Production and injection moulding of nickel aluminide powder: H.Paisley et al. (Brunel University, Uxbridge, Middlesex, UK.)

Abstract

Intermetallics have long been recognized as potential candidates for a variety of high-temperature structural applications to operate well beyond the operating temperatures of conventional materials due to their excellent oxidation and corrosion resistances. In this paper, we compare and contrast the mechanical properties such as yield strength, ultimate tensile strength, and tensile elongations of Ni3Al-based alloys, Fe3Al-based alloys, and FeAl alloys with several of the commercially available superalloys such as Haynes 214 (NiCrAlY), MA-956 (yttriadispersed FeCrAlY), and a FeNiCr alloy (HU steel) used in carburizing applications. Our comparisons clearly show that cast and wrought Ni3Al-based alloys exhibit superior mechanical properties over the commercially available alloys such as the FeNiCr HU steel and Haynes 214. Electrical resistivity of iron aluminides increases with the increase of aluminum content, and the electrical resistivities of Fe3Al- and FeAl-based alloys are 50–100% higher than those of commercially available heating-element materials. Processing problems associated with the melting and casting of intermetallics are discussed in light of their large, negative heats of formation; high-aluminum content of intermetallics; and the safe operating temperatures of crucible materials for melting them. A furnace-loading sequence enabled us to properly utilize the heat of reaction of intermetallics resulting in the development of the Exo-Melt™ process for melting and casting of intermetallics for a variety of structural applications. The Exo-Melt™ process allowed us to cast a wide variety of structural intermetallic parts using sand, centrifugal, and investment casting techniques, and a total of 15 000 kg of intermetallic parts were cast by the Exo-Melt™ process during 1995.