学术论文

2023

[1] 李康迪, 王珺, 徐自力*, 闫松, 王振. 某型液体火箭发动机小部分进气度涡轮盘振动分析及改型设计[J]. 火箭推进. 2023.49(1):80-86.

[2] 徐自力, 吴锦涛, 刘畅, 王珺, 黄道琼. 部分进气高转速涡轮盘动力学设计及可靠性评估方法研究[C], 3届中国力学学会转子动力学与控制学术交流会, 68, 编号E11, 2023.5.5 - 5.8

[3] 徐自力, 王存俊, 李广, 王鹏. 小样本数据集下基于孪生网络的智能故障诊断方法研究[C], 3届中国力学学会转子动力学与控制学术交流会, P68, 编号E12, 2023.5.5 - 5.8

[4] 徐自力, 王存俊, 王鹏. 基于高斯混合分布的多传感器信息融合智能故障诊断方法研究[C], 3届中国力学学会转子动力学与控制学术交流会, P75, 编号E25, 2023.5.5 - 5.8

[5] 王鹏, 刘畅, 徐自力, 慕琴琴, 霍施宇, 徐健. 超转试验器转子-限位轴承碰摩非线性特性分析[C]. 15届全国转子动力学学术大会(ROTDYN2023), 2023.4.21 – 4.24, 沈阳.

[6] 孙羽键, 田旭, 杜大华, 王珺, 徐自力. 多场环境下某液体火箭发动机涡轮盘-转子振动特性分析及评价[C]. 15届全国转子动力学学术大会(ROTDYN2023), 2023.4.21 – 4.24, 沈阳.

[7] 房晓辉, 徐自力, 黄金平, 王珺, 黄道琼. 涡轮泵三点接触球轴承-转子系统动特性研究[C]. 15届全国转子动力学学术大会(ROTDYN2023), 2023.4.21 – 4.24, 沈阳.

[8] 霍鑫杰, 龚志诚, 徐自力, 黄金平, 王珺. 轴向力对涡轮泵球轴承及转子系统动力特性的影响研究. 15届全国转子动力学学术大会(ROTDYN2023), 2023.4.21 – 4.24, 沈阳.

[12] Kangdi Li, Yunxiang Du, Zili Zu*, Shizhi Zhao, Lu Cheng. Flutter analysis of compressor blades under travelling wave modes using an efficient fluid-structure interaction method[J]. Chinese Journal of Aeronautics. Manuscript ID CJOA-D-22-01517R1. 2023.2.9录用(没有见刊)

[13] Cun Xin, Manqing Qin, Mengfu He, Zili Xu*. An approach for extracting damage features in noisy environments using DOG multi-scale space and fractal dimension[J]. Nondestructive Testing and Evaluation, 2023, 38(5):767-797. (DOI: 10.1080/10589759.2023.2170372, 查询网址: https://www.tandfonline.com/doi/full/10.1080/10589759.2023.2170372)

[14] 龚志诚, 徐自力, 王珺, 黄金平. 不同轴向游隙下涡轮泵球轴承动态特性研究[J]. 学报, 2023,57(07):101-110 DOI: 10.7652/xjtuxb202307009, 查询网址:http://zkxb.xjtu.edu.cn/#/digest?ArticleID=4780)

[15] 房晓辉, 徐自力, 王珺, 黄金平. 保持架过梁断裂前后球轴承的动力学行为分析[J]. 火箭推进, 2023.3录用(没有见刊)

 

2022

[1] Cun Xin, Jun Wang, Zili Xu*, Cunjun Wang, Song Yan. Marker-free fatigue crack detection and localization by integrating the optical flow and information entropy[J]. Structural Health Monitoring. 2022, 20(4): 2124-2143, SCI: 000800542200001; EI: 20222212181937.

[2] Cun Xin, Cunjun Wang, Zili Xu*. Damage detection of structures from motion videos using high-spatial-resolution mode shapes and data fusion[J]. Engineering Failure Analysis, 2022, 140(2): 106560, SCI: 000827254200003; EI: 20222712318699.

[3] Cun Xin, CunJun Wang, Zili Xu*. Marker-free vision-based method for vibration measurements of RC structure under seismic vibration. Earthquake Engineering & Structural Dynamics. 2022, 51(8): 1773-1793, SCI: 000768999500001; EI: 20221111795469.

[4] Jingjing Gao, Cunjun Wang, Zili Xu*, Jun Wang, Song Yan, Zhen Wang. Gaussian process regression based remaining fatigue life prediction for metallic materials under two-step loading[J]. International Journal of Fatigue. 2022(158): 106730, SCI:000792829100001, EI: 20220311487442.

