砌体结构窗下墙地震破坏研究

利用数值模拟试验方法建立3组砌体墙模型,设计不同窗下墙跨高比、不同墙体开洞率以及不同墙体高宽比的一系列算例。分析这些因素对砌体结构窗下墙地震破坏影响程度,并提出控制条件,使窗下墙先于窗间墙破坏,实现结构抗震多道设防的抗震设防目标。     

基于增量动力分析方法的砌体结构地震易损性分析

砌体结构是一种脆性结构,变形能力和承载力均较低,因取材方便、施工简单和造价低等优势在中国被广泛应用。为了评估砌体结构的抗震性能,本文基于增量动力分析（Incremental Dynamic Analysis,IDA）方法研究了多层砌体结构的地震易损性,分析了影响砌体结构地震易损性的主要因素以及群体多层砌体结构地震易损性。研究结果表明:在相同场地条件情况下,砌体结构的房屋层数、砌筑砂浆强度、设防烈度和墙体面积率对结构的地震易损性影响较明显;当结构层高在2.8~3.3 m之间时,层高对结构地震易损性的影响不大。抗震设防砌体结构抗震能力比不设防结构有明显提高,说明构造柱和圈梁等构造措施能显著提高砌体结构的抗倒塌能力,这与目前的基本认识相同,也证明了增量动力分析方法的有效性。     

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。     

汶川地震区砖砌体住宅房屋易损性研究

砖砌体住宅房屋占城乡建筑的80%以上,它的易损性分析是进行地震灾害损失预测的重要组成部分。文中介绍了砖砌体住宅房屋易损性的分析方法及存在的问题,充分利用汶川地震区砖砌体住宅房屋的震害调查数据,考虑到建筑物数据的离散性,分别给出了城区砖砌体住宅房屋、农村砖砌体住宅房屋两类建筑物群体的破坏状态易损性曲线包络(最大、平均、最小值),从而给出了其破坏概率矩阵,并给出了每个破坏概率的偏差值。     

基于BP神经网络模型的村镇砖砌体结构震害预测研究

砖砌体结构是村镇地区一种量大面广的结构形式,其抗震性能薄弱,在地震中极易出现脆性破坏。本文尝试应用基于L-M算法的BP神经网络方法,利用它强大的非线性映射功能,建立起村镇地区砖砌体结构震害影响因素与破坏状态等级之间关系。设计出一个9-6-5的三层神经网络模型,根据实地调查,筛选出影响房屋震害的9个主要因素,如层数、层高、砌筑方式、砖墙面积率等作为神经网络的输入参数,输出参数为房屋5种破坏状态。选择2008汶川地震后四川、陕西、甘肃等地的震害实例作为学习样本对所构建的神经网络模型进行训练。训练结果表明,该模型对已训练数据有很好的适应性,但如果要将其用于单个或群体建筑的易损性分析,并取得较精确的预测结果,还需积累足够多的训练样本,并进行大量的网络试验工作。     

带竖向构造钢筋再生混凝土砖结构振动台试验研究

提出了带竖向构造钢筋再生混凝土砖砌体结构,进行了2个两层再生混凝土砖砌体房屋结构1/2缩尺模型的模拟地震振动台试验研究,2个结构模型的墙体厚度均为120 mm,一层设有门洞和窗洞,二层设有窗洞。2个模型中,1个为带竖向构造钢筋再生混凝土砖砌体房屋,1个为普通无竖向构造钢筋再生混凝土砖砌体房屋。试验中输入El Centro地震动,测试分析了台面加速度反应、一层和二层顶板加速度反应、结构层间位移反应以及各阶段结构损伤与破坏特征等。研究表明:带竖向构造钢筋再生混凝土砖砌体房屋比普通再生混凝土砖砌体房屋的破坏程度轻,墙体裂缝位置相对错动小,抗震性能显著提高;带竖向构造钢筋再生混凝土砖砌体房屋可用于地震区村镇建筑。     

