ASSESSMENT OF EXISTING STEEL FRAMES WITH INFILLS UNDER MULTIPLE EARTHQUAKES

Proceedings of the 7th International Conference on Computational Methods in Structural Dynamics and Earthquake Engineering (COMPDYN 2015) Pub Date : 2019-06-26 DOI:10.7712/120119.7347.19837

L. Sarno, J.R. Wu, M. D’Aniello, S. Costanzo, R. Landolfo, O. Kwon, F. Freddi

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引用次数: 2

Abstract

Many existing steel multi-storey frames in Europe were designed prior to the provisions of modern seismic design codes; therefore, they often exhibit low resistance to earthquakes due to their insufficient energy dissipation capacity. However, the current framework for assessing existing structures in EC8-3 is inadequate and should be reviewed. Particular attention should be paid to the contribution from masonry infill walls as they significantly affect the modal properties and the lateral stiffness of structures. To this end, two 3D models of a two-storey steel moment-resisting frame were developed to assess the applicability of the current framework in EC8-3 to the infilled structures under multiple earthquakes through nonlinear analyses. The modelling of masonry infill walls was achieved through a macro-model using equivalent diagonal struts. The ground motions utilised during the analyses took the records of the recent 2016 Central Italy earthquake sequence. As part of the project HITFRAMES, this paper serves as a preparation for the experiment to be conducted in Greece.

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多次地震作用下既有填充钢框架的评估

在欧洲，许多现有的多层钢框架是在现代抗震设计规范规定之前设计的;因此，由于耗能能力不足，往往表现出较低的抗震性能。然而，目前评估EC8-3中现有结构的框架是不够的，应该进行审查。应特别注意砌体填充墙的贡献，因为它们显著影响结构的模态特性和侧移刚度。为此，开发了两层钢抗弯矩框架的两个三维模型，通过非线性分析来评估EC8-3中当前框架在多次地震下对填充结构的适用性。通过采用等效斜杆的宏观模型对砌体填充墙进行建模。分析过程中使用的地面运动记录了2016年意大利中部地震序列。作为HITFRAMES项目的一部分，本文为将在希腊进行的实验做准备。

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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Proceedings of the 7th International Conference on Computational Methods in Structural Dynamics and Earthquake Engineering (COMPDYN 2015)

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