Development of Heat Treatments for Selective Laser Melting Ti6Al4V Alloy: Effect on Microstructure, Mechanical Properties, and Corrosion Resistance

Cecchel, Silvia; Ferrario, Davide; Cornacchia, Giovanna; Gelfi, Marcello

doi:10.1002/adem.202000359

Cited by 26 publications

(30 citation statements)

References 29 publications

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“…Indeed, the equiassic and isotropic macrostructure of SLM, composed of a mixture of thin α lamellae and β phase, guarantees the proper match of mechanical strength and ductility. This confirms that the heat treatment, selected after preliminary investigations, [25] guaranteed the achievement of the proper microstructure on the SLM conrod to respect the mechanical requirements during its operation. The positive comparison with the tensile properties of the forged samples confirmed these conclusions, proving that the SLM microstructure induced by the heat treatment was proper for the application.…”

Section: Tensile Test and Hardnesssupporting

confidence: 65%

“…The two processes present different microstructure, as expected in relation with process dissimilarities, but the aforementioned features were achieved for both CM and SLM samples. It is important to remember that these features were achieved due to the detailed preliminary researches on heat treatments [ 25 ] that guaranteed the achievement of the proper microstructure on the SLM conrod. In addition, both the microstructures are expected to give good mechanical properties.…”

Section: Resultsmentioning

confidence: 99%

“…For major details, see the related previous research about this topic. [25] Microstructure at higher magnification was analyzed looking at SEM images, as shown in Figure 10 and 11 for forged and SLM section, respectively. For SEM analysis, α phase is dark while β phase is light.…”

Section: Microstructural Observationmentioning

confidence: 99%

“…From the analysis of the aforementioned literature and after a previous research work on samples produced in the same batch of the conrod, [ 25 ] the following heat treatment was considered the best option to achieve the desired mechanical properties on the SLM conrods: super‐β transus solubilization followed by a tempering. Indeed, considering the specific application, this heat treatment shows the best match of mechanical properties, residual stresses, and corrosion resistance.…”

Section: Introductionmentioning

confidence: 99%

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Numerical, Mechanical, and Metallurgical Investigation of an Innovative Near Net Shape Titanium Selective Laser Melting Engine Component and Comparison with the Conventional Forged One

Cecchel¹,

Ferrario²,

Mega³

et al. 2021

Adv Eng Mater

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As is well known today, additive manufacturing (AM) is a process of joining materials to make objects from 3D model data as opposed to subtractive manufacturing methodologies which remove material. [1] In general, AM technology allows the manufacturing of parts directly from digital model by depositing the material through a layer-by-layer approach that is digitally controlled. This emerging technology can manufacture metallic components with high precision. Among the main advantages, it can be found freedom of part design, part complexity, lightweighting, part consolidation, and design for specific functions. In light of this, AM technologies could provide an optimal trade-off between the need to increase manufacturing speed for highly customized and complex parts while achieving required mechanical properties with near net shaped components containing fewer defects. All these aspects are of interests in metal AM for aerospace, oil and gas, marine, and transport applications. [2] Among these processes, particularly selective laser melting (SLM) is one of the most used. This is a powder bed fusion process that uses metal powder, mainly for the manufacturing of components belonging to the biomedical and automotive field. [3][4][5] SLM has the great benefit to generate very complex shapes [6] that are often impossible to be produced with the conventional technologies. Thus, near net shape (NNS) parts and undercuts can be now easily created with this new technology. Another SLM benefit could be the creation of internal passages by maintaining a good dimensional control; this could be used, for example, for the integration of cooling channels. A first benefit that can be gathered is the reduction of metalworking operation. In the automotive field, the opportunity to create lightweight components [7][8][9] due to a NNS design is even more important. Indeed, this is one of the most feasible measures to reduce the vehicle emissions [10][11][12] and consequently the traffic-related air pollution. As mentioned earlier, it is clearly the need to modify how engineers think when designing parts; the typical design of traditional subtractive manufacturing processes is very different from the new shapes achievable with AM. [13] Thus, to take full advantage of unique capabilities from AM processes, specific Design for Additive Manufacturing (DfAM) methods are needed. Typical DfAM includes topology optimization and other design methods which can be supported by AM-enabled features. In the automotive domain, SLM is currently limited for the production of prototypes or rare spare parts, while research is moving toward a larger adoption of this technology, [14,15] for example, targeting the production of components for high-end and luxury vehicles.

