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Xu Wanhai, Ma Yexuan. Some advances in energy harvesting theory and technology based on flow-induced vibration of cylindrical structures. Chinese Journal of Theoretical and Applied Mechanics, 2024, 56(3): 524-539. DOI: 10.6052/0459-1879-23-558
Citation: Xu Wanhai, Ma Yexuan. Some advances in energy harvesting theory and technology based on flow-induced vibration of cylindrical structures. Chinese Journal of Theoretical and Applied Mechanics, 2024, 56(3): 524-539. DOI: 10.6052/0459-1879-23-558

SOME ADVANCES IN ENERGY HARVESTING THEORY AND TECHNOLOGY BASED ON FLOW-INDUCED VIBRATION OF CYLINDRICAL STRUCTURES

  • Received Date: November 21, 2023
  • Accepted Date: January 15, 2024
  • Available Online: January 15, 2024
  • Published Date: January 16, 2024
  • Tidal energy, characterized by its widespread distribution and immense reserves, stands as a promising renewable energy source suitable for large-scale development and utilization. Flow-induced vibration, a common fluid-structure interaction phenomenon, facilitates efficient energy conversion at lower flow velocities through the vibration of cylindrical structures. Energy harvesting technologies based on flow-induced vibration of cylindrical structures exhibit significant potential for wide-ranging engineering applications in the future. In recent years, numerous experimental and numerical simulation studies have been conducted to explore the flow-induced vibration characteristics and energy harvesting performance of cylinder structures. This paper comprehensively presents the research progress in the theoretical and technical aspects of flow-induced vibration energy harvesting for various cross-sectional forms of single cylinder and cylinder arrays. For the case of flow-induced vibration energy harvesting from a single cylinder, substantial progress has been made in elucidating the influence patterns of passive turbulence controllers, system damping, Reynolds number and boundary conditions on energy harvesting performance. Theoretical foundations and technological advancements have been preliminarily established. Concerning the energy harvesting from a non-circular cross-sectional cylinder, the paper outlines the preliminary understanding of the flow-induced vibration mechanisms and energy harvesting capabilities of triangular, quadrilateral, polygonal and irregularly shaped cylinder under specific conditions such as incoming flow angle, system mass ratio, system damping, system stiffness, and Reynolds number. In the context of flow-induced vibration energy harvesting from cylinder arrays, the interference of flow fields between cylinder oscillators necessitates a rational design of parameters such as cylinder arrangement, cylinder spacing and system damping to achieve maximized fluidic energy capture. By reviewing the domestic and international research progress in flow-induced vibration energy harvesting theories and technologies, this paper provides a prospective outlook for future studies, aiming to stimulate the development of flow-induced vibration energy harvesting theories and advance the engineering applications of flow-induced vibration energy conversion devices.
  • [1]
    Hammons TJ. Tidal power. Proceedings of the IEEE, 1993, 81(3): 419-433 doi: 10.1109/5.241486
    [2]
    于华明, 刘容子, 鲍献文等. 海洋可再生能源发展现状与展望. 青岛: 中国海洋大学出版社, 2012 (Yu Huaming, Liu Rongzi, Bao Xianwen, et al. The Development and Prospect of the Marine Renewable Energy. Qingdao: China Ocean University Press, 2012 (in Chinese)

    Yu Huaming, Liu Rongzi, Bao Xianwen, et al. The Development and Prospect of the Marine Renewable Energy. Qingdao: China Ocean University Press, 2012 (in Chinese)
    [3]
    刘美琴, 仲颖, 郑源等. 海洋能利用技术研究进展与展望. 可再生能源, 2009, 27(5): 78-81 (Liu Meiqin, Zhong Ying, Zheng Yuan, et al. Research status and prospects of marine current energy utilization technology. Renewable Energy Resources, 2009, 27(5): 78-81 (in Chinese)

    Liu Meiqin, Zhong Ying, Zheng Yuan, et al. Research status and prospects of marine current energy utilization technology. Renewable Energy Resources, 2009, 27(5): 78-81 (in Chinese)
    [4]
    胡振兴. 潮流能发电装置功率控制系统设计与开发. [硕士论文]. 青岛: 中国海洋大学, 2013 (Hu Zhenxing. Design and development on the power control system for tidal current energy power generation equipment. [Master Thesis]. Qingdao: Ocean University of China, 2013 (in Chinese)

