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个人经历 Personal experience 工作经历 教育经历 2018年1月至今，西北工业大学无人系统技术研究院，副教授 2014年10月至2017年10月，巴黎萨克雷大学，国立高等先进技术学院，固体力学，博士2011年09月至2014年04月，西北工业大学，机电学院，航空宇航制造工程，硕士2010年06月至2011年06月，西北工业大学，机电学院，飞行器制造工程，学士2007年09月至2010年06月，西北工业大学，教育实验学院，本硕连读

教育教学

科学研究 Scientific Research 研究方向智能材料与结构的表征建模方法、基于智能材料的仿生变体结构设计、智能驱动技术及变体结构设计、抗冲击结构与减振结构设计、变刚度结构及其优化设计等研究工作。硕博士研究生招生专业：无人系统科学与技术（99G200，学术型），机器人工程（085510，专业型）。科研项目2022.10-2024.10，173基金，基于智能可变形材料的XXX飞行器技术2021.01-2023.12，GF重点实验室基金，基于XXX结构的变外形无人机技术2021.01-2024.12，中国航发自主创新专项，形状记忆材料航空发动机排气系统应用技术2020.05-2022.04，GFKJCXTQ项目，仿生智能点阵一体化技术2020.01-2022.12，中国科协青年人才托举工程，智能变体机构的材料-结构-工艺多因素一体化设计2020.01-2021.12，陕西省留学人员择优资助项目，镍钛合金功能构件成形-装配-服役一体化分析技术2020.01-2023.12，GFKJCXTQ项目子课题，流动稳定机理及自适应变形技术2020.01-2021.12，HJJ型号基础预研课题，结构可变刚度优化设计技术2020.01-2020.12，西安现代控制技术研究所，形状记忆合金智能驱动机构设计2019.01-2021.12，国家自然科学基金青年项目，形状记忆合金內滞回效应机理分析与本构建模2018.11-2019.10，GFKJCXTQ项目子课题，轻质超弹性复合装甲设计2018.10-2019.07，GFKJCXTQ项目子课题，共用动力低成本结构设计2018.01-2020.12，中央高校基本科研业务费项目，形状记忆合金有限变形与热力耦合行为表征建模

荣誉获奖

教育教学 Education and teaching 教育教学 本科生科学素养课《智能材料与结构系统》、《智能无人系统技术及应用》，本科生大类平台课《工程力学上册》，研究生专业课《智能材料与结构系统》、《智能无人系统前沿技术》。

