Refinement process and mechanisms of tungsten powder by high energy ball milling

“…When the milling speed increases to 500 rpm, Figure 2c shows that the tungsten powder appears in a flake structure in the micron-scale, and large amount of particles are in the nanoscale after 30 h of ball milling. The size of tungsten particles is in the range from the nanoscale to micron-scale with a D 50 of 50 nm, as shown in Reference [29]. The ball-milled tungsten powder is in the fracturing stage [29], and a large amount of nanoscale particles appear.…”

“…The size of tungsten particles is in the range from the nanoscale to micron-scale with a D 50 of 50 nm, as shown in Reference [29]. The ball-milled tungsten powder is in the fracturing stage [29], and a large amount of nanoscale particles appear. When the milling time increases to 60 h, the micron-scale particles are further refined and disappear gradually, as shown in Figure 2d.…”

“…When the milling time increases to 60 h, the micron-scale particles are further refined and disappear gradually, as shown in Figure 2d. The D 50 of the tungsten particles is 50 nm, as shown in Reference [29], which gives the particle size distribution.…”

“…Most particle sizes are in the micron-scale, as shown in Figure 3a, and the D 50 of the tungsten particles is 1050 nm. Few nanoscale particles fall off from the micron-scale particles with a flake structure, which means that the ball-milled tungsten powder is in the squeezing stage [29]. As the milling time increases, the micron-scale particles with the flake structure are further squeezed, and finally the particles are smashed and fractured.…”

Effect of Ball Milling Parameters on the Refinement of Tungsten Powder

“…When the milling speed increases to 500 rpm, Figure 2c shows that the tungsten powder appears in a flake structure in the micron-scale, and large amount of particles are in the nanoscale after 30 h of ball milling. The size of tungsten particles is in the range from the nanoscale to micron-scale with a D 50 of 50 nm, as shown in Reference [29]. The ball-milled tungsten powder is in the fracturing stage [29], and a large amount of nanoscale particles appear.…”

“…The size of tungsten particles is in the range from the nanoscale to micron-scale with a D 50 of 50 nm, as shown in Reference [29]. The ball-milled tungsten powder is in the fracturing stage [29], and a large amount of nanoscale particles appear. When the milling time increases to 60 h, the micron-scale particles are further refined and disappear gradually, as shown in Figure 2d.…”

“…When the milling time increases to 60 h, the micron-scale particles are further refined and disappear gradually, as shown in Figure 2d. The D 50 of the tungsten particles is 50 nm, as shown in Reference [29], which gives the particle size distribution.…”

“…Most particle sizes are in the micron-scale, as shown in Figure 3a, and the D 50 of the tungsten particles is 1050 nm. Few nanoscale particles fall off from the micron-scale particles with a flake structure, which means that the ball-milled tungsten powder is in the squeezing stage [29]. As the milling time increases, the micron-scale particles with the flake structure are further squeezed, and finally the particles are smashed and fractured.…”

Effect of Ball Milling Parameters on the Refinement of Tungsten Powder

“…The beginning of fracture can be attributed to increasing impact energy formed during mechanical milling at the high milling speed of 200 rpm. As known, the morphology of ductile metal particles changes to flake structure during the early stage of milling and those flake particles become both fractured and cold‐welded to each other in the second stage [12–14]. However, brittle ceramic particles do not show flake morphology.…”

Synthesis of SiC nanoparticles by central composite design response surface methodology directed mechanical milling

A study of nanocrystalline nickel powders developed via high-energy ball milling