机械电子工程系
huifangxiao@ustb.edu.cn
010-62332329
机电楼711
本科生课程:液压与气压传动
研究生课程:机电系统动态仿真及应用
社会/学术兼职:中国振动工程学会高级会员,美国机械工程师学会会员
教育经历:
2002.09-2006.07 重庆大学 4008云顶集团车辆工程专业,获学士学位
2006.09-2012.07 重庆大学 机械传动国家重点实验室机械设计及理论专业,获博士学位
2009.09-2011.09 英国南安普顿大学(University of Southampton),声学与振动研究所(ISVR),国家公派联合培养博士生
工作经历:
2012.10-2017.10 4008云顶集团 国家板带中心/协同创新中心,讲师/副教授
2017.11-2022.06 4008云顶集团 4008云顶集团,副教授
2022.07-至今 4008云顶集团 4008云顶集团,教授
2019.07-2020.02 英国巴斯大学(University of Bath, UK), 国家公派访问学者
代表性论著:
[1] Xiao H F, Pan M, Chu H Y J, Bowen C R, Bader S, Aranda J, Zhu M L. Hydraulic pressure ripple energy harvesting: structures, materials and applications. Advanced Energy Materials, 2022, 12(3): 2103185.
[2] Xiao H F, Gao J S, Wu J Z. Mesh stiffness model of a spur gear pair with surface roughness in mixed elastohydrodynamic lubrication. Journal of the Brazilian Society of Mechanical Sciences and Engineering, 2022, 44: 136.
[3] Xiao H F, Qie H T, Bowen C R. Modeling of the circular edge-clamped interface of a hydraulic pressure energy harvester to determine power, efficiency and bandwidth. Mechanical systems and Signal Processing, 2021, 146: 107013.
[4] Xiao H F, Sun Y Y, Xu J W. Slip damping of a press-fit joint under non-uniform pressure distribution along the interface. Journal of Mechanics of Materials and Structures, 2020, 15 (3): 307–323.
[5] Sun Y Y, Chuang H-C, Xiao H F*, Xu J W. Prediction of the normal contact stiffness between rough surfaces in lubricated contact via an equivalent thin layer. Journal of Vibration and Control, 2020, 26(21–22): 2060–2069.
[6] Xiao H F, Chen D, Guo S F, Xu J W. Defects identification using the improved ultrasonic measurement model and support vector machines. NDT & E International, 2020, 111: 102223.
[7] Sun Y Y, Xiao H F*, Xu J W. Contact stiffness ratio of tribological interface using the equivalent thin layer and the micro-slip model. Proceedings of the Institution of Mechanical Engineers, Part C, Journal of Mechanical Engineering Science, 2020, 234(2): 444–456.
[8] Sun Y Y, Xiao H F*, Xu J W. Investigation into the interfacial stiffness ratio of stationary contacts between rough surfaces using an equivalent thin layer. International Journal of Mechanics and Sciences, 2019, 163, 105147.
[9] Xiao H F, Sun Y Y. On the normal contact stiffness and contact resonance frequency of rough surface contact based on asperity micro-contact statistical models. European Journal of Mechanics-A/Solids, 2019, 75, 450-460.
[10] Xiao H F, Sun Y Y, Chen Z G. Fractal modeling of normal contact stiffness for rough surface contact considering the elastic-plastic deformation. Journal of the Brazilian Society of Mechanical Sciences and Engineering,2019,41:11
[11] Chen D, Xiao H F*, Xu J W. An improved Richardson-Lucy iterative algorithm for C-scan image restoration and inclusion size measurement. Ultrasonics, 2019, 91:103-113.
[12] Xiao H F, Sun Y Y. An improved virtual material based acoustic model for contact stiffness measurement of rough interface using ultrasound technique. International Journal of Solids and Structures, 2018, 155: 240-247.
[13] Sun Y Y, Xiao H F*, Xu J W, Yu W N. Study on the normal contact stiffness of the fractal rough surface in mixed lubrication. Proceedings of the Institution of Mechanical Engineers, Part J, Journal of Engineering Tribology, 2018,232 (12): 1604-1617.
