Ti和B含量对X100管线钢用埋弧焊熔敷金属冲击韧性的影响
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摘要
研究了不同Ti和B元素含量对自主研发的X100管线钢用埋弧焊焊丝和高碱度焊剂匹配焊接所得熔敷金属冲击性能的影响。结果表明,B元素含量小于0.0006%、Ti元素含量小于0.015%时,增加Ti和B元素,都有助于提高熔敷金属的冲击韧性;在B元素含量为0.0006%、Ti元素含量为0.015%时,熔敷金属冲击吸收能量-60℃达到最大值(101J)。B元素含量在0.0006%~0.001%之间,随着Ti,B元素含量的增加,熔敷金属冲击韧性都下降;B元素含量超过0.001%后,随着Ti含量的增加,熔敷金属冲击韧性快速降低。
The effects of titanium( Ti) and boron( B) on impact toughness of the deposited metal obtained by own researched high basic flux and wire for submerged arc welding X100 pipeline were studied. When the content of B was below 0. 000 6% and the content of Ti was below 0. 015%,the impact toughness of the deposited metal increased with increasing content of Ti and B. In the case of the content of B and Ti is 0. 000 6% and0. 015% respectively,the impact toughness of the deposited metal reaches the maximum( 101 J) at-60 ℃.While the content of B is in the scope of 0. 000 6%-0. 001%,the impact toughness of the deposited metal decreases with the content of Ti and B rising. Meanwhile the content of B beyond 0. 001%,the impact toughness of the deposited metal decreases rapidly.
The effects of titanium( Ti) and boron( B) on impact toughness of the deposited metal obtained by own researched high basic flux and wire for submerged arc welding X100 pipeline were studied. When the content of B was below 0. 000 6% and the content of Ti was below 0. 015%,the impact toughness of the deposited metal increased with increasing content of Ti and B. In the case of the content of B and Ti is 0. 000 6% and0. 015% respectively,the impact toughness of the deposited metal reaches the maximum( 101 J) at-60 ℃.While the content of B is in the scope of 0. 000 6%-0. 001%,the impact toughness of the deposited metal decreases with the content of Ti and B rising. Meanwhile the content of B beyond 0. 001%,the impact toughness of the deposited metal decreases rapidly.
引文
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[3]栗卓新,温培银,李国栋,等.一种X90/X100管线钢用高强度金属芯埋弧焊丝及其制备方法:中国CN20150406117[P].2015-07-10.
[4]裴新军,潘川,于俊川,等.X100管线钢用埋弧焊焊丝和烧结焊剂的开发[J].机械制造文摘——焊接分册,2013(5):15-17.
[5]纪彬彬.焊接材料对X100管线钢焊缝组织和性能的影响研究[D].沈阳:东北大学,2014.
[6]姜敏.高钢级X100管线钢工艺、组织与性能的研究[D].上海:上海大学,2014.
[7]Evans G M.Microstructure and properties of ferrite steel welds containing A1 and Ti[J].Welding Journal,1995,74(8):249s-261s.
[8]Ohkita S,Homma H,Tsushima S,et al. The effect of oxide inclusions on microstructure of Ti-B containing weld metal[J].Australian Welding Journal,1984,29(3):29-36.
[9]Evans G M.The effect of titanium on the microstructure and properties of C-Mn all-weld metal deposits[J].Welding Journal,1991,49(125):22-33.
[10]杨军,薛锦,段立宇.Ti-B微量合金化元素对焊缝金属韧性的影响机制[J].西安交通大学学报,1999,33(1):97-101.
[11]彭堃.高强Ti-4F钢中硼、磷竞争晶界偏聚及其对性能的影响[D].武汉:武汉科技大学,2014.