地震作用下钢筋混凝土框架-填充墙相互作用分析

对带填充墙的钢筋混凝土框架结构进行数值分析,研究填充墙体对框架结构抗震性能的影响。采用有限元软件ABAQUS建立了填充墙框架结构模型,通过数值模拟分别分析了墙体开洞、墙体材料以及填充墙与框架的连接形式在多遇和罕遇地震下对填充墙框架动力响应及损伤的影响。分析结果表明:刚性连接下的填充墙对框架产生了刚度效应,使得其自振周期为纯框架的0.2~0.7倍,导致在地震作用下的响应增大,但填充墙对框架的约束效应限制了框架柱的变形,增大了结构的抗侧承载力;罕遇地震下填充墙与框架存在复杂的相互作用,开洞填充墙对框架柱产生了约束作用,减小了柱的计算高度,满布填充墙对框架产生斜压杆效应,导致柱端出现附加剪应力容易出现剪切破坏。柔性连接下的填充墙对框架的自振周期影响很小,在进行抗震验算时可不进行自振周期折减,在多遇和罕遇地震波作用下的动力响应以及损伤均与纯框架类似,与抗震规范的设计计算吻合,同时也可避免填充墙的破坏。     

空腔结构砌体复合填充墙钢框架极限承载力分析及抗震计算

系统地研究了新型空腔结构材料钢结构住宅体系中空腔结构砌体复合填充墙与钢框架的屈服准则、破坏机构以及极限承载力计算，同时分析了空腔结构砌体复合填充墙钢框架水平地震力的计算与分配以及相应的变形，最后研究了在水平地震作用下填充墙墙体开裂后对填充墙框架刚度的影响。     

汶川地震中某RC框架结构的震害分析与模拟

2008年5月12日,四川省汶川县发生里氏8.0级地震,造成了巨大的人员伤亡以及工程结构震害。本文基于江油市某RC框架结构的震害调查,分析了该框架结果出现底层"薄弱层"和"强梁弱柱"的破坏机制的主要原因。采用该框架结构附近三个台站的主震加速度记录作为输入开展了非线性地震反应分析。研究表明,填充墙的竖向不均匀布置改变了框架的抗侧刚度分布,造成底层薄弱层的破坏现象。底层柱子的轴压比相对较大,塑性变形能力及耗能能力相对较差,使得底层柱的变形量更容易达到其塑性变形极限而发生破坏。由于现浇楼板对梁刚度和抗弯承载力的增强,框架结构很难出现规范中"强柱弱梁"的破坏机制。结构基本周期对应的加速度反应谱值是决定结构地震反应的主要参数,基本周期加速度反应谱值的增加会导致结构塑性铰的迅速发展,造成结构出现柱铰机构而整体失稳倒塌。建议设计框架结构时,尽量避免填充墙的不均匀布置。适当增加底层柱的截面面积和配筋率,降低轴压比以保证良好的延性。梁端负向抗弯承载力计算时采用T型截面,并考虑一定范围内楼板配筋的影响。     

考虑墙-框连接刚度影响的填充墙框架结构抗震性能分析

历史震害表明,填充墙与框架的连接刚度对框架结构的抗震性能有重要影响。我国《建筑抗震设计规范》(2010)建议"框架结构中的砌体填充墙,宜与柱脱开或采用柔性连接",但对二者的具体连接刚度,规范并没有做出明确规定。运用ABAQUS软件,对前人开展的考虑填充墙与框架连接影响的框架结构拟静力试验进行数值模拟,对比分析填充墙框架结构破坏特征及滞回曲线等抗震性能指标,验证了有限元模型的可靠性。基于某典型框架结构,建立不考虑填充墙、考虑填充墙与框架不同连接刚度的框架结构有限元模型。模态分析表明,连接刚度对框架结构的频率影响较小,结构的动力特性趋于一致;多遇地震和罕遇地震作用下的弹塑性时程分析表明,合适的连接刚度可以提高结构的抗震性能。研究可为框架结构的抗震设计提供参考。     

半刚性连接多层组合框架自振周期实用计算方法

推导了半刚性连接组合梁单元不考虑轴向变形和剪切变形的刚度方程,基于此刚度方程给出了框架柱的抗侧移刚度.采用连续弹性体无限自由度体系剪切自由振动方程,推导了半刚性连接多层组合框架自振周期实用计算公式.通过算例说明了连接的转动刚度以及正负弯矩作用下连接转动刚度的不同对自振周期的影响.     

