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2. Lattice structures in stainless steel 17-4PH manufactured via selective laser melting (SLM) process: dimensional accuracy, satellites formation, compressive response and printing parameters optimization

Author

Alcide Bertocco, Gianluca Iannitti, Antonio Caraviello, Luca Esposito, Bertocco, Alcide, Iannitti, Gianluca, Caraviello, Antonio, and Esposito, Luca

Subjects
Compression behaviour, Selective laser melting, Additive manufacturing, Control and Systems Engineering, Optimization procedure, Mechanical Engineering, Lattice structures, Printing parameters, Industrial and Manufacturing Engineering, Software, Computer Science Applications
Abstract

By the term, lattice structures are intended topologically ordered open-celled structures consisting of one or more repeating unit cells. Technological development and especially the growth of the additive manufacturing (AM) industry allows innovative structural design, including complex lattice structure. Selective laser melting (SLM) is an AM process that enables the manufacture of space filling structures. This work investigated the influence of the most important process parameter settings on lattices printability, focusing on the geometrical accuracy, the quantity of powders adhered to the main frame (satellites) and their compression behaviour. The process parameters such as the laser power, scan speed and layer height affect vigorously the design, quality and mechanical properties of the part. The aim of the paper is to evaluate how different parameter combinations affect the cellular structures’ printing. Twenty-four lattice structures with cubic and rhombic dodecahedron unit cells made of stainless steel 17-4PH (AISI-630) were printed using different combinations of SLM process parameters. Each structure was analysed considering its geometrical, topological and mechanical properties. Finally, the best parameter combination was evaluated comparing results achieved. Although this work investigated the 17-4PH stainless steel, physical principles related to the printing process described are generally true for the SLM process. Therefore, the adopted approach could still be suitable also for all the other materials commonly used with this AM technology.

Published
2022
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3. Effect of the Mixing Technique of Graphene Nanoplatelets and Graphene Nanofibers on Fracture Toughness of Epoxy Based Nanocomposites and Composites

Author

Aldobenedetto Zotti, Simona Zuppolini, Anna Borriello, Valeria Vinti, Luigi Trinchillo, Domenico Borrelli, Antonio Caraviello, and Mauro Zarrelli

Subjects
Polymers and Plastics, graphene nanoplatelet (GNP), graphite nanofibers, fracture toughness, nanocomposites, carbon fiber reinforced composite (CFRC), mode I and mode II interlaminar fracture toughness, General Chemistry
Abstract

In this work, the effect of different mixing techniques on thermal and mechanical properties of graphene nanoplatelets (GNPs) and graphene nanofibers (GANFs) loaded epoxy nanocomposites was investigated. Three dispersion methods were employed: a high shear rate (HSR), ultrasonication (US) and the fluidized bed method (FBM). The optical microscopy has revealed that the most suitable dispersion, in terms of homogeneity and cluster size, is achieved by implementing the US and FBM techniques, leading to nanocomposites with the largest increase of glass transition temperature, as supported by the DMA analysis data. The fracture toughness results show a general increase of both the critical stress intensity factor (KIC) and the critical strain energy release rate (GIC), likely due to the homogeneity and the low scale dispersion of the carbonaceous nanostructures. Based on the nanocomposite fracture toughness improvements and also assuming a potential large scale up production of the nanocomposite matrix, a single mixing technique, namely the FBM, was employed to manufacture the carbon fiber reinforced composite (CFRC). This method has resulted in being less time-consuming and is potentially most suitable for the high volume industrial production. The CFRCs were characterized in terms of tensile, flexural and interlaminar fracture toughness properties and the results were analyzed and discussed.

Published
2022

4. Selective laser melting of an Al-Si-Mg-Cu alloy: feasibility and processing aspects

Author

Antonio Caraviello, Antonello Astarita, Irene Del Sol, Roberta Della Gatta, Della Gatta, R., Del Sol, I., Caraviello, A., and Astarita, A.

