The phenomena of die wall lubricated warm compaction of non-lubricant admixed iron powders were researched, and its mechanism of densification was discussed. Water atomized powder obtained from the Wuhan Iron and Stee...The phenomena of die wall lubricated warm compaction of non-lubricant admixed iron powders were researched, and its mechanism of densification was discussed. Water atomized powder obtained from the Wuhan Iron and Steel Corporation was used. With compacting and sintering, compared with cold compaction, the density of warm compacted samples increases by 0.070.22 g/cm3 at the same pressed pressure. The maximum achievable green density of warm compacted samples is 7.12 g/cm3 at 120 ℃, and the maximum sintered density is 7.18 g/cm3 at 80 ℃. Compared with cold compaction, the ejection force of warm compaction is smaller; the maximum discrepancy is about 7 kN. The warm compacted mechanism of densification of ironpowders can be obtained: heating the powder contributes to improving plastic defosmation of powder particles, and accelerating the mutual filling and rearrangement of powder particles.展开更多
文摘The phenomena of die wall lubricated warm compaction of non-lubricant admixed iron powders were researched, and its mechanism of densification was discussed. Water atomized powder obtained from the Wuhan Iron and Steel Corporation was used. With compacting and sintering, compared with cold compaction, the density of warm compacted samples increases by 0.070.22 g/cm3 at the same pressed pressure. The maximum achievable green density of warm compacted samples is 7.12 g/cm3 at 120 ℃, and the maximum sintered density is 7.18 g/cm3 at 80 ℃. Compared with cold compaction, the ejection force of warm compaction is smaller; the maximum discrepancy is about 7 kN. The warm compacted mechanism of densification of ironpowders can be obtained: heating the powder contributes to improving plastic defosmation of powder particles, and accelerating the mutual filling and rearrangement of powder particles.