近断层地震动作用下土质边坡动力响应研究

根据汶川地震中滑坡多沿断层分布的特点,利用FLAC有限差分软件建立了一个土质边坡动力数值分析模型,分别研究了具有向前方向性效应、滑冲效应和无速度脉冲的近断层地震动作用下边坡的动力响应.结果表明:含速度脉冲地震动对边坡的破坏作用远强于无速度脉冲地震动,且具有滑冲效应的地震动引起的边坡动力响应稍大于向前方向性效应地震动.近断层地震作用下,边坡水平方向绝对峰值加速度分布存在沿高程放大效应.具有向前方向性效应的地震动会增强边坡加速度的高程放大效应而具有滑冲效应的地震动则在一定程度上削弱了这种放大效应,且边坡中下部绝对峰值加速度值相对于向前方向性效应地震动和无速度脉冲地震动引起的绝对峰值加速度值较大.     

不同方向地震动作用下水平层状边坡动力响应特性

在斜坡的动力响应分析中,地震动的激振方向是影响斜坡动力响应规律的主要因素之一.本文以“5·12”汶川地震灾区典型斜坡岩性及结构为模拟特征,通过对水平层状岩质斜坡开展振动台模型试验,探究地震动方向对斜坡动力响应规律的影响.以输入峰值加速度0.3g的正弦波和天然波为例,着重对比分析斜坡模型在水平向、竖直向及合成向激振波作用下的加速度动力响应规律.研究结果表明:水平向上,在不同频率的地震动作用下,斜坡的中上部的加速度动力响应较之下部更为显著,X向地震动作用下斜坡的加速度动力响应沿高程呈较强的线性增大特征,而Z向地震动作用下斜坡的动力响应却表现出明显的非线性,且斜坡在合成向天然波作用下的响应规律表现出明显的P-△效应;竖直向上,Z向地震动作用下斜坡坡表和坡内的加速度响应值会随着频率的增加而不断减小,出现逐渐衰减和频散的现象.     

结构系统地震动输入模式与相关问题的几点讨论

针对单自由度结构系统,定性讨论了一致地震动输入模式之间的关系、对体系响应的影响及相关问题.主要结论为:一致地震动输入的位移与加速度之间必须较好地满足运动学关系;宜采用位移输入模式计算长周期体系的地震响应;宜采用加速度输入模式计算短周期体系的地震响应.     

高速铁路车-桥耦合体系地震响应分析

为了研究车桥耦合体系在地震作用下的响应,采用有限元方法,在现有有限元模型基础上,建立了更为精细的高速铁路车-桥耦合模型,计算了车桥体系的动力特性及典型地震动输入下的反应。同时还建立了单桥有限元模型,比较了单桥模型和车桥耦合模型的自振特性和地震响应的差异,得到了桥面加速度反应放大系数。结果表明:在给定的典型地震动作用下,车桥耦合模型地震响应放大系数与单桥模型有较大差异,同时输入地震动频谱特性对桥面地震加速度响应有显著影响。     

高聚物防渗墙土质堤坝地震加速度响应的动力离心试验研究

为研究高聚物防渗墙土质堤坝地震加速度反应规律,采用El Centro波,在0.05 g、0.1 g、0.2 g和0.4 g工况下进行了高聚物防渗墙土质堤坝和传统刚性防渗墙—混凝土防渗墙土质堤坝的离心机振动台的对比试验。试验采用非等应力离心模型,利用加速度传感器测量了坝体不同位置的加速度时程响应。结果表明:高聚物防渗墙土质堤坝峰值加速度随输入地震动增加而增加,随坝高增加而增加,最大峰值加速度在坝顶上;高聚物防渗墙土质堤坝最大峰值加速度随输入地震动的增大呈线性增加趋势,而最大峰值加速度放大系数随输入地震动增大而减小;从模型试验的角度来看,在同等水平地震作用下,混凝土防渗墙土质堤坝抗地震加速度反应能力好于高聚物防渗墙土质堤坝,但在强震下混凝土防渗墙体发生了破坏,这一点可由附近土体加速度突增判断。     

双向地震作用下锯末混合土场地动力特性分析

在北京工业大学振动台台阵系统上开展了一系列锯末混合土地基自由场振动台模型试验,试验中模型箱采用装配式连续体刚性模型箱,试验中输入地震动时程采用El Centro地震动记录、Taft地震动记录和天津地震动记录,地震动输入方向分为水平单向和水平双向。文中,重点考察了双向地震动输入下锯末混合土模型场地的动力特性及其变化规律,主要指标包括模型场地地震动反应的峰值加速度及其动力放大系数、加速度时程及其傅氏谱。试验结果表明:随着输入地震动强度的增大,同一测点反应的峰值加速度总体上在增大,而其加速度动力放大系数总体上呈现减小的趋势,反应的频谱组成从较高频率向较低频率移动;双向地震作用下锯末混合土模型场地的动力变化规律与单向地震作用下较为一致。     

