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Polimer Esaslı Ayak Ortezlerinin Mekaniksel Davranışlarının Sonlu Elemanlar Yöntemi Kullanılarak Tahmini

Year 2022, , 525 - 530, 31.03.2022
https://doi.org/10.31590/ejosat.1083267

Abstract

3B baskı alanındaki teknolojik gelişmeler son yıllarda hızlı bir şekilde büyüyerek birçok sektörde kullanılmaya başlanmıştır. 3B baskı, tasarım süreçlerini ve tasarımlara ait prototiplerin imalat süreçlerini hızlandırmaktadır. Tasarım optimizasyonu ve karmaşık modellerin imalatında, geleneksel imalat yöntemlerinin aksine daha düşük maliyetlerle günler yerine saatler içinde yapılabilmektedir. Bunun yanısıra 3B baskı, farklı özelliklere sahip malzemelerle kişiye özel, fonksiyonel ve güvenilir biyomekanik modellerin tasarlanarak imalatına olanak tanımakta ve istenen mekanik özelliklerin önceden tahmin edilebilmesi için sonlu elemanlar yöntemiyle birleştirilebilmektedir. Yapılan çalışmada da 3B baskıda kullanılan PLA, ABS ve PETG olmak üzere 3 farklı polimerin, tasarlanan bir ayak ortezine ait mekanik özelliklerin baskı öncesinde tahmin edilebilmesine yönelik simülasyonu bu yöntemle gerçekleştirilmiştir. Yetişkin bir birey referans alınarak sınır koşulları ve uygulanması gereken eksenel kuvvetler belirlenerek, 3 farklı polimer için toplam deformasyon, eşdeğer (Von-Mises) gerilimi ve güvenlik faktörü ANSYS programı ile analiz edilerek simüle edilmiştir. Simülasyon sonuçlarına göre, karşılaştırmalı olarak incelenen polimerler arasında eksenel olarak uygulanan kuvvetleri en iyi sönümlemeyi gerçekleştiren polimerin, ABS olduğu tespit edilmiştir. Diğer iki polimer malzeme arasında ise sönümlemeyi en iyi sağlayan polimer sırasıyla PETG, PLA şeklinde olduğu sonucuna varılmıştır.