底层框架砌体房屋抗震性能分析

底层框架多层砌体房屋为上刚下柔的结构体系，因此这类房屋对抗震性能提出更高的要求，本文从结构体系的强度、刚度和延性3方面分析了增强其抗震能力的方法。     

新型柔性连接开洞填充墙RC框架结构平面外抗震性能

砌体填充墙钢筋混凝土(reinforced concrete, RC)框架结构在强地震作用下容易损伤破坏,我国规范建议填充墙与框架之间采用彼此脱开或柔性连接做法,但这也增加了填充墙平面外倒塌的风险。基于此对一种新型柔性连接开洞砌体填充墙RC框架结构进行了平面外的拟静力试验研究,分析了其失效过程、受力特征和破坏模式。结果表明：砌体填充墙RC框架结构平面外承载能力主要依靠于拱承载机制,槽钢轨道可以有效提高框架对填充墙两侧的约束作用,防止填充墙与框架之间的相对滑动,有利于水平拱承载机制的形成。对比普通柔性连接开洞砌体填充墙RC框架结构,采用新型柔性连接的开洞砌体填充墙RC框架结构,平面外的峰值承载力和峰值承载力处割线刚度分别提高了44.14%和9.70%;新型柔性连接开洞砌体填充墙RC框架结构在峰值承载力状态下和极限承载力状态下,其罕遇地震作用加速度相比于普通柔性连接开洞砌体填充墙RC框架结构分别提高了81.03%和77.36%。因此,采用新型柔性连接构造可有效提高开洞砌体填充墙RC框架结构的承载能力,改善开洞砌体填充墙RC框架结构平面外的稳定性,从而提高开洞砌体填充墙RC框架结构平面外的抗...     

楼层侧向刚度比对砌体结构地震易损性的影响分析

砌体结构的震害现象表明楼层侧向刚度不均匀分布是造成其破坏的重要原因之一。本文开展楼层侧向刚度变化对结构易损性的影响分析。以3层和6层砌体结构为例,采用等效多自由度层间剪切模型,基于非线性动力时程分析,定量研究了竖向刚度不规则性对砌体结构易损性的影响。以结构最大层间位移角为地震反应参数,借助增量动力分析及回归拟合方法,建立了基于峰值加速度的结构易损性曲线。通过改变楼层的侧向刚度值来模拟薄弱层,研究了楼层刚度变化对结构不同破坏状态超越概率的影响。通过改变底层与二层的侧向刚度比,分析了底部刚度突变对结构不同破坏状态超越概率分布的影响。研究表明:与规则结构相比,当刚度突变位于结构底层时,在地震作用下结构易损性相对较高;随着底层与二层的侧向刚度比从0.5增大至1.2,结构易损性逐渐降低。当刚度比为1.5时,结构薄弱层由底层转移至二层,结构整体易损性增加;当底层与二层侧向刚度比小于1时,结构倒塌易损性要显著高于规则结构。     

