共查询到19条相似文献,搜索用时 187 毫秒
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本文系统地总结了近几十年来结构地震易损性分析及地震破坏损失预测的发展 ,指出了建筑物地震易损性分析存在的一些重要问题 ,如缺乏震害经验的建筑物地震易损性估计、采用地震动参数进行建筑物地震易损性估计等问题。本文重点研究了理论计算的易损性估计方法 ,给出了对于不同地震动建筑物出现或超越不同状态的概率 ,将多层砖房的理论易损性估计结果同实际震害资料进行了对比 ,并对经正规设计但缺乏震害经验的高层建筑地震易损性进行了估计。另外 ,本文也着重研究了以地震动峰值加速度及反应谱作为地震动输入参数时的结构地震易损性分析方法… 相似文献
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近年来广西地震发生频率明显提高,陆续发生了3次5级以上中强地震,包括2016年苍梧5.4级地震、2019年北流5.2级地震和2019年靖西5.2级地震,这可能意味着广西地区进入了地震活跃期。2019年靖西5.2级地震造成较重的房屋建筑物破坏,是分析广西房屋震害很好的样本。本文对各烈度区内不同结构类型房屋的震害现象进行了整理和统计,分析了不同结构类型房屋的震害特征与震害原因。结果显示:简易房屋除年久失修的之外基本完好;砌体结构房屋因结构不规则,缺乏抗震构造措施等,破坏较重,且破坏形式多样;框架结构房屋主体完好但填充墙会出现破坏。 相似文献
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台湾海峡7.3级地震建筑物震害分析与损失评估 总被引:1,自引:1,他引:1
对台湾海峡7.3级地震广东境内建筑物的地震破坏进行了调查,对地震损失进行了总体评估,并根据当地的工程地质情况,建筑物的结构,用材和施工特点等,分析了各种地震破坏形态和破坏规律,为今后的建筑抗震设防提出了有闪斩建议。 相似文献
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1976年唐山7.8级地震对山东省北部的惠民及德州地区建筑物造成破坏和人员伤亡,震后山东省组成现场联合考察队进行了震害调查。对当年的现场考察资料做了系统整理分析,使用惠民及德州地区建筑物破坏和人员伤亡现场考察资料,补充相邻的河北省有关县(市)建筑物破坏资料,客观分析1976年唐山地震对鲁北造成的灾害情况,把该区地震烈度由原来的Ⅳ、Ⅴ度校订为Ⅵ度,Ⅵ度等震线大体沿肃宁—深县—德州—商河—黄河入海口一带分布,较原来Ⅵ度等震线(沿肃宁—沧州市—黄骅—渤海分布)向南移动约100 km,并对烈度及等震线修订的合理性进行了讨论。 相似文献
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雷州半岛地裂与地震活动关系初探 总被引:2,自引:1,他引:2
本文叙述了该区17年来出现的地裂现象和特征及地震活动情况。从地裂发生与地震活动的时间序列、空间分布以及地裂与地震孕育的地质构造背景等方面对地裂与地震活动的关系进行了统计、分析。结果认为,雷州半岛地裂与地震活动无关,不属构造成因地裂,而是干旱、暴风雨、滑坡等营力引起的。但雷州半岛大面积分布玄武岩风化壳,其土力学性质可以形成相当规模的干裂而破坏和影响建筑物,因此,在工程建设时应予注意。 相似文献
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汶川8.0级特大地震汉源县震害特点与烈度异常成因探讨 总被引:1,自引:0,他引:1
本文在汉源县地震灾害调查的基础上,通过收集前人在该区已取得的成果资料,采用综合分析、类比等方法,对汉源县地震烈度异常区震害及造成异常的原因进行了分析探讨。汉源县建筑物破坏形式以水平地震作用造成的“X”型剪切破坏为主,竖向地震造成的破坏较少。地震波传播路径、场地土层条件和地形地貌条件三者的耦合是造成汉源县烈度异常的主要原因,其中场地土层中占优势厚度的砾石层是造成场地地震波放大的主要内因。本文取得的初步结论为更加深入地科学研究本区地震烈度异常的原因提供了新思路。 相似文献
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2017年5月11日新疆塔什库尔干5.5级地震给震区建筑结构造成了不同程度破坏。选择震区钢筋混凝土(RC)框架结构、砖混结构以及土石木结构等3类典型建筑结构,介绍了各类建筑结构地震破坏特点,分析了震害特征与破坏机理。结果表明:RC框架结构在地震中表现出了优异的抗震性能,即使在震中区,破坏也仅仅表现为非结构性破坏,如填充墙开裂和吊顶脱落等;砖混结构绝大多数抗震性能优良,仅震中区的少数建筑物发生了承重墙墙体开裂情况;土石木结构房屋抗震性能最差,地震破坏最为严重,是导致该次地震人员伤亡主要原因。建议地震高烈度设防区房屋建筑应采用抗震性能较好的RC框架结构和砖混结构,而抗震性能差的土石木建筑房屋应尽量避免继续建设和使用。结果可供类似地区房屋建设和建筑结构抗震设计等工作参考。 相似文献
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以2020年1月19日伽师M S6.4地震现场烈度调查结果为基础,综合余震分布、发震构造及仪器烈度值等研究成果,确定了本次地震的烈度分布。此次地震极震区烈度为Ⅷ度(8度),Ⅵ度(6度)区及以上总面积为7599 km 2。分析各个烈度区内不同结构房屋的震害,结果表明,震害较重房屋主要是由于这些房屋年久失修,施工质量不高,缺乏必要的抗震措施等自身原因造成的,其中没有抗震措施的砖木结构房屋是震害主体。随着新疆地区农村房屋的抗震性能提高,在以后的地震烈度调查中,需要现场调查人员依据不同结构房屋的破坏等级及平均震害指数等参数综合判定调查点的烈度值,在没有明显震害的低烈度区,仪器烈度值将会成为烈度图绘制的重要依据。 相似文献
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A PRELIMINARY STUDY ON THE METHOD OF SEISMIC INTENSITY ASSESSMENT BASED ON RESIDENTIAL BUILDING DATA AND HIGH RESOLUTION REMOTE SENSING IMAGES 下载免费PDF全文
