Integration of vehicle, propulsion system and separation unit designs for a launcher using in-flight oxygen collection

Bizzarri, Didier; Hendrick, Patrick; Heyen, Georges; Ngendakumana, Philippe

doi:10.2514/6.2005-3421

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Integration of vehicle, propulsion system and separation unit designs for a launcher using in-flight oxygen collection

Bizzarri, Didier; Hendrick, Patrick; Heyen, Georges et al.

2005 • In AIAA/CIRA 13th International Space Planes and Hypersonics Systems and Technologies Conference

Peer reviewed

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https://hdl.handle.net/2268/36743

DOI
10.2514/6.2005-3421

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Keywords :

Two-Stage-To-Orbit; LOX collection; ACES; centrifugal distillation; mass transfer; liquid-gas contactor; liquid hydrogen; space launcher

Abstract :

[en] The use of in-flight Oxygen Collection has shown to significantly improve space launcher performance. The conceptual approach followed by the Royal Military Academy of Brussels (RMA) has tried to widen the available design margins in order to reduce the required technological leap and limit the economical risk associated with such a development. The aim of the ESA-funded theoretical and experimental study on an air separation device is to demonstrate the possibility of performing efficient air distillation in a compact rotating column. An integration of the vehicle, propulsion system and separation unit designs is presented aiming to optimise the overall vehicle performance while keeping technological difficulty and system complexity at a reasonable level. Reference vehicles are presented in their specific mission profiles with an emphasis on TSTO’s. Different layouts of the internal energy and mass flowsheets are compared, in order to make best use of the refrigeration capacity of the hydrogen fuel running though the propulsion system during the first phase of the flight considering the separator as a classical distillation column. This analysis provides the requirements in terms of heat exchange capacity, compression ratios and number of so-called transfer units needed in the separator. Here, the system is intentionally kept simple, to limit complexity, but the analysis is thorough and accurate, including, for example, the effect of the presence of argon. An analysis of the separation unit to reach those requirements is proposed. That includes internals, practical building with estimates of pressure drop, separation performance and flow limitation. Analysis of size reduction of the distillation unit from usual 1-g column to the high-g unit is provided as well as the scale up methodology of laboratory results. First experimental results obtained with our centrifugally enhanced distillation separation system are presented and perspectives for a larger on-board operational unit proposed.

Disciplines :

Aerospace & aeronautics engineering

Author, co-author :

Bizzarri, Didier

Hendrick, Patrick

Heyen, Georges ; Université de Liège - ULiège > Département de chimie appliquée > LASSC (Labo d'analyse et synthèse des systèmes chimiques)

Ngendakumana, Philippe ; Université de Liège - ULiège > Département d'aérospatiale et mécanique > Thermotechnique

Language :

English

Title :

Integration of vehicle, propulsion system and separation unit designs for a launcher using in-flight oxygen collection

Publication date :

May 2005

Event name :

AIAA/CIRA 13th International Space Planes and Hypersonics Systems and Technologies Conference

Event place :

Capua, Italy

Event date :

du 16 mai 2005 au 20 mai 2005

Audience :

International

Main work title :

AIAA/CIRA 13th International Space Planes and Hypersonics Systems and Technologies Conference

Peer reviewed :

Peer reviewed

Funders :

ASE - Agence Spatiale Européenne

Available on ORBi :

since 17 May 2010

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Bibliography

P. Hendrick, F. Breugelmans, B. Marquet, M. Saint-Mard, M. Strengnart, P. Ngendakumana and D. Bizzarri, "Fully and Partially Reusable TSTO launchers using In-Flight LOX Collection", ISTS 2000-g-09, Morioka, 28 May - 02 June 2000.
P. Hendrick, "VPSC, a vehicle parametric sizing code", AIAA-2001-1846, Kyoto, 24 - 27 April 2001
P. Hendrick & A. Mignon, "Utilization of Existing Large Subsonic Aircraft Elements to Implement In-Flight LOX Collection Aircraft", AIAA-2000-3107, JPC, Huntsville, 16-19 July 2000.
J. C. Houbolt, "Why Twin-Fuselage Aircraft?", Astronautics and Aeronautics, Apr 1982, pp. 26-35.
Leingang J.L., Maurice L.Q. & Carreiro L., Wright Laboratory, "In-Flight Oxidiser Collection Systems for Airbreathing Space Boosters", Developments in High-Speed-Vehicle Propulsion Systems, AIAA book, Vol. 165, Ch. 7, pp 333-384, 1996.
Gottzmann C. et al., "Airborne Rotary Air Separator Study", Union Carbide Industrial Gases Inc., NASA CR-189099, Dec 1990.
DRNEVICH R & NOWOBILSKI J., "Airborne Rotary Air Separator Study", Praxair, NASA CR-191045, Dec 1992.
Peng D.Y, Robinson D.B., A new two-constant equation of state, Ind.Eng.Chem., Fundam. 15, 59-64 (1976).
H. Knapp, R. Döring, L. Oellrich, U. Plöcker, J.M. Prausnitz, R. Langhorst, S. Zeck, Vapor-Liquid Equilibria for Mixtures of Low Boiling Substances, Chemistry Data Series Vol 6, DECHEMA (1982)
D. Bizzarri, P. Hendrick, Study and development of an air distillation subscale unit for in-flight oxygen collection, Proceedings of 12th AIAA International Space Planes and Hypersonic Systems and Technologies, Norfolk, Virginia (2003)
T.K.Sherwood, G.H.Shipley and F.A.L.Holloway, "Flooding Velocities in Packed Columns", Industrial and Engineering Chemistry, 30, 765, July (1938)
F.R.Dell, H.R.C.Prart, "A Note on the Correlation of Flooding Rates for Packed Gas-Liquid Columns", J.Apl.Chem.,2,Aug (1952)