    Hu Zhenxing. Design and development on the power control system for tidal current energy power generation equipment. [Master Thesis]. Qingdao: Ocean University of China, 2013 (in Chinese)
    [5]
    郑洁, 杨淑涵, 柳存根等. 海洋可再生能源装备技术发展研究. 中国工程科学, 2023, 25(3): 23-32 (Yang Jie, Yang Shuan, Liu Cungen, et al. Development of marine renewable energy equipment and technologies. Strategic Study of Chinese Academy of Engineering, 2023, 25(3): 23-32 (in Chinese)

    Yang Jie, Yang Shuan, Liu Cungen, et al. Development of marine renewable energy equipment and technologies. Strategic Study of Chinese Academy of Engineering, 2023, 25(3): 23-32 (in Chinese)
    [6]
    Williamson CHK, Govardhan R. A brief review of recent results in vortex-induced vibrations. Journal of Wind Engineering and Industrial Aerodynamics, 2008, 96: 713-735 doi: 10.1016/j.jweia.2007.06.019
    [7]
    及春宁, 李非凡, 陈威霖等. 圆柱涡激振动研究进展与展望. 海洋技术学报, 2015, 34(1): 106-118 (Ji Chunning, Li Feifan, Chen Weilin, et al. Progress and prospect of the study on vortex-induced vibration of circular cylinders. Journal of Ocean Technology, 2015, 34(1): 106-118 (in Chinese)

    Ji Chunning, Li Feifan, Chen Weilin, et al. Progress and prospect of the study on vortex-induced vibration of circular cylinders. Journal of Ocean Technology, 2015, 34(1): 106-118 (in Chinese)
    [8]
    Liu GJ, Li HY, Qiu ZZ, et al. A mini review of recent progress on vortex-induced vibrations of marine risers. Ocean Engineering, 2020, 195: 106704 doi: 10.1016/j.oceaneng.2019.106704
    [9]
    徐万海, 马烨璇. 倾斜圆柱结构涡激振动研究进展. 力学学报, 2022, 54(10): 2641-2658 (Xu Wanhai, Ma Yexuan. Research progress on vortex-induced vibration of inclined cylindrical structures. Chinese Journal of Theoretical and Applied Mechanics, 2022, 54(10): 2641-2658 (in Chinese)

    Xu Wanhai, Ma Yexuan. Research progress on vortex-induced vibration of inclined cylindrical structures. Chinese Journal of Theoretical and Applied Mechanics, 2022, 54(10): 2641-2658 (in Chinese)
    [10]
    Ma LX, Lin K, Fan DX, et al. Flexible cylinder flow-induced vibration. Physics of Fluids, 2022, 34: 011302 doi: 10.1063/5.0078418
    [11]
    Ma XQ, Zhou SX. A review of flow-induced vibration energy harvesters. Energy Conversion and Management, 2022, 254: 115223 doi: 10.1016/j.enconman.2022.115223
    [12]
    Wang JL, Geng LF, Ding L, et al. The state-of-the-art review on energy harvesting of flow-induced vibrations. Applied Energy, 2020, 267: 114902 doi: 10.1016/j.apenergy.2020.114902
    [13]
    练继建, 燕翔, 刘昉. 流致振动能量利用的研究现状与展望. 南水北调与水利科技, 2018, 16(1): 176-188 (Lian Jijian, Yan Xiang, Liu Fang. Development and prospect of study on the energy harness of flow-induced motion. South to North Water Transfers and Water Science & Technology, 2018, 16(1): 176-188 (in Chinese)