汶川地震后绵竹、都江堰市房屋震害调查与分析

依据笔者在四川省绵竹市、都江堰市参加建设部组织的汶川地震震后房屋应急评估所取得的资料,对该次地震造成的建筑结构破坏进行了分析,从砖砌体结构、混凝土框架结构、构造问题以及设计与施工缺陷4个方面,论述了各种破坏的形态与成因,讨论了现行设计方法中存在的问题,提出了相应的改进建议。主要结论有：砌体结构的底层墙体强度不足、开间过大、形体复杂是导致其破坏的重要原因,在设计中,应适当提高砌体结构底层墙体的强度,控制房屋的开间,加强形体变化部位;砌体结构的窗下墙应作为连接墙肢的连梁考虑,可以将其设计成抗震设防的第一道防线;框架结构设计中,应考虑框架与填充墙的相互作用,考虑楼梯斜梁或斜板参与结构的整体受力;在现行规范要求的基础上,要适当增加框架柱的截面,节点附近的箍筋应采用焊接封闭箍或螺旋箍;应加强非结构构件的连接与锚固;对乡村房屋建设应予以监管,杜绝结构体系不明确的房屋出现。     

芦山地震底部框架砌体房屋震害分析

根据芦山地震现场考察结果,论述了底部框架砌体房屋的震害特征,并为提高底部框架砌体房屋防震减灾能力提出6点建议:(1)控制底框上下层侧向刚度比和实现"多道抗震防线"的思想是保证底部框架砌体房屋抗震能力的关键;(2)应该采取适当的抗震措施,提高过渡层的抗震能力;(3)上部各层砌体要设置圈梁和构造柱,确保整个底部框架砌体房屋的整体性;(4)进一步加强楼梯间的设计与构造措施的研究;(5)出屋面小屋要加强与主体结构的可靠连接;(6)对挡板、吊顶等附属构件要避免在地震中坠落伤人。     

Study on the effect of the infill walls on the seismic performance of a reinforced concrete frame

Motivated by the seismic damage observed to reinforced concrete (RC) frame structures during the Wenchuan earthquake, the effect of infill walls on the seismic performance of a RC frame is studied in this paper. Infill walls, especially those made of masonry, offer some amount of stiffness and strength. Therefore, the effect of infill walls should be considered during the design of RC frames. In this study, an analysis of the recorded ground motion in the Wenchuan earthquake is performed. Then, a numerical model is developed to simulate the infill walls. Finally, nonlinear dynamic analysis is carried out on a RC frame with and without infill walls, respectively, by using CANNY software. Through a comparative analysis, the following conclusions can be drawn. The failure mode of the frame with infill walls is in accordance with the seismic damage failure pattern, which is strong beam and weak column mode. This indicates that the infill walls change the failure pattern of the frame, and it is necessary to consider them in the seismic design of the RC frame. The numerical model presented in this paper can effectively simulate the effect of infill walls on the RC frame.     

蒸压加气混凝土砌块砌体填充墙框架结构抗震性能试验

为进一步改善框架结构平面内和平面外抗震性能,本文提出带X形斜撑的新型砌体填充墙构造方案,并进行了4榀蒸压加气混凝土砌块砌体填充墙框架结构试验,以研究墙体构造措施和墙-框连接方式对框架结构抗震性能的影响。首先进行平面内水平低周往复荷载试验,随后进行历经平面内损伤的平面外单调静力加载试验,最后进行承载力、刚度退化和耗能能力等抗震性能指标的分析。结果表明:墙-框柔性连接方案下,填充墙框架结构的平面内及平面外水平承载力和初始刚度均小于刚性连接方案,而变形能力、耗能能力和位移延性等性能指标均比刚性连接表现更好;墙-框柔性连接且填充墙带X形斜撑框架结构的平面内及平面外抗震性能指标均有明显改善,更有利于抗震。     

Seismic safety assessment of existing masonry infill structures in Nepal

Reinforced concrete (RC) buildings in Nepal are constructed with RC frames and masonry infill panels. These structures exhibit a highly non-linear inelastic behavior resulting from the interaction between the panels and frames. This paper presents an extensive case study of existing RC buildings in Nepal. Non-linear analyses were performed on structural models of the buildings considered as a bare frame and with masonry infill, in order to evaluate the influence of infill walls on the failure mechanisms. Five three-storey buildings with different structural configurations and detailing were selected. The effect of masonry infill panels on structural response was delineated by comparing the bare-framed response with the infill response. Seismic performance is evaluated with regard to global strength, stiffness, energy dissipation, inter-storey drift, and total deflection of the structure. A parametric analysis of structures with masonry infill is also performed. For this, the influence of different material properties is studied, namely diagonal compressive stress, modulus of elasticity and tensile stress of masonry infill panels. Study results show that masonry infill increases the global strength and stiffness of the structures; it decreases the inter-storey drift and hence the total displacement of the structure. The results quantify the influence of the infill panels on structural response and, in particular, the effect of the diagonal compressive strength of the masonry wall.     

