钢管混凝土框架结构抗震性能试验研究

通过 2榀具有同一外形尺寸及用料的钢管混凝土框架在低周往复荷载下的试验 ,研究了该类型结构的破坏形态、变形特点、荷载一位移滞回模型及结构耗能比 ,分析了钢管混凝土框架结构的受力特点及抗震性能 ,为工程设计提供了试验依据。     

构造柱一圈梁体系外多孔砖内混凝土小型空心砌块六层足尺房屋抗震性能试验研究

本文简述了六层构造柱 -圈梁体系外墙用多孔砖、内墙用混凝土小型空心砌块足尺房屋抗震试验的设计 ,介绍了模型楼的试验结果 ,并对试验结果进行了分析 ,评价了此类房屋的抗震能力。最后 ,本文对此类房屋的工程实践提出一些建议     

钢混凝土组合梁低周反复荷载试验研究

本文基于钢－混凝土组合梁的低周反复荷载试验，对其破坏形态、滞回曲线、抗震延性、耗能能力、刚度退化、变形恢复能力等抗震性能进行了较为深入的研究，研究结果表明：钢－混凝土组合梁具有良好的抗震性能。     

寒冷地区无粘结预应力混凝土梁的抗弯与疲劳强度研究

针对我国行业标准《无粘结预应力混凝土结构技术规程》(以下简称《规程》)中,对无粘结预应力筋的极限应力设计取值规定的不足,根据大量的试验数据,推导出了适用于桥梁工程的无粘结预应力混凝土上部结构多种截面形式的无粘结筋极限应力增量实用简化计算方法。同时根据试验结果得出无粘结预应力混凝土受弯构件在反复荷载作用下的性能是可靠的结论。     

大坝抗震安全性研究进展

论证了广大坝抗震安全性研究的实践与发展现状。目前大坝在地震作用下的应力与变形分析方法主要有拟静力法和动力响应分析法,并依据大坝混凝土的抗拉强度判断大坝的安全性;各国规范体现的抗震设防弹念和大坝材料的容许应力差别很大。坝址河谷不同高程处地震动状态不尽相同、河谷两恻同一高程处地震动也不一样。混凝土材料的强度与加载速度、应变速率有关;地震时大坝不同部位的应变速率不相同、同一部位的应变速率也随时间变化;混凝土的动态强度既与应变速率有关。也与应变历史等其它因素有关。大坝河谷地震动的输入机理和模型研究、混凝土的动态强度的变化规律探索、大坝抗震安全性评价准则的完善与创新等将有待深入。通过以上内容针对性分析,提出了大坝抗震评价的一些合理建议、方法以及进一步的研究方向。     

钢筋混凝土桥梁地震易损性评估模型设计

桥梁作为交通中不可或缺的一部分,对其地震易损性进行研究具有现实意义。针对当前桥梁地震易损性分析方法存在准确性待提升的问题,提出基于模糊评定的钢筋混凝土桥梁地震易损性评估模型。以桥梁结构层次、材料层次及边界层几方面为主对桥梁评估过程中的不确定性参数进行分析。以分析结果为依据,考虑到桥梁损失是一个比较模糊的概念,引入模糊数学中的模糊评定方法对桥梁地震易损性进行评估。融合位移下桥梁支座损伤分析、能量下桥墩损伤分析、周期下桥梁结构整体损伤分析,构建可以反映钢筋混凝土桥梁由局部到整体的多层次模糊易损性评估模型。通过实验对所建模型进行验证,结果显示：在纵向只发生轻微破坏,且轻微破坏的概率较小,基本处于完好状态。而在横向,发生轻微破坏的概率较大,甚至还可能发生中等破坏。在地震作用下,桥梁破坏也基本以轻微破坏和中等破坏为主,严重破坏的概率很小。     

THE N2 METHOD FOR THE SEISMIC DAMAGE ANALYSIS OF RC BUILDINGS

A comprehensive, though relatively simple, non-linear method for the seismic damage analysis of reinforced concrete buildings (the N2 method) has been elaborated. The basic features of the method are: the use of two separate mathematical models, application of the response spectrum approach and of the non-linear static analysis, and the choice of a damage model which includes cumulative damage. The method yields results of reasonable accuracy provided that the structure oscillates predominantly in the first mode. Three variants of a seven-storey building have been used as illustrative examples for the application of the method. Four different types of the analysis, with different degrees of sophistication, have been performed in order to estimate the influence of several assumptions and approximations used in the N2 method.     

