Towards understanding the brittle–ductile transition in the extreme manufacturing 被引量：5

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摘要 The brittle–ductile transition(BDT) widely exists in the manufacturing with extremely small deformation scale, thermally assisted machining, and high-speed machining. This paper reviews the BDT in extreme manufacturing. The factors affecting the BDT in extreme manufacturing are analyzed, including the deformation scale and deformation temperature induced brittle-to-ductile transition, and the reverse transition induced by grain size and strain rate. A discussion is arranged to explore the mechanisms of BDT and how to improve the machinability based on the BDT. It is proposed that the mutual transition between brittleness and ductility results from the competition between the occurrence of plastic deformation and the propagation of cracks. The brittleness or ductility of machined material should benefit a specific manufacturing process, which can be regulated by the deformation scale, deformation temperature and machining speed.

作者 Tao Zhang Feng Jiang Hui Huang Jing Lu Yueqin Wu Zhengyi Jiang Xipeng Xu

机构地区 National and Local Joint Engineering Research Center for Intelligent Manufacturing Technology of Brittle Material Products Institute of Manufacturing Engineering School of Mechanical

出处《International Journal of Extreme Manufacturing》 EI 2021年第2期1-21,共21页 极端制造（英文）

基金 support from the National Natural Science Foundation of China (Grant No. 51835004)。

关键词 brittle–ductile transition deformation scale deformation temperature grain size strain rate

分类号 TB30 [一般工业技术—材料科学与工程]

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