[5] Cunjun Wang, Cun Xin, Zili Xu*, Manqing Qin, Mengfu He. Mix-VAEs: A novel multisensor information fusion model for intelligent fault diagnosis[J]. Neurocomputing. 2022, 492: 234-244, SCI: 000510066300006; EI: 20221511958185.

[6] 刘畅, 徐自力*, 慕琴琴, 霍施宇. 叶片丢失后停车过程转子瞬态动力响应分析, 航空动力学报. 2022.1.7 录用

[7] 杜友耀, 邓春志, 常鑫, 徐自力*, 张映明, 高跃. 缠绕张力对复合材料缠绕结构材料强度的影响规律研究. 复合材料科学与工程. 2022(08):70-74.

[8] Cunjun Wang, Zili Xu*, Jun Wang, Song Yan. A multiple VAEs-based information fusion framework with mutual-KL loss for intelligent fault diagnosis and toward OoD detection[C]. IEEE International Conference on Prognostics and Health Management (ICPHM), 2022: 188-197, EI: 20223012414696. 主办:Institute of Electrical and Electronics Engineers (IEEE), June 6-8, 2022. Detroit, MI/Online.

[9] 周倩倩, 谭永华, 徐自力*, 王珺, 王振. 运载火箭圆柱形贮箱中推进剂大幅晃动的数值模拟[J]. 推进技术, 2022, 43(5):200627.

[10] 吴锦涛, 王珺, 徐自力*, 闫松, 王振. 高转速部分进气涡轮盘气流力及叶片振动响应研究[J]. 学报. 2022.56(7):108-117, EI20224713139511.

[11] Kangdi Li, Zili Zu*, Shizhi Zhao, Lu Cheng. Semi-implicit fluid structure interaction method based on the convergence of aerodynamic force residual: an efficient method for blades flutter analysis[C]. ICDVC.

[12] Jingjing Gao, Cunjun Wang, Zili Xu*, JunWang, Song Yan, Zhen Wang. Gaussian process regression based remaining fatigue life prediction for metallic materials under two-step loading[J]. International Journal of Fatigue.

[13] Cun Xin, Manqing Qin, Mengfu He, Zili Xu*. An approach for damage detection in noisy environments using DOG multi-scale space and fractal dimension[J]. Nondestructive Testing and Evaluation.

[14] 李康迪, 周倩倩, 徐自力*, 王鑫, 靳亚峰. 考虑进口预旋的阶梯型迷宫密封转子动力特性研究[J/OL]. 学报, 2022, 56(03):117-123, EI20221411918562.

[15] 仲继泽, 邱昌林, 沈渡, 孙启滨, 杜堃, 徐自力*. 管路附件对管路系统声传递-辐射特性的影响[J/OL]. 学报, 2022,56(01):79-84.

[16] 王存俊, 徐自力*. 基于Transformer网络的多源信号融合及智能故障诊断研究[C], 2022年全国设备监测诊断与维护学术会议 暨第十八届全国设备故障诊断学术会议 暨第二十届全国设备监测与诊断学术会议, pp3979-3982, 2022812-14, 山西, 太原, 中国振动工程学会故障诊断专业委员会、中国机械工程学会智能运维分会、中国设备管理协会设备诊断工程委员会.

[17] 徐自力. 基于视觉的结构全场高分辨率振动测量技术及应用[C]. 2022 年第七届装备环境工程发展论坛云南省昆明市. 2022.11.10-11.13, 主办单位:2022 年第七届装备环境工程发展论坛组委会.

[18] Jingjing Gao, Jun Wang, Zili Xu*, Cunjun Wang, Song Yan. Multiaxial fatigue prediction and uncertainty quantification based on back propagation neural network and Gaussian process regression[J]. International Journal of Fatigue. 2023(168): 107361, DOI: 10.1016/j.ijfatigue.2022.107361

 

2021

[1] Cunjun Wang, Cun Xin, Zili Xu*. A novel deep metric learning model for imbalanced fault diagnosis and toward open-set classification[J]. Knowledge-Based Systems, 2021, 220: 106925.

[2] Cunjun Wang, Zili Xu*. An intelligent fault diagnosis model based on deep neural network for few-shot fault diagnosis[J]. Neurocomputing, 2021, 456: 550-562.

[3] 邱恒斌, 徐自力*. 分形接触干摩擦模型及在围带叶片受迫响应分析中的应用[J]. 动力学与控制学报, 2021, 19(04): 48-54.

