temperatures in crown fires. Canadian Journal of Forest Research 34, 1577–1587.
Measurements of radiant emissive power and temperatures in crown fires.Crossref | GoogleScholarGoogle Scholar |

Carballo-Leyenda B, Villa JG, López-Satué J, Rodríguez-Marroyo JA (2017) Impact of different personal protective clothing on wildland firefighters’ physiological strain. Frontiers in Physiology 8, 618
Impact of different personal protective clothing on wildland firefighters’ physiological strain.Crossref | GoogleScholarGoogle Scholar | 28894421PubMed |

Carballo-Leyenda B, Villa JG, López-Satué J, Collado PS, Rodríguez-Marroyo JA (2018) Fractional contribution of wildland firefighters’ personal protective equipment on physiological strain. Frontiers in Physiology 9, 1139
Fractional contribution of wildland firefighters’ personal protective equipment on physiological strain.Crossref | GoogleScholarGoogle Scholar | 30154736PubMed |

Carballo-Leyenda B, Villa JG, López-Satué J, Rodriguez Marroyo JA (2019) Characterising wildland firefighters’ thermal environment during live-fire suppression. Frontiers in Physiology 10, 949
Characterising wildland firefighters’ thermal environment during live-fire suppression.Crossref | GoogleScholarGoogle Scholar | 31427982PubMed |

Cheuvront SN, Kenefick RW, Montain SJ, Sawka MN (2010) Mechanisms of aerobic performance impairment with heat stress and dehydration. Journal of Applied Physiology 109, 1989–1995.
Mechanisms of aerobic performance impairment with heat stress and dehydration.Crossref | GoogleScholarGoogle Scholar | 20689090PubMed |

Cuddy JS, Ruby BC (2011) High work output combined with high ambient temperatures caused heat exhaustion in a wildland firefighter despite high fluid intake. Wilderness & Environmental Medicine 22, 122–125.
High work output combined with high ambient temperatures caused heat exhaustion in a wildland firefighter despite high fluid intake.Crossref | GoogleScholarGoogle Scholar |

Cuddy JS, Sol JA, Hailes WS, Ruby BC (2015) Work patterns dictate energy demands and thermal strain during wildland firefighting. Wilderness & Environmental Medicine 26, 221–226.
Work patterns dictate energy demands and thermal strain during wildland firefighting.Crossref | GoogleScholarGoogle Scholar |

Donoho DL, Johnstone IM (1994) Ideal spatial adaptation by wavelet shrinkage. Biometrika 81, 425–455.
Ideal spatial adaptation by wavelet shrinkage.Crossref | GoogleScholarGoogle Scholar |

Eglin CM, Coles S, Tipton MJ (2004) Physiological responses of firefighter instructors during training exercises. Ergonomics 47, 483–494.
Physiological responses of firefighter instructors during training exercises.Crossref | GoogleScholarGoogle Scholar | 15204300PubMed |

Foster JA, Roberts GV (1994) Measurements of the firefighting environment. (Fire Research Development Group: London) Available at https://www.ukfrs.com/sites/default/files/2017-09/Measurements of the Firefighting Environment.pdf.

Frankman D, Webb BW, Butler BW (2010) Time-resolved radiation and convection heat transfer in combusting discontinuous fuel beds. Combustion Science and Technology 182, 1391–1412.
Time-resolved radiation and convection heat transfer in combusting discontinuous fuel beds.Crossref | GoogleScholarGoogle Scholar |

Frankman D, Webb BW, Butler BW, Jimenez D, Forthofer JM, Sopko P, Shannon KS, Hiers JK, Ottmar RD (2013) Measurements of convective and radiative heating in wildland fires. International Journal of Wildland Fire 22, 157–167.
Measurements of convective and radiative heating in wildland fires.Crossref | GoogleScholarGoogle Scholar |

Gradolewski D, Redlarski G (2014) Wavelet-based denoising method for real phonocardiography signal recorded by mobile devices in noisy environment. Computers in Biology and Medicine 52, 119–129.
Wavelet-based denoising method for real phonocardiography signal recorded by mobile devices in noisy environment.Crossref | GoogleScholarGoogle Scholar | 25038586PubMed |

Hendrie AL, Brotherhood JR, Budd GM, Jeffery SE, Beasley FA, Costin BP, Zhien W, Baker MM, Cheney NP, Dawson MP (1997) Project Aquarius 8. Sweating, drinking, and dehydration in men suppressing wildland fires. International Journal of Wildland Fire 7, 145–148.
Project Aquarius 8. Sweating, drinking, and dehydration in men suppressing wildland fires.Crossref | GoogleScholarGoogle Scholar |

Horn GP, DeBlois J, Shalmyeva I, Smith DL (2012) Quantifying dehydration in the fire service using field methods and novel devices. Prehospital Emergency Care 16, 347–355.
Quantifying dehydration in the fire service using field methods and novel devices.Crossref | GoogleScholarGoogle Scholar | 22443314PubMed |

Horn GP, Kesler RM, Kerber S, Fent KW, Schroeder TJ, Scott WS, Fehling PC, Fernhall B, Smith DL (2018) Thermal response to firefighting activities in residential structure fires: impact of job assignment and suppression tactic. Ergonomics 61, 404–419.
Thermal response to firefighting activities in residential structure fires: impact of job assignment and suppression tactic.Crossref | GoogleScholarGoogle Scholar | 28737481PubMed |

Kinsman P (1991) Major Hazard Assessment: Survey of Current Methodologies and Information Sources. Specialist Inspector Reports No. 29. Health and Safety Executive. (Surrey, UK)

Krasny J, Rockett JA, Huang D (1988) Protecting firefighters exposed in room fires: Comparison of results of bench scale test for thermal protection and conditions during room flashover. Fire Technology 24, 5–19.
Protecting firefighters exposed in room fires: Comparison of results of bench scale test for thermal protection and conditions during room flashover.Crossref | GoogleScholarGoogle Scholar |

Lawson JR (2009) Fire facts. NIST Special Publication 1102. Heat Flux, Temperature, & Thermal Response. (Gaithersburg, MD) Available at https://www.nist.gov/publications/fire-facts.

