Active and passive hybrid vibration control and analysis of dike pipeline

ZHANG Jianwei; ZHANG Kai; LIU Xizhu; JIANG Qi; HOU Ge

doi:10.11975/j.issn.1002-6819.202309023

Transactions of the Chinese Society of Agricultural Engineering > 2023 > 39(24): 47-55. > DOI: 10.11975/j.issn.1002-6819.202309023

ZHANG Jianwei, ZHANG Kai, LIU Xizhu, et al. Active and passive hybrid vibration control and analysis of dike pipeline[J]. Transactions of the Chinese Society of Agricultural Engineering (Transactions of the CSAE), 2023, 39(24): 47-55. DOI: 10.11975/j.issn.1002-6819.202309023

Citation:

PDF (2249 KB)

Active and passive hybrid vibration control and analysis of dike pipeline

1.
College of Water Conservancy, North China University of Water Conservancy and Electric Power, Zhengzhou 450046, China
2.
Jinan Key Laboratory of Digital Twin and Smart Water Resources, Shandong Provincial Water Resources Survey and Design Institute Co., Ltd., Jinan 250013, China

More Information

Received Date: September 03, 2023
Revised Date: October 28, 2023
Available Online: January 16, 2024

Graphical Abstract

Abstract

Abstract

An active passive hybrid control system (MRTMD) was proposed to combine a magnetorheological damper (MRD) and a tuned mass damper (TMD). The vibration of water supply and drainage pipelines was controlled when passing through embankments caused by the operation of pumping station units. Linear quadratic regulator (LQR) based optimal control algorithm was utilized to optimize the parameters of the active passive hybrid vibration control system, in order to minimize the acceleration of the structure. Magnetorheological damper damping was stable enough to change the damping frequency in the new system, compared with the traditional single-tuned mass damper. Firstly, a simulation signal was constructed to simulate the load excitation of pump station units during operation, the vibration response of pump station pipeline was also used to compare with a single TMD and MRD control, in order to verify the applicability and effectiveness of the MRTMD for pump station pipeline vibration reduction. Secondly, shock waves were used as excitation to simulate and analyze the control effect of pipeline dynamic response, in response to the phenomenon of water hammer during opening and closing of the unit or the abnormal vibration under extreme working conditions. The damping force and displacement hysteresis curve were used to explore the robustness and vibration reduction of the output resistance force; Finally, MRTMD was applied to the water supply and drainage pipeline project in the Beijiang Dam in Guangdong Province. The simplified two-degree-of-freedom mass, stiffness, and damping matrices of the pipeline were solved using load inversion and then established the pipeline vibration dynamics equation. Taking the vibration reduction efficiency as the evaluation index, the vibration reduction efficiency of the new system on the water supply and drainage pipeline structure passing through the embankment was analyzed from the time domain perspective. The effective vibration reduction frequency range and energy reduction efficiency of each main frequency of MRTMD were also analyzed from the frequency domain perspective. The results show that the damping force provided by MRTMD shared a wide range, stable output, and strong energy dissipation. Better control was achieved in the acceleration response of pipeline structure, when passing through the embankment, with a damping efficiency of 37.56%-38.07%. There was a slightly better control in the displacement response of the structure, compared with the acceleration response, with a damping efficiency of 40.23%-41.38%, and a damping effect of 33.9% at the pipeline passing through the embankment. The vibration reduction was superior to single TMD and MRD control; There was the weakening effect of MRTMD on the main frequency energy of various vibration sources during operation in a frequency domain. Among them, the mechanical vibration energy caused by the rotation of the main shaft (such as rotation frequency and doubling frequency) was reduced to 27.46% and 75.88%, respectively, while the vibration energy was significantly reduced to 36.46% for medium to low frequency vibration that caused by water flow impact and axial vortices formed in the impeller.
- vibration,
- acceleration,
- pipeline,
- active passive hybrid control,
- magnetorheological damper,
- tuned mass damper

FullText(HTML)

References (30)

