‘Knock on nanocellulose’: Approaching the laminar burning velocity of powder-air flames

• Published in: Process safety and environmental protection Vol. 134; pp. 247 - 259
• Main Authors: Santandrea, Audrey, Gavard, Marine, Pacault, Stéphanie, Vignes, Alexis, Perrin, Laurent, Dufaud, Olivier
• Format: Journal Article
• Language: English
• Published: Rugby Elsevier B.V 01.02.2020; Elsevier Science Ltd; Elsevier
• Subjects: Aerodynamics; Burning; Burning rate; Burning velocity; Devolatilization; Dust explosion; Engineering Sciences; Flame propagation; Gases; Low turbulence; Nanocellulose; Nanopowder; Propagation; Sedimentation; Sedimentation rates; Turbulence; Velocity; Visualization; Nanocellulose; Dust explosion; Nanopowder; Flame propagation; Burning velocity
• ISSN: 0957-5820; 1744-3598; 0957-5820
• DOI: 10.1016/j.psep.2019.12.018

•Laminar burning velocity of nanocellulose-air mixtures was determined experimentally.•A value of 20cms−1 is proposed for the laminar burning velocity of nanocellulose.•Tests performed in a semi-open tube a modified 20L sphere give consistent results.•Linear and nonlinear correlations between flame stretching and velocity were compared.•These results are useful as inputs to CFD models of dust explosion on a larger scale. Due to their low sedimentation rate, nano-objects offer the opportunity to study flame propagation at low turbulence. The burning velocity was then estimated by flame visualization in two apparatuses: a vertical 1m long tube with a square cross-section and a 20L sphere equipped with visualization windows and a vent. This works aims to study the laminar burning velocity of nanocellulose by a direct visualization of the flame propagation within these devices. A high-speed video camera was used to record the flame propagation, and an estimation of the unstretched burning velocity was obtained through linear and nonlinear relationships relating the flame stretching and the flame velocities. Although these methods were initially established for gases, the organic nature of nanocellulose implies a fast devolatilization, which makes the application of the methods possible in this work. Similar results were obtained in both apparatuses in different turbulence conditions, proving the laminar burning velocity was approached. The laminar burning velocity for the nanocellulose was determined to be 21cms−1. This value, estimated through flame propagation visualization, was then compared to the value calculated by applying a semi-empiric correlation to the pressure-time evolution recorded during standard explosion tests in the 20L vessel.