McLellan TM, Daanen HAM, Cheung SS (2013) Encapsulated environment. Comprehensive Physiology 3, 1363–1391.
Encapsulated environment.Crossref | GoogleScholarGoogle Scholar | 23897690PubMed |

Morvan D, Meradji S, Mell W (2013) Interaction between head fire and backfire in grasslands. Fire Safety Journal 58, 195–203.
Interaction between head fire and backfire in grasslands.Crossref | GoogleScholarGoogle Scholar |

O’Sullivan S, Jagger S (2004) Human vulnerability to thermal radiation offshore. HSL/2004/04. Health and Safety Executive. (Surrey, UK)

Parsons RA, Butler BW, Mell W (2014) Safety zones and convective heat: numerical simulation of potential burn injury from heat sources influenced by slopes and winds. In ‘Advances in Forest Fires Research’. (Ed DX Viegas) pp. 1500–1507. (Imprensa da Universidade de Coimbra: Coimbra, Portugal)10.14195/978-989-26-0884-6_165

Raimundo AM, Figueiredo AR (2009) Personal protective clothing and safety of firefighters near a high intensity fire front. Fire Safety Journal 44, 514–521.
Personal protective clothing and safety of firefighters near a high intensity fire front.Crossref | GoogleScholarGoogle Scholar |

Raj PK (2008) Field tests on human tolerance to (LNG) fire radiant heat exposure, and attenuation effects of clothing and other objects. Journal of Hazardous Materials 157, 247–259.
Field tests on human tolerance to (LNG) fire radiant heat exposure, and attenuation effects of clothing and other objects.Crossref | GoogleScholarGoogle Scholar | 18291577PubMed |

Rodríguez-Marroyo JA, Villa JG, López-Satue J, Pernía R, Carballo B, García-López J, Foster C (2011) Physical and thermal strain of firefighters according to the firefighting tactics used to suppress wildfires. Ergonomics 54, 1101–1108.
Physical and thermal strain of firefighters according to the firefighting tactics used to suppress wildfires.Crossref | GoogleScholarGoogle Scholar | 22026953PubMed |

Rodríguez-Marroyo JA, López-Satue J, Pernía R, Carballo B, García-López J, Foster C, Villa JG (2012) Physiological work demands of Spanish wildland firefighters during wildfire suppression. International Archives of Occupational and Environmental Health 85, 221–228.
Physiological work demands of Spanish wildland firefighters during wildfire suppression.Crossref | GoogleScholarGoogle Scholar | 21656120PubMed |

Rossi RM (2003) Fire fighting and its influence on the body. Ergonomics 46, 1017–1033.
Fire fighting and its influence on the body.Crossref | GoogleScholarGoogle Scholar |

Ruby BC, Shriver TC, Zderic TW, Sharkey BJ, Burks C, Tysk S (2002) Total energy expenditure during arduous wildfire suppression. Medicine and Science in Sports and Exercise 34, 1048–1054.
Total energy expenditure during arduous wildfire suppression.Crossref | GoogleScholarGoogle Scholar | 12048336PubMed |

Song G, Paskaluk S, Sati R, Crown EM, Doug Dale J, Ackerman M (2011) Thermal protective performance of protective clothing used for low radiant heat protection. Textile Research Journal 81, 311–323.
Thermal protective performance of protective clothing used for low radiant heat protection.Crossref | GoogleScholarGoogle Scholar |

Wieczorek CJ, Dembsey NA (2001) Human variability correction factors for use with simplified engineering tools for predicting pain and second degree skin burns. Journal of Fire Protection Engineering 11, 88–111.
Human variability correction factors for use with simplified engineering tools for predicting pain and second degree skin burns.Crossref | GoogleScholarGoogle Scholar |

Willi JM, Horn GP, Madrzykowski D (2016) Characterising a firefighter’s immediate thermal environment in live-fire training scenarios. Fire Technology 52, 1667–1696.
Characterising a firefighter’s immediate thermal environment in live-fire training scenarios.Crossref | GoogleScholarGoogle Scholar |

Yang C, He Z, Yu W (2009) Comparison of public peak detection algorithms for MALDI mass spectrometry data analysis. BMC Bioinformatics 10, 4
Comparison of public peak detection algorithms for MALDI mass spectrometry data analysis.Crossref | GoogleScholarGoogle Scholar | 19126200PubMed |

Zárate L, Arnaldos J, Casal J (2008) Establishing safety distances for wildland fires. Fire Safety Journal 43, 565–575.
Establishing safety distances for wildland fires.Crossref | GoogleScholarGoogle Scholar |