Design, fabrication, and evaluation of functionally graded triply periodic minimal surface structures fabricated by 3D printing

Hassan, Ibrahim M.; Enab, Tawakol A.; Fouda, Noha; Eldesouky, Ibrahim

doi:10.1007/s40430-022-03972-3

J Braz. Soc. Mech. Sci. Eng.

2023

DOI: 10.1007/s40430-022-03972-3

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Design, fabrication, and evaluation of functionally graded triply periodic minimal surface structures fabricated by 3D printing

Ibrahim M. Hassan

Tawakol A. Enab

Noha Fouda

et al.

Abstract: Cellular structures are a favorite selection for the design of lightweight components and energy absorption applications due to several advantages such as their customizable stiffness and strength. In this investigation, functionally graded (FG) triply periodic minimal surfaces, Schoen-IWP (SIWP), and Schwarz primitive (SPrim) cellular structures were fabricated by masked stereolithography (MSLA) technique using ABS-like gray resin. The sample morphology, deformation behavior, mechanical characteristics, and e… Show more

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Cited by 12 publications

References 51 publications

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CFD Analysis of the Flow in Schwarz‐D TPMS Structures for Engineering Applications

Vhora,

Thévenin,

Janiga

et al. 2024

Chemie Ingenieur Technik

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A comprehensive analysis of the flow in Schwarz‐D triply periodic minimal surfaces (TPMS) structures based on CFD simulations is presented. The pressure drops and friction factor characteristics of the structure are investigated by employing both full‐scale and representative elementary volume (REV)‐scale CFD setups. The results are validated against experimental data from the literature. An analytical model is developed using hydraulic diameter, porosity, and permeability from the CFD simulation results. The findings contribute valuable insights into the optimization and application of Schwarz‐D TPMS structures in engineering systems.

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CFD Analysis of the Flow in Schwarz‐D TPMS Structures for Engineering Applications

Vhora,

Thévenin,

Janiga

et al. 2024

Chemie Ingenieur Technik

View full text Add to dashboard Cite

show abstract

Structural simulation of Ti–Ha–CaCO3 biocomposites using finite element analysis (FEA) for biomechanical stability of hip implant

Ibrahim,

Abolarin,

Abdulrahman

et al. 2024

Int J Interact Des Manuf

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The structural integrity of new biocomposite implants is critical in ensuring the success of biomedical implants under physiological loading conditions. Studying the stress distribution, deformation, and potential failure modes under different loading scenarios is complex, expensive, and time-consuming, as it involves repeated surgery on clinical assessment. The present study aims to investigate the biomechanical stability of hip implants made of a Ti–Ha–CaCO3 biocomposite using finite element analysis. The Ti–Ha–CaCO3 biocomposite was modeled and simulated using Solidworks. The model mesh was generated to represent the implant’s geometry accurately, and normal human activities (standing and jumping) were considered the boundary conditions with the lower part of the femur fixed. The model was subjected to static loading following ISO 7206-4 with an equivalent load of 2300 N according to ASTM F2996-13 standard. The Ti–Ha–CaCO3 biocomposite demonstrated outstanding biomechanical stability under loading circumstances. The maximum von Mises stress (354.7 MPa) observed with the GSB-femur model in the implant was below the yield strength of the titanium implant, indicating that the implant can withstand applied loads without experiencing permanent deformation. However, 74.11 MPa was obtained as acceptable von Mises stress using GSB intramedullary rods for bone fixation. The most stable implant is DSB, with the lowest displacement value of 2.68 mm. Low equivalent strains were achieved for all the implants, as the highest strain (0.012) was obtained in the simulation of the stem DSB-femur model. Low-stress signals (SS) were obtained for the implant-femur models, indicating they are suitable for replacing bone for that loading. The DSB (7.19) is the most suitable among the studied stem-femur models, and GSB (0.87) remains the suitable intramedullary rod-femur model with the lowest SS.

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Experimental study of energy absorption capability in the lattice structures based on the octagonal bipyramid unit cell

Sadeghzade,

Gharehbaghi,

Toozandehjani

et al. 2023

J Braz. Soc. Mech. Sci. Eng.

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Design, fabrication, and evaluation of functionally graded triply periodic minimal surface structures fabricated by 3D printing

Cited by 12 publications

References 51 publications

CFD Analysis of the Flow in Schwarz‐D TPMS Structures for Engineering Applications

CFD Analysis of the Flow in Schwarz‐D TPMS Structures for Engineering Applications

Structural simulation of Ti–Ha–CaCO3 biocomposites using finite element analysis (FEA) for biomechanical stability of hip implant

Experimental study of energy absorption capability in the lattice structures based on the octagonal bipyramid unit cell

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