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:: International Transaction Journal of Engineering, Management, & Applied Sciences & Technologies

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ISSN 2228-9860
eISSN 1906-9642
CODEN: ITJEA8


FEATURE PEER-REVIEWED ARTICLE

Vol.13(13)(2022)

  • Comparing Boundary Conditions on Hybrid Biomaterials Using Computational Analysis

    Nur Nabila Mohd Nazali, Muhammad Hafiz Irfan Zakaria, Abdul Halim Abdullah, Muhammad Ilham Khalit (School of Mechanical Engineering, College of Engineering, Universiti Teknologi MARA (UiTM) Shah Alam, MALAYSIA),
    Norie A. Akeel (Mechanical and Mechatronic Engineering, Sohar University, OMAN),
    Nor Fazli Adull Manan (School of Mechanical Engineering, College of Engineering, Universiti Teknologi MARA (UiTM) Shah Alam, MALAYSIA).

    Discipline: Biomaterial, Biomechanics, Engineering, Mechanical Engineering, Biology.

    ➤ FullText

    doi: 10.14456/ITJEMAST.2022.257

    Keywords:Ansys; Biomechanics; Hyperelastic; Laporene; Non-linear; Neo-Hookean; Ogden; Soft tissue; Viscoelastic

    Abstract
    Scientists integrate the mechanical qualities of creating biological materials with their immunomodulatory properties to advance biomaterial technologies. In this study, three different boundary conditions are used to assess the biomechanical characteristics of leporine skin in terms of stress, strain, and stretch. By using Ansys Mechanical APDL, the improvised dog-bone dimension was created. Using the Odgen and Neo-Hookean hyperelastic models, the specimen was identified as a non-linear material. After applying the parallel forces to the x-axis, 30-degree angle, and two separate categories of Ogden parameters, the results turned to µ =0.048MPa, α =7.073 for Anterior-Posterior (AP) while µ =0.020MPa, α =9.249 for Dorsal-Ventral (DV). At the end of the simulation, the specimen elongated at F1=14N, F2=27N, F3=40N, F4=54N, F5=67N, and F6=80N. The stress-stretch curves thus show that the angle of orientation affects the biomechanical parameters and that Anterior-Posterior (AP) has a higher stretch ratio than Dorsal-Ventral (DV). Technically, the outcomes showed how varied boundary conditions affected the laporene skin once the initial stresses were applied. Future applications include animal dermatology, hyperelastic modelling, and soft tissue analysis.

    Paper ID: 13A13E

    Cite this article:

    Mohd Nazali, N.N., Zakaria, M.A.I., Abdullah, A.H., Khalit, M.I., Akeel, N.A, and Adull Manan, N.F. (2022). Comparing Boundary Conditions on Hybrid Biomaterials Using Computational Analysis. International Transaction Journal of Engineering, Management, & Applied Sciences & Technologies, 13(13), 13A13E, 1-9. http://TUENGR.COM/V13/13A13E.pdf DOI: 10.14456/ITJEMAST.2022.257

References

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Other issues:
Vol.13(12)(2022)
Vol.13(11)(2022)
Vol.13(10)(2022)
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