Abstract
Tungsten heavy alloys are two-phase metal matrix composites that include W–Ni–Fe and W–Ni–Cu. The significant feature of these alloys is their ability to acquire both strength and ductility. In order to improve the mechanical properties of the basic alloy and to limit or avoid the need for post-processing techniques, other elements are doped with the alloy and performance studies are carried out. This work focuses on the developments through the years in improving the performance of the classical tungsten heavy alloy of W–Ni–Fe through doping of other elements. The influence of the percentage addition of rare earth elements of yttrium, lanthanum, and their oxides and refractory metals such as rhenium, tantalum, and molybdenum on the mechanical properties of the heavy alloy is critically analyzed. Based on the microstructural and property evaluation, the effects of adding the elements at various proportions are discussed. The addition of molybdenum and rhenium to the heavy alloy gives good strength and ductility. The oxides of yttrium, when added in a small quantity, help to reduce the tungsten’s grain size and obtain good tensile and compressive strengths at high temperatures.
Highlights
Tungsten, as a metal, is unique due to its high melting point, high density, good thermal conductivity, and high elastic modulus [1]
Grain size is a significant factor in obtaining a good yield strength of the alloy
With a reduced grain size, the probability of moving the dislocations formed at the boundaries to induce plasticity is lower [90]
Summary
As a metal, is unique due to its high melting point, high density, good thermal conductivity, and high elastic modulus [1]. Pure tungsten requires a very high sintering temperature, in the range of 1600 to 2000 ◦ C, depending upon the tungsten particle size and the sintering method to get fully densified [21,22,23] To overcome this difficulty in sintering and to introduce a ductile phase into the alloy, elements with a lower melting point and having preferably good solubility with tungsten are mixed with the base metal. New processing methods like laser melting deposition (LMD) [41,42] and selective laser melting (SLM) [43,44] have been attempted to produce tungsten heavy alloys These additive manufacturing techniques are used to fabricate near-net-shaped parts of high complexity. An understanding of the effects of alloying these elements in different proportions will help us to optimize the process of designing materials for specific requirements
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