纳米晶FeAl的结构、强度和韧性

M.A Morris-Muñoz , A Dodge , D.G Morris
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引用次数: 85

摘要

将晶粒细化到纳米晶水平被认为是一种提高强度同时增强延展性和韧性的方法。本研究采用机械合金化和热锻法制备了纳米晶块状FeAl。粉末在碾磨过程中迅速达到部分有序状态,低温退火足以使化学均匀化并使其完全有序。铣削过程中的污染导致碳化物和氧化物颗粒的形成,在加热过程中使细晶粒稳定。根据固结温度的不同,块状材料的晶粒尺寸为20nm ~ 100nm。硬度和抗压强度在此晶粒尺寸范围内变化不大。断裂韧性在中等小晶粒尺寸下保持较高,仅在最低温度下凝固。在一个合理的细晶粒尺寸范围内(40-100nm),可以实现良好的颗粒间结合和高密度,从而获得良好的强度和韧性。
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Structure, strength and toughness of nanocrystalline FeAl

Refining grain size to the nanocrystalline level has been suggested as a way of improving strength while enhancing ductility and toughness. In the present study, nanocrystalline bulk FeAl has been prepared by mechanical alloying and hot forging. Powders quickly reach a state of partial order during milling, and low temperature annealing is sufficient to chemically homogenise and give full order. Contamination during milling leads to the formation of carbide and oxide particles, which stabilise fine grains during heating. Bulk materials show grain sizes of 20nm to 100nm depending on the consolidation temperature. Hardness and compression strength show little change over this grain size range. Fracture toughness stays high down to moderately small grain sizes, falling only for consolidation at the lowest temperatures. There appears to be a reasonable range of fine grain sizes (40–100nm) where good interparticle bonding and high densities can be achieved leading to good strength and toughness.

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