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High-density tungsten alloy, also referred to as tungsten-heavy alloy, is composed primarily of tungsten (with a mass fraction of 85% to 99%) and is alloyed with elements such as Ni, Cu, Fe to achieve densities between 16.5 and 19.0 g/cc. The most prevalent types include tungsten nickel copper and tungsten nickel iron alloys, where tungsten content ranges from 90% to 97%. The tungsten nickel copper variety is distinguished by its non-magnetic properties, in contrast to the magnetic nature of the tungsten nickel iron alloy. The latter is more commonly utilized due to its superior mechanical characteristics compared to the former.
The fabrication of high-density tungsten alloy typically follows the powder metallurgy pathway, which includes several steps:
Some items may be produced directly through the sintering process.
Sintering Process
For sintering high-density tungsten alloys, the liquid phase sintering technique is employed, usually setting the temperature 20 to 60 ℃ above the alloy's liquid phase. For W-Ni-Fe alloys, the sintering occurs at temperatures between 1500 and 1525 ℃, aiming for densities near theoretical values. The process typically lasts 60 to 90 minutes; durations beyond 120 minutes can degrade the alloy's qualities. Utilizing a higher sintering temperature for a shorter duration can enhance the tensile strength and ductility of the alloy. The cooling rate selection is crucial and depends on the alloy's Ni to Fe mass ratio. When this ratio avoids the formation of brittle compounds (typically between 2 and 4), the cooling rate can be adjusted without risking intermetallic compound formation, thus minimizing brittleness and porosity.
Heat Treatment
Post-sintering treatments include quenching, rapid cooling, atmospheric dehydrogenation, and surface hardening to minimize interface impurity segregation like P and S, mitigate hydrogen embrittlement, and tailor other alloy properties. These treatments refine the microstructure, enhance solid solution strengthening
, and can boost the alloy's strength significantly.
Plastic Deformation Processing
To further enhance mechanical properties, high-density tungsten alloys undergo various plastic deformation processes after sintering. Techniques such as forging, hydrostatic extrusion, hot extrusion, and hot rolling are applied, especially to produce large-diameter tungsten alloy core materials with high aspect ratios. Dehydrogenation through vacuum heat treatment before deformation reduces hydrogen embrittlement and strengthens phase boundaries, significantly improving the alloy's strength and ductility. The extent of deformation critically influences the
material's properties; as deformation increases, so does the strength and hardness, albeit at the expense of ductility. Recent developments in large deformation strengthening have shown significant improvements in mechanical properties, necessary for advanced applications like armor-piercing cores, which may require multiple forging and deformation cycles to achieve desired specifications.
Machining
Following plastic deformation, machining processes such as turning, milling, cutting, drilling, and polishing are selected based on the specific requirements of the design drawings to achieve the final product form.
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