台湾av影片

导师

情况

硕导

学历

博士

职称

讲师

职务

无

邮编

243032

办公地点

机械楼505

电子邮箱

[email protected]

个

人

基

本

信

息

博士毕业于南京理工大学，期间赴澳大利亚悉尼科技大学联合培养一年。主持省基金和中国博士后面上基金项目各1项，企业横向1项，参与国家级纵向项目多项。以第一和通讯作者发表学术论文14篇，申请发明专利3项。 

主要研究方向：

（1）主动隔振与控制技术

（2）基于磁流变/电机驱动技术的抗冲击应用

（3）磁流变智能执行结构设计方法

主

持

项

目

[1] 台湾av影片 引进人才科研启动基金“短间隔循环冲击下磁流变-前冲复合缓冲控制机理研究”（2024.09-2027.08），在研，主持；

科

研

论

文

及

成

果

[1] Wang HX, Chen W, Hang T, Li ZC, Wang X, Chen Y, Zheng JJ. Multi-scale heterogeneous composite elastomer absorbers synergistically enhanced by CoNi nanospheres and carbon nanotubes[J]. Journal of Colloid and Interface Science, 2025, 682:11-21.

[2] Wang HX, Li D, Cai FX, Li YC, Wang J, Zheng JJ. Design and experiment study on a novel magnetorheological impact damper coupled with multiple parallel relief orifices for reducing higher impact peaks[J]. Journal of Intelligent Material Systems and Structures, 2025, 36(4), 242-258.

[3] Wang HX, Xue SN, Qian K, Li YC. Magnetic field-dependent dynamic behavior of magnetorheological grease composite in a wide temperature range: experiment and modeling[J]. Colloids and Surfaces A: Physicochemical and Engineering Aspects,2024,686: 133468.

[4] Wang HX, Li D, Xue SN, Sun JJ, Wang J. Design and experiment study of a novel dual-channel independent-coil magnetorheological grease damper[J]. Smart Materials and Structures, 2024, 33(3):035035.

[5] Wang HX, Huang XG, Liu Tao, Wang J. Modeling and Semi-Active Control Performance Analysis of MRE Isolator based on BPNN Optimized by GA using Different Evaluation Indexes[J]. Journal of Intelligent Material Systems and Structures, 2023, 34(20): 2428-2442.

[6] Wang HX, Chang TX, Li YC, Wang J. Characterization of nonlinear viscoelasticity of magnetorheological grease under large oscillatory shear by using Fourier transform-Chebyshev analysis[J]. Journal of Intelligent Material Systems and Structures, 2021, 32(5): 614-631.

[7] Wang HX, Chang TX, Li YC, Wang J. Field-frequency-dependent nonlinear rheology behavior of magnetorheological grease under large amplitude oscillatory shear[J]. Frontiers in Materials, 2021, 8: 642049.

[8] Wang HX, Zhang G, Wang J. Normal force of lithium-based magnetorheological grease under quasi-static shear with large deformation[J]. RSC advances, 2019,9(47): 27167-27175.

[9] Wang HX, Li YC, Zhang G, Wang J. Effect of temperature on rheological properties of lithium-based magnetorheological grease[J]. Smart Materials and Structures, 2019, 28(3): 035002.

[10] Wang HX, Zhang G, Wang J. Quasi-Static Rheological Properties of Lithium-Based Magnetorheological Grease under Large Deformation[J]. Materials, 2019, 12(15): 2431.

[11] 汪辉兴, 张广, 欧阳青, 王炅. 磁流变脂在剪切模式下的流变特性[J]. 上海交通大学学报, 2019, 53(3): 380-386.

[12] Mao RS, Zhang G, Wang HX(通讯作者), Wang J. Temperature dependent dynamic properties of magnetorheological gel composite: experiment and modeling[J]. Smart Materials and Structures, 2022, 31(3): 035002.

[13] Huang JC, Li SQ, Li YC, Wang HX(通讯作者). A heavy-duty magnetorheological fluid mount with flow and squeeze model[J]. Smart Materials and Structures, 2021, 30(8): 085012.

[14] Wang J, Zhang G, Wang HX, Ouyang Q, Zheng JJ, Li YC, Li ZC. Magneto-Rheological Materials and Their Applications: Use of magnetorheological shock absorber for impact loading mitigation with individually controllable coils[M]. Institution of Engineering and Technology, 2019.