References

[1]	张巧玲,黄铋匀,杨振东,等. 基于特征线法的含气输水管道水锤特性分析[J]. 农业工程学报,2022,38(5):79-86. ZHANG Qiaoling, HUANG Biyun, YANG Zhendong, et al. Water hammer properties of gas-bearing water pipeline using characteristics method[J]. Transactions of the Chinese Society of Agricultural Engineering (Transactions of the CSAE), 2022, 38(5): 79-86. (in Chinese with English abstract)
[2]	汪怡然,俞晓东,韩笑笑,等. 考虑泥沙颗粒影响的长距离供水工程单向塔水锤防护[J]. 农业工程学报,2023,39(4):84-91. WANG Yiran, YU Xiaodong, HAN Xiaoxiao, et al. One-way surge tank protection of sediment-laden water hammer on long-distance water supply projects[J]. Transactions of the Chinese Society of Agricultural Engineering (Transactions of the CSAE), 2023, 39(4): 84-91. (in Chinese with English abstract)
[3]	王正中,江浩源,王羿,等. 旱寒区输水渠道防渗抗冻胀研究进展与前沿[J]. 农业工程学报,2020,36(22):120-132. WANG Zhengzhong, JIANG Haoyuan, WANG Yi, et al. Research progresses and frontiers in anti-seepage and anti-frost heave of canals in cold-arid regions[J]. Transactions of the Chinese Society of Agricultural Engineering (Transactions of the CSAE), 2020, 36(22): 120-132. (in Chinese with English abstract)
[4]	司乔瑞,唐亚静,甘星城,等. 立式管道泵进水弯管和叶轮的参数化分析与验证[J]. 农业工程学报,2020,36(17):54-63. SI Qiaorui, TANG Yajing, GAN Xingcheng, et al. Parametric analysis and verification of curved inlet pipe and impeller of vertical inline pump[J]. Transactions of the Chinese Society of Agricultural Engineering (Transactions of the CSAE), 2020, 36(17): 54-63. (in Chinese with English abstract)
[5]	赵雷雷,于曰伟,曹建虎,等. 减振器节流阀片区段均布压力下应力解析算法及其应用[J]. 农业工程学报,2022,38(18):72-80. ZHAO Leilei, YU Yuewei, CAO Jianhu, et al. Analytical algorithm for the stress of damper throttle-slices and its application under interval uniformly distributed pressure[J]. Transactions of the Chinese Society of Agricultural Engineering (Transactions of the CSAE), 2022, 38(18): 72-80. (in Chinese with English abstract)
[6]	ADDALA M B, BHALLA S, MADAN A. Performance based design of a new hybrid passive energy dissipation device for vibration control of reinforced concrete frames subjected to broad-ranging earthquake ground excitations[J]. Advances in Structural Engineering, 2022, 25(4): 895-912. DOI: 10.1177/13694332211052350
[7]	白久林,李晨辉,王宇航. 考虑RNA运行作用的近海风电结构主动质量阻尼器振动控制研究[J]. 振动与冲击,2023,42(23):183-191. BAI Jiulin, LI Chenhui, WANG Yuhang. Active mass damper vibration control of offshore wind turbine structure considering RNA operation[J]. Journal of Vibration and Shock, 2023, 42(23): 183-191. (in Chinese with English abstract)
[8]	LIN Y F, VENNA S V. A novel method for piezoelectric transducers placement for passive vibration control of geometrically non‐linear structures[J]. Sensor Review, 2008, 28(3): 233-241. DOI: 10.1108/02602280810882599
[9]	PORFIRI M, DELLISOLA F, SANTINI E. Modeling and design of passive electric networks interconnecting piezoelectric transducers for distributed vibration control[J]. International Journal of Applied Electromagnetics and Mechanics, 2005, 21(2): 69-87. DOI: 10.3233/JAE-2005-672
