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Published in: Fire Technology 1/2014

01-01-2014

Characterization of Fuel Properties and Fire Spread Rates for Little Bluestem Grass

Authors: K. J. Overholt, J. Cabrera, A. Kurzawski, M. Koopersmith, O. A. Ezekoye

Published in: Fire Technology | Issue 1/2014

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Abstract

Rapid urban sprawl and population decentralization in recent decades have increased the size of the wildland-urban interface and resulted in higher community risk and vulnerability to wildfire. This paper primarily focuses on understanding grass-fueled fires common to Texas and improving the understanding of the physics and fire dynamics that are inherent in the grassland and prairie flame spread problem. Little bluestem (Schizachyrium scoparium) grass was chosen as the grassland fuel due to its prevalent coverage in the Texas area and its relevance to grassland fires in Texas. The methodology in this study relies on a framework to characterize fuel properties of little bluestem grass using small- and intermediate-scale experiments to better predict full-scale fire behavior. An intermediate-scale numerical flame spread model was developed for grass fuels that accounts for fuel moisture content to calculate the mass versus time of a burning little bluestem plant. The results of the small- and intermediate-scale experiments were used to develop input parameters for a field-scale numerical simulation of a grass field using a physics-based computational fire model, Wildland-urban interface Fire Dynamics Simulator (WFDS). A sensitivity analysis was performed to determine the effect of varying WFDS input parameters on the fire spread rate. The results indicate that the fuel moisture content had the most significant impact on the fire spread rate.

