结构动力学、阻尼与控制

海上新能源结构（风能与波浪能）

结构随机动力学，结构与荷载的不确定性量化

波浪-结构、风-结构的流固耦合

纵向项目：

1. 上海市科学技术委员会，“科技创新行动计划” 政府（机构）间合作项目（24160712200），2024/12-2027/11，在研，项目负责人

2. 科技部，中国-克罗地亚科技合作委员会第十届例会交流项目，2024/12-2026/12，在研，项目负责人

3. 国家自然科学基金面上项目（52478317），2025/01-2028/12，在研，项目负责人

4. 人社部外国专家项目（H20240245），2024/08-2025/12，在研，项目负责人

5. 国家海外高层次青年人才项目，2023/01-2027/12，在研，项目负责人

6. 同济大学高层次人才引进启动项目，2022/08-2027/07，在研，项目负责人

7. 丹麦AUFF基金会青年人才项目，2017/10-2021/12，结题，项目负责人

8. 上海市科学技术委员会，中-丹政府间国际科技合作基金项目，2018/04-2021/03，结题，丹方负责人

9. 丹麦高等教育和科学部，EUopSTART 项目，2018/10-2019/01，结题，项目负责人

横向项目：

1. 大叶轮机组气弹稳定性动力学仿真，2025/05-，在研，项目负责人

2. 浮式风机振动控制方法，2025/01-，在研，项目负责人
   

3. 液体阻尼器项目，2023/06-2025/02，项目负责人

4. 大叶轮机组叶片硬件加阻理论分析与计算，2023/11-2025/02，项目负责人

Researchgate: https://www.researchgate.net/profile/Zili-Zhang-10

一. 代表性期刊论文 (*为通讯作者)

[54] Li X, Basu B, Giuseppe H, Zhang Z*. Closed-form solution to multi-mode aerodynamic damping of monopile-supported offshore wind turbines. Engineering Structures, 2025, 332, 119993.

[53] Fang C, Wang J, Xiao Y, Yu K, Chen Q, Zhang Z, Lu Z, Guo J. Superelastic nanocrystalline NiTiNb SMA cables with wide working temperature window for seismic application. Construction and Building Materials, 2025, 483, 141787.

[52] He C, Sun T, Zhang Z, Liu H, Wang C, Wang J. Numerical investigation on the second-order sum-frequency wave forces induced mooring fatigue of a 15 MW TLP FOWT. Ocean Engineering, 2025, 322, 120463.

[51] Xu J, He Z, D Wang D, He G, Wu Q, Zhang Z. Nonlinear dynamic response analyses of Onshore Wind Turbines with Steel-Concrete Hybrid Tower using a co-simulation approach. Renewable Energy, 2025, 122475.

[50] Zhang Y, Li T, Yang Q, Wei K, Zhang Z. Hydrodynamic model for a semi-submersible wind turbine platform with effects of ocean currents. Ocean Engineering, 2024, 313, 119517.

[49] Luo Y, Sun H*, Zhang Z*, Wang W, Zuo L. Analytical optimization of the rotational inertia double tuned mass damper for structures under random excitation. Structures, 2024, 69, 107462.

[48] Song Y, Hong X, Sun T, Zhang Z. Joint probabilistic modeling of extreme wind-wave conditions under typhoon impact and applications to extreme response analysis of floating offshore wind turbines. Engineering Structures, 2024, 318, 118686.

[47] Ding H, Zhang Z*, Wang J*, Zhang J, Altay A. Multiscale fluid-structure coupled real-time hybrid simulation of monopile wind turbines with vibration control devices. Mechanical System and Signal Processing, 2024, 215: 111439.

[46] Zhang Z, Li X, Larsen T, Sun T*, Yang Q. Pole-placement based calibration of an electromagnetically realizable inerter-based vibration absorber (IDVA) for rotating wind turbine blades. Structural Control and Health Monitoring, 2024, 7255774.

[45] Zhang Z, Li X, Chen B, Hua X. Closed-form optimal design of the tuned inerter damper (TID) connecting adjacent flexible buildings. Engineering Structures, 2024, 302: 117419.

[44] Gao Y, Zhai E*, Li S, Zhang Z *, Xu Z, Zhang G, Racic V, Chen J, Wang L, Zhang Z. Integrated design and real-world application of a tuned mass damper (TMD) with displacement constraints for large offshore monopile wind turbines, Ocean Engineering, 2024, 292: 116568.

[43] Høeg CE, Zhang Z*. A semi-analytical hydrodynamic model for floating offshore wind turbines (FOWT) with application to a FOWT heave plate tuned mass damper. Ocean Engineering, 2023, 287-2: 115756.

