Kinetics of high temperature oxidation of chromium rich HfC reinforced cobalt based alloys

Conrath, Élodie; Berthod, Patrice

doi:10.1179/1743278213y.0000000105

Cited by 9 publications

(29 citation statements)

References 15 publications

(24 reference statements)

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“…Thus, in chromium-rich iron-based alloys too, Hf additions in sufficiently great quantities allowed the development of numerous HfC carbides in the interdendritic spaces, mainly with a eutectic nature and a script-like shape but also with a blocky shape for some of them. This is a common point with the similar Hf-containing cobaltbased alloys [14] and Hf-containing nickel-based alloys [15] which both presented also these repartition and shape of eutectic HfC carbides. However the presence of obviously blocky pre-eutectic HfC was met essentially in the cobalt alloys.…”

Section: Discussionsupporting

confidence: 62%

“…As for these Hf-rich cobalt-based and nickel-based alloys previously elaborated by foundry and tested in oxidation at the same temperature the presence of so high quantities of hafnium influences the high temperature oxidation behavior of the corresponding Fe-25Cr-C base alloys. The kinetics were accelerated by the presence of hafnium, less than observed for the cobalt-based alloys [14] but more for the nickel-based alloys [15]. By comparison with the nickel-based alloys for which the scale thicknesses were rather homogeneous, this is due to the formation of thick multi-constituted oxide islands.…”

Section: Discussionmentioning

confidence: 78%

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High Temperature Oxidation of HfC-Containing Chromium-Rich Iron-Based Alloys

Berthod

Conrath

2014

Oxid Met

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International audienceThree HfC-containing iron-based alloys were successfully prepared in the foundry. The alloys, all containing 25 wt% Cr, 0.25 or 0.50 wt% C and 3.7 to 5.6 wt% Hf, are characterized by a dendritic matrix and the presence of interdendritic script-like HfC carbides. These alloys were subjected to thermogravimetry test in air at 1,200 A degrees C for 46 h. Such exposure at this high temperature did not significantly modify the characteristics of the bulk HfC carbides. In contrast the presence of hafnium led to non-parabolic oxidation kinetics and fast mass gain rates, by comparison with similar Hf-free ternary alloys. The scales formed all over the samples' surfaces were never composed exclusively of chromia and iron oxides or (iron, chromium) oxides were present in significant quantities. Some particles of hafnium oxides were also present in the external scales. A subsurface zone in which the HfC carbides were in situ replaced by hafnium oxides developed from the oxidation front. Catastrophic oxidation started in several locations and threatened to expand all around the samples beyond the stage duration. The high temperature oxidation behavior of these HfC-containing iron-based alloys appeared better than their cobalt-based counterparts, but worse than their nickel-based counterparts, for the same conditions of oxidation test

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Section: Discussionsupporting

confidence: 62%

Section: Discussionmentioning

confidence: 78%

High Temperature Oxidation of HfC-Containing Chromium-Rich Iron-Based Alloys

Berthod

Conrath

2014

Oxid Met

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“…Indeed they are globally oxidation resistant but probably also corrosion resistant thanks to their high chromium contents, and creep resistant thanks to the good stability of the eutectic HfC carbides at high temperature, a creep-resistance which may be better than for TaC-reinforced cobalt-based alloys for which the fragmentation of the TaC was more severe for similar duration at the same temperature [20]. In contrast with similar cobalt-based alloys containing also high fractions of HfC carbides but not so resistant against high temperature oxidation [21], these alloys are thus ready to be tested at high temperature, without protective coating, to verify the later point: notably specifying their resistance against creep deformation. Values of the linear constant k l , of the parabolic constant k p and of the constant chromia volatilization constant k v , the two later ones being derived from the m × dm/dt = f(m) plots.…”

Section: Resultsmentioning

confidence: 99%

Kinetics of High Temperature Oxidation and Chromia Volatilization for HfC-Containing Nickel-Based Alloys

Conrath

Berthod

2013

Oxid Met

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Many cast chromia-forming nickel-based superalloys are reinforced by carbides. In such alloys the primary chromium carbides or tantalum carbides rapidly lose their strengthening effect in service at high temperature because of decrease in volume fraction and morphology evolution. Other carbides, HfC for example, are more stable at high temperature and they can be candidates for the reinforcement of this type of superalloy. In this work, three nickel-based alloys containing 25 wt.%Cr, 0.25 or 0.50 wt.%C, and Hf with contents high enough (3.7 and 5.6 wt.%) to promote the formation of numerous primary HfC carbides, were elaborated by foundry. They were tested in oxidation by air during 46h at 1200°C, with thermogravimetry measurement and metallographic characterization. All the mass gain curves obtained are parabolic and the oxidation rates of the studied alloys are only slightly faster than for corresponding ternary nickel alloys containing the same chromium and carbon quantities. The obtained values of the parabolic constant k p and of the chromia volatilization constant k v , deduced by applying the {m × dm/dt = k p-k v × m} method, are typical of a chromia-forming behavior. However, small quantities of HfO 2 and NiCrTaO 4 oxides are noticed in addition to the chromia scale. In the bulk, the volume fraction and morphology of the HfC carbides only changed a little.

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“…The cobalt-based alloys, previously studied in isothermal oxidation [8], were prepared by casting. The pure elements (Alfa Aesar, purity > 99.9%) were melted together in a High Frequency induction furnace (CELES) under an inert atmosphere of 300millibars of pure Argon.…”

Section: The Studied Alloysmentioning

confidence: 99%

Oxide Spallation During Post-isothermal High Temperature Oxidation Cooling of Cr-rich Cast Alloys Highly Alloyed with Hf

Conrath¹,

Berthod²

2016

TOMSJ

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Cobalt, nickel and iron-based alloys containing 25wt.%Cr and strengthened either by chromium carbides or by HfC were oxidized at 1000, 1100 and 1200°C to obtain external oxide scales. The spallation of these oxides during the post-oxidation cooling was studied by exploiting the cooling part of the thermogravimetry curves. The best resistant alloys against scale spallation were the iron-based alloys which did not lose oxide. The nickel-based alloys well behaved too. The worst alloys were the cobalt alloys, principally due to the complex composition of the oxide scales. Beside the base element, the thickness of the oxide was also identified as a major parameter. The presence of Hf with contents much higher than usual was also beneficial for the resistance against spallation.This is an open access article licensed under the terms of the Creative Commons Attribution-Non-Commercial 4.0 International Public License (CC BY-NC 4.0) (https://creativecommons.org/licenses/by-nc/4.0/legalcode), which permits unrestricted, non-commercial use, distribution and reproduction in any medium, provided the work is properly cited.

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Kinetics of high temperature oxidation of chromium rich HfC reinforced cobalt based alloys

Cited by 9 publications

References 15 publications

High Temperature Oxidation of HfC-Containing Chromium-Rich Iron-Based Alloys

High Temperature Oxidation of HfC-Containing Chromium-Rich Iron-Based Alloys

Kinetics of High Temperature Oxidation and Chromia Volatilization for HfC-Containing Nickel-Based Alloys

Oxide Spallation During Post-isothermal High Temperature Oxidation Cooling of Cr-rich Cast Alloys Highly Alloyed with Hf

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