Experimental Investigation of the Near-Wall Region in the NASA HiVHAc EDU2 Hall Thruster
- Author
- Kamhawi, Hani
- Published
- July 4, 2015.
- Physical Description
- 1 electronic document
- Additional Creators
- Huang, Wensheng, Shastry, Rohit, and Haag, Thomas W.
Online Version
- hdl.handle.net , Connect to this object online.
- Restrictions on Access
- Unclassified, Unlimited, Publicly available.
Free-to-read Unrestricted online access - Summary
- The HiVHAc propulsion system is currently being developed to support Discovery-class NASA science missions. Presently, the thruster meets the required operational lifetime by utilizing a novel discharge channel replacement mechanism. As a risk reduction activity, an alternative approach is being investigated that modifies the existing magnetic circuit to shift the ion acceleration zone further downstream such that the magnetic components are not exposed to direct ion impingement during the thruster's lifetime while maintaining adequate thruster performance and stability. To measure the change in plasma properties between the original magnetic circuit configuration and the modified, "advanced" configuration, six Langmuir probes were flush-mounted within each channel wall near the thruster exit plane. Plasma potential and electron temperature were measured for both configurations across a wide range of discharge voltages and powers. Measurements indicate that the upstream edge of the acceleration zone shifted downstream by as much as 0.104 channel lengths, depending on operating condition. The upstream edge of the acceleration zone also appears to be more insensitive to operating condition in the advanced configuration, remaining between 0.136 and 0.178 channel lengths upstream of the thruster exit plane. Facility effects studies performed on the original configuration indicate that the plasma and acceleration zone recede further upstream into the channel with increasing facility pressure. These results will be used to inform further modifications to the magnetic circuit that will provide maximum protection of the magnetic components without significant changes to thruster performance and stability.
- Other Subject(s)
- Collection
- NASA Technical Reports Server (NTRS) Collection.
- Note
- Document ID: 20150021866.
GRC-E-DAA-TN24676.
ISTS-2015-b-246.
IEPC-2015-246.
Nano-satellite Symposium; 4-10 Jul. 2015; Kobe-Hyogo; Japan.
International Symposium on Space Technology and Science; 4-10 Jul. 2015; Kobe-Hyogo; Japan.
International Electric Propulsion Conference (IEPC); 4-10 Jul. 2015; Kobe-Hyogo; Japan. - Terms of Use and Reproduction
- No Copyright.
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