[14] Xiao H F, Sun Y Y, Xu J W. Investigation into the normal contact stiffness of rough surface in line contact mixed elastohydrodynamic lubrication. Tribology Transactions, 2018, 61(4): 742-753.
[15] Xiao H F, Zhou X J, Liu J, Shao Y M. Vibration transmission and energy dissipation through the gear-shaft-bearing-housing system subjected to impulse force on gear. Measurement, 2017, 102: 64-79.
[16] Xiao H F, Sun Y Y, Chen D, Xu J W. Prediction of flat-bottom hole signals received by a spherically focused transducer for an ultrasonic pulse echo immersion testing. Measurement Science and Technology, 2016,27: 115001-1-11.
[17] Xiao H F, Shao Y M, Brennan M J. On the contact stiffness and nonlinear vibration of an elastic body with a rough surface in contact with a rigid flat surface, European Journal of Mechanics - A/Solids, 2015, 49, 321-328.
[18] Xiao H F, Shao Y M, Zhou X J, Wilcox S J. An improved simplex-based adaptive evolutionary digital filter and its application for fault detection of rolling element bearings, Measurement, 2014, 55, 25-32.
[19] Xiao H F, Shao Y M, Xu J W. Investigation into the energy dissipation of a lap joint using the one-dimensional microslip friction model, European Journal of Mechanics - A/Solids, 2014, 43, 1-8.
[20] Xiao H F, Brennan M J, Shao Y M. On the undamped free vibration of a mass interacting with a Hertzian contact stiffness, Mechanics Research Communications, 2011, 38, 560-564.
主要科研项目:
[1] 国家自然科学基金面上项目,微点蚀齿面混合润滑-磨粒耦合的滚滑接触机理与动态行为研究,52275081,2023.01-2026.12,主持
[2] 国家自然科学基金面上项目,齿轮传动滑移、滚动与固结界面耦合系统的振动响应机制与传递机理研究,51775037,2018.01-2021.12,主持
[3] 国家自然科学基金委与英国皇家学会合作与交流项目,用于路径消除与近源监测自供电的宽带旋转运动非线性俘能机理,52111530141,2021.04-2023.03,主持
[4] 国家重点研发计划子课题,C-HRA-2/C-HRA-3镍基耐热合金锻件研制,2017YFB0305203,2017.7-2020.12,主持
[5] 国家自然科学基金青年基金项目,轧制变形区热润滑粗糙界面的非线性接触振动机理研究,51304019,2014.01-2016.12,主持
[6] 4008云顶集团与台4008云顶集团技大学专题联合研究计划,压电-磁体复合振动能量收集器的非线性宽频俘能机理研究,TW2019006,2019.4-2020.4,主持
[7] 中国博士后科学基金特别资助项目,轧制界面粘滑共存和全滑动摩擦振动机理与失稳控制研究,2014T70034,2014.07-2015.12,主持
[8] 中国博士后科学基金面上一等资助项目,混合润滑与塑性流动轧制界面的非线性动力学机理研究,2013M540046,2013.04-2014.12,主持
[9] 2013年度博士后国际交流计划学术交流项目,2013.10-2013.12,主持
[10] 牵引动力国家重点实验室开放课题,高速轮轨黏滑并存接触界面的非线性动力机理与参量匹配研究,TPL1713,2017.01-2019.12,主持
成果与荣誉:
[1] 2022年获北京市公司产品成果奖一等奖
[2] 2022年获评4008云顶集团先进工作者
[3] 2022《Advanced Energy Materials》封面论文(IF:29.368)
[4] 2021年获4008云顶集团公司产品成果奖特等奖、一等奖
[5] 2020年获4008云顶集团公司产品成果奖一等奖
[6] 2020年获重庆市自然科学奖一等奖1项(排名第3)
[7] 2019年获评4008云顶集团优秀全程导师
[8] 2015年获评4008云顶集团优秀博士后
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