[10]	PARK C H, PARK H C. Multiple-mode structural vibration control using negative capacitive shunt damping[J]. Journal of Mechanical Science and Technology, 2003, 17(11): 1650-1657.
[11]	杨毅,冷鼎鑫,徐凯,等. 磁流变调谐质量阻尼器在海上风机振动控制中的应[J]. 重庆大学学报,2022,45(3):20-30. YANG Yi, LENG Dingxin, XU Kai, et al. Application of magnetorheological TMD in vibration control of offshore wind turbines[J]. Journal of Chongqing University, 2022, 45(3): 20-30. (in Chinese with English abstract)
[12]	XUE X, TANG J. Vibration control of nonlinear rotating beam using piezoelectric actuator and sliding mode approach[J]. Journal of Vibration and Control, 2008, 14(6): 885-908. DOI: 10.1177/1077546307085354
[13]	QIU J H, HARAGUCHI M. Vibration control of a plate using a self-sensing piezoelectric actuator and an adaptive control approach[J]. Journal of Intelligent Material Systems and Structures, 2006(17): 660-669.
[14]	刘彦辉,谭平,周福霖,等. 主被动调谐控制结构动力响应分析与试验[J]. 振动、测试与诊断,2015,35(3):441-447, 587-588. LIU Yanhui, TAN Ping, ZHOU Fulin, et al. Experimental and analytical study of dynamic response of structure controlled by active-passive hybrid tune mass damper[J]. Journal of Vibration, Measurement & Diagnosis, 2015, 35(3): 441-447, 587-588. (in Chinese with English abstract)
[15]	廖英英,刘永强,杨绍普. 一种新型混合半主动控制策略在高速铁道车辆振动控制中的应用[J]. 振动与冲击,2013,32(12):84-87. LIAO Yingying, LIU Yongqiang, YANG Shaopu. A new mixed semi-active control strategy and its application in vibration control of a high-speed railway vehicles[J]. Journal of Vibration and Shock, 2013, 32(12): 84-87. (in Chinese with English abstract)
[16]	周亚丽,张奇志,熊斌. 基于分支电路的主动-被动混合式结构振动控制[J]. 噪声与振动控制,2006,5(6):5-8. ZHOU Yali, ZHANG Qizhi, XIONG Bin. Active-passive hybrid structural vibration control using shunted circuit[J]. Noise and Vibration Control, 2006, 5(6): 5-8. (in Chinese with English abstract)
[17]	马小陆,裘进浩,季宏丽,等. 负电容在主-被动混合压电振动控制中的应用[J]. 华南理工大学学报(自然科学版),2012,40(3):112-118. MA Xiaolu, QIU Jinhao, JI Hongli, et al. Application of negative capacitance to active-passive hybrid piezoelectric vibration control[J]. Journal of South China University of Technology (Natural Science Edition), 2012, 40(3): 112-118. (in Chinese with English abstract)
[18]	赵祥昇,李春祥,曹黎媛. 结构-NFVD-TTMDI的控制性能[J]. 振动工程学报,2022,35(1):55-63. ZHAO Xiangsheng, LI Chunxiang, CAO Liyuan. Control performance of structural-NFVD-TTMDI[J]. Journal of Vibration Engineering, 2022, 35(1): 55-63. (in Chinese with English abstract)
[19]	张延年,刘斌,李艺,等. MRD与LRB相混合的结构振动控制[J]. 东北大学学报(自然科学版),2006,27(1):95-98. ZHANG Yannian, LIU Bin, LI Yi, et al. Structural vibration control using a mixture of MRD and LRB[J]. Journal of Northeastern University(Natural Science), 2006, 27(1): 95-98. (in Chinese with English abstract)
[20]	王海军,陈波,杨秀维,等. 抽水蓄能电站管道水力振动在围岩中的传播规律研究[J]. 水资源与水工程学报,2023,34(3):116-122. WANG Haijun, CHEN Bo, YANG Xiuwei, et al. Propagation law of hydraulic vibration of pipeline in surrounding rock of pumped storage power station[J]. Journal of Water Resources & Water Engineering, 2023, 34(3): 116-122. (in Chinese with English abstract)