References

  • A., Bashir, D., Dinkel, I., Pipinos, and S., Myers, “Implementation of an ankle foot orthosis to ımprove mobility in peripheral artery disease,” Archives of Physical Medicine and Rehabilitation, 102 (10), e24, 2021.
  • S., Shahar, M. T. H., Sultan, S. H., Lee, M., Jawaid, A. U. M., Shah, S. N. A., Safri, and P. N., Sivasankaran, “A review on the orthotics and prosthetics and the potential of kenaf composites as alternative materials for ankle-foot orthosis,” Journal of the mechanical behavior of biomedical materials, 99, 169-185, 2019.
  • A., Esmanhotto and G., Esmanhotto, “A simple idea for reducing the cost and weight of plaster-cast orthoses,” Revista Brasileira de Ortopedia, 48, 17-21, 2013.
  • N., Tırpan, “Uzun yürüme ortezlerinde ölçü alma, pozitif model oluşturma, biyomekaniksel prensipler,” 10. Uluslararası Protez-Ortez Kongresi, Hacettepe Üniversitesi Kültür Merkezi, ANKARA, 54-60, 2018.
  • N., Sabyrov, Z., Sotsial, A., Abilgaziyev, D., Adair and M. H., Ali, “Design of a flexible neck orthosis on Fused Deposition Modeling printer for rehabilitation on regular usage,” Procedia Computer Science, 179, 63-71, 2021.
  • H., Choi, K. M., Peters, M. B., MacConnell, K. K., Ly, E. S., Eckert and K. M., Steele, “Impact of ankle foot orthosis stiffness on Achilles’ tendon and gastrocnemius function during unimpaired gait” Journal of biomechanics, 64, 145-152, 2017.
  • S., Petersmann, M., Spoerk, W., Van De Steene, M., Üçal, J., Wiener, G., Pinter and F., Arbeiter, “Mechanical properties of polymeric implant materials produced by extrusion-based additive manufacturing,” Journal of the Mechanical Behavior of Biomedical Materials, 104, 103611, 2020.
  • D., Totah, I., Kovalenko, M., Saez, and K., Barton, “Manufacturing choices for ankle-foot Orthoses: a multi-objective optimization,” Procedia CIRP, 65, 145-150, 2017.
  • A., Dal Maso and F., Cosmi, “3D-printed ankle-foot orthosis: a design method,” Materials Today: Proceedings, 12, 252-261, 2019.
  • L. A., Melnyk and M. O., Oyewumi, Integration of 3D printing technology in pharmaceutical compounding: Progress, prospects, and challenges,” Annals of 3D Printed Medicine, 4, 100035, 2021.
  • A., Kantaros, O., Diegel, D., Piromalis, G., Tsaramirsis, A. O., Khadidos, A. O., Khadidos and S., Jan, “3D printing: Making an innovative technology widely accessible through makerspaces and outsourced services,” Materials Today: Proceedings, 49, 2712-2723, 2022.
  • S., Chunhua and S., Guangqing, “Application and Development of 3D Printing in Medical Field. Modern Mechanical Engineering, 10 (03), 25, 2020.
  • B., Barroqueiro, A., Andrade-Campos and R. A., Valente, “Integrated Methodology for Designing Structures coming from Additive Layer Manufacturing,” Procedia Manufacturing, 47, 425-428, 2020.
  • Ü. G., Başçı ve R., Yamanoğlu, “Yeni nesil üretim teknolojisi: FDM ile eklemeli imalat,” International Journal of 3D Printing Technologies and Digital Industry, 5 (2), 339-352, 2021.
  • M., Walbran, K., Turner and A. J., McDaid, “Customized 3D printed ankle-foot orthosis with adaptable carbon fibre composite spring joint,” Cogent Engineering, 3 (1), 1227022, 2016.
  • H. K., Banga, P., Kalra, R. M., Belokar and R., Kumar, “Effect of 3D-printed ankle foot orthosis during walking of foot deformities patients,” In Recent Advances in Mechanical Engineering, Springer, Singapore, 275-288, 2020.
  • W., Jia, J., Sun, T., Guan and Z., Xing, “Thermal-mechanical coupling analysis of 3D printing nozzle based on Ansys,” In Second IYSF Academic Symposium on Artificial Intelligence and Computer Engineering, 12079, 272-277, 2021.
  • Ü., Çevik and M., Kam, “A review study on mechanical properties of obtained products by FDM method and metal/polymer composite filament production,” Journal of Nanomaterials, 2020.

Prediction of Mechanical Behavior of Polymer-Based Foot Orthoses Using Finite Element Method

Year 2022, , 525 - 530, 31.03.2022
https://doi.org/10.31590/ejosat.1083267

Abstract

Technological developments in the field of 3D printing have grown rapidly in recent years and have been used in many sectors. 3D printing speeds up the design processes and the manufacturing processes of prototypes of designs. In design optimization and manufacturing of complex models, it can be done in hours instead of days, with lower costs, unlike traditional manufacturing methods. In addition, 3D printing allows the design and manufacture of personalized, functional and reliable biomechanical models with materials with different properties, and can be combined with the finite element method to predict the desired mechanical properties. In the study, 3 different polymers, namely PLA, ABS and PETG used in 3D printing, were simulated to predict the mechanical properties of a designed foot orthosis before printing, using this method. By taking an adult individual as a reference, boundary conditions and axial forces to be applied were determined, and total deformation, equivalent (Von-Mises) stress and safety factor for 3 different polymers were analyzed and simulated with the ANSYS program. According to the simulation results, it has been determined that ABS is the polymer that performs the best damping of the axially applied forces among the comparatively examined polymers. Among the other two polymer materials, it was concluded that the polymer that provides the best damping is in the form of PETG and PLA, respectively.

