钢筋混凝土结构基于地震损伤性能的设计

本文结合我国地震设防水准,在国内外有关地震损在量研究结果的基础上,提出钢筋混凝土结构地震损伤的“三水准”性能目标;其次,对于剪切型钢筋混凝土结构,提出了结构层间柱－压弯构件三线性恢复力模型参数确定和地震损伤计算方法;第三,提出了地震损伤直接验算和将地震损伤验算归结为变形验算的钢筋混凝土结构地震损伤性能设计方法;最后,通过设计例题说明了本文方法应用的可行性。     

钢筋混凝土结构基于改进能力谱法的地震损伤性能设计

本文基于国内外非线性静力分析方法,阐述了最近由Ｃｈｏｐｒａ和Ｇｏｅｌ提供的改进能力谱法的基本概念和实施步骤;其次,结合文献「１８」中提出的钢筋沸凝土结构地震损伤“三水准”性能目标和改进能力谱法,提出了基于能力谱法的结构地震损伤性能简化设计及验算方法;最后,通过设计例题说明了本文方法的可行性,并将计算结果与时程分析进行了比较,显示了此法的有效性。     

非线性结构体系可靠度的重要抽样方法

最近S．K．AU与J．L．Beck提出了一种高效率的线性体系的重要抽样法。本文应用0方差抽样的概念对Au和Beck的方法进行了分析,然后在此基础上把Au和Beck的方法推广到具有非线性失效面的结构体系。应用本文提出的方法对3个算例进行了计算分析,抽样20次的结果与一般抽样法10^5～10^6次的结果非常接近,表明本文方法有很高的计算效率。     

立式钢制储罐基于地震损伤性能的抗震设计方法

针对立式钢制储罐在强烈地震作用下会产生不同程度的损伤的特点，遵循抗震设计规范的“小震不坏，中震可修，大震不倒”的抗震设计原则，结合三水准烈度，提出了储罐的地震损伤性能目标，并给出了基于地震损伤性能的抗震设计方法。所提出抗震设计方法，更加准确地考虑了储罐的提离问题。     

基于性能的基础隔震钢筋混凝土框剪结构的倒塌可靠度分析

利用基于性能的结构可靠度分析方法,对基础隔震钢筋混凝土框剪结构进行分析研究。选取20条实际地震动记录,以0.2g为步长对结构地震动参数PGA进行调幅后,建立了140个结构-地震动样本空间。选取上部结构的最大层间位移角、隔震层位移为量化指标,对每一个样本进行动力非线性时程分析后,将结构响应进行统计得到结构在各地震动强度下超越极限破坏状态的概率,将其绘制成基础隔震钢筋混凝土框剪结构的易损性曲线并利用整体可靠度方法分析结构发生倒塌的可靠度指标。该方法直观地反映了结构发生倒塌的概率,为结构的地震损失评估提供依据。     

线性结构的非平稳随机地震反应与可靠度分析

基于Sigma振子过程完全非平稳地震荷载模型,建立线性结构随机地震反应分析的时域表达式,利用Simpson法则迭代计算结构随机地震反应的二阶统计特性,由穿越方法,给出具有较大设计安全界限结构地震可靠度的近似评估方法。一个抗弯钢框架的非平稳地震反应与可靠度分析,说明了本文方法的效率、精度和应用过程。     

基于性能的结构抗震设计研究

介绍了结构抗震性能水准的划分、抗震性能目标的确定以及常用的基于性能的抗震设计方法。文中着重探讨了按延性系数进行结构性能抗震设计的方法和步骤，最后指出性能抗震设计方法今后的发展趋势。     

大型塔式容器抗震可靠性设计的实用方法

本文在文献[1]的基础上，提出塔式容器抗震可靠性设计的实用方法，该方法可以直接导实际大型塔式容器的抗震可靠性设计及抗震加固。     

基于能量分析的地震损伤性能评估

结合能量分析法和文献[1]提出的钢筋混凝土框架结构“三水准”地震损伤性能目标,采用改进的双参数线性组合地震损伤模型,本文提出了基于能量分析的地震损伤性能评估方法;通过算例说明了本文提出的抗震性能评估方法不仅能够准确地分析结构在大震作用下的地震损伤性能,而且思路简洁、计算方便、可用于结构抗震性能评估;另外,本文提出的地震损伤模型具有较强的灵活性,可适用于不同钢筋混凝土构件和结构的抗震性能评估。     

Reliability-based design of R/C water tank structures under seismic action

Based on a reliability level 2 method, a procedure is proposed to design reinforced concrete structures for elevated tanks subjected to seismic action, with a specified probability of failure in a 50-year design life. To evaluate the probability of failure the ultimate limit state is obtained when the top column displacement demanded by the earthquake, a random variable, reaches the allowable displacement, which is here treated as deterministic. The seismic action is characterized probabilistically by the power spectral density function of the ground acceleration, which is obtained from a design spectrum. The strength and ductility of an annular column section of confined reinforced concrete for cyclic loads are evaluated with design aids. Design charts are made for a given tank capacity and specified seismic zone that allow one to choose different combinations of strength, stiffness and ductility for the same tolerable probability of failure. A step by step method is suggested for the design of the annular column section, choosing finally the most convenient design. The advantage of this methodology is shown through a numerical example.     

