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李盈利 — 博士生导师、硕士生导师

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  • 教师姓名:李盈利

  • 职称:教授

  • 教师拼音名称:liyingli

  • 性别:女

  • 所在单位:交通运输工程学院

  • 学历:研究生(博士后)

  • 入职时间:2016-03-15

  • 学位:博士学位

  • 毕业院校:湖南大学

  • 在职信息:在职

  • 学科:交通运输工程

  • 招生学科:交通运输工程

  • 通讯/办公地址

  • 邮箱

https://www.researchgate.net/profile/Yingli_Li3/publications


[109] Inertial Amplification and Negative Stiffness in a Frame-Based Metamaterial for Low-Frequency Vibration Attenuation  . Thin-Walled Structures.2026


[108] Hybrid stepwise topology optimization for versatile bandgap design in single-phase elastic metamaterials. Mechanical Systems and Signal Processing, 2026


[107] Hybrid Crawling–jumping Dynamics of a Vibration-driven Bristle Robot. Chaos, Solitons and Fractals. 2026,208:118228


[106] Crawling Motion and Dynamic Mechanism of a Dielectric Elastomer-Actuated Double-Cone Crawling Robot . Mechatronics. 2026,117:103510


[105] Customized bending of pneumatic soft robotic arms based on cylinder balloons and constraint tapes. Sensors and Actuators: A. Physical. 2026,399:117422


[104] Integrated flexible curved beam quasi-zero stiffness vibration isolator with multi-step payloads. Engineering Structures, 2026,351:122028


[103] A hybrid piezoelectric-triboelectric generator with inertial amplification for vibration energy harvesting. European Journal of Mechanics / A Solids. 2026,116 : 105851.


[102] Inverse design of multifunctional acoustic metamaterials with ventilation and directional acoustic control. Thin–Walled Structures. 2025, 217:113875


[101] Passive vibration-driven robots with magnetic bistable nonlinear energy sinks efficient low-frequency response. Nonlinear Dynamics. 2025 https://doi.org/10.1007/s11071-025-11473-w 


[100]  Inverse design on customised absorption of acoustic metamaterials with high degrees of freedom by deep learning. Mechanical Systems and Signal Processing. 2025, 237:112989


[99 ] Customized inverse design of integrative quas1-zero-stittness metastructures by data-driven method. Engineering Structures. 2025, 340:120744


[98]  集成减振与俘能特性的折叠梁超结构研究.铁道科学与工程学报.2025 DOI:10.19713/j.cnki.43-1423/u.T20250421 


[97]  A pneumatic soft gripper with pre-deformed stiffener inspired by blowing dragon toys. Mechanics of Advanced Materials and Structures. 2025


[96]  Floating projection topology optimization framework for efficient design of bi-connected 3D acoustic metamaterials. Computer Methods in Applied Mechanics and Engineering. 2025,441:118020


[95]  A high expansion and contraction ratio tendon-driven spiral soft robotic arm inspired by the potato tower. Mechanics of Advanced Materials and Structures. 2025, 1–15. https://doi.org/10.1080/15376494.2025.2482183


[94]  Inverse-designed multifunctional metamaterials for broadband acoustic absorption and ventilation. Composite Structures, 362, 2025, 119106,


[93] Tacticity-based chiral topological metamaterials for longitudinal and torsional wave manipulation. International Journal of Mechanical Sciences. (2025), doi: https://doi.org/10.1016/j.ijmecsci.2025.109922


[92] Three-field topology optimization of single-phase phononic crystals with desired bandgaps for elastic wave manipulation. Engineering Structures. 326 (2025) 119554


[91] Enhancing low-frequency motion of passive vibration-driven robots with inertial amplification structure: Modeling, simulations and experiments. Applied Mathematical Modelling. 140 (2025) 115877


[90]  Forward-backstepping design of phononic crystals with anticipated band gap by data-driven method.Mechanical Systems and Signal Processing, 2024


[89] Realization of topological Bragg and locally resonant interface states in one-dimensional metamaterial beam-resonator-foundation system.Journal of Physics D: Applied Physics.2024