EFFECT OF MODELLING ASSUMPTIONS AND INPUT MOTION CHARACTERISTICS ON SEISMIC DESIGN PARAMETERS OF RC BRIDGE PIERS

Modelling assumptions, boundary and loading conditions have a significant effect on analytical assessment of ductility supply and demand measures for RC bridges, a structural form which had suffered extensively in recent earthquakes. In recognition of the important role played by analysis in advancing seismic design of bridges, this paper is concerned with assessing the effect of model characteristics and earthquake strong-motion selection on analytical action and deformation seismic design parameters. This is of particular significance when viewed in the light of the large capital investment and problems with the satisfaction of dynamic similitude encountered in physical testing of piers and pier-deck assemblies. The models studied range between simple fixed-base cantilever and inclusion of both soil and deck effects, represented by assemblies of springs in translational and rotational degrees of freedom. Moreover, two sets of earthquake records are used in dynamic analysis, each comprising six records covering low, intermediate and high a/v, where a and v are the peak ground acceleration and velocity, respectively. The two sets differ in the scaling procedure employed to bring them to a common level of severity; the first set is obtained by direct acceleration scaling whilst the second utilizes the concept of velocity spectral intensity. The results from static and dynamic analysis, using advanced material characterization and solution procedures, are assessed and discussed. Subject to the limitations of the study, outlined in the paper, the results indicate that the inclusion of deck stiffness and/or soil representation is essential to avail of accurate seismic response parameters. However, the effect of variations in soil stiffness and/or deck torsional rigidity applied in the analysis is rather small, compared to the inclusion/exclusion of the model feature. Moreover, it is also observed that using acceleration scaling leads to much larger scatter in the results than when velocity spectral intensity scaling is used. Finally, the results from two particular earthquakes, Friuli and El Centro, highlight the peril of using a small number of records selected without due consideration to the relationship between their wave form, predominant periods and spectral shapes on the one hand and the response periods of the structure on the other.     

SEISMIC PERFORMANCE OF AN INSTRUMENTED TEN-STOREY REINFORCED CONCRETE BUILDING

Results from analytical studies conducted on an instrumented ten-storey reinforced concrete building which experienced ground accelerations in excess of 0⋅6g during the 1987 Whittier-Narrows California earthquake and suffered only minimal damage are presented. Using the dynamic characteristics inferred from accelerations recorded in the building during the earthquake, a mathematical model was calibrated to study the response of the building and to explain its good behaviour despite the apparent severity of the motions recorded in the basement of the building. Very good correlation was obtained between the computed and recorded response of the building. Non-linear analyses were conducted to evaluate the strength and deformation capacity of the building and to estimate its response in the event of more severe earthquake ground motions. Special emphasis is given to the evaluation of the overstrength of the building. Lateral overstrengths larger than 4⋅2 and larger than 5⋅7 were computed for the longitudinal and transverse directions of the building, respectively. It is concluded that these high levels overstrength in the building played an important role in limiting the damage during the Whittier-Narrow earthquake. Since the estimation of inelastic deformations during severe earthquake ground motions depends on the actual strength of the building, it is recommended to consider explicitly probable values of this overstrength in the strength reduction factors.     

发泡剂对氯氧镁水泥材料的适易性研究

本文主要介绍了不同类型水泥发泡剂在氯氧镁水泥(MOC)泡沫混凝土体系中的影响因素。对比不同发泡方式获得MOC泡沫混凝土的结构特征、力学性能、离子溶蚀速率以及微观结构等,研究了发泡方式和不同类发泡剂对MOC泡沫混凝土的适宜性。结果表明,对于MOC胶凝材料物理发泡方式相比化学发泡方式更能获得优良的泡沫混凝土,物理发泡剂中动植物蛋白类发泡剂是获得优良MOC泡沫混凝土的最佳选择。