Small Satellite LEO Maneuvers with Low-Power Electric Propulsion

King, Scott; Walker, Mitchell L. R.; Kluever, Craig A.

doi:10.2514/6.2008-4516

Cited by 3 publications

(1 citation statement)

References 16 publications

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“…Thus, the deployment can be decomposed in two main actions: the placement of satellites into the correct orbital planes, which are typically spaced by a predefined DX, and the in-plane separation which generates a certain Dk between two adjacent satellites in an orbital plane. The paper focuses on the first aspect exclusively, since the latter is typically characterized by smaller DV s and it has been widely treated in literature (Shang et al, 2015;Pontani and Teofilatto, 2022;King et al, 2008). In this paper, the term ''deployment" will be used to indicate the first aspect exclusively.…”

Section: Introductionmentioning

confidence: 99%

Optimization of constellation deployment using on-board propulsion and Earth nodal regression

Pasquale¹,

Sanjurjo-Rivo²,

Grande³

2022

Advances in Space Research

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Section: Introductionmentioning

confidence: 99%

Optimization of constellation deployment using on-board propulsion and Earth nodal regression

Pasquale¹,

Sanjurjo-Rivo²,

Grande³

2022

Advances in Space Research

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Sitael Hollow Cathodes for Low-Power Hall Effect Thrusters

Pedrini

Ducci

Misuri

et al. 2018

IEEE Trans. Plasma Sci.

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Low-power Hall effect thrusters (HETs) belong to a class of electric thrusters with an operating power lower than 500 W. The application of this class of HETs is suited for small satellites for telecommunications and Earth observation missions. Sitael is active in this field, through the development of two HETs, HT100, and HT400, belonging to a power class of 100 and 400 W, respectively. HT100 is a permanent-magnet thruster operating in the 100- to 250-W range, providing thrust between 4 and 13 mN, and specific impulse between 900 and 1400 s. HT400 operates in the 350- to 750-W range, providing thrust between 20 and 45 mN, and specific impulse between 1300 and 1700 s. Two cathodes have been developed and tested, referred to as HC1 and HC3, conceived for HT100 and HT400, respectively. Both cathodes are based on Sitael heritage in theoretical modeling and experimental activities for the development of such devices, and rely on lanthanum hexaboride emitters. HC1 is a cathode designed to provide a discharge current in the 0.3-1 A range, operating in steady-state conditions at mass flow rates between 0.08 and 0.5 mg/s of xenon. HC3 was designed for the range 1-3 A of discharge current, with 0.08-0.5 mg/s of mass flow rate. Both HC1 and HC3 have an expected lifetime higher than 10⁴ h, based on the rate of material evaporation from the emitter surface, computed with the aid of a theoretical model developed to guide the cathode design. Experiments were carried out, including preliminary characterization campaigns, of each of the two cathodes and HET-cathode coupling tests. The collected data are presented and discussed with reference to the model predictions, showing a good agreement between theoretical and experimental results

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