    Lian Jijian, Yan Xiang, Liu Fang. Development and prospect of study on the energy harness of flow-induced motion. South to North Water Transfers and Water Science & Technology, 2018, 16(1): 176-188 (in Chinese)
    [14]
    Mehmood A, Abdelkefi A, Hajj MR, et al. Piezoelectric energy harvesting from vortex-induced vibrations of circular cylinder. Journal of Sound and Vibration, 2013, 332(19): 4656-4667 doi: 10.1016/j.jsv.2013.03.033
    [15]
    Dai HL, Abdelkefi A, Wang L. Theoretical modeling and nonlinear analysis of piezoelectric energy harvesting from vortex-induced vibrations. Journal of Intelligent Material Systems and Structures, 2014, 25(14): 1861-1874 doi: 10.1177/1045389X14538329
    [16]
    Dai HL, Abdelkefi A, Wang L. Piezoelectric energy harvesting from concurrent vortex-induced vibrations and base excitations. Nonlinear Dynamics, 2014, 77: 967-981 doi: 10.1007/s11071-014-1355-8
    [17]
    Wang DA, Chiu CY, Pham HT. Electromagnetic energy harvesting from vibrations induced by Kármán vortex street. Mechatronics, 2012, 22: 746-756 doi: 10.1016/j.mechatronics.2012.03.005
    [18]
    Bernitsas MM, Ben-Simon Y, Raghavan K, et al. VIVACE (vortex induced vibration for aquatic clean energy): a new concept in generation of clean and renewable energy from fluid flow. Journal of Offshore Mechanics and Arctic Engineering, 2008, 130(4): 041101 doi: 10.1115/1.2957913
    [19]
    Bernitsas MM, Ben-Simon Y, Raghavan K, et al. The VIVACE converter: Model test at high damping and Reynolds number around 105. Journal of Offshore Mechanics and Arctic Engineering, 2008, 131(1): 011102
    [20]
    Erturk A, Inman DJ. An experimentally validated bimorph cantilever model for piezoelectric energy harvesting from base excitations. Smart Materials and Structures, 2009, 18(2): 025009 doi: 10.1088/0964-1726/18/2/025009
    [21]
    Allen JJ, Smits AJ. Energy harvesting. Journal of Fluids and Structures, 2001, 15(3): 629-640
    [22]
    Taylor GW, Burns JR, Kammann SA, et al. The energy harvesting eel: a small subsurface ocean/river power generator. IEEE Journal of Oceanic Engineering, 2001, 26(4): 539-547 doi: 10.1109/48.972090
    [23]
    Hobbs WB, Hu DL. Tree-inspired piezoelectric energy harvesting. Journal of Fluids and Structures, 2012, 28: 103-114 doi: 10.1016/j.jfluidstructs.2011.08.005
    [24]
    Hobbs WB. Piezoelectric energy harvesting: vortex induced vibrations in plants, soap films, and arrays of cylinders. [PhD Thesis]. Atlanta: Georgia Institute of Technology, 2010
    [25]
    Muralt P. Ferroelectric thin films for micro-sensors and actuators: A review. Journal of Micromechanics and Microengineering, 2000, 10(2): 136-146 doi: 10.1088/0960-1317/10/2/307
    [26]
    Shi S, New TH, Liu Y. Flapping dynamics of a low aspect-ratio energy-harvesting membrane immersed in a square cylinder wake. Experimental Thermal and Fluid Science, 2013, 46: 151-161 doi: 10.1016/j.expthermflusci.2012.12.007
    [27]
    Gao X, Shih WH, Shih WY. Flow energy harvesting using piezoelectric cantilevers with cylindrical extension. IEEE Transactions on Industrial Electronics, 2012, 60: 1116-1118
    [28]
    Kim ES, Sun H, Park H, et al. Development of an alternating lift converter utilizing flow-induced oscillations to harness horizontal hydrokinetic energy. Renewable and Sustainable Energy Reviews, 2021, 145: 111094 doi: 10.1016/j.rser.2021.111094
    [29]
    Blevins RD. Flow-Induced Vibration, 2nd edn. Florida: Krieger Publishing Company, 1990
    [30]
    White FM. Fluid Mechanics, 5th edn. New York: McGraw Hill, 2005
    [31]
    Raghavan K. Energy extraction from a steady flow using vortex induced vibration. [PhD Thesis]. Ann Arbor: The University of Michigan, 2007
    [32]
    Chang CC, Bernitsas MM. Design of VIVACE converter using PTC//Proceedings of the ASME 30th International Conference on Ocean, Offshore and Arctic Engineering. Rotterdam, 2011: 733-744
    [33]
    Zhang BS, Li BY, Fu S, et al. Experimental investigation of the effect of high damping on the VIV energy converter near the free surface. Energy, 2022, 244: 122677 doi: 10.1016/j.energy.2021.122677
    [34]
    Bernitsas MM. Raghavan K. Reduction/suppression of VIV of circular cylinders through roughness distribution at 8 × 103 < Re < 1.5 × 104//Proceedings of the ASME 2008 27th International Conference on Ocean, Offshore and Arctic Engineering. Estoril, 2008: 1001-1005
    [35]
    Bernitsas MM, Raghavan K, Duchene G. Induced separation and vorticity using roughness in VIV of circular cylinders at 8 × 103 < Re < 2.0 × 105//Proceedings of the 2008 27th International Conference on Ocean, Offshore and Arctic Engineering. Estoril, 2008: 993-999
    [36]
    Park H, Bernitsas MM, Kumar RA. Selective roughness in the boundary layer to supress flow-induced motions of circular cylinder at 30000 < Re < 120000. Journal of Offshore Mechanics and Arctic Engineering, 2010, 134(4): 041801
    [37]
    Chang CC, Kumar RA, Bernitsas MM. VIV and galloping of single circular cylinder with surface roughness at 3.0 × 104 Re ≤ 1.2 × 105. Ocean Engineering, 2011, 38: 1713-1732 doi: 10.1016/j.oceaneng.2011.07.013
    [38]
    Wu W, Bernitsas MM, Maki K. RANS simulation vs. experiments of flow induced motion of circular cylinder with passive turbulence control at 35000 < Re < 130000//Proceedings of the ASME 30th International Conference on Ocean, Offshore and Arctic Engineering. Rotterdam, 2011: 733-744
    [39]
    Zhang DH, Feng L, Yang H, et al. Vortex-induced vibration characteristics of a PTC cylinder with a free surface effect. Energies, 2020, 13(4): 907 doi: 10.3390/en13040907
    [40]
    Raghavan K, Bernitsas MM. Enhancement of high damping VIV through roughness distribution for energy harnessing at 8 × 103 < Re < 1.5 × 105//Proceedings of the ASME 27th International Conference on Ocean, Offshore and Arctic Engineering. Estoril, 2008: 871-882
    [41]
    徐万海, 罗浩, 孙海. 近自由表面海流能发电装置VIVACE流激振动的实验研究. 振动与冲击, 2019, 38(4): 83-89 (Xu Wanhai, Luo Hao, Sun Hai. An experimental study on flow-induced vibration of the VIVACE converter for harnessing ocean flow energy beneath a free surface. Journal of Vibration and Shock, 2019, 38(4): 83-89 (in Chinese)

