个人信息:
姓名:张婷 职称:副教授
专业:机械工程 学历层次:博士研究生
办公室地点:行政楼1008 办公电话:021-67791193
电子邮箱:zhangt@sues.edu.cn
研究方向:结构振动控制
主讲课程:《工程力学一》、《工程力学二》、《机械振动学》
个人简介:(教育背景、工作经历)
张婷,女,副教授。2014年毕业于上海交通大学机械工程专业,获得工学博士学位。现于上海工程技术大学从事教学与科研工作,主要从事机械振动控制与振动信号传感等方向的科研工作。近年来主持一项校启动课研项目1项、青培项目1项、横项课题1项与青年基金项目1项,并发表有关研究领域的学术论文有20余篇。
主要科研成果:(代表性论文、专利、著作等)
[1] Zhang T,Li HG and Bi Y. Hysteresis characteristics influence on the super-harmonic vibration of a bi-stable piezoelectric energy harvester. Journal of Low Frequency Noise Vibration and Active Control, 2018, 37(4): 1003-1014.
[2] Ting Zhang, Ying Pan, Lijie Cao. Dynamical Model for an Interharmonic Property of a Piezoelectric Bimorph Cantilever Beam with Self-Sensing Function. Shock and Vibration, 2016, 2016:1-9.
[3] Zhang T, Li HG, Zhong ZY, et al. Hysteresis model and adaptive vibration suppression for a smart beam with time delay. Journal of Sound and Vibration, 2015, 358:35-47.
[4] T Zhang, HG Li, GP Cai, FC Li. Experimental Verifications of Vibration Suppression for aSmart Cantilever Beam with a Modified Velocity Feedback Controller, Shock and Vibration, 2014,172570(9pp).
[5] Zhang T, Yang BT, Li HG, Meng G. Dynamic Modeling and Adaptive Control of a GiantMagnetostrictive Actuator for Vibration Control. Sensors and Actuators A: Physical, 2013, 190:96–105.
[6] Zhang T, Li HG. Adaptive Pole Placement Control for Vibration Control of a Smart CantileveredBeam in Thermal Environment. Journal of Vibration and Control, 2013, 19(10) 1460 – 1470.
[7] Zhang T, Li HG, Cai GP. Hysteresis Identification and Adaptive Vibration Control for a SmartCantilever Beam by a Piezoelectric Actuator. Sensors and Actuators A: Physical, 2013, 203:168-175.
[8] T Zhang, HG Li, JJ Zhao. Vibration Control and Dynamical Model of a Thermal-Electrical-Mechanical Coupled Smart Cantilevered Beam, Advanced Engineering Forum, 2012, 2-3:535-540.
[9] Ting Zhang, Hao Lina, Chunlei Wang. The Periodic Output Feedback Control for Creep Characteristics of IPMC. Chinese Control and Decision Conference, 2010, 3992-3997.
[10] Li Jun, Zhang Ting, Wu Zidong et al. A breeze energy harvesting of vibration caused with a cantilevered piezoelectric beam. Vibroengineering Procedia, 2019, 29: 49-53.
[11] Pan Y, Zhang T. Dynamical model of a fault phenomenon and reliability analysis for a circuit breaker in a vibration environment. Vibroengineering Procedia, 2019, 23: 43-48.
[12]胡晓琳, 张婷. 基于自校正PID控制的智能悬臂梁振动控制. 噪声与振动控制, 2019, 39 (2): 21-26.
[13] Wang RP, Zhang T and Yang Y. Adaptive vibration control for a cantilevered beam using actuating and sensing functions of a piezoelectric bimorph. Vibroengineering Procedia, 2018, 20: 87-90.
[14] Hu X, Zhang T. First two modal adaptive vibration control for a smart beam with two piezoelectric bimorphs by a self-tuning PID control. Journal of Physics Conference Series, 2018, 1074:012044.
[15] Wang CL, Zhang T, Wei XH, et al. Dynamic characteristics and stability criterion of rotary galloping gait with an articulated passive spine joint. Advanced Robotics, 2017, 31(4): 168-183.
[16] Chunlei Wang, Ting Zhang, Xiaohui Wei, et al. Dynamic Imbalance Analysis and Stability Control of Galloping Gait for a Passive Quadruped Robot. Applied Bionics and Biomechanics, 2015, 2015:1-17.
[17] BT Yang, T Zhang, JQ Li, FC Li, HG Li and G Meng. Research on GiantMagnetostrictiveActuator for Low Frequency Adaptive Vibration Control. Advances in Vibration Engineering, 2013, 12(6): 611-622.
[18] BT Yang, QW Liu, T Zhang, Y Cao, ZQ Feng, G Meng. Non-contact Translation-RotationSensor Using Combined Effects of Magnetostriction and Piezoelectricity. Sensors, 2012, 12(10),13829-13841.
[19] Song W, Nazarova, MN, Zhang Y, Zhang T and Li M.Sparse reconstruction based on the admm and lasso-lsqr for bearings vibration signals. IEEE Access. 2017,5:20083-20088.
[20] Zhong ZY, Zhou JP, Zhang HL andZhang T. Effect of the equivalent stiffness of flexible supports on the mems cantilever-based sensors. Computers & Structures, 2016, 169, 101-111.
