建筑结构利用TLCD减振的神经网络智能控制

本文提出了建筑结构利用调谐液体柱型阻尼器（ＴＬＣＤ）减振的神经网络智能控制方法。首先阐述了确定ＴＬＣＤ半主动控制策略;然后利用ＢＰ人工神经网络方法计算并控制ＴＬＣＤ隔板孔洞的面积,以调节和控制阻尼比＆Ｔ,实现对建筑结构的智能控制。地震作用下的数值分析表明,本文所述的方法是十分有效的。     

高层建筑地震反应最优多重TLD控制

本文以坑层建筑地震反应进行了最优多重ＴＬＤ（ＭＴＬＤ）ｓ控制研究。文中阐述了ＴＬＤ系统的工作原理笔ＭＴＬＤｓ系统的参数；建立了多层结构－ＴＭＬＤｓ系统耦联体系的运动方程；分析了ＭＴＬＤｓ系统的参数对在谐波作用下多层结构动力反应的影响以及各参数之间的关系。     

TLD结构减震体系的简化计算

本文提出了ＴＬＤ结构减体系的简化计算方法,并与数值计算方法进行了比较,通过对ＴＤＬＤ结构系振动控制仿真计算结果的分析, 结论;两种计算方法的结果比较吻合。     

设置TMD,TLD控制系统的高层建筑风振分析与设计方法

本文结合我国现行风荷载规范，研究设置ＴＭＤ、ＴＬＤ控制系统的高层建筑风振分析与抗风设计的实用方法。首先，ＴＭＤ、ＴＬＤ系统的风振控制效果归并到了受控结构的内荷载折减上；其次，导出了满足舒适度标准的结构动侧移界限的相应的计算公式；第三，比较了ＴＭＤ、ＴＬＤ系统的控制效果以及分别对高层钢和钢筋混凝土结构的控制效果；最后，通过大量的计算和分析，分别确定了ＴＭＤ、ＴＬＤ系统参数的最佳取值区间以及参数之间的     

相邻建筑结构的模糊振动控制

本文研究了相邻建筑结构的模糊控制问题。首先,介绍相邻建筑结构体系的特点,建立体系的力学模型及运动方程;然后,进行了半主动控制研究,提出了控制的方法;最后,利用模糊控制方法实现了结构的智能控制。通过以上研究,说明相邻建筑结构相互振动控制是十分有效的,所得出的结论对实际工程的应用具有指导意义。     

工程抗震的新领域——结构振动控制

本文叙述了建筑结构振动控制的起源和设想,介绍了控制理论在建筑结构抗震中的应用和当前振动控制应用开发研究的现状,最后提出了该领域研究的前景展望和有待解决的主要理论和技术课题.      

HEDC控制体系的参数优化设计

介绍了高效被动阻尼控制装置（ＨＥＤＣ）的工作原理,利用Ｈａｍｉｌｔｏｎ原理,建立了ＨＥＤＣ控制体系地运动方程。通过仿真计算,分析和研究了ＨＥＤＣ参数对控制效果的影响规律,得到了一些有意义的结论。参数优化结果表明,通过合理设计参数,ＨＥＤＣ可以充分发挥阻尼器的工作潜力,取得十分显著的控制效果。     

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。     

A STUDY ON VIBRATION REDUCTION IN HIGH-RISE STRUCTURES BY MULTI-TLDs

本文研究高层建筑利用调液阻尼器（ＴＬＤ）减小地震反应的方法。首先探讨了激励频率比、调谐频率比对减震效果的影响。在此基础上建立了具有不同ＴＬＤ设置方式的高层建筑体系的学模型和运动方程，首次提出了利用多个ＴＬＤ减小高层建筑多个振型的方法。最后通过数值算例验证了本文方法的有效性。     

基于交通振动环境下建筑结构损伤机理及减振隔振的研究现状

随着交通建设的发展,越来越多的公路要临近已有建筑物通过,而由于建设或重车通行引起的振动对周边建筑结构产生了很大的安全威胁,严重的甚至造成了建筑结构的损坏。论文通过对交通振动下建筑结构的振动控制标准和在振动中的损伤机理进行综述,系统总结了交通振动对建筑影响的方法,介绍了目前交通振动对建筑结构安全性影响的研究现状和方法,分析了减振隔振的发展现状,创新性的提出将疲劳寿命作为建筑结构振动容许值的参考依据。在总结分析现状的情况下提出目前存在的问题,给出了相关的意见和建议,可为今后的相关研究提供参考。     