    Xu Wanhai, Luo Hao, Sun Hai. An experimental study on flow-induced vibration of the VIVACE converter for harnessing ocean flow energy beneath a free surface. Journal of Vibration and Shock, 2019, 38(4): 83-89 (in Chinese)
    [42]
    Xu WH, Yang M, Wang EH. Performance of single-cylinder VIVACE converter for hydrokinetic energy harvesting from flow-induced vibration near a free surface. Ocean Engineering, 2020, 218: 108168 doi: 10.1016/j.oceaneng.2020.108168
    [43]
    Lee JH, Bernitsas MM. High-damping, high-Reynolds VIV tests for energy harnessing using the VIVACE converter. Ocean Engineering, 2011, 38(16): 1697-1712 doi: 10.1016/j.oceaneng.2011.06.007
    [44]
    Lee JH, Xiros N, Bernitsas MM. Virtual damper-spring system for VIV experiments and hydrokinetic energy conversion. Ocean Engineering, 2011, 38(5-6): 732-747 doi: 10.1016/j.oceaneng.2010.12.014
    [45]
    Sun Hai, Kim ES, Bernitsas MP, et al. Virtual spring-damping system for flow-induced motion experiments. Journal of Offshore Mechanics and Arctic Engineering, 2015, 37: 061801
    [46]
    Bernitsas MM, Raghavan K. Converter of current/tide/wave energy. Provisional Patent Application. United States Patent and Trademark Office Serial, 2004, 60(628, 252
    [47]
    Bernitsas MM, Raghavan K. Fluid motion energy converter. Provisional Patent Application. United States Patent and Trademark Office Serial, 2005, 11(272, 504
    [48]
    Bernitsas MM, Raghavan K. Enhancement of vortex induced forces and motion through surface roughness control. Provisional Patent Application. United States Patent and Trademark Office Serial, 2011, 8(047, 232
    [49]
    Tamimi V, Seif MS, Shahvaghar-Asl S, et al. FIV energy harvesting from sharp edge square and diamond oscillators. International Journal of Maritime Technology, 2019, 12: 1-8 doi: 10.29252/ijmt.12.1
    [50]
    Seyed-Aghazadeh B, Carlson DW, Modarres-Sadeghi Y. Vortex-induced vibration and galloping of prisms with triangular cross-sections. Journal of Fluid Mechanics, 2017, 817: 590-618 doi: 10.1017/jfm.2017.119
    [51]
    Ding L, Zhang L, Wu CW, et al. Flow induced motion and energy harvesting of bluff bodies with different cross sections. Energy Conversion and Management, 2015, 91: 416-426 doi: 10.1016/j.enconman.2014.12.039
    [52]
    Zhang BS, Song BW, Mao ZY, et al. Hydrokinetic energy harnessing by spring-mounted oscillators in FIM with different cross sections from triangle to circle. Energy, 2019, 189: 116249 doi: 10.1016/j.energy.2019.116249
    [53]
    Wang JL, Sheng LJ, Ding L. A comprehensive numerical study on flow-induced vibrations with various groove structures suppression or enhancing energy scavenging. Ocean Engineering, 2023, 271: 113781 doi: 10.1016/j.oceaneng.2023.113781
    [54]
    Zhu HJ, Zhao Y, Zhou TM. CFD analysis of energy harvesting from flow induced vibration of a circular cylinder with an attached free-to-rotate pentagram impeller. Applied Energy, 2018, 212: 304-321 doi: 10.1016/j.apenergy.2017.12.059
    [55]
    Zhu HJ, Gao Y. Hydrokinetic energy harvesting from flow-induced vibration of a circular cylinder with two symmetrical fin-shaped strips. Energy, 2018, 165: 1259-1281 doi: 10.1016/j.energy.2018.10.109
    [56]
    Obasaju ED, Ermshaus R, Naudascher E. Vortex-induced streamwise oscillations of a square-section cylinders in a uniform stream. Journal of Fluid Mechanics, 1990, 213: 171-189 doi: 10.1017/S0022112090002270
    [57]
    Zhao J, Leontini JS, Lo Jacono D, et al. Fluid-structure interaction of a square cylinder at different angles of attack. Journal of Fluid Mechanics, 2014, 747: 688-721 doi: 10.1017/jfm.2014.167
    [58]
    徐枫, 欧进萍. 方柱非定常绕流与涡激振动的数值模拟. 东南大学学报, 2005, S1: 35-39 (Xu Feng, Ou Jinping. Numerical simulation of unsteady flow around square cylinder and vortex-induced vibratio. Journal of Southeast University, 2005, S1: 35-39 (in Chinese)