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Literature
1.
go back to reference Clements C (2007) Observing the dynamics of wildland grass fires: fireflux—a field validation experiment. Bull Am Meteorol Soc 1–14 Clements C (2007) Observing the dynamics of wildland grass fires: fireflux—a field validation experiment. Bull Am Meteorol Soc 1–14
2.
go back to reference Massada A, Radeloff V, Stewart S, Hawbaker T (2009) Wildfire risk in the wildland–urban interface: a simulation study in northwestern Wisconsin. For Ecol Manage 258(9):1990–1999CrossRef Massada A, Radeloff V, Stewart S, Hawbaker T (2009) Wildfire risk in the wildland–urban interface: a simulation study in northwestern Wisconsin. For Ecol Manage 258(9):1990–1999CrossRef
3.
go back to reference Gray R, Dunivan M, Jones J, Ridenour K, Leathers M, Stafford K (2007) Cross Plains, Texas wildland fire case study. Texas Forest Service, Lufkin Gray R, Dunivan M, Jones J, Ridenour K, Leathers M, Stafford K (2007) Cross Plains, Texas wildland fire case study. Texas Forest Service, Lufkin
5.
go back to reference Finney MA (2004) FARSITE: Fire area simulator—model development and evaluation. USDA Forest Service Research Paper, RMRS-RP-4 Revised Finney MA (2004) FARSITE: Fire area simulator—model development and evaluation. USDA Forest Service Research Paper, RMRS-RP-4 Revised
6.
go back to reference Mutlu M, Popescu S, Zhao K (2008) Sensitivity analysis of fire behavior modeling with LIDAR-derived surface fuel maps. For Ecol Manage 256(3):289–294CrossRef Mutlu M, Popescu S, Zhao K (2008) Sensitivity analysis of fire behavior modeling with LIDAR-derived surface fuel maps. For Ecol Manage 256(3):289–294CrossRef
7.
go back to reference Hardy C, Heilman W, Weise D, Goodrick S, Ottmar R (2008) Fire behavior science advancement plan Hardy C, Heilman W, Weise D, Goodrick S, Ottmar R (2008) Fire behavior science advancement plan
8.
go back to reference Mell W, Jenkins M, Gould J, Cheney P (2007) A physics-based approach to modelling grassland fires. Int J Wildland Fire 16(1):1–22CrossRef Mell W, Jenkins M, Gould J, Cheney P (2007) A physics-based approach to modelling grassland fires. Int J Wildland Fire 16(1):1–22CrossRef
9.
go back to reference Albini F (1976) Estimating wildfire behavior and effects. USDA Forest Service, intermountain forest and range experiment station, general technical report INT-30, p 92 Albini F (1976) Estimating wildfire behavior and effects. USDA Forest Service, intermountain forest and range experiment station, general technical report INT-30, p 92
10.
go back to reference Anderson H (1982) Aids to determining fuel models for estimating fire behavior. USDA Forest Service, intermountain forest and range experiment station. General technical report, INT-122, p 22 Anderson H (1982) Aids to determining fuel models for estimating fire behavior. USDA Forest Service, intermountain forest and range experiment station. General technical report, INT-122, p 22
11.
go back to reference Viney N (1991) A review of fine fuel moisture modelling. Int J Wildland Fire 1(4):215–234CrossRef Viney N (1991) A review of fine fuel moisture modelling. Int J Wildland Fire 1(4):215–234CrossRef
12.
go back to reference Bartoli P, Simeoni A, Biteau H, Torero JL, Santoni PA (2011) Determination of the main parameters influencing forest fuel combustion dynamics. Fire Saf J 46(1–2):27–33CrossRef Bartoli P, Simeoni A, Biteau H, Torero JL, Santoni PA (2011) Determination of the main parameters influencing forest fuel combustion dynamics. Fire Saf J 46(1–2):27–33CrossRef
13.
go back to reference Beer T (1993) The speed of a fire front and its dependence on wind-speed. Int J Wildland Fire 3(4):193–202CrossRef Beer T (1993) The speed of a fire front and its dependence on wind-speed. Int J Wildland Fire 3(4):193–202CrossRef
14.
go back to reference Allred K (1982) Describing the grass inflorescence. J Range Manage 35(5):672–675CrossRef Allred K (1982) Describing the grass inflorescence. J Range Manage 35(5):672–675CrossRef
15.
go back to reference Cheney N, Gould J, Catchpole W (1993) The influence of fuel, weather and fire shape variables on fire-spread in grasslands. Int J Wildland Fire 3(1):31–44CrossRef Cheney N, Gould J, Catchpole W (1993) The influence of fuel, weather and fire shape variables on fire-spread in grasslands. Int J Wildland Fire 3(1):31–44CrossRef
16.
go back to reference Mindykowski P, Fuentes A, Consalvi JL, Porterie B (2011) Piloted ignition of wildland fuels. Fire Saf J 46(1–2):34–40CrossRef Mindykowski P, Fuentes A, Consalvi JL, Porterie B (2011) Piloted ignition of wildland fuels. Fire Saf J 46(1–2):34–40CrossRef
17.
go back to reference Tran H, White R (1992) Burning rate of solid wood measured in a heat release rate calorimeter. Fire Mater 16(4):197–206CrossRef Tran H, White R (1992) Burning rate of solid wood measured in a heat release rate calorimeter. Fire Mater 16(4):197–206CrossRef
18.
19.
go back to reference Society of Fire Protection Engineers (2008) SFPE handbook of fire protection engineering, 4th edn. National Fire Protection Association, Quincy Society of Fire Protection Engineers (2008) SFPE handbook of fire protection engineering, 4th edn. National Fire Protection Association, Quincy
20.
go back to reference Anderson H, Rothermel R (1965) Influence of moisture and wind upon the characteristics of free-burning fires. In: Proceedings of symposium (international) on combustion, vol 10. Pittsburgh, pp 1009–1019 Anderson H, Rothermel R (1965) Influence of moisture and wind upon the characteristics of free-burning fires. In: Proceedings of symposium (international) on combustion, vol 10. Pittsburgh, pp 1009–1019
21.
go back to reference Cheney N, Gould J, Catchpole W (1998) Prediction of fire spread in grasslands. Int J Wildland Fire 8(1):1–13CrossRef Cheney N, Gould J, Catchpole W (1998) Prediction of fire spread in grasslands. Int J Wildland Fire 8(1):1–13CrossRef
22.
