Microstructures and mechanical properties of welding joint of Q235/1Cr18Ni9Ti dissimilar steel with ultra-narrow-gap welding

被引：0

作者：

Zheng S. ^{[1
]}

Li Y. ^{[1
]}

Shi W. ^{[2
]}

Zhao X. ^{[1
]}

机构：

[1] Lanzhou Jiaotong University, Lanzhou

[2] Lanzhou LS Test Technology Co., Ltd., Lanzhou

来源：

Hanjie Xuebao/Transactions of the China Welding Institution | 2019年 / 40卷 / 08期

关键词：

Dissimilar steel; Mechanical property; Microstructure; Ultra-narrow-gap welding;

D O I：

10.12073/j.hjxb.2019400206

中图分类号：

学科分类号：

摘要：

Dissimilar steels with thick wall welded by ultra-narrow-gap welding have some extra advantages in increasing welding efficiency, reducing production costs, improving mechanical properties of joint. In the paper, microstructures and mechanical properties of welding joint of Q235/1Cr18Ni9Ti dissimilar steels with ultra-narrow-gap welding were studied. The results indicated that welding pool of backing weld solidified with the FA solidification mode, and solidification microstructures were made of fine equiaxed grains of austenites and a few dendritic ferrites. Welding pool of filling bead and cover pass near the transition region of fusion solidified with the AF solidification mode, solidification microstructures are made of cellular austenites and ferrites between cellular austenites, welding pool of filling bead and cover pass far away from the transition region of fusion can solidify with the FA solidification mode, and solidification microstructures were made of columnar dendrite of austenites and a few skeleton ferrites. Ultra-narrow-gap welding joint of dissimilar steel had excellent tensile strength and bending property, and the heat affected zone near the Q235 base metal can not soften. Impact toughness of the transition region of fusion and the heat affected zone near the Q235 base metal was better than that of weld zone. © 2019, Editorial Board of Transactions of the China Welding Institution, Magazine Agency Welding. All right reserved.

引用

页码：38 / 43

页数：5

共 11 条

[1] Dupont J.N., Microstructural evolution and high temperature failure of ferritic to austenitic dissimilar welds, International Materials Reviews, 57, 4, pp. 208-234, (2012)
[2] Zheng Y., Cai Z., He Y., Et al., Study on the influence of fusion ratio on carbon migration phenomenon in the narrow gap welding of dissimilar steels, Journal of Mechanical Engineering, 52, 12, pp. 74-80, (2016)
[3] Nelson T.W., Lippold J.C., Mills M.J., Nature and evolution of the fusion boundary in ferritic-austenitic dissimilar metal welds-part2: on-cooling transformations, Welding Journal, 10, pp. 267-277, (2000)
[4] Du B., Li Y., Jia Y., Embrittlement and fracture behavior of fusion zone in dissimilar steel welded joints, Transactions of the China Welding Institution, 19, 1, pp. 8-12, (1998)
[5] Verena W., Bernhard D., Silvia H., Et al., Investigations of dissimilar welds of the temperature steels P91 and PM2000, Fusion Engineering and Design, 88, pp. 2539-2542, (2013)
[6] Ming H., Zhang Z., Wang J., Et al., Microstructural characterization of an SA508-309L/308L-316L domestic dissimilar metal welded safe-end joint, Materials Characterization, 97, pp. 101-115, (2014)
[7] Wang R., Wang F., Tian H., Et al., Analysis of dissimilar steels welded joints, Transactions of the China Welding Institution, 34, 2, pp. 58-62, (2013)
[8] Fan C., Sun Q., Zhao B., Et al., Stability of double wires narrow-gap gas metal arc welding, Journal of Mechanical Engineering, 45, 7, pp. 265-269, (2009)
[9] Zheng S., Shi Z., Han F., Et al., Ultra-narrow-gap weld of 1Cr18Ni9Ti stainless steel with constricted arc by ultra-fine granular flux, Transactions of the China Welding Institution, 36, 2, pp. 67-70, (2015)
[10] Zheng S., Li X., Che J., Et al., Weld formation and heating mechanism in ultra-narrow gap with constricted arc by ultra-fine granular flux, China Welding, 21, 1, pp. 39-43, (2012)

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