Abstract
Rotating detonation engines have the potential to achieve the high propulsive efficiencies of detonation cycles in a simple and effective annular geometry. A two-dimensional Euler simulation is modified to include mixing factors to simulate the imperfect mixing of injected reactant streams. Contrary to expectations, mixing is shown to have a minimal impact on performance. Oblique detonation waves are shown to increase local stream thermal efficiency, which compensates for other losses in the flow stream. The degree of reactant mixing is, however, a factor in controlling the stability and existence of rotating detonations.
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This work was sponsored by a contract from Innovative Scientific Solutions, Inc. and by the Office of Naval Research through the NRL 6.1 Computational Physics Task Area.
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Communicated by J. Yang.
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Nordeen, C.A., Schwer, D., Schauer, F. et al. Role of inlet reactant mixedness on the thermodynamic performance of a rotating detonation engine. Shock Waves 26, 417–428 (2016). https://doi.org/10.1007/s00193-015-0570-7
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DOI: https://doi.org/10.1007/s00193-015-0570-7