A Comprehensive Mechanical Examination of ABS and ABS-like Polymers Additively Manufactured by Material Extrusion and Vat Photopolymerization Processes

Golubović, Zorana; Danilov, Ivan; Bojović, Božica; Petrov, Ljubiša; Sedmak, Aleksandar; Mišković, Žarko; Mitrović, Nenad

doi:10.3390/polym15214197

Cited by 3 publications

(2 citation statements)

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“…In the paper [41], the authors determined that raising the infill percentage from 20% to 50% in ABS results in a 26% enhancement in ultimate tensile strength (UTS), a 24% increase in yield stress, a 45% boost in Young's modulus, and a slight 1% improvement in elongation at break. ABS-like resin is part of the group of thermoplastic polymers consisting of three components: acrylonitrile, butadiene, and styrene [47][48][49][50][51][52][53]. As reported in [49], the presence of acrylonitrile enhances the thermal and chemical resilience, along with the surface hardness of the end product.…”

Section: Introductionmentioning

confidence: 99%

“…ABS-like resin material is accessible for commercial purposes; however, it lacks extensive mechanical research, resulting in limited available literature [47]. In the paper [47], Golubović et al conducted an extensive mechanical examination of both ABS and similar polymers produced via additive manufacturing techniques such as FDM, SLA, and DLP. The research utilized test samples with a complete infill density and a print orientation of 90 degrees.…”

Section: Introductionmentioning

confidence: 99%

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Characterization and Comparative Analysis of Mechanical Parameters of FDM- and SLA-Printed ABS Materials

Hozdić

2024

Applied Sciences

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This research paper provides an in-depth examination of the mechanical characteristics of 3D-printed specimens made from acrylonitrile butadiene styrene (ABS) and resins akin to ABS, with a focus on two widely used 3D printing methodologies: fused deposition modeling (FDM) and stereolithography (SLA). The study investigates how variations in 3D printing technology and infill density impact mechanical parameters such as Young’s modulus, tensile strength, strain, nominal strain at break, maximum displacement, and maximum force at break. Tensile testing was conducted to assess these critical parameters. The results indicate distinct differences in mechanical performance between FDM- and SLA-printed specimens, with SLA consistently showing superior mechanical parameters, especially in terms of tensile strength, displacement, and Young’s modulus. SLA-printed specimens at 30% infill density exhibited a 38.11% increase in average tensile strength compared to FDM counterparts and at 100% infill density, a 39.57% increase was observed. The average maximum displacement for SLA specimens at 30% infill density showed a 14.96% increase and at 100% infill density, a 30.32% increase was observed compared to FDM specimens. Additionally, the average Young’s modulus for SLA specimens at 30% infill density increased by 17.89% and at 100% infill density, a 13.48% increase was observed, highlighting the superior mechanical properties of SLA-printed ABS-like resin materials. In tensile testing, FDM-printed specimens with 30% infill density showed an average strain of 2.16% and at 100% infill density, a slightly higher deformation of 3.1% was recorded. Conversely, SLA-printed specimens at 30% infill density exhibited a strain of 2.24% and at 100% infill density, a higher strain value of 4.15% was observed. The comparison suggests that increasing the infill density in FDM does not significantly improve deformation resistance, while in SLA, it leads to a substantial increase in deformation, raising questions about the practicality of higher infill densities. The testing data underscore the impact of infill density on the average nominal strain at break, revealing improved performance in FDM and significant strain endurance in SLA. The study concludes that SLA technology offers clear advantages, making it a promising option for producing ABS and ABS-like resin materials with enhanced mechanical properties.

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Section: Introductionmentioning

confidence: 99%

Section: Introductionmentioning

confidence: 99%

Characterization and Comparative Analysis of Mechanical Parameters of FDM- and SLA-Printed ABS Materials

Hozdić

2024

Applied Sciences

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Comparative analysis of ABS materials mechanical properties

Golubovic,

Bojovic,

Petrov

et al. 2024

Procedia Structural Integrity

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Lean-and-Green Fractional Factorial Screening of 3D-Printed ABS Mechanical Properties Using a Gibbs Sampler and a Neutrosophic Profiler

Pantas,

Besseris

2024

Sustainability

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The use of acrylonitrile butadiene styrene (ABS) in additive manufacturing applications constitutes an elucidating example of a promising match of a sustainable material to a sustainable production process. Lean-and-green datacentric-based techniques may enhance the sustainability of product-making and process-improvement efforts. The mechanical properties—the yield strength and the ultimate compression strength—of 3D-printed ABS product specimens are profiled by considering as many as eleven controlling factors at the process/product design stage. A fractional-factorial trial planner is used to sustainably suppress by three orders of magnitude the experimental needs for materials, machine time, and work hours. A Gibbs sampler and a neutrosophic profiler are employed to treat the complex production process by taking into account potential data uncertainty complications due to multiple distributions and indeterminacy issues due to inconsistencies owing to mechanical testing conditions. The small-data multifactorial screening outcomes appeared to steadily converge to three factors (the layer height, the infill pattern angle, and the outline overlap) with a couple of extra factors (the number of top/bottom layers and the infill density) to supplement the linear modeling effort and provide adequate predictions for maximizing the responses of the two examined mechanical properties. The performance of the optimal 3D-printed ABS specimens exhibited sustainably acceptable discrepancies, which were estimated at 3.5% for the confirmed mean yield strength of 51.70 MPa and at 5.5% for the confirmed mean ultimate compression strength of 53.58 MPa. The verified predictors that were optimally determined from this study were (1) the layer thickness—set at 0.1 mm; (2) the infill angle—set at 0°; (3) the outline overlap—set at 80%; (4) the number of top/bottom layers—set at 5; and (5) the infill density—set at 100%. The multifactorial datacentric approach composed of a fractional-factorial trial planner, a Gibbs sampler, and a neutrosophic profiler may be further tested on more intricate materials and composites while introducing additional product/process characteristics.

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A Comprehensive Mechanical Examination of ABS and ABS-like Polymers Additively Manufactured by Material Extrusion and Vat Photopolymerization Processes

Cited by 3 publications

References 47 publications

Characterization and Comparative Analysis of Mechanical Parameters of FDM- and SLA-Printed ABS Materials

Characterization and Comparative Analysis of Mechanical Parameters of FDM- and SLA-Printed ABS Materials

Comparative analysis of ABS materials mechanical properties

Lean-and-Green Fractional Factorial Screening of 3D-Printed ABS Mechanical Properties Using a Gibbs Sampler and a Neutrosophic Profiler

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