Thermogravimetric Study of Oxide Spallation for Chromium-Rich Cast Cobalt-Based and Iron-Based Alloys Oxidized at High Temperature

Berthod, Patrice

doi:10.2174/1876503300902010061

Cited by 13 publications

(13 citation statements)

References 15 publications

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“…The cooling parts of these curves of mass gain, corrected from the air buoyancy variations and plotted versus temperature, can give indications about oxide spallation 17 . The deduced parameters were the temperatures at which oxide spallation started and the final mass variation during the whole cycle.…”

Section: Thermogravimetry Tests and Kinetic Exploitationsmentioning

confidence: 99%

Oxidation behaviour at 1100°C in air of 25 wt-% Cr-containing cobalt-based alloys containing high quantities of hafnium carbides

Berthod

Conrath

2016

Canadian Metallurgical Quarterly

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Hafnium, usually added to improve the high temperature oxidation resistance of alloys, allowed obtaining HfC carbides which are very efficient for the creepresistance. For that Hf must be added in particularly high quantities which may possibly influence the oxidation behavior. Three HfC-strengthened cast cobalt alloys were studied all along thermogravimetry tests at 1100°C. They were compared to similar but Hf-free ternary alloys. The mass variation were plotted according to {m × dm/dt = f(-m)} to specify all kinetic oxidation constants, and versus temperature to study the oxidation beginning during heating and the scale spallation during cooling. The presence of many HfC carbides obviously influences the high temperature oxidation: mass gain occurring sooner during heating, faster isothermal mass gains but better behavior in oxide scale spallation during cooling. This deterioration of oxidation behavior must be corrected to hope benefiting from the high creepresistance brought by this new type of strengthening.

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Section: Thermogravimetry Tests and Kinetic Exploitationsmentioning

confidence: 99%

Oxidation behaviour at 1100°C in air of 25 wt-% Cr-containing cobalt-based alloys containing high quantities of hafnium carbides

Berthod

Conrath

2016

Canadian Metallurgical Quarterly

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“…Since the used thermobalance was not a symmetric one, the effect of air buoyancy was analyzed and the mass gain at heating (and also at cooling) was corrected using a 'method already described in an earlier work (Ref. 20)'. For that the mass gains were plotted versus temperature instead of time, and corrected from the apparent mass variations due to the buoyancy variations of the heated air.…”

Section: High Temperature Oxidation Tests and Kinetic Exploitationsmentioning

confidence: 99%

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

Conrath¹,

Berthod²

2013

Corrosion Engineering, Science and Technology

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Mostly known to improve the high temperature oxidation resistance of superalloys, hafnium may also form carbides. Several per cents of Hf allow developing a dense carbide network to mechanically strengthen alloys. Here, the high temperature oxidation behaviour of three HfC containing cobalt alloys was characterised at all steps of a thermogravimetry test: heating, isothermal stage and cooling, compared with two Co-Cr-C model alloys. The five alloys were heated in synthetic air, maintained at 1200°C during 50 h and then cooled. The mass gains were plotted versus time or according to {mxdmldt^Kp-mx Kv) to specify the isothermal kinetic constants, or versus temperature to determine how oxidation acts during heating and oxide spallation occurs during cooling. Compared to the ternary alloys, the oxidation of the HfC reinforced alloys starts earlier but leads to lower mass gains during heating, the isothermal oxidation is faster and oxide spallation occurs later.

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“…The cooling parts were exploited and the oxidized samples were metallographically characterized. This helped to examine how some of the parameters characterizing the oxide spallation (temperature of spallation start, average rate of mass loss by spallation, and final mass loss [7]) varied versus the base element, the nature of the carbides which reinforce the alloys, and the total mass gain achieved before the cooling started.…”

Section: Introductionmentioning

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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Thermogravimetric Study of Oxide Spallation for Chromium-Rich Cast Cobalt-Based and Iron-Based Alloys Oxidized at High Temperature

Cited by 13 publications

References 15 publications

Oxidation behaviour at 1100°C in air of 25 wt-% Cr-containing cobalt-based alloys containing high quantities of hafnium carbides

Oxidation behaviour at 1100°C in air of 25 wt-% Cr-containing cobalt-based alloys containing high quantities of hafnium carbides

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

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

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