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Magnetohydrodynamic Augmented Propulsion ExperimentA fundamental obstacle to routine space access is the specific energy limitations associated with chemical fuels. In the case of vertical take-off, the high thrust needed for vertical liftoff and acceleration to orbit translates into power levels in the 10 GW range. Furthermore, useful payload mass fractions are possible only if the exhaust particle energy (i.e., exhaust velocity) is much greater than that available with traditional chemical propulsion. The electronic binding energy released by the best chemical reactions (e.g., LOX/LH2 for example, is less than 2 eV per product molecule (approx. 1.8 eV per H2O molecule), which translates into particle velocities less than 5 km/s. Useful payload fractions, however, will require exhaust velocities exceeding 15 km/s (i.e., particle energies greater than 20 eV). As an added challenge, the envisioned hypothetical RLV (reusable launch vehicle) should accomplish these amazing performance feats while providing relatively low acceleration levels to orbit (2-3g maximum). From such fundamental considerations, it is painfully obvious that planned and current RLV solutions based on chemical fuels alone represent only a temporary solution and can only result in minor gains, at best. What is truly needed is a revolutionary approach that will dramatically reduce the amount of fuel and size of the launch vehicle. This implies the need for new compact high-power energy sources as well as advanced accelerator technologies for increasing engine exhaust velocity. Electromagnetic acceleration techniques are of immense interest since they can be used to circumvent the thermal limits associated with conventional propulsion systems. This paper describes the Magnetohydrodynamic Augmented Propulsion Experiment (MAPX) being undertaken at NASA Marshall Space Flight Center (MSFC). In this experiment, a 1-MW arc heater is being used as a feeder for a 1-MW magnetohydrodynamic (MHD) accelerator. The purpose of the experiment is to demonstrate that an MHD accelerator can be an effective augmentation system for increasing engine exhaust velocity. More specifically, the experiment is intended to show that electromagnetic effects are effective at producing flow acceleration whereas electrothermal effects do not cause unacceptable heating of the working fluid. The MHD accelerator was designed as an externally diagonalized segmented Faraday channel, which will be inserted into an existing 2-tesla electromagnet. This allows the external power to be connected through two terminals thereby minimizing the complexity and cost associated with powering each segment independently. The design of the accelerator and other components in the flow path has been completed and fabrication activities are underway. This paper provides a full description of MAPX including performance analysis, design, and test plans, and current status.
Document ID
20020067630
Acquisition Source
Marshall Space Flight Center
Document Type
Conference Paper
Authors
Litchford, Ron J.
(NASA Marshall Space Flight Center Huntsville, AL United States)
Cole, John
(NASA Marshall Space Flight Center Huntsville, AL United States)
Lineberry, John
(LyTec, LLC Tullahoma, TN United States)
Chapman, Jim
(LyTec, LLC Tullahoma, TN United States)
Schmidt, Harold
(LyTec, LLC Tullahoma, TN United States)
Cook, Stephen
Date Acquired
August 20, 2013
Publication Date
January 1, 2002
Subject Category
Plasma Physics
Meeting Information
Meeting: 33rd Plasmadynamics and Lasers Conference
Location: Maui, HI
Country: United States
Start Date: May 20, 2002
End Date: May 23, 2002
Distribution Limits
Public
Copyright
Work of the US Gov. Public Use Permitted.

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