Emitted current self-balancing for spacecraft charging mitigation in a high-voltage power converter for electrospray thrusters

Electrospray thrusters offer remarkable efficiency at low power levels and compact form factor, positioning them as promising propulsion systems for small satellite platforms. The ability of electrospray thrusters to emit both positive and negative ion beams has significant implications for charge n...

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Veröffentlicht in:Journal of electric propulsion 2024-11, Vol.3 (1), p.26, Article 26
Hauptverfasser: Blázquez-Plaza, Francisco José, Barrado, Andrés, Wijnen, Mick
Format: Artikel
Sprache:eng
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Zusammenfassung:Electrospray thrusters offer remarkable efficiency at low power levels and compact form factor, positioning them as promising propulsion systems for small satellite platforms. The ability of electrospray thrusters to emit both positive and negative ion beams has significant implications for charge neutralization. In theory, electrosprays could function without the need for an external cathode. If two separate thrusters are operated simultaneously with one emitting a positive ion beam and the other an identical negative ion beam, the spacecraft would theoretically remain charge-neutral, allowing the thrusters to operate continuously without inducing spacecraft charging. This article explores the self-balancing of emitted currents, and consequently the ion beams, by incorporating a capacitor as a control element. This approach achieves current balancing without altering the operation of the power converter. The thruster’s behavior as an electrical load is simulated using a novel electrical model derived from experimental thruster data. This model, integrated within the converter, demonstrates that the inclusion of a capacitor effectively balances the emitted currents. Experimental validation aligns with the simulation results, confirming current balance with a relative error between polarities of only 1% in the final test cases.
ISSN:2731-4596
2731-4596
DOI:10.1007/s44205-024-00089-8