Feasibility of Cast and Wrought Co-Al-W-X Gamma-Prime Superalloys

Erin T. McDevitt

doi:10.4028/www.scientific.net/MSF.783-786.1159

Paper Titles

Role of Ti/Al Ratio of Ti-Al-X (X=Cr, Nb, Ta and W) Intermetallics on High Temperature Tensile Properties
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Evaluation of Tool Performance of Recycle-Type Fe₃Al Based Alloy for Pure Cu
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Effects of Geometric Constraint on Solidification Microstructural Development of Peritectic TiAl Alloys
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High Temperature Tensile Behavior of Directionally Solidified MAR-M247 Superalloy
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Feasibility of Cast and Wrought Co-Al-W-X Gamma-Prime Superalloys
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Metals for High Temperature Applications under Extreme Conditions – Development and Testing
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Phase Equilibrium between B2 Aluminide NiAl and Nb-Mo bcc Solid Solution Phase
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Spark Plasma Heat Treated ZrB₂-SiC and HfB₂-SiC Composites
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Mechanical Behaviors of Alloy 617 with Varied Strain Rates at High Temperatures
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HomeMaterials Science ForumMaterials Science Forum Vols. 783-786Feasibility of Cast and Wrought Co-Al-W-X...

Feasibility of Cast and Wrought Co-Al-W-X Gamma-Prime Superalloys

Abstract:

In 2006, J. Sato et al. discovered the L1₂ gamma-prime phase in the Co-Al-W alloy system. Since that time there has been a significant academic effort to characterize and understand the thermodynamics, the structure, and properties of alloys in this system. That work has shown that such alloys have promise as next generation high temperature materials due to the ability to engineer a high gamma-prime content alloy with a higher gamma prime solvus and higher melting point than many Ni-base gamma-prime strengthened alloys. Furthermore, a relatively narrow range of solidification temperature and large range of temperature between the gamma-prime solvus and the solidus are two characteristics that suggest cast and wrought versions of the alloys should be able to be manufactured routinely. However, to date all published research has been on small, laboratory scale samples typically less than about 2 kg, cast and hot rolled or cast as single crystals. This paper describes ATI’s experience in assessing the feasibility of manufacturing a cast and wrought billet product in the Co-Al-W-X alloy system. Three 22 kg heats were produced to examine a small range of alloy compositions of potential commercial interest: Co-9Al-9W, Co-9Al-9W-2Ti, and Co-9Al-9W-2Ti-0.02B, respectively. Each heat was vacuum induction melted and vacuum arc remelted. The as-cast microstructure will be presented. Ingots were homogenized and hot worked. The microstructure at various stages of production are shown and hot working behavior is described.

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Periodical:

Materials Science Forum (Volumes 783-786)

Pages:

1159-1164

DOI:

https://doi.org/10.4028/www.scientific.net/MSF.783-786.1159

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Cite this paper

Online since:

May 2014

Authors:

Erin T. McDevitt

Keywords:

Billetizing, Cast, Cobalt, Ductility, Gamma-Prime, Ingot Metallurgy, Superalloy, Vacuum Arc Remelting, Vacuum Induction Melting, Wrought Alloys

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