    Xu Feng, Ou Jinping. Numerical simulation of unsteady flow around square cylinder and vortex-induced vibratio. Journal of Southeast University, 2005, S1: 35-39 (in Chinese)
    [59]
    方平治, 顾明. 高雷诺数条件下二维方柱涡激振动的数值模拟. 同济大学学报, 2008, 2: 161-165 (Fang Pingzhi, Gu Ming. Numerical simulation of vortex-induced vibration for a square cylinder at high Reynolds mumber. Journal of Tongji University, 2008, 2: 161-165 (in Chinese)

    Fang Pingzhi, Gu Ming. Numerical simulation of vortex-induced vibration for a square cylinder at high Reynolds mumber. Journal of Tongji University, 2008, 2: 161-165 (in Chinese)
    [60]
    Andrianne T, Aryoputro RP, Laurent P, et al. Energy harvesting from different aeroelastic instabilities of a square cylinder. Journal of Wind Engineering and Industrial Aerodynamics, 2018, 172: 164-169 doi: 10.1016/j.jweia.2017.10.031
    [61]
    Han P, Huang QG, Pan G, et al. Energy harvesting from flow-induced vibration of a low-mass square cylinder with different incidence angles. Aip Advances, 2021, 11(2): 025126 doi: 10.1063/5.0037071
    [62]
    Zhang BS, Mao ZY, Song BW, et al. Numerical investigation on effect of damping-ratio and mass-ratio on energy harnessing of a square cylinder in FIM. Energy, 2018, 144: 218-231 doi: 10.1016/j.energy.2017.11.153
    [63]
    韩鹏, 潘光, 黄桥高等. 雷诺数对于方柱流致振动能量收集系统的影响. 西北工业大学学报, 2020, 38(5): 928-936 (Han Peng, Pan Guang, Huang Qiaogao, et al. The effects of Reynolds number on energy harvesting from FIV by a square cylinder. Journal of Northwestern Polytechnical University, 2020, 38(5): 928-936 (in Chinese) doi: 10.1051/jnwpu/20203850928

    Han Peng, Pan Guang, Huang Qiaogao, et al. The effects of Reynolds number on energy harvesting from FIV by a square cylinder. Journal of Northwestern Polytechnical University, 2020, 38(5): 928-936 (in Chinese) doi: 10.1051/jnwpu/20203850928
    [64]
    Zhang BS, Wang KH, Song BW, et al. Numerical investigation on the effect of the cross-sectional aspect ratio of a rectangular cylinder in FIM on hydrokinetic energy conversion. Energy, 2018, 165: 949-964 doi: 10.1016/j.energy.2018.09.138
    [65]
    Chen WL, Wei YH, Ji CN, et al. Mass ratio effects on flow-induced vibrations of an equilateral triangular prism. Journal of Fluids and Structures, 2023, 116: 103808 doi: 10.1016/j.jfluidstructs.2022.103808
    [66]
    Zhu HB, Ping H, Wang R, et al. Dynamic response of a cable with triangular cross section subject to uniform flow at Reynolds number 3900. Physics of Fluids, 2020, 32: 045103 doi: 10.1063/1.5144402
    [67]
    Park H, Mentzelopoulos AP, Bernitsas MM. Hydrokinetic energy harvesting from slow currents using flow-induced oscillations. Renewable Energy, 2023, 214: 242-254 doi: 10.1016/j.renene.2023.05.110
    [68]
    张军. 正三棱柱流致振动和能量转化试验研究. [博士论文]. 天津: 天津大学, 2017 (Zhang Jun. Experimental investigation on the flow induced vibration and energy extraction of an equilateral triangle prism. [PhD Thesis]. Tianjin: Tianjin University, 2017 (in Chinese)

