Oxidation of Thin Nickel-Based Superalloy Specimens: Kinetics Study and Mechanical Integrity

Romain, Charles; Texier, Damien; Desgranges, Clara; Cormier, Jonathan; Knittel, S.; Monceau, Daniel; Delagnes, Denis

doi:10.1007/s11085-021-10075-2

Cited by 8 publications

(5 citation statements)

References 22 publications

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“…This can cause a ''breakaway'' phenomenon, that is, the formation of a less protective oxide layer formed from the other elements of the alloy, and faster growing by several orders of magnitude. 37,38 In the case of a titanium alloy, another thin wall effect exists, as oxygen diffuses in large quantities into the metal under the oxide layer and weakens it. 12 This effect is, of course, more dangerous on a thin wall.…”

Section: Effect Of Complex Geometries and Thin Wallsmentioning

confidence: 99%

High Temperature Oxidation of Additively Manufactured Structural Alloys

Monceau

Vilasi

2022

JOM

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Metal alloys produced by additive manufacturing have specifi c microstruc tures and compositions. Their microstructure is generally out of equilibrium, textured, and inhomogeneities can be observed. They can have pores and nano-inclusions. The contents of volatile elements may deviate from the nominal composition. These alloys often experience signifi cant interna! stresses and present fairly rough surfaces depending on the process used. Hipping these alloys modifies their microstructure and defects. This literature review shows that open porosity can lead to much higher oxidation kinetics than dense materials, with very deep interna! oxide penetrations. Neverthe less, when fabricated with optimized parameters, LBM-or EBM-alloys, such as TA6V, 718, or 316L, can behave as well as, or even better than, wrought alloys. The roughness of the surface is not necessarily problematic, but it can lead to local breakaway phenomena and premature spalling on some alloys. It has been verifi ed that the nature of the grain boundaries strongly affects the intergranular oxidation. The effect of chemical segregations on the protective nature of the outer oxide layer has also been reported. Today, too few studies have been devoted to the effect of raw and pre-oxidized surface states after HIP on cyclic oxidation and on hot corrosion of these alloys.

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Section: Effect Of Complex Geometries and Thin Wallsmentioning

confidence: 99%

High Temperature Oxidation of Additively Manufactured Structural Alloys

Monceau

Vilasi

2022

JOM

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“…This approach simpli es the variables to be considered, facilitating phenomena understanding; however, it may not re ect the complexities of real application conditions. Some oxidation features have been reported critical for tensile and fatigue life of this alloy system and others, including carbides dissolution, oxide scale thickness, and internal oxidation depth [13][14][15][16][17]. A correlation between the internal oxidation depth and fatigue life reduction was reported for ME3, U720, and Rene 104 [15,16].…”

Section: Introductionmentioning

confidence: 99%

Influence of Alloy 625 Manufacturing Process on 950˚C Oxidation Behavior in Air and Post-Oxidation High-Cycle Fatigue Performance

Nope,

Wang,

Gleeson

2024

Preprint

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This study investigates the effect of the Alloy 625 manufacturing process on the high-cycle fatigue (HCF) performance of oxidized samples. Conventional manufacturing processes (wrought and casting) and additive manufacturing (AM) processes (laser powder bed fusion and direct energy deposition) were studied. Results of Alloy 625 isothermal oxidation at 950°C in air revealed that AM samples showed faster oxidation kinetics and enhanced intergranular oxidation (IGO) with associated voids; the latter two were attributed partially to the alloy's greater amount of interstitial oxygen compared to conventional manufacturing processes. The HCF results showed that oxidized AM samples have a shorter life than oxidized wrought counterparts, where the earlier crack initiation in the oxidized AM samples is attributed to greater oxidation-induced subsurface degradation. This subsurface degradation includes the enhanced IGO and associated voids.

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“…The formation of the Al 2 O 3 scale and intrusions, together with the interdiffusion with the substrate, causes aluminum depletion in the coating. In thin products, this may bring the Al concentration down to a critical level where Al 2 O 3 is no longer stable [30,[32][33][34][35][36][37][38][39]. Other oxides may then form at the oxide/gas and metal/oxide interfaces on large regions.…”

Section: Introductionmentioning

confidence: 99%