全密度功能性复杂金属零件的激光直接快速制造

针对具有复杂结构的全密度功能性金属零件快速制造难题，探讨了该类零件的选区激光熔化直接快速制造方法，并结合实验，重点对同步保证选区激光熔化快速制造金属零件成型密度及精度的工艺进行了研究。结果表明：同步消除球化、飞溅及气孔对成型件致密性及精度的影响是实现选区激光熔化快速制造全密度功能性复杂金属零件的难点及关键；在维持良好的抗氧化气氛条件下，可采用尽可能薄的铺粉厚度及恰当调节其它成型参数的方法，以保证对上一层有足够的重熔量来消除球化及气孔现象;同时，采用合适的扫描策略，可弱化飞溅对成型质量的影响来解决工艺难题。采用该工艺方案可快速制造全密度功能性复杂金属零件，所成型的316L不锈钢叶轮零件相对密度为99.8%，硬度为HB192，表面粗糙度约为40 μm，尺寸精度在±0.1 mm以内，稍经打磨后即可投入使用。

Abstract

It is very difficult to rapidly and directly manufacture FMPCD (Functional Metal Part with Complex Structure and Full Density). In this study, the method of rapid manufacturing of this type of part by SLM (Selective Laser Melting) was discussed, and the problem of ensuring synchronously part density and precision during SLM processing was analyzed detailedly combined with some SLM experiments. The results show that in order to rapidly manufacture FMPCD by SLM, it is necessary to reduce the effects of balling, spattering and air holes on part density and precision; Balling and air holes can be avoided by maintaining enough re-melting amount of upper solidified layer which can be got through use of enough thin powder layer thickness and careful adjustment of other processing parameters under good antioxidated gas protection, and the bad effects of spattering on part quality can be weakened by proper scanning strategy. Using this processing method, the goal of rapid manufacturing of FMPCD can be attained: a complex-structure 316L stainless steel impeller with density of 99.8%, hardness of HB 192, size accuracy of ±0.1mm and surface roughness of about Ra40μm which can be put into used after simple polishing was made successfully in this study.

参考文献

[1] Yadroitsev I, Shishkovsky I, Bertrand P, et al. Manufacturing of fine-structured 3D porous filter elements by selective laser melting［J］. Applied Surface Science, 2009,255(10): 5523-5527.

[2] Osakada K, Shiomi M. Flexible manufacturing of metallic products by selective laser melting of powder［J］. International Journal of Machine Tools and Manufacture, 2006, 46(11): 1188-1193.

[3] Kamran A M, Erasenthiran P, Hopkinson N. High density selective laser melting of waspaloy［J］. Journal of Materials Processing Technology, 2008, 195(1/2/3): 77-87.

[4] 沈显峰,姚进,王洋,等.金属粉末的直接选区激光烧结温度场数值模拟［J］. 光电子.激光,2005, 16( 4): 492-495. (Shen Xianfeng ，Yao Jin，Wang Yang, et al. Numerical simulation of thermal distribution in direct metal laser sintering. Journal of Optoelectronics·Laser,2005, 16( 4): 492-495)

[5] 吴伟辉, 杨永强, 王红卫,等.光纤激光直接快速成型316L不锈钢精密零件研究［J］.激光技术，2009，33(5)：486-489.(Wu Weihui，Yang Yongqiang，Wang Hongwei, et al. Research on direct rapid manufacturing of 316L fine metal part using fiber laser. Laser Technology，2009，33(5)：486-489)

[6] Krutha J P, Froyenb L, Van Vaerenbergha J, et al. Selective laser melting of iron-based powder［J］. Journal of Materials Processing Technology, 2004, 149(1/3): 616-622.

