@article{8e41ff6930174cb299e78cc9d15c4b22,
title = "Cylindrical Rotating Detonation Engine with Propellant Injection Cooling",
abstract = "A cylindrical rotating detonation engine (24 mm diameter) with multiple injector holes on the combustor side wall for both propellant injection and cooling by injector gas flow was designed and tested. As each set of injectors created its own detonations, the synchronized detonation waves propagated along the three injector rows. From the axial view, those detonation combustion regions stood off from the injector surface as the non-well-mixed propellant existed between the wall and the combustion zone. This combustion region tended to broaden in lateral and radial directions as the mass flow rate increased by pushing its region with the injected propellant. Wall heat flux and heat balance were evaluated by a one-dimensional unsteady heat transfer model with propellant injection cooling. Even when the flow rate was doubled, the increase in the wall heat flux was only 18–25%. This heat trend and the image of standoff self-chemiluminescence from the injector surface implied that a non-well-mixed unburned propellant acted as a heat-reduction layer to ease heat load into the combustor. Measurements and thermal analysis verified the flow structure near the injector and heat-exchange mechanism due to the propellant gas flow, which has a potential for thermal steady operation.",
author = "Keisuke Goto and Kosei Ota and Akira Kawasaki and Noboru Itouyama and Hiroaki Watanabe and Ken Matsuoka and Jiro Kasahara and Akiko Matsuo and Ikkoh Funaki and Hideto Kawashima",
note = "Funding Information: This research was subsidized by a “Study on Innovative Detonation Propulsion Mechanism,” Research-and-Development Grant Program (Engineering) from the Institute of Space and Astronautical Science, the Japan Aerospace Exploration Agency, and the “Research and Development of an Ultra-High-Thermal-Efficiency Rotating Detonation Engine with Self-Compression Mechanism,” Advanced Research Program for Energy and Environmental Technologies, the New Energy and Industrial Technology Development Organization. The fundamental device development was subsidized by a Grant-in-Aid for Specially Promoted Research No. 19H05464, Grant-in-Aid for Scientific Researches (A) No. 24246137, (B) No. 17H03480, and Grant-in-Aid for JSPS Fellows No. 19J15418 from the Japan Society for the Promotion of Science. The test piece and test chamber were manufactured by Yasuda-Koki Co., Ltd.; Mizutani-Seiki Co., Ltd.; Hakudo Co., Ltd.; and Nakashima Special Co., Ltd. Funding Information: This research was subsidized by a ?Study on Innovative Detonation Propulsion Mechanism,? Research-and-Development Grant Program (Engineering) from the Institute of Space and Astronautical Science, the Japan Aerospace Exploration Agency, and the ?Research and Development of an Ultra-High-Thermal-Efficiency Rotating Detonation Engine with Self-Compression Mechanism,? Advanced Research Program for Energy and Environmental Technologies, the New Energy and Industrial Technology Development Organization. The fundamental device development was subsidized by a Grant-in-Aid for Specially Promoted Research No. 19H05464, Grant-in-Aid for Scientific Researches (A) No. 24246137, (B) No. 17H03480, and Grant-in-Aid for JSPS Fellows No. 19J15418 from the Japan Society for the Promotion of Science. The test piece and test chamber were manufactured by Yasuda-Koki Co., Ltd.; Mizutani-Seiki Co., Ltd.; Hakudo Co., Ltd.; and Nakashima Special Co., Ltd. Publisher Copyright: {\textcopyright} AIAA International. All rights reserved.",
year = "2022",
doi = "10.2514/1.B38427",
language = "English",
volume = "38",
pages = "410--420",
journal = "Journal of Propulsion and Power",
issn = "0748-4658",
publisher = "American Institute of Aeronautics and Astronautics Inc. (AIAA)",
number = "3",
}