The improvements and innovations in the field of robotics have given a great opportunity to perform tasks that are hazardous for humans to perform. For example, robots can be used for working on high-storied buildings, inspection on ferromagnetic surfaces, painting and maintenance of buildings, surveillance purposes, etc., at the outset, to carry out any operation on vertical surfaces, which may be quite hazardous and time-consuming as well, wall climbing robots (WCRs) can be deployed. The method of adhesion determines the stability of the robot on the wall, be it smooth or coarse. Using magnets to bring about magnetic adhesion would be advantageous when the robot is maneuvered over iron or steel surfaces, typically, to clean boilers, etc., This paper presents the different ways of placements of the magnets, both permanent and electromagnets, in order to introduce adequate magnetic adhesion that would cease the robot from toppling down while encountering an obstacle. This work proposes two methods of arrangement of magnets: square and diamond. Four electromagnets when arranged in array formation with 5000 windings of thin copper coil, generated a magnetic field force of approximately 150 N when 50 A of current is passed. By and large, around 35 N to 40 N is the suction force that would be sufficient to stick the WCR of 2kg on the wall, while using a suction chamber instead of electromagnets. Other methods of placing the magnets such as square and diamond are studied and compared as well using FEMM. Hence arranging the 4 electromagnets in array formation gives an adhesion pressure sufficient to hold and move the WCR, over the vertical wall against gravity.

Wall climbing robot; Electromagnetic adhesion; Electromagnets arrangements; Magnetic flux linkage

J. Jose, D. Dinakaran, M. M. Ramya and D. G. Harris Samuel, “A Survey on Magnetic Wall-Climbing Robots for Inspection,” International Journal of Mechanical and Production Engineering Research and Development (IJMPERD), vol. 8, no. 6, pp. 59-68, 2018.

S. K. Mahmood, S. H. Bakhy, M. A. Tawfik, “Magnetic–type Climbing Wheeled Mobile Robot for Engineering Education,” 2nd International Scientific Conference of Al-Ayen University (ISCAU-2020).

C. Yan, Z. Sun, W. Zhang, and Q. Chen, "Design of novel multidirectional magnetized permanent magnetic adsorption device for wall-climbing robots." International Journal of Precision Engineering and Manufacturing, vol. 17, no. 7, pp. 871-878, 2016.

K. Huang, Y. Sun, J. Yang, M. Hao, Y. Chen, X. Hong, and X. Li “Researches on a Wall-Climbing Robot Based on Electromagnetic Adsorption,” 2019 IEEE 3rd Information Technology, Networking, Electronic and Automation Control Conference (ITNEC), 2019.

J. Fan, T. Xu, Q. Fang, J. Zhao, and Y. Zhu, "A Novel Style Design of a Permanent-Magnetic Adsorption Mechanism for a Wall-Climbing Robot," ASME. J. Mechanisms Robotics, vol. 12, no. 3, p. 035001, 2020.

A. San-Millan, “Design of a teleoperated wall climbing robot for oil tank inspection,” 23rd Mediterranean Conference on Control and Automation (MED), 2015.

N. Navaprakash, U. Ramachandraiah, G. Muthukumaran, V. Rakesh and A. P. Ashutosh, “Modeling and Experimental Analysis of Suction Pressure Generated by Active Suction Chamber Based Wall Climbing Robot with a Novel Bottom Restrictor,” Procedia Computer Science, vol. 133, pp. 847-854, 2018, doi: 10.1016/j.procs.2018.07.110.

Y. Chang, “Development of a wall climbing inspection robot with high mobility on complex shaped walls,” University of Canterbury, 2015.

M. F. Silva, R. S. Barbosa, and A. L. C. Oliveira, “Climbing Robot for Ferromagnetic Surfaces with Dynamic Adjustment of the Adhesion System,” Journal of Robotics, vol. 2012, p. 906545, 2012.

X. Chen, Y. Wu, H. Hao, H. Shi and H. Huang, “Tracked Wall-Climbing Robot for Calibration of Large Vertical Metal Tanks,” Appl. Sci., vol. 9, p. 2671, 2019.

