Design and Validation of Payload: Weight for a Bioinspired Inch Worm Wall Climbing Robot (IWWCR) Using Coppeliasim

Authors

  • Rakesh Rajendran Hindustan Institute of Technology and Science, Centre for Automation and Robotics, Department of Mechatronics Engineering, Padur, Chennai, Tamil Nadu, India Author https://orcid.org/0000-0002-6879-8835
  • Joshuva Arockia Dhanraj Hindustan Institute of Technology and Science, Centre for Automation and Robotics, Department of Mechatronics Engineering, Padur, Chennai, Tamil Nadu, India Author https://orcid.org/0000-0001-5048-7775
  • Shivakumar.N Periyar Maniammai Institute of Science and Technology, Centre for Excellence in Training and Research in Automation technology, Thanjavur, Tamil Nadu, India Author https://orcid.org/0000-0002-7831-6203
  • Rajanandhini.C Periyar Maniammai Institute of Science and Technology, Centre for Excellence in Training and Research in Automation technology, Thanjavur, Tamil Nadu, India Author https://orcid.org/0009-0004-1865-2127
  • Saravana Kumar Uthirapathy Periyar Maniammai Institute of Science and Technology, Centre for Excellence in Training and Research in Automation technology, Thanjavur, Tamil Nadu, India Author https://orcid.org/0009-0009-2605-924X
  • Hamsadhwani Vivekanandan Periyar Maniammai Institute of Science and Technology, Centre for Excellence in Training and Research in Automation technology, Thanjavur, Tamil Nadu, India Author https://orcid.org/0000-0001-9432-3107

DOI:

https://doi.org/10.56294/sctconf2024660

Keywords:

Inch Worm Wall Climbing Robot (IWWCR), Coppeliasim, FEMM, CAA, Payload(p), Weight(w)

Abstract

 

In this growing era technology robots are replacing the humans by performing many risky operations enhancing the safety factor of human life. Particularly while considering performing task at high rise building or any high-altitude jobs, the need of wall climbing robot emerges. There are various types of wall climbing robot classified based on its adhesive mechanism and locomotive methods. Out of the various available method, Bioinspired type Robot has its own unique feature specifically when we talk about softbot. Bio inspired robots mimics the locomotion or any other specific feature of living creatures

In this paper, an novel approach is introduced for design and development of a Bio inspired Wall Climbing Robot (WCR) using a simulation software named Coppelialsim. An inch worm wall climbing robot is proposed mimicking the locomotion of inch worm is proposed as novel design. The design of the proposed WCR is validated with respect to payload(p): weight (w) value using the static and dynamic analysis both in simulation environment using coppeliasim software and real time experimental testing after fabrication. The flow of electromagnetic flux is further justified with the software called Finite Element Magnetic Method (FEMM) and the structural design of the proposed design is validated with respect to the Computer Aided Analysis (CAA) software. Thus, the proposed IWWCR possess the high p: w value when compared to all other existing bioinspired Wall climbing Robot

References

1. Lam TL, Xu Y. A flexible tree climbing robot: Treebot-design and implementation. In IEEE International Conference on Robotics and Automation 2011 May 9, pp. 5849,5854.

2. Jiang Q, Xu F. Grasping claws of bionic climbing robot for rough wall surface: Modeling and analysis. Applied Sciences. 2017 Dec 22; 8,1): 14. https://doi.org/10,3390/app8010014

3. Rajendran R, Dhanraj JA. A comparative survey on weight & payload of wall climbing robot (WCR) using magnetic adhesive, suction adhesive and fusion type adhesive. Materials Today: Proceedings. 2023 Apr 12.

4. Bartsch S, Birnschein T, Römmermann M, Hilljegerdes J, Kühn D, Kirchner F. Development of the six‐legged walking and climbing robot Space Climber. Journal of Field Robotics. 2012 May; 29,3): 506,532.

5. Xu F, Wang X, Jiang G. Design and analysis of a wall-climbing robot based on a mechanism utilizing hook-like claws. International Journal of advanced robotic systems. 2012 Dec 24; 9,6): 261. https://doi.org/10,5772/53895

6. Xu F, Shen J, Hu J, Jiang G. A rough concrete wall-climbing robot based on grasping claws: Mechanical design, analysis and laboratory experiments. International Journal of Advanced Robotic Systems. 2016 Oct 7; 13,5): 1729881416666777. https://doi.org/10,1177/1729881416666777

7. Ji A, Zhao Z, Manoonpong P, Wang W, Chen G, Dai Z. A bio-inspired climbing robot with flexible pads and claws. Journal of Bionic Engineering. 2018 Mar; 15: 368,378.

