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面向激光跟踪仪宽频隔振器的理论分析及试验评价

刘海平 张世乘 门玲鸰 何振强

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面向激光跟踪仪宽频隔振器的理论分析及试验评价

刘海平, 张世乘, 门玲鸰, 何振强

Theoretical analysis and experimental evaluation of vibration isolation system with broadband characteristic for laser tracker

Liu Hai-Ping, Zhang Shi-Cheng, Men Ling-Ling, He Zhen-Qiang
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  • 高能同步辐射光源施工现场, 采用激光跟踪仪对高能光源磁铁设备标定、预准直和隧道测量时, 激光跟踪仪受周边环境振动影响较大, 并严重危害其测量精度. 为了有效地控制环境振动的影响, 提出一种面向激光跟踪仪的宽频隔振器, 并安装在激光跟踪仪三角支架的支腿位置, 在保证隔振性能的同时兼具较好的承载能力. 针对上述系统, 建立等效单自由度非线性动力学微分方程, 采用复变量-平均法获得宽频隔振器的稳态响应解, 并应用数值有限元方法验证理论模型及计算结果的正确性. 在此基础上, 采用谐波平衡法分析非线性系统的稳定性, 并考虑关键设计参数K3对其隔振性能的影响. 结合实际工作环境, 选择部分典型工况(包括: 长时间静压, 垂向冲击激励和横向位移激励)进行实测, 评估宽频隔振器的静态稳定性和振动控制效果. 结果表明, 长时间静压后, 激光跟踪仪最大沉降位移约2×10–5 m; 不同动态载荷作用下, 宽频隔振器对激光跟踪仪振动响应幅值的衰减率最高可达97%, 且有效隔振频带较宽; 满足所有技术指标要求.
    High-energy synchrotron radiation source, as a large scientific device, is under construction in Beijing, China. This device is one of the fourth-generation synchrotron radiation sources with the highest brightness in the world. It will provide an important support platform for basic science and engineering science. As a kind of high-precision large-scale measurement equipment, laser tracker is used mainly in high-energy particle accelerator equipment installation, precision poses dynamic measurement and antenna feed dynamic motion precision engineering measurement field. At the construction site of high energy synchrotron radiation source, the laser tracker is often used to calibrate and pre-collimate the high energy source magnet equipment and carry on the tunnel measurement . However, the laser tracker is easily affected by the vibration of the surrounding environment, and the adverse vibration seriously affects its measurement accuracy and even causes the equipment to damage. In order to effectively control the influence of environmental vibration and ensure good static bearing capacity, a broadband vibration isolator for laser tracker is proposed. It is installed in the leg position of the triangular bracket of the laser tracker, which ensures the vibration isolation performance and good bearing capacity. For the above system, the equivalent single freedom nonlinear dynamic differential equation is established, and the steady-state response solution of the broadband isolator is obtained by using the complex variable-average method. The numerical finite element method is used to verify the correctness of the theoretical model and corresponding calculation results. On this basis, the stability of a nonlinear system is analyzed by harmonic balance method, and the influence of key designing parameter K3 on vibration isolation performance is considered. Combined with the complexity of the actual working environment of laser tracker, a variety of typical working conditions are set up for test, including long time static pressure test, vertical impact excitation and lateral displacement excitation tests, to evaluate the static stability and vibration control effect of broadband isolator. The experimental results show that the maximum static displacement of the laser tracker is about 2×10–5 m under static pressure in a long time, and the maximum static load is within the allowable error range. When the occasional impacting is triggered, the installation of broadband isolator can make the combination quickly restore stability in about 2.95 s, exhibiting better vibration isolation performance. Under different dynamic loads, by comparing the acceleration frequency response curves of the laser tracker with and without the isolator, in the frequency band below the fundamental frequency of the laser tracker, the attenuation rate of the combined system can be up to about 97% with and without the vibration isolator. In the frequency band above the fundamental frequency, the attenuation rate of the combined system with and without the vibration isolation system can reach up to about 88%, and the effective vibration isolation frequency band is extended. The broadband vibration isolator meets all technical requirements.
      通信作者: 刘海平, liuhaiping@ustb.edu.cn
    • 基金项目: 广东省基础与应用基础研究基金(批准号: 2021B1515120049)、佛山市科技创新专项资金产学研合作项目(批准号: BK22BE021)和北京市科技计划课题(批准号: Z191100005619011)资助的课题.
      Corresponding author: Liu Hai-Ping, liuhaiping@ustb.edu.cn
    • Funds: Project supported by the Guangdong Basic and Applied Basic Research Foundation, China (Grant No. 2021B1515120049), the Foshan Science and Technology Innovation Funds for Industry University Cooperation Project (Grant No. BK22BE021), and the Beijing Science and Technology Project, China (Grant No. Z191100005619011).
    [1]