L. Han, L. Wang, S. Fan, and Y. Wang, "Research on distributed electromagnetic track adsorption mechanism," In 2021 IEEE 2nd International Conference on Big Data, Artificial Intelligence and Internet of Things Engineering (ICBAIE), pp. 892-898. IEEE, 2021.

W. A. Demirjian, "Investigation and Implementation of Track-based Climbing Robots Using Dry-adhesives for High-payload Applications," PhD diss., Tennessee Technological University, 2019.

X. Tang, D. Zhang, Z. Li and J. Chen, “An Omni-directional Wall-climbing Microrobot with Magnetic Wheels Directly Integrated with Electromagnetic Micromotors,” International Journal of Advanced Robotic Systems, vol. 9, no. 1, p. 16, 2012.

S. Gao, R. Hou, J. Li, Y. Pan, S. He, and H. Li, "Magnetic Field Analysis and Structure Design of a New Magnetic Wheel for Wall-Climbing Robot," Journal of Superconductivity and Novel Magnetism, vol. 35, no. 2, pp. 529-537, 2022.

D. Zhang, Z. Li and J. Chen, “Design and Optimization of an Omnidirectional Permanent-Magnetic Wheeled Wall-Climbing Microrobot with MEMS-Based Electromagnetic Micromotors,” Advanced Robotics, vol. 26, no. 1-2, pp. 197-218, 2012.

R. S. Bisht, P. M. Pathak, and S. K. Panigrahi, "Experimental investigations on permanent magnet based wheel mechanism for safe navigation of climbing robot," Procedia computer science, vol. 133, pp. 377-384, 2018.

R. S. Bisht, P. M. Pathak, and S. K. Panigrahi, "Development of Magnetic Adhesion Based Wheel-Driven Climbing Machine for Ferrous Surface Applications," In Dynamic Systems and Control Conference, vol. 51890, p. V001T04A016, 2018.

M. S. Chabukswar, R. K. Nanwatkar, and A. M. Bagde, “Design and Experimental Analysis of Magnetic Climbing Robot,” International Journal of Research in Engineering, Science and Management, vol. 2, no. 12, 2019.

W. Shen, J. Gu and Y. Shen, "Permanent magnetic system design for the wall-climbing robot," IEEE International Conference Mechatronics and Automation, 2005, pp. 2078-2083 Vol. 4.

M. O. F. Howlader and T. P. Sattar, “Finite Element Analysis based Optimization of Magnetic Adhesion Module for Concrete Wall Climbing Robot,” International Journal of Advanced Computer Science and Applications, vol. 6, no. 8, 2015, doi: 10.14569/IJACSA.2015.060802.

D. N. Badodkar, N. K. Singh, N. S. Dalal, and M. Singh, “EMAT Integrated with Vertical Climbing Robot for Boiler Tube Inspection,” In Proc. of National Seminar & Exhibition on Non-Destructive Evaluation, pp. 32-36, 2009.

Ö. Acar and C. F. YaŞar, “Autonomous Climbing Robot for Tank Inspection,” Procedia Computer Science, vol. 158, pp. 376-381, 2019.

W. Zhang, W. Zhang and Z. Sun, “A reconfigurable soft wall-climbing robot actuated by electromagnet,” International Journal of Advanced Robotic Systems, vol. 18, no. 2, pp. 1–10, 2021.

M. I. Yehya, S. Hussain, A. Wasim, M. Jahanza, and H. Abdalla," A cost effective and light weight unipolar electroadhesion pad technology for adhesion mechanism of wall climbing robot," International Journal of Robotics and Mechatronics, vol. 2, no. 1, pp. 1-10, 2016.

G. Gu, J. Zou, R. Zhao, X. Zhao, and X. Zhu, “Soft wall-climbing robots,” Science Robotics, vol. 3, no. 25, p. eaat2874, 2018, doi: 10.1126/scirobotics.aat2874.

A. Sahbel, A. Abbas, and T. Sattar, “Experimental and Numerical Optimization of Magnetic Adhesion Force for Wall Climbing Robot Applications,” International Journal of Mecical Engineering and Robotics Research, vol. 8, no. 1, 2019, doi: 10.18178/ijmerr.8.1.18-24.

M. Baranski and K. Glapa, “3D thermal field modelling in electromagnetic gripping system,” ITM Web of Conferences, vol. 28, p. 01012, 2019, doi: 10.1051/itmconf/20192801012.

