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All issues Volume 287 (2021) E3S Web Conf., 287 (2021) 03006 References
Open Access
Issue
E3S Web Conf.
Volume 287, 2021
International Conference on Process Engineering and Advanced Materials 2020 (ICPEAM2020)
Article Number 03006
Number of page(s) 6
Section Process Systems Engineering & Optimization
DOI https://doi.org/10.1051/e3sconf/202128703006
Published online 06 July 2021
  1. Vijayaraghavan G. (2000) Review Article DUST EXPLOSIONS - A MAJOR INDUSTRIAL HAZARD. [Google Scholar]
  2. Hosseinzadeh S., Berghmans J., Degreve J., Verplaetsen F. (2019) A model for the minimum ignition energy of dust clouds. Process Saf Environ Prot 121:43–49 [Google Scholar]
  3. Zhang Q., Zhang B. (2015) Effect of ignition delay on explosion parameters of corn dust/air inconfined chamber. J Loss Prev Process Ind 33:23–28 [Google Scholar]
  4. Weber M., (2006) Some Safety Aspects on the Design of Sparger Systems for the. Process Saf Prog 25:326–330 [Google Scholar]
  5. Yuan Z., Khakzad N., Khan F., Amyotte P. (2015) Dust explosions: A threat to the process industries. Process Saf Environ Prot 98:57–71 [Google Scholar]
  6. Addai E.K., Gabel D., Krause U. (2016) Experimental investigation on the minimum ignition temperature of hybrid mixtures of dusts and gases or solvents. J Hazard Mater 301:314–326 [Google Scholar]
  7. Liu H., Chen H., Zhang X., Hu Y., Fan C. (2019) Effects of different factors on the minimum ignition temperature of the mixed dust cloud of coal and oil shale. J Loss Prev Process Ind 62:103977 [Google Scholar]
  8. Wang Q., Fang X., Shu C.M., Wang Q., Sheng Y., Jiang J., Sun Y., Sheng Z. (2020) Minimum ignition temperatures and explosion characteristics of micron-sized aluminium powder. J Loss Prev Process Ind 64:104076 [Google Scholar]
  9. Mittal M. (2014) Explosion characteristics of micron- and nano-size magnesium powders. J Loss Prev Process Ind 27:55–64 [Google Scholar]
  10. Zhang J., Xu P., Sun L., Zhang W., Jin J. (2018) Factors influencing and a statistical method for describing dust explosion parameters: A review. J Loss Prev Process Ind 56:386–401 [Google Scholar]
  11. Bernard S., Lebecki K., Gillard P., Youinou L., Baudry G. (2010) Statistical method for the determination of the ignition energy of dust cloud-experimental validation. J Loss Prev Process Ind 23:404–411 [Google Scholar]
  12. Ba D., Boyaci I.H. (2007) Modeling and optimization i: Usability of response surface methodology. J Food Eng 78:836–845 [Google Scholar]
  13. Deng J., Qu J., Wang Q., Zhai X., Xiao Y., Cheng Y., Shu C.M. (2019) Minimum ignition temperature of aluminium dust clouds via the Godbert-Greenwald furnace. Process Saf Environ Prot 129:176–183 [Google Scholar]
  14. Bagaria P., Prasad S., Sun J., Bellair R., Mashuga C. (2019) Effect of particle morphology on dust minimum ignition energy. Powder Technol 355:1–6 [Google Scholar]

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