Nonane droplet combustion with and without buoyant convection: Flame structure, burning rate and extinction in air and helium

Abstract

The burning and extinction characteristics of isolated small nonane droplets are examined in a buoyant convective environment and in an environment with no external axial convection (as created by doing experiments at low gravity) to promote spherical droplet flames. The ambience is air and a mixture of 30%O 2/70%He to assess the influence of soot formation. The initial droplet diameter ( D o) ranges from 0.4 to 0.95 mm. Measurements are reported of the extinction diameter and time to extinction, and of the evolution of droplet diameter, flame diameter, soot shell diameter, burning rate, and broadband radiative emissions. In a buoyancy-free environment for air larger droplets burn slower than smaller droplets for the range of D o examined, which is attributed to the influence of soot. In the presence of a buoyant flow in air, no influence of D o is observed on the burning rate while the buoyant flames are still heavily sooting. The effect of D o is believed to be due to a combination of dominance of the nonluminous, nonsooting, portion of the buoyant flame around the forward half of the droplet on heat transport and the secondary role of the luminous wake portion of the flame. In a non-sooting helium inert at low gravity, no effect of D o is found on the evolution of droplet diameter. Flame extinction is observed only in the 30%O 2/70%He ambience. For all of the observations, extinction appears to occur before the disappearance of the droplet which is then followed by a period of evaporation. The extinction diameter and time to extinction increases with D o and an empirical correlation is presented for these two variables.