8. Alarcon JCM. Information security: A comprehensive approach to risk management in the digital world. SCT Proceedings in Interdisciplinary Insights and Innovations 2023,1:84,84. https://doi.org/10,56294/piii202384.

9. Auza-Santiváñez JC, Díaz JAC, Cruz OAV, Robles-Nina SM, Escalante CS, Huanca BA. Bibliometric Analysis of the Worldwide Scholarly Output on Artificial Intelligence in Scopus. Gamification and Augmented Reality 2023,1:11,11. https://doi.org/10,56294/gr202311.

10. Auza-Santivañez JC, Lopez-Quispe AG, Carías A, Huanca BA, Remón AS, Condo-Gutierrez AR, et al. Improvements in functionality and quality of life after aquatic therapy in stroke survivors. AG Salud 2023,1:15,15. https://doi.org/10,62486/agsalud202315.

11. Barrios CJC, Hereñú MP, Francisco SM. Augmented reality for surgical skills training, update on the topic. Gamification and Augmented Reality 2023,1:8,8. https://doi.org/10,56294/gr20238.

12. Batista-Mariño Y, Gutiérrez-Cristo HG, Díaz-Vidal M, Peña-Marrero Y, Mulet-Labrada S, Díaz LE-R. Behavior of stomatological emergencies of dental origin. Mario Pozo Ochoa Stomatology Clinic. 2022,2023. AG Odontologia 2023,1:6,6. https://doi.org/10,62486/agodonto20236.

13. Bian S, Xu F, Wei Y, Kong D. a novel type of wall-climbing robot with a gear transmission system arm and adhere mechanism inspired by Cicada and Gecko. Applied Sciences. 2021 Apr 30; 11,9): 4137. https://doi.org/10,3390/app11094137

14. Birkmeyer P, Gillies AG, Fearing RS. Dynamic climbing of near-vertical smooth surfaces. In2012 IEEE/RSJ International Conference on Intelligent Robots and Systems 2012 Oct 7, pp. 286,292.

15. Bretl T, Rock S, Latombe JC, Kennedy B, Aghazarian H. Free-climbing with a multi-use robot. In Experimental Robotics IX: The 9th International Symposium on Experimental Robotics 2006, pp. 449,458.

16. Cano CAG, Castillo VS. Systematic review on Augmented Reality in health education. Gamification and Augmented Reality 2023,1:28,28. https://doi.org/10,56294/gr202328.

17. Cardenas DC. Health and Safety at Work: Importance of the Ergonomic Workplace. SCT Proceedings in Interdisciplinary Insights and Innovations 2023,1:83,83. https://doi.org/10,56294/piii202383.

18. Carlo M, Metin S. A biomimetic climbing robot based on the gecko. Journal of Bionic Engineering. 2006 Sep 1; 3,3): 115,25.

19. Castillo-González W. Kinesthetic treatment on stiffness, quality of life and functional independence in patients with rheumatoid arthritis. AG Salud 2023,1:20,20. https://doi.org/10,62486/agsalud202320.

20. Chung WK, Li J, Chen Y, Xu Y. A novel design of movable gripper for non-enclosable truss climbing. In2011 IEEE International Conference on Robotics and Automation 2011 May 9, pp. 519,525.

21. Cuervo MED. Exclusive breastfeeding. Factors that influence its abandonment. AG Multidisciplinar 2023,1:6,6. https://doi.org/10,62486/agmu20236.

22. Daltorio KA, Witushynsky TC, Wile GD, Palmer LR, Ab Malek A, Ahmad MR, Southard L, Gorb SN, Ritzmann RE, Quinn RD. A body joint improves vertical to horizontal transitions of a wall-climbing robot. In IEEE International Conference on Robotics and Automation 2008 May 19, 3046,3051.

23. Diaz DPM. Staff turnover in companies. AG Managment 2023,1:16,16. https://doi.org/10,62486/agma202316.

24. Dionicio RJA, Serna YPO, Claudio BAM, Ruiz JAZ. Sales processes of the consultants of a company in the bakery industry. Southern Perspective / Perspectiva Austral 2023,1:2,2. https://doi.org/10,56294/pa20232.

25. Figueredo-Rigores A, Blanco-Romero L, Llevat-Romero D. Systemic view of periodontal diseases. AG Odontologia 2023,1:14,14. https://doi.org/10,62486/agodonto202314.

26. Frank M, Ricci E. Education for sustainability: Transforming school curricula. Southern Perspective / Perspectiva Austral 2023,1:3,3. https://doi.org/10,56294/pa20233.

27. Funatsu M, Kawasaki Y, Kawasaki S, Kikuchi K. Development of cm-scale wall climbing hexapod robot with claws. In Proceedings of the 3rd International Conference on Design Engineering and Science—ICDES, Pilsen, Czech Republic 2014 Aug 31, pp. 101,106.

