Progress in Additive Manufacturing on Complex Structures and High-performance Materials

被引：15

作者：

Liu W. ^{[1
]}

Li N. ^{[1
]}

Zhou B. ^{[1
]}

Zhang G. ^{[1
]}

Liang J. ^{[1
]}

Zheng T. ^{[1
]}

Xiong H. ^{[1
]}

机构：

[1] 3D Printing Research & Engineering Technology Center, AECC Beijing Institute of Aeronautical Materials, Beijing

来源：

Jixie Gongcheng Xuebao/Journal of Mechanical Engineering | 2019年 / 55卷 / 20期

关键词：

Additive manufacturing; Arc; Complex structures; Electron beam; High-performance materials; Laser;

D O I：

10.3901/JME.2019.20.128

中图分类号：

学科分类号：

摘要：

With the characteristics of point by point melting and layer by layer manufacturing, additive manufacturing (AM), on one hand, can fabricate the three-dimensional complex structure parts rapidly; on the other hand, it can realize the high performance of materials. Based on the technological advantages and important application prospects of AM technology, the recent efforts and advances in AM on complex structures including:lattice structures, large thin-walled structures, complex surface structures, integrated structures; and materials including:iron-based alloys, titanium-based alloys, nickel-based alloys, aluminum-based alloys, intermetallic compounds, functionally gradient materials, ceramics are presented and reviewed. The development trend of AM on structure design, special materials system, new materials, repairing and remanufacturing, data base and standards are also forecasted. © 2019 Journal of Mechanical Engineering.

引用

页码：128 / 151and159

共 164 条

[21] Wang J., Chen C., Wang X., Et al., Microstructure and compressive properties of porous stainless steel prepared by laser 3D printing, Journal of Mechanical Engineering, 52, 21, pp. 206-212, (2016)
[22] Paul C.P., Mishra S.K., Kumar A., Et al., Laser rapid manufacturing on vertical surfaces: Analytical and experimental studies, Surface and Coatings Technology, 224, pp. 18-28, (2013)
[23] Alimardani M., Toyserkani E., Prediction of laser solid freeform fabrication using neuro-fuzzy method, Applied Soft Computing, 8, 1, pp. 316-323, (2008)
[24] Ponche R., Kerbrat O., Mognol P., Et al., A novel methodology of design for additive manufacturing applied to additive laser manufacturing process, Robotics and Computer-Integrated Manufacturing, 30, 4, pp. 389-398, (2014)
[25] Mahmood K., Pinkerton A.J., Direct laser deposition with different types of 316L steel particle: a comparative study of final part properties, Proceedings of the Institution of Mechanical Engineers, Part Journal of Engineering Manufacture, 227, 4, pp. 520-531, (2013)
[26] Liu J., Li L., Effects of powder concentration distribution on fabrication of thin-wall parts in coaxial laser cladding, Optics & Laser Technology, 37, 4, pp. 287-292, (2005)
[27] Wang T., Fu G., Shi S., On-line defocusing measurement and control system for laser cladding pool based on embedded machine vision, China Laser, 42, 3, pp. 120-127, (2015)
[28] Zhu G., Zhang A., Li D., Et al., Z-axis single-layer travel model for thin-walled parts manufactured by laser metal, Journal of Welding, 31, 8, pp. 57-60, (2010)
[29] Doan T., Li D., Lu B., Et al., Effect of scanning mode on cracking of DZ125L superalloy thin-walled parts directly formed by laser metal, China Laser, 39, 10, pp. 38-45, (2012)
[30] Wu S., Shi S., Xiao J., Et al., Study on the characteristics of molten pool of thin-walled parts formed by ring laser powder feeding, Applied Laser, 33, 3, pp. 250-253, (2013)

← 1 2 3 4 5 6 7 8 9 10 →