MPD (magnetoplasmadynamic) thrust-chamber flow dynamics. Annual report, 1 October 1986-30 September 1987
Performance characteristics of Magnetoplasmadynamic(MPD) arcjets depend on proper matching of electromagnetic and fluid-mechanical constraints within the thrust chamber. Experimental measurements of internal-flow conditions during MPD arcjet operation are needed to guide developement of flow models and to assess the validity of theoretical predictions. Efforts are continuing in a corporative effort to apply an array of diagnostic techniques including time-, space-, and spectrally-resolved photography to examine MPD arcjet internal flows. Experimental elucidation of the internal flow structure is used to develop predictive models for optimal geometries and operating parameters. Probes have been used to map the current and voltage distributions within uniform height and flared annular channels. This work is concerned with the effect of thruster channel variations on the current conduction regions of the MPD internal flow. Other aspects of the internal flow structure that were modeled involve the transition of the input mass flow from neutral gas to electrically-conducting plasma. Scale sizes for the transition region were estimated in terms of the electrical and thermodynamic properties of the propellant gas (e.g., argon). These estimates indicate that the electrical conductivity of the flow can be established in distances that are small compared to the characteristic dimension for current conduction near the entrance to the arcjet thrust chamber.
- Research Organization:
- R and D Associates, Alexandria, VA (USA)
- OSTI ID:
- 7148894
- Report Number(s):
- AD-A-189940/0/XAB; RDA-TR-144200
- Country of Publication:
- United States
- Language:
- English
Similar Records
MPD thrust-chamber flow dynamics. Final report, October 1988-30 October 1989
Plasma thruster development: magnetoplasmadynamic propulsion, status, and basic problems. Interim report, October 1984-September 1985
Related Subjects
SUPERCONDUCTIVITY AND SUPERFLUIDITY
30 DIRECT ENERGY CONVERSION
MAGNETOHYDRODYNAMICS
MHD CHANNELS
MHD GENERATORS
FLOW MODELS
ARGON
DISTRIBUTION
ELECTRIC CONDUCTORS
ELECTRICAL PROPERTIES
EXPERIMENTAL DATA
OPTIMIZATION
PROGRESS REPORT
PROPELLANTS
THERMODYNAMIC PROPERTIES
VALIDATION
DATA
DIRECT ENERGY CONVERTERS
DOCUMENT TYPES
ELEMENTS
FLUID MECHANICS
FLUIDS
GASES
HYDRODYNAMICS
INFORMATION
MATHEMATICAL MODELS
MECHANICS
NONMETALS
NUMERICAL DATA
PHYSICAL PROPERTIES
RARE GASES
TESTING
640430* - Fluid Physics- Magnetohydrodynamics
300104 - MHD Generators- Duct Engineering & Fluid Dynamics