    罗涛, 何晓业, 汪昭义, 王巍, 李笑, 黄晴晴, 何振强, 柯志勇, 马娜, 王铜, 梁静, 李波, 门铃鸰, 王小龙, 董岚 2021 武汉大学学报(信息科学版) DOI: 10.13203/j.whugis20200718

    Luo T, He X Y, Wang S Y, Wang W, Li X, Huang Q Q, He Z Q, Ke Z Y, Ma N, Wang T, Liang J, Li B, Men L L, Wang X L, Dong L 2021 Geomatics Inf. Sci. Wuhan Univ. DOI: 10.13203/j. whugis20200718 (in Chinese)

    [2]

    Jiao Y, Duan Z, Guo Y, Ji D, Li X, Peng Y, Qin Q, Qiu J, Tian S, Wang J 2016 Phys. Procedia 84 40Google Scholar

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    李广云, 范百兴 2017 测绘学报 46 10Google Scholar

    Li G Y, Fan B X 2017 Acta Geod. Cartogr. Sin. 46 10Google Scholar

    [4]

    Kristiansen P, Horbach J, Döhrmann R, Heuer J 2015 J. Synchrotron Radiat. 22 4Google Scholar

    [5]

    Omidalizarandi M, Kargoll B, Paffenholz J A, Paffenholz J A, Neumann I 2018 Adv. Mech. Eng. 10 119Google Scholar

    [6]

    徐亚明, 郑琪, 管啸 2020 测绘地理信息 45 812Google Scholar

    Xu Y M, Zheng Q, Guan X 2020 J. Geomat. 45 812Google Scholar

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    Bronowicki A J, Abhyankar N S, Griffin S F 1999 Smart Mater. Struct. 8 740Google Scholar

    [8]

    Davis L, Hyland D, Yen G, Dask A 1999 Smart Mater. Struct. 8 753Google Scholar

    [9]

    Vaillon L, Petitjean B, Frapard B, Lebihan D 1999 Smart Mater. Struct. 8 781Google Scholar

    [10]

    Vaillon L, Sanctorum B, Sperandei J, Defendini A, Griseri G, Alberti M V 2002 Proc. 5th ESA Int. Conf. Spacecr. Guid Italy, Frascati, October

    [11]

    Onoda J, Minesugi K 1996 AIAA J. 34 207Google Scholar

    [12]

    Onoda J, Minesugi K 1994 J. Spacecraft Rockets 31 67Google Scholar

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    Onoda J, Minesugi K 1996 AIAA J. 34 355Google Scholar

    [14]

    Chen S B, Xuan M, Xin J, Liu Y, Gu S, Li J, Zhang L 2020 Int. J. Mech. Sci. 179 105592Google Scholar

    [15]

    姜伟伟, 徐治洲, 任戈 2014 噪声与振动控制 34 186Google Scholar

    Jiang W W, Xu Z Z, Ren G 2014 Noise Vibr. Control 34 186Google Scholar

    [16]

    杜言鲁, 丁亚林, 许永森, 聂品 2015 中国机械工程 26 2880Google Scholar

    Du Y L, Ding Y L, Xu Y S, Nie P 2015 Chin. Mech. Eng. 26 2880Google Scholar

    [17]

    郑凤翥, 宁飞, 王培群, 霍丽烨, 赵志草 2018 应用光学 39 453Google Scholar

    Zheng F Z, Ning F, Wang P Q, Huo L Y, Zhao Z C 2018 J. Appl. Opt. 39 453Google Scholar

    [18]

    Qi Y, Wang H L, Xu Q Q, Du Y L, Shao X Z, Yang H 2021 Optik 242 167016Google Scholar

    [19]

    Dong G, Ma C, Y Luo 2020 Int. J. Appl. Electromagnet. Mech. 64 315Google Scholar

    [20]

