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Received February 12, 2012
Accepted June 23, 2012
- This is an Open-Access article distributed under the terms of the Creative Commons Attribution Non-Commercial License (http://creativecommons.org/licenses/bync/3.0) which permits unrestricted non-commercial use, distribution, and reproduction in any medium, provided the original work is properly cited.
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Thermal-balanced integral model for pyrolysis and ignition of wood
Key Laboratory of Energy Thermal Conversion and Control of Ministry of Education, School of Energy and Environment, Southeast University, Nanjing 210096, China 1State Key Laboratory of Clean Energy Utilization, Zhejiang University Hangzhou, 310027, China 2Department of Building Services Engineering, The Hong Kong Polytechnic University, Hong Kong, China
101011398@seu.edu.cn
Korean Journal of Chemical Engineering, January 2013, 30(1), 228-234(7), 10.1007/s11814-012-0098-9
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Abstract
The pyrolysis and ignition of wood is of great importance to understand the initial stage of combustion, helping control the occurrence and spread of unwanted building and forestry fires. The development of a thermal-balanced model is introduced for examining the analytical relationship between the ignition time and external heat flux. The critical heat flux, one of the important fire-retardant characteristics of combustible solid, is determined from a correlation study between the ignition time and external heat flux. One of the thermal-balanced integral models, considering the effect of surface heat losses, average absorptivity and moisture content, is employed to give the prediction of surface temperature rise, ignition time and ignition temperature of the Aspen. The results show that the model readily and satisfactorily predicts ignition temperature and ignition time of wood with different moisture contents.
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Mikkola E, Indrek S, Wichman OJ, Fire and Materials., 14, 87 (1989)
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Babrauskas V, Ignition handbookPublished by Fire Science Publisher (2003)
Lawson DI, Simms DL, British J. Appl. Phys., 9, 288 (1952)
Simms DL, Combust. Flame., 4, 293 (1960)
Simms DL, Margaret L, Combust. Flame., 11, 377 (1967)
Wesson HR, Welker JR, Sliepcevich CM, Combust. Flame., 16, 303 (1971)
Quintiere G, Harkleroad T, New concepts for measuring spread properties, Fire safety and engineering, ASTM STP 882, American Society for Testing and Materials, Philadelphia, 239 (1985)
Mikkola E, WichmanIS, Fire and Materials., 14, 87 (1989)
Moghtaderi B, Novozhilov V, Fletcher DF, Kent JH, Fire Safety Journal., 29, 41 (1997)
Spearpoint MJ, Quintiere JG, Fire Safety Journal., 36, 391 (2001)
Kashiwagi T, Combust. Flame., 44, 223 (1982)
Bilbao R, Mastral JF, Aldea ME, Ceamanos J, Betran M, Lana JA, Combust. Flame, 126(1-2), 1363 (2001)
Bilbao R, Mastral JF, Lana JA, Ceamanos J, Aldea ME, J. Anal. Appl. Pyrol., 62, 63 (2002)
Jassens M, Fire and Materials., 15, 151 (1991)
Shen DK, Fang MX, Luo ZY, Cen KF, Fire Safety Journal., 42, 210 (2007)
Shen DK, Gu S, Luo KH, Bridgwater AV, Fang MX, Fuel, 88(6), 1024 (2009)
Carslaw HS, Jaeger JC, Conduction of Heat in Solids 2nd Ed. Oxford, Clarendon Press (1959)
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Bluhme DA, Fire and Materials., 11, 195 (1987)
Mikkola E, Indrek S, Wichman OJ, Fire and Materials., 14, 87 (1989)