28. Gómez LVB, Guevara DAN. Analysis of the difference of the legally relevant facts of the indicator facts. AG Multidisciplinar 2023,1:17,17. https://doi.org/10,62486/agmu202317.

29. Gonzalez-Argote D, Gonzalez-Argote J, Machuca-Contreras F. Blockchain in the health sector: a systematic literature review of success cases. Gamification and Augmented Reality 2023,1:6,6. https://doi.org/10,56294/gr20236.

30. Gonzalez-Argote J, Castillo-González W. Productivity and Impact of the Scientific Production on Human-Computer Interaction in Scopus from 2018 to 2022. AG Multidisciplinar 2023,1:10,10. https://doi.org/10,62486/agmu202310.

31. Herera LMZ. Consequences of global warming. SCT Proceedings in Interdisciplinary Insights and Innovations 2023,1:74,74. https://doi.org/10,56294/piii202374.

32. Kotay KD, Rus DL. Navigating 3d steel web structures with an inchworm robot. In Proceedings of IEEE/RSJ International Conference on Intelligent Robots and Systems. IROS'96,1996 Nov 8, Vol. 1, pp. 368,375.

33. Ledesma-Céspedes N, Leyva-Samue L, Barrios-Ledesma L. Use of radiographs in endodontic treatments in pregnant women. AG Odontologia 2023,1:3,3. https://doi.org/10,62486/agodonto20233.

34. Li H, Sun X, Chen Z, Zhang L, Wang H, Wu X. Design of a wheeled wall climbing robot based on the performance of bio-inspired dry adhesive material. Robotica. 2022 Mar; 40,3): 611,624.

35. Liu J, Tong Z, Fu J, Wang D, Su Q, Zou J. A gecko inspired fluid driven climbing robot. In 2011 IEEE International Conference on Robotics and Automation 2011 May 9, pp. 783,788.

36. Liu J, Xu L, Chen S, Xu H, Cheng G, Xu J. Development of a bio-inspired wall-climbing robot composed of spine wheels, adhesive belts and eddy suction cup. Robotica. 2021 Jan; 39,1): 3,22.

37. Lopez ACA. Contributions of John Calvin to education. A systematic review. AG Multidisciplinar 2023,1:11,11. https://doi.org/10,62486/agmu202311.

38. Marcelo KVG, Claudio BAM, Ruiz JAZ. Impact of Work Motivation on service advisors of a public institution in North Lima. Southern Perspective / Perspectiva Austral 2023,1:11,11. https://doi.org/10,56294/pa202311.

39. Millán YA, Montano-Silva RM, Ruiz-Salazar R. Epidemiology of oral cancer. AG Odontologia 2023,1:17,17. https://doi.org/10,62486/agodonto202317.

40. Mosquera ASB, Román-Mireles A, Rodríguez-Álvarez AM, Mora CC, Esmeraldas E del CO, Barrios BSV, et al. Science as a bridge to scientific knowledge: literature review. AG Multidisciplinar 2023,1:20,20. https://doi.org/10,62486/agmu202320.

41. Ojeda EKE. Emotional Salary. SCT Proceedings in Interdisciplinary Insights and Innovations 2023,1:73,73. https://doi.org/10,56294/piii202373.

42. Olguín-Martínez CM, Rivera RIB, Perez RLR, Guzmán JRV, Romero-Carazas R, Suárez NR, et al. Bibliometric analysis of occupational health in civil construction works. AG Salud 2023,1:10,10. https://doi.org/10,62486/agsalud202310.

43. Osorio CA, Londoño CÁ. El dictamen pericial en la jurisdicción contenciosa administrativa de conformidad con la ley 2080 de 2021. Southern Perspective / Perspectiva Austral 2024,2:22,22. https://doi.org/10,56294/pa202422.

44. Polo LFB. Effects of stress on employees. AG Salud 2023,1:31,31. https://doi.org/10,62486/agsalud202331.

45. Pupo-Martínez Y, Dalmau-Ramírez E, Meriño-Collazo L, Céspedes-Proenza I, Cruz-Sánchez A, Blanco-Romero L. Occlusal changes in primary dentition after treatment of dental interferences. AG Odontologia 2023,1:10,10. https://doi.org/10,62486/agodonto202310.

46. Rajendran R, Dhanraj JA. A Fault Tree Analysis (FTA) Focusing the Design Attributes and Decision Tree Analysis (DTA) Comparing Payload: Weight for Various Adhesive Mechanism of Wall Climbing Robot. International Journal of Intelligent Systems and Applications in Engineering. 2023 Apr 16; 11,5s): 606,617.

47. Rajendran R, Dhanraj JA. Free Body Diagram Analysis and Finite Element Method Analysis of Wall Climbing Robot using the Hybrid Adhesive Mechanism. 2023; 10,5): 213,226.

