单向张弦梁结构风振响应的时域分析

张弦梁屋盖结构自重轻,地震作用下的动力问题不是结构设计的控制因素,但是在风荷载作用下结构的动力响应较为显著,在设计中应给予足够重视。本文首先利用Matlab编程工具,模拟结构的风速时程曲线,然后利用有限元软件中的瞬态动力学分析模块对这种结构进行动力时程分析,讨论其在脉动风荷载作用下的动力响应,并将结果和频域法脉动风荷载的分析结果进行对比,验证了计算结构的可靠性。得到一些有意义的结论,供张弦梁结构的工程应用参考。     

基于风速时程的体育场挑篷结构风振响应分析

依据自回归(AR)法,确立了考虑风速时程空间相关性的模拟方法,并利用Matlab语言编制了相应的程序。基于上述方法,模拟了某体育场挑篷结构的风速时程,并对所得风速时程离散值进行数理统计分析,结果表明模拟谱与目标谱吻合较好。根据结构风振响应分析的需要,将模拟风速转变为风荷载对结构进行时程分析,获得了结构风振响应,为结构抗风设计提供依据。计算表明,基于风速时程的结构风振响应分析方法可有效分析体育场挑篷的风振响应。     

摆,油阻尼器减振的试验研究

高柔结构在地震或风荷载作用下会产生很大的振动，本文提出一种控制高柔结构振动的新方法－－摆、油阻尼器体系，并在振动台进行了模拟试验，结果表明：该方法可使结构振动位移幅值减小５０％，在试验中变换了体系的各有关参数，研究了摆长，质量比，碰击间隙对减振效果的影响，文中详细研究了油阻尼器的工作过程及减振机理，从理论上初步分析了摆，油阻尼器体系减振原因，提出了可供实际设计参考的方法和原则。     

利用水箱减振的结构控制研究

本文通过水箱的正弦波激振试验,验证了计算振荡水频率的理论公式,得出了估算振荡水阻尼的经验关系。文中通过水箱-结构体系的地震模拟试验,验证了水箱减振装置的控制效果,并结合试验结果,对水箱-结构体系的地震反应进行了数值模拟。研究结果表明,利用水箱减小高柔结构的地震反应是一种简易、可行、有效的被动控制方式。     

调谐液体减振器的减振作用分析

本文以水箱-结构体系为对象,研究了调谐减振器的减振作用,肯定了它的减振效果,对其减振效果与液体自振频率、液深等因素的关系进行了分析。在本文中水箱的计算模型是三维的,液体用半解析单元离散,结构为一多自由度体系。本文计算模型的自由度数目较一般有限元法大大减少。     

地震和风耦合作用下上海中心大厦结构易损性研究

随着城市人口的增加,越来越多的超高层建筑在中国各大城市涌现,在其全寿命周期内不可避免的会遭受风甚至地震等多灾害的作用。以上海中心大厦为分析模型,根据其场地条件,采用Benowitez在2015年提出的1种基于随机波的模型方法模拟不同高度处具有空间相关性的脉动风荷载时程。通过对Perform 3D有限元软件建立的上海中心大厦模型进行非线性动力时程分析,研究地震和风耦合作用下对于结构性能的影响,并基于多灾害需求生成结构在地震和风耦合作用下的易损性曲面来研究结构的抗振可靠度。结果表明:结构的响应和易损性随着风速和PGA的增大而显著增大;随着风速的增大结构的响应和易损性均有增大的趋势,但随着地震动的增大,风荷载对结构响应和易损性影响逐步减小。     

悬索跨越管道的顺风向风振响应分析

根据渭惠渠跨越段工程中某悬索跨越管道的工程实例,利用MATLAB软件编制了悬索跨越管道的空间相关性风场的模拟程序,模拟风速的功率谱密度函数与目标功率谱均吻合较好,说明本文方法具有较高的精度。将风速转换为风荷载,并施加在悬索跨越管道的有限元模型上,进行风振响应分析,获得结构的位移和加速度时程曲线及构件的应力分布情况,结果表明该悬索跨越管道结构在风荷载作用下是安全的,为同类结构的抗风设计提供参考。     

圆球减振装置对风力发电高塔的振动控制研究

本文提出了圆球减振装置对风力发电高塔振动控制的工作原理和计算方法,并对其控制效果进行了理论研究。首先利用拉格朗日方程推导得到圆球减振装置的自振频率及其对单自由度系统的被动控制力,并推广至多自由度系统。进而将风力发电高塔等效为集中质点模型,建立了风塔-减振装置体系的运动微分方程。用谐波叠加法模拟得到脉动风速时程,分析比较了风力发电高塔在无控及有控状态下的动力响应及疲劳寿命。计算结果表明,圆球减振装置是一种简单、经济和实用的减振装置,能够有效减小风塔的动力响应,延长其疲劳寿命。     

