基于有限元的激光增材过程熔化热积累模拟
Finite element simulation of melting heat accumulation in laser additive manufacturing
-
摘要: 采用高斯体热源对H13模具钢的单层多道选区激光熔化温度场进行了模拟.研究了S型扫描时,不同扫描长度的热积累及其对熔池形貌的影响,通过试验验证了模拟结果的正确性,并提出了减小热积累的措施.结果表明,扫描长度越短,热积累越严重,熔池在第5道时的最高温度越高.以不同扫描长度的熔化长度、熔深和熔宽的平均增长率为标准可知,它们的平均增长率分别为32.1%,27.1%和13.5%.采用单向扫描的方式可减小热积累的程度,与S形扫描路径相比,当扫描长度为6 mm时,第5道的最高温度由3 115.6℃降低到2 881.51℃,但完成相同道次的扫描所用时间是S型扫描的两倍.Abstract: In this paper, the temperature field of single-layer and multi-beads Selective Laser Melting (SLM) of H13 die steel was simulated by using Gauss body heat source. The heat accumulation of different scanning lengths and its effect on the morphology of molten pool during S-type scanning were studied. The correctness of the simulation was verified by experiments and an improved measure was proposed to reduce the heat accumulation. The results show that the shorter the scanning length, the more serious of the heat accumulation, and accordingly the higher the maximum temperature of the molten pool in the fifth bead. By taking the average growth rates of melting length, melting depth and melting width under different scanning lengths as the standard, the average growth rates of them were 32.1%, 27.1% and 13.5%, respectively. The maximum temperature of the fifth bead was reduced from 3 115.6℃ to 2 881.51℃ when employed a unidirectional scanning at 6 mm. However, the time of completing the same pass is twice as much as that of the S-type scanning.
-
Keywords:
- H13 die steel /
- selective laser melting /
- temperature field /
- heat accumulation
-
-
[1] Ding X, Wang L. Heat transfer and fluid flow of molten pool during selective laser melting of AlSi10Mg powder:simulation and experiment[J]. Journal of Manufacturing Processes, 2017, 26:280-289. [2] Cheng B, Shrestha S, Chou K. Stress and deformation evaluations of scanning strategy effect in selective laser melting[J]. Additive Manufacturing, 2016, 12:240-251. [3] Shi X, Ma S, Liu C, et al. Parameter optimization for Ti-47Al-2Cr-2Nb in selective laser melting based on geometric characteristics of single scan tracks[J]. Optics&Laser Technology, 2017, 90:71-79. [4] Denlinger E R, Pan M. Effect of stress relaxation on distortion in additive manufacturing process modeling[J]. Additive Manufacturing, 2016, 12:51-59. [5] Li Y, Gu D. Parametric analysis of thermal behavior during selective laser melting additive manufacturing of aluminum alloy powder[J]. Materials&Design, 2014, 63(2):856-867. [6] Wu J, Wang L, An X. Numerical analysis of residual stress evolution of AlSi10Mg manufactured by selective laser melting[J]. Optik-International Journal for Light and Electron Optics, 2017, 137:65-78. [7] Hussein A, Hao L, Yan C, et al. Finite element simulation of the temperature and stress fields in single layers built without-support in selective laser melting[J]. Materials&Design, 2013, 52(24):638-647. [8] Hu H, Ding X, Wang L. Numerical analysis of heat transfer during multi-layer selective laser melting of AlSi10Mg[J]. Optik-International Journal for Light and Electron Optics, 2016, 127(20):8883-8891. [9] Gu D, He B. Finite element simulation and experimental investigation of residual stresses in selective laser melted Ti-Ni shape memory alloy[J]. Computational Materials Science, 2016, 117(6):221-232. [10] Tang T, Felicelli S D. Numerical analysis of thermo-mechanical behavior of laser cladding process[C]//TMS Meeting&Exhibition, 2014:211-218. [11] Chen J, Xue L. Laser cladding of wear resistant CPM 9V tool steel on hardened H13 substrate for potential automotive tooling applications[J]. Materials Science&Technology, 2010(10):2459-2470. [12] Lee Y S, Zhang W. Modeling of heat transfer, fluid flow and solidification microstructure of nickel-base superalloy fabricated by laser powder bed fusion[J]. Additive Manufacturing, 2016, 12:178-188. [13] Pinkerton A J, Li L. Direct additive laser manufacturing using gas-and water-atomised H13 tool steel powders[J]. International Journal of Advanced Manufacturing Technology, 2005, 25(5-6):471-479. -
期刊类型引用(7)
1. 杜世浩,韩志杰,高雪强,眭君娜,刘钊,张永弟. SLM成形多层多道金属薄壁件温度场有限元模拟. 河北科技大学学报. 2023(04): 335-345 . 
百度学术
2. 庞铭,浮艺旋. 激光扫描速度对激光增材制造机场供油管网温度场的影响研究. 热加工工艺. 2022(07): 119-123+127 . 百度学术
3. 张国滨,姜梦,陈曦,陈奥,雷正龙,陈彦宾. 常压/真空环境激光焊接焊缝成形特性及残余应力与变形对比. 焊接学报. 2022(08): 34-41+115 . 本站查看
4. 奥妮,何子昂,吴圣川,彭鑫,吴正凯,张振先,祝弘滨. 激光增材制造AlSi10Mg合金的力学性能研究进展. 焊接学报. 2022(09): 1-19+113 . 本站查看
5. 龚淼,戴士杰,王涛. 航空超薄压气机叶片堆焊修复关键参数研究. 机床与液压. 2021(02): 20-25+14 . 百度学术
6. 赵昌龙,刘俊,姚世航,王阔,王旭旭. 表面织构对模具钢激光熔覆层性能的影响分析. 表面技术. 2021(06): 101-108+192 . 百度学术
7. 郭辰光,王磊,岳海涛,赵丽娟. 液压支架导向套再制造修复温度场及应力场分析. 煤炭学报. 2021(S2): 1105-1113 . 百度学术
其他类型引用(8)
计量
- 文章访问数: 448
- HTML全文浏览量: 22
- PDF下载量: 206
- 被引次数: 15
下载:
