Abstract

This paper presents detumbling and capture of space debris by a dual-arm space robot for active space debris removal missions. Space debris, such as a malfunctioning satellite or a rocket upper stage, often has uncontrolled tumbling motion. It also has uncertainties in its parameters, such as inertial characteristics or surface frictional roughness. These factors make the debris capture missions difficult to accomplish. To cope with such challenging missions, we propose a detumbling and capture control method for a dual-arm robot based on repeated impact capable of suppressing the debris motion by repeatedly utilizing an effect of a passive damping factor in the contact characteristics. In this paper, as the initial step of a study on the repeated impact-based capture method, we assume that the capture target is a rocket upper stage that can be simply modeled as a cylindrical body and mainly has angular velocity motion in its principle axis of inertia. A motion tracking control law of an end-effector of the robot arm is introduced to maintain the repeated impact. The proposed control method enables the robot to accomplish the detumbling and capture without precise estimation of the inertial characteristics and surface frictional roughness of the debris. The validity of the proposed method is presented by numerical simulations and planar microgravity experiments using an air-floating system. In particular, the experimental evaluation shows the fundamental feasibility of the proposed method, and thus, the result contributes to a practical application.

Highlights

  • An active space debris removal system is a critical technology for sustainable utilization of an orbital environment (Liou and Johnson, 2006)

  • We propose a repeated impact-based control method for detumbling and capture of a spinning object by a dual-arm space robot in orbit

  • This paper presented a repeated impact-based capture control for a dual-arm space robot and its experimental validation

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Summary

Introduction

An active space debris removal system is a critical technology for sustainable utilization of an orbital environment (Liou and Johnson, 2006). To achieve secure capture and de-orbit of the space debris, robotic removal missions have been proposed toward practical space debris mitigation. A contactless detumbling method by inducing eddy currents has been proposed (Kadaba and Naishadham, 1995; Sugai et al, 2013; Gomez and Walker, 2015) These methods targeted a fixed-base (not free-flying) chaser system or focused only on the target’s spin. A rotational motion damper for detumbling with relative motion has been proposed (Matsunaga et al, 2001) This method basically assumes the condition that the target parameters, including mass and moment of inertia, are fully known

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