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14 results on '"Antonella Sola"'

1. Open challenges in tensile testing of additively manufactured polymers: A literature survey and a case study in fused filament fabrication

Author

Antonella Sola, Wei Juene Chong, Dejana Pejak Simunec, Yuncang Li, Adrian Trinchi, Ilias (Louis) Kyratzis, and Cuie Wen

Subjects
Tensile properties, International standard, Size effect, Additive manufacturing, Fused filament fabrication, Fused deposition modeling, Polymers and polymer manufacture, TP1080-1185
Abstract

Additive manufacturing (AM, also commonly termed 3D printing) is progressing from being a rapid prototyping tool to serving as pillar of the Industry 4.0 revolution. Thanks to their low density and ease of printing, polymers are receiving increasing interest for the fabrication of structural and lightweight parts. Nonetheless, the lack of appropriate standards, specifically conceived to consistently verify the tensile properties of polymer parts and benchmark them against conventional products, is a major obstacle to the wider uptake of polymer AM in industry. After reviewing the standardisation needs in AM with a focus on mechanical testing, the paper closely examines the hurdles that are encountered when existing standards are applied to measure the tensile properties of polymer parts fabricated by fused filament fabrication (FFF, aka fused deposition modeling, FDM), which is presently the most popular material extrusion AM technique. Existing standards are unable to account for the numerous printing parameters that govern the mechanical response of FFF parts. Moreover, the literature suggests that the raster- and layer-induced anisotropic behaviour and the complicated interplay between structural features at different length scales (micro/meso/macro-structure) undermine pre-existing concepts regarding the specimen geometry and classical theories regarding the size effect, and ultimately jeopardise the transferability of conventional tensile test standards to FFF parts. Finally, the statistical analysis of the tensile properties of poly(lactic acid) (PLA) FFF specimens printed according to different standards (ASTM D638 type I and ASTM D3039) and in different sizes provides experimental evidence to confirm the literature-based argumentation. Ultimately, the literature survey, supported by the experimental results, demonstrates that, until dedicated standards become available, existing standards for tensile testing should be applied to FFF with prudence. Whilst not specified in conventional standards, set-up and printing parameters should be fully reported to ensure the repeatability of the results, rectangular geometries should be preferred to dumbbell-like ones in order to avoid premature failure at the fillets, and the size of the specimens should not be changed arbitrarily.

Published
2023
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12. Electron beam melting in biomedical manufacturing

Author

Alireza Nouri and Antonella Sola

Subjects
medicine.diagnostic_test, Computer science, Cathode ray, Fuse (electrical), medicine, Mechanical engineering, Metal powder, Computed tomography, Object (computer science)
Abstract

Electron beam melting (EBM) is an additive manufacturing technique that uses an electron beam to selectively fuse and consolidate the metal powder. The final object is built up layer-by-layer according to a computer-aided design or, in case of customized biomedical implants, according to a computed tomography of the patient. This chapter introduces the basic concepts of EBM and the advantages and limitations of applying this technique in biomedical manufacturing. Subsequently, the chapter is describing the processing steps of EBM, the consolidation mechanisms, and the potential microstructural defects of the finished parts. A thorough discussion is provided about the EBM capability of producing cellular structures, dental implants, and orthopedic prostheses, with an emphasis on customized parts. The chapter closes with a survey of the challenges and the future developments of EBM to fabricate biomedical devices.

Published
2020
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13. List of Contributors

Author

Andrej Atrens, Arne Biesiekierski, Sanjeet Chandra, Matthew S. Dargusch, Songlin Ding, Kate Fox, Jianye Han, Christopher Jeffery, Sean Johnston, Guangxian Li, Yuncang Li, Syed Hasan Masood, Khurram Munir, Alireza Nouri, Rizwan Abdul Rahman Rashid, Aaqil Rifai, Syed Haider Riza, Avik Sarker, Antonella Sola, Yu Sun, Nhiem Tran, Phong A. Tran, Ryan Vadori, Jeffrey Venezuela, Gui Wang, Cuie Wen, Hongtao Yang, Sen Yu, Zhentao Yu, and Yufeng Zheng

Published
2020
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14. Mechanical performance of epoxy coated AR-glass fabric Textile Reinforced Mortar: Influence of coating thickness and formulation

Author

Massimo Messori, Antonella Sola, Andrea Nobili, and Cesare Signorini

Subjects
Materials science, Epoxy coating, Composite number, 0211 other engineering and technologies, 02 engineering and technology, engineering.material, Industrial and Manufacturing Engineering, Coating thickness, Coating, 021105 building & construction, Composite material, Textile Reinforced Mortar, Embedment, Mechanical Engineering, Epoxy, 021001 nanoscience & nanotechnology, Mechanics of Materials, visual_art, Ceramics and Composites, engineering, visual_art.visual_art_medium, Hardening (metallurgy), Surface modification, Coating thickness Epoxy coating Textile Reinforced Mortar, Mortar, Elongation, 0210 nano-technology
Abstract

The mechanical performance of epoxy coated AR-glass fabric reinforced composite is investigated. A three-stage manufacturing process is considered, which involves fabric surface functionalization, liquid coating deposition and long-term setting and finally fabric embedment in the mortar matrix. Two epoxy coatings are considered, which only differ by the hardening agent. However, coating thickness is significantly diverse as a result of modified viscosity during liquid deposition. Performance is assessed in uni-axial tension as well as in three-point bending and it is expressed in terms of strength curves, data dispersion, crack pattern and failure mechanism. Remarkably, despite being very similar, the analyzed coatings produce a significantly different performance, especially when data dispersion is incorporated and design limits are considered. Indeed, although both coatings are able to consistently deliver fabric rupture at failure, only the thinnest is associated with small data scattering and an almost plastic post-peak behavior in bending. The associated design elongation limit reaches the maximum allowed value according to the ICC guidelines. In fact, it appears that coating thickness plays a crucial role in determining mechanical performance and fabric flexibility. The proposed manufacturing process proves extremely effective at enhancing matrix-to-fabric adhesion and thereby prevent telescopic failure.

Published
2018

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