    Zhang Jun. Experimental investigation on the flow induced vibration and energy extraction of an equilateral triangle prism. [PhD Thesis]. Tianjin: Tianjin University, 2017 (in Chinese)
    [69]
    Zou QF, Ding L, Song T, et al. Experimental and numerical study on 2-DOF wind-induced vibration and energy harvesting of triangular prism. Ocean Engineering, 2023, 283: 114928
    [70]
    Yan X, Lian JJ, Liu F, et al. Hydrokinetic energy conversion of Flow-induced motion for triangular prism by varying magnetic flux density of generator. Energy Conversion and Management, 2021, 227: 113553 doi: 10.1016/j.enconman.2020.113553
    [71]
    Shao N, Lian JJ, Liu F, et al. Experimental investigation of flow induced motion and energy conversion for triangular prism. Energy, 2020, 194: 116865 doi: 10.1016/j.energy.2019.116865
    [72]
    李恒. 不同截面形状柱体流致振动及能量转换特性. [硕士论文]. 重庆: 重庆大学, 2015 (Li Heng. The flow-induced motion and energy harvesting characteristics of a cylinder with different cross-sections. [Master Thesis]. Chongqing: Chongqing University, 2015 (in Chinese)

    Li Heng. The flow-induced motion and energy harvesting characteristics of a cylinder with different cross-sections. [Master Thesis]. Chongqing: Chongqing University, 2015 (in Chinese)
    [73]
    Barati E, Biabani M, Zarkak MR. Numerical investigation on vortex-induced vibration energy harvesting of a heated circular cylinder with various cross-sections. International Communications in Heat and Mass Transfer, 2022, 132: 105888 doi: 10.1016/j.icheatmasstransfer.2022.105888
    [74]
    Shao N, Lian JJ, Xu GB, et al. Experimental investigation of flow-induced motion and energy conversion of a T-section prism. Energies, 2018, 11(8): 2035 doi: 10.3390/en11082035
    [75]
    燕翔, 练继建, 刘昉等. T形截面振子的驰振特性试验研究. 振动工程学报, 2019, 32: 431-438 (Yan Xiang, Lian Jijian, Liu Fang, et al. Experimental investigation on the galloping characteristics of the T-section prism. Journal of Vibration Engineering, 2019, 32: 431-438 (in Chinese)

    Yan Xiang, Lian Jijian, Liu Fang, et al. Experimental investigation on the galloping characteristics of the T-section prism. Journal of Vibration Engineering, 2019, 32: 431-438 (in Chinese)
    [76]
    Lian JJ, Ran DJ, Yan X, et al. Hydrokinetic energy harvesting from flow-induced motion of oscillators with different combined sections. Energy, 2023, 269: 126814 doi: 10.1016/j.energy.2023.126814
    [77]
    冉聃颉, 练继建, 邵楠等. 圆-三角-附板振子流致振动与发电研究. 水力发电学报, 2022, 41(11): 86-95 (Ran Danjie, Lian Jijian, Shao Nan, et al. Hydrokinetic energy harvesting from flow-induced motion of circular-triangle-attachment oscillator. Journal of Hydroelectric Engineering, 2022, 41(11): 86-95 (in Chinese)

