Modal Analysis of Electric sail

The electric solar wind sail (E-sail) has been proposed as a novel propulsion system that, if successful, promises to facilitate missions that would be inconvenient or impractical with traditional chemical propellants. The most common E-sail concept includes a central hub with several long positivel...

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Veröffentlicht in:	Acta astronautica 2021-08, Vol.185, p.140-147
1. Verfasser:	Lillian, Todd D.
Format:	Artikel
Sprache:	eng
Schlagworte:	Control Control stability Dynamic stability Electric sail Mathematical models Modal Analysis Propulsion systems Resonant frequencies Sails Solar wind Spokes Tether
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creator	Lillian, Todd D.
description	The electric solar wind sail (E-sail) has been proposed as a novel propulsion system that, if successful, promises to facilitate missions that would be inconvenient or impractical with traditional chemical propellants. The most common E-sail concept includes a central hub with several long positively charged tethers extending radially outward that harvest momentum from protons in the solar wind. Before the technology is ready for a demonstration mission, we must prove E-sail dynamics can be controlled throughout all phases of the mission. The objective of this paper is to present an analytical model for the linear vibrations of hub and spoke E-sails to facilitate the development of necessary control schemes. Although there is no limit to the number of spokes in our model, we demonstrate its capability by representing a system with 3 spokes. The resultant natural frequencies and mode shapes provide insight into the dynamics and stability of E-sails and lay the foundation for development of control schemes. In addition, our work reveals several simple calculations that accurately estimate many of the natural frequencies and could be used to facilitate the design of future E-sails. •Derivation of an analytical model for electric solar wind sail vibrations.•Simple models accurately predict natural frequencies of electric solar wind sails.•Hub and spoke electric solar wind sails can configured to be infinitesimally stable.
doi_str_mv	10.1016/j.actaastro.2021.05.003
format	Article
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subjects	Control Control stability Dynamic stability Electric sail Mathematical models Modal Analysis Propulsion systems Resonant frequencies Sails Solar wind Spokes Tether
title	Modal Analysis of Electric sail
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