Process Parameters of Additive and Subtractive Hybrid Manufacturing for GH3536 Superalloy

Yingwei Zhang; Jing Wang; Quanwei Sun; Qian Bai; Hefeng Ling; Xiaodan Li

doi:10.3788/LOP230913

[1] Bai Y C, Zhao C L, Zhang Y et al. Microstructure and mechanical properties of additively manufactured multi-material component with maraging steel on CrMn steel[J]. Materials Science and Engineering: A, 802, 140630(2021).

[2] Zhang X J, Tang S Y, Zhao H Y et al. Research status and key technologies of 3D printing[J]. Journal of Materials Engineering, 44, 122-128(2016).

[3] Du W, Bai Q, Zhang B. Machining characteristics of 18Ni-300 steel in additive/subtractive hybrid manufacturing[J]. The International Journal of Advanced Manufacturing Technology, 95, 2509-2519(2018).

[4] Guo N N, Leu M C. Additive manufacturing: technology, applications and research needs[J]. Frontiers of Mechanical Engineering, 8, 215-243(2013).

[5] Du W. Study on performance integrity of titanium alloy materials made by adding materials and reducing materials[D](2018).

[6] Tang C M, Zhao J B, Tian T T et al. Development of composite manufacturing system of additive and subtractive materials based on laser selective melting and high-speed cutting[J]. Hot Working Technology, 51, 118-122(2022).

[7] Chen L, Xu K, Tang K. Optimized sequence planning for multi-axis hybrid machining of complex geometries[J]. Computers & Graphics, 70, 176-187(2018).

[8] Wüst P, Edelmann A, Hellmann R. Areal surface roughness optimization of maraging steel parts produced by hybrid additive manufacturing[J]. Materials, 13, 418(2020).

[9] Zhang X, Dong A P, Du D F et al. Effect of SLM process parameters on microscopic defects and surface quality of GH3536 superalloy[J]. Journal of Aeronautical Materials, 42, 71-80(2022).

[10] Wang Y Y, Shen P C, Liang X H. Effect of SLM process parameters on micro-morphology of 316L stainless steel forming parts[J]. Journal of Guangxi University of Science and Technology, 34, 121-127(2023).

[11] Feng E H, Wang X Q, Han X et al. Optimization of process parameters for laser selective melting of Ti6Al4V alloy[J]. Powder Metallurgy Technology, 40, 555-563(2022).

[12] Yang H Q, Wang Z Y, Xiao C B et al. Microstructure and mechanical properties of alloy GH22 as insulate plates against heat in industrial gas turbine[J]. Journal of Materials Engineering, 38, 15-19(2010).

[13] Sing S L, Yeong W Y. Laser powder bed fusion for metal additive manufacturing: perspectives on recent developments[J]. Virtual and Physical Prototyping, 15, 359-370(2020).

[14] Kasperovich G, Haubrich J, Gussone J et al. Correlation between porosity and processing parameters in TiAl6V4 produced by selective laser melting[J]. Materials & Design, 105, 160-170(2016).

[15] Montero-Sistiaga M L, Liu Z Z, Bautmans L et al. Effect of temperature on the microstructure and tensile properties of micro-crack free hastelloy X produced by selective laser melting[J]. Additive Manufacturing, 31, 100995(2020).

[16] Öktem H. An integrated study of surface roughness for modelling and optimization of cutting parameters during end milling operation[J]. The International Journal of Advanced Manufacturing Technology, 43, 852-861(2009).

[17] Li S. Study on milling characteristics of titanium alloy manufactured by adding and subtracting materials[D](2018).

[18] Jia T H. Study on mechanical properties and milling performance of nickel-based superalloy deposited by directional energy[D](2022).