Micromechanical behavior and thermal stability of a dual-phase α+α’ titanium alloy produced by additive manufacturing

Formanoir, Charlotte de; Martin, Guilhem; Prima, Frédéric; Allain, Sébastien; Dessolier, Thibaut; Sun, Fan; Vivès, Solange; Hary, Benjamin; Bréchet, Y.; Godet, Stéphane

doi:10.1016/j.actamat.2018.09.050

Cited by 145 publications

(31 citation statements)

References 45 publications

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“…The progressive decomposition of the martensite during the partitioning of the two as-quenched microstructures lead to different mechanical properties. As reported by several authors [5]…”

Section: Mechanical Propertiessupporting

confidence: 63%

“…Then, fast cooling leads to the martensitic transformation of the stable high-temperature β phase into a V-enriched α' phase. When the quenching temperature is increased, the α' gets more enriched in aluminium and more depleted in vanadium [5]. For this purpose, with the rise of the quenching temperature, the chemical composition of the martensite is closer to the αroom temperature chemical composition and further from that of β. Consequently, α' martensite has an out-of-equilibrium composition that changes according to the solution treatment temperatures.…”

Section: Microstructurementioning

confidence: 99%

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Towards work-hardenability of Ti-6Al-4V through a quenching and partitioning approach

et al. 2020

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In this work, the work-hardening ability of Ti-6Al-4V alloy was investigated using a quenching and partitioning strategy on dual-phase Ti-6Al-4V samples. As recently reported [1], it is known that a sub-transus thermal treatment followed by water quenching are able to generate a dual phaseα + α’ microstructure with a remarkable work-hardening coupled with an interesting balance between strength and ductility. Based on this statement, several heat treatments at various subtransus temperatures were performed on as-forged Ti-6Al-4V. In such a way, the respective volume fraction of each phase along with the size and the distance to the equilibrium composition of the quenched martensite are taken as microstructural variables to decompose the work hardenability of dual-phase Ti-6Al-4V alloys into respective contributions. Then, annealing of the metastable α + α’ microstructure was performed to trigger the α’ martensite decomposition, involving a partitioning of the alloying elements. The present investigation was carried out on wrought material. The quenching and partitioning parameters led to a wide range of mechanical properties and associated work-hardening behaviour. The as-quenched and further annealed microstructures were characterized by Scanning Electron Microscopy (SEM). The resulting mechanical properties were discussed and compared to those of as-forged material.

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“…The progressive decomposition of the martensite during the partitioning of the two as-quenched microstructures lead to different mechanical properties. As reported by several authors [5]…”

Section: Mechanical Propertiessupporting

confidence: 63%

Section: Microstructurementioning

confidence: 99%

Towards work-hardenability of Ti-6Al-4V through a quenching and partitioning approach

et al. 2020

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“…Titanium and titanium alloys possess good comprehensive properties, such as low density, high specific strength, high temperature resistance, corrosion resistance, magnetic resistance, impact resistance, and good biocompatibility, having extensive application prospects in the aviation field [1,2]. However, the low hardness and poor tribological performance limit the applications of titanium alloys, such as the application of titanium alloy fasteners in aerospace [3,4].…”

Section: Introductionmentioning

confidence: 99%

Tribological Behavior of Titanium Alloy Treated by Nitriding and Surface Texturing Composite Technology

Kang

Wang

et al. 2019

Materials

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This study experimentally investigated the effect of surface textures on the tribological mechanism of nitrided titanium alloy (Ti–6Al–4V). The titanium alloy samples were nitrided at various temperatures ranging from 750 to 950 °C for 10 h in a plasma nitriding furnace. Then, surface textures were fabricated on the polished titanium alloy and plasma nitrided samples by laser process system. The surface roughness, microhardness, and constitution of samples treated by single nitriding and samples treated by composite technology were characterized. The tribological properties of the samples were investigated on a CSM ball-on-disc tribometer. The results show that plasma nitriding effectively enhances the wear resistance of the substrate. The wear rate decreases first and then increases with the increase of nitriding temperature, and the wear rate reaches the minimum at 900 °C. However, the increase in roughness caused by nitriding treatment leads to an increase in the friction coefficient. It is found that surface textures can obviously reduce the friction coefficient of the nitrided titanium alloy. In addition, it can also reduce the wear rate of titanium alloys after nitriding at 900 and 950 °C. It can be concluded that the nitriding and surface texturing combined treatment can obviously reduce the friction coefficient and wear rate at the nitriding temperatures of 900 and 950 °C. This is attributed to the combined effect of high hardness of nitride layers and the function of micro-trap for wear debris of surface textures.

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“…Многочисленные исследования микроструктуры титанового сплава Ti−6Al−4V, полученного методами аддитивных технологий либо подвергнутого электроннопучковой обработке [14,[21][22][23], показали, что при высокой скорости охлаждения титанового сплава Ti−6Al−4V атомы ванадия не успевают диффундировать к границам зерен или границам пластин α ′ -мартенсита, оставаясь в твердом растворе на основе α-Ti, и тем самым уменьшая вероятность образования β-фазы. При этом наличие ванадия в твердом растворе должно приводить к уменьшению параметров решетки α-Ti, а также к увеличению полных среднеквадратичных смещений атомов.…”

Section: результаты и их обсуждениеunclassified

Влияние охлаждения подложки на микроструктуру и фазовый состав изделий из титанового сплава Ti-6Al-4V, полученных методами аддитивных технологий

Перевалова¹,

Panin²,

Kazachenok³

2020

Журнал Технической Физики

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The microstructure, phase composition, and parameters of the -Ti based solid solution in the Ti-6Al-4V alloy obtained by 3D printing without cooling and with water cooling of the titanium substrate were studied by the methods of X-ray diffraction analysis, transmission diffraction and scanning electron microscopy, and optical metallography. It was found that the use of water cooling of the substrate leads to a decrease of the hereditary  grains sizes, an increase in the volume fraction of the  phase, a decrease in the volume fraction of the  phase and the total mean square displacement of atoms in the -Ti crystal lattice, as well as an increase in the elastic macrostrain of the samples.

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Micromechanical behavior and thermal stability of a dual-phase α+α’ titanium alloy produced by additive manufacturing

Cited by 145 publications

References 45 publications

Towards work-hardenability of Ti-6Al-4V through a quenching and partitioning approach

Towards work-hardenability of Ti-6Al-4V through a quenching and partitioning approach

Tribological Behavior of Titanium Alloy Treated by Nitriding and Surface Texturing Composite Technology

Влияние охлаждения подложки на микроструктуру и фазовый состав изделий из титанового сплава Ti-6Al-4V, полученных методами аддитивных технологий

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