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Section: Tensile Test and Hardnesssupporting

confidence: 65%

Section: Resultsmentioning

confidence: 99%

Section: Microstructural Observationmentioning

confidence: 99%

Section: Introductionmentioning

confidence: 99%

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Numerical, Mechanical, and Metallurgical Investigation of an Innovative Near Net Shape Titanium Selective Laser Melting Engine Component and Comparison with the Conventional Forged One

Cecchel¹,

Ferrario²,

Mega³

et al. 2021

Adv Eng Mater

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“…[11][12][13][14][15][16] Several manufacturing processes among the aforementioned applications contemplate the implementation of material characterization procedures, either on pristine samples of the material or on previously manufactured parts. The most commonly applied experimental procedures to identify the macroscopic orthotropic elastoplastic properties of a material include monotonic tensile, [17,18] compression, [19,20] and shear [21,22] tests of material samples obtained from its orthogonal directions. The main limitations of these tests are the size of the specimens and their subsequent destruction,…”

mentioning

confidence: 99%

Nanomechanical Characterization of the Deformation Response of Orthotropic Ti–6Al–4V

et al. 2021

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The research interest in titanium alloys lies in the fact that their exceptional mechanical properties make them ideal for specific industrial applications, such as biomedical, aerospace, and military industries. [1][2][3] Despite its high cost, Ti-6Al-4V alloy is currently the most widely used titanium alloy, [4] combining good biocompatibility and corrosion resistance, [5][6][7][8][9][10] high strength, low weight, and ductility. [11][12][13][14][15][16] Several manufacturing processes among the aforementioned applications contemplate the implementation of material characterization procedures, either on pristine samples of the material or on previously manufactured parts. The most commonly applied experimental procedures to identify the macroscopic orthotropic elastoplastic properties of a material include monotonic tensile, [17,18] compression, [19,20] and shear [21,22] tests of material samples obtained from its orthogonal directions. The main limitations of these tests are the size of the specimens and their subsequent destruction,

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Wear and Corrosion Characterization of a Ti–6Al–4V Component for Automotive Applications: Forging versus Selective Laser Melting Technologies

Cecchel¹,

Montesano

Cornacchia

2022

Adv Eng Mater

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Selective laser melting (SLM) is applied to manufacture a Ti-6Al-4V conrod, an engine component, in order to reduce the weight respect to the original version produced by forging with the same alloy. The weight reduction is achieved through a topological optimization and is about 15%. The article focuses on an experimental study of titanium SLM and hot forging components based on evaluation and comparison of properties relevant for automotive applications: metallurgy, corrosion behavior, and wear resistance. The microstructure is duplex, composed of equiaxial α and β grains for both the technologies analyzed; different morphology and distribution of α and β phases are observed as expected. The analysis on corrosion and wear resistance against 100Cr6 highlights very similar properties for the two technologies. Finally, this study confirms that Ti-6Al-4V made by SLM can substitute the traditional forging technologies in the transport field for the properties here studied.

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Development of Heat Treatments for Selective Laser Melting Ti6Al4V Alloy: Effect on Microstructure, Mechanical Properties, and Corrosion Resistance

Cited by 26 publications

References 29 publications

Numerical, Mechanical, and Metallurgical Investigation of an Innovative Near Net Shape Titanium Selective Laser Melting Engine Component and Comparison with the Conventional Forged One

Numerical, Mechanical, and Metallurgical Investigation of an Innovative Near Net Shape Titanium Selective Laser Melting Engine Component and Comparison with the Conventional Forged One

Nanomechanical Characterization of the Deformation Response of Orthotropic Ti–6Al–4V

Wear and Corrosion Characterization of a Ti–6Al–4V Component for Automotive Applications: Forging versus Selective Laser Melting Technologies

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