HomeRecoletos Multidisciplinary Research Journalvol. 1 no. Special Issue (2025)

Comparative Finite Element Analysis of Exoskeletons Materials for Durability in Rehabilitation

Michael Leander Roque | Elijah Gabasan | Ken Sammuel Camacho | Nilo T. Bugtai | Francisco Emmanuel Munsayac Jr. Iii

Discipline: bioengineering, medical and biomedical engineering

 

Abstract:

Background: Assistive devices, such as exoskeletons, are one of the biggest breakthroughs in the medical industry, especially regarding physical therapy and rehabilitation. However, many of these devices are expensive. Due to this, one of the many concerns consumers have about these assistive devices is their durability and longevity. As such, there is a need to ensure that these devices are durable enough to handle a significant amount of use. Methods: One way to ensure the durability of these devices is to use quality materials when creating them. This paper tackles this further, wherein three materials, namely aluminum, stainless steel, and titanium, are tested in two exoskeleton models, wherein nine tests per model were done. The models are inputted into the ANSYS software and tested using the “Static Structural” analysis system. These models’ stress, strain, and deformation values are then obtained and analyzed. Results: The results are then compared with one another and then ranked accordingly. Conclusion: The study concluded that aluminum is the best primary material for exoskeletons due to its resulting mechanical properties. It should be noted, however, that both models had different results for their best material, showing that, although aluminum would be the best overall material, the best material would still depend on the model’s size, shape, and purpose, which aligns with the hypothesis of the study.



References:

  1. Aalco. (2020, October 16). Aluminium: Specifications, properties, classifications and classes. AZoM. https://www.azom.com/article.aspx?ArticleID=2863
  2. Ding, B., Qian, J., Shen, L., & Zhang, Y. (2012, December 11-14). Finite element analysis and optimized design of exoskeleton for lower extremity rehabilitation training. 2012 IEEE International Conference on Robotics and Biomimetics (ROBIO), 1397–1402. https://doi.org/10.1109/robio.2012.6491164
  3. English, T. (2023, March 5). What is finite element analysis and how does it work? Interesting Engineering. https://interestingengineering.com/science/what-is-finite-element-analysis-and-how-does-it-work
  4. Fakhouri, F. S., Fakhouri, A. S., Ijaz, M. F., Alotaibi, M., & Almalki, A. (2023). Design of an after-fall-assistive device for elderly patients by finite element methods. Journal of Disability, 2(4), 6–12. https://doi.org/10.57197/jdr-2023-0043
  5. GrabCad. (n.d.) Exoskeletons. Community. https://grabcad.com/library?page=1&per_page=100&time=all_time&sort=popular&query=exoskeletons
  6. Hoel, R. (2021, November 17). Examining the past, present, and future of assistive technology. Accessibility. https://www.accessibility.com/blog/examining-the-past-present-and-future-of-assistive-technology
  7. Nias, K. (2019, March 1). History of the wheelchair. Science Museum Blog. https://blog.sciencemuseum.org.uk/history-of-the-wheelchair/
  8. Siviy, C., Baker, L. M., Quinlivan, B. T., Porciuncula, F., Swaminathan, K., Awad, L. N., & Walsh, C. J. (2023). Opportunities and challenges in the development of exoskeletons for locomotor assistance. Nature Biomedical Engineering, 7, 456–472. https://doi.org/10.1038/s41551-022-00984-1
  9. Stainless steel - mechanical properties. (2014, June 17). AZoM. https://www.azom.com/article.aspx?ArticleID=11049
  10. Titanium (Ti) - the different properties and applications. (2013, August 13). AZoM. https://www.azom.com/article.aspx?ArticleID=9118
  11. Umesh, K., & Vidhyapriya, R. (2021). Finite element analysis of lower limb exoskeleton during sit-to-stand transition. Computer Methods in Biomechanics and Biomedical Engineering, 24(13), 1419–1425. https://doi.org/10.1080/10255842.2021.1892658
  12. Wahab, M. A. (2014). The mechanics of adhesives in composite and metal joints : Finite element analysis with ANSYS. Destech Publications, Inc.
  13. World Health Organization. (2024). Assistive technology. https://www.who.int/news-room/fact-sheets/detail/assistive-technology
  14. Zeńczak-Praga, K., Zgorzalewicz-Stachowiak, M., & Cesar, K. (2015). “Analiza stosowanego zaopatrzenia ortopedycznego przez chorych na mózgowe porażenie dziecięce - doniesienie wstępne” [Analysis of using assistive devices by patients suffering from cerebral palsy - preliminary report]. Polski Merkuriusz Lekarski: Organ Polskiego Towarzystwa Lekarskiego, 39(233), 311–315.

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