[42] Ren Y, Yu Z, Hua X, Amdahl J, Zhang Z, Chen Z. Experimental and numerical investigation on the deformation behaviors of large diameter steel tubes under concentrated lateral impact loads. International Journal of Impact Engineering, 2023, 150: 104696.

[41] Song Y, Sun T, Zhang Z*. Fatigue reliability analysis of floating offshore wind turbines considering the uncertainty due to finite sampling of load conditions. Renewable Energy, 2023, 212: 570-588.

[40] Zhang Z, Chen B, Hua X. Closed-form optimization of tuned mass-damper-inerter (TMDI) in flexible structures. Journal of Building Engineering, 2023, 72: 106554.

[39] Zhang Z*, Hammad KA, Song Y. Closed-form derivation of aerodynamic damping matrix and pitch vector of an aero-servo-elastic wind turbine system. Journal of Wind Engineering & Industrial Aerodynamics, 2023, 238: 105409.

[38] Song Y, Sørensen JD, Zhang Z, Sun T, Chen J. Load condition determination for efficient fatigue analysis of floating offshore wind turbines using a GF-discrepancy-based point selection method. Ocean Engineering, 2023, 276: 114211.

[37] Høeg CE, Zhang Z*. Reaction loads analysis of floating offshore wind turbines: methods and applications in the modal-based modelling framework. Ocean Engineering, 2022, 266: 112952.

[36] Ren Y, Meng Q, Chen C, Hua X, Zhang Z, Chen Z. Dynamic behavior and damage analysis of a spar-type floating offshore wind turbine under ship collision. Engineering Structures, 2022, 272: 114815.

[35] Chen B, Zhang Z*, Xugang Hua*. Equal modal damping-based optimal design of a grounded tuned mass-damper-inerter for flexible structures. Structural Control and Health Monitoring, 2022, e3106.

[34] Zhang Z. Vibration suppression of floating offshore wind turbines using electromagnetic shunt turned mass damper. Renewable Energy, 2022, 198: 1279-1295.

[33] Sun T, Zhang Z*. Optimal control and performance evaluation of an inerter based point absorber wave energy converter. Ocean Engineering, 2022, 29: 111883.

[32] Chen B, Zhang Z*, Hua X*, Basu B. Optimal calibration of a tuned liquid column damper (TLCD) for rotating wind turbine blades. Journal of Sound and Vibration, 2022, 521: 116565.

[31] Zhang Z. Understanding and exploiting the nonlinear behavior of tuned liquid dampers (TLDs) for structural vibration control by means of a nonlinear reduced order model (ROM). Engineering Structures, 2022, 251: 113524 .

[30] Larsen TG, Zhang Z*, Høgsberg JB. Vibration damping of offshore wind turbines by optimally calibrated pendulum absorber with shunted electromagnetic transducer. Journal of Sound and Vibration, 2021, 505: 116144.

[29] Chen B, Zhang Z*, Hua X. Closed-form optimal calibration of a tuned liquid column damper (TLCD) for flexible structures. International Journal of Mechanical Sciences, 2021, 198: 106364.

[28] Høeg CE, Zhang Z*. The influence of gyroscopic effects on dynamic responses of floating offshore wind turbines in idling and operational conditions. Ocean Engineering, 2021, 227: 108712.

[27] Zhang Z*, Høeg CE. Inerter-enhanced tuned mass damper for vibration damping of floating offshore wind turbines. Ocean Engineering, 2021, 223: 108663.

[26] Song Y, Basu B, Zhang Z, Sorensen JD, Chen J. Dynamic reliability analysis of a floating offshore wind turbine under wind-wave joint excitations via probability density evolution method. Renewable Energy, 2021, 168: 991-1014.

[25] Chen B, Basu B, Hua X*, Feng Z, Zhang Z*, Chen Z, Nielsen SRK. Online DWT algorithm for identification of aerodynamic damping in wind turbines. Mechanical Systems and Signal Processing, 2020, 152: 107437.

[24] Chen B, Hua X*, Zhang Z*, Nielsen SRK, Chen Z. Active flutter control of the wind turbines using double-pitched blades. Renewable Energy, 2020, 163: 2081-2097.

[23] Zhang Z*, Larsen TG. Optimal calibration of the rotational inertia double tuned mass damper (RIDTMD) for rotating wind turbine blades. Journal of Sound and Vibration, 2020, 493: 115827.

[22] Hua X, Meng Q, Chen B, Zhang Z. Structural damping sensitivity affecting the flutter performance of a 10-MW offshore wind turbine. Advances in Structural Engineering, 2020, 10.1177/1369433220927260.