Subjects
0209 industrial biotechnology, melting, Materials science, alsi10mg, Alloy, 02 engineering and technology, engineering.material, Selective, 01 natural sciences, Industrial and Manufacturing Engineering, law.invention, power, 020901 industrial engineering & automation, law, 0103 physical sciences, General Materials Science, Selective laser melting, 010302 applied physics, density, Mechanical Engineering, Metallurgy, proce, Laser, slm, laser, mixture, parameter, Mechanics of Materials, Fluidized bed, Scientific method, engineering, cu, , energy
Abstract

A customized Al-Cu-Mg-Si alloy is successfully processed by selective laser melting. AlSi10Mg powder, used as a master alloy, has been mixed with pure Cu powder through a fluidized bed and the obtained powder mix was used as feedstock material for the printing process. To investigate the feasibility of the process and to discuss the effect of the process parameters, a two-step experimental campaign has been carried out: in the first batch of experiments the energy density has been varied to frame the processing window while in the second batch the energy density has been kept constant and the main process parameters have been varied to highlight their influence on the process. Density, porosity, and microhardness have been chosen as output to evaluate the success of the process. The microstructure and composition phase were studied through scanning electron microscopy and X-ray elemental mapping, respectively. A maximum relative density of 97% has been obtained while a predominant role of the laser beam power has been observed.

Published
2021
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5. Laser-Powder Bed Fusion of Inconel 718 Alloy: Effect of the Contour Strategy on Surface Quality and Sub-Surface Density

Author

Andrea El Hassanin, Francesco Napolitano, Carmela Trimarco, Emanuele Manco, Fabio Scherillo, Domenico Borrelli, Antonio Caraviello, Antonio Squillace, Antonello Astarita, El Hassanin, A., Napolitano, F., Trimarco, C., Manco, E., Scherillo, F., Borrelli, D., Caraviello, A., Squillace, A., and Astarita, A.

Subjects
Mechanics of Materials, Mechanical Engineering, General Materials Science
Abstract

The in-situ contour strategy during Laser-Powder Bed Fusion (L-PBF) process remains one of the most promising solutions to improve the poor surface quality of the parts. On the other hand, it is well established that contour step affects the formation of sub-surface defects. The aim of this work is to assess the entity of sub-surface defects during the Laser-Powder Bed Fusion of Inconel 718 samples for which different contour processing conditions are considered. Cubic samples with 10 mm side were produced through L-PBF using a Concept Laser Cusing M2 L-PBF machine. The samples were printed with fixed bulk laser parameters, adopting a layer thickness of 30 μm and a chessboard laser scanning strategy. The in-situ contour conditions were changed in terms of laser scanning speed and hatch zone border. Afterwards, the samples were analyzed in terms of surface roughness (Sa) and sub-surface density through confocal microscopy. The results revealed that the surface roughness was the most affected output as a function of the varied process parameters, including the sample position on the building platform, with values ranging from 13 to 32 μm. On the other hand, the sub-surface density was always higher than 99%.

Published
2022

8. Experimental Study of Cold Sprayed Metallic Coatings on Thermoplastic Matrix Composites

Author

Antonello Astarita, Antonio Caraviello, Roberta Della Gatta, Massimo Durante, Luca Boccarusso, Alessia Serena Perna, Raffaele Sansone, Antonio Viscusi, Luigi Carrino, Viscusi, A., Perna, A. S., Astarita, A., Boccarusso, L., Caraviello, A., Carrino, L., Gatta, R. D., Durante, M., and Sansone, R.

Subjects
Composite material, 010302 applied physics, 0209 industrial biotechnology, Materials science, Cold spray technology, Mechanical Engineering, 02 engineering and technology, 01 natural sciences, Metal, 020901 industrial engineering & automation, Mechanics of Materials, visual_art, 0103 physical sciences, visual_art.visual_art_medium, Aluminium coating, General Materials Science, Thermoplastic matrix, Deposition process, Deposition proce, Particle-substrate interaction
Abstract

In this research activity, the manufacturing of metallic coatings on polymer-based panels through the low pressure cold spray technique was studied. Aluminium particles were sprayed for the metallization and carbon fibre composite materials with thermoplastic matrix (PP, PA66) were used as substrates. Different deposition parameter combinations have been set to investigate the feasibility of the process; SEM analyses were carried out to study the coating surface morphology and the interface interaction between particle and substrate. The results showed that the CS process is an effective technique to create aluminium coatings on polymeric matrix composite materials: compact coatings can be obtained if the process parameters are properly set.