go back to reference Rehm R, McDermott R (2009) Mathematical modeling of wildland–urban interface fires. Paper presented at the mathematics and fire workshop, Zaragoza Rehm R, McDermott R (2009) Mathematical modeling of wildland–urban interface fires. Paper presented at the mathematics and fire workshop, Zaragoza
23.
go back to reference Sharples JJ, Mcrae RHD, Weber RO, Gill AM (2009) A simple index for assessing fuel moisture content. Environ Model Softw 24(5):637–646CrossRef Sharples JJ, Mcrae RHD, Weber RO, Gill AM (2009) A simple index for assessing fuel moisture content. Environ Model Softw 24(5):637–646CrossRef
24.
go back to reference Madrigal J, Guijarro M, Hernando C, Diez C, Marino E (2011) Estimation of peak heat release rate of a forest fuel bed in outdoor laboratory conditions. J Fire Sci 29(1):53–70CrossRef Madrigal J, Guijarro M, Hernando C, Diez C, Marino E (2011) Estimation of peak heat release rate of a forest fuel bed in outdoor laboratory conditions. J Fire Sci 29(1):53–70CrossRef
25.
go back to reference Mell W, Maranghides A, McDermott R, Manzello S (2009) Numerical simulation and experiments of burning douglas fir trees. Combust Flame 156(10):2023–2041CrossRef Mell W, Maranghides A, McDermott R, Manzello S (2009) Numerical simulation and experiments of burning douglas fir trees. Combust Flame 156(10):2023–2041CrossRef
26.
go back to reference Dupuy J, Marechal J, Morvan D (2003) Fires from a cylindrical forest fuel burner: combustion dynamics and flame properties. Combust Flame 135(1–2):65–76CrossRef Dupuy J, Marechal J, Morvan D (2003) Fires from a cylindrical forest fuel burner: combustion dynamics and flame properties. Combust Flame 135(1–2):65–76CrossRef
27.
go back to reference Stenseng M, Jensen A, Dam-Johansen K (2001) Investigation of biomass pyrolysis by thermogravimetric analysis and differential scanning calorimetry. J Anal Appl Pyrol 58–59:765–780CrossRef Stenseng M, Jensen A, Dam-Johansen K (2001) Investigation of biomass pyrolysis by thermogravimetric analysis and differential scanning calorimetry. J Anal Appl Pyrol 58–59:765–780CrossRef
28.
go back to reference Zhang Z, Zhang H, Zhou D (2011) Flammability characterisation of grassland species of Songhua Jiang-Nen Jiang Plain (China) using thermal analysis. Fire Saf J 46(5):1–6CrossRef Zhang Z, Zhang H, Zhou D (2011) Flammability characterisation of grassland species of Songhua Jiang-Nen Jiang Plain (China) using thermal analysis. Fire Saf J 46(5):1–6CrossRef
30.
go back to reference Dalgarn M, Wilson R (1975) Net productivity and ecological efficiency of andropogon scoparius growing in an Ohio relict prairie. Ohio J Sci 75(4):194–197 Dalgarn M, Wilson R (1975) Net productivity and ecological efficiency of andropogon scoparius growing in an Ohio relict prairie. Ohio J Sci 75(4):194–197
31.
go back to reference Golley F (1961) Energy values of ecological materials. Ecology 42(3):581–584CrossRef Golley F (1961) Energy values of ecological materials. Ecology 42(3):581–584CrossRef
32.
go back to reference Kidnie S (2009) Fuel load and fire behaviour in the southern Ontario tallgrass prairie. Thesis, University of Toronto Kidnie S (2009) Fuel load and fire behaviour in the southern Ontario tallgrass prairie. Thesis, University of Toronto
33.
go back to reference Lyon RE (2000) Solid-state thermochemistry of flaming combustion. In: Grand AF, Wilkie CA (eds) Fire retardancy of polymeric materials. CRC Press, Boca Raton, pp 391–447 Lyon RE (2000) Solid-state thermochemistry of flaming combustion. In: Grand AF, Wilkie CA (eds) Fire retardancy of polymeric materials. CRC Press, Boca Raton, pp 391–447
34.
go back to reference Incropera FP (2001) Fundamentals of heat and mass transfer. Wiley, New York Incropera FP (2001) Fundamentals of heat and mass transfer. Wiley, New York
35.
go back to reference McGrattan K, McDermott R, Hostikka S, Floyd J (2010) Fire dynamics simulator (Version 5): user’s guide. NIST special publication 1019–5. National Institute of Standards and Technology, Gaithersburg McGrattan K, McDermott R, Hostikka S, Floyd J (2010) Fire dynamics simulator (Version 5): user’s guide. NIST special publication 1019–5. National Institute of Standards and Technology, Gaithersburg
36.
go back to reference Ritchie S, Steckler K, Hamins A, Cleary T, Yang J, Kashiwagi T (1997) The effect of sample size on the heat release rate of charring materials. In: Fire safety science: Proceedings of the fifth international symposium, Melbourne, pp 177–188 Ritchie S, Steckler K, Hamins A, Cleary T, Yang J, Kashiwagi T (1997) The effect of sample size on the heat release rate of charring materials. In: Fire safety science: Proceedings of the fifth international symposium, Melbourne, pp 177–188
37.
go back to reference Rothermel R (1972) A mathematical model for predicting fire spread in wildland fuels. USDA Forest Service Research Paper INT-115 Rothermel R (1972) A mathematical model for predicting fire spread in wildland fuels. USDA Forest Service Research Paper INT-115
38.
go back to reference Morvan D, Méradji S, Accary G (2009) Physical modelling of fire spread in grasslands. Fire Saf J 44(1):50–61CrossRef Morvan D, Méradji S, Accary G (2009) Physical modelling of fire spread in grasslands. Fire Saf J 44(1):50–61CrossRef
39.
go back to reference Leithead HL, Yarlett LL, Shiflet TN (1971) 100 native forage grasses in 11 southern states (Agriculture handbook no. 389). U.S. Soil Conservation Service Leithead HL, Yarlett LL, Shiflet TN (1971) 100 native forage grasses in 11 southern states (Agriculture handbook no. 389). U.S. Soil Conservation Service
Metadata
Title
Characterization of Fuel Properties and Fire Spread Rates for Little Bluestem Grass
Authors
K. J. Overholt
J. Cabrera
A. Kurzawski
M. Koopersmith
O. A. Ezekoye
Publication date
01-01-2014
Publisher
Springer US
Published in
Fire Technology / Issue 1/2014
Print ISSN: 0015-2684
Electronic ISSN: 1572-8099
DOI
https://doi.org/10.1007/s10694-012-0266-9

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