    Ran Danjie, Lian Jijian, Shao Nan, et al. Hydrokinetic energy harvesting from flow-induced motion of circular-triangle-attachment oscillator. Journal of Hydroelectric Engineering, 2022, 41(11): 86-95 (in Chinese)
    [78]
    Huang S, Herfjord K. Experimental investigation of the forces and motion responses of two interfering VIV circular cylinders at various tandem and staggered positions. Applied Ocean Research, 2013, 43: 264-273 doi: 10.1016/j.apor.2013.10.003
    [79]
    Assi GRS. Wake-induced vibration of tandem and staggered cylinders with two degrees of freedom. Journal of Fluids and Structures, 2014, 50: 340-357 doi: 10.1016/j.jfluidstructs.2014.07.002
    [80]
    Xu WH, Ma YX, Cheng AK, et al. Experimental investigation on multi-mode flow-induced vibrations of two long flexible cylinders in a tandem arrangement. International Journal of Mechanical Sciences, 2018, 135: 261-278 doi: 10.1016/j.ijmecsci.2017.11.027
    [81]
    Xu WH, Qin WQ, Yu Y. Flow-induced vibration of two identical long flexible cylinders in a staggered arrangement. International Journal of Mechanical Sciences, 2020, 180: 105637 doi: 10.1016/j.ijmecsci.2020.105637
    [82]
    Lin K, Wang JS, Zheng HX, et al. Numerical investigation of flow-induced vibrations of two cylinders in tandem arrangement with full wake interference. Physics of Fluids, 2020, 32: 015112 doi: 10.1063/1.5134984
    [83]
    Xu WH, Wu HK, Song ZY, et al. Flow-induced vibrations of two staggered cylinders with a moderate spacing and varying incident angles at subcritical Reynolds numbers. Ocean Engineering, 2022, 258: 111723 doi: 10.1016/j.oceaneng.2022.111723
    [84]
    Zdravkovich MM. Flow induced oscillations of two interfering circular cylinders. Journal of Sound and Vibration, 1985, 101(4): 511-521 doi: 10.1016/S0022-460X(85)80068-7
    [85]
    Ali U, Islam M, Kadi KE, et al. Energy harvesting from wake-induced vibrations of a downstream cylinder in tandem arrangement. Procedia Computer Science, 2023, 224: 280-287 doi: 10.1016/j.procs.2023.09.038
    [86]
    Sun H, Ma C, Kim ES, et al. Hydrokinetic energy conversion by two rough tandem-cylinders in flow-induced motions: Effect of spacing and stiffness. Renewable Energy, 2017, 107: 61-80 doi: 10.1016/j.renene.2017.01.043
    [87]
    Xu WH, Ji CN, Sun H, et al. Flow-induced vibration and hydrokinetic power conversion of two staggered rough cylinders for 2.5 × 104 < Re < 1.2 × 105. Journal of Offshore Mechanics and Arctic Engineering, 2018, 140(2): 021905 doi: 10.1115/1.4038932
    [88]
    Ding WJ, Sun H, Xu WH, et al. Numerical investigation on interactive FIO of two-tandem cylinders for hydrokinetic energy harnessing. Ocean Engineering, 2019, 187: 106215 doi: 10.1016/j.oceaneng.2019.106215
    [89]
    Sun H, Li HJ, Yang NK, et al. Experimental and numerical study of the shielding effect of two tandem rough cylinders in flow-induce oscillation. Marine Structures, 2023, 89: 103374 doi: 10.1016/j.marstruc.2023.103374
    [90]
    Sun H, Bernitsas MM, Turkol M. Adaptive harnessing damping in hydrokinetic energy conversion by two rough tandem-cylinders using flow-induced vibrations. Renewable Energy, 2020, 149: 828-860 doi: 10.1016/j.renene.2019.12.076
    [91]
    Zhang BS, Li BY, Li CP, et al. Effects of variable damping on hydrokinetic energy conversion of a cylinder using wake-induced vibration. Renewable Energy, 2023, 213: 176-194 doi: 10.1016/j.renene.2023.06.004
    [92]
    Chen ZL, Alam MM, Qin B, et al. Energy harvesting from and vibration response of different diameter cylinders. Applied Energy, 2020, 278: 115737 doi: 10.1016/j.apenergy.2020.115737
    [93]
    Bai X, Chen Y, Sun H, et al. Numerical study on ocean current energy converter by tandem cylinder with different diameter using flow-induced vibration. Ocean Engineering, 2022, 257: 111539 doi: 10.1016/j.oceaneng.2022.111539
    [94]
    Tang RJ, Gu YB, Mi XW, et al. Numerical analysis of WIV phenomenon with two in-series cylinders: WIV suppression and energy harvesting. Ocean Engineering, 2022, 262: 112154 doi: 10.1016/j.oceaneng.2022.112154
    [95]
    Ding L, Zou QF, Zhang L, et al. Research on flow-induced vibration and energy harvesting of three circular cylinders with roughness strips in tandem. Energies, 2018, 11: 2977 doi: 10.3390/en11112977
    [96]
    Han P, Pan G, Zhang BS, et al. Three-cylinder oscillator under flow Flow induced vibration and energy harvesting. Ocean Engineering, 2020, 211: 107619 doi: 10.1016/j.oceaneng.2020.107619
    [97]
    Wang JL, Su Z, Li H, et al. Imposing a wake effect to improve clean marine energy harvesting by flow-induced vibrations. Ocean Engineering, 2020, 208: 107455 doi: 10.1016/j.oceaneng.2020.107455
    [98]
    Rabiee AH, Esmaeili M. Effect of the flow incidence angle on the VIV-based energy harvesting from triple oscillating cylinders. Sustainable Energy Technologies and Assessments, 2023, 57: 103312 doi: 10.1016/j.seta.2023.103312
    [99]
    罗竹梅, 张立翔, 张晓旭等. 涡激振动驱动的柱群结构俘获海流能的稳定性分析. 振动与冲击, 2019, 38(8): 96-116 (Luo Zhumei, Zhang Lixiang, Zhang Xiaoxu, et al. Stability analysis of harvesting ocean current energy for a multi-cylinder structure driven by VIV. Journal of Vibration and Shock, 2019, 38(8): 96-116 (in Chinese)

