Effect of Mn and Ni on Microstructure and Impact Toughness of Submerged Arc Weld Metals 被引量：1

Effect of Mn and Ni on Microstructure and Impact Toughness of Submerged Arc Weld Metals

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摘要 The influences of Mn and Ni contents on the impact toughness and microstructure in the weld metals of high strength low alloy steels were studied. The objective of this study was to determine the optimum composition ranges of Mn and Ni to develop welding consumables with better resistance to cold cracking. The results indicated that Mn and Ni had considerable effect on the microstructure of weld metal, and both Mn and Ni promoted acicular ferrite at the expense of proeutectoid ferrite and ferrite side plates. Varying Ni content influenced the Charpy impact energy, the extent of which depended on Mn content. Based on the properties and impact resistance, the optimum levels of Mn and Ni were suggested to be 0.6%—0.9%,, and 2.5%—3.5%, respectively. Additions beyond this limit promoted the formation of segregation structures and other microstructural features, which may be detrimental to weld metal toughness. The influences of Mn and Ni contents on the impact toughness and microstructure in the weld metals of high strength low alloy steels were studied. The objective of this study was to determine the optimum composition ranges of Mn and Ni to develop welding consumables with better resistance to cold cracking. The results indicated that Mn and Ni had considerable effect on the microstructure of weld metal, and both Mn and Ni promoted acicular ferrite at the expense of proeutectoid ferrite and ferrite side plates. Varying Ni content influenced the Charpy impact energy, the extent of which depended on Mn content. Based on the properties and impact resistance, the optimum levels of Mn and Ni were suggested to be 0.6%—0.9%,, and 2.5%—3.5%, respectively. Additions beyond this limit promoted the formation of segregation structures and other microstructural features, which may be detrimental to weld metal toughness.

作者杨立军王会超张智张津孟宪群黄世明白璆熠

机构地区 School of Materials Science and Engineering School of Mechanical Engineering Tianjin Metallurgy Group Flourish Steel Industrial Co.

出处《Transactions of Tianjin University》 EI CAS 2015年第6期562-566,共5页 天津大学学报（英文版）

关键词 deposited metal microstructure toughness composition balancing 下线服务迁移

分类号 TG445 [金属学及工艺—焊接]

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参考文献12

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Transactions of Tianjin University

2015年第6期

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Effect of Mn and Ni on Microstructure and Impact Toughness of Submerged Arc Weld Metals 被引量：1

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