R/C frame–infill interaction model and its application to Indonesian buildings

This paper proposes a new analytical model for masonry‐infilled R/C frames to evaluate the seismic performance considering R/C frame–infill interactions. The proposed analytical model replaces masonry infill with a diagonal compression strut, which represents distributed compression transferred between frame and infill interfaces. The equivalent strut width is presented as a function of the frame–infill contact length, which can be evaluated by static equilibriums related to compression balance and lateral displacement compatibility at the frame–infill interfaces. The proposed analytical model was verified through comparisons with experimental results obtained for several brick masonry‐infilled R/C frames representing a typical R/C building with nonstructural masonry infill in Indonesia. As a result, good agreements were observed between the experimental and analytical values of the lateral strength and ductility of the infilled frames. The seismic performances of two earthquake‐damaged R/C buildings with different damage conditions were evaluated considering infill effects by applying the proposed analytical model. Consequently, the nonstructural brick masonry infill significantly affected the seismic resistances of the buildings, which seemed to lead to differing levels of damage for each building. These results indicate that the proposed analytical model can be an effective tool for more precisely screening earthquake‐vulnerable existing R/C buildings in Indonesia. Copyright © 2016 The Authors. Earthquake Engineering & Structural Dynamics Published by John Wiley & Sons Ltd.     

Effects of vertical irregularity and thickness of unreinforced masonry infill on the robustness of RC framed buildings

Presence of irregularities in reinforced concrete (RC) buildings increases seismic vulnerability. During severe seismic shaking, such buildings may suffer disproportionate damage or even collapse that can be minimized by increasing robustness. Robustness is a desirable property of structural systems that can mitigate susceptible buildings to disproportionate collapse. In this paper, the effects of vertical irregularity and thickness of unreinforced masonry infill on the robustness of a six‐story three‐bay RC frame are quantified. Nonlinear static analysis of the frame is performed, and parametric study is undertaken by considering two parameters: absence of masonry infill at different floors (i.e., vertical irregularities) and infill thickness. Robustness has been quantified in terms of stiffness, base shear, ductility, and energy dissipation capacity of the frame. It was observed that the infill thickness and vertical irregularity have significant influence on the response of RC frame. The response surface method is used to develop a predictive equation for robustness as a function of the two parameters. The predictive equation is validated further using 12 randomly selected computer simulations. Copyright © 2013 John Wiley & Sons, Ltd.     

Low‐seismic damage strategies for infilled RC frames: shake‐table tests

Unreinforced masonry (URM) infill panels are widely used as partitions in RC frames and typically considered as non‐structural elements in the design process. However, observations from recent major earthquakes have shown that under seismic excitation, the structural interaction between columns and infill walls can significantly alter the structural behaviour, thus causing catastrophic consequences. The purpose of this research was to propose and test an innovative low seismic damage detailing method, which isolates the infill panel from bounding columns with finite width vertical gaps during the infill panel construction phase and deploys steel wire connections in mortar layers anchored to columns. Taking into account the similitude requirements, a total of six one‐third scale, single‐storey single‐bay RC frames with different infill configurations and flexible connection details were carefully designed and tested on a shake‐table. Three real earthquake records were selected and scaled to ascending intensity levels and used as input signals. A series of thorough investigations including dynamic characteristics, hysteretic behaviour, failure mechanisms, out‐of‐plane vulnerabilities and the effect of different gap filling materials and load transfer mechanisms were rigorously studied. The experimental results indicate that the undesirable interaction between infill panels and bounding frame is significantly reduced using the proposed low seismic damage detailing concept. Direct shear failure of columns at an early stage is prevented, and structural redundancy at high levels of excitation can be provided. In general, the structural stability and integrity, and displacement ductility of infilled RC frames can remarkably be improved. Copyright © 2017 John Wiley & Sons, Ltd.     

