Model study of the influence of the magnetic field configuration on the performance and lifetime of a Hall thruster

Garrigues, Laurent; Hagelaar, Gerjan; Bareilles, J.; Boniface, C.; Boeuf, Jean-Pierre

doi:10.1063/1.1622670

Cited by 93 publications

(80 citation statements)

References 8 publications

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“…The thrust from cold gas or electrothermal thrusters is derived from the momentum of the exhausted neutral gas propellant, as distinct from electrostatic or electromagnetic thrusters, where the thrust is defined as the force in reaction to the acceleration of ions through an electric field [71,72]. PR belongs to the former class of neutral gas thrusters; it operates as an electrothermal microthruster when RF power is supplied to ionize and heat the neutral gas propellant [30,31], and as a cold gas microthruster when no RF power is supplied.…”

Section: Thrustmentioning

confidence: 99%

A Comprehensive Cold Gas Performance Study of the Pocket Rocket Radiofrequency Electrothermal Microthruster

Charles

Boswell

2017

Front. Phys.

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This paper presents computational fluid dynamics simulations of the cold gas operation of Pocket Rocket and Mini Pocket Rocket radiofrequency electrothermal microthrusters, replicating experiments performed in both sub-Torr and vacuum environments. This work takes advantage of flow velocity choking to circumvent the invalidity of modeling vacuum regions within a CFD simulation, while still preserving the accuracy of the desired results in the internal regions of the microthrusters. Simulated results of the plenum stagnation pressure is in precise agreement with experimental measurements when slip boundary conditions with the correct tangential momentum accommodation coefficients for each gas are used. Thrust and specific impulse is calculated by integrating the flow profiles at the exit of the microthrusters, and are in good agreement with experimental pendulum thrust balance measurements and theoretical expectations. For low thrust conditions where experimental instruments are not sufficiently sensitive, these cold gas simulations provide additional data points against which experimental results can be verified and extrapolated. The cold gas simulations presented in this paper will be used as a benchmark to compare with future plasma simulations of the Pocket Rocket microthruster.

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Section: Thrustmentioning

confidence: 99%

A Comprehensive Cold Gas Performance Study of the Pocket Rocket Radiofrequency Electrothermal Microthruster

Charles

Boswell

2017

Front. Phys.

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“…3 A relatively long (~ 2 cm) ion acceleration region with a large voltage drop is usually located both inside the channel and outside the channel exit, where the fringing magnetic field can lead to defocusing of the ion beam. 3,4 The use of segmented electrodes along the thruster channel can provide additional control of the plasma flow in a Hall thruster. [5][6][7][8] The plume narrowing effect measured for molybdenum and carbon electrodes at low discharge voltages (≤300 V) 6,7 was attributed to the reduced voltage drop outside the channel exit.…”

mentioning

confidence: 99%

Operation of a segmented Hall thruster with low-sputtering carbon-velvet electrodes

Raitses¹,

Staack²,

Dunaevsky³

et al. 2006

Journal of Applied Physics

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Carbon fiber velvet material provides exceptional sputtering resistance properties exceeding those for graphite and carbon composite materials. A 2kW Hall thruster with segmented electrodes made of this material was operated in the discharge voltage range of 200–700V. The arcing between the floating velvet electrodes and the plasma was visually observed, especially, during the initial conditioning time, which lasted for about 1h. The comparison of voltage versus current and plume characteristics of the Hall thruster with and without segmented electrodes indicates that the magnetic insulation of the segmented thruster improves with the discharge voltage at a fixed magnetic field. The observations reported here also extend the regimes wherein the segmented Hall thruster can have a narrower plume than that of the conventional nonsegmented thruster.

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“…While this may prove to be accurate, there are still questions concerning the rate at which lifetime decreases with voltage. Modeling by Garrigues, et al [52] has begun to address some of these issues by demonstrating how erosion rates in 1600 s specific impulse thrusters decrease when a plasma lens is used (in lieu of less concave magnetic field lines). Efforts to predict the operational lifetime of NASA Hall thrusters are also currently be pursued [53].…”

Section: Discussionmentioning

confidence: 99%

Efficiency Analysis of a High-Specific Impulse Hall Thruster

Hofer¹,

Gallimore

2004

40th AIAA/ASME/SAE/ASEE Joint Propulsion Conference and Exhibit

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Model study of the influence of the magnetic field configuration on the performance and lifetime of a Hall thruster

Cited by 93 publications

References 8 publications

A Comprehensive Cold Gas Performance Study of the Pocket Rocket Radiofrequency Electrothermal Microthruster

A Comprehensive Cold Gas Performance Study of the Pocket Rocket Radiofrequency Electrothermal Microthruster

Operation of a segmented Hall thruster with low-sputtering carbon-velvet electrodes

Efficiency Analysis of a High-Specific Impulse Hall Thruster

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