Version 1
: Received: 13 February 2024 / Approved: 13 February 2024 / Online: 13 February 2024 (12:32:40 CET)
How to cite:
Lenggana, B. W.; Fardan, M. F.; Ubaidillah, U.; Choi, S.-B.; Susilo, D. D.; Aljabri, A.; Khan, S. Z. Design of a Transtibial Prosthetic Pylon Using Auxetic Metamaterials: Simulation and Experimental Validation. Preprints2024, 2024020745. https://doi.org/10.20944/preprints202402.0745.v1
Lenggana, B. W.; Fardan, M. F.; Ubaidillah, U.; Choi, S.-B.; Susilo, D. D.; Aljabri, A.; Khan, S. Z. Design of a Transtibial Prosthetic Pylon Using Auxetic Metamaterials: Simulation and Experimental Validation. Preprints 2024, 2024020745. https://doi.org/10.20944/preprints202402.0745.v1
Lenggana, B. W.; Fardan, M. F.; Ubaidillah, U.; Choi, S.-B.; Susilo, D. D.; Aljabri, A.; Khan, S. Z. Design of a Transtibial Prosthetic Pylon Using Auxetic Metamaterials: Simulation and Experimental Validation. Preprints2024, 2024020745. https://doi.org/10.20944/preprints202402.0745.v1
APA Style
Lenggana, B. W., Fardan, M. F., Ubaidillah, U., Choi, S. B., Susilo, D. D., Aljabri, A., & Khan, S. Z. (2024). Design of a Transtibial Prosthetic Pylon Using Auxetic Metamaterials: Simulation and Experimental Validation. Preprints. https://doi.org/10.20944/preprints202402.0745.v1
Chicago/Turabian Style
Lenggana, B. W., Abdurrahman Aljabri and Sohaib Zia Khan. 2024 "Design of a Transtibial Prosthetic Pylon Using Auxetic Metamaterials: Simulation and Experimental Validation" Preprints. https://doi.org/10.20944/preprints202402.0745.v1
Abstract
Prosthetic device is designed to function as a replacement for a missing limb and typically consists of suspension, liner, socket, pylon and foot components. The objectives of this research are to design a pylon component of a transtibial prosthetics by implementing auxetic metamaterial and to also validate performance of the designed pylon under quasi-static and dynamic conditions. The design and analysis processes are conducted using the finite element analysis and its effectiveness is validated by experimental testing of the prototype pylon sample. In the design process, the pylon structure is formulated by rearranging 2D re-entrant hexagon model into 3D model. It is identified from the design evaluation that the pylon exhibits the stiffness of the value of 79.24, 2371.6, and 13344 kN/m for the ligament thickness variation of 0.3 mm, 1 mm, and 2 mm, respectively. This directly indicates a capability of the stiffness tuning of the pylon by changing the ligament thickness. It is evaluated that the pylon with the ligament thickness of 0.3 mm causes the deformation of 0.53 cm during a single period of gait cycle, while the ligament thickness of the 1 mm causes the deformation of 0.4 cm. The deformation physically indicates the energy absorption of the pylon structure and hence the thinner ligament, the higher energy absorption provides. It is also found from the deformation transition of the primary and secondary bends, the negative Poisson’s ratio is occurred in 3D model transformed from 2D re-entrant hexagon.
Public Health and Healthcare, Public Health and Health Services
Copyright:
This is an open access article distributed under the Creative Commons Attribution License which permits unrestricted use, distribution, and reproduction in any medium, provided the original work is properly cited.