Weldability and Properties of Newly Developed LW4280 High Gamma Prime Nickel Based Superalloy for 3D AM and Repair of Turbine Engine Components

Volume 7: Industrial and Cogeneration; Manufacturing Materials and Metallurgy Pub Date : 2021-06-07 DOI:10.1115/gt2021-58851

Alexandre Gontcharov, P. Lowden, Ashutosh Jena, S. Kwon, M. Brochu

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Abstract

Chemical composition, structure, mechanical and oxidation properties of welds produced utilizing laser direct energy deposition process of a newly developed LW4280 welding powder will be presented. Crack-free and high-density specimens were fabricated for manufacturing standard and subsized tensile test samples as per ASTM E-8. Optical and scanning electron microscopy revealed the formation of epitaxial grain growth during solidification of the welding pool followed by precipitation of fine gamma prime phase during the reheating from the subsequent weld layers. A sub-solvus primary aging temperature determined using Thermo-Calc software followed by secondary aging resulted in precipitation of above 49% of cuboidal γ′ phase. Excellent ultimate tensile strength of 1310 MPa (190 ksi), 0.2% yield strength of 855 MPa (124 ksi), and elongation of 18.7% were measured at ambient temperature. At 926°C (1700°F), the tensile testing yielded of 579 MPa (84 ksi), 0.2% yield strength of 462 MPa (67 ksi), and elongation of 18.8%. Cyclic oxidation resistance of the LW4280 weld material at 1120°C (2048°F) was superior to Rene 80 and Mar M247 while slightly below Rene 142.

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新研制的LW4280高γ素数镍基高温合金用于涡轮发动机零件3D增材制造和修复的可焊性和性能

介绍了激光直接能量沉积法制备LW4280焊接粉末的化学成分、结构、力学性能和氧化性能。根据ASTM E-8制作无裂纹和高密度试样，用于制造标准和补贴拉伸试验样品。光学显微镜和扫描电镜观察发现，焊接熔池在凝固过程中形成外延晶粒生长，随后焊接层在再加热过程中析出细小的γ素相。采用thermal - calc软件测定亚溶质初时效温度，然后进行二次时效，析出49%以上的立方γ′相。室温下的极限抗拉强度为1310 MPa (190 ksi)，屈服强度为855 MPa (124 ksi)，延伸率为18.7%。在926°C(1700°F)时，拉伸试验的屈服强度为579 MPa (84 ksi)，屈服强度为462 MPa (67 ksi)，延伸率为18.8%。LW4280焊接材料在1120°C(2048°F)下的抗循环氧化性能优于Rene 80和Mar M247，略低于Rene 142。

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Volume 7: Industrial and Cogeneration; Manufacturing Materials and Metallurgy

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