Published
2019
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9. On the effect of the layer thickness in Laser-Powder Bed Fusion of pre-mixed Incone1718-Cu powders

Author

Antonello Astarita, Irene Del Sol Illana, Antonino Squillace, Antonio Caraviello, Andrea El Hassanin, Fabio Scherillo, Domenico Borrelli, El Hassanin, Andrea, Scherillo, Fabio, del Sol Illana, Irene, Caraviello, Antonio, Borrelli, Domenico, Astarita, Antonello, and Squillace, Antonino

Subjects
Materials science, Thermal conductivity, Electrical resistivity and conductivity, Surface roughness, Relative density, Context (language use), Composite material, Inconel, Microstructure, Indentation hardness
Abstract

The customization of material characteristics in combination with extreme design flexibility represents the most intriguing scope of Additive Manufacturing. In this context, this work investigated the feasibility of the Laser-based Powder Bed Fusion process (L-PBF) of pre-mixed Inconel 718-Cu powder blends, exploring the effects of the laser-related process parameters and Cu addition, in order to develop alloys able to combine excellent mechanical properties under severe operating conditions with good thermal and electrical conductivity. More specifically, this work investigated the effects of using a layer thickness of $\boldsymbol{30 \mu \mathrm{m}}$ on the process quality in terms of density, microhardness, microstructure and surface roughness. Results showed that cubic samples with 10 mm side were successfully produced, with a relative density always greater than 98 percent. The resulting microhardness was from 290 to 340 HV, decreasing as a function of the Cu addition and keyhole defects development. The latter were the main defects observed in the microstructure, characterized also by heterogeneous crystalline grains for all the investigated conditions. Finally, the surface roughness (Sa) was from 7 to $\boldsymbol{25 \mu \mathrm{m}}$ , in line with the typical values of L-PBF products.

Published
2021

10. On the Microstructural Analysis of LFW Joints of Ti6Al4V Components Made via Electron Beam Melting

Author

Luigi Carrino, Rosario Borrelli, Mariacira Liberini, Antonino Squillace, Stefania Franchitti, Fabio Scherillo, Carmine Pirozzi, Pierluigi Cirillo, Antonio Caraviello, Antonello Astarita, Scherillo, Fabio, Liberini, Mariacira, Astarita, Antonello, Franchitti, Stefania, Pirozzi, Carmine, Borrelli, Rosario, Cirillo, Pierluigi, Caraviello, Antonio, Squillace, Antonino, and Carrino, Luigi

Subjects
010302 applied physics, Materials science, Metallurgy, Compaction, Recrystallization (metallurgy), Titanium alloy, 02 engineering and technology, General Medicine, 021001 nanoscience & nanotechnology, Microstructure, 01 natural sciences, Martensite, 0103 physical sciences, Lamellar structure, Friction welding, Composite material, 0210 nano-technology, Near net shape
Abstract

Additive Manufacturing (AM), applied to metal industry, is a family of processes that allow complex shape components to be realized from raw materials in the form of powders. The compaction of the powders is achieved by local melting of bed. Electron Beam Melting (EBM) is an additive manufacturing process in which a focalized electron beam is the heat source that allows the powders to be compacted. By EBM it is possible to realize complex shape components; this feature is of particular interest in titanium industry where numerous efforts are done to develop near net shape processes. One of the limits of EBM based AM process is the difficulty to realize large dimension parts. Due to this limit the study of joining processes of different parts is of great interest. In the present work the microstructure evolution of sheets of TI6Al4V made by EBM and joined by Linear Friction Welding (LFW) is analyzed in details. The bulk microstructure of the specimen is fine lamellar; lamellae are enclosed in alpha colonies. Different types of porosities are observed. In the joint a Thermo Mechanical Affected Zone (TMAZ) and Weld Bead (WB) are evident. In TMAZ a partial recrystallization occurs and the parent microstructure is deformed. Complete recrystallization occurs in WB whose structure is martensitic.

Published
2017
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11. Influence of Eta-Phase on Wear Behavior of WC-Co Carbides

Author

Antonio Caraviello, F. Capece Minutolo, Antonio Langella, Luigi Carrino, Massimo Durante, Antonio Formisano, Formisano, Antonio, MEMOLA CAPECE MINUTOLO, Fabrizio, Caraviello, Antonio, Carrino, Luigi, Durante, Massimo, and Langella, Antonio

