Inelastic response spectra for an integrated displacement and energy-based seismic design (DEBD) of structures

IF 2.2 Q2 CONSTRUCTION & BUILDING TECHNOLOGY
Giulio Proietti, Livio Pedone, Simone D'Amore, Stefano Pampanin
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Abstract

The severe socio-economic impact of recent earthquakes has further highlighted the crucial need for a paradigm shift in performance-based design criteria and objectives towards a low-damage design philosophy, in order to reduce losses in terms of human lives, repair/reconstruction costs, and recovery time (deaths, dollars and downtime). Currently, displacement-based parameters are typically adopted to design/assess the seismic performance of the structures, by limiting the maximum displacement or the maximum interstorey drift ratio (IDR) reached by the structure under different earthquake intensities. However and arguably, displacement-based quantities are characterized by inherent weaknesses, since, for instance, they are not cumulated parameters, thus not able to capture directly the effects of multiple cycles, deterioration and damage cumulation. Therefore, in the last decades, energy-based approaches were investigated and developed in order to establish alternative engineering demand parameters for the assessment of post-event damage through a dynamic energy balance. Towards the main goal of developing an integrated Displacement and Energy-Based Design/assessment procedure (DEBD) for actual use in practice, this research work proposes an innovative approach based on the use of inelastic spectra correlating the energy components with the corresponding maximum displacement response parameters of the structure. In practical terms, the proposal is to further integrate and develop the well-known Direct Displacement-Based Design, by directly adopting the hysteretic energy as an additional design parameter. The energy inelastic spectra are developed through an extensive parametric analysis of Single-Degree-of-Freedom (SDoF) systems, with different nonlinear hysteretic models. In such an approach, the maximum seismic energy demand imparted to a structure can be directly predicted and controlled, whilst distinguishing the various components of the energy balance, including the hysteretic one. The effects of near-field and far-field earthquakes are also investigated. Results show that in the first case the seismic demand is concentrated in the peak of a few large cycles that absorb the demand energy induced by the high component in peak ground velocity in the second case the higher equivalent number of plastic cycles tends to become critical for structures with inadequate structural details and prone to suffer by cumulative cycles and overall plastic fatigue mechanisms.
基于位移和能量的结构抗震设计的非弹性反应谱
最近地震造成的严重社会经济影响进一步突出表明,迫切需要将基于性能的设计标准和目标转变为低损害设计理念,以减少人员生命损失、修复/重建成本和恢复时间(死亡、美元和停机时间)。目前,通常采用基于位移的参数来设计/评估结构的抗震性能,通过限制结构在不同烈度下达到的最大位移或最大层间位移比(IDR)。然而,基于位移的数量有其固有的弱点,因为,例如,它们不是累积参数,因此不能直接捕捉多次循环、恶化和损害累积的影响。因此,在过去的几十年里,基于能量的方法被研究和发展,以建立替代的工程需求参数,通过动态能量平衡来评估事件后的损害。为了开发一种基于位移和能量的综合设计/评估程序(DEBD)以供实际应用,本研究提出了一种基于非弹性谱的创新方法,该方法将结构的能量分量与相应的最大位移响应参数相关联。在实践中,建议进一步整合和发展著名的直接基于位移的设计,直接采用滞回能作为附加的设计参数。通过对具有不同非线性滞回模型的单自由度系统进行广泛的参数分析,得到了系统的能量非弹性谱。在这种方法中,可以直接预测和控制赋予结构的最大地震能量需求,同时区分能量平衡的各个组成部分,包括滞后部分。研究了近场和远场地震的影响。结果表明,在第一种情况下,地震需求集中在几个大循环的峰值上,这些大循环吸收了峰值地面速度高分量引起的需求能量;在第二种情况下,较高的等效塑性循环次数对于结构细节不充分的结构来说变得至关重要,容易遭受累积循环和整体塑性疲劳机制的影响。
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
Frontiers in Built Environment
Frontiers in Built Environment Social Sciences-Urban Studies
CiteScore
4.80
自引率
6.70%
发文量
266
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