Wrought cobalt-base superalloys are used extensively in gas turbine engines because of their excellent high-temperature creep and fatigue strengths and resistance to hot corrosion attack. In addition, the unique character of the oxide scales that form on some of the alloys provides outstanding resistance to high-temperature sliding wear. This article provides a review of the evolutionary development of wrought cobalt-base alloys in terms of alloy design and physical metallurgy. The topics include solid-so-lution strengthening, carbide precipitation characteristics, and attempts to introduce age hardening. The use of PHACOMP to enhance thermal stability characteristics and the incorporation of rare-earth ele-ments to improve oxidation resistance is also reviewed and discussed. The further development of cobalt-base superalloys has been severely hampered by past political events, which have accentuated the strategic vulnerability of cobalt as a base or as an alloying element. Consequently, alternative alloys have been developed that use little or no cobalt. One such alternative, Haynes® 230TMalloy, is discussed briefly.
[1]
H. M. Tawancy,et al.
On the fcc → hcp transformation in a cobalt-base superalloy (Haynes alloy No. 25)
,
1986
.
[2]
H. M. Tawancy,et al.
Development of a New Nickel-Base Superalloy
,
1984
.
[3]
A. Ninham.
The effect of mechanical properties on erosion
,
1988
.
[4]
H. M. Tawancy.
Long-term ageing characteristics of Hastelloy alloy X
,
1983
.
[5]
P. Beck,et al.
TERNARY LAVES PHASES WITH TRANSITION ELEMENTS AND SILICON
,
1961
.
[6]
J. J. Barnes,et al.
A Burner Rig Investigation of the Hot Corrosion Behavior of Several Wrought Superalloys and Intermetallics
,
1991
.
[7]
D. Woodford.
Cavitation-erosion-lnduced phase transformations in alloys
,
1972
.
[8]
K. Ludema,et al.
Wear of materials
,
1977
.
[9]
C. Sims.
A contemporary view of cobalt-base alloys
,
1969
.