基于非线性模型的TLD参数优化

高柔结构在强风或地震等环境荷载作用下，往往会产生较大的变形和位移。采用调谐液体阻尼器对结构进行控制时，需要选择合适的水箱尺寸和水深，以期获得最好的减振效果。以往的调谐液体阻尼器参数优化往往基于等效线性模型或在小幅值激励下有较好精度的非线性浅水波动模型。采用了一种具有非线性阻尼和非线性刚度的等效调谐质量阻尼器模型对影响调谐液体阻尼器减振效率的主要参数进行了优化，该模型不再受小幅值激励的限制。优化结果表明，激励幅值对TLD的最优参数和减振效果有明显影响，同时水箱长度对TLD减振效果也有明显影响，这是基于线性模型TLD优化不能得到的结论。     

拟负刚度阻尼减振结构的动力特性与减振效果分析

对拟负刚度阻尼减振结构的动力特性与减振效果进行了研究。首先,证明了采用拟负刚度控制方法时,结构响应与外荷载之间满足齐次性;其次,对拟负刚度阻尼减振结构的加速度放大系数和位移放大系数进行了研究,并与粘滞阻尼减振结构的加速度放大系数和位移放大系数进行了比较;最后,对地震荷栽作用下拟负刚度阻尼减振结构的减振效果进行了分析。研究结果表明：当外荷载与结构的频率比大于1或结构的周期较长时,拟负刚度控制对结构绝对加速度的控制效果要好于粘滞阻尼减振结构的控制效果,对结构位移的控制效果要差于粘滞阻尼减振结构的控制效果。     

Tuned liquid dampers simulation for earthquake response control of buildings

This paper is focused on the study of an earthquake protection system, the tuned liquid damper (TLD), which can, if adequately designed, reduce earthquake demands on buildings. This positive effect is accomplished taking into account the oscillation of the free surface of a fluid inside a tank (sloshing). The behaviour of an isolated TLD, subjected to a sinusoidal excitation at its base, with different displacement amplitudes, was studied by finite element analysis. The efficiency of the TLD in improving the seismic response of an existing building, representative of modern architecture buildings in southern European countries was also evaluated based on linear dynamic analyses.     

Control performance comparison between tuned liquid damper and tuned liquid column damper using real-time hybrid simulation

Tuned liquid damper(TLD) and tuned liquid column damper(TLCD) are two types of passive control devices that are widely used in structural control. In this study, a real-time hybrid simulation(RTHS) technique is employed to investigate the difference in control performance between TLD and TLCD. A series of RTHSs is presented with the premise of the same liquid length, mass ratio, and structural parameters. Herein, TLD and TLCD are physically experimented, and controlled structures are numerically simulated. Then, parametric studies are performed to further evaluate the different performance between TLD and TLCD. Experimental results demonstrate that TLD is more effective than TLCD under different amplitude excitations.     

Tuned liquid dampers for controlling earthquake response of structures

Numerical simulations of a single‐degree‐of‐freedom (SDOF) structure, rigidly supporting a tuned liquid damper (TLD) and subjected to both real and artificially generated earthquake ground motions, show that a properly designed TLD can significantly reduce the structure's response to these motions. The TLD is a rigid, rectangular tank with shallow water in it. Its fundamental linear sloshing frequency is tuned to the structure's natural frequency. The TLD is more effective in reducing structural response as the ground excitation level increases. This is because it then dissipates more energy due to sloshing and wave breaking. A larger water‐depth to tank‐length ratio than previous studies suggested, which still falls within the constraint of shallow water theory, is shown to be more suitable for excitation levels expected in strong earthquake motions. A larger water‐mass to structure‐mass ratio is shown to be required for a TLD to remain equally effective as structural damping increases. Furthermore, the reduction in response is seen to be fairly insensitive to the bandwidth of the ground motion but is dependent on the structure's natural frequency relative to the significant ground frequencies. Finally, a practical approach is suggested for the design of a TLD to control earthquake response. Copyright © 2000 John Wiley & Sons, Ltd.     

TLD控制的钢结构振动台模型试验研究

本文通过钢结构的振动台模型试验,研究了在刚性地基条件下矩形调谐流体阻尼器(TLD)对结构地震反应的减震机理和减震效果,为进一步研究土-结构相互作用对结构TLD减震控制效率影响的振动台模型试验提供对比数据。试验结果表明,在水箱中设置铁丝网有助于提高TLD的减震效率,地震动的频谱特性和峰值加速度大小对TLD的减震效率有重要影响。     

An investigation of tuned liquid dampers equipped with damping screens under 2D excitation

This paper reports on the results of a study conducted on tanks partially filled with water, representing tuned liquid dampers (TLD), subjected to both 1D and 2D horizontal excitations. The sloshing response of the water in the tank is characterized by the free surface motion, the resulting base shear force, and evaluation of the energy dissipated by the sloshing water. A 1D non‐linear flow model capable of simulating a TLD equipped with damping screens is employed to model a 2D TLD. Application of this particular model requires the assumption that the response is decoupled and can be treated as the summation of two independent 1D TLDs. Results from the non‐linear flow model are compared with the 2D experimental shake table test results leading to a validation of the decoupled response assumption. This attractive decoupled response property allows square and rectangular tanks to be used as 2D TLDs, which can simultaneously reduce the dynamic response of a structure in two perpendicular modes of vibration. Copyright © 2005 John Wiley & Sons, Ltd.     

