金属学报  2005, Vol. 41 Issue (3): 251-254

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镍基合金γ'相亚点阵成分的最优化测算及其应用

阎光宗;彭志方

武汉大学动力与机械学院;武汉 430072

An optimization algorithm and its application for predicting elemental concentrations of sublattices of γ' phase in Ni base superalloys

YAN Guangzong; PENG Zhifang

Department of Materials Engineering; College of Power and Mechanical Engineering; Wuhan University; Wuhan 430072

阎光宗; 彭志方 . 镍基合金γ'相亚点阵成分的最优化测算及其应用[J]. 金属学报, 2005, 41(3): 251-254 .
, . An optimization algorithm and its application for predicting elemental concentrations of sublattices of γ' phase in Ni base superalloys[J]. Acta Metall Sin, 2005, 41(3): 251-254 .

摘要 参考文献 相关文章 Metrics 全文: PDF(142 KB)   摘要: 综合考虑镍基合金γ'相中原子尺寸失配和电负性因素对γ'相亚点阵成分的影响, 建立了用于预测γ'相亚点阵成分的最优化数学模型.根据已知的 '相成分, 采用迭代替换方法确定优化问题中亚点阵成分变量的取值范围,运用分层宽容多目标优化法, 计算了γ'相中合金元素在Ni位置和Al位置的浓度. 利用已知γ'相成分和点阵常数数据对计算结果进行了验证, 证实了该方法的可用性及其准确性. 关键词 ： 镍基合金,  γ'相亚点阵,  亚点阵     Abstract：The effects of mismatch in atomic size and electronegativity of alloying elements on the elemental concentration of sublattices of γ' phase in Ni base superalloys were investigated. The mathematic model of optimizations was established to predict the elemental concentration of sublattices of γ' phase. Ranges of the selected values of concentration variables were determined by use of the iterative and substitutional method. Based on chemical compositions of the γ' phase, the elemental content at the Ni and Al sites in the γ'phase can be calculated with the layered multi-objective optimization algorithm with tolerance. Using the reported data on both the chemical compositions and the lattice parameters of γ' phase, a comparison between the predicted and the reported values of lattice parameters was made through the application of the predicted values of the elemental concentrations of the γ'sublattices to verify the feasibility and the accuracy of the present method. Key words： Ni base superalloy    γ'phase    sublattice 收稿日期: 2004-05-09      ZTFLH:  TG132.3   服务 把本文推荐给朋友 加入引用管理器 E-mail Alert RSS 作者相关文章 阎光宗 彭志方 44.8K 链接本文: https://www.ams.org.cn/CN/      或      https://www.ams.org.cn/CN/Y2005/V41/I3/251 [1] Peng Z F, Liu P. Acta Matall Sin, 2004; 40: 569 (彭志方,刘攀,金属学报,2004;40:569) [2] Hu S G, Shi B C. Principles of Optimization Algorithms. Wuhan: Huazhong University of Science and Technology, 2000: 5 (胡适耕,施保昌,最优化原理.武汉:华中理工大学出版社, 2000:5) [3] Pan J S, Tong J M. Basis of Material Science. Beijing: Tsinghua University Press, 1998: 90 (潘金生,仝健民.材料科学基础.北京:清华大学出版社, 1998:90) [4] Xiao J M, Zhu F W. Energetics of Materials. Shanghai: Shanghai Science and Technology Press, 1999: 266 (肖纪美,朱逢吾.材料能量学.上海:上海科学技术出版社, 1999:266) [5] Xie K X, Han L X, Lin Y L. Method of Optimization Algorithms. Tianjin: Tianjin University Press, 1997: 1 (解可新,韩立兴,林友联.最优化方法.天津:天津大学出版 社,1997:1) [6] Caron P, Khan T. Mater Sci Eng, 1983; 61: 173 [7] Kuhn H A, Biermann H, Ungar T, Mughrabi H. Acta Met- all Mater, 1991; 39: 2783 [8] Nathal M V, Ebert L J. Metall Trans, 1985; 16A: 1849 [9] Harf F H. Metall Trans, 1985; 16A: 993 [10] Narayan V. University of Cambridge, 1999, In: http:// www.msm.cam.ac.uk/map/data/neural/lattmisfit-b.html [11] Bruckner U, Epishin A, Link T, Dressel K. Mater Sci Eng, 1998; A247: 23 [12] Copland E H, Jacobson N S, Ritzert F J. NASA TM-2001-210897, 2001 [1] 韩恩厚, 王俭秋. 表面状态对核电关键材料腐蚀和应力腐蚀的影响[J]. 金属学报, 2023, 59(4): 513-522. [2] 余春, 徐济进, 魏啸, 陆皓. 核级镍基合金焊接材料失塑裂纹研究现状[J]. 金属学报, 2022, 58(4): 529-540. [3] 王迪, 王栋, 谢光, 王莉, 董加胜, 陈立佳. Pt-Al涂层对一种镍基单晶高温合金抗热腐蚀行为的影响[J]. 金属学报, 2021, 57(6): 780-790. [4] 余磊, 曹睿. 镍基合金焊接裂纹研究现状[J]. 金属学报, 2021, 57(1): 16-28. [5] 华涵钰,谢君,舒德龙,侯桂臣,盛乃成,于金江,崔传勇,孙晓峰,周亦胄. W含量对一种高W镍基高温合金显微组织的影响[J]. 金属学报, 2020, 56(2): 161-170. [6] 李克俭, 张宇, 蔡志鹏. 异种金属焊接接头在热-力耦合作用下的断裂位置转移机理[J]. 金属学报, 2020, 56(11): 1463-1473. [7] 王资兴,黄烁,张北江,王磊,赵光普. 高合金化GH4065镍基变形高温合金点状偏析研究[J]. 金属学报, 2019, 55(3): 417-426. [8] 韦康, 张麦仓, 谢锡善. 超超临界电站用镍基合金热加工过程的再结晶机理[J]. 金属学报, 2017, 53(12): 1611-1619. [9] 欧美琼,刘扬,查向东,马颖澈,程乐明,刘奎. 一种新型镍基合金在超临界多种离子共存环境下的腐蚀行为*[J]. 金属学报, 2016, 52(12): 1557-1564. [10] 谢君,于金江,孙晓峰,金涛,杨彦红. 温度对高W含量K416B镍基合金拉伸行为的影响*[J]. 金属学报, 2015, 51(8): 943-950. [11] 谢君, 于金江, 孙晓峰, 金涛, 孙元. 高钨K416B铸造镍基合金高温蠕变期间碳化物演化行为[J]. 金属学报, 2015, 51(4): 458-464. [12] 谢君,田素贵,刘姣,周晓明,苏勇. FGH95粉末镍基合金蠕变期间位错网的形成与分析[J]. 金属学报, 2013, 49(7): 838-844. [13] 张姝,田素贵,于慧臣,于莉丽,于兴福. [111]取向镍基单晶合金在蠕变期间组织演化的有限元分析[J]. 金属学报, 2012, 48(5): 561-568. [14] 张胜寒 檀玉 梁可心. 光电化学法研究镍基合金在288℃高温水中生成氧化膜的半导体性质[J]. 金属学报, 2011, 47(9): 1147-1152. [15] 赵帅 李秀艳 戎利建. 一种奥氏体FeNi基合金中的锯齿流变现象[J]. 金属学报, 2011, 47(8): 1017-1021. Viewed Full text Abstract Cited   Shared      Discussed