填充墙RC框架结构加固方法的研究现状及展望

综述了用于提高填充墙钢筋混凝土(RC)框架结构抗震性能和改善结构损伤模式的几类加固措施,从工艺、加固效果和破坏形式3个角度进行了分析.在建筑结构设计过程中,填充墙通常被视为一种典型的脆性非均质非结构构件,忽视了填充墙与RC框架之间的相互作用.地震调查报告表明,在结构遭受地震作用时,填充墙通常先于钢筋混凝土框架发生破坏,...     

多层砖房底部两层框架抗震变形性能分析

为实现多层砖房底部两层框架结构的加固,需要研究其抗震变形性能。以某底部两层框架、上部四层砖房建筑为对象,通过STRAND7有限元软件构建有限元计算模型,考虑水平荷载与垂直荷载,深入分析多层砖房底部两层框架抗震变形性能。仿真结果表明,建筑结构振型受结构横向楼板刚度的影响较显著,不同振型的频率变化中,X向1阶频率与Y向2阶频率变化最快,楼板平面内弯曲频率变化最慢;整体结构在X向与Y向分别呈现线性剪切变形和弯剪变形,Y向上由于填充墙发挥抗震墙功能,底部两层框架变形较小;在7度多遇地震影响下,底部两层结构中第二层楼板变形较第一层严重,多层砖房底部两层框架建筑结构处于弹性工作状态。     

Simplified macro‐model for infill masonry walls considering the out‐of‐plane behaviour

One of the main challenges in earthquake risk mitigation is the assessment of existing buildings not designed according to modern codes and the development of effective techniques to strengthen these structures. Particular attention should be given to RC frame structures with masonry infill panels, as demonstrated by their poor performance in recent earthquakes in Europe. Understanding the seismic behaviour of masonry‐infilled RC frames presents one of the most difficult problems in structural engineering. Analytical tools to evaluate infill–frame interaction and the failure mechanisms need to be further studied. This research intends to develop a simplified macro‐model that takes into account the out‐of‐plane behaviour of the infill panels and the corresponding in‐plane and out‐of‐plane interaction when subjected to seismic loadings. Finally, a vulnerability assessment of an RC building will be performed in order to evaluate the influence of the out‐of‐plane consideration in the building response. Copyright © 2015 John Wiley & Sons, Ltd.     

Analysis of the in‐plane response of earthen masonry infill panels partitioned by sliding joints

The vulnerability of infilled frames represents a critical issue in many regions with high seismicity around the world where infills are typically made of heavy masonry as they are used for thermal control of the buildings because of their thermal inertia. In this context, the use of earthen masonry infills can give a superior performance because of their ability to regulate thermal‐hygrometric performance of the building and sustainability of its life‐cycle. This paper presents a numerical study on the seismic behaviour of infill walls made of earthen masonry and partitioned with horizontal wooden planks that allow the relative sliding of the partitions. The combination of the deformability of earthen masonry and the sliding mechanism occurring along the wooden planks gives a high ductility capacity to the in‐plane response of the infill and, at the same time, significantly reduces its stiffness and strength, as compared with traditional solid infills made of fired clay units. As a result, the detrimental interaction with the frame and the damage in the infill when subjected to in‐plane loading can be minimized. The numerical model is validated with results from an experimental study and is used to perform a parametric analysis to examine the influence of variations in the geometry and mechanical properties of the infill walls, as well as the configuration of the sliding joints. Based on the findings of this study, design guidelines for practical applications are provided, together with simple formulation for evaluating their performance. Copyright © 2016 John Wiley & Sons, Ltd.