不同烈度区农村自建砖砌体房屋震害特征研究

农村自建砖砌体房屋通常没有正规的设计和施工导致该类房屋抗震性能较差。文中以汶川8.0级地震为例,在不同烈度区选择具有代表性地区的农村自建砖砌体房屋为研究对象,分析了该类型房屋不同烈度区的震害特征。通过使用数量化术语的震害描述,对在不同烈度区的农村自建砖砌体房屋的墙体、楼板屋盖、附属结构的破坏进行了震害分析,得到了地震作用下仅考虑结构振动破坏时该类型房屋的破坏特征。最后也给出了降低农村自建砖砌体房屋震害的一些建议。     

底层窗间墙破坏模式砌体抗震性能试验研究

为研究整体开洞墙体中发生底层窗间墙破坏模式时墙体的抗震性能,对一砌体结构缩尺开洞墙体模型展开多点同步加载拟静力试验。分析了各层墙体与整片墙的破坏特征、承载与变形能力、滞回耗能特性、刚度退化规律及延性表现,重点研究了底层窗间墙位于整体结构中时其破坏过程与变形规律。试验结果表明:破坏模式相同的开洞墙体较单独墙肢抗震性能有所不同,各工况加载峰值点的上升与下降过程更为缓慢、滞回曲线更为饱满、刚度退化过程更为缓和以及延性特征更为明显。基于底层窗间墙破坏模式,依据现行规范中开洞墙体承载力计算方法所得结果与试验结果吻合,但强弱构件失效机制无从体现。试验结果可为探求砌体结构合理设计方法与实现开洞墙体延性破坏模式提供依据。     

砖砌体房屋非线性地震反应分析方法和破坏状态指标的确定与验证

砖砌体房屋在历次地震中的破坏均较为严重,为了准确评估其在大震作用下的抗震性能,选择高效的结构分析方法并选取合适的破坏状态指标至关重要。首先,在仔细比较现有结构非线性分析方法的基础上,结合砖砌体结构的特点,采用了可以"考虑构造柱影响"的砖墙体三线型恢复力模型,并建立了砖砌体结构的层剪切非线性分析模型,利用基于自平衡力的弹塑性动力反应分析方法实现了砖砌体结构的非线性动力时程分析;然后,选取延伸系数作为砖砌体结构的破坏状态指标,来判别结构的破坏状态;最后,利用一个带有震害的实际算例,采用三条能充分反映该工程场地特征的地震动对其进行非线性动力时程分析,验证了文中砖墙体恢复力模型、非线性动力时程分析方法以及破坏状态指标的合理性和有效性。文中所确定的模型、方法和破坏状态指标可为大震作用下砖砌体房屋的抗震性能鉴定和评估、抗震加固以及震害分析提供方法和依据。     

无筋砌体农居地震弹塑性有限元研究

利用ABAQUS软件对既有的砌体墙试验结果进行了数值模拟,验证了模型的正确性以及混凝土损伤塑性模型对模拟砌体结构受力性能的可用性。在此基础上,借助实地调查获得的结构参数和材料性能数据,以重庆典型农居建筑为例,建立了无筋砌体农居的三维有限元模型,对数值模型进行了动力特性分析和不同烈度下多遇及罕遇地震的动力弹塑性时程分析,并建议了无筋砌体结构农居在不同地震烈度破坏下墙体表面积受拉损伤率的临界值。最后,利用既有文献提出的层间位移角限值,分析了该农居的破坏程度,比较了墙体表面积受拉损伤率和层间位移角限值衡量砌体结构的破坏程度。分析结果表明:提出的墙体表面积受拉损伤率和层间位移角限值衡量砌体结构破坏程度吻合良好;当墙体表面积受拉损伤率小于1%时,结构轻微破坏;当位于1%~5%时,发生中等程度破坏;当位于5%~30%时,发生严重破坏;当大于30%时,结构倒塌。     

In‐plane and out‐of‐plane behavior of confined masonry walls for various toothing and openings details and prediction of their strength and stiffness

