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Compaction of Ti–6Al–4V powder using high velocity compaction technique
Graphical abstract Display Omitted
Highlights We compacted Ti–6Al–4V powder by HVC technique. As impact force rises up, the green density of the compacts increases gradually. At impact force 1.857kN relative sintered density of the compacts reaches 99.88%. Spring back of the green compact’s decreases gradually with increasing impact force. Mechanical properties of the samples increases with increasing impact force.
Abstract High velocity compaction technique was applied to the compaction of pre-alloyed, hydride–dehydride Ti–6Al–4V powder. The powder was pressed in single stroke with a compaction speed of 7.10–8.70ms−1. When the speed was 8.70ms−1, the relative density of the compacts reaches up to 85.89% with a green density of 3.831gcm−3. The green samples were sintered at 1300°C in Ar-gas atmosphere. Scanning electron microscope (SEM) was used to examine the surface of the sintered samples. Density and mechanical properties such as Vickers micro hardness and bending strength of the powder samples were investigated. Experimental results indicated that with the increase in impact force, the density and mechanical properties of the compacts increased. The sintered compacts exhibited a maximum relative density of 99.88% with a sintered density of 4.415gcm−3, hardness of 364–483 HV and the bending strength in the range of 103–126.78MPa. The springback of the compacts decreased with increasing impact force.
Compaction of Ti–6Al–4V powder using high velocity compaction technique
Graphical abstract Display Omitted
Highlights We compacted Ti–6Al–4V powder by HVC technique. As impact force rises up, the green density of the compacts increases gradually. At impact force 1.857kN relative sintered density of the compacts reaches 99.88%. Spring back of the green compact’s decreases gradually with increasing impact force. Mechanical properties of the samples increases with increasing impact force.
Abstract High velocity compaction technique was applied to the compaction of pre-alloyed, hydride–dehydride Ti–6Al–4V powder. The powder was pressed in single stroke with a compaction speed of 7.10–8.70ms−1. When the speed was 8.70ms−1, the relative density of the compacts reaches up to 85.89% with a green density of 3.831gcm−3. The green samples were sintered at 1300°C in Ar-gas atmosphere. Scanning electron microscope (SEM) was used to examine the surface of the sintered samples. Density and mechanical properties such as Vickers micro hardness and bending strength of the powder samples were investigated. Experimental results indicated that with the increase in impact force, the density and mechanical properties of the compacts increased. The sintered compacts exhibited a maximum relative density of 99.88% with a sintered density of 4.415gcm−3, hardness of 364–483 HV and the bending strength in the range of 103–126.78MPa. The springback of the compacts decreased with increasing impact force.
Compaction of Ti–6Al–4V powder using high velocity compaction technique
Khan, Dil Faraz (author) / Yin, Haiqing (author) / Li, He (author) / Qu, Xuanhui (author) / Khan, Matiullah (author) / Ali, Shujaat (author) / Iqbal, M. Zubair (author)
2013-03-02
5 pages
Article (Journal)
Electronic Resource
English
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