姓名:朱麟
出生年月籍贯:1993年1月生于陕西省榆林市
最高学历:工学博士
所在专业:过程装备与控制工程
通讯地址:陕西省西安市太白北路229号化工学院(710069)
电子邮箱:zl@nwu.edu.cn
主要研究方向:针对能源动力、航天航空、石油化工等工业领域中服役于高温条件下的设备出现的高温损伤问题,从材料力学性能、微观组织演化、宏观无损检测等角度出发,对设备的高温损伤过程及剩余寿命预测进行系统研究。具体研究方向包括:
● 极端环境下材料力学行为与表征技术
● 高温蠕变过程多尺度建模与计算
● 材料组织演化及性能研究
● 先进无损检测技术开发与应用
近期发表论文情况
[1] L. Zhu, X. B. Liu, F. Ping, et al. Characterization of creep degradation of modified 9Cr-1Mo steel using magnetic measurement. J. Test. Eval., Vol. 48 (5), pp. 4030-4039, 2020.
[2] T. Liang, X. B. Liu, P. Fan, L. Zhu, Y. Bi, Y. G. Zhang. Prediction of long-term creep life of 9Cr-1Mo-VNb steel using artificial neural network. Int. J. Pres. Ves. Pip., Vol.179, 104014, 2020.
[3] L. Zhu, X. B. Liu, P. Fan, J. Q. Liu. A Study of microstructure evolution during creep of 9Cr-1Mo steel using ultrasonic and hardness measurements. J. Mater. Eng. Perform., Vol. 28 (4), pp. 2348-2355, 2019.
[4] L. Zhu, X. B. Liu, P. Fan, Y. Dan, L. T. Wang. Creep rupture behaviour of modified 9Cr-1Mo heat-resistant steel strengthened with different mechanisms. Mater. High. Temp., Vol. 36 (6), pp. 548-561, 2019.
[5] L. Zhu, X. B. Liu, P. Fan, J. Q. Liu, C. F. Pan. Comparative study of creep behavior in 9Cr-1Mo steel with different prediction methods. J. Press. Vess.-T. ASME, Vol. 141
(6), pp. 061406(1)-061406(9), 2019.
[6] X. B. Liu, P. Fan, L. Zhu. Characterization of dislocation evolution during creep of 9Cr1Mo steel using internal friction measurement. Mater. Charact., Vol. 150, pp. 98-106, 2019.
[7] 毕瑶,刘新宝,朱麟,张亚岗. 高温蠕变过程中高铬耐热钢的电化学极化行为. 金属热处理, Vol. 44 (11), pp. 213-218, 2019.
[8] M. M. Guo,X. B. Liu,L. Zhu, Q. Zhang, J. Q. Liu. Characterization of small-angle grain boundary evolution during creep of P91 steel using EBSD technique. Materials
Review, Vol. 32 (5), pp. 1747-1751, 2018.
[9] 张琦,刘新宝,朱麟,郭苗苗,刘剑秋. 基于P91钢的蠕变损伤模型比较. 西北大学学报, Vol. 47 (5), pp. 711-716, 2018.
[10] 刘剑秋,刘新宝,朱麟,郭苗苗,张琦. 9Cr-1Mo耐热钢蠕变过程中可动位错演化行为表征. 西北大学学报, Vol. 48 (1), pp. 66-70, 2018.
[11] L. Zhu, X. B. Liu, T. Xin, C. F. Pan, J. Q. Liu. Prediction of long-term creep rupture time of P91 steel based on microstructure evolution. Materials Review, Vol. 31 (5), pp. 98-106, 2017.