J. Jose, R. S. Elankavi, D. Dinakaran, R. K. Chetty, and M. M. Ramya, "A Comparative Study of Adhesion Mechanism for Wall Climbing Robots: Ring Magnet vs. Block Magnets," In IOP Conference Series: Materials Science and Engineering, vol. 1145, no. 1, p. 012063, 2021.

J. Jose, R. S. Elankavi, D. Dinakaran, R. K. Chetty, and M. M. Ramya, "Optimization of Distance Between Magnets for Magnetic Wall Climbing Robots," In 2020 3rd International Conference on Intelligent Sustainable Systems (ICISS), pp. 1574-1578, IEEE, 2020.

G. G. Garrido and T. P. Sattar, "An Autonomous Wall-Climbing Robot for Inspection of Reinforced Concrete Structures: SIRCAUR," Journal of Artificial Intelligence and Technology, vol. 1, no. 3, pp. 188-196, 2021.

A. Hajeer, L. Chen, and E. Hu, "Review of classification for wall climbing robots for industrial inspection applications," In 2020 IEEE 16th International Conference on Automation Science and Engineering (CASE), pp. 1421-1426. IEEE, 2020.

M. Zhang, X. Zhang, M. Li, J. Cao, and Z. Huang, "Optimization Design and Flexible Detection Method of a Surface Adaptation Wall-Climbing Robot with Multisensor Integration for Petrochemical Tanks," Sensors, vol. 20, no. 22, p. 6651, 2020.

N. S. Vlasova and N. V. Bykov, “The Problem of Adhesion Methods and Locomotion Mechanism Development for Wall-Climbing Robots,” ArXiv abs/1905.09214, 2019.

X. Li, Z. Zhixiang, and Q. Lan, "Research on a wall climbing robot based on electrostatic adhesion," In 2016 10th International Conference on Sensing Technology (ICST), pp. 1-6. IEEE, 2016.

M. M. Moniri, M. Bamdad, and M. Z. Sayyadan, "A novel design of wall climbing robot for inspection of storage steel tanks," In 2015 3rd RSI International Conference on Robotics and Mechatronics (ICROM), pp. 557-562. IEEE, 2015.

M. S. Chabukswar, R. K. Nanwatkar, and A. M. Bagde, "Design and Experimental Analysis of Magnetic Climbing Robot," International Journal of Research in Engineering, Science and Management, vol. 2, no. 12, 2019.

S. Batai, "Development of a wall-climbing robot for boiler tube inspection," 2019.

M. Patel, A. Patra, P. Chattopadhyay, A. Majumder, and S. K. Ghoshal, "Evolution of a Modular Limbless Crawling and Climbing Robot," Advanced Science, Engineering and Medicine, vol. 12, no. 11, pp. 1371-1377, 2020.

Y. Phalak, R. Deotalu, and S. Agrawal, "Mechanical Design of Omnidirectional Spherical Wall Traversing Robot," Advances in Mechanical Engineering, pp. 17-23, 2021.

Z. H. Yu, "Design and analysis of a climbing robot for window cleaning," 2019.

F. O. Cardenas, "Design of novel adaptive magnetic adhesion mechanism for climbing robots in ferric structures," PhD diss., University of Sheffield, 2016.

L. Xinrui, G. Denghui, and C. Yuan, "Design and optimization of the magnetic adsorption mechanism of a pipeline-climbing robot," Journal of Mechanical Science and Technology, vol. 35, no. 11, pp. 5161-5171, 2021.

W. Rui, "Study on Non-Destructive Testing System for Corrosion and Crack Inspection of Steel Bridge Based on Magnetic Sensor and Climbing Robot," 2016.

N. Kasashima, K. Ashida, T. Yano, A. Gofuku, and M. Shibata, "Torque control method of an electromagnetic spherical motor using torque map," IEEE/ASME Transactions on Mechatronics 21, no. 4, pp. 2050-2060, 2016.

J. Mao, K. He, J. Li, and X. Sun, "Simulation and experimental verification of permanent magnet adsorption unit for wall-climbing robot," 2016 IEEE International Conference on Information and Automation (ICIA), pp. 1189-1194, 2016.