Eight half‐scale brick masonry walls were tested to study two important aspects of confined masonry (CM) walls related to its seismic behavior under in‐plane and out‐of‐plane loads. Four solid wall specimens tested to investigate the role of type of interface between the masonry and tie‐columns, such as toothing varying from none to every course. The other four specimens with openings were tested to study the effectiveness of various strengthening options around opening to mitigate their negative influence. In the set of four walls, one wall was infilled frame while the other three were CM walls of different configurations. The experimental results were further used to determine the accuracy of various existing models in predicting the in‐plane response quantities of CM walls. Confined masonry walls maintained structural integrity even when severely damaged and performed much better than infill frames. No significant effect of toothing details was noticed although toothing at every brick course was preferred for better post‐peak response. For perforated walls, provision of vertical elements along with continuous horizontal bands around openings was more effective in improving the overall response. Several empirical and semi‐empirical equations are available to estimate the lateral strength and stiffness of CM walls, but those including the contribution of longitudinal reinforcement in tie‐columns provided better predictions. The available equations along with reduction factors proposed for infills could not provide good estimates of strength and stiffness for perforated CM walls. However, recently proposed relations correlating strength/stiffness with the degree of confinement provided reasonable predictions for all wall specimens. Copyright © 2016 John Wiley & Sons, Ltd.     

Seismic capacity of irregular unreinforced masonry walls with openings

Masonry buildings are often characterized by geometric irregularities. In many cases, such buildings meet global regularity requirements provided by seismic codes, but they are composed by irregular walls with openings. The latter are masonry walls characterized by (i) openings of different sizes, (ii) openings misaligned in the horizontal and/or vertical direction, or (iii) a variable number of openings per story. An irregular layout of openings can induce not only a nonuniform distribution of gravity loads among masonry piers but also unfavorable damage localizations resulting in a premature collapse of the wall and hence a higher seismic vulnerability. This paper is aimed at providing a simplified methodology to assess the effects of irregularities on the in‐plane seismic capacity of unreinforced masonry (URM) walls with openings. To this end, a macroelement method was developed and validated through experimental results available in the literature. The proposed methodology was based on the quantification of wall irregularities by means of geometric indices and their effects on seismic capacity of URM walls with openings through both sensitivity and regression analyses. Sensitivity analysis was based on a high number of static pushover analyses and allowed to assess variations in key seismic capacity parameters. Regression analysis let to describe each capacity parameter under varying irregularity index, providing empirical models for seismic assessment of irregular URM walls with openings. The in‐plane seismic capacity was found to be significantly affected by wall irregularities, especially in the case of openings with different heights. Copyright © 2012 John Wiley & Sons, Ltd.     

北京地区农村砖木结构振动台试验研究

为了了解北京地区典型砖木结构(木柱支撑,木屋盖,外砖墙)农村住宅结构的抗震能力,根据北京地区这类农村住宅结构的调研结果,本文介绍了一座典型砖木结构单层三开间农村住宅2/3缩尺振动台试验结构模型的设计与动力试验结果。按照北京地区8度抗震设防的要求,分别完成了模型在设计小震(0.072g)、中震(0.2g)和大震(0.4g)条件下的振动台动力试验,量测了模型的动力响应,记录了不同激励水平下模型的开裂情况。基于试验结果,分析了这种结构的抗震能力以及该类型房屋的抗震薄弱点,为制定这类结构的抗震加固方案提供依据。     

Experimental and analytical investigation of seismic stability of masonry walls at Beauharnois powerhouse

The seismic stability of the facade brick-masonry walls of the machinery building of the Beauharnois powerhouse near Montreal, Quebec, Canada were investigated numerically by use of non-linear models and applying experimental methods on site and on the IZIIS’ seismic shake-table. The dynamic properties of the machinery building were obtained by ambient vibration measurements. Based on these results, a model of a representative part of the building, consisting of steel frames and brick masonry wall, was designed and constructed to the reduced scale at the IZIIS’ Dynamic Testing Laboratory and then tested on the two-component shake-table. The geometry of the original structure was completely scaled to 1/3, consisting of many realistically simulated details such us: brick layers, steel columns, openings, window frames, steel connectors between brick layers, number of layers, brick dimensions, etc. The material used for the model was: original steel for the frame structure and bricks of reduced mechanical properties for the masonry wall, close to the similitude requirements according to the Backingham’s theorem, valuable for adequate artificial—mass simulation model as well as true replica simulation model. More than 50 seismic tests were performed considering the design earthquake Nahanni NWT, H1, with a time scaling factor of 3^1/2, and acceleration scaling factor 1, according to the model design rules. The intensity of the applied input earthquake excitation was from 0.05 to 1.2 g. The design peak acceleration of Nahanni earthquake was 0.2 g. The cracks development was stated at 0.7 g input acceleration. These were concentrated around the openings. No collapse happened even under the strongest earthquake input. The numerical part of this paper deals with formulation/application of the critical plane approach to seismic analysis of masonry structures. Starting with the constituents, i.e. mortar and bricks, the macroscopic strength properties of masonry were established based on numerical homogenization. Generally, based on all the performed experimental tests, considering some simplifications and assumptions in the constructing details, as well as in the design of the model, the global conclusion is that the existing wall is very well incorporated in the steel structure of the powerhouse. The complementary stiffness of the steel frame and the brick masonry wall produces interactive deformation of the system. Only local cracking and relative displacement between the wall and the steel frames could be expected in the case of a strong earthquake.     