神经网络半主动TLCD对偏心结构的减震控制

本文采用在结构水平双向设置TLCD半主动控制装置的方法，对偏心结构在多维地震作用下的振动控制问题进行研究。首先利用多层前向神经网络，对偏心结构在双向地震输入下的两个平动方向的反应进行预测，然后在建立起半主动控制策略的基础上，利用神经网络根据控制准则调整TLCD的开孔率，实现以结构的半主动控制，数值结构表明，这种方法能对结构的平动反应和扭转反应都能起到的较好的减震效果。     

Wind-induced vibration control of bridges using liquid column damper

The potential application of tuned liquid column damper (TLCD) for suppressing wind-induced vibration of long span bridges is explored in this paper. By installing the TLCD in the bridge deck, a mathematical model for the bridge-TLCD system is established. The governing equations of the system are developed by considering all three displacement components of the deck in vertical, lateral, and torsional vibrations, in which the interactions between the bridge deck, the TLCD, the aeroelastic forces, and the aerodynamic forces are fully reflected. Both buffeting and flutter analyses are carried out. The buffeting analysis is performed through random vibration approach, and a critical flutter condition is identified from flutter analysis. A numerical example is presented to demonstrate the control effectiveness of the damper and it is shown that the TLCD can be an effective device for suppressing wind-induced vibration of long span bridges, either for reducing the buffeting response or increasing the critical flutter wind velocity of the bridge.     

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.     

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.     

Active tuned liquid column damper with propellers

The active control of a Tuned Liquid Column Damper (TLCD) with two propellers is presented. A single‐degree‐of‐freedom system with a passive or active TLCD is used as an example to set up the basic equation of motion. The Optimal Control Theory is applied to establish the control law and to calculate the control force generated by these two propellers installed inside the TLCD. A simple pendulum‐like model test is carried out to study the dynamic characteristics of the passive and active TLCDs and the effectiveness of the vibrational control. Comparison of the experimental result with the analytical one shows a good agreement. Finally, the analytical results of the seismic response are also included as an example for demonstration and application. Copyright © 2003 John Wiley & Sons, Ltd.     

Impact of seismic excitation characteristics on the efficiency of tuned liquid column dampers

Various types of passive control systems have been used to suppress the seismic response of structures in recent years. Among these systems, Tuned Liquid Column Dampers （TLCDs） dissipate the input earthquake energy by combining the effects of the movement of the liquid mass in the container, the restoring force on the liquid due to the gravity loads and the damping due to the liquid movement through orifices. In this study, the effects of seismic excitation characteristics such as frequency content and soil condition on the seismic performance of TLCDs are investigated using nonlinear time-history analyses. In this regard, among the past earthquake ground motion records of Iran, 16 records with different parameters were selected. In the structural model developed, the attached TLCD is simulated as a Tuned Mass Damper （TMD） having the same vibration period and damping ratio as the original TLCD. The numerical results show that the seismic excitation characteristics have a substantial role on the displacement reduction capability of TLCDs and they should be considered accordingly in the design of TLCDs.     

半主动TLCD对固定式海洋平台的离散神经网络滑模控制

主要研究了半主动调液柱型阻尼器（TLCD）对固定式海洋平台的离散神经网络滑模变结构控制方法。首先建立了平台结构-TLCD控制系统微分方程及其离散化状态空间表达,然后阐述了基于神经网络的滑模变结构控制的基本算法和控制策略,最后应用该神经网络滑模变结构控制策略对一个已建成的实际海洋平台结构的TLCD半主动控制问题进行了数值仿真分析。仿真分析的结果证明了该方法的有效性。     

多维地震作用下非对称结构利用TLCD减震控制研究

本文提出在结构两正交方向同时设置U形调液阻尼器（TLCD）用来减小地震作用下的平动－扭转反应，文中建立了结构－TLCD体系在多维地震动作用下的运动方程，分析了系统参数对减震效果的影响，最后通过数值算例，给出了高层建筑平扭耦联地震反应的减震效果。     

ER智能材料在结构振动控制中的应用

ＥＲ智能材料是一种可控流体,它能在电场的作用下可从牛顿流体变为剪切屈服应力较高的粘塑性体,且这种转变连续,可逆,迅速,因此,可用它来制作可调阻尼器,实现对工程结构风振和地震反应半主动控制,本文在简要地介绍了ＥＲ智能材料电流变效应的基本原理和影响因素之后,建立了适用于土木工程结构控制用的二种类型的ＥＲ可调阻尼器的工作原理和力学模型,并在介绍了ＥＲ可控阻尼器对工程结构风振和地震反应半主动控制的实施原则