4D printing of porous PLA-TPU structures: effect of applied deformation, loading mode and infill pattern on the shape memory performance

Rahmatabadi, Davood; Soltanmohammadi, Kianoosh; Aberoumand, Mohammad; Soleyman, Elyas; Ghasemi, Ismaeil; Baniassadi, Majid; Abrinia, Karen; Bodaghi, Mahdi; Baghani, Mostafa

doi:10.1088/1402-4896/ad1957

Cited by 29 publications

(12 citation statements)

References 47 publications

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“…Therefore, the amount of programming stress for the vertical pattern is 1.23 times more than the horizontal. In the case that the grids and rasters are in the direction of applying force, they show more resistance than when the force is applied in the direction perpendicular to them [31]. This difference is more profound in the stretching mode.…”

Section: Constrained Shape Memory Cyclementioning

confidence: 98%

4D printing and annealing of PETG composites reinforced with short carbon fibers

Rahmatabadi,

Soleyman,

Fallah Min Bashi

et al. 2024

Phys. Scr.

Self Cite

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In this study, for the first time, post-heat treatment was applied to improve the stress recovery of short carbon fiber reinforced PETG (SCFRPETG). PETG and SCFRPETG composite were printed under optimal conditions, and constrained and free shape memory cycles were applied under compression and three-point bending loadings to assess shape and stress recovery. The results of the free shape memory test for both vertical and horizontal patterns showed that PETG composite also has a higher shape memory effect (SME) compared to PETG. The SME was significantly improved by performing heat treatment. The stress recovery values for pure PETG, reinforced PETG before and after annealing are 2.48 MPa, 3.04 MPa and 3.18 MPa, respectively. It showed that the addition of 1.5% carbon fiber increases the stress recovery by 22%. The increasing trend reaches 28% by performing post-heat treatment. Additionally, altering the printing pattern affects the programming and stress recovery values. For the SCFRPETG composite samples before and after annealing, changing the printing pattern from horizontal to vertical, resulted in a 16% and 7% increase in recovery stress, respectively. SEM results confirm that the annealing process removes the layered structure, micro-holes caused by shrinkage and 4D printing mechanism. Using the controlled heat treatment method can be a practical solution to solve the problem of adhesion and reduce the anisotropy of FDM 3D printed layers.

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Section: Constrained Shape Memory Cyclementioning

confidence: 98%

4D printing and annealing of PETG composites reinforced with short carbon fibers

Rahmatabadi,

Soleyman,

Fallah Min Bashi

et al. 2024

Phys. Scr.

Self Cite

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“…Davood Rahmatabadi et al demonstrated that by incorporating just 30% TPU (thermoplastic polyurethane) with 70% PLA (polylactic acid) in a composite manufactured through fused deposition modeling 3D printing, they significantly improved the shape memory performance [49]. Their composite displayed shape fixity and shape recovery rates of up to 100% and 91%, respectively.…”

Section: Application To the Manufacture Of Heart Valve Structuresmentioning

confidence: 99%

Aortic Valve Engineering Advancements: Precision Tuning with Laser Sintering Additive Manufacturing of TPU/TPE Submillimeter Membranes

Ciobotaru,

Batistella,

De Oliveira Emmer

et al. 2024

Polymers

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Synthetic biomaterials play a crucial role in developing tissue-engineered heart valves (TEHVs) due to their versatile mechanical properties. Achieving the right balance between mechanical strength and manufacturability is essential. Thermoplastic polyurethanes (TPUs) and elastomers (TPEs) garner significant attention for TEHV applications due to their notable stability, fatigue resistance, and customizable properties such as shear strength and elasticity. This study explores the additive manufacturing technique of selective laser sintering (SLS) for TPUs and TPEs to optimize process parameters to balance flexibility and strength, mimicking aortic valve tissue properties. Additionally, it aims to assess the feasibility of printing aortic valve models with submillimeter membranes. The results demonstrate that the SLS-TPU/TPE technique can produce micrometric valve structures with soft shape memory properties, resembling aortic tissue in strength, flexibility, and fineness. These models show promise for surgical training and manipulation, display intriguing echogenicity properties, and can potentially be personalized to shape biocompatible valve substitutes.

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“…Furthermore, the 4D printing technique has emerged as a powerful tool for creating objects tailored for biomedical implants and smart textiles. By leveraging materials like PVC [2,3] and porous PLA-TPU [4], 4D printing enables the fabrication of structures capable of dynamically changing shape in response to external triggers. However, the challenge of poor mechanical properties in SMPs can be effectively addressed by harnessing the unique characteristics of nanofillers [5].…”

Section: Introductionmentioning

confidence: 99%

Analysing the shape memory behaviour of MWCNT-enhanced nanocomposites: a comparative study between experimental and finite element analysis

Gupta,

Mittal,

Kumar

et al. 2024

Funct. Compos. Struct.

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Shape memory polymers (SMPs) are known for their unique ability to withstand large deformations and revert to their original shape under specific external stimuli. However, their broader application in biomedical and structural applications is restricted by limited mechanical and thermal properties. Introducing multi-walled carbon nanotubes (MWCNTs) into SMPs has proven to significantly enhance these characteristics without affecting their inherent shape memory features. This study investigates shape memory nanocomposites (SMNCs) through dynamic and thermogravimetric analyses, along with tensile, flexural, and shape memory testing, and explores fracture interfaces using scanning electron microscopy. Findings indicate optimal shape memory, thermal, and mechanical properties with 0.6 wt% MWCNT content, showcasing a shape recovery ratio of 93.11%, storage modulus of 4127.63 MPa, tensile strength of 55 MPa, and flexural strength of 107.94 MPa. Moreover, incorporating MWCNTs into epoxy demonstrated a reduction in recovery times by up to 50% at 0.6 wt% concentration. Despite a slight decrease in shape fixity ratio from 98.77% to 92.11%, shape recoverability remained nearly consistent across all samples. The study also introduces a novel finite element (FE) method in ABAQUS for modeling the thermomechanical behaviour of SMNCs, incorporating viscoelasticity, validated by matching experimental results with FE simulations, highlighting its accuracy and practical applicability in engineering.

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4D printing of porous PLA-TPU structures: effect of applied deformation, loading mode and infill pattern on the shape memory performance

Cited by 29 publications

References 47 publications

4D printing and annealing of PETG composites reinforced with short carbon fibers

4D printing and annealing of PETG composites reinforced with short carbon fibers

Aortic Valve Engineering Advancements: Precision Tuning with Laser Sintering Additive Manufacturing of TPU/TPE Submillimeter Membranes

Analysing the shape memory behaviour of MWCNT-enhanced nanocomposites: a comparative study between experimental and finite element analysis

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