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地震作用下时滞位移反馈对AMD振动控制效果的影响

孙艺瑕

孙艺瑕,2024. 地震作用下时滞位移反馈对AMD振动控制效果的影响. 震灾防御技术,19(2):334−341. doi:10.11899/zzfy20240213. doi: 10.11899/zzfy20240213
引用本文: 孙艺瑕,2024. 地震作用下时滞位移反馈对AMD振动控制效果的影响. 震灾防御技术,19(2):334−341. doi:10.11899/zzfy20240213. doi: 10.11899/zzfy20240213
Sun Yixia. Effect of Time-delayed Displacement Feedback on AMD Vibration Control under Seismic Excitation[J]. Technology for Earthquake Disaster Prevention, 2024, 19(2): 334-341. doi: 10.11899/zzfy20240213
Citation: Sun Yixia. Effect of Time-delayed Displacement Feedback on AMD Vibration Control under Seismic Excitation[J]. Technology for Earthquake Disaster Prevention, 2024, 19(2): 334-341. doi: 10.11899/zzfy20240213

地震作用下时滞位移反馈对AMD振动控制效果的影响

doi: 10.11899/zzfy20240213
基金项目: 国家自然科学基金(11602135)
详细信息
    作者简介:

    孙艺瑕,女,生于1983年。博士,副教授,硕士生导师。主要从事振动主动控制方面的研究。E-mail:sunyixia@sues.edu.cn

Effect of Time-delayed Displacement Feedback on AMD Vibration Control under Seismic Excitation

  • 摘要: 在传统被动TMD的基础上引入时滞位移反馈控制,将TMD转变为AMD。在AMD系统中,将时滞和反馈增益系数作为可调的控制参数。首先,建立AMD作用下两自由度耦合振动系统力学模型和数学模型;然后,采用特征值分析法判断控制参数平面上系统的稳定性;最后,以位移响应峰值、加速度响应峰值、位移均方根和加速度均方根为评价指标,基于Simulink仿真,分析控制参数对El Centro波作用下AMD振动控制效果的影响。研究结果表明,当系统物理参数固定时,控制参数取值决定了系统振动稳定性;相较于TMD作用的情况,合理的控制参数取值,可使AMD达到更佳的振动控制效果,主结构和阻尼器地震响应均在不同程度上得到抑制;在控制参数取值不合理的情况下,AMD振动控制效果变差。
  • 图  1  AMD控制系统力学模型

    Figure  1.  Mechanical model of AMD control system

    图  2  满足特征根为纯虚根的gτ取值

    Figure  2.  Values of g and τ corresponding to the pure imaginary eigenroots

    图  3  A点对应的系统位移响应

    Figure  3.  Displacement response of the system at point A

    图  4  B点对应的系统位移响应

    Figure  4.  Displacement response of the system at point B

    图  5  系统稳定性分区

    Figure  5.  System stability chart

    图  6  系统位移时程响应

    Figure  6.  Displacement time history response

    图  7  系统加速度时程响应

    Figure  7.  Acceleration time history response

    图  8  反馈增益系数对位移峰值的影响

    Figure  8.  Effect of feedback gain coefficient on displacement peak

    图  9  反馈增益系数对加速度峰值的影响

    Figure  9.  Effect of feedback gain coefficient on acceleration peak

    图  10  反馈增益系数对位移均方根的影响

    Figure  10.  Effect of feedback gain coefficient on displacement root mean square

    图  11  反馈增益系数对加速度均方根的影响

    Figure  11.  Effect of feedback gain coefficient on acceleration root mean square

    表  1  不同情况下系统响应峰值及其均方根

    Table  1.   Peak and root mean square of system response in three cases

    控制参数取值 位移峰值/cm 加速度峰值/cm 位移均方根/cm 加速度均方根/Gal
    g/(N·m−1 τ/s 主结构 TMD AMD 主结构 TMD AMD 主结构 TMD AMD 主结构 TMD AMD
    无控 0.92 294 0.30 98
    0 0.74 4.85 232 1519 0.23 1.39 71 447
    −1 000 0.20 0.63 4.10 200 1263 0.21 1.24 68 382
    下载: 导出CSV

    表  2  时滞对系统响应峰值及其均方根的影响

    Table  2.   Effect of τ on peak and root mean square of system response

    控制参数取值 位移峰值/cm 加速度峰值/cm 位移均方根/cm 加速度均方根/Gal
    g/(N·m−1 τ/s 主结构 AMD 主结构 AMD 主结构 AMD 主结构 AMD
    −1 000 0.05 0.90 6.28 307 2 033 0.29 1.98 90 666
    0.10 0.93 10.11 287 3 236 0.30 2.66 95 858
    0.15 0.69 6.76 202 2 115 0.21 1.85 68 570
    0.20 0.63 4.10 200 1 263 0.21 1.24 68 382
    0.25 0.67 3.29 216 1 024 0.22 1.02 72 319
    0.30 0.74 3.27 233 1 024 0.23 1.02 75 328
    0.35 0.81 3.90 247 1 243 0.25 1.31 80 441
    0.40 0.93 6.89 291 2 287 0.29 2.09 94 725
    下载: 导出CSV
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出版历程
  • 收稿日期:  2023-06-19
  • 刊出日期:  2024-06-30

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