After destructive earthquakes, the assessment result of seismic intensity is an important decision-making basis for emergency rescue, recovery and reconstruction. This job requires higher timeliness by government and society. Because remote sensing technology is not affected by the terrible traffic conditions on the ground after the earthquake, large-scale seismic damage information in the earthquake area can be collected in a short time by the remote sensing image. The remote sensing technique plays a more and more important role in rapid acquisition of seismic damage information, emergency rescue decision-making, seismic intensity assessment and other work. On the basis of previous studies, this paper proposes a new method to assess seismic intensity by using remote sensing image, i.e. to interpret the building collapse rate of a residential quarter after an earthquake by high-resolution remote sensing images. If there already are detailed building data and building structure vulnerability matrix data of a residential area, we can calculate the building collapse rate under any intensity values in this residential area by using the theory of earthquake damage prediction. Assuming that the building collapse rate interpreted by remote sensing is equal to the building collapse rate predicted by using the existing data, it will be easy to calculate the actual seismic intensity of the residential area in this earthquake event. Based on this idea, according to the relevant standard specifications issued by China Earthquake Administration, this paper puts forward some functional models, such as the calculation model of building collapse rate based on remote sensing, the data matrix model of residential building structure, the prediction function matrix model of residential building collapse rate and the prediction model of residential building collapse rate. A formula for calculating seismic intensity by using remote sensing interpretation of collapse rate is also proposed. To test and verify the proposed method, this paper takes two neighboring blocks of Jiegu Town after the Yushu M7.1 earthquake in Qinghai Province as an example. The building structure matrix of the study block was constructed by using pre-earthquake 0.6m resolution satellite remote sensing image(QuickBird, acquired on November 6, 2004), post-earthquake 0.2m aerial remote sensing image(acquired by National Bureau of Surveying and Mapping, April 15, 2010) and some field investigation data. The building collapse rate in the two blocks was calculated by using the interpretation results of seismic damage from the Remote Sensing Technology Coordinating Group of China Seismological Bureau. The seismic damage matrix of building structures in Yushu area is