Recent Experimental Efforts on High-Pressure Supercritical Injection for Liquid Rockets and Their Implications

Pressure and temperature of the liquid rocket thrust chambers into which propellants are injected have been in an ascending trajectory to gain higher specific impulse. It is quite possible then that the thermodynamic condition into which liquid propellants are injected reaches or surpasses the critical point of one or more of the injected fluids. For example, in cryogenic hydrogen/oxygen liquid rocket engines, such as Space Shuttle Main Engine (SSME) or Vulcain (Ariane 5), the injected liquid oxygen finds itself in a supercritical condition. Very little detailed information was available on the behavior of liquid jets under such a harsh environment nearly two decades ago. The author had the opportunity to be intimately involved in the evolutionary understanding of injection processes at the Air Force Research Laboratory (AFRL), spanning sub- to supercritical conditions during this period. The information included here attempts to present a coherent summary of experimental achievements pertinent to liquid rockets, focusing only on the injection of nonreacting cryogenic liquids into a high-pressure environment surpassing the critical point of at least one of the propellants. Moreover, some implications of the results acquired under such an environment are offered in the context of the liquid rocket combustion instability problem.

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Hot-fire testing of liquid oxygen/hydrogen single coaxial injector at high-pressure conditions with optical diagnostics

Progress in Propulsion Physics – Volume 11 ◽

10.1051/eucass/201911391 ◽

2019 ◽

Author(s):

D.I. Suslov ◽

J.S. Hardi ◽

B. Knapp ◽

M. Oschwald

Keyword(s):

High Pressure ◽

High Speed ◽

Optical Diagnostics ◽

Liquid Oxygen ◽

Experimental Investigations ◽

Rocket Engines ◽

Chamber Length ◽

Substantial Progress ◽

Liquid Rocket ◽

Coaxial Injector

Injector behavior is of utmost importance for the performance and stability of liquid rocket engines (LREs). A major problem is getting a highly efficient homogeneous mixture and effective chemical reaction of fuels at minimum chamber length. Despite substantial progress in numerical simulations, a need for experimental data at representative conditions for development and validation of numerical design tools still exists. Therefore, in the framework of the DLR-project “ProTau,” the authors have performed tests to create an extended data base for numerical tool validation for high-pressure liquid oxygen (LOx) / hydrogen combustion. During the experimental investigations, a windowed DLR subscale thrust chamber model “C” (designated BKC) has been operated over a broad range of conditions at reduced pressures of approximately 0.8 (4 MPa), 1 (5 MPa), and 1.2 (6 MPa) with respect to the thermodynamic critical pressure of oxygen. Liquid oxygen and gaseous hydrogen (GH2) have been injected through a single coaxial injector element at temperatures of ~ 120 and ~ 130 K, respectively. High-speed optical diagnostics have been implemented, including imaging of OH* emission and shadowgraph imaging at frequencies from 8 up to 10 kHz to visualize the flow field.

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Modeling High-Pressure Mixing and Combustion Processes in Liquid Rocket Engines

Journal of Propulsion and Power ◽

10.2514/2.5349 ◽

1998 ◽

Vol 14 (5) ◽

pp. 843-857 ◽

Cited By ~ 204

Author(s):

Joseph C. Oefelein ◽

Vigor Yang

Keyword(s):

High Pressure ◽

Rocket Engines ◽

Liquid Rocket Engines ◽

Liquid Rocket ◽

Combustion Processes

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Numerical Investigation of Injection, Mixing and Combustion in Rocket Engines Under High-Pressure Conditions

Notes on Numerical Fluid Mechanics and Multidisciplinary Design - Future Space-Transport-System Components under High Thermal and Mechanical Loads ◽

10.1007/978-3-030-53847-7_13 ◽

2020 ◽

pp. 209-221

Author(s):

Christoph Traxinger ◽

Julian Zips ◽

Christian Stemmer ◽

Michael Pfitzner

Keyword(s):

High Pressure ◽

Large Eddy Simulations ◽

Experimental Investigations ◽

High Fidelity ◽

Rocket Engines ◽

Eddy Simulation ◽

Liquid Rocket Engines ◽

Large Eddy ◽

Numerical Tools ◽

Liquid Rocket

Abstract The design and development of future rocket engines severely relies on accurate, efficient and robust numerical tools. Large-Eddy Simulation in combination with high-fidelity thermodynamics and combustion models is a promising candidate for the accurate prediction of the flow field and the investigation and understanding of the on-going processes during mixing and combustion. In the present work, a numerical framework is presented capable of predicting real-gas behavior and nonadiabatic combustion under conditions typically encountered in liquid rocket engines. Results of Large-Eddy Simulations are compared to experimental investigations. Overall, a good agreement is found making the introduced numerical tool suitable for the high-fidelity investigation of high-pressure mixing and combustion.

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