    杜宁, 胡明勇, 毕勇, 朱庆生 2017 振动与冲击 36 184

    Du N, Hu M Y, Bi Y, Zhu Q S 2017 J. Vibr. Shock 36 184

    [21]

    Carrella A, Brennan M J, Waters T P 2007 J. Sound Vibr. 301 678Google Scholar

    [22]

    Takamori A 2002 Ph. D. Dissertation (Tokyo: University of Tokyo)

    [23]

    Stochino A, Abbot B, Aso Y, Barton M, Bertolini A, Boschi V, Coyne D, DeSalvo R, Galli C, Huang Y M 2007 Nucl. Instrum. Methods Phys. Res. , Sect. A 598 737Google Scholar

    [24]

    Yao J, Wu K, Guo M, Wang G, Wang L 2019 IEEE Trans. Instrum. Meas. 99 1Google Scholar

    [25]

    Xu D L, Yu Q P, Zhou J X, Bishop S R 2013 J. Sound Vibr. 332 3377Google Scholar

    [26]

    Xu D L, Zhang Y Y, Zhou J X, Lou J J 2013 J. Vibr. Control 20 2314Google Scholar

    [27]

    李强, 徐登峰, 李林, 魏绍炎 2019 振动与冲击 38 100Google Scholar

    Li Q, Xu D F, Li L, Wei S Y 2019 J. Vibr. Shock 38 100Google Scholar

    [28]

    严博, 马洪业, 韩瑞祥, 王珂, 武传宇 2019 机械工程学报 55 169Google Scholar

    Yan B, Ma H X, Han R X, Wang K, Wu C Y 2019 J. Mech. Eng. 55 169Google Scholar

    [29]

    Sun M, Chen J 2018 Math Probl Eng. 2018 5693618Google Scholar

    [30]

    刘海平, 申大山, 赵鹏鹏 2021 振动工程学报 34 490Google Scholar

    Liu H P, Shen D S, Zhao P P 2021 J. Vibr. Eng. 34 490Google Scholar

  • 图 1  宽频隔振器实物照片

    Fig. 1.  Photo of isolator with broadband characteristic.

    图 2  薄片梁的力-位移曲线

    Fig. 2.  Force-displacement curves of thin sheet beam.

    图 3  宽频隔振器的等效力学模型 (a) 未受载状态; (b) 静平衡状态

    Fig. 3.  Equivalent mechanical model of isolator with broadband characteristic: (a) unloaded state; (b) static equilibrium state.

    图 4  宽频隔振器的安装位置

    Fig. 4.  Installation position of isolator with broadband characteristic.

    图 5  宽频隔振器加速度传递率曲线

    Fig. 5.  Acceleration transmissibility curves of isolator with broadband characteristic.

    图 6  宽频隔振器加速度传递率曲线

    Fig. 6.  Acceleration transmissibility curve of isolator with broadband characteristic.

    图 7  不同K3对应加速度传递率曲线

    Fig. 7.  Acceleration transmissibility curves for different K3.

    图 8  宽频隔振器长时间静态力学试验照片

    Fig. 8.  Photograph of long time static mechanical test of isolator with broadband characteristic.

    图 9  测试系统照片

    Fig. 9.  Test System Photo.

    图 10  系统模型的理论、仿真及实测结果对比

    Fig. 10.  Comparison of theoretical, simulation and measured results of the overall model.

    图 11  未安装宽频隔振器组合体的频响曲线(工况1)

    Fig. 11.  Frequency response curves of the assembly without broadband isolator (case 1).

    图 12  频响曲线(工况2)

    Fig. 12.  Frequency response curves (case 2).

    图 13  钢块敲击对应频响曲线(工况2)

    Fig. 13.  Frequency response curves under steel-block hit (case 2).

    图 14  安装宽频隔振器, 不同位置加速度频响曲线(工况3)

    Fig. 14.  Acceleration frequency response curves with broadband isolators at different locations (case 3).

    图 15  安装宽频隔振器前后, 激光跟踪仪安装面垂向加速度频响曲线(工况4)

    Fig. 15.  Vertical acceleration frequency response curves of laser tracker’s mounting position with and without broadband isolators (case 4).

