Design of novel adaptive magnetic adhesion mechanism for climbing robots in ferric structures By: Francisco Ochoa Cardenas A thesis submitted in partial fulfilment of the requirements for the degree of Doctor of Philosophy The University of Sheffield Faculty of Engendering Department of Automatic Control and Systems Engineering November 2016 ii iii iv Abstract The work presented in this thesis proposes a novel adaptive magnetic adhesion mechanism that can be implemented in most locomotion mechanisms employed in climbing robots for ferric structures. This novel mechanism has the capability to switch OFF and ON its magnetic adhesion with minimal power consumption, and remain at either state after the excitation is removed. Furthermore, the proposed adhesion mechanism has the ability to adapt the strength of the adhesive force to a desired magnitude. These capabilities make the proposed adhesion mechanism a potential solution in the field of wall climbing robots. The novel contributions of the proposed mechanism include the switching of the adhesive force, selectivity of the adhesive force magnitude; determination of the parameters that have an impact in the final adhesive force. Finally, a final prototype is constructed with customised components and it is subject to a set of simulations and experiments to validate its performance. iii iv Acknowledgments Firstly, I would like to express my deepest gratitude to my supervisor, Prof. Tony J. Dodd, for all his support, guidance through the PhD and specially for his patience. All my gratitude to the people that encouraged me on pursuing the PhD and that always were present. • My wife, whose support, patience and encouragement where vital for reaching the end. • My daughter and son, which are the motor that push me go further and never give up. • My parents, whose care, support and guidance in life have driven me to reach the unimaginable. • My aunts Cuca and Pina Ochoa, and uncle Luis Ochoa, who set the basis, along with my parents, that allowed me be where I am, and more important to be who I am Last but not least, I would like to thank my two Mexicans sponsors, CONACyT and SEP (under Becas Complemento SEP grant), for the great opportunity to going abroad to study and contribute the future of my country. v vi Contents 1.1. Motivation ........................................................................................................ 2 1.2. Problem definition ......................................................................................... 4 1.3. Aims and objectives ....................................................................................... 4 1.4. Contributions ...................................................................................................5 1.5. Thesis outline .................................................................................................. 6 2.1. Classification of the unmanned vehicles ................................................ 10 2.2. Wall climbing mobile robots ...................................................................... 14 2.2.1. Locomotion mechanisms ............................................................... 18 2.2.2. Adhesion mechanisms .................................................................... 21 2.3. WCMR for inspection of ferric structures ............................................. 26 2.3.1. Electro-permanent magnets ......................................................... 28 2.4. Concluding remarks ..................................................................................... 31 3.1. Theory.............................................................................................................. 33 vii 3.1.1. Important concepts ........................................................................ 34 3.2. Working principles ...................................................................................... 39 3.2.1. OFF and ON configurations .......................................................... 40 3.2.2. Variable magnetic adhesive force ............................................... 43 3.2.3. Characteristics of the EPMs ......................................................... 44 3.3. Validation of the electro-permanent magnet concept ....................... 45 3.3.1. Basic configuration and components of the EPM .................. 46 3.3.2. Equipment and experimental setup .......................................... 48 3.3.3. Simulation and experimental results: basic OFF and ON configurations ........................................................................... 54 3.3.4. Switching between states and variable magnetic adhesive force ................................................................................... 58 3.4. Concluding remarks .................................................................................... 64 4.1. Locomotion mechanism selection .......................................................... 66 4.1.1. Selection of the locomotion mechanism and EPMAM integration ......................................................................................... 70 4.2. EPMAM Implementation in the wheeled locomotion mechanism ..................................................................................................... 73 4.2.1. Preliminary simulations of the wheeled EPMAM design ...................................................................................................77 4.3. Validation of the proposed wheeled locomotion mechanism with EPMAM .................................................................................................. 80 4.3.1. OFF and ON states validation ....................................................... 81 4.3.2. Validation of the OFF-ON and ON-OFF switching, and variable magnetic adhesion .......................................................... 83 4.4. Concluding remarks .................................................................................... 90 5.1. Influence of the individual design components in the final adhesive force ................................................................................................ 94 5.1.1. Steel keepers ..................................................................................... 95 5.1.2. Enamelled wire gauge..................................................................... 97 5.1.3. Gap between EPM device and adhesion surface ..................... 98 5.2. Configuration of the EPMAM into the wheel ...................................... 101 5.2.1. Rotating EPMAM ............................................................................ 101 viii
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