    Luo Zhumei, Zhang Lixiang, Zhang Xiaoxu, et al. Stability analysis of harvesting ocean current energy for a multi-cylinder structure driven by VIV. Journal of Vibration and Shock, 2019, 38(8): 96-116 (in Chinese)
    [100]
    罗竹梅, 聂耳, 郭涛. 涡激振动驱动的柱群结构集中俘获海流能研究. 太阳能学报, 2021, 42(4): 89-94 (Luo Zhumei, Nie Er, Guo Tao. Study on centralized harvesting ocean current energy with column-group structure by VIV. Acta Energiae Solaris Sinica, 2021, 42(4): 89-94 (in Chinese)

    Luo Zhumei, Nie Er, Guo Tao. Study on centralized harvesting ocean current energy with column-group structure by VIV. Acta Energiae Solaris Sinica, 2021, 42(4): 89-94 (in Chinese)
    [101]
    Zhang BS, Mao ZY, Song BW. Numerical investigation on VIV energy harvesting of four cylinders in close staggered formation. Ocean Engineering, 2018, 165: 55-68 doi: 10.1016/j.oceaneng.2018.07.042
    [102]
    Kim ES, Bernitsas MM. Performance prediction of horizontal hydrokinetic energy converter using multiple-cylinder synergy in flow induced motion. Applied Energy, 2016, 170: 92-100 doi: 10.1016/j.apenergy.2016.02.116
    [103]
    邵楠. 双三棱柱流致振动特性及发电振子布局优选试验研究. [博士论文]. 天津: 天津大学, 2020 (Shao Nan. Experimental study on flow induced motion characteristics and energy conversion optimal layout for two triangular prisms. [Phd Thesis]. Tianjin: Tianjin University, 2020 (in Chinese)

    Shao Nan. Experimental study on flow induced motion characteristics and energy conversion optimal layout for two triangular prisms. [Phd Thesis]. Tianjin: Tianjin University, 2020 (in Chinese)
    [104]
    Shao N, Lian JJ, Yan X, et al. Experimental study on energy conversion of flow induced motion for two triangular prisms in staggered arrangement. Energy, 2022, 249: 123764 doi: 10.1016/j.energy.2022.123764
    [105]
    Tamimi V, Esfehani MJ, Zeinoddini M, et al. Marine hydrokinetic energy harvesting performance of diamond and square oscillators in tandem arrangements. Energy, 2020, 202: 117749 doi: 10.1016/j.energy.2020.117749
    [106]
    Tamimi V, Esfehani MJ, Zeinoddini M, et al. Hydroelastic response and electromagnetic energy harvesting of square oscillators: Effects of free and fixed square wakes. Energy, 2023, 263: 125982 doi: 10.1016/j.energy.2022.125982
    [107]
    Shao N, Xu GB, Liu F, et al. Experimental study on the flow-induced motion and hydrokinetic energy of two T-section prisms in tandem arrangement. Applied Sciences, 2020, 10(3): 1136 doi: 10.3390/app10031136
    [108]
    Liu JL, Bao B, Chen JT, et al. Marine energy harvesting from tidal currents and offshore winds: A 2-DOF system based on flow-induced vibrations. Nano Energy, 2023, 114: 108664 doi: 10.1016/j.nanoen.2023.108664
    [109]
    Tamimi V, Wu J, Naeeni STO, et al. Effects of dissimilar wakes on energy harvesting of flow induced vibration (FIV) based converters with circular oscillator. Applied Energy, 2021, 281: 116092 doi: 10.1016/j.apenergy.2020.116092
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