TY - GEN
T1 - Heating and ignition of metallic particles by a CO2 Laser
AU - Mohan, Salil
AU - Trunov, Mikhaylo A.
AU - Dreizin, Edward L.
PY - 2007
Y1 - 2007
N2 - This paper presents an experimental technique and respective heat transfer model for studying ignition of micron-sized metallic particles at varied heating rates in the range of 106 K/s. The experimental setup uses a CO 2 laser as a heating source. The interaction of the laser beam with particles is particle size-dependent and a narrow range of particle sizes (around 3.37 m) is heated most effectively. Therefore, the he at transfer model needs to be only analyzed for the particles with this specific size, which greatly simplifies the interpretation of experiments. The powder is aerosolized inside a plate capacitor by charging particles contacting the capacitor's electrodes. A thin, laminar aerosol jet is carried out by an oxidizing gas through a small opening in the top electrode and is fed into a laser beam. The velocities of particles in the jet are in the range of 0.1 - 3 m/s. For each selected jet velocity, the laser power is increased until the particles are observed to ignite. The ignition is detected optically using a digital camera and a photomultiplier. The ignition thresholds for spherical aluminum powder were measured at three different particle jet velocities resulting in three different heating rates. The experimental data for aluminum, for which the ignition kinetics parameters are known, were acquired at a specific heating rate and used to calibrate the detailed heat transfer model. The experiments with different heating rates were performed to validate the model. The developed experimental technique and the heat transfer model can now be used to determine the ignition kinetics of different metallic powders in various gas environments.
AB - This paper presents an experimental technique and respective heat transfer model for studying ignition of micron-sized metallic particles at varied heating rates in the range of 106 K/s. The experimental setup uses a CO 2 laser as a heating source. The interaction of the laser beam with particles is particle size-dependent and a narrow range of particle sizes (around 3.37 m) is heated most effectively. Therefore, the he at transfer model needs to be only analyzed for the particles with this specific size, which greatly simplifies the interpretation of experiments. The powder is aerosolized inside a plate capacitor by charging particles contacting the capacitor's electrodes. A thin, laminar aerosol jet is carried out by an oxidizing gas through a small opening in the top electrode and is fed into a laser beam. The velocities of particles in the jet are in the range of 0.1 - 3 m/s. For each selected jet velocity, the laser power is increased until the particles are observed to ignite. The ignition is detected optically using a digital camera and a photomultiplier. The ignition thresholds for spherical aluminum powder were measured at three different particle jet velocities resulting in three different heating rates. The experimental data for aluminum, for which the ignition kinetics parameters are known, were acquired at a specific heating rate and used to calibrate the detailed heat transfer model. The experiments with different heating rates were performed to validate the model. The developed experimental technique and the heat transfer model can now be used to determine the ignition kinetics of different metallic powders in various gas environments.
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M3 - Conference contribution
AN - SCOPUS:34347249151
SN - 1563478900
SN - 9781563478901
T3 - Collection of Technical Papers - 45th AIAA Aerospace Sciences Meeting
SP - 16859
EP - 16870
BT - Collection of Technical Papers - 45th AIAA Aerospace Sciences Meeting
T2 - 45th AIAA Aerospace Sciences Meeting 2007
Y2 - 8 January 2007 through 11 January 2007
ER -