Study on High-Power Laser Welding Process of 316L Stainless Steel with Nitrogen Shield

LEI Xiaowei; CHEN Liyang; ZHANG Yi; MA Zhaowei

Volume 38 Issue 3

Jun. 2023

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Development and Application of Materials > 2023 > 38(3): 24-30.

LEI Xiaowei, CHEN Liyang, ZHANG Yi, MA Zhaowei. Study on High-Power Laser Welding Process of 316L Stainless Steel with Nitrogen Shield[J]. Development and Application of Materials, 2023, 38(3): 24-30.

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Study on High-Power Laser Welding Process of 316L Stainless Steel with Nitrogen Shield

Luoyang Ship Material Research Institute, Luoyang 471023, China

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Received Date: October 07, 2022
Available Online: July 09, 2023

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Abstract

The laser welding test of 10 mm thick 316L austenitic stainless steel with nitrogen shield was carried out by high-power fiber laser in order to reduce pores. It is found that the porosity decreases significantly with nitrogen as shield gas than argon as shield gas, and that the weld section is narrower. The excellent "keyhole" welding joint is obtained. The width of the weld surface is about 2 mm; the width of the weld root about 1.5 mm. The weld face is slightly concave, and the depth-width ration is 5∶1. The results of RT and PT meet the requirements of NB/T 47013—2015 GradeⅠ. The results of mechanical and technological properties meet the requirements of NB/T 47014—2011. The impact performance test shows that the weld has excellent impact performance. The impact fracture is observed by microscopy, and the dimples are obvious, which is a typical ductile fracture. The weld zone is mainly dendritic austenite and precipitated phase, and the HAZ is mainly twinning austenite and δ-ferrite.
- 316L stainless steel,
- high-power fiber laser,
- nitrogen protection,
- properties of joint

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[1]	胡佩佩, 王春明, 胡席远. 光纤激光及其复合焊接研究进展[J]. 焊接, 2011(7): 40-45.
[2]	QUINTINO L, COSTA A, MIRANDA R, et al. Wel-ding with high power fiber lasers-A preliminary st-udy[J]. Materials & Design, 2007, 28(4): 1231-1237.
[3]	VERHAEGHE G, BARNES S. Low-porosity laser welding of 12.7mm thickness aerospace aluminum[C]//Proceedings of INALCO 2007,October 24-26, 2007, Tokyo.
[4]	LI C, MUNEHARUA K, TAKAO S, et al. Fiber la-serGMA hybrid welding of commercially pure titanium[J]. Materials & Design, 2009, 30(1): 109-114.
[5]	崔丽, 李晓延, 贺定勇, 等. 工业纯钛光纤激光-MIG复合焊接工艺及性能[J]. 焊接学报, 2009, 30(11): 33-36.
[6]	崔丽, 张彦超, 贺定勇, 等. 高功率光纤激光焊接的研究进展[J]. 激光技术, 2012, 36(2): 154-159.
[7]	KATAYAMA S, YOSHIDA D, MATSUNAWA A. Ef-fect of nitrogen shielding gas on laser weldability of austenitic stainless steel[J]. Journal of High Temperature Society, 2004, 30(2): 93-99.
[8]	ZHAO L, TIAN Z L, PENG Y. Porosity and nitrogen content of weld metal in laser welding of high nitrogen austenitic stainless steel[J]. ISIJ International, 2007, 47(12): 1772-1775.
[9]	WU S K, ZHENG K, ZOU J L, et al. A study of the behavior and effects of nitrogen take-up from protective gas shielding in laser welding of stainless steel[J]. Journal of Manufacturing Processes, 2018, 34: 477-485.

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