Flame-propagation behavior and a dynamic model for the thermal-radiation effects in coal-dust explosions

• Published in: Journal of loss prevention in the process industries Vol. 29; pp. 65 - 71
• Main Authors: Cao, Weiguo, Gao, Wei, Liang, Jiyuan, Xu, Sen, Pan, Feng
• Format: Journal Article
• Language: English
• Published: Kidlington Elsevier Ltd 01.05.2014; Elsevier Science Ltd
• Subjects: Chemical reactions; Clouds; Coal; Coal-dust explosion; Combustion; Dust; Dynamic model; Dynamic models; Explosions; Fireball thermal radiation; Fireballs; Flame-propagation behavior; High speed; Outlets; Propagation; Radiation; Thermal energy; Tubes; Coal-dust explosion; Dynamic model; Fireball thermal radiation; Flame-propagation behavior
• ISSN: 0950-4230; 1873-3352
• DOI: 10.1016/j.jlp.2014.02.002

To reveal the flame-propagation behavior and the thermal-radiation effects during coal-dust explosions, two coal-dust clouds were tested in a semi-enclosed vertical combustion tube. A high-speed video camera and a thermal infrared imaging device were used to record the flame-propagation process and the thermal-radiation effects of the fireball at the combustion-tube outlet. The flame propagated more quickly and with a higher temperature in the more volatile coal-dust cloud. The coal-dust concentration also significantly affected the propagation behavior of the combustion zone. When the coal-dust concentration was increased, the flame-propagation velocity and the fireball temperature increased before decreasing overall. Based on the experimental results, a dynamic model of the thermal radiation was employed to describe the changes in the fireballs quantitatively and to estimate the thermal-radiation effects during coal-dust explosions. •We examined the flame-propagation behaviors and thermal-radiation effects of a fireball.•The flame-propagation behaviors were similar in the two types of coal-dust clouds.•On the basis of the experimental results, fireball thermal dynamic calculations were performed.•The dynamic model provided a theoretical foundation for the damage power of dust explosions.