半比例浮石混凝土砌体建筑的结构响应:振动台/环境振动试验和有限元分析

IF 1.9 3区 工程技术 Q3 MECHANICS
Ali Kaya, Boudjamaa Roudane, Süleyman Adanur, Fezayil Sunca, Ali Fuat Genç, Murat Gunaydin, Ahmet Can Altunişik
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引用次数: 0

摘要

砌体结构的抗震性能评估对于确保地震多发地区建筑物的安全和抗震能力至关重要。文献中关于浮石构件的研究数量有限。此外,将浮石砌体建筑作为一个整体结构来研究其地震行为的研究几乎为零。在这种情况下,对其地震响应和动态特性缺乏全面的了解。针对这一知识空白,我们开展了一项振动台实验活动,将半比例浮石砌体建筑暴露在模拟地震力下。为了加强实验结果,还进行了数值模拟,以确认和扩展我们对浮石砌体结构如何对动态力做出反应的理解。综合实验和数值结果,我们可以全面了解浮石砌体建筑在地震事件中的表现。实验研究结束时,观察到浮石模型的频率值与未损坏状态相比降低了 23.5%。在数值模型中,这一数值降低了 19.85%。对于未损坏和损坏模型,前三个实验模态振型与数值模态振型相似。实验和数值结果都表明,预期的损坏发生在相同的区域。这些结果表明,非线性 FE 模型有助于确定潜在的破坏模型位置。这些研究结果对类似传统砌体建筑的抗震设计和改造具有借鉴意义,有助于在地震多发地区开发具有抗震能力的可持续工程解决方案。
本文章由计算机程序翻译,如有差异,请以英文原文为准。

Structural response of half-scale pumice concrete masonry building: shake table/ambient vibration tests and FE analysis

Structural response of half-scale pumice concrete masonry building: shake table/ambient vibration tests and FE analysis

Seismic performance evaluation of masonry structures is of paramount importance for ensuring the safety and resilience of buildings in earthquake-prone regions. There are limited number of studies on pumice elements in the literature. In addition, there are almost no studies investigating the earthquake behavior of pumice masonry building as a whole structure. In this context, a comprehensive understanding of their seismic response and dynamic characteristics has been lacking. To address this knowledge gap, a shake-table experimental campaign was undertaken, wherein half-scale pumice masonry building was exposed to simulated seismic forces. To enhance the experimental findings, numerical simulations were performed to confirm and expand our comprehension of how the pumice masonry structure responds to dynamic forces. Integrating both experimental and numerical outcomes provides a holistic understanding of how pumice masonry buildings behave during seismic events. At the end of the experimental study, the frequency values of the pumice model were observed to decrease up to 23.5% in the modes compared to the undamaged state. In the numerical model, this value decreases up to 19.85%. For the undamaged and damaged model, the first three experimental mode shapes were similar to the numerical mode shapes. Both experimental and numerical results show that the expected damages occur in the same regions. These results show that nonlinear FE models can be helpful in determining potential damage model locations. The findings have implications for the seismic design and retrofitting of similar traditional masonry buildings, facilitating the development of resilient and sustainable engineering solutions in seismic-prone regions.

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来源期刊
Meccanica
Meccanica 物理-力学
CiteScore
4.70
自引率
3.70%
发文量
151
审稿时长
7 months
期刊介绍: Meccanica focuses on the methodological framework shared by mechanical scientists when addressing theoretical or applied problems. Original papers address various aspects of mechanical and mathematical modeling, of solution, as well as of analysis of system behavior. The journal explores fundamental and applications issues in established areas of mechanics research as well as in emerging fields; contemporary research on general mechanics, solid and structural mechanics, fluid mechanics, and mechanics of machines; interdisciplinary fields between mechanics and other mathematical and engineering sciences; interaction of mechanics with dynamical systems, advanced materials, control and computation; electromechanics; biomechanics. Articles include full length papers; topical overviews; brief notes; discussions and comments on published papers; book reviews; and an international calendar of conferences. Meccanica, the official journal of the Italian Association of Theoretical and Applied Mechanics, was established in 1966.
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