[4] 徐自力, 谢石林.将科研四要素有机融入振动力学教学全过程的实践与思考[C]. 第十四届全国振动理论及应用学术会议(NVTA2021), P10. 2022.10.22.~10.25

[5] 徐自力, 刘畅, 王 珺, 闫 松, 黄道琼. 大推力液体火箭发动机涡轮盘共振机理及安全评价[C]. 第十四届全国振动理论及应用学术会议(NVTA2021), P66. 2022.10.22.~10.25

[6] 龚志诚, 徐自力*, 霍鑫杰, 王珺, 黄金平. 涡轮泵大轴向游隙球轴承动态特性分析模型及数值求解方法[C].第四届中国空天技术论坛论文集, P184~189, 江西上饶, 2021.6.14-6.17

[7] 李康迪, 徐自力*, 赵仕志, 成露. 基于气动力残差收敛架构的半隐式流固耦合算法[C]. 第十七届全国空气弹性学术交流会议论文集, 沈阳, 2021.10.10~10.12

[8] 徐自力, 王存俊, 刘畅. 长尾分布数据下的动力装备智能诊断研究[C]. 高端装备动力学与健康维护创新论坛论文集. 高端装备动力学与健康维护创新论坛暨中国振动工程学会转子动力学专业委员会第十一届一次常务理事会议, 广东省东莞,  2021.5.8~5.12

 

2020

[1] Tian Guo, Lianping Wu, Cunjun Wang, Zili Xu*. Damage detection in a novel deep learning framework: a robust method for feature extraction[J]. Structural Health Monitoring.2019.1-19, 2020, 19, 424-442.

[2] 郭奕蓉, 张建勋, 谭丁森, 徐自力*, 秦庆华. -热载荷下双金属复合管的屈曲失效研究[J]. 计算力学学报, 2020, 37(2):137-144. 

[3] 杜云祥, 徐自力*, 焦玉雪, 李康迪. 基于振动时滞的非零叶间相位角叶片颤振分析[J], 航空动力学报, 2020,35(8):1752-1761.

[4] 潘渤, 徐自力*,赵博, 葛祥. 三交叉弦结构非线性自由振动频率特性分析振动与冲击[J]. 2020, 39(8):186-192.

[5] 庾明达, 徐自力*, 刘贞谷, 冯志鹏, 张毅雄, 陈建国. 整体弹性结构法及在叶片流固耦合分析中的应用[J]. 推进技术. 2020,41(6):1379-1386.

[6] 李康迪, 徐自力*, 杜云祥. 压气机失速先兆及转子多工况流场的DMD分析[J]. 航空动力学报, 2020, 35(11), 2409-2416.

[7] 焦玉雪, 徐自力*, 尹刚, 吴方松, 范小平. 太阳能光热发电汽轮机转子热机械应力分析及启动优化[J]. 汽轮机技术, 2020, 62(06): 417-420.

[8] 徐自力*, 杜云祥, 焦玉雪. 基于振动时滞的非零叶间相位角叶片颤振分析方法及应用[C]. 第十四届全国转子动力学学术大会, 2020.10.29-11.02, p39

 

2020年前

[1] 徐自力, 周子宣. 航空发动机多级叶盘-轴系统扭转耦合振动特性[J]. 交通运输工程学报, 2019,19(3):79-88. Xu Zili, Zhou Zixuan. Torsional coupled vibration characteristics of multi-stage blade disc-shaft system of aeroengine[J]. Journal of Traffic and Transportation Engineering. 2019,19(3):79-88.

[2] 周子宣, 徐自力*. 三维叶盘失谐模态分析的摄动降阶方法[J]. 学报, 2019,53(9):42-48.

[3] 徐自力, 赵宇, 刘畅. 660MW汽轮发电机组末级长叶片与轴系耦合振动的理论分析和试验研究, 编号:T06_W_01, 第十三届全国振动理论及应用学术会议(NVTA2019), P250, 2019.11.9 – 11.

[4] 杜云祥, 徐自力*, 焦玉雪. 基于振动时滞法的非零叶间相位角叶片颤振分析,编号:T19_W_01, 第十三届全国振动理论及应用学术会议(NVTA2019), P345, 2019.11.9 – 11.

[5] 辛存, 徐自力*, 郭天. 机械结构振动测量的计算机视觉方法, 2019 年陕西省宇航学会学术交流会论文集. 2019.7.4-6, 1097-1104.

[6] 周倩倩, 徐自力*. 推进剂贮箱液体晃动与振动特性研究. 2019 年陕西省宇航学会学术交流会论文集. 2019.7.4-6, 828-833.

[7] 王存俊, 徐自力*, 郭天, . 大阻尼层合结构界面粘接质量检测的频响函数奇异值熵方法. 2019 年陕西省宇航学会学术交流会论文集. 2019.7.4-6,1230-1239.

[8] Tian Guo, Zili Xu*. Structural health monitoring using DOG multi-scale space: An approach for analyzing damage characteristics[J]. Smart Materials and Structures, 27(3),1361-665, 2018.