地震动参数对边坡地震响应的影响规律

选取了具有不同峰值加速度、频谱和持时的6组地震动加速度时程作为输入,基于有限元数值模拟方法建立了二维均质边坡有限元模型,模拟分析了不同地震动作用下边坡模型的加速度和位移响应,揭示了地震动峰值加速度、频谱和持时对土坡地震响应的影响作用及其规律.研究结果显示:地震动峰值加速度、频谱和持时对土坡地震响应均有显著的影响,其中,边坡坡脚处和坡肩处的变形位移随地震动峰值加速度、特征周期和持时的增大而增大,坡体临空面各点的峰值加速度放大系数呈现随输入地震动特征周期的增大而增大、随输入地震动峰值加速度的增大而减小的规律.研究结果可为地震作用下边坡稳定性设计及防治研究提供参考.      

地震动强度非平稳特性参数与结构响应之间的近似定量关系分析

本文在对实际地震加速度记录统计分析的基础上,给出了能够合理描述地震动强度非平稳特性的参数及其取值范围;然后引入实验设计方法,建立了适合于地震动强度非平稳特性参数分析的实验设计算法,用来分析地震动强度非平稳特性参数的变化对结构响应的影响;最后通过与近似技术相结合,建立了地震动强度非平稳特性参数与结构响应之间的近似定量关系模型.结果表明,本文提出的实验设计方法适合于对地震动强度非平稳特性参数进行分析,该方法在有效地减小计算量的同时,获得了结构响应与参数变化之间的对应关系.基于实验设计方法进行的特性参数方差分析结果表明:地震动的稳态持时对结构地震响应的影响比较显著;对于周期较小的结构,特性参数之间的交互作用对结构地震响应的影响显著,但当周期大于1 s时,则不显著.本文建立的近似定量关系模型能够较好地反映不同特性参数、不同周期结构动力响应之间的联系,为工程实践中基于结构特性合理设置地震动特性参数、合成或挑选地震加速度时程提供理论依据.      

地震边坡非线性特征及敏感性分析

使用时程分析法研究边坡动力响应的非线性特征,基于强度判据的安全系数给出地震动峰值加速度以及能量持时阀值等参数对非线性特征的影响。研究认为:对于一定的岩土材料,边坡动力响应的位移、速度、加速度呈现出明显的非线性特征,具有较强的关联性,各质点具有统一的波形形式;位移和速度变化相对地震加速度变化有明显的滞后,质点加速度相对地震加速度有明显的同步性;地震动峰值加速度以及能量持时阀值的变化均对边坡安全系数和塑性区的分布有一定的影响。     

地下综合管廊大型振动台模型试验研究

针对地下综合管廊缺乏抗震研究的现状,开展了地下综合管廊大型振动台模型试验研究。试验中除对通常的地下结构振动台试验中常规地震响应进行了测量外,还测量了模型场地水平位移、模型结构的层间位移、模型结构内钢筋应变。同时,通过自行设计的接触面土体滑移传感器测量了结构顶板接触面土体滑移。本文对模型结构的动力响应以及接触面和周围土体地震响应规律进行了分析。结果表明：在地震作用下地下综合管廊的地震加速度响应服从周围土体的地震响应,其响应幅值不会大于周围土体的加速度响应幅值;结构内力最大部位出现在结构的角部,并且内力随着地震动强度的增加而增大;地下综合管廊接触面土压总体上随着地震动强度的增加而增大,侧板和顶、底板的土压力分布模式不同;在水平地震作用下,地下综合管廊会产生顶、底板之间的相对位移,同时伴随着横截面内的刚体转动;地下综合管廊壁板与土接触面的作用力是结构产生内力的直接原因,其中侧壁土压起主要作用。     

Seismic performance of earth-core and concrete-faced rock-fill dams by large-scale shaking table tests

Two of China's highest earth-core rock-fill dams (ECRDs) and concrete-faced rock-fill dams (CFRDs) were simulated by large-scale earthquake simulation shaking table tests in this work. A series of staged tests were performed, including white noise, different types of earthquake excitations with different magnitudes etc. The seismic performance of the ECRD and CFRD models were analyzed and investigated. The test results indicated that reservoir impoundment influenced the structure and seismic characteristics of the ECRD model much more than the CFRD model. The average fundamental frequency of the CFRD decreased less than