[88] 高速列车下穿机场地下车站时车站站台噪声测试与分析. 应用声学. 2024


[87] 内插管共振腔-多孔材料组合吸声板结构低频宽带设计. 动力学与控制. 2024


[86] Topological optimization design of multi-material phononic crystals with floating projection constraints to achieve ultra-wide band gap. Composite Structures. 2024,346:118387


[85] Piezoelectric-triboelectric energy harvester with elastic double-side stoppers. International Journal of Mechanical Sciences, 2024, 280:109561


[84] Bandgap tunability and programmability of four-leaf clover shaped elastic metastructures. Thin-Walled Structures, 2024, 200:111965


[83] Full-band vibration isolation of multi-step quasi-zero stiffness systems, International Journal of Mechanical Sciences, 2024, 274:109277


[82] Limb-inspired quasizero stiffness structure for ultralow-frequency vibration attenuation, International Journal of Mechanical Sciences, 2024,274:109251


[81] Acoustic metasurface embedded with thin-walled plate based on phase modulation for multi-angle broadband sound absorption, Thin-Walled Structures, 2024, 199:111839


[80] Systematic topology optimization of elastic metamaterials for broadband bandgaps and customized mechanical properties. Mechanical Systems and Signal Processing, 2024, 211: 111260 (Q1, Impact factor: 8.934)


[79]  Tunable bandgap characteristic of various hexagon-type elastic metamaterials for broadband vibration attenuation. Aerospace Science and Technology, 2024, 145:108872 (Q1, Impact factor:5.457)


[78]  Wave propagation and vibration attenuation in spiral ABH metamaterial beams. International Journal of Mechanical Sciences. 2024, 269:108976 (Q1, Impact factor: 6.772)


[77]  Low-frequency broadband sound absorption of the metastructure with extended tube resonators and porous materials Applied Acoustics. 2024, 217:109827  (Q1, Impact factor:3.641)


[76]  Transfer path analysis of a railway vehicle based on Global Transfer Direct Transfer (GTDT), International Journal of Heavy Vehicle Systems. 2024, 1(31):1-31 (Q4, Impact factor: 0.54)


[75] Quasi-full bandgap generating mechanism by coupling negative stiffness and inertial amplification. European Journal of Mechanics / A Solids,2024, 103, 105143 (Q1, Impact factor: 4.873)


[74] 旋转单元型打孔超结构设计及减振性能研究.振动与冲击. 2024.已录用(EI)


[73] 高速列车下穿机场地下车站时周边区域辐射噪声预测.应用声学. 2024.已录用(EI)


[72]  风电运维母船舱室噪声预报与吸声控制. 动力学与控制学报.2024.已录用(CSTPCD)


[71]  基于气动噪声数值分析的高速列车等效通过噪声预测. 铁道科学与工程学报.2024, 已录用 ( EI)


[70]  300 km/h高速列车过站时机场地下车站辐射噪声研究.噪声与振动控制, 2024,44(6), 已录用(CSSCD)


[69] Multi-objective optimization of elastic metaplates for lightweight and ultrawide bandgaps. International Journal of Mechanical Sciences, 2023, 108603 (Q1, Impact factor: 6.772, ISSN: 0020-7403, 2023.7)


[68] Bandgap mechanisms and wave characteristics analysis of a three-dimensional elastic metastructure. International Journal of Structural Integrity. 2023, 14(4):564-582. (Q2, ISSN: 1757-9864, Impact factor: 1.34, 2023.2)


[67]  Elastic wave propagation and vibration characteristics of diamond-shaped metastructures. Archive of Applied Mechanics. 2023. https://doi.org/10.1007/s00419-023-02468-3(Q2, ISSN: 0939-1533, Impact factor: 2.467 , 2023.7)[66] 复合负泊松比蜂窝超结构板低频减振特性研究.动力学与控制学报.2023,21(7):12-19 (CSTPCD)


[65]  Elastic wave propagation and bandgaps mechanism of two-dimensional windmill-like elastic metamaterials. Applied Acoustics. 2023.208:109364. (Q1, Impact factor:3.641, ISSN: 0003-682X, 2023.4)


