Investigation of Co-Cr-Fe-Mn-Ni Non-Equiatomic High-Entropy Alloy Fabricated by Wire Arc Additive Manufacturing

Осинцев, К. А.; Konovalov, S. V.; Zagulyaev, D. V.; Ivanov, Yurii; Громов, В. Е.; Panchenko, Irina

doi:10.3390/met12020197

Cited by 16 publications

(10 citation statements)

References 46 publications

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“…These five elements constitute a quinary system, the thermodynamic description of which was studied until recently [6,7] . Beside the conventional foundry of equimolar FeCoNiCrMn alloys, different ways of elaboration of superalloys were recently applied to HEAs: single crystalline growth [8] , additive manufacturing [9] or thin film deposition [10] . Their behaviors in case of extreme conditions of solicitations were also explored, mechanical properties [11,12] or chemical reactivity at high temperature [13] .…”

Section: Introductionmentioning

confidence: 99%

As-Cast Microstructures of High Entropy Alloys Designed to Be TaC-Strengthened

Berthod

2022

j. of met. mater. res.

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In this work two new alloys were obtained by extrapolation from a wellknown high entropy alloy, the equimolar CoNiFeMnCr one. This was doneby the addition of carbon and of tantalum, Ta being one of the strongestMC-former elements. They were produced by conventional casting underinert atmosphere. The obtained microstructures were characterized by X-raydiffraction, metallography, electron microscopy, and energy dispersionspectrometry. Their hardness was also measured by hardness indentation.In parallel, the original CoNiFeMnCr alloy was also synthesized andcharacterized for comparison. The reference HEA alloy is single-phasedwith an austenitic structure, while the two {Ta, C}-added alloys aredouble-phased, with an austenitic matrix and interdendritic script-likeTaC carbides. The matrixes of these HEA/TaC alloy are equivalent toan equimolar CoNiFeMnCr alloy to which 2 wt.% Ta is present in solidsolution. The presence of the TaC carbides caused a significant increase inhardness which suggests that the HEA/TaC alloys may be mechanicallystronger than the HEA reference alloy at high temperature.

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Section: Introductionmentioning

confidence: 99%

As-Cast Microstructures of High Entropy Alloys Designed to Be TaC-Strengthened

Berthod

2022

j. of met. mater. res.

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“…Further research on the manufacturing of complex concentrated metal-cored wire, as a well-established filler for welding, needs to be done, although an alternative for alloydevelopment and the determination of the mechanical properties has been established using cable-like wires [31][32][33].…”

Section: Discussionmentioning

confidence: 99%

“…Here, too, the degrees of freedom in composition are significantly greater for small quantities of filler compared to solid wires. These cable-like fillers have been realized for complex concentrated alloys; demonstrated in [31][32][33]. Here, the limiting factor is the available diameter of the different alloying elements.…”

Section: Wire and Arc Additive Manufacturingmentioning

confidence: 99%

Wire and Arc Additive Manufacturing of a CoCrFeMoNiV Complex Concentrated Alloy Using Metal-Cored Wire—Process, Properties, and Wear Resistance

et al. 2022

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The field of complex concentrated alloys offers a very large number of variations in alloy composition. The achievable range of properties varies greatly within these variants. The experimental determination of the properties is in many cases laborious. In this work, the possibility of using metal-cored wires to produce sufficient large samples for the determination of the properties using arc-based additive manufacturing or in detail wire and arc additive manufacturing (WAAM) is to be demonstrated by giving an example. In the example, a cored wire is used for the production of a CoCrFeNiMo alloy. In addition to the process parameters used for the additive manufacturing, the mechanical properties of the alloy produced in this way are presented and related to the properties of a cast sample with a similar chemical composition. The characterization of the resulting microstructure and wear resistance will complete this work. It will be shown that it is possible to create additively manufactured structures for a microstructure and a property determination by using metal-cored filler wires in arc-based additive manufacturing. In this case, the additively manufactured structure shows an FCC two-phased microstructure, a yield strength of 534 MPa, and a decent wear resistance.

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“…According to Shen et al [ 201 ], the AM HEA produced using wire DED with seven different wires (one Fe wires, two Ni wires, two Al wires, one Co wire and one 304 stainless steel wire) had similar mechanical properties to those of the cast alloy made with the same wires as feedstock material for the AMF process. Other studies [ 202 , 203 ] have demonstrated that the use of three non-pure welding wires can form a single solid solution, as shown in Figure 14 .…”

Section: Additive Manufacturing (Am) Technologies Of High Entropy All...mentioning

confidence: 96%

Additive Manufacturing Technologies of High Entropy Alloys (HEA): Review and Prospects

2023

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Additive manufacturing (AM) technologies have gained considerable attention in recent years as an innovative method to produce high entropy alloy (HEA) components. The unique and excellent mechanical and environmental properties of HEAs can be used in various demanding applications, such as the aerospace and automotive industries. This review paper aims to inspect the status and prospects of research and development related to the production of HEAs by AM technologies. Several AM processes can be used to fabricate HEA components, mainly powder bed fusion (PBF), direct energy deposition (DED), material extrusion (ME), and binder jetting (BJ). PBF technologies, such as selective laser melting (SLM) and electron beam melting (EBM), have been widely used to produce HEA components with good dimensional accuracy and surface finish. DED techniques, such as blown powder deposition (BPD) and wire arc AM (WAAM), that have high deposition rates can be used to produce large, custom-made parts with relatively reduced surface finish quality. BJ and ME techniques can be used to produce green bodies that require subsequent sintering to obtain adequate density. The use of AM to produce HEA components provides the ability to make complex shapes and create composite materials with reinforced particles. However, the microstructure and mechanical properties of AM-produced HEAs can be significantly affected by the processing parameters and post-processing heat treatment, but overall, AM technology appears to be a promising approach for producing advanced HEA components with unique properties. This paper reviews the various technologies and associated aspects of AM for HEAs. The concluding remarks highlight the critical effect of the printing parameters in relation to the complex synthesis mechanism of HEA elements that is required to obtain adequate properties. In addition, the importance of using feedstock material in the form of mix elemental powder or wires rather than pre-alloyed substance is also emphasized in order that HEA components can be produced by AM processes at an affordable cost.

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Investigation of Co-Cr-Fe-Mn-Ni Non-Equiatomic High-Entropy Alloy Fabricated by Wire Arc Additive Manufacturing

Cited by 16 publications

References 46 publications

As-Cast Microstructures of High Entropy Alloys Designed to Be TaC-Strengthened

As-Cast Microstructures of High Entropy Alloys Designed to Be TaC-Strengthened

Wire and Arc Additive Manufacturing of a CoCrFeMoNiV Complex Concentrated Alloy Using Metal-Cored Wire—Process, Properties, and Wear Resistance

Additive Manufacturing Technologies of High Entropy Alloys (HEA): Review and Prospects

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