Combustion Characteristics of Suspended Hydrocarbon Fuel Droplets with Various Nanoenergetic Additives

摘要

The burning process of multiple liquid fuels with various nanoenergetic additives is investigated experimentally in the suspended droplet configuration. Specifically, the burning rate constant and ignition delay are measured for two base fuels, rocket grade kerosene (RP-2) and ethanol, with seven energetic additives; the investigated additives include aluminum (Al), magnesium oxide (MgO), graphene, graphene nano-platelet (GNP), as well as numerous soluble additives including ammonia borane (AB), ammonium nitrate (NaAN) and sodium borohydride (), all of which do not exceed 6 wt.% loading concentration. Results from these experiments show that in general, there is not a significant modification to the steady burning rate for these nanofuel combinations (averaging 10%) for the loading concentrations considered. Instead, the additives exhibit a majority of particle burning during the end of the droplet lifetime, which generally are short-lived events that do not affect the overall . This is illustrated by calculating the instantaneous burning rate for these nanofuels, where is 2% to 18% higher than pure fuels during the last half of the droplet burn time depending on the additive type. Similarly, nanofuel ignition delays generally only exhibit modest changes for a majority of the investigated combinations, causing only a 5% change on average. However, two nanofuels consisting of ethanol with 5 wt.% soluble ammonia borane and RP-2 with 1 wt. suspended graphene do exhibit increases in of approximately 20 and 30, respectively. These nanofuel compounds also exhibit substantial qualitative combustion behavioral changes including flame color changes and micro-droplet shedding events for ethanol with ammonia borane, as well as a notable reduction in the average burning rate of 20 for RP-2 with graphene. Therefore, these two nanofuel combinations may be candidates for further study as a means to garner control of combustion dynamics in a reacting liquid rocket spray environment.