48. Rajendran R, Dhanraj JA. Measurement of payload under variable adhesive force through coppeliasim and validating the design of a wall climbing robot. Measurement: Sensors. 2023 Oct 1; 29: 100872. https://doi.org/10,1016/j.measen.2023,100872

49. Ramos YAV. Little Attention of Companies in the Commercial Sector Regarding the Implementation of Safety and Health at Work in Colombia During the Year 2015 to 2020. SCT Proceedings in Interdisciplinary Insights and Innovations 2023,1:79,79. https://doi.org/10,56294/piii202379.

50. Roa BAV, Ortiz MAC, Cano CAG. Analysis of the simple tax regime in Colombia, case of night traders in the city of Florencia, Caquetá. AG Managment 2023,1:14,14. https://doi.org/10,62486/agma202314.

51. Rodríguez LPM, Sánchez PAS. Social appropriation of knowledge applying the knowledge management methodology. Case study: San Miguel de Sema, Boyacá. AG Managment 2023,1:13,13. https://doi.org/10,62486/agma202313.

52. Romero-Carazas R. Prompt lawyer: a challenge in the face of the integration of artificial intelligence and law. Gamification and Augmented Reality 2023,1:7,7. https://doi.org/10,56294/gr20237.

53. Saavedra MOR. Revaluation of Property, Plant and Equipment under the criteria of IAS 16: Property, Plant and Equipment. AG Managment 2023,1:11,11. https://doi.org/10,62486/agma202311.

54. Shen W, Gu J, Shen Y. Permanent magnetic system design for the wall-climbing robot. In IEEE International Conference Mechatronics and Automation, 2005,2005 Jul 29, Vol. 4, pp. 2078,2083.

55. Sintov A, Avramovich T, Shapiro A. Design and motion planning of an autonomous climbing robot with claws. Robotics and Autonomous Systems. 2011 Nov 1; 59,11): 1008,1019.

56. Solano AVC, Arboleda LDC, García CCC, Dominguez CDC. Benefits of artificial intelligence in companies. AG Managment 2023,1:17,17. https://doi.org/10,62486/agma202317.

57. Spenko MJ, Haynes GC, Saunders JA, Cutkosky MR, Rizzi AA, Full RJ, Koditschek DE. Biologically inspired climbing with a hexapedal robot. Journal of field robotics. 2008 Apr; 25,4‐5): 223,242.

58. Sun J, Bauman L, Yu L, Zhao B. Gecko-and-inchworm-inspired untethered soft robot for climbing on walls and ceilings. Cell Reports Physical Science. 2023 Feb 15; 4,2).

59. Unver O, Murphy M, Sitti M. Geckobot and waalbot: Small-scale wall climbing robots. InInfotech@ Aerospace 2005, p. 6940.

60. Valdés IYM, Valdés LC, Fuentes SS. Professional development, professionalization and successful professional performance of the Bachelor of Optometry and Opticianry. AG Salud 2023,1:7,7. https://doi.org/10,62486/agsalud20237.

61. Velásquez AA, Gómez JAY, Claudio BAM, Ruiz JAZ. Soft skills and the labor market insertion of students in the last cycles of administration at a university in northern Lima. Southern Perspective / Perspectiva Austral 2024,2:21,21. https://doi.org/10,56294/pa202421.

62. Wile GD, Daltorio KA, Diller ED, Palmer LR, Gorb SN, Ritzmann RE, Quinn RD. Screenbot: Walking inverted using distributed inward gripping. In 2008 IEEE/RSJ International Conference on Intelligent Robots and Systems 2008 Sep 22, pp. 1513,1518.

63. Zhang H, Wang W, Zhang J. A novel passive adhesion principle and application for an inspired climbing caterpillar robot. In 2009 IEEE International Conference on Mechatronics 2009 Apr 14, pp. 1,6.

64. Zhang HX, Gonzalez-Gomez J, Chen SY, Wang W, Liu R, Li D, Zhang JW. A novel modular climbing caterpillar using low-frequency vibrating passive suckers. In2007 IEEE/ASME international conference on advanced intelligent mechatronics 2007 Sep 4, pp. 1,6

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Published

2024-03-30

How to Cite

1.
Rajendran R, Arockia DJ, Shivakumar N, Rajanandhini C, Kumar US, Vivekanandan H. Design and Validation of Payload: Weight for a Bioinspired Inch Worm Wall Climbing Robot (IWWCR) Using Coppeliasim. Salud, Ciencia y Tecnología - Serie de Conferencias [Internet]. 2024 Mar. 30 [cited 2024 Dec. 2];3:660. Available from: https://conferencias.ageditor.ar/index.php/sctconf/article/view/1059