[7] 付立定,史玉升,章文献,等.316L 不锈钢粉末选择性激光熔化快速成形的工艺研究［J］.应用激光,2008,28(2): 108-111.(Fu Liding, Shi Yusheng, Zhang Wenxian,et al. The process research of 316L stainless steel in selective laser melting. Applied Laser,2008,28(2): 108-111)

[8] Abe F， Osakada K， Shiomi M， et al. The manufacturing of hard tools from metallic powders by selective laser melting［J］. Materials Processing Technology, 2001, 111(1/3): 210-213.

[9] 贺瑞军，王华明. 激光熔化沉积Ti-6Al-2Zr-Mo-V钛合金组织特征研究［J］. 航空材料学报,2009,29(6): 18-22.(He Ruijun, Wang Huaming. Microstructure features of laser deposited Ti-6Al-2Zr-Mo-V Alloy. Journal of aeronautical materials,2009,29(6): 18-22)

[10] 马良,黄卫东,许小静.基于分形扫描的TC4合金激光立体成形研究［J］. 稀有金属材料与工程,2009,38(10): 1731-1735.(Ma Liang, Huang Weidong, Xu Xiaojing. Research on Laser Solid Forming of TC4 Alloy Based on Fractal Scanning. Rare metal materials and engineering,2009,38(10): 1731-1735)

[11] 齐海波，林峰，颜永年,等.EFGH不锈钢粉末的电子束选区熔化成形［J］. 清华大学学报(自然科学版),2007,47(7): 1941-1944.(Qi Haibo,Lin Feng,Yan Yongnian, et al.Electron beam selective melting of 316L stainless steel powder. Journal of Tsinghua University(Sci&Tech),2007,47(7): 1941-1944)

[12] Abe F, Santos E Costa, Kitamura Y, et al. Influence of forming conditions on the titanium model in rapid prototyping with the selective laser melting process ［J］. Mechanical Engineering Science, 2003, 217(1): 120-126.

[13] Gusarov A V, Yadroitsev I, Bertrand PH, et al.Heat transfer modeling and stability analysis of selective laser melting［J］. Applied Surface Science, 2007, 254(4): 975-979.

[14] Badrossamay M, Childs T H C. Further studies in selective laser melting of stainless and tool steel powders［J］. International Journal of Machine Tools and Manufacture, 2007, 47(5): 779 - 784.

[15] Kruth J P, Froyen L, Vaerenbergh J Van, et al. Selective laser melting of iron-based powder［J］. Journal of Materials Processing Technology, 2004, 149(1-3): 616-622.

[16] Tolochko N K, Mozzharov S E, Yadroitsev I A,et al. Balling processes during selective laser treatment of powders［J］. Rapid Prototyping Journal, 2004, 10(2): 78-87.

[17] 吴伟辉，杨永强，王迪,等. 选区激光熔化变密度快速制造工艺研究［J］.中国激光，2010,37(7): 1879-1884.(Wu Weihui,Yang Yong qiang,Wang Di,et al. Research on variable density rapid manufacturing process based on selective laser melting technology. Chinese Journal of Laser，2010,37(7): 1879-1884)

[18] 吴伟辉，杨永强，何兴容,等. 金属质手术模板的全数字化设计及制造［J］.光学精密工程，2010，18(5): 1135-1143.(Wu Weihui,Yang Yongqiang, He Xingrong,et al.All-digital rapid design and manufacture of metal customized surgical guide plate. Optics and Precision Engineering,2010,18(5): 1135-1143)

吴伟辉, 杨永强, 王迪. 全密度功能性复杂金属零件的激光直接快速制造[J]. 强激光与粒子束, 2011, 23(6): 1653. Wu Weihui, Yang Yongqiang, Wang Di. Research on laser direct rapid manufacturing of functional metal part with complex structure and full density[J]. High Power Laser and Particle Beams, 2011, 23(6): 1653.

全密度功能性复杂金属零件的激光直接快速制造

关于本站 Cookie 的使用提示

全站搜索

全密度功能性复杂金属零件的激光直接快速制造

相关论文

相关资讯

关于本站 Cookie 的使用提示

全站搜索