[21]	KHAZAEE M, KHADEM S E, MOSLEMI A, et al. Vibration mitigation of a pipe conveying fluid with a passive geometrically nonlinear absorber: A tuning optimal design[J]. Communications in Nonlinear Science and Numerical Simulation, 2020, 91(12): 105439.
[22]	BORGI S E, ALRUMAIHI S, RAJENDRAN A, et al. Model updating of a scaled piping system and vibration attenuation via locally resonant bandgap formation[J]. International Journal of Mechanical Sciences, 2021, 194(11): 106211.
[23]	张翌娜,王立彬,张建伟,等. 梯级泵站管道TMD振动控制仿真与减振优化[J]. 水电能源科学,2018,36(8):153-157. ZHANG Yina, WANG Libin, ZHANG Jianwei, et al. Vibration control simulation and damping optimization of TMD system for pipeline of cascade pumping stations[J]. Water Resources and Power, 2018, 36(8): 153-157. (in Chinese with English abstract)
[24]	欧进萍. 结构振动控制-主动、半主动与智能控制[M]. 北京:科学出版社,2003:186-235.
[25]	李火坤,杜磊,梁萱,等. 基于原型振动测试的泄洪闸闸墩动位移反演[J]. 振动、测试与诊断,2018,38(6):1122-1129, 1288. LI Huokun, DU Lei, LIANG Xuan, et al. Dynamic displacement inversion for sluice pier based on prototype vibration test[J]. Journal of Vibration, Measurement & Diagnosis, 2018, 38(6): 1122-1129, 1288. (in Chinese with English abstract)
[26]	李火坤,王刚,魏博文,等. 基于敏感性分析与粒子群算法的拱坝原型动弹性模量反演方法[J]. 水利学报,2020,51(11):1401-1411. LI Huokun, WANG Gang, WEI Bowen, et al. Inversion of prototype dynamic elastic modulus of arch dam based on sensitivity analysis and particle swarm optimization[J]. Journal of Hydraulic Engineering, 2020, 51(11): 1401-1411. (in Chinese with English abstract)
[27]	张建伟,崔广涛,马斌,等. 基于泄流响应的高拱坝振源时域识别[J]. 天津大学学报(自然科学与工程技术版),2008,41(9):1124-1129. ZHANG Jianwei, CUI Guangtao, MA Bin, et al. Time domain identification of excitation sources for high arch dams based on discharge flow vibration response[J]. Journal of Tianjin University(Science and Technology), 2008, 41(9): 1124-1129. (in Chinese with English abstract)
[28]	张建伟,江琦,王涛. 基于原型观测的梯级泵站管道振源特性分析[J]. 农业工程学报,2017,33(1):77-83. DOI: 10.11975/j.issn.1002-6819.2017.01.010 ZHANG Jianwei, JIANG Qi, WANG Tao. Analysis of vibration characteristics of pipeline of trapezoid pumping station based on prototype observation[J]. Transactions of the Chinese Society of Agricultural Engineering (Transactions of the CSAE), 2017, 33(1): 77-83. (in Chinese with English abstract) DOI: 10.11975/j.issn.1002-6819.2017.01.010
[29]	张龑,练继建,刘昉,等. 基于原型观测的厂顶溢流式水电站厂房结构振动特性研究[J]. 天津大学学报(自然科学与工程技术版),2015,48(7):584-590. ZHANG Yan, LIAN Jijian, LIU Fang, et al. Vibration characteristics of powerhouse structure of roof overflow hydroelectric station based on prototype observation[J]. Journal of Tianjin University(Science and Technology), 2015, 48(7): 584-590. (in Chinese with English abstract)
[30]	张建伟,杨灿,黄锦林,等. 基于传递熵的泵站管道振动传递路径特性分析[J]. 农业工程学报,2021,37(15):47-52. ZHANG Jianwei, YANG Can, HUANG Jinlin, et al. Analysis of the pipeline transfer path characteristics of pumping stations based on transfer entropy[J]. Transactions of the Chinese Society of Agricultural Engineering (Transactions of the CSAE), 2021, 37(15): 47-52. (in Chinese with English abstract)