N. V. Syrykh and V. G. Chashchukhin, "Wall-climbing robots with permanent-magnet contact devices: Design and control concept of the contact devices," Journal of Computer and Systems Sciences International, vol. 58, no. 5, pp. 818-827, 2019.

M. B. Khan, T. Chuthong, J. Homchanthanakul, and P. Manoonpong, "Electromagnetic Feet With Soft Toes for Adaptive, Versatile, and Stable Locomotion of an Inchworm-Inspired Pipe Crawling Robot," Frontiers in bioengineering and biotechnology, vol. 242, 2022.

Q. Han, F. Cao, P. Yi, and T. Li, "Motion Control of a Gecko-like Robot Based on a Central Pattern Generator," Sensors, vol. 21, no. 18, p. 6045, 2021.

Q. Hu, E. Dong, and D. Sun, "Soft Gripper Design Based on the Integration of Flat Dry Adhesive, Soft Actuator, and Microspine," IEEE Transactions on Robotics, vol. 37, no. 4, pp. 1065-1080, 2021.

N. Ebrahimi, C. Bi, D. J. Cappelleri, G. Ciuti, A. T. Conn, D. Faivre, N. Habibi et al., "Magnetic actuation methods in bio/soft robotics," Advanced Functional Materials, vol. 31, no. 11, p. 2005137, 2021.

B. N. Persson and J. Guo, "Electroadhesion for soft adhesive pads and robotics: theory and numerical results," Soft matter, vol. 15, no. 40, pp. 8032-8039, 2019.

X. Gao, Z. Li, J. Wu, X. Xin, X. Shen, X. Yuan, J. Yang, Z. Chu, and S. Dong, "A piezoelectric and electromagnetic dual mechanism multimodal linear actuator for generating macro-and nanomotion," Research, vol. 2019, 2019.

A. Vakhguelt, R. Syswoio Jo, and M. J. Bergander, "Electromagnetic acoustic boiler tubes inspection with robotic device," Vibroengineering Procedia, vol. 15, pp. 115-118, 2017.

H. Nemati, F. Alvidrez, A. Das, N. Masurkar, M. Rudraboina, H. Marvi, and E. Dehghan-Niri, "Integrating Electromagnetic Acoustic Transducers in a Modular Robotic Gripper for Inspecting Tubular Components," Materials Evaluation, vol. 79, no. 7, 2021.

R. R. Sattarov and M. A. Almaev, "Electromagnetic worm-like locomotion system for in-pipe robots: Design and vibration-driven motion analysis,” 2017 Dynamics of Systems, Mechanisms and Machines (Dynamics), pp. 1-6, 2017.

X.‐X. Wang, W.‐Q. Cao, M.‐S. Cao, and J. Yuan, "Assembling nano–microarchitecture for electromagnetic absorbers and smart devices," Advanced materials, vol. 32, no. 36, p. 2002112, 2020.

L. Seifert, J. Boulanger, D. Orth, and K. Davids, "Environmental design shapes perceptual-motor exploration, learning, and transfer in climbing," Frontiers in Psychology, vol. 6, p. 1819, 2015.

J. Guo and K-M. Lee, Flexonics for Manufacturing and Robotics: Modeling, Design and Analysis Methods, Springer, 2018.

E. Asadi, B. Li and I. -M. Chen, "Pictobot: A Cooperative Painting Robot for Interior Finishing of Industrial Developments," in IEEE Robotics & Automation Magazine, vol. 25, no. 2, pp. 82-94, June 2018, doi: 10.1109/MRA.2018.2816972.

J. Sanchez, J.-A. Corrales, B.-C. Bouzgarrou, and Y. Mezouar, "Robotic manipulation and sensing of deformable objects in domestic and industrial applications: a survey," The International Journal of Robotics Research, vol. 37, no. 7, pp. 688-716, 2018.

B. Mazzolai, A. Mondini, F. Tramacere, G. Riccomi, A. Sadeghi, G. Giordano, E. Del Dottore, M. Scaccia, M. Zampato, and S. Carminati, "Octopus‐Inspired Soft Arm with Suction Cups for Enhanced Grasping Tasks in Confined Environments," Advanced Intelligent Systems, vol. 1, no. 6, p. 1900041, 2019.