Global damage indexes for the seismic performance assessement of RC structures

When performing the seismic risk assessment of new or existing buildings, the definition of compact indexes able to measure the damaging and safety level of structures is essential, also in view of the economic considerations on buildings rehabilitation. This paper proposes two series of indexes, named, respectively, Global Damage Indexes (GDIs), which are representative of the overall structure performance, and Section Damage Indexes (SDIs), which assess the conditions of reinforced concrete (RC) beam‐column sections. Such indexes are evaluated by means of an efficient numerical model able to perform nonlinear analyses of the RC frame, based on the continuum damage mechanics theory and fiber approach. An improvement of a two‐parameter damage model for concrete, developed by some of the authors, which guarantees a better correlation between the Local Damage Indexes (LDIs) and the material's mechanical characteristics, is also presented. For the reinforcement, a specific LDI, named ‘steel damage index’, which takes into account the plastic strain development and the bar buckling effect, is proposed. The numerical model has been employed to simulate several experimental tests, in order to verify the accuracy of the proposed approach in predicting the RC member's behavior. Nonlinear static and dynamic analyses of two RC frames are carried out. The robustness of the method, as well as the effectiveness of the GDIs in assessing the structural conditions, are demonstrated here. Finally, comparisons between the evolution of GDIs and the achievement of the performance levels as proposed in FEMA 356 are reported. Copyright © 2009 John Wiley & Sons, Ltd.     

抗震设计中结构的性能等级与设计性能安全指数

通常根据结构的破坏程度可以将结构的破坏划分为：基本完好、轻微破坏、中等破坏、严重破坏、倒塌等5个阶段。根据这5个阶段,本文将结构在地震过程中的性能极限状态划分为：功能连续极限状态、破坏控制极限状态、控制损失极限状态和防止倒塌极限状态,并以此作为划分结构性能等级的标准。定义结构失效概率的自然对数的负值为设计性能安全指数,通过计算结构失效概率对各构件可靠指标的一阶偏导数的方法,求出结构的设计性能安全等级。这种方法可以考虑建筑结构构件、建筑非结构构件以及其它非结构构件的性能,而且同时可以考虑结构系统总体效应的影响,因而能够比较全面地反映结构的抗震性能等级。     

FRC框架结构的损伤程度控制及性能评估

为研究纤维增强混凝土(FRC)框架结构体系预期损伤部位的损伤程度控制和性能评估方法,采用ABAQUS有限元软件对该框架结构模型进行动力时程分析.针对该结构体系,研究其各种性能水准极限状态的定性描述和量化方法,并进行结构抗震性能评估.研究结果显示,预期损伤部位采用FRC材料,可以减小RC框架结构的层间残余侧移角、柱端截面...     

钢框架结构直接基于位移抗震性能设计的非迭代法

为使直接基于位移的抗震性能设计方法更加简便准确,本文采用一种直接基于位移的非迭代抗震设计方法对钢框架结构进行设计。该方法首先考虑结构的非弹性反应确定等效弹性反应谱和弹塑性反应谱,并建立了使用Newmark-Hall变形折减系数的能力谱的明确表达式。采用能力-需求图方法,确定了结构需要的目标位移与延性、谱位移和谱加速度之间关系的明确表示式,得到结构的刚度和设计基底剪力,进而确定构件截面,完成结构设计。对五层两跨平面钢框架结构进行了直接基于位移的抗震性能设计,设计过程简便,无需迭代程序,不需画出反应谱,通过时程分析验证了设计结果的精确性。本文研究表明:直接基于位移的非迭代抗震设计方法是一种简便、高效、精确的抗震性能设计方法。     

Response-based damage assessment of structures

The structure's ability to survive an earthquake may be measured in terms of the expected state of damage of the structure after the earthquake. Damage may be quantified by using any of several damage indices defined as functions whose values can be related to particular structural damage states. A number of available response-based damage indices are discussed and critically evaluated for their applicability in seismic damage evaluation. A new rational approach for damage assessment is presented which provides a measure of the physical response characteristics of the structure and is better suited for non-linear structural analysis. A practical method based on the static pushover analysis is proposed to estimate the expected damage to structures when subjected to earthquakes of different intensities. Results of the analysis of ductile and non-ductile reinforced concrete buildings show that the proposed procedure for damage assessment gives a simple, consistent and rational damage indicator for structures. Copyright © 1999 John Wiley & Sons, Ltd.     

Reliability-based optimal design of nonlinear viscous dampers for the seismic protection of structural systems

Viscous dampers are widely employed for enhancing the seismic performance of structural systems, and their design is often carried out using simplified approaches to account for the uncertainty in the seismic input. This paper introduces a novel and rigorous approach that allows to explicitly consider the variability of the intensity and characteristics of the seismic input in designing the optimal viscous constant and velocity exponent of the dampers based on performance-based criteria. The optimal solution permits controlling the probability of structural failure, while minimizing the damper cost, related to the sum of the damper forces. The solution to the optimization problem is efficiently sought via the constrained optimization by linear approximation (COBYLA) method, while Subset simulation together with auxiliary response method are employed for the performance assessment at each iteration of the optimization process. A 3-storey steel moment-resisting building frame is considered to illustrate the application of the proposed design methodology and to evaluate and compare the performances that can be achieved with different damper nonlinearity levels. Comparisons are also made with the results obtained by applying simplifying approaches, often employed in design practice, as those aiming to minimize the sum of the viscous damping constant and/or considering a single hazard level for the performance assessment.