[21] Zhang Z, Fitzgerald B. Tuned mass-damper-inerter (TMDI) for suppressing edgewise vibrations of wind turbine blades. Engineering Structures, 2020, 221: 110928.

[20] Zhang Z*, Høeg CE . Dynamics and control of spar type floating offshore wind turbines with tuned liquid column dampers. Structural Control and Health Monitoring, 2020, 27(6): e2532.

[19] Zhang Z. Optimal tuning of the tuned mass damper (TMD) for rotating wind turbine blades. Engineering Structures, 2020, 207: 110209.

[18] Zhang Z. Numerical and experimental investigations of the sloshing modal properties of sloped-bottom tuned liquid damper. Engineering Structures, 2020, 204: 110042.

[17] Chen J, Song Y, Peng Y, Nielsen SRK, Zhang Z. An Efficient Rotational Sampling Method of Wind Fields for Wind Turbine Blade Fatigue Analysis. Renewable Energy, 2020, 146: 2170-2187.

[16] Roy A, Zhang Z, Ghosh A, Basu B. On the nonlinear performance of a tuned sloshing damper under small amplitude excitation. Journal of Vibration and Control, 2019, 25: 2695-2705.

[15] Zhang Z*, Basu B, Nielsen SRK. Real-time hybrid aeroelastic simulation of wind turbines with various types of full-scale tuned liquid dampers. Wind Energy, 2019, 22(2): 239-256.

[14] Ji W, Luo Q, Zhang Z*, Wang H, Du T, Heiselberg PK. Investigation on thermal performance of the wall-mounted attached ventilation for night cooling under hot summer conditions. Building and Environment, 2018, 146: 268-279.

[13] Grinderslev C, Lubek M, Zhang Z*. Nonlinear fluid-structure interaction of bridge deck: CFD analysis and semi-analytical modeling. Wind and Structures, 2018, 27(6): 381-397.

[12] Chen B, Zhang Z, Hua X, Nielsen SRK, Basu B. Enhancement of flutter stability in wind turbines with a new type of passive damper of torsional rotation of blades. Journal of Wind Engineering & Industrial Aerodynamics, 2018, 173: 171-179.

[11] Zhang Z*, Chen B, Nielsen SRK, Olsen J. Gyroscopic power take-off wave energy point absorber in irregular sea states. Ocean Engineering, 2017, 143: 113-124.

[10] Chen B, Zhang Z, Hua X, Basu B, Nielsen SRK. Identification of aerodynamic damping in wind turbines using time-frequency analysis. Mechanical Systems and Signal Processing, 2017, 91: 198-214.

[9] Zhang Z, Staino A, Basu B*, Nielsen SRK. Performance evaluation of full scale tuned liquid dampers (TLDs) for vibration control of large wind turbines using real time hybrid testing. Engineering Structures, 2016, 126: 417-431.

[8] Basu B, Zhang Z, Nielsen SRK. Damping of edgewise vibration in wind turbine blades by means of circular liquid dampers. Wind Energy, 2016, 19(2): 213-226.

[7] Zhang Z*, Nielsen SRKN, Basu B, Li J. Nonlinear modeling of tuned liquid dampers (TLDs) in rotating wind turbine blades for edgewise vibration control. Journal of Fluids and Structures, 2015, 59: 252-269.

[6] Nielsen SRK, Zhang Z, Kramer MM, Olsen J. Stability analysis of the Gyroscopic Power Take-Off wave energy point absorber. Journal of Sound and Vibration, 2015, 355: 418-433.

[5] Zhang Z*, Basu B, Nielsen SRK. Tuned liquid column dampers for mitigation of edgewise vibrations in rotating wind turbine blades. Structural Control and Health Monitoring, 2015, 22(3): 500-517.

[4] Zhang Z*, Li J, Nielsen SRK, Basu B. Mitigation of edgewise vibrations in wind turbine blades by means of roller dampers. Journal of Sound and Vibration, 2014, 333(21): 5283-5298.

[3] Zhang Z*, Nielsen SRK, Blaabjerg F, Zhou D. Dynamics and control of lateral tower vibrations in offshore wind turbines by means of active generator torque. Energies, 2014, 7(11): 7746-7772.

[2] Zhang Z, Chen JB, Li J. Theoretical study and experimental verification of vibration control of offshore wind turbines by a ball vibration absorber. Structure and Infrastructure Engineering, 2014, 10(8), 1087-1100.

[1] Nielsen SRK, Zhou Q, Kramer MM, Basu B, Zhang Z. Optimal control of nonlinear wave energy point converters. Ocean Engineering, 2013; 12: 176–187.

二. 专著

Nielsen SRK, Zhang Z. Stochastic Dynamics. 2017. Aarhus University Press.