    图 16  安装宽频隔振器前后, 激光跟踪仪安装面水平向加速度频响曲线(工况5)

    Fig. 16.  Acceleration frequency response curve of laser tracker’s mounting position with and without broadband isolators along horizontal direction (case 5).

    图 17  高频模态振型

    Fig. 17.  Modal shape in higher frequency region.

    图 18  时域加速度响应曲线

    Fig. 18.  Acceleration response curve in time domain.

    表 1  薄片梁的设计参数

    Table 1.  Designing parameters of thin sheet beam.

    名称符号数值
    总长度L70 mm
    初始角度θ126°
    端点角度θ2–25°
    弹性模量E208 GPa
    厚度d1 mm
    初始宽度w24 mm
    下载: 导出CSV

    表 2  宽频隔振器材料参数表

    Table 2.  Material parameters of isolator with broadband characteristic.

    名称薄片梁转接件
    材料60 Si2CrVA10 F
    密度/(kg·m3)78507990
    泊松比0.30.24
    弹性模量/Pa2.1×10111.96×1011
    下载: 导出CSV

    表 3  长时间静压试验实测变形量

    Table 3.  Deformation measured under long time compression condition.

    实测变形量/m
    测试工况5 h15 h
    方向X–1.2×10–51.6×10–5
    Y6×10-6–2.1×10–5
    Z1.2×10–55×10–5
    下载: 导出CSV

    表 4  试验工况表

    Table 4.  Test conditions table.

    序号工况测点编号及位置
    1未安装隔振器, 钢块敲击地面#1, #2, #3; 支架支腿位置
    2安装隔振器, 钢块敲击地面前后, 支架处响应#1, #2, #3; 支架支腿位置
    3安装隔振器, 钢块敲击地面, 地面、支架及激光跟踪仪处响应#2, #4, #5; 支架支腿、激光跟踪仪及地面垂向
    4安装隔振器, 钢块敲击地面, 激光跟踪仪处响应#4; 激光跟踪仪安装面垂向
    5安装隔振器, 钢块敲击地面, 激光跟踪仪处响应#4; 激光跟踪仪安装面水平向
    6安装隔振器, 水平推动激光跟踪仪处响应#4; 激光跟踪仪安装面水平向
    下载: 导出CSV

    表 5  模态固有频率对比及振型图

    Table 5.  Natural frequencies and mode shapes.

    模态阶数固有频率/Hz模态振型
    仿真结果实测结果误差
    114.3114.753.0%
    241.9142.752.0%
    360.5047.253.3%
    486.9950.2521.9%
    588.6657.7534.9%
    下载: 导出CSV
  • [1]

    罗涛, 何晓业, 汪昭义, 王巍, 李笑, 黄晴晴, 何振强, 柯志勇, 马娜, 王铜, 梁静, 李波, 门铃鸰, 王小龙, 董岚 2021 武汉大学学报(信息科学版) DOI: 10.13203/j.whugis20200718

    Luo T, He X Y, Wang S Y, Wang W, Li X, Huang Q Q, He Z Q, Ke Z Y, Ma N, Wang T, Liang J, Li B, Men L L, Wang X L, Dong L 2021 Geomatics Inf. Sci. Wuhan Univ. DOI: 10.13203/j. whugis20200718 (in Chinese)

    [2]

    Jiao Y, Duan Z, Guo Y, Ji D, Li X, Peng Y, Qin Q, Qiu J, Tian S, Wang J 2016 Phys. Procedia 84 40Google Scholar

    [3]

    李广云, 范百兴 2017 测绘学报 46 10Google Scholar

    Li G Y, Fan B X 2017 Acta Geod. Cartogr. Sin. 46 10Google Scholar

    [4]

    Kristiansen P, Horbach J, Döhrmann R, Heuer J 2015 J. Synchrotron Radiat. 22 4Google Scholar

    [5]

    Omidalizarandi M, Kargoll B, Paffenholz J A, Paffenholz J A, Neumann I 2018 Adv. Mech. Eng. 10 119Google Scholar

    [6]

    徐亚明, 郑琪, 管啸 2020 测绘地理信息 45 812Google Scholar

    Xu Y M, Zheng Q, Guan X 2020 J. Geomat. 45 812Google Scholar

    [7]

    Bronowicki A J, Abhyankar N S, Griffin S F 1999 Smart Mater. Struct. 8 740Google Scholar