[9] Jize Zhong, Zili Xu*. A reduced mesh movement method based on pseudo elastic solid for fluid structure interaction. Proceedings of the Institution of Mechanical Engineers, Part C: Journal of Mechanical Engineering Science, 2018.232(6):973-986.

[10] Jize Zhong, Zili Xu*. A time-space synchronized fluid structure coupling algorithm for the prediction of wing flutter[J]. Proceedings of the Institution of Mechanical Engineers, Part G: Journal of Aerospace Engineering, 2018,232(5):922-931. 

[11] Xuanen Kan, Zili Xu*. Vibration localization for a rotating mistuning bladed disk with the Coriolis effect by a state space decoupling method[J]. Pro. ImechE Part G: Journal of Aerospace Engineering. 2017, DOI:101177/0954410017744238.

[12] Jize Zhong, Zili Xu*. A reduced mesh movement method based on pseudo elastic solid for fluid structure interaction. Proceedings of the Institution of Mechanical Engineers, Part C: Journal of Mechanical Engineering Science.2017, DOI: 10.1177/0954 406 217700177.

[13] Tian Guo, Zili Xu*. Data fusion of multi-scale representations for structural damage detection[J]. Mechanical Systems and Signal Processing.98:1020-1033.2017.

[14] Xuanen Kan, Zili Xu*, Bo Zhao, Jize Zhong. Effect of Coriolis Force on Forced Response Magnification of Intentionally Mistuned Bladed Disk[J].Journal of Sound and Vibration.399(7): 124-136. 2017.

[15] Jize Zhong, Zili Xu*. A modal approach for coupled fluid structure computations of wing flutter[J]. Proceedings of the Institution of Mechanical Engineers, Part G: Journal of Aerospace Engineering.231(1):72-81.2017.

[16] Jize Zhong, Zili Xu*,An energy method for flutter analysis of wing using one-way fluid structure coupling[J]. Proceedings of the Institution of Mechanical Engineers, Part G: Journal of Aerospace Engineering.231(14): 2560–2569, 2017.

[17] Jize Zhong, Zili Xu*, Coupled fluid structure analysis for wing 445.6 flutter using a fast dynamic mesh technology[J].International Journal of Computational Fluid Dynamics, 30(7-10): 531-542, 2016.

[18] Bo Zhao, Xuanen Kan, Zili Xu*, Jize Zhong, Tian Guo. Structural damage detection by using single natural frequency and the corresponding mode shape[J]. Shock and Vibration, 2016(1):1-8. 2016.

[19] Jize Zhong, Zili Xu*. Effect of the coverage of dynamic mesh region on the efficiency and accuracy of coupled fluid structure simulation for blade flutter[C]. Proceedings of ASME Turbo Expo 2015, GT2015-43147. June 15-19, 2015, Montréal, Canada. SCI: UT CSCD:6075444.

[20] Xuanen Kan, Zili Xu*, Yu Zhao, Baitong Dou, Wenbin Zhao. Tiejun Wang. Transient response of control stage blade disk due to partial admission by a reduced method[C]. Proceedings of ASME Turbo Expo 2015, GT2015-43194. June 15-19, 2015, Montréal, Canada. EI: 20160301830532.

[21] Chen Dexiang, Zili Xu*, Shi Liu, Xiong-xin Feng. Least Squares Finite Element Method with High Continuity NURBS Basis for Incompressible Navier-Stokes Equations[J].  Journal of computational physics,260:204-221. 2014.

[22] Xu Zili, Yang Yi, Zhang chunmei. Modeling contact interface between rough surfaces based on fractal contact model and thin layer elements[C]. 20th International Congress on Sound and Vibration (ICSV20), Bangkok, Thailand, 7-11 July 2013, ICSV20-593

[23] Yalin Liu,Bo Shangguan,Zili Xu*. A friction contact stiffness model of fractal geometry in forced response analysis of shrouded blade[J]. Nonlinear Dynamics, 70(3):2247-2257. 2012.

[24] Shangguan Bo, Zili Xu*. Experimental study of friction damping of blade with loosely assembled dovetail attachment[J]. Proceedings of the Institution of Mechanical Engineers, Part A: Journal of Power and Energy,226(6) 738–750. 2012.

[25] Gu Weiwei, Zili Xu*, Liu Yalin. A method to predict the nonlinear vibratory response of bladed disk system with shrouded dampers[J]. Proceedings of the Institution of Mechanical Engineers(Proc. IMechE),Part C, Journal of Mechanical Engineering Science. 2012,226(6):1620-1632.

[26]Weiwei Gu, Zili Xu*, Shangjin Wang. Advanced modeling of friction contact in three-dimensional motion when analysing of the forced response of a shrouded blade. Proc. IMechE Part A: Journal of Power and Energy.,224:573-582.2010.