Mechanical, morphological, and dimensional properties of heat-treated fused deposition modeling printed polymeric matrix of polyethylene terephthalate glycol

Kumar, Sudhir; Singh, Inderjeet; Kumar, Dinesh; Mago, Jonty; Koloor, S S R

doi:10.1177/14777606231218354

Cited by 3 publications

(2 citation statements)

References 35 publications

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“…A new factor, the "Krenchel coefficient (n 0 )," is introduced, which takes into account the fiber orientation angle. The elastic modulus of the composite is calculated through equation (10).…”

Section: Analytical Prediction Of the Mechanical Properties Of 3d-pri...mentioning

confidence: 99%

“…Applying a heat treatment to the printed parts can improve the mechanical properties of these thermoplastics. 10 Additionally, the mechanical performance of parts can be enhanced by adding short or long fibers or particles (powder). In a study, Kumar et al 11 demonstrated that the inclusion of wood or iron oxide powder can enhance specific mechanical properties, such as toughness, during recycling cycles.…”

Section: Introductionmentioning

confidence: 99%

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Study of 3D-printed onyx parts reinforced with continuous glass fibers: Focus on mechanical characterization, analytical prediction and numerical simulation

Nikiema,

Balland,

Sergent

2024

Journal of Composite Materials

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The 3D printing of continuous-fiber composites is currently relevant to engineers and researchers. This study aims to characterize and predict the mechanical properties of Onyx/glass fiber specimens printed using 3D printing. The work assesses the impact of glass fiber printing parameters on the mechanical behavior of printed parts and proposes analytical and numerical methods to predict mechanical properties. A physicochemical analysis was conducted on 3D printed continuous glass fibers. The study also investigated the impact of fiber printing parameters on composite parts. The results indicate that the 3D-printed glass fibers consist of nylon, continuous glass fibers, and voids (porosity), which range from 58% to 63%, 31% to 38%, and 5% to 8%, respectively. Mechanical characterizations indicate that printing fiber layers in blocks results in superior mechanical properties compared to printing alternating layers of glass fibers and Onyx. Additionally, the concentric mode of fiber printing can be challenging if the ‘start rotation’ parameter is not adjusted correctly. Premature specimen breakage occurred when fiber printing began within their useful length, resulting in a deformation at break that was approximately 34% less, depending on the starting position. The proposed analytical and numerical prediction methods had prediction errors of approximately 7% to 12% and 5% to 7%, respectively. Engineers can use these prediction approaches during the dimensioning phase of 3D printed composite parts.

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Section: Analytical Prediction Of the Mechanical Properties Of 3d-pri...mentioning

confidence: 99%

Section: Introductionmentioning

confidence: 99%

Study of 3D-printed onyx parts reinforced with continuous glass fibers: Focus on mechanical characterization, analytical prediction and numerical simulation

Nikiema,

Balland,

Sergent

2024

Journal of Composite Materials

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The potential of virgin Polyethylene Terephthalate Glycol (PETG) grades and their blends with waste PET(G) for filament-based material extrusion applications

Trossaert,

Ohnmacht,

Fiorillo

et al. 2025

Additive Manufacturing

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Optimizing mechanical behaviour of polylactic acid (PLA) specimen in fused deposition modeling (FDM): A Taguchi approach

Rizwee,

Kumar

2024

Progress in Rubber, Plastics and Recycling Technology

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The quality of the fabricated part in the Fused Deposition Modeling (FDM) technique is primarily influenced by the printing variables. Therefore, it is crucial to select the parameters appropriately in order to enhance the qualities of the build specimen. In light of this, this research investigated experimentally and statistically the influence of several printing parameters, like layer thickness, printing speed, and the density of infill, on mechanical properties using polylactic acid (PLA) material. On the basis of Taguchi’s factorial design model, nine trials established. The PLA parts manufactured on the FDM printer and mechanical properties evaluated using uniaxial tensile and hardness test. The Signal-to-Noise ratio (S/N) was being used to identify the best combination of the printing parameters. Analysis of Variance (ANOVA) used to find the significant variables and how they affected mechanical properties. In addition, a linear regression analysis performed to estimate the tensile strength ([Formula: see text]) and hardness of the manufactured component. The scanning electron microscope (SEM) was utilised for fractural surface analysis. The results reveal that only one factor, infill density (100 %), is statistically significant and have a substantial effect on the tensile strength (88.98%). Printing speed have more effect (55.38%) and layer thickness have the least affect (18.66%) on the hardness. Last, but not least, the confirmation test demonstrates that the experimental and statistical findings are consistent.

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Mechanical, morphological, and dimensional properties of heat-treated fused deposition modeling printed polymeric matrix of polyethylene terephthalate glycol

Cited by 3 publications

References 35 publications

Study of 3D-printed onyx parts reinforced with continuous glass fibers: Focus on mechanical characterization, analytical prediction and numerical simulation

Study of 3D-printed onyx parts reinforced with continuous glass fibers: Focus on mechanical characterization, analytical prediction and numerical simulation

The potential of virgin Polyethylene Terephthalate Glycol (PETG) grades and their blends with waste PET(G) for filament-based material extrusion applications

Optimizing mechanical behaviour of polylactic acid (PLA) specimen in fused deposition modeling (FDM): A Taguchi approach

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