Abstract
Particle size has significant effect on flame propagation behaviors in dust explosions. In this study, the flame propagation behaviors and microstructures in micro- and nano-titanium dust explosions were observed and compared. Results showed that flame propagation mechanisms in 50nm and 35μm titanium dust clouds were quite different. 50nm titanium dust flame was characterized by discrete single glowing burning particles with smooth spherical flame front. While 35μm titanium dust flame was marked by clusters of glowing burning particles with irregular flame front. 50nm titanium flame velocity was fluctuated more violent and the average flame propagation velocity was faster than that of 35μm titanium flame. In addition, micro explosion phenomenon occurred significantly in the burning process of 50nm titanium particles. SEM photos showed that 50nm titanium particles were approximately spherical shape with observably agglomerations before ignition. However, the combustion products exhibited complicated structures combined the spherical titanium oxides with considerable larger diameters and irregularly spliced smaller titanium oxides. 35μm titanium particles were in irregular shape before ignition, but in spherical shape after combustion. These results indicated that oxidation reaction occurred on the liquid surface of 35μm and 50nm titanium particles. From X-ray photoelectron spectroscopy, it was revealed that the dominant oxidation states of 35μm titanium combustion products was TiO2 (Ti4+), and to a much lesser extent of Ti2O3 (Ti3+). However, 50nm titanium combustion products contained 61% TiO2 (Ti4+), 18% Ti2O3 (Ti3+), 8% TiO (Ti2+) and 13% TiN (Ti3+).
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