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4. A new System Design Tool for a Hybrid Rocket Engine Application

Author

Quero Granado, Elena, Pelenghi, Giulio, Hijlkema, Jouke, Anthoine, Jérôme, Lestrade, Jean-Yves, and CRETIN, Dorine

Subjects
[SPI] Engineering Sciences [physics], 1.5-D combustion chamber model Nomenclature, System design tool, OUTIL-SYSTEME, System design tool hybrid rocket engine 1.5-D combustion chamber model, PROPULSION HYBRIDE, 1.5-D combustion chamber model, hybrid rocket engine, MODELISATION 1.5D, [PHYS] Physics [physics]
Abstract

A system design tool allowing to simulate the complete operation of a hybrid rocket engine is developed in this paper. The algorithm of the application is made in such a way that allows the simulation of an element, an ensemble of elements or all the elements constituting a hybrid space propulsion system. The objective is to simulate and predict the behavior of the engine at different conditions / configurations during the first pre-design phases. As the tool will be exclusively used during these phases, a balance between the duration of the simulation and its precision must be reached. Given these constraints, a maximum error of 30% between the experimental and the numerical results is considered adequate to validate the solution. The main parts of our HYCAT engine-characterized by a catalytic injection of oxidizer-are modeled and included in this tool: the mass flow rate regulator and the catalyst (feed and injection subsystems) through 0-D models; the combustion chamber with a 1.5-D model; and the nozzle through a 1-D model. An iterative method is employed to attain the pressure convergence in the combustion chamber between these three main parts of the engine whose corresponding system of equations is solved by a Newton-Raphson technique. Seven experiments performed on HYCAT are used to validate the results of the conceived tool. From all the performed simulations, only two of them present relative differences with the experiment above the defined threshold. The largest errors are produced for the fuel regression rate, the consumed mass of fuel, and the mixing ratio variables. The best agreements with the experiments are found for the simulations with the largest oxidizer mass fluxes (G ox >230 kg/m 2 /s) and where the mixing ratio is closer to the stoichiometric value, defining thus, the range of applicability of the system design tool.

Published
2022

5. Overview of the CNES 'high performance green monopropellant project': requirements, organization & breakthroughs

Author

Pelletier, Nicolas, Lestrade, Jean-Yves, Centre National d'Études Spatiales [Toulouse] (CNES), ONERA / DMPE, Université de Toulouse [Toulouse], ONERA-PRES Université de Toulouse, and André, Cécile

Subjects
ROADMAP, GREEN PROPULSION, [SPI.FLUID]Engineering Sciences [physics]/Reactive fluid environment, MONERGOL VERT, [SPI.FLUID] Engineering Sciences [physics]/Reactive fluid environment, ULTRA-HIGH TEMPERATURE MATERIAL, MATERIAU ULTRA-HAUTE TEMPERATURE, HIGH PERFORMANCE, [PHYS.PHYS.PHYS-SPACE-PH]Physics [physics]/Physics [physics]/Space Physics [physics.space-ph], HAUTE PERFORMANCE, BREAKTHROUGHS, IONIC LIQUIDS, LIQUIDE IONIQUE, MONOPROPELLANT, FEUILLE DE ROUTE, PROJECT, [PHYS.PHYS.PHYS-SPACE-PH] Physics [physics]/Physics [physics]/Space Physics [physics.space-ph]
Abstract

International audience; CNES, the French Space Agency, has been leading for nearly six years intensive research on alternative green propellants for spacecrafts thrusters. More precisely, research has been focused on premixed monopropellant formulations based on state-of-the-art energetic materials and green chemistry approaches. The goal of this program is to provide an innovative propulsion system to replace standard hydrazine technology, demonstrating total breaking performance, low toxicity and high versatility. Hydrazine, mostly used in its anhydrous form as catalyzed monopropellant, is indeed an old and undoubtedly flight-proven product, but suffers from relatively poor propelling performance and from a high toxicity (both acute and suspected CMR). This paper describes the origins of the project and the main requirements we have imposed on ourselves. It also gives an overview of both the organization and the roadmap of the development plan, then concluding on the achievements and breakthroughs obtained to date.

Published
2018

6. Numerical simulation of a green monopropellant for spacecraft application

Author

Levard, Quentin, Louis, Neven, Pelletier, N., Le, Duc Minh, Rouzaud, Olivier, Lempereur, Christine, Hijlkema, Jouke, Lestrade, Jean-Yves, Anthoine, Jerôme, ONERA / DMPE, Université de Toulouse [Toulouse], ONERA-PRES Université de Toulouse, Centre National d'Études Spatiales [Toulouse] (CNES), and André, Cécile

Subjects
SHADOW IMAGING, REGRESSION DE GOUTTE, [SPI.FLUID]Engineering Sciences [physics]/Reactive fluid environment, MONERGOL VERT, LIQUIDE IONIQUE ENERGETIQUE, [SPI.FLUID] Engineering Sciences [physics]/Reactive fluid environment, GREEN MONOPROPELLANT, DROPLET REGRESSION, RETROECLAIRAGE, [PHYS.PHYS.PHYS-SPACE-PH] Physics [physics]/Physics [physics]/Space Physics [physics.space-ph], ENERGETIC IONIC LIQUID, [PHYS.PHYS.PHYS-SPACE-PH]Physics [physics]/Physics [physics]/Space Physics [physics.space-ph]
Abstract