    [8]

    Davis L, Hyland D, Yen G, Dask A 1999 Smart Mater. Struct. 8 753Google Scholar

    [9]

    Vaillon L, Petitjean B, Frapard B, Lebihan D 1999 Smart Mater. Struct. 8 781Google Scholar

    [10]

    Vaillon L, Sanctorum B, Sperandei J, Defendini A, Griseri G, Alberti M V 2002 Proc. 5th ESA Int. Conf. Spacecr. Guid Italy, Frascati, October

    [11]

    Onoda J, Minesugi K 1996 AIAA J. 34 207Google Scholar

    [12]

    Onoda J, Minesugi K 1994 J. Spacecraft Rockets 31 67Google Scholar

    [13]

    Onoda J, Minesugi K 1996 AIAA J. 34 355Google Scholar

    [14]

    Chen S B, Xuan M, Xin J, Liu Y, Gu S, Li J, Zhang L 2020 Int. J. Mech. Sci. 179 105592Google Scholar

    [15]

    姜伟伟, 徐治洲, 任戈 2014 噪声与振动控制 34 186Google Scholar

    Jiang W W, Xu Z Z, Ren G 2014 Noise Vibr. Control 34 186Google Scholar

    [16]

    杜言鲁, 丁亚林, 许永森, 聂品 2015 中国机械工程 26 2880Google Scholar

    Du Y L, Ding Y L, Xu Y S, Nie P 2015 Chin. Mech. Eng. 26 2880Google Scholar

    [17]

    郑凤翥, 宁飞, 王培群, 霍丽烨, 赵志草 2018 应用光学 39 453Google Scholar

    Zheng F Z, Ning F, Wang P Q, Huo L Y, Zhao Z C 2018 J. Appl. Opt. 39 453Google Scholar

    [18]

    Qi Y, Wang H L, Xu Q Q, Du Y L, Shao X Z, Yang H 2021 Optik 242 167016Google Scholar

    [19]

    Dong G, Ma C, Y Luo 2020 Int. J. Appl. Electromagnet. Mech. 64 315Google Scholar

    [20]

    杜宁, 胡明勇, 毕勇, 朱庆生 2017 振动与冲击 36 184

    Du N, Hu M Y, Bi Y, Zhu Q S 2017 J. Vibr. Shock 36 184

    [21]

    Carrella A, Brennan M J, Waters T P 2007 J. Sound Vibr. 301 678Google Scholar

    [22]

    Takamori A 2002 Ph. D. Dissertation (Tokyo: University of Tokyo)

    [23]

    Stochino A, Abbot B, Aso Y, Barton M, Bertolini A, Boschi V, Coyne D, DeSalvo R, Galli C, Huang Y M 2007 Nucl. Instrum. Methods Phys. Res. , Sect. A 598 737Google Scholar

    [24]

    Yao J, Wu K, Guo M, Wang G, Wang L 2019 IEEE Trans. Instrum. Meas. 99 1Google Scholar

    [25]

    Xu D L, Yu Q P, Zhou J X, Bishop S R 2013 J. Sound Vibr. 332 3377Google Scholar

    [26]

    Xu D L, Zhang Y Y, Zhou J X, Lou J J 2013 J. Vibr. Control 20 2314Google Scholar

    [27]

    李强, 徐登峰, 李林, 魏绍炎 2019 振动与冲击 38 100Google Scholar

    Li Q, Xu D F, Li L, Wei S Y 2019 J. Vibr. Shock 38 100Google Scholar

    [28]

    严博, 马洪业, 韩瑞祥, 王珂, 武传宇 2019 机械工程学报 55 169Google Scholar

    Yan B, Ma H X, Han R X, Wang K, Wu C Y 2019 J. Mech. Eng. 55 169Google Scholar

    [29]

    Sun M, Chen J 2018 Math Probl Eng. 2018 5693618Google Scholar

    [30]

    刘海平, 申大山, 赵鹏鹏 2021 振动工程学报 34 490Google Scholar

    Liu H P, Shen D S, Zhao P P 2021 J. Vibr. Eng. 34 490Google Scholar

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出版历程
  • 收稿日期:  2022-02-21
  • 修回日期:  2022-04-04
  • 上网日期:  2022-08-02
  • 刊出日期:  2022-08-20

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