科学研究

学术成果 Academic Achievements 期刊论文2022[21] Wang J, Huang B, Gu X, et al. Actuation performance of machined helical springs from NiTi shape memory alloy[J]. International Journal of Mechanical Sciences, 2022, 236: 107744.[20] Wang L, Wang J（通讯）, Xu Y, et al. Free vibration of pseudoelastic NiTi wire: finite element modeling and numerical design. Mechanics of Advanced Materials and Structures, 2022: 1-14.[19] Wang J , Cao Y , Xu Y , et al. Finite element modeling of the damping capacity and vibration behavior of cellular shape memory alloy. Mechanics of Advanced Materials and Structures, 2022, 29(15): 2142-2155.2021[18] Wang J, Gu X, Xu Y, et al. Thermomechanical modeling of nonlinear internal hysteresis due to incomplete phase transformation in pseudoelastic shape memory alloys. Nonlinear Dynamics, 2021, 103(2): 1393-1414.2020[17] Gu X, Su X, Wang J（通讯）, et al. Improvement of the impact resistance of plain-woven composite by embedding superelastic shape memory alloy wires. Frontiers of Mechanical Engineering, 2020, 15(9):1-11.[16] Wang J, Ren X, Xu Y, et al. Thermodynamic behavior of NiTi shape memory alloy against low-velocity impact: experiment and simulation. International Journal of Impact Engineering, 2020, 139: 103532.[15] You Y, Wang J（通讯）, Su X, et al. Effect of plasticity on superelasticity and hysteretic dissipation of NiTi shape memory alloy. Materials Today Communications, 2020: 101137.2019[14] Wang S, Wang J（通讯）, Xu Y, et al. Compressive behavior and energy absorption of polymeric lattice structures made by additive manufacturing. Frontiers of Mechanical Engineering, 2019: 1-9.[13] Wang J, Xu Y, Zhang W, et al. Thermomechanical Modeling of Amorphous Glassy Polymer Undergoing Large Viscoplastic Deformation: 3-Points Bending and Gas-Blow Forming. Polymers, 2019, 11(4): 654.[12] Wang J, Xu Y, Zhang W, et al. A finite-strain thermomechanical model for severe superplastic deformation of Ti-6Al-4V at elevated temperature. Journal of Alloys and Compounds, 2019, 787: 1336-1344.[11] Wang J, Zhang W, Zhu J, et al. Finite element simulation of thermomechanical training on functional stability of shape memory alloy wave spring actuator. Journal of Intelligent Material Systems and Structures, 2019, 30(8): 1239-1251.2018[10] Wang J, Xu Y, Gao T, et al. A 3D thermomechanical constitutive model for polycarbonate and its application in ballistic simulation. Polymer Engineering & Science, 2018, 58: 2237-2248.[9] Moumni Z, Zhang Y, Wang J, et al. A Global Approach for the Fatigue of Shape Memory Alloys. Shape Memory and Superelasticity, 2018: 1-17.2017[8] Wang J, Moumni Z, Zhang W. A thermomechanically coupled finite-strain constitutive model for cyclic pseudoelasticity of polycrystalline shape memory alloys. International Journal of Plasticity, 2017, 97: 194-221.[7] Wang J, Moumni Z, Zhang W, et al. A thermomechanically coupled finite deformation constitutive model for shape memory alloys based on Hencky strain. International Journal of Engineering Science, 2017, 117: 51-77.[6] Wang J, Moumni Z, Zhang W, et al. A 3D finite-strain-based constitutive model for shape memory alloys accounting for thermomechanical coupling and martensite reorientation. Smart Materials and Structures, 2017, 26(6): 065006.2016[5] Wang J, Xu Y, Zhang W, et al. A damage-based elastic-viscoplastic constitutive model for amorphous glassy polycarbonate polymers. Materials & Design, 2016, 97: 519-531.[4] Xu Y, Gao T, Wang J, et al. Experimentation and modeling of the tension behavior of polycarbonate at high strain rates. Polymers, 2016, 8(3): 63.2014[3] Wang J, Xu Y, Zhang W. Finite element simulation of PMMA aircraft windshield against bird strike by using a rate and temperature dependent nonlinear viscoelastic constitutive model. Composite Structures, 2014, 108: 21-30.[2] Dar U A, Zhang W, Xu Y, Wang J. Thermal and strain rate sensitive compressive behavior of polycarbonate polymer-experimental and constitutive analysis. Journal of Polymer Research, 2014, 21(8): 519.2013[1] Uzair A, Wang J, Xu Y J, et al. High-Speed Bird Impact Analysis of Aircraft Windshield by Using a Nonlinear Viscoelastic Model. Applied Mechanics and Materials. Trans Tech Publications, 2013, 290: 85-90. 会议论文[7] 王骏，形状记忆合金內滞回效应机理分析与热力学本构建模，2019中国力学大会-相变固体材料的多尺度多场耦合力学行为分会场，杭州，2019年8月。[6] 王骏，许英杰，朱继宏，张卫红，基于形状记忆合金的轻质抗冲击复合材料与结构，2019中国轻型材料应用及发展论坛，格尔木，2019年7月。[5] 王骏，形状记忆合金波浪弹簧热力学训练行为有限元分析，2018全国固体力学学术会议-智能材料多场耦合变形行为分会场，哈尔滨，2018年11月。[4] 王骏，形状记忆合金功能构件役前训练行为热力学分析，中国科协第365次青年科学家论坛“先进直升机关键材料与制造技术”，北京，2018年10月。[3] Wang J, Moumni Z, Zhang W, et al (2017, May). A thermomechanical Hencky strain constitutive model for shape memory alloys (CSMA 2017), Giens(Var), France[2] Wang J, Moumni Z, Zhang W (2016, June). A thermo-mechanical constitutive model of shape memory alloys in finite deformation (ECCOMAS 2016), Crete, Greece[1] Wang J, Xu Y, Zhang W & Moumni Z (2014, October). A new damage-based model for the nonlinear behavior of polycarbonate (MPMS 2014), Palaiseau, France

学术成果

综合介绍