Determining the Effective Space Debris Attitude Motion Modes for Ion-Beam-Assisted Transportation

Contactless space debris transportation systems based on the use of an ion beam are a promising direction among active space debris removal systems. The magnitude of the force generated by the ion beam depends on the orientation of the space debris object in the ion beam created by an active spacecraft. During the ion transport process, the space debris object can oscillate or rotate, which leads to a change in the generated force. The aim of this study is to develop an algorithm for determining the attitude motion mode of space debris, which is most favorable for its contactless transportation. The time-averaged generated ion force is used as the performance index. A simplified system of equations describing the spatial motion of a cylindrical axisymmetric object in a circular orbit is obtained. A generalized energy integral is found. An algorithm for determining the most favorable angular motion mode of a space debris object is developed. A numerical study of a cylindrical space debris object attitude motion under the action of an ion torque is carried out. The favorable attitude motion mode is determined, and the average forces in the most favorable and unfavorable modes are compared.

[1]  Bijiao He,et al.  A Review of Research on the Vacuum Plume , 2022, Aerospace.

[2]  V. Aslanov,et al.  Review of contact and contactless active space debris removal approaches , 2022, Progress in Aerospace Sciences.

[3]  V. Svotina,et al.  Space debris removal – Review of technologies and techniques. Flexible or virtual connection between space debris and service spacecraft , 2022, Acta Astronautica.

[4]  A. Kiran,et al.  Conceptual analysis for a technology demonstration mission of the ion beam shepherds , 2022, CEAS Space Journal.

[5]  Vladimir S. Aslanov,et al.  Fuel costs estimation for ion beam assisted space debris removal mission with and without attitude control , 2021 .

[6]  V. Aslanov,et al.  Detumbling of axisymmetric space debris during transportation by ion beam shepherd in 3D case , 2021, Advances in Space Research.

[7]  F. Cichocki,et al.  Formation and neutralization of electric charge and current of an ion thruster plume , 2021, Plasma Sources Science and Technology.

[8]  V. Svotina,et al.  Ion Source—Mathematical Simulation Results versus Experimental Data , 2021, Aerospace.

[9]  A. I. Pokryshkin,et al.  Control of a service satellite during its mission on space debris removal from orbits with high inclination by implementation of an ion beam method , 2021, Acta Astronautica.

[10]  Alessandro Rossi,et al.  Identifying the 50 statistically-most-concerning derelict objects in LEO , 2021 .

[11]  V. A. Kirillov,et al.  Problematic issues of spacecraft development for contactless removal of space debris by ion beam , 2021 .

[12]  H. Yue,et al.  Prospects of de-tumbling large space debris using a two-satellite electromagnetic formation , 2021 .

[13]  S. Khoroshylov Relative control of an ion beam shepherd satellite in eccentric orbits , 2020 .

[14]  C. Pardini,et al.  Environmental sustainability of large satellite constellations in low earth orbit , 2020 .

[15]  Bijiao He,et al.  Sputtering distribution of LIPS200 ion thruster plume , 2019, Acta Astronautica.

[16]  Hodei Urrutxua,et al.  A preliminary design procedure for an ion-beam shepherd mission , 2019, Aerospace Science and Technology.

[17]  Alex Ellery,et al.  Tutorial Review on Space Manipulators for Space Debris Mitigation , 2019, Robotics.

[18]  Inna Sharf,et al.  Simulation of tether-nets for capture of space debris and small asteroids , 2019, Acta Astronautica.

[19]  C. Bombardelli,et al.  Relative control of an ion beam shepherd satellite using the impulse compensation thruster , 2018, Acta Astronautica.

[20]  F. Cichocki,et al.  Spacecraft-plasma-debris interaction in an ion beam shepherd mission , 2018 .

[21]  M. Merino,et al.  Non-Maxwellian electron energy probability functions in the plume of a SPT-100 Hall thruster , 2017 .

[22]  Thomas Schildknecht,et al.  Apparent rotation properties of space debris extracted from photometric measurements , 2017 .

[23]  A. A. Fokov,et al.  Determination of the force transmitted by an ion thruster plasma plume to an orbital object , 2016 .

[24]  J. Liou An active debris removal parametric study for LEO environment remediation , 2011 .

[25]  C. Bombardelli,et al.  Ion Beam Shepherd for Contactless Space Debris Removal , 2011, 1102.1289.

[26]  A. Ledkov,et al.  Descent of Nanosatellite from Low Earth Orbit by Ion Beam , 2019, Izvestiya of Saratov University. New Series. Series: Mathematics. Mechanics. Informatics.