Study on the microstructure of superalloy GH4065A solidified under high pressure
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摘要: 通过OM和SEM观察了以常压和加压(2 MPa)两种凝固方式下的GH4065A铸锭显微组织,以分析加压对GH4065A铸锭凝固组织的影响。结果表明,常压下的铸态GH4065A有大量疏松缩孔,微观组织中主要析出相是γ’相,偏析最为严重的元素是Nb。在2 MPa下进行凝固,可以消除大量疏松缩孔,提高铸件的致密度,并使Nb元素的残余偏析指数大大降低;加压凝固可以使合金GH4065A的二次枝晶间距低于常压铸锭,这是由于加压使相变温度升高,从而增大熔体的相变驱动力,增加结晶数目,晶粒细化。上述结果表明加压凝固在高温合金中的巨大优势和应用前景,推广到更多的高温合金牌号,以发挥压力凝固的重要价值。Abstract: OM and SEM were used to observe the microstructure of GH4065A under two solidification modes: normal pressure and pressure (under 2 MPa) to analyze the effect of high pressure on the structure. The results show that the as-cast GH4065A structure under normal pressure has a large number of loose shrinkage cavities, the main precipitated phase in the microstructure is γ' phase, and the most severely segregated element is Nb. Solidification at 2 MPa can eliminate a large number of loose shrinkage cavities, increase the density of castings, and greatly reduce the residual segregation index of Nb element. At the same time, the pressure solidification can make the secondary dendrite spacing of alloy GH4065A lower than that of the normal pressure ingot. This is because the pressure increases the phase transition temperature, thereby increasing the phase transition driving force of the melt and refining the crystal grains. These results demonstrate that the great advantages and application prospects of pressurized solidification in superalloys, and it can be extended to other superalloy grades in order to exert the important value of pressurized solidification.
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Key words:
- superalloy /
- pressurized solidification /
- microstructure /
- segregation characteristics
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图 1 铸态GH4065A的取样位置
(a)常压;(b)高压
Figure 1. Sampling position of as-cast GH4065A (a)normal pressure, (b)high pressure
图 2 GH4065A的低倍组织
(a)常压;(b)高压
Figure 2. Macrostructure of GH4065A (a) normal pressure, (b) high pressure
图 3 铸态GH4065A枝晶形貌及析出相形貌
(a)枝晶形貌;(b)析出相
Figure 3. (a) Dendrite morphology and (b) precipitated phase morphology of as-cast GH4065A
图 4 铸态GH4065A不同凝固方式二次枝晶间距测量结果
Figure 4. Measurements of second dendrite distance of multiple locations of as-cast GH4065A
图 5 铸态GH4065A在扫描电镜下的点扫描分析
(a)枝晶干;(b)枝晶间
Figure 5. Point scanning analysis of as-cast GH4065A under scanning electron microscope (a) dendrite, (b) inter-dendrite
表 1 GH4065A合金的名义成分[7]
Table 1. Nominal chemical compositions of GH4065A alloy
% C Cr Co Fe Ti Al Nb Mo W B Zr Ni 0.011 16.0 13.0 1.0 3.7 2.1 0.7 4.0 4.0 0.015 0.05 余量 
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表 2 常压下凝固铸锭各元素不同位置偏析系数K
Table 2. Segregation coefficient K of various elements in different positions of non-pressurized solidified ingot
试样编号 Al Ti Cr Fe Co Ni Nb Mo W 1 1.04 2.34 0.86 0.64 0.91 1.02 5.62 1.19 0.60 2 1.08 2.35 0.90 0.87 0.90 1.01 3.86 1.17 0.63 3 0.84 2.98 0.84 1.04 0.89 0.97 11.38 1.40 0.60 4 0.97 1.79 0.96 1.04 0.95 0.99 3.38 1.14 0.78 5 0.97 1.42 0.95 1.05 0.96 1.00 2.06 1.09 0.83 6 0.91 2.94 0.85 0.74 0.86 0.94 14.02 1.22 0.88
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表 3 加压凝固铸锭各元素不同位置偏析系数K
Table 3. Segregation coefficient K of various elements in different positions of pressurized solidification ingot
试样编号 Al Ti Cr Fe Co Ni Nb Mo W 1 1.09 2.19 0.94 0.99 0.89 1.00 3.75 1.23 0.61 2 1.05 2.16 0.92 0.98 0.91 0.98 3.77 1.20 0.63 3 1.11 2.42 0.85 0.49 0.87 1.03 4.78 1.19 0.55 4 0.93 1.66 0.98 0.90 0.98 0.99 2.86 1.19 0.77 5 0.99 1.61 0.93 0.80 0.95 1.01 2.33 1.12 0.73 6 0.92 2.87 0.87 0.82 0.89 0.96 8.04 1.31 0.78
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