Deorbit kit demonstration mission Articles uri icon

authors

  • SANCHEZ ARRIAGA, GONZALO
  • TARABINI CASTELLANI, LORENZO
  • GARCIA GONZALEZ, S.
  • ORTEGA, A.
  • MADRID, S.
  • LORENZINI, ENRICO
  • OLIVIERI, L.
  • SAREGO, G.
  • BRUNELLO, A.
  • VALMORBIDA, A.
  • TAJMAR, MARTIN
  • DROBNY, C.
  • WULFKUEHLER, J-P.
  • NERGER, R.
  • WATZIG, KATJA
  • SHAHSAVANI, SADAF

publication date

  • June 2022

start page

  • 165

end page

  • 173

issue

  • 2

volume

  • 9

International Standard Serial Number (ISSN)

  • 2468-8975

Electronic International Standard Serial Number (EISSN)

  • 2468-8967

abstract

  • In Low Earth Orbit, it is possible to use the ambient plasma and the geomagnetic field to exchange momentum with the Earth's magnetosphere without using propellant. A device that allows an efficient momentum exchange is the electrodynamic tether (EDT), a long conductor attached to the satellite. EDT technology has been demonstrated in several past missions, being the Plasma Motor Generator mission (NASA 1993) one of the most successful. Nevertheless, it is not until today that reality has imposed a strong need and a concrete use case for developing this technology. In March 2019, the European Commission project Electrodynamic Tether technology for PAssive Consumable-less deorbit Kit (E.T.PACK) started the design of a new generation EDT. After completing the design phase, the consortium manufactured and is currently testing a Deorbit Kit Demonstrator (DKD) breadboard based on EDT technology. The objective of E.T.PACK is to reach Technology Readiness Level equal to 4 by 2022. The DKD is a standalone 24-kg satellite with the objective to demonstrate the performances of the improved EDT solution and validate its ultra-compact deployment system. The DKD is composed of two modules that will separate in orbit extending a 500-m long tape-like tether. The deployed bare-Aluminium tether will capture electrons from the ambient plasma passively and the circuit will be closed with the ionospheric plasma by using an active electron emitter. E.T.PACK tether will take advantage of several novelties with respect to the mission flown in the past that will allow to optimize the system volume and mass. Once successful demonstrated in orbit, the team plans to develop a suite of EDT systems capable of deorbiting satellites between 200 and 1000 kg from an altitude up to 1200 km in a few months. The work presents the current design status of the de-orbit kit demonstrator breadboard, the simulations of the system deorbit performances and the development approach.

subjects

  • Aeronautics
  • Physics

keywords

  • deorbit kit; electrodynamic; propellantless; space debris; tether