A BIOMECHATRONIC APPLICATION ON PROSTHETICS FOR UNDERGRADUATE ENGINEERING STUDENTS

Abstract

Human hand prosthetics imply a great challenge to researchers to help regaining the lost motor functions for amputated people. A relatively high amount of labor and budget are required to reach the ordinary prosthetics for amputees. Improvement of assistive technologies has provided to design and manufacture more functional hand prosthetics. Novel tools employed in assistive technology including 3-dimensional printers and user-friendly electronics complementary devices have made a great contribution to prosthetics area with fast and cost effective solutions. Although a significant development of technical facilities has been occurred, prosthetic hands with high functionality could not gain wide currency since the manufacturing and design processes require more educated engineers and biomechanicsts. Introducing the design and manufacturing steps of prosthetics for educational purposes in engineering and life sciences could be very effective in order to ease accessing the more functional prosthetics and to increase the prevalence of use. Education of new methodology and devices provides crucial opportunities to enhance the ability and usage of new generation prosthetics. In this study, a prosthetic hand design, control and manufacturing implementations were carried out by undergraduate students in the context of dissertation study. The custom based human hand prosthetics was manufactured according to following steps. Three-dimensional CAD models of prosthetic hand components including palm and fingers were designed in a solid body modeling software. Then, the model parts were printed using 3-D printers and they were assembled. The forces were transmitted to the fingers via elastic strings which were controlled via Arduino controlled servo motor. The programmable motions of servo motors enable to direct control of fingers. Specific education on design, manufacturing and control of human prosthetics has the potential to provide a high impact on obtaining more functional and cost effective prosthetics which enables more people to regain their lost motor patterns.

Keywords

• Assistive technologies,human hand prosthetics,science and engineering education

References

1. Kyberd, P. J. & Evans, M. & Winkel, S. (1998). An lntelligent Anthropomorphic Hand with Automatic Grasp. Robotica, Vol.16, pp 531-536. Carrozza, M. C. & Cappiello, G. & Micera, S. & Edin, B. B. & Beccai, L. & Cipriani, C. (2006). Design of a cybernetic hand for perception and action. Biol. Cybern., vol. 95, no. 6, pp. 629–644. Touch Bionics Inc., “www.touchbionics.com,” 2009. DEKA Research and Development Corp., www.dekaresearch.com, 2008. Zecca, M. & Micera, S. & Carrozza, M. C. & Dario, P. (2002). Control of multifunctional prosthetic hands by processing the electromyographic signal.Critical Reviews in Biomedical Engineering, vol. 30, no. 4–6,pp. 459–485. Peltola, S.M. & Melchels, F. P. W. & Grijpma, D. W. , & Kellomäki M. (2008). A review of rapid prototyping techniques for tissue engineering purposes. Ann Med 40:268–280. Yeong, W. Y. & Chua, C. K. & Leong, K. F. & Chandrasekaran, M. (2004). Rapid prototyping in tissue engineering: challenges and potential. Trends Biotechnol. 22, 643–652. Lantada, A. D. & Morgado, P. L. (2012). Rapid prototyping for biomedical engineering: current capabilities and challenges. Annu. Rev. bioeng. 14, 73–96. Subburaj, K. & Nair, C. & Rajesh, S. & Meshram, S. & Ravi, B. (2007). Rapid development of auricular prosthesis using CAD and rapid proto- typing technologies. Int J Oral Maxillofac Surg 36:938–943. Lee, M. & Chang, C. & Ku, Y. (2008). New layer-based imaging and rapid prototyping techniques for computer-aided design and manufacture of custom dental restoration. J Med Eng Technol 32:83–90. http://enablingthefuture.org/