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Phase, microstructure and properties evolution of fine-grained W–Mo–Ni–Fe alloy during spark plasma sintering
Highlights ► Fine-grained W–Mo–Ni–Fe alloy was fabricated by HEBM assisted SPS technology. ► The HEBM-SPS technology degraded the sintering temperature of W–Mo–Ni–Fe alloy. ► The microstructure of W–Mo–Ni–Fe alloy consists of four different phases. ► The intergranular fracture is dominant for most fine-grained W–Mo–Ni–Fe alloy.
Abstract Fine-grained tungsten (W) heavy alloy containing molybdenum (Mo) with W particle sizes of less than 5μm were fabricated by spark plasma sintering (SPS) pre-milling W–2Mo–7Ni–3Fe powder at a lower temperature of 1000–1250°C. Phase, microstructure and mechanical properties evolution of W–Mo–Ni–Fe alloy during spark plasma sintering were studied in detail. As increasing sintering temperature, the hardness of the alloy decreased rapidly. However, bending strength of the alloy demonstrated a fall–rise–fall trend, and the maximum strength was obtained at 1150°C. The W–2Mo–7Ni–3Fe alloy microstructure was composed of white W-grain, gray W-rich structure, black γ-(Ni, Fe, W, Mo) binding phase, and deep-gray W-rich structure. The intergranular fracture along the W/W grain boundary is the main fracture modes of W–2Mo–7Ni–3Fe alloy.
Phase, microstructure and properties evolution of fine-grained W–Mo–Ni–Fe alloy during spark plasma sintering
Highlights ► Fine-grained W–Mo–Ni–Fe alloy was fabricated by HEBM assisted SPS technology. ► The HEBM-SPS technology degraded the sintering temperature of W–Mo–Ni–Fe alloy. ► The microstructure of W–Mo–Ni–Fe alloy consists of four different phases. ► The intergranular fracture is dominant for most fine-grained W–Mo–Ni–Fe alloy.
Abstract Fine-grained tungsten (W) heavy alloy containing molybdenum (Mo) with W particle sizes of less than 5μm were fabricated by spark plasma sintering (SPS) pre-milling W–2Mo–7Ni–3Fe powder at a lower temperature of 1000–1250°C. Phase, microstructure and mechanical properties evolution of W–Mo–Ni–Fe alloy during spark plasma sintering were studied in detail. As increasing sintering temperature, the hardness of the alloy decreased rapidly. However, bending strength of the alloy demonstrated a fall–rise–fall trend, and the maximum strength was obtained at 1150°C. The W–2Mo–7Ni–3Fe alloy microstructure was composed of white W-grain, gray W-rich structure, black γ-(Ni, Fe, W, Mo) binding phase, and deep-gray W-rich structure. The intergranular fracture along the W/W grain boundary is the main fracture modes of W–2Mo–7Ni–3Fe alloy.
Phase, microstructure and properties evolution of fine-grained W–Mo–Ni–Fe alloy during spark plasma sintering
Ding, L. (author) / Xiang, D.P. (author) / Li, Y.Y. (author) / Zhao, Y.W. (author) / Li, J.B. (author)
2011-12-05
5 pages
Article (Journal)
Electronic Resource
English
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