International audience; Satellite attitude and orbit control manoeuvers are mostly realized by chemical thrusters, using catalytic decomposition of hydrazine. However, hydrazine is known for its carcinogenic and toxic effects and its use is thus threatened by the European chemical regulation REACh. A new monopropellant is therefore under development by CNES (the French Space Agency), and 3 prototypes are still in competition. The final choice of the best formulation will be based on real thruster tests. These new propellants are based on energetic ionic liquids, and the expected flame temperature is about 3000 K. To develop an optimized thruster demonstrator, numerical simulations, combining heat transfer and radiation in complex materials and diphasic behavior are necessary. Energetic ionic liquids have a very complex way of decomposing which explains why it is impossible to use current phase change models implemented in ONERA’s multiphysics code CEDRE. A new macroscopic combustion model is being developed and implemented in CEDRE following the phenomenology of solid homogeneous propellants. Simultaneously an experiment is prepared to observe the combustion of an isolated droplet, in order to measure its regression. This experiment is a proof of concept for the final experimental CNES’s setup GIMLI. This experiment will be validated on ethanol combustion and tested with the new family of green monopropellant.

Published
2018

7. HYPROGEO Hybrid Propulsion: Latest project achievements

Author

Lécossais, Anthony, Odic, Karine, Fiot, Daniel, Lestrade, Jean-Yves, Verberne, Onno, Fernando, Priya, Christ, Philipp, Searle, Tim, Airbus Defence and Space [Toulouse], ArianeGroup SAS, ONERA / DMPE, Université de Toulouse [Toulouse], ONERA-PRES Université de Toulouse, Nammo Raufoss AS, Airbus Defence and Space Ltd (Angleterre), Evonik Resource Efficiency GmbH, SpaceTec Partners, and André, Cécile

Subjects
POLYETHYLENE, PEROXIDE D'HYDROGENE, HYPROGEO, GREEN PROPULSION, LONG DURATION FIRING, [SPI.FLUID]Engineering Sciences [physics]/Reactive fluid environment, REDUCTION DE COUTS, H2020, PROPULSION SATELLITE, [SPI.FLUID] Engineering Sciences [physics]/Reactive fluid environment, TUYERE ENDURANTE, CHAMBRE DE COMBUSTIN ISOCHORE, [PHYS.PHYS.PHYS-SPACE-PH]Physics [physics]/Physics [physics]/Space Physics [physics.space-ph], COST REDUCTION, HYBRID PROPULSION, STABLE THRUST, ISOCHORIC COMBUSTION CHAMBER, HIGH TEST PEROXIDE (HTP), HYDROGEN PEROXIDE, PROPULSION HYBRIDE, [PHYS.PHYS.PHYS-SPACE-PH] Physics [physics]/Physics [physics]/Space Physics [physics.space-ph], SPACECRAFT PROPULSION
Abstract

International audience; Independent access to space is a key component of the European Space Policy. The competition is increasing in this area both for the full launching systems and the key subsystems. Cost effectiveness becomes the main driving factor. This paper describes the advancements performed in HYPROGEO, a 3-years cooperative R&D project funded by the European Commission’s Horizon 2020 program. HYPROGEO is a consortium of 14 European partners managed by Airbus Defence and Space Toulouse, bringing together complementary profiles from large space industry, SMEs till research institutes.

Published
2018

8. Catalytic Injectors for an Isochoric Hybrid Rocket Motor

Author

Musker, Antony J., Lestrade, Jean-Yves, Anthoine, Jérôme, Lécossais, Anthony, André, Cécile, DELTACAT Ltd, ONERA / DMPE, Université de Toulouse [Toulouse], ONERA-PRES Université de Toulouse, and Airbus Defence and Space [Toulouse]

Subjects
PROJET H2020 HYPROGEO, CATALYST, H2020 HYPROGEO PROJECT, [PHYS.PHYS.PHYS-INS-DET] Physics [physics]/Physics [physics]/Instrumentation and Detectors [physics.ins-det], CATALYSEUR, [PHYS.PHYS.PHYS-INS-DET]Physics [physics]/Physics [physics]/Instrumentation and Detectors [physics.ins-det], [PHYS.PHYS.PHYS-SPACE-PH]Physics [physics]/Physics [physics]/Space Physics [physics.space-ph], [PHYS.PHYS.PHYS-SPACE-PH] Physics [physics]/Physics [physics]/Space Physics [physics.space-ph]
Abstract

International audience; The EU H2020 HYPROGEO Project, coordinated by Airbus Defence and Space (Toulouse), called for the design and manufacture of two sets of catalytic injectors for a novel, isochoric hybrid rocket motor. The hybrid motor forms the basis of a propulsion system for future GEO/apogee-kick applications. The motor burns its fuel axially rather than radially and relies on a constant, vortical flow of hot oxygen for ignition and sustained combustion. The hot oxygen is provided by the rapid decomposition of hydrogen peroxide. Two aqueous concentrations were used: 87.5% for an intermediate motor, and 98% for the final breadboard design. Critical to success is the catalyst, referred to as PX1. This comprises a ceramic substrate and an active (catalytic) surface. On contact with hydrogen peroxide, oxygen and steam are liberated exothermically. The efficacy of PX1, used in combination with 98% concentration peroxide, was demonstrated in 2016.