constructed by using the abundant scientific data of the scientific investigation team of the project “Comprehensive Scientific Investigation of the Yushu M7.1 Earthquake in Qinghai Province” of China Seismological Bureau. On this basis, the collapse rate prediction function of different structures in Yushu area is constructed. According to the prediction function of collapse rate and the building structure matrix of the two blocks, the building collapse rate under different intensity values is predicted, and the curve of intensity-collapse rate function is drawn. By comparing the building collapse rate interpreted by remote sensing and the intensity-collapse rate function curve of this two blocks, the seismic intensity of both blocks are calculated to be the same value: Ⅸ degree, which is consistent with the results of the field scientific investigation of the earthquake. The validation shows that the method proposed in this paper can effectively avoid the influence caused by the difference of seismic performance of buildings and accurately evaluate seismic intensity when using remote sensing technique. The method has certain application value for earthquake emergency work. 相似文献
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Mario Rodriguez 《地震工程与结构动力学》1994,23(6):627-643
Even though a number of parameters have been proposed in the literature for measuring the capacity of earthquake ground motions to damage structures, most of them are not consistent with building damage observed during earthquakes. In this study, a parameter for measuring seismic damage capacity is proposed. It uses the energy dissipated by a structure in inelastic deformations and a structural overall drift, and it is evaluated for three typical ground motions recorded in severe earthquakes. By using this parameter, consistent results with building damage observed in these earthquakes are obtained, which indicate the importance of displacement control for minimizing seismic damage. 相似文献
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地震对建筑结构的损伤轻则影响建筑完整性,重则导致建筑崩塌。近几年,地震损伤评估问题得到地震工程研究领域的高度重视,但对点支式玻璃建筑结构的损伤评估研究较少。为此,构建一种点支式玻璃建筑结构地震损伤评估模型。采用基于HHT变换的结构损伤部位识别方法判断地震中点支式玻璃建筑损伤部位,建立点支式玻璃建筑结构地震损伤评估多元联系数模型,评估点支式玻璃建筑损伤部位的损伤情况。结果表明,该评估模型对某地区点支式玻璃建筑结构地震损伤评估情况与实际结果一致,且该模型可控性较强,评估范围全面,评估效率明显优于其他评估模型,应用价值较高。 相似文献
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现阶段针对建筑复合节能墙体的抗震性能评估主要根据强震发生后墙体损毁程度实现,评估结果精确度低,因此构建强震环境下建筑复合节能墙体抗震性能评估模型,根据复合节能墙体构件的强度和刚度退化系数,描述强震环境下建筑复合节能墙体损伤情况;在此基础上,采用动态增量分析法(IDA)在不同强度地震动输入条件下,根据建筑复合节能墙体结构响应参数和地震动强度参数构建2种参数的关系曲线——IDA曲线,利用R-O单一函数曲线规则化IDA曲线,获取IDA概率分位曲线,并将50%概率分位曲线斜率用于描述墙体结构损伤的变化,该曲线斜率则为墙体结构损伤指数,依据该指数准确评估强震环境下建筑复合节能墙体抗震性能。实验结果表明,所构建模型可准确分析不同峰值地面加速度时建筑复合节能墙体结构的位移变化,且模型随地震等级不断提升,评估建筑复合节能墙体抗震性结果精度逐渐提高,是一种适合强震环境的建筑复合节能墙体抗震评估模型。 相似文献