◎研究方向 [1] 自供能主动振动控制系统 [2] 基于强化学习的控制算法优化研究 [3] 电磁高性能振动控制与能量采集系统
◎教育经历 香港理工大学 博士 2011.9-2017.1 香港理工大学 本科 2007.9-2011.8
◎工作经历 太阳成集团副教授 2018.2-至今 香港理工大学 博士后 2017.2-2018.1
◎学术兼职 中国振动工程学会结构抗振控制与健康监测青年委员会委员 《Mechanical System and Signal Processing》、《Engineering Structures》、《Journal of Sound and Vibration》等期刊审稿人。 《Structural Control and Health Monitoring》特刊《Recent Advances in Smart Structures》客座编辑。
◎主讲课程 传感器原理 传感器与检测技术 测试信号分析与处理 无损检测技术
◎指导研究生及博士后 2018级 石伟 2019级 关岫 赵复磊 2020级 吴智巍 于庆阳 2021级 王镜洋 卫筱林 马骏驰 2022级 陈元滨 卢平 李敬真 左瑶 2023级 王旭东 张锦红 潘阳 2024级 于文婷 曾梦婷 2025级 王睿清 张来鑫 颜凯
◎承担项目 [1]中石化胜利油田技术检测中心,CO2 驱移动式标准装置隔振优化研究及测控平台开发,主持。 [2]山东省自然科学基金,面上项目,拉索自供能主动减振方法与试验研究,主持。 [3]国家自然科学基金,青年科学基金项目,基于负刚度逆势能循环的拉索主动减振机理与优化研究,主持 [4]山东省自然科学基金,博士基金,基于负刚度的拉索多模态振动控制技术,主持。 [5]太阳成集团学校项目,基于负刚度和磁流变液体的混合振动控制技术,主持。 [6]中石油重大科技合作项目,基于宽频电/声响应信息融合的含水合物饱和度评价方法研究,参与。 [7]自主创新科研计划项目(理工科)科技专项,基于宽频电/声响应信息融合的含水合物饱和度评价方法研究,参与。
◎获奖情况 [1]2022年获得香港工程师学会结构分部颁发的结构卓越奖大奖(The Hong Kong Institution of Engineers Structural Division, Structural Excellence Award 2022: Grand Award) [2]2017年获International Council for Research and Innovation in Building and Construction香港理工大学员工分部博士生毕业论文比赛第一名
◎荣誉称号
◎著作
◎论文 [1]Shi, X., Li, J., Zhu, S., Cai, Q.*, Dai, K., & Han, W. (2025). Negative stiffness energy-harvesting electromagnetic damper for vibration control of bridge stay cable. Engineering Structures, 332, 120072. [2]张智强, 李高峰, 王高云, 王杰, 王宏伟,隋国勇,石翔*. (2025). 外部振动对科里奥利质量流量计测量精度分析与误差建模. 科学技术与工程{25}(36), 15516-15524. [3]Shi, X., Wang, J., Lu, P., Xing, H., & Li, J. Y.* (2025). Robustness analysis of self-powered active electromagnetic suspension system using interval model. Journal of Vibration Engineering & Technologies, 13(2), 195. [4]Cai,Q., Lu, P, Chen, Y., & Shi, X.* (2024). Robustness analysis for the vibration control performance of energy-harvesting tuned mass damper with uncertainties. Smart Materials and Structures, 33(8), 085004. [5]Shi, X., Wei, X., Li, J. Y., Xing, H., & Cai, Q.* (2024). Robustness Evaluation of Negative Stiffness Damper for Cable Vibration Mitigation Based on Interval Model with Experimental Validation. Structural Control and Health Monitoring, 2024(1), 1258183. [6]Shi, X., Yu, Q., Wu, Z., Li, J. Y.*, & Zhu, S. (2024). Active control for vehicle suspension using a self-powered dual-function active electromagnetic damper. Journal of Sound and Vibration, 569, 117976. [7]Shi, X., Wu, Z., Hua, Y., Shi, W., Zhu, S., & Li, J.* (2024). Tracking active control forces by using a semi-active vehicle suspension integrated with negative stiffness. International Journal of Structural Stability and Dynamics, 24(02), 2450019. [8]Shi, X., Ma, J., Xing, L., Li, J. Y.*, & Zhu, S.* (2022). Analytical study on the effects of flexural rigidity and negative stiffness in the optimal tuning of inerter-based damper for cable vibration mitigation. Advances in Structural Engineering, 25(16), 3316-3333. [9]Shi, X., Guan, X., Shen, W.*, & Xing, L. (2022). A control strategy using negative stiffness and semi‐active viscous damping for fully tracking active control force for bridge cables: Principles and simulations. Structural Control and Health Monitoring, 29(9), e2989. [10]Hua, Y., Zhu, S.*, & Shi, X. (2022). High-performance semiactive secondary suspension of high-speed trains using negative stiffness and magnetorheological dampers. Vehicle System Dynamics, 60(7), 2290-2311. [11]Shi, X., Zhao, F., Yan, Z., Zhu, S.