References

  • A., Bashir, D., Dinkel, I., Pipinos, and S., Myers, “Implementation of an ankle foot orthosis to ımprove mobility in peripheral artery disease,” Archives of Physical Medicine and Rehabilitation, 102 (10), e24, 2021.
  • S., Shahar, M. T. H., Sultan, S. H., Lee, M., Jawaid, A. U. M., Shah, S. N. A., Safri, and P. N., Sivasankaran, “A review on the orthotics and prosthetics and the potential of kenaf composites as alternative materials for ankle-foot orthosis,” Journal of the mechanical behavior of biomedical materials, 99, 169-185, 2019.
  • A., Esmanhotto and G., Esmanhotto, “A simple idea for reducing the cost and weight of plaster-cast orthoses,” Revista Brasileira de Ortopedia, 48, 17-21, 2013.
  • N., Tırpan, “Uzun yürüme ortezlerinde ölçü alma, pozitif model oluşturma, biyomekaniksel prensipler,” 10. Uluslararası Protez-Ortez Kongresi, Hacettepe Üniversitesi Kültür Merkezi, ANKARA, 54-60, 2018.
  • N., Sabyrov, Z., Sotsial, A., Abilgaziyev, D., Adair and M. H., Ali, “Design of a flexible neck orthosis on Fused Deposition Modeling printer for rehabilitation on regular usage,” Procedia Computer Science, 179, 63-71, 2021.
  • H., Choi, K. M., Peters, M. B., MacConnell, K. K., Ly, E. S., Eckert and K. M., Steele, “Impact of ankle foot orthosis stiffness on Achilles’ tendon and gastrocnemius function during unimpaired gait” Journal of biomechanics, 64, 145-152, 2017.
  • S., Petersmann, M., Spoerk, W., Van De Steene, M., Üçal, J., Wiener, G., Pinter and F., Arbeiter, “Mechanical properties of polymeric implant materials produced by extrusion-based additive manufacturing,” Journal of the Mechanical Behavior of Biomedical Materials, 104, 103611, 2020.
  • D., Totah, I., Kovalenko, M., Saez, and K., Barton, “Manufacturing choices for ankle-foot Orthoses: a multi-objective optimization,” Procedia CIRP, 65, 145-150, 2017.
  • A., Dal Maso and F., Cosmi, “3D-printed ankle-foot orthosis: a design method,” Materials Today: Proceedings, 12, 252-261, 2019.
  • L. A., Melnyk and M. O., Oyewumi, Integration of 3D printing technology in pharmaceutical compounding: Progress, prospects, and challenges,” Annals of 3D Printed Medicine, 4, 100035, 2021.
  • A., Kantaros, O., Diegel, D., Piromalis, G., Tsaramirsis, A. O., Khadidos, A. O., Khadidos and S., Jan, “3D printing: Making an innovative technology widely accessible through makerspaces and outsourced services,” Materials Today: Proceedings, 49, 2712-2723, 2022.
  • S., Chunhua and S., Guangqing, “Application and Development of 3D Printing in Medical Field. Modern Mechanical Engineering, 10 (03), 25, 2020.
  • B., Barroqueiro, A., Andrade-Campos and R. A., Valente, “Integrated Methodology for Designing Structures coming from Additive Layer Manufacturing,” Procedia Manufacturing, 47, 425-428, 2020.
  • Ü. G., Başçı ve R., Yamanoğlu, “Yeni nesil üretim teknolojisi: FDM ile eklemeli imalat,” International Journal of 3D Printing Technologies and Digital Industry, 5 (2), 339-352, 2021.
  • M., Walbran, K., Turner and A. J., McDaid, “Customized 3D printed ankle-foot orthosis with adaptable carbon fibre composite spring joint,” Cogent Engineering, 3 (1), 1227022, 2016.
  • H. K., Banga, P., Kalra, R. M., Belokar and R., Kumar, “Effect of 3D-printed ankle foot orthosis during walking of foot deformities patients,” In Recent Advances in Mechanical Engineering, Springer, Singapore, 275-288, 2020.
  • W., Jia, J., Sun, T., Guan and Z., Xing, “Thermal-mechanical coupling analysis of 3D printing nozzle based on Ansys,” In Second IYSF Academic Symposium on Artificial Intelligence and Computer Engineering, 12079, 272-277, 2021.
  • Ü., Çevik and M., Kam, “A review study on mechanical properties of obtained products by FDM method and metal/polymer composite filament production,” Journal of Nanomaterials, 2020.
There are 18 citations in total.

Details

Primary Language Turkish
Subjects Engineering
Journal Section Articles
Authors

Mustafa Güneş 0000-0002-0266-6370

Abdulhamit Sevgi 0000-0003-3567-848X

Cebrail Ölmez 0000-0001-9111-0325

Zehra Sever 0000-0002-2928-1323

Publication Date March 31, 2022
Published in Issue Year 2022

Cite

APA Güneş, M., Sevgi, A., Ölmez, C., Sever, Z. (2022). Polimer Esaslı Ayak Ortezlerinin Mekaniksel Davranışlarının Sonlu Elemanlar Yöntemi Kullanılarak Tahmini. Avrupa Bilim Ve Teknoloji Dergisi(34), 525-530. https://doi.org/10.31590/ejosat.1083267