冻融作用下带构造柱砖墙抗震性能试验研究

以4榀相同特性的带构造柱砖墙为研究对象,分别进行0、40、80及120次冻融循环试验和低周反复荷载试验,来研究冻融环境对砌体结构抗震性能的影响。试验结果表明:随着冻融循环次数的增加,裂缝出现更早,发展更为迅速,破坏程度更加严重,承载力、刚度、耗能、延性均出现明显的衰减。本文从宏观和微观两个方面对遭受冻融作用砖墙进行了损伤机理的分析。     

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,未经合理设计的填充墙RC框架结构将在地震作用下产生严重不良后果。试验结果和数值模拟分析结果证明,砌块的强度越低、砂浆的强度越高,结构的承载能力和刚度退化越慢、耗能能力越好。文中根据目前已有的建筑材料改性试验结果,从改性机理出发,分析了一系列有利于提高结构抗震性能的新型材料,并对结构的设计方案进行了探讨。     

基于位移的底部框架-抗震墙房屋抗震能力分析

在基于性能/位移抗震设计思想下,通过动力时程分析,研究了底部两层框剪砖房结构在不同地震强度作用下的弹塑性反应和变形特征;针对《规范》中对底部两层框剪砖房结构侧向刚度比的限定条件,研究了不同侧向刚度比条件下结构的抗震能力,得到了相关结论。     

水平嵌筋加固砖砌体墙抗震性能试验研究

以嵌缝胶泥作为嵌缝材料,针对不同高宽比和不同配筋率的6片墙体进行了拟静力试验,探讨了嵌筋加固砖砌体墙的破坏特征、变形能力、承载能力、耗能能力、滞回特征及刚度退化等抗震性能,建立了以试验为基础的嵌筋加固砖砌体墙的抗剪承载力计算公式。研究结果表明:高宽比为1.8的试件,嵌筋墙体较无筋墙体水平抗剪极限承载力提高了17%~31%,延性提高了54%~83%;高宽比为0.5的试件,嵌筋墙体较无筋墙体水平抗剪极限承载力提高了13%~17%,延性提高了17%~20%,嵌筋加固墙体滞回环饱满,耗能能力有较大幅度提高,破坏形式由脆性破坏转变为延性破坏,嵌筋对墙体初始刚度的影响较小,给出的抗剪承载力公式计算值与试验值接近,为工程应用奠定了基础。     

带斜筋单排配筋L形截面剪力墙的非工程方向抗震性能1

带斜筋单排配筋混凝土剪力墙结构是为取代粘土砖多层住宅结构而发展起来的一种新型多层混凝土结构,其经济性合理,抗震性能优于传统的砌体结构.为进一步充分了解其抗震性能,开展该新型结构体系中“L”形截面剪力墙的非工程轴方向抗震性能试验研究.进行1个单排配筋混凝土“L”形截面剪力墙和1个带斜筋的单排配筋混凝土“L”形截面剪力墙低周反复荷载试验,对比分析其破坏特征、滞回特性、耗能能力、承载力、延性、刚度,并利用ABAQUS软件进行非线性有限元分析,探究斜筋对其抗震性能的影响.研究结果表明,在非工程轴方向,带斜筋单排配筋“L”形截面混凝土剪力墙的抗震性能优于不带斜筋的剪力墙.