Published
2018

9. 3D miles simulation of a hybrid rocket with SWIRL injection

Author

Messineo, Jérôme, Lestrade, Jean-Yves, Hijlkema, Jouke, Anthoine, Jérôme, ONERA - The French Aerospace Lab [Mauzac], ONERA, and André, Cécile

Subjects
INJECTION TOURBILLONNAIRE COMBURANT, MOTEUR FUSEE HYBRIDE, EFFICACITE COMBUSTION, OSCILLATION PRESSION, SIMULATION NUMERIQUE 3D, [SPI.MECA.MEFL] Engineering Sciences [physics]/Mechanics [physics.med-ph]/Fluids mechanics [physics.class-ph], [SPI.MECA.MEFL]Engineering Sciences [physics]/Mechanics [physics.med-ph]/Fluids mechanics [physics.class-ph]
Abstract

International audience; Oxidizer injection plays a major role in the behaviour of hybrid rocket engines, especially regarding combustion efficiency and stability. This study aims to compare two firing tests with associated numerical simulations based on gaseous oxidizer axial or swirl injection through a catalyzer. The oxidizer and fuel couple used was H2O2 (87.5 %)/HDPE. Numerical 3D MILES (Monotone Integrated Large Eddy Simulation) simulations of both configurations were performed and analyzed regarding on one side the combustion efficiency influenced by propellants mixing, and on the other side the pressure oscillations provoked by the formation of large scale vortices in the aft-combustion chamber.

Published
2016

10. Development of a catalyst for highly concentrated hydrogen peroxide

Author

Lestrade, Jean-Yves, Prévot, Pierre, Messineo, Jérôme, Anthoine, Jerôme, Casu, Santiago, Geiger, Bastian, ONERA - The French Aerospace Lab [Mauzac], ONERA, Heraeus Deutschland GmbH & CO KG, and André, Cécile

Subjects
SWIRL INJECTION, HIGH COMBUSTION EFFICIENCY, PEROXIDE D'HYDROGENE, [SPI.FLUID]Engineering Sciences [physics]/Reactive fluid environment, [CHIM.CATA] Chemical Sciences/Catalysis, [SPI.FLUID] Engineering Sciences [physics]/Reactive fluid environment, [CHIM.CATA]Chemical Sciences/Catalysis, EFFICACITE HAUTE COMBUSTION, SPATIAL GRADE HYDROGEN PEROXIDE, CATALYTIC DECOMPOSITION, INJECTEUR TOURBILLONNAIRE, MOTEUR FUSEE HYBRIDE, DECOMPOSITION CATALYTIQUE, PROPULSION SPATIALE, HYBROD ROCKET ENGINE
Abstract

International audience; Hybrid propulsion technology suffers from low propulsive performances generally due to low combustion efficiency in regards to the other chemical propulsion systems. When hydrogen peroxide is used as oxidizer, one of the most promising ways to increase this efficiency combines a catalyst and a swirl injector in order to have an oxidizing gaseous stream and an improved mixing between the two propellants. A complementary solution to directly increase the propulsive performance consists of using hydrogen peroxide at higher concentration than the spatial grade (87.5%) which improves the theoretical specific impulse up to 12s for 98% H2 O2. This paper presents the development of a catalyst compatible with very high concentrated hydrogen peroxide (98%) and the firing tests performed with this catalyst coupled to a hybrid engine in order to highlight the increase in combustion efficiency.

Published
2016

11. Hydrodynamic Instabilities Modeling in Hybrid Rocket Engines.

Author

Messineo, Jérôme, Lestrade, Jean-Yves, Hijlkema, Jouke, and Anthoine, Jérôme

Abstract

Firing tests of a H2O2/polyethylene hybrid rocket motor were performed and analyzed in terms of pressure oscillations under various configurations, using liquid oxidizer injection or gaseous injection through a catalyzer. Most of the firing tests presented pressure oscillations in the range of 200-2000 Hz, provoked by periodic vortex shedding occurring in the postcombustion chamber. These instabilities revealed particular behaviors such as frequency shifts and jumps. To understand these phenomena, the classical theory of vortex shedding in a cavity has been adapted to hybrid rocket engines by introducing an additional parameter that aims to consider the recirculation area in the postcombustion chamber to correctly explain the frequencies' behavior. Dedicated numerical simulations based on unsteady Reynolds-averaged Navier-Stokes equations and single-phase flow were performed to characterize this new parameter. Predictions of the proposed modeling were finally compared with the available firing tests database and revealed promising results, whatever the type of oxidizer injection, the operating combustion chamber pressure, and even in the presence of nozzle throat erosion. [ABSTRACT FROM AUTHOR]

Published
2019
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