Study on the eddy current damping of the spin dynamics of space debris from the Ariane launcher upper stages

Study on the eddy current damping of the spin dynamics of space debris from the Ariane launcher upper stages

This paper addresses the topic of damping of the spin dynamics of a spatial debris orbiting around the Earth. Such debris, which can consist of parts of heavy launchers such as the Ariane rocket under consideration in this article, are impacted by torques generated by eddy currents as their conducti...

Full description

Saved in:
Bibliographic Details
Published in:Acta astronautica Vol. 76; pp. 145 - 153
Main Authors: Praly, N., Hillion, M., Bonnal, C., Laurent-Varin, J., Petit, N.
Format: Journal Article
Language:English
Published: Elsevier Ltd 01-07-2012
Elsevier
Subjects:
Automatic
Damping of spin motion
Eddy currents
Engineering Sciences
Space debris
Space debris
Damping of spin motion
Eddy currents
Online Access:Get full text
Tags: Add Tag
No Tags, Be the first to tag this record!
Description
Summary:This paper addresses the topic of damping of the spin dynamics of a spatial debris orbiting around the Earth. Such debris, which can consist of parts of heavy launchers such as the Ariane rocket under consideration in this article, are impacted by torques generated by eddy currents as their conducting non-ferromagnetic body orbits through the Earth magnetosphere. Several previous works have focused on describing this induction phenomenon and have proposed analysis of empirical observations of this particular and important effect which has attracted much attention since the number of spatial debris has emerged as a problem for the future of space programs, especially in low orbits. In this paper, we present a relatively comprehensive modeling of the induction phenomenon, by means of Maxwell's equations inside the conducting and non-ferromagnetic body. Through the generalized Ohm's law, we show how one can obtain a partial differential equation with Neumann's boundary conditions problem that, once solved, e.g. through a finite elements method, yields the values of induced currents and braking torques. The case of a depleted upper stage of a heavy launcher, having a cylindrical shape and thin walls is particularly studied. We show a methodology to estimate the decay-rate of the spinning velocity, which is proven to satisfy a first-order asymptotically stable linear dynamics. Special cases consisting of typical orbit of space debris are treated. ► Methodology to compute induction braking torques. ► Application to a sphere and Ariane-5-H10-stage-like geometry to evaluate eddy current braking torques. ► Simulation of damping dynamics of a rotating debris along typical H-10 orbits. ► Decay time evaluation for an Ariane-5-H10-stage-like geometry below 250 days. ► Survey on H-10 stages observations.
ISSN:0094-5765
1879-2030
DOI:10.1016/j.actaastro.2012.03.004