Subjects
Materials science, Article Subject, lcsh:Mechanical engineering and machinery, Wear Behavior, Widia, chemistry.chemical_element, Sintering, 02 engineering and technology, Indentation hardness, Carbide, Machining, Phase (matter), lcsh:TJ1-1570, Eta-Phase, WC-Co Carbide, 020502 materials, Mechanical Engineering, Abrasive, Metallurgy, 021001 nanoscience & nanotechnology, Surfaces, Coatings and Films, Characterization (materials science), 0205 materials engineering, chemistry, 0210 nano-technology, Carbon
Abstract

Cemented carbides, also known as Widia, are hard metals produced by sintering process and widely used in mechanical machining. They show high cutting capacity and good wear resistance; consequently, they result to be excellent materials for manufacturing cutting tools and sandblast nozzles. In this work, the wear resistance of WC-Co carbides containing Eta-phase, a secondary phase present in the hard metals when a carbon content deficiency occurs, is analyzed. Different mixtures of carbide are prepared and sintered, with different weight percentages of carbon, in order to form Eta-phase and then analyze how the carbon content influences the wear resistance of the material. This characterization is carried out by abrasive wear tests. The test parameters are chosen considering the working conditions of sandblast nozzles. Additional information is gathered through microscopic observations and the evaluation of hardness and microhardness of the different mixtures. The analyses highlight that there is a limit of carbon content below which bad sintering occurs. Considering the mixtures without these sintering problems, they show a wear resistance depending on the size and distribution of the Eta-phase; moreover, the one with high carbon content deficiency shows the best performance.

Published
2016
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12. Deposition of aluminum coatings on bio-composite laminates

Author

Raffaele Sansone, Luigi Carrino, Antonio Caraviello, Massimo Durante, Antonello Astarita, Dario De Fazio, Antonio Viscusi, Luca Boccarusso, Boccarusso, L., Viscusi, A., Durante, M., Astarita, A., De Fazio, D., Sansone, R., Caraviello, A., and Carrino, L.

Subjects
Materials science, Bending (metalworking), Scratch, Composite number, Gas dynamic cold spray, Compression molding, Deposition (phase transition), Substrate (printing), Composite material, Composite laminates, computer, computer.programming_language
Abstract

As a result of the increasing environmental awareness, the concern for environmental sustainability and the growing global waste problem, the interest of bio-composites materials is growing rapidly in the last years in order to use them in various engineering fields. Tremendous advantages and opportunities are associated with the use of these materials. On the other hand, some issues are related to the superficial properties of the bio-laminates, in particular the wear properties, the flame resistance and the aesthetic appearance have to be improved in order to extend the application fields of these materials. Aiming to these goals this paper deals with the study of the deposition of aluminum coating through cold spray process on hemp/PLA bio-composites manufactured by using the compression molding technique. Therefore, SEM observations, roughness analyses, bending tests, pin on disk and scratch tests were carried out in order to study the feasibility of the process and to investigate on the properties of the coated samples. The experimental results proved that when the process parameters of the deposition process are properly set, no damages are induced in the composite panel and that the aluminum coating, under specific load conditions, resulted to be able to protect the substrate.

Published
2018
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13. Wear Behavior of WC-Co Carbides with Addition of Cr3C2 and Ni

Author

Fabrizio Memola Capece Minutolo, Antonio Caraviello, Luigi Carrino, Massimo Durante, Antonio Formisano, and Antonio Langella

Subjects
Materials science, Mechanical Engineering, Abrasive, Metallurgy, chemistry.chemical_element, Diamond, engineering.material, Carbide, Nickel, chemistry.chemical_compound, chemistry, Mechanics of Materials, Tungsten carbide, Cemented carbide, engineering, General Materials Science, Cobalt, Chromium carbide
Abstract

Cemented carbides present some characteristics that ensure high performances for cutting and wear-resistant tools. The aim of the work is to evaluate the influence of Chromium Carbide and Nickel on the properties (wear and friction) of a cemented carbide constituted by a hard phase of tungsten carbide and a binder phase of cobalt. Different tests were carried out by varying the percentage of Cr3C2 and, for one only case, also Nickel was added. The tests were carried out by a pin-on-disk apparatus and diamond abrasive sheet. The experimental campaign provided tests for different values of load and relative velocity. Friction coefficient was directly evaluated by the apparatus and data on the wear were obtained by measuring the loss of weight of the samples (parallelepipeds with hemispherical head). The tests allowed to determine the percentage of Cr3C2 that ensure an improvement of the aforementioned properties and to highlight the irrelevance of Nickel.

Published
2014
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