[[1] PÓŁKA, M., WOLIÑSKI, M., KUKFISZ, B., SALAMONOWICZ, Z. 2014. Analysis of susceptibility to ignition of dust layer and dust coud of selected hardened unsaturated polyester resins, Polimery, 59(11-12), 805-810. ISSN 0032-272510.14314/polimery.2014.805]Search in Google Scholar
[[2] TAVEAU, J. 2014. Application of dust explosion protection systems. Procedia Engineering. 84, 297 – 305. ISSN 1877-705810.1016/j.proeng.2014.10.438]Search in Google Scholar
[[3] AMYOTTE, P. R., ECKHOFF, R.K. 2010. Dust explosion causation, prevention and mitigation: An overview. Journal of Chemical Health & Safety, 17(1), 15 – 28. ISSN 1871-553210.1016/j.jchas.2009.05.002]Search in Google Scholar
[[4] EBADAT, V. 2010. Dust explosion hazard assessment. Journal of Loss Prevention in the Process Industries.23, 907 – 912, ISSN: 0950-423010.1016/j.jlp.2010.05.006]Search in Google Scholar
[[5] CHIN, Y. S., DARVELL, L. I., LEA-LANGTON, A. R., JONES, J. M., WILLIAMS, A. 2016. Ignition Risks of Biomass Dust on Hot Surfaces. Energy and Fuels,30(6), 4398-4404. ISSN 0887-062410.1021/acs.energyfuels.5b02622]Search in Google Scholar
[[6] AJRASH, M. J., ZANGANEH J., MOGHTADERI, B. 2016. Experimental investigation of the minimum auto-ignition temperature (MAIT) of the coal dust layer in a hot and humid environment. Fire Safety Journal, 82, 12-22. ISSN 0379-711210.1016/j.firesaf.2016.02.007]Search in Google Scholar
[[7] BO, M., CLERICO, M., POGNANT, F. 2015. Cone-calorimeter tests of rice dusts explosiveness. Geoingegneria Ambientale e Mineraria, 146(3), 15-22. ISSN 1121-9041]Search in Google Scholar
[[8] EN 14034-3+A1:2012 Determination of explosion characteristics of dust clouds. Part 3:Determination of the lower explosion limit LEL of dust clouds]Search in Google Scholar
[[9] EN ISO/IEC 80079-20-2:2016 Explosive Atmospheres - Part 20-2: Material characteristics - Combustible dust test methods]Search in Google Scholar