A model of tuned liquid damper for suppressing pitching motions of structures

A tuned liquid damper (TLD), which consists of rigid tanks partially filled by liquid, is a type of passive control device relying upon liquid sloshing forces or moments to change the dynamical properties and to dissipate vibrational energy of a structure. An analytical non-linear model is proposed for a TLD using rectangular tanks filled with shallow liquid under pitching vibration, utilizing a shallow water wave theory. The model includes the linear damping of the sloshing liquid, which is an important parameter in the study of a TLD as it affects the efficiency of the TLD. Shaking table experiments were conducted for verification; good agreement between the analytical simulations and the experimental results was observed in a small excitation amplitude range. The simulations of TLD-structure interaction by using the proposed model show that the TLD can efficiently suppress resonant pitching vibration of a structure. It is also found that the effectiveness of a TLD for suppressing the pitching vibration depends not only on the mass of liquid in the TLD but also on the configuration of the liquid as well as upon the position where the TLD is located. If the configuration of the liquid, i.e. the liquid depth and the TLD tank size, is designed suitably, the TLD can have a large suppressing moment and can be very effective even with a small mass of liquid.     

Shaking table test and numerical analysis of offshore wind turbine tower systems controlled by TLCD

A wind turbine system equipped with a tuned liquid column damper(TLCD) is comprehensively studied via shaking table tests using a 1/13-scaled model. The effects of wind and wave actions are considered by inputting responseequivalent accelerations on the shaking table. The test results show that the control effect of the TLCD system is significant in reducing the responses under both wind-wave equivalent loads and ground motions, but obviously varies for different inputs. Further, a blade-hub-tower integrated numerical model for the wind turbine system is established. The model is capable of considering the rotational effect of blades by combining Kane’s equation with the finite element method. The responses of the wind tower equipped with TLCD devices are numerically obtained and compared to the test results, showing that under both controlled and uncontrolled conditions with and without blades’ rotation, the corresponding responses exhibit good agreement. This demonstrates that the proposed numerical model performs well in capturing the wind-wave coupled response of the offshore wind turbine systems under control. Both numerical and experimental results show that the TLCD system can significantly reduce the structural response and thus improve the safety and serviceability of the offshore wind turbine tower systems. Additional issues that require further study are discussed.     

利用调液阻尼器减振的结构控制研究进展

调液阻尼器（ＴＬＤ）是一种新型而有效的结构减振装置。本文论述了这方面研究及应用的进展情况，内容包括：一、ＴＬＤ的优越性和发展历史；二、理论计算模型；三、试验研究；四、ＴＬＤ在实际结构中的应用及测试；五、值得进一步探讨的问题。     

Contribution of tuned liquid column gas dampers to the performance of offshore wind turbines under wind,wave, and seismic excitations

The main intention of the present study is to reduce wind, wave, and seismic induced vibrations of jackettype offshore wind turbines (JOWTs) through a newly developed vibration absorber, called tuned liquid column gas damper (TLCGD). Using a Simulink-based model, an analytical model is developed to simulate global behavior of JOWTs under different dynamic excitations. The study is followed by a parametric study to explore efficiency of the TLCGD in terms of nacelle acceleration reduction under wind, wave, and earthquake loads. Study results indicate that optimum frequency of the TLCGD is rather insensitive to excitation type. In addition, while the gain in vibration control from TLCGDs with higher mass ratios is generally more pronounced, heavy TLCGDs are more sensitive to their tuned frequency such that ill-regulated TLCGD with high mass ratio can lead to destructive results. It is revealed that a well regulated TLCGD has noticeable contribution to the dynamic response of the JOWT under any excitation.     

TLD对海洋平台地震反应控制的简化计算方法

调频液体阻尼器（Tune Liquid Damper，简称TLD）对地面结构位移反应与加速度反应的较好控制作用已得到理论与试验的验证。本文在此基础上研究了TLD对海洋平台动力反应控制的简化计算方法。计算中，TLD中液体的控制力采用较精确的数值计算法和简化计算法两种方法，通过对海洋平台地震反应计算的结果表明，该简化计算方法具有很高的精度，其结果对海洋平台的抗震设计具有借鉴作用。