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This article is cited in 2 scientific papers (total in 2 papers)
Numerical simulation of the flowfield in a boron-based slurry fuel ramjet
Y.-L. Xiao, Zh.-X. Xia, L.-Y. Huang, L.-K. Ma, D.-L. Yang College of Aerospace Science and Engineering, National University of Defense Technology, Changsha, 410073, People’s Republic of China
Abstract:
By considering the parametric variation of an individual boron particle in a boron agglomerate, the heat transfer, and the mass transfer between the boron particle agglomerate and the surroundings, an ignition and combustion model of a boron agglomerate is proposed. An experiment of a ramjet combustor using a boron-based slurry fuel is designed and operated for the purpose of validating the ramjet configuration and verifying the combustion of boron particles. Then a mathematical model for simulating a multiphase reacting flow within the combustor of a boron-based slurry fuel ramjet is established. Kerosene droplets and boron particles are injected discretely to the burner flowfield, and their trajectories are traced using the discrete phase model. The influence of the agglomerate size, bypass air mass flow rate, initial boron particle diameter, and boron particle content on the combustion efficiency of the slurry fuels is analyzed in detail. The results show that the combustion efficiency decreases with an increase in the agglomerate radius, initial boron particle diameter, and boron particle content. The combustion efficiency increases with an increase in the mass flow rate of bypass air. If the agglomerate diameter is greater than 100 $\mu$m or the bypass air mass flow rate is smaller than 50 g/s, the boron particles cannot be fully burned.
Keywords:
slurry, ramjet, boron, agglomerate.
Received: 14.08.2018 Revised: 19.10.2018 Accepted: 28.11.2018
Citation:
Y.-L. Xiao, Zh.-X. Xia, L.-Y. Huang, L.-K. Ma, D.-L. Yang, “Numerical simulation of the flowfield in a boron-based slurry fuel ramjet”, Fizika Goreniya i Vzryva, 55:3 (2019), 126–137; Combustion, Explosion and Shock Waves, 55:3 (2019), 361–371
Linking options:
https://www.mathnet.ru/eng/fgv591 https://www.mathnet.ru/eng/fgv/v55/i3/p126
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