The stored energy of plastic deformation has been estimated from transmission electron microscope measurements of dislocation boundary spacings and misorientation angles using Al (99.99 pet) cold rolled to reductions of 5 to 90 pet as an example system. In order to obtain the most accurate estimate of stored energy, it is necessary to take into account the presence of two classes of dislocation boundary, considering the boundary misorientation angle distribution and the stereology of each class independently. Stereological relationships are developed to predict the stored energy estimates that would result from electron backscatter pattern (EBSP) investigations on these microstructures. The calculations show that EBSP investigations can be used to estimate the stored energy, but that at low strains, the limited angular resolution will lead to a significant underestimation. A relationship between the flow stress (0.2 pet offset) and the stored energy is found, though the relationship differs significantly for the low and high strain regimes. At low strains, the flow stress is linearly related to the square root of the stored energy (Es) according to sigma -sigma_0 = Ma[(G/K)Es]~(0.5), where G is the bulk modulus, M is the Taylor factor, and K and a are constants.
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机译:塑性变形的存储能量已经通过透射电子显微镜对位错边界间距和取向差角度的测量进行了估算,其中使用Al(99.99磅)冷轧至减少5到90磅作为示例系统。为了获得最准确的储能估计,有必要考虑两类位错边界的存在,并分别考虑边界错位角分布和每类的立体感。建立了立体关系,以预测由于对这些微结构的电子背向散射图(EBSP)研究而产生的储能估计。计算表明,EBSP研究可用于估计存储的能量,但是在低应变下,有限的角度分辨率将导致严重的低估。尽管在低应变和高应变状态下,流动应力(0.2 pet偏移)与存储的能量之间存在关系,但该关系存在显着差异。在低应变下,根据sigma -sigma_0 = Ma [(G / K)Es]〜(0.5),流变应力与储能(Es)的平方根线性相关,其中G为体积模量,M为泰勒因子,K和a是常数。
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