Multi-experimental seismic analysis of low-rise thin reinforced concrete wall building with unconnected elastomeric isolators using real-time hybrid simulations

IF 2.1 4区 工程技术 Q2 CONSTRUCTION & BUILDING TECHNOLOGY
Bryan Castillo Torres, Eivar A Artunduaga Triviño, Johannio Marulanda Casas, Albert R Ortiz, Peter Thomson
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引用次数: 0

Abstract

In response to the pressing need for housing and streamlining construction processes, the building industry has embraced innovative construction techniques. One such method, known as the Industrialized Housing Construction (IHC) system, departs from traditional framing systems by utilizing thin-reinforced concrete walls (TRCW). These TRCWs, characterized by high flowability and rapid strength gain, enable quick and efficient monolithic construction of walls and slabs. However, challenges have arisen regarding the structural behavior of these elements, potentially compromising their seismic performance. Given the significant seismic risk, there is a compelling need to develop resilient buildings by using this cost-efficient structural system. This study proposes the use of passive control systems such as base isolation to address this problem. While base isolation has proven effective in other countries, its feasibility in structures using TRCW and its performance during actual seismic events warrants further investigation. This paper presents an innovative approach using Multi-Axial Real-Time Hybrid Simulation (M-RTHS), which combines numerical and experimental components to gain deeper insights into the seismic response of low-rise TRCW buildings with base isolation using unconnected fiber-reinforced elastomeric isolators (U-FREIs). The methodology is detailed and includes the division of the structure into numerical and experimental segments and the use of transfer systems to replicate real seismic excitations, including those from El Centro (USA, 1940), Pizarro (Colombia, 2004), Chihuahua (Mexico, 2013), Loma Prieta (USA, 1989), and Kobe (Japan, 1995), with a maximum amplitude of 7.36 [Formula: see text] (0.75 g). The results highlight a remarkable reduction in upper structure floor drifts of over 57.47%, the characterization of the behavior and energy dissipation of each experimental specimen, and the optimal evaluation of M-RTHS. This research paves the way for improving the seismic resistance of buildings in regions prone to seismic activity, especially those using innovative construction methods such as TRCW.
利用实时混合模拟对带有非连接弹性隔震器的低层钢筋混凝土薄壁建筑进行多重试验性抗震分析
为了满足对住房的迫切需求并简化施工流程,建筑行业采用了创新的施工技术。其中一种方法被称为 "工业化住宅建筑(IHC)系统",它采用薄型钢筋混凝土墙(TRCW),从而摆脱了传统的框架系统。这些 TRCW 的特点是流动性高、强度增加快,可以快速高效地整体建造墙体和楼板。然而,这些构件的结构行为也面临挑战,可能会影响其抗震性能。鉴于巨大的地震风险,亟需利用这种具有成本效益的结构系统来开发抗震建筑。本研究建议使用基座隔震等被动控制系统来解决这一问题。虽然基底隔震在其他国家已被证明是有效的,但其在使用热浸镀锌钢筋混凝土的结构中的可行性及其在实际地震事件中的性能还需要进一步研究。本文介绍了一种使用多轴实时混合模拟(M-RTHS)的创新方法,该方法结合了数值和实验组件,可深入了解使用非连接纤维增强弹性体隔震器(U-FREIs)进行基底隔震的低层嗮瓦建筑的地震响应。研究方法非常详细,包括将结构划分为数值段和实验段,并使用传递系统来复制真实地震激励,包括埃尔森特罗(美国,1940 年)、皮萨罗(哥伦比亚,2004 年)、奇瓦瓦(墨西哥,2013 年)、洛马普列塔(美国,1989 年)和神户(日本,1995 年)的地震激励,最大振幅为 7.36 [计算公式:见正文] (0.75 g)。研究结果表明,上部结构楼板漂移明显减少了 57.47%以上,每个实验样本的行为和能量耗散都得到了表征,并对 M-RTHS 进行了优化评估。这项研究为提高地震多发地区建筑物的抗震性铺平了道路,尤其是那些采用创新施工方法(如 TRCW)的建筑物。
本文章由计算机程序翻译,如有差异,请以英文原文为准。
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来源期刊
Advances in Structural Engineering
Advances in Structural Engineering 工程技术-工程:土木
CiteScore
5.00
自引率
11.50%
发文量
230
审稿时长
2.3 months
期刊介绍: Advances in Structural Engineering was established in 1997 and has become one of the major peer-reviewed journals in the field of structural engineering. To better fulfil the mission of the journal, we have recently decided to launch two new features for the journal: (a) invited review papers providing an in-depth exposition of a topic of significant current interest; (b) short papers reporting truly new technologies in structural engineering.
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