利用分布式负刚度装置对现有结构进行抗震保护

K. Kapasakalis, Spiridon Kapasakalis, Evangelos x Evangelos SAPOUNTZAKIS
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摘要

在这项研究中,对 KDamper 概念进行了扩展(EKD 装置),并将其应用于现有多层建筑结构的多个楼层,旨在降低地震激励引起的结构动态响应。KDamper 是一种新颖的被动减震概念,主要基于适当刚度元素的优化组合,其中一个刚度元素为负值(NS)。与调谐质量阻尼器(TMD)相比,KDamper 对质量的要求更低,因为 NS 元件是根据安装质量实施的,而且 NS 力与惯性力同相,人为地放大了惯性力。受分布式 TMD(d-TMD)概念的启发,为进行抗震保护,安装了多个 EKD(d-EKD),并沿结构高度分布。这些 EKD 的设计和空间分配是通过和谐搜索 (HS) 算法确定的,该算法可在遵守结构约束和限制的同时确定最佳装置参数。生成人工加速度图并将其作为优化过程的输入。根据所获得的数值结果,d-EKD 概念在降低结构动态响应方面优于 d-TMD,其引入的附加振荡质量小了一个数量级。此外,结果表明,尽管增加了质量和 NS 元素,但由于安装了拟议的 EKD 装置,结构特性和特征频率没有发生重大变化。
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SEISMIC PROTECTION OF EXISTING STRUCTURES WITH DISTRIBUTED NEGATIVE STIFFNESS DEVICES
In this research study, the KDamper concept is extended (EKD device) and applied to multiple floors of existing multi-story building structures, aiming to reduce the structure dynamic responses due to earthquake excitations. The KDamper is a novel passive vibration absorption concept, based essentially on the optimal combination of appropriate stiffness elements, one of which has a negative value (NS). The mass requirements of KDamper are reduced, compared to the Tuned Mass Damper (TMD), as the NS element is implemented to the installed mass and the NS force is in phase with the inertia force, artificially amplifying it. Inspired by the concept of distributed TMDs (d-TMDs), multiple EKDs (d-EKDs) are installed and distributed along the height of the structure, for seismic protection. The design and spatial allocation of these EKDs are determined using a Harmony Search (HS) algorithm, which identifies optimal device parameters while adhering to structural constraints and limitations. Artificial accelerograms are generated and introduced as input to the optimization process. Based on the numerical results obtained, the d-EKD concept, outperforms the d-TMD in reducing the structural dynamic responses, introducing one order of magnitude smaller added oscillating masses. In addition, results indicate no significant alteration of the structural properties and eigenfrequencies due to the installation of the proposed EKD devices, despite the addition of masses and NS elements.
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