[64] Low-frequency sound insulation of honeycomb membrane-type acoustic metamaterials with different interlayer characteristics. Journal of Vibration and Control. 2023,1-16(Q2, Impact factor:3.095, ISSN: 1077-5463, Citations:,2023.2)


[63]  Nonlinear dynamics of 1D meta-structure with inertia amplification.  Applied Mathematical Modelling. 2023.118:728-744.(Q1, Impact factor:5.336, ISSN:0307-904X, 2023.1)


[62]  Ultra-broadband sound absorption of a multiple-cavity metastructure with gradient thickness. Aerospace Science and Technology, 2023. 133:108140  (Q1, Impact factor:5.457,  WOS:000924049500001, ISSN:1270-963, 2023.1)


[61]  Acoustic transmission characteristics based on coiled-up space metamaterials. Applied Acoustics. 2023, 203: 109199. (Q1, Impact factor:3.641,  WOS:000921736300001, ISSN: 0003-682X, 2022.12)


[60]  Theoretical analysis on topological interface states of 1D compression-torsion coupling metamaterial. Composite Structures. 2023, 305:116556 (Q1, Impact factor: 6.603,  WOS:000906330600001,ISSN: 1879-1085, 17/326, 2022.12)


[59] Topological optimization of thin elastic metamaterial plates for ultrawide flexural vibration bandgaps. International Journal of Mechanical Sciences, 2023, 242:108014(Q1, Impact factor: 6.772,  WOS:000895503300001, ISSN: 0020-7403, 2022.11)


[58] Broadband vibration attenuation characteristic of 2D phononic crystals with cross-like pores. Thin-Walled Structures.2023, 183:110418 (Q1, Impact factor: 5.881,  WOS:000913231700007, ISSN: 0263-8231, 2022.11)


[57] Analytical dispersion curves and bandgap boundaries for quadrilateral lattices. European Journal of Mechanics / A Solids. 2023, 97:104835(Q1, Impact factor: 4.873, WOS:000882434400002, 2022.10)


[56] Double-beam metastructure with inertially amplified resonators for flexural wave attenuation, European Journal of Mechanics / A Solids. 2023, 97,104794(Q1, Impact factor: 4.873,  WOS:000860627700001, ISSN: 0997-7538, 2022.09)


[55] 梁板型声子晶体带隙特性及列车减振应用. 中南大学学报,2023,54(7):2029-2940(EI)


[54] 微穿孔板—二次余数扩散体复合结构的吸声特性仿真分析.噪声与振动控制,2023, 43(1):68-74(CSSCD)


[53]  轨道车辆空调送风系统噪声振动传递分析.铁道科学与工程学报,2023, 20(5) :1833-1845. (EI)


[52] Bandgap mechanism and vibration attenuation of a quasi-zero stiffness metastructure. International Journal of Structural Integrity. 2022, 13(6): 1041-1059. (Q2, ISSN: 1757-9864,  WOS:000883097300001, Impact factor: 1.34, 2022.11)


[51] Bandgaps and topological interfaces of metabeams with periodic acoustic black holes. Mechanics of Advanced Materials and Structures. 2022:1-18 (Q2,  WOS:000898257600001,Impact factor: 3.338, ISSN: 1537-6532, 2022.11)


[50] Influencing factors and mechanism of high-speed railway passenger overall comfort: Insights from source functional brain network and subjective report. Frontiers in Public Health, 2022, 10: 993172. (Q1, Impact factor: 6.461,  WOS:000874005800001, 2022.09)


[49] Theoretical analysis of 2D meta-structure with inertia amplification. International Journal of Mechanical Sciences, 2022, 235, 107717(Q1, Impact factor: 6.772,  WOS:000870470600001,ISSN: 0020-7403, 2022.09)


[48] Enhancing sound absorption for an acoustic metastructure with extended tubes at ultra-low frequency, Journal of Applied Physics. 2022,132, 115104(Q1, Impact factor: 2.877,  WOS:000875231100012, ISSN: 0020-7403, 2022.08)


[47] Wave propagation in two-dimensional elastic metastructures with triangular configuration, Thin-Walled Structures. 2022,181, 110043 (Q1, Impact factor: 5.881,  WOS:000858629800002, ISSN: 0263-8231, 2022.08)


