This text is based on the research work of the author in the field of space robots. It started as a collection of notes of the lectures on Space Robotics given by the author to the students of the International Master on Space Exploration and Development Systems (SEEDS) but evolved to a research monograph on the subject. Its aim is the study of the automatic machines aimed to operate both autonomously and as a support to astronauts in space exploration and exploitation missions, with particular attention to the devices designed for planetary environment, including small planets, comets and asteroids. This material was then completed and made more systematic so that it can hopefully be useful not only to the students of that course but also to those who have an interest in the wide and much interdisciplinary field of space robotics, and in particular in its mechanical aspects. The focus is drawn mainly on the mechanics of space robots: the author is well aware that, even in this specific field, it is far from being complete and that robots, like all mechatronic systems, are so integrated that no single aspect can be dealt separately. Many important aspects are either dealt with only marginally or altogether left out. The very important topics of the control and the behavior of robots, for instance, are only marginally touched, even if their influence on the mechanical aspect to which this book is dedicated is not at all marginal. The structure of the book is so organized: ∙ Chapter 1: a very short introductory overview of human and robotic space exploration, stressing the need for man-machine cooperation in exploration. The various types of robotic missions in LEO, deep space and on planets and their basic requirements are shortly summarized. ∙ Chapter 2 deals in a synthetic way with the main characteristics of the environments space robots are facing and will face in the future. Since space environment is a specialized subject, dealt with in many books, this subject is only briefly summarized. ∙ The configurations of robot arms and the basic kinematic and dynamic relationships needed for their design are described in Chapter 3. ∙ Chapter 4 is devoted to the study of mobility on planetary surfaces, using different kind of supporting devices, like wheels, legs and aerodynamic or aerostatic devices. ∙ The basic characteristics of wheeled robots and vehicles are summarized in Chapter 5. The behavior of wheeled devices is studied in its various aspects, like longitudinal, lateral and suspension dynamics. The consequences of operating wheeled machines in the various environments are analyzed in some detail. The chapter is concluded by a description of the only vehicle that successfully carried humans on the surface of the Moon, the Apollo Lunar Roving Vehicle. ∙ Vehicles and robots that use legs, tracks or other devices to move on a solid surface are described in Chapter 6. Since a great number of different architectures were proposed and sometimes even used in the past, not all the possible configurations are illustrated: the choice was based on the actual existing applications and on the perspectives of future use. ∙ Chapter 7 is devoted to a short overview of the transducers used for actuation and sensing in space robots. ∙ A short overview of the energy sources and storage devices that can be used for space robots is reported in Chapter 8. The book includes two appendices summarizing the theoretical formulations allowing to write mathematical models of space robots including a variety of mechanical components, such as arms, legs, etc. The author found it necessary to include them since the participants to the course in Space Exploration and Development Systems have a much varied background and what may seem obvious to some students, could be difficult for other ones. In a similar ways, some of the readers of this book may not be familiar with the concepts of analytical mechanics or dynamics of deformable bodies used in the text, mainly in Chapters 3 and 5. In 2014 it received the Engineering Science Book Award of the International Academy of Astronautics, given annually to recognize excellence in publication made by a member or a corresponding member of the Academy in the fields related to basic engineering science.

Introduction to the Mechanics of Space Robots / Genta, Giancarlo. - STAMPA. - (2012). [10.1007/978-94-007-1796-1]

Introduction to the Mechanics of Space Robots

GENTA, GIANCARLO
2012

Abstract

This text is based on the research work of the author in the field of space robots. It started as a collection of notes of the lectures on Space Robotics given by the author to the students of the International Master on Space Exploration and Development Systems (SEEDS) but evolved to a research monograph on the subject. Its aim is the study of the automatic machines aimed to operate both autonomously and as a support to astronauts in space exploration and exploitation missions, with particular attention to the devices designed for planetary environment, including small planets, comets and asteroids. This material was then completed and made more systematic so that it can hopefully be useful not only to the students of that course but also to those who have an interest in the wide and much interdisciplinary field of space robotics, and in particular in its mechanical aspects. The focus is drawn mainly on the mechanics of space robots: the author is well aware that, even in this specific field, it is far from being complete and that robots, like all mechatronic systems, are so integrated that no single aspect can be dealt separately. Many important aspects are either dealt with only marginally or altogether left out. The very important topics of the control and the behavior of robots, for instance, are only marginally touched, even if their influence on the mechanical aspect to which this book is dedicated is not at all marginal. The structure of the book is so organized: ∙ Chapter 1: a very short introductory overview of human and robotic space exploration, stressing the need for man-machine cooperation in exploration. The various types of robotic missions in LEO, deep space and on planets and their basic requirements are shortly summarized. ∙ Chapter 2 deals in a synthetic way with the main characteristics of the environments space robots are facing and will face in the future. Since space environment is a specialized subject, dealt with in many books, this subject is only briefly summarized. ∙ The configurations of robot arms and the basic kinematic and dynamic relationships needed for their design are described in Chapter 3. ∙ Chapter 4 is devoted to the study of mobility on planetary surfaces, using different kind of supporting devices, like wheels, legs and aerodynamic or aerostatic devices. ∙ The basic characteristics of wheeled robots and vehicles are summarized in Chapter 5. The behavior of wheeled devices is studied in its various aspects, like longitudinal, lateral and suspension dynamics. The consequences of operating wheeled machines in the various environments are analyzed in some detail. The chapter is concluded by a description of the only vehicle that successfully carried humans on the surface of the Moon, the Apollo Lunar Roving Vehicle. ∙ Vehicles and robots that use legs, tracks or other devices to move on a solid surface are described in Chapter 6. Since a great number of different architectures were proposed and sometimes even used in the past, not all the possible configurations are illustrated: the choice was based on the actual existing applications and on the perspectives of future use. ∙ Chapter 7 is devoted to a short overview of the transducers used for actuation and sensing in space robots. ∙ A short overview of the energy sources and storage devices that can be used for space robots is reported in Chapter 8. The book includes two appendices summarizing the theoretical formulations allowing to write mathematical models of space robots including a variety of mechanical components, such as arms, legs, etc. The author found it necessary to include them since the participants to the course in Space Exploration and Development Systems have a much varied background and what may seem obvious to some students, could be difficult for other ones. In a similar ways, some of the readers of this book may not be familiar with the concepts of analytical mechanics or dynamics of deformable bodies used in the text, mainly in Chapters 3 and 5. In 2014 it received the Engineering Science Book Award of the International Academy of Astronautics, given annually to recognize excellence in publication made by a member or a corresponding member of the Academy in the fields related to basic engineering science.
2012
9789400717954
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Utilizza questo identificativo per citare o creare un link a questo documento: https://hdl.handle.net/11583/2460376
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