带状附加物放置角度对流致振动与振子俘能特性影响研究

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摘要流致振动普遍存在于工程领域与自然界，由于复杂性和多学科交叉的特点，流致振动一直是学界研究热点之一，利用被动湍流控制(passive turbulence control,PTC)来增强流致振动的俘能技术更是受到了广泛关注。本文在光滑圆柱上放置不同角度的对称带状方形附加物，实验得到了振子的振幅、振动频率、输出功率、能量转换效率和振子升力系数，进一步揭示了被动湍流控制增强流致振动的机理。研究结果表明：PTC圆柱振子的最大振幅为2.0 D，是光滑圆柱振子最大振幅的5倍；最大输出功率达0.44 W，是光滑圆柱振子最大输出功率的14倍。这说明合理的配置附加物的放置角度，可以使振子的振动由涡激振动(vortex-induce vibration，VIV)发展为驰振，同时获得较高的输出功率和能量转换效率，为利用流致振动进行能量转换和收集提供了必要的理论指导和技术支撑。

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	孙宏军1
	吕鹏飞1
	丁红兵1
	李金霞2
	宋晨睿1

关键词 ：流致振动, 被动湍流控制PTC, 涡激振动, 驰振

Abstract：Flow induced vibration generally exists in the field of engineering and nature. Due to the complexity and interdisciplinary, the flow induced vibration has always been one of the research hotspots in the academic community. The energy harvesting technology using passive turbulence control (PTC) to enhance flow induced vibration has attracted extensive attention. The study focused on the characteristics of flow induced vibration of cantilever vibrator by placing symmetrical square strip attachments with different angles on a smooth cylinder. The response of amplitude and frequency, output power and energy conversion efficiency, and the lift coefficient were obtained. The mechanism of passive turbulence control to enhance flow induced vibration was further revealed. The results showed that the maximum amplitude of PTC cylindrical vibrator is 2.0 D, which is 5 times that of smooth cylindrical vibrator; The maximum output power is 0.44 W, which is 14 times of the maximum output power of the smooth cylindrical vibrator. The reasonable placement angle of the attachment can make the vibration of the vibrator develop from vortex induced vibration to galloping, and obtain high output power and energy conversion efficiency, which provides necessary theoretical guidance and technical support for energy conversion and collection by flow induced vibration.

Key words： flow induced vibration passive turbulence control PTC vortex induced vibration galloping;

收稿日期: 2022-01-17 出版日期: 2023-03-28

引用本文:

孙宏军1，吕鹏飞1，丁红兵1，李金霞2，宋晨睿1. 带状附加物放置角度对流致振动与振子俘能特性影响研究[J]. 振动与冲击, 2023, 42(6): 98-105.
SUN Hongjun1，L Pengfei1，DING Hongbing1，LI Jinxia2，SONG Chenrui1. Experimental study on the influence of the placement angles of strip attachments on the flow induced vibration of a cantilever vibrator and the energy harvesting characteristics. JOURNAL OF VIBRATION AND SHOCK, 2023, 42(6): 98-105.

链接本文:

http://jvs.sjtu.edu.cn/CN/ 或 http://jvs.sjtu.edu.cn/CN/Y2023/V42/I6/98

[1]. 丁林,张力,姜德义.高雷诺数范围内不同形状柱体流致振动特性研究[J].振动与击,2015,34(12):176-181.
DING Lin, ZHANG Li, JIANG Deyi. Flow-induced motion of bluff bodies with different cross sections in flow field with high Reynolds number. [J]. Journal of Vibration and Shock.,2015,34(12):176-181.
[2]. 王人凤,尤云祥,陈科,等.低质量比舵系统流致振动特征研究[J].振动与冲击,2018,37(18):8.
WANG Renfeng, YOU Yunxiang, CHEN Ke, et al. Flow induced vibration characteristics of a hydrofoil system with a low mass ratio. [J]. Journal of Vibration and Shock,2018,37(18):8.
[3]. 王灵芝.基于流-固-电耦合的悬臂结构驰振及其俘能研究[D].重庆大学,2019.
WANG Lingzhi. Galloping and Energy Harvesting Study of Cantilever Structures Considering Fluid-Solid-Electric Coupling. [D]. Chongqing University,2019.
[4]. 宋汝君.圆柱型压电俘能器的流激振动及其发电性能研究[D].哈尔滨:哈尔滨工业大学,2016.
SONG Rujun. Research on Flow-Induced Vibration and Power Generation of Cylindrical Piezoelectric Energy Harvester[D]. Harbin: Harbin Institute of Technology,2016.
[5]. 丁林, 邹瑞, 张力,等. 基于拓扑网格方法的多钝体流致振动分析[J]. 振动与冲击, 2019, 38(22):8.
DING Ling, CHU Rui, ZHANG Li, et al. Analysis on the flow induced motion of multiple bluff bodies based on topological mesh[J]. Journal of Vibration and Shock, 2019, 38(22):8.
[6]. Shin Y S, Wambsganss M W. Flow-induced vibration in LMFBR steam generators: a state-of-the-art review[J]. Nuclear Engineering and Design, 1977, 40(2): 235-284.
[7]. 及春宁,陈威霖,徐万海.正方形顺排排列四圆柱流致振动响应研究[J].振动与冲击,2016,35(11):54-60.
JI Chunning, CHEN Weilin, XU Wanhai. Folw-induced vibration of four square-arranged circular cylinders[J]. Journal of Vibration and Shock,2016,35(11):54-60.
[8]. 张可丰,谢永诚.堆内构件防断支承组件流致振动分析[J].振动与冲击,2009,28(12):183-187.
ZHANG Kefeng, XIE Yongcheng. Flow-induced vibration analysis for the secondary support assembly of reactor internal. [J]. Journal of Vibration and Shock,2009,28(12):183-187.
[9]. 马文勇,张璐,张晓斌等.风偏角对方形断面结构驰振不稳定性影响[J].振动与冲击,2021,40(02):171-175+184.
MA Wenyong , ZHANG Lu , ZHANG xiaobing，et al. Influence of wind deflection angle on galloping instability of square-section structures[J]. Journal of Vibration and Shock, 2021,40(02): 171-175+184.
[10]. 练继建,燕翔,刘昉,等.正方形截面振子在不同来流方向的单自由度流致振动特性研究[J].振动与冲击,2017,36(15):29-35.
JI Lianjian, YAN Xiang, LIU Fang, et al. Flow induced vibration characteristics of a single-DOF square cylinder at different incident angles [J]. Journal of Vibration and Shock,2017,36(15):29-35.
[11]. Feng C C. The measurements of vortex-induced effects on flow past a stationary and oscillation and galloping[J]. Master's thesis (University of British Columbia, Vancouver, Canada, 1968), 1968.
[12]. Khalak A, Williamson C H K. Dynamics of a hydroelastic cylinder with very low mass and damping[J]. Journal of Fluids and Structures, 1996, 10(5): 455-472.
[13]. Khalak A, Williamson C H K. Motions, forces and mode transitions in vortex-induced vibrations at low mass-damping[J]. Journal of fluids and Structures, 1999, 13(7-8): 813-851.
[14]. Bernitsas M M, Raghavan K, Ben-Simon Y, et al. VIVACE (Vortex Induced Vibration Aquatic Clean Energy): A new concept in generation of clean and renewable energy from fluid flow[J]. 2008.
[15]. Achenbach E. Influence of surface roughness on the cross-flow around a circular cylinder[J]. Journal of fluid mechanics, 1971, 46(2): 321-335.
[16]. Chang C C, Kumar R A, Bernitsas M M. VIV and galloping of single circular cylinder with surface roughness at 3.0× 104 ≤Re≤1.2×105 [J]. Ocean Engineering, 2011, 38(16): 1713-1732.
[17]. Wang J, Zhao G, Zhang M, et al. Efficient study of a coarse structure number on the bluff body during the harvesting of wind energy[J]. Energy Sources, Part A: Recovery, Utilization, and Environmental Effects, 2018, 40(15): 1788-1797.
[18]. Park H R, Kumar R A, Bernitsas M M. Enhancement of flow induced motions of rigid circular cylinder on springs by localized surface roughness at 3×104 ≤Re≤1.2×105 [J]. Ocean Eng., 2013, 72(1): 403-415.
[19]. Ding L, Yang L, Yang Z, et al. Performance improvement of aeroelastic energy harvesters with two symmetrical fin-shaped rods[J]. Journal of Wind Engineering and Industrial Aerodynamics, 2020, 196: 104051.
[20]. Hu G, Tse K T, Kwok K C S, et al. Aerodynamic modification to a circular cylinder to enhance the piezoelectric wind energy harvesting[J]. Applied Physics Letters, 2016, 109(19): 193902.
[21]. 靳遵龙,李国平,耿林风,等.被动湍流控制圆柱驰振能量收集的等效电路研究[J].振动与冲击,2020,39(9):7.
JIN Zunlong, LI Guoping, GENG Linfeng, et al. Equivalent circuit analysis of the galloping-based piezoelectric energy harvester with a passive turbulence control cylinder[J]. Journal of Vibration and Shock,2020,39(9):7.
[22]. 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[J].振动与冲击,2019, 38(4):7.
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[J]. Journal of Vibration and Shock,2019, 38(4):7.
[23]. Sun W, Guo F, Seok J. Development of a novel vibro-wind galloping energy harvester with high power density incorporated with a nested bluff-body structure[J]. Energy conversion and management, 2019, 197: 111880.
[24]. Sirohi J, Mahadik R. Piezoelectric wind energy harvester for low-power sensors[J]. Journal of Intelligent
[25]. Bernitsas M M, Raghavan K, Ben-Simon Y, et al. VIVACE (Vortex Induced Vibration Aquatic Clean Energy): A new concept in generation of clean and renewable energy from fluid flow[J]. 2008.
[26]. Lian J, Yan X, Liu F, et al. Analysis on Flow Induced Motion of Cylinders with Different Cross Sections and the Potential Capacity of Energy Transference from the Flow[J]. Shock and Vibration,2017, (2017-01-18), 2017, 2017(pt.1):19.
[27]. Lian J, Yan X, Liu F, et al. Analysis on Flow Induced Motion of Cylinders with Different Cross Sections and the Potential Capacity of Energy Transference from the Flow[J]. Shock and Vibration,2017, (2017-01-18), 2017, 2017(pt.1):19.
[28]. Betz A. Introduction to the Theory of Flow Machines. (1966)(DG Randall, Trans.) Oxford[J]
[29]. Sun H, Kim E S, Nowakowski G, et al. Effect of mass-ratio, damping, and stiffness on optimal hydrokinetic energy conversion of a single, rough cylinder in flow induced motions[J]. Renewable Energy, 2016, 99: 936-959.
[30]. Zhu H, Gao Y. Hydrokinetic energy harvesting from flow-induced vibration of a circular cylinder with two symmetrical fin-shaped strips[J]. Energy, 2018, 165: 1259-1281.
[31]. Zhang B, Mao Z, Song B, et al. Numerical investigation on effect of damping-ratio and mass-ratio on energy harnessing of a square cylinder in FIM[J]. Energy, 2018, 144: 218-231.