将一种镍基单晶高温合金在室温沿不同晶体取向压缩变形,研究了在试样表面形成的滑移线和微观组织的变化。结果表明:这种合金〈111〉取向试样的屈服强度最高,〈001〉取向的强度最低,〈110〉取向的强度居中。〈001〉和〈110〉取向的试样在压缩变形过程中主要启动八面体滑移系,其中〈110〉取向明显观察到双滑移系的开动;而〈111〉取向的试样则启动了六面体滑移系。基体通道、枝晶、共晶等组织的备向异性,在一定程度上影响不同晶体取向合金的变形特征。〈110〉取向试样的变形组织中形成了大量的层错,而在其它两个取向的试样中则未观察到。〈111〉取向变形后基体通道中的位错密度明显高于其它两个取向,这种高加工硬化率使〈111〉取向具有高的屈服强度。
A nickel base single crystal superalloy was compressed at room temperature along the 001,110 and 111 orientations,respectively.The evolution of the slip traces and the microstructure in the deformation was investigated by metallographic microscope and transmission electron microscope. It was found that compress deformation depends on the crystal orientation and the precedence of the compress yield stress is:111,110,001.For the 001 or 110 oriented specimen compressed 4.5% the slip traces match the octahedral slip,and the slip traces in the 111 oriented alloy prove to slip along the {001} planes.It is noted that deformation of the 110 oriented alloy takes place by activation of two slip systems.The anisotropy of the matrix channel,dendritic segregation and eutectic leads to the change of deformation behavior for various orientations.For the 110 oriented alloyγ' particles cut by stacking fault.The high dense dislocation of the 111 oriented alloy contributes to its high yield strength.
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