[46] Multiscale porous with coiled-up channel for low-frequency broadband sound absorption, International Journal of Mechanical Sciences, 2022,232, 107622 (Q1, Impact factor: 6.772, WOS:000889047900002,  ISSN: 0020-7403 2022.08)


[45] Propagation of elastic waves in metamaterial plates with various lattices for low-frequency vibration attenuation. Journal of Sound and Vibration, 2022, 536:117140. (202206,Q1, Impact factor: 3.655, WOS: 000825306500001, ISSN: 0022-460X, Citations: 2 2022.06)


[44] Exact wave propagation analysis of lattice structures based on the dynamic stiffness method and the Wittrick-Williams algorithm. Mechanical Systems and Signal Processing. 2022,174: 109044. (202203,Q1, Impact factor: 8.934, WOS: 000793295900004, ISSN: 0888-3270, Citations: 5 2022.06)


[43]  Wave propagation of 2D elastic metamaterial with rotating squares and hinges. International Journal of Mechanical Sciences. 2022, 217,107037 (202112,Q1, Impact factor: 6.772, WOS: 000741539500004, ISSN: 0020-7403, Citations: 8 2021.12)


[42] Band gap mechanism and vibration attenuation characteristics of quasi-one-dimensional tetra-chiral metamaterials. European Journal of Mechanics / A Solids. 2022, (92)104478. (202111,Q1, Impact factor: 4.873, WOS: 000740224200005, ISSN: 0997-7538, Citations: 0 2021.11)


[41] Bandgap and wave propagation of spring-mass-truss elastic metamaterial with a scissor-like structure. Journal of Physics D: Applied Physics. 2022, 55:055303. (Q2, Impact factor: 3.409, WOS: 000712610900001, ISSN: 0022-3727, Citations: 4 2021.10)


[40] Bandgap and vibration transfer characteristics of scissor-like periodic metamaterials. Journal of Applied Physics. 2021, 130(2):025103. (202107,Q2, Impact factor: 2.877, WOS: 000681706000009, ISSN: 0021-8979, Citations: 7, 2021.07)


[39] Vibration characteristics of innovative reentrant-chiral elastic metamaterials. European Journal of Mechanics / A Solids. 2021, 90(289):104350. (Q1, Impact factor: 4.873, WOS: 000686047400003, ISSN: 0997-7538, Citations: 7, 2021.08)


[38] Hybrid multi-resonators elastic metamaterials for broad low-frequency bandgaps. International Journal of Mechanical Sciences. 2021, 202-203:106501. (Q1, Impact factor: 6.772, WOS: 000670371800005, ISSN: 0020-7403, Citations: 12, 2021.05) 


[37]  Fast prediction method of failure modes for steel box structures under internal blast loading. Engineering Failure Analysis. 2021, 120, 104919. (Q2, Impact factor: 3.643, WOS: 000604258500004, ISSN: 1350-6307, Citations: 5, 2020.09)


[36] Multipolar resonance and bandgap formation mechanism of star-shaped lattice structure. International Journal of Mechanical Sciences. 2020, 193,106163. (Q1, Impact factor: 6.772, WOS:000636787700016, ISSN: 0020-7403, Citations: 6, 2020.10)


[35] Configuration effect and bandgap mechanism of quasi-one-dimensional periodic lattice structure. International Journal of Mechanical Sciences. 2020, 190,106017. (Q1, Impact factor: 6.772, WOS:000605762500010, ISSN: 0020-7403, Citations: 7, 2020.08)


[34] Bandgap merging and widening of elastic metamaterial with heterogeneous resonator. Journal of Physics D: Applied Physics. 2020,53, 475302 (Q2, Impact factor:3.409, WOS:000568370500001, ISSN: 0022-3727, Citations: 10, 2020.08)


[33] Band gaps and vibration transfer characteristics of one dimensional triangular arrangement elastic metamaterials. Journal of Physics D: Applied Physics. 2020 , 53,345303. (Q2, Impact factor:3.409,  WOS:000542543300001, ISSN: 0022-3727, Citations: 6, 2020.10)


