https://ogma.newcastle.edu.au/vital/access/ /manager/Index en-au 5 https://ogma.newcastle.edu.au/vital/access/ /manager/Repository/uon:30929 Thu 31 Oct 2019 11:47:10 AEDT ]]> https://ogma.newcastle.edu.au/vital/access/ /manager/Repository/uon:32401 -1 at 4.0 m from the ignition source) than inside the vessel (173 bar.s^-1) for 9.5% methane.]]> Thu 31 May 2018 09:12:14 AEST ]]> https://ogma.newcastle.edu.au/vital/access/ /manager/Repository/uon:32402 Thu 31 May 2018 09:12:07 AEST ]]> https://ogma.newcastle.edu.au/vital/access/ /manager/Repository/uon:34979 Thu 03 Oct 2019 15:06:54 AEST ]]> https://ogma.newcastle.edu.au/vital/access/ /manager/Repository/uon:13591 Sat 24 Mar 2018 10:35:54 AEDT ]]> https://ogma.newcastle.edu.au/vital/access/ /manager/Repository/uon:34978 3 spherical explosion chamber. The effects of turbulence and explosive powders on explosion parameters such as the deflagration index, maximum explosion pressure and burning velocity were examined. Theoretical calculations were conducted and are presented alongside the experimental data. The study suggests that the presence of turbulence increases the maximum explosion pressure. The values of the deflagration indices and burning velocities were found to be increased by the turbulence. The presence of an explosive powder provides similar effects to turbulence, and the values of the maximum explosion pressure, deflagration index and burning velocities increased with increases of the mass of the explosive powders. The magnitude of the turbulence generated in the explosion chamber was determined theoretically by employing Damköhler’s correlation.]]> Mon 02 Mar 2020 11:49:31 AEDT ]]>