*, & Li, J. Y. (2021). High‐performance vibration isolation technique using passive negative stiffness and semiactive damping. Computer‐Aided Civil and Infrastructure Engineering, 36(8), 1034-1055. [12]Shi, X., Shi, W., Lin, K., Xing, L., & Zhu, S.* (2021). Optimal design of tuned inerter dampers with series or parallel stiffness connection for cable vibration control. Structural Control and Health Monitoring, 28(3), e2673. [13]Li, J. Y., Zhu, S.*, Shi, X., & Shen, W. (2020). Electromagnetic Shunt Damper for Bridge Cable Vibration Mitigation: Full-Scale Experimental Study. Journal of Structural Engineering, 146(1), 04019175. [14]Shi, X, & Zhu, S.* (2019). A comparative study of vibration isolation performance using negative stiffness and inerter dampers. Journal of the Franklin Institute, 356(14), 7922-7946. [15]Yan, Z.*, Yin, X., Yao, Y., Liu, J., Liu, M., Wang, J., ... & Shi, X. (2019). Simulation study of rotor erosion for a continuous-wave pulse generator by computational fluid dynamics. Systems Science & Control Engineering, 7(1), 460-467. [16]Shi, X.*, Shi, W., & Xing, L. (2019). Performance analysis of vehicle suspension systems with negative stiffness. Smart Structures and Systems, 24(1), 141-155. [17]Shi, X., Zhu, S.*, Ni, Y. Q., & Li, J. (2018). Vibration suppression in high-speed trains with negative stiffness dampers. Smart Structures and Systems.21(5), 653-668 [18]Shi, X., & Zhu, S.* (2018). Dynamic characteristics of stay cables with inerter dampers. Journal of Sound and Vibration, 423, 287-305. [19]Shi, X., & Zhu, S.* (2018). Nonlinear impact of negative stiffness dampers on stay cables. Structural Monitoring and Maintenance, 5(1), 15-38. [20]Shi, X., Zhu, S.*, & Nagarajaiah, S. (2017). Performance comparison between passive negative-stiffness dampers and active control in cable vibration mitigation. Journal of Bridge Engineering, 22(9), 04017054. [21]Shi, X., Zhu, S.*, & Spencer Jr, B. F. (2017). Experimental study on passive negative stiffness damper for cable vibration mitigation. Journal of Engineering Mechanics, 143(9), 04017070. [22]Shi, X., & Zhu, S.* (2017). Simulation and optimization of magnetic negative stiffness dampers. Sensors and Actuators A: Physical, 259, 14-33. [23]Shi, X., Zhu, S.*, Li, J. Y., & Spencer Jr, B. F. (2016). Dynamic behavior of stay cables with passive negative stiffness dampers. Smart Materials and Structures, 25(7), 075044. [24]Shi, X., & Zhu, S.* (2015). Magnetic negative stiffness dampers. Smart materials and structures, 24(7), 072002. [25]Zhu, S.*, Shi, X., Leung, R. C., Cheng, L., Ng, S., Zhang, X., & Wang, Y. (2014). Impact of construction-induced vibration on vibration-sensitive medical equipment: a case study. Advances in Structural Engineering, 17(6), 907-920.
◎专利 [1]石翔;潘阳;张锦红;基于双重谐振的仪表减振控制方法及系统,ZL202511923598.6 [2]石翔;曾梦婷;李敬真;传感器布置与反馈算法协同优化振动控制的方法,ZL202511324570.0 [3]石翔;左瑶;李敬真;结构振动控制中传感器布置与反馈控制算法联合优化方法, ZL202411874089.4 [4]石翔;卢平;张锦红;电磁转换常数可调的自适应电磁减振系统及方法, ZL202411237098.2 [5]石翔;关岫;于庆阳;二维平面负刚度装置, ZL202111351808.0,ZL202110817152.0 [6]石翔;吴智巍;鄢志丹;李毅;王福民;王文兵;温室大棚自动控温装置及方法 [7]石翔;一种基于负刚度和可变阻尼的混合振动控制装置、方法及应用,ZL201811553244.7 [8]朱松晔;石翔; 用于产生负刚度的电磁设备和振动控制的方法, ZL201710113005.9 [9]石翔;一种被动线性磁负刚度装置,ZL201610185997.1 [10]石翔;直流电磁负刚度装置,ZL201510262372.6
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