[32] A lightweight multilayer honeycomb membrane-type acoustic metamaterial. Applied Acoustics. 2020, 168, 107427. (Q1, Impact factor:3.641,  WOS:000552711200004, ISSN: 0003-682X, Citations: 23, 2020.05)[31] 车底设备激励下地铁车体结构响应分析.噪声与振动控制,2020,40(3):137-141(CSSCD)


[30] Investigating the Effect of Dimension Parameters on Sound Transmission Losses in Nomex Honeycomb Sandwich. Applied Sciences, 2020, 10, 3109 (Q2, Impact factor:2.838,  WOS:000535541900122, ISSN: 2076-3417, Citations: 4, 2020.04)


[29] 车辆型材结构的隔声性能优化研究.噪声与振动控制,2019,39(5) :84-88(CSSCD)


[28] EMU6动车组气动声学性能分析[J].铁道科学与工程学报,2018,15(08):1911-1919. ( EI)


[27] Modelling temperature and residual stress fields in selective laser melting. International Journal of Mechanical Sciences, 2018,136:24-35. (Q1, Impact factor:5.329,  WOS:000425197900003, ISSN: 0020-7403, Citations: 120)


[26] Force transmissibility of floating raft systems with quasi-zero-stiffness isolators. Journal of Vibration and Control, 2018, 24(16): 3608-3616. (Q2, Impact factor:3.095,  WOS:000441283900007, ISSN: 1077-5463, Citations: 16(2))


[25] Vibration attenuation of high dimensional quasi-zero stiffness floating raft system. International Journal of Mechanical Sciences, 2017,126: 186-195. (Q1, Impact factor:5.329,  WOS:000402353200017, ISSN: 0020-7403, Citations: 35(2))


[24] Heat transfer and phase transition in the selective laser melting process. International Journal of Heat and Mass Transfer, 2017,108: 2408-2416. (Q1, Impact factor:5.584,  WOS:000399357700107, ISSN: 0017-9310, Citations: 42(1))


[23] Nonlinear dynamic responses of functionally graded tubes subjected to moving load based on a refined beam model. Nonlinear Dynamics, 2017, 88: 1441-1452. (Q1, Impact factor:5.022,  WOS:000398943900045, ISSN: 0924-090X, Citations: 26)


[22] A six-DOF vibration isolation platform supported by a hexapod of quasi-zero-stiffness struts. Journal of Vibration and Acoustics, 2017, 139(3):034502.1-034502.5. (Q2, Impact factor:1.583,  WOS:000400713200018 , ISSN: 1048-9002, Citations: 42(5))


[21] A novel quasi-zero-stiffness strut and its applications in six-degree-of-freedom vibration isolation platform. Journal of Sound & Vibration,2017, 394:59-74. (Q1, Impact factor:3.655,  WOS:000388826400014, ISSN: 0022-460X, Citations: 103(2))


[20] Spectrum reconstruction of quasi-zero stiffness floating raft systems. Chaos, Solitons & Fractals, 2016, 93:123-129. (Q1, Impact factor:5.944,  WOS:000355890200011, ISSN: 0960-0779, Citations: 3)


[19] Chaotification of quasi-zero-stiffness system with time delay control. Nonlinear Dynamics, 2016, 86:353-368. (Q1, Impact factor:5.022,  WOS:000383024200027, ISSN: 0924-090X, Citations: 8)


[18] Analysis of nonlinear dynamic responses for functionally graded beams resting on tensionless elastic foundation under thermal shock. Composite Structures, 2016, 142: 272–277. (Q1, Impact factor:5.407,  WOS:000372691300025, ISSN: 0263-8223, Citations: 18(4))


[17] Nonlinear bending and vibration of functionally graded tubes resting on elastic foundations in thermal environment based on a refined beam model.Applied Mathematical Modelling, 2016, 1–14. (Q1, Impact factor:5.129,  WOS:000355890200011,ISSN: 0307-904X, Citations: 58(2))


[16] A thermo-elasto-plastic model for a fiber-metal laminated beam with interfacial damage. Applied Mathematical Modelling, 2015,39(12):3317-3310. (Q1, Impact factor:5.129,  WOS:000355890200011,ISSN:0307-904X, Citations: 5)


[15] Reliability analysis for the stability of piezoelectric delaminated axisymmetric laminated cylindrical shells. Mechanics of Advanced Materials and Structures, 2014, 21 (4), 284-292. (Q1, Impact factor:4.03, WOS:000328471900005, ISSN:1537-6494, Citations: 2)


[14] Nonlinear analysis of thermally and electrically actuated functionally graded material microbeam. Proceedings of the Royal Society A: Mathematical, Physical and Engineering Sciences, 2014, 470(2162): 20130473.(Q2, Impact factor:2.704, WOS:000332393700003, ISSN:1364–5021, Citations: 22)


[13] Dynamic effects of delayed feedback control on nonlinear vibration isolation floating raft systems. Journal of Sound and Vibration, 2014, 333:  2665-2676.(Q1, Impact factor:3.655, WOS:000335274100001, ISSN:22-460X, Citations: 4)


[12] Unified nonlinear quasistatic and dynamic analysis of RF-MEMS switches. Acta Mechanica, 2013, 224 (8): 1741-1755.(Q2, Impact factor:2.698, WOS:000322154900012, ISSN:0001-5970, Citations: 22)


[11] Chaotification of a nonlinear vibration isolation system by dual time delayed feedback control. International Journal of Bifurcation and Chaos, 2013, 23(6)1350096. (Q2, Impact factor:2.836, WOS:000321583400006, ISSN: 0218-1274, Citations: 3)


[10] Chaotification and optimization design of a nonlinear vibration isolation system. Journal of Vibration and Control, 2012, 18(14):2129-2139.(Q2, Impact factor:3.095,  WOS:000310877700004, ISSN:1077-5463, Citations: 10)


[9] Nonlinear dynamic analysis of 2-DOF nonlinear vibration isolation floating raft systems with feedback control. Chaos, Solitons & Fractals, 2012, 45: 1092-1099.(Q1, Impact factor:5.944,  WOS:000309315800003, ISSN:0960-0779, Citations: 9(4))


[8] Postbuckling and delamination growth for delaminated piezoelectric elasto-plastic laminated beams under hygrothermal conditions. Journal of Mechanic of Materials and Structures, 2012, 7(1): 85-102(Q4, Impact factor:1.21,  WOS:000302878500004, ISSN:1559-3959, Citations: 1)


[7] Chaotification of Vibration Isolation Floating Raft System via Time-delay Feedback Control. Chaos, Solitons & Fractals, 2012, 45: 1255-1265.(Q1, Impact factor:5.944,  WOS:000309315800020, ISSN:0960-0779, Citations: 13(5))


[6] Analysis of delamination fatigue growth for delaminated piezoelectric elasto-plastic laminated beams under hygrothermal conditions. Composite Structures, 2011, 93(2): 889-901(Q1, Impact factor:5.407, WOS:000284861600063, ISSN:0263-8223, Citations: 8(3))


[5] Stability and chaotification of vibration isolation floating raft systems with time-delayed feedback control. Chaos: An Interdisciplinary Journal of Nonlinear Science, 2011, 21, 033115 (Q1, Impact factor:3.642,  WOS:000295619000015, ISSN:1054-1500, Citations: 14(6))


[4] Nonlinear dynamic response for functionally graded shallow spherical shell under low velocity impact in thermal environment. Applied Mathematical Modelling, 2011, 35:2887–2900. (Q1, Impact factor:5.129,  WOS:000288829200023, ISSN:0307-904X, Citations: 31(3))


[3] 基于最优时延反馈控制的主-被动非线性隔振方法研究. 振动工程学报, 2011, 24(6): 639-645. (Jiaxi Zhou, Daolin Xu, Yingli Li. An active-passive nonlinear vibration isolation method based on optimal time-delay feedback control. Journal of Vibration Engineering, 2011, 24(6):639-645.)


[2] Chaotifing Duffing-type System with Large Parameter Range Based on Optimal Time-Delay Feedback Control.  Proceedings of 2010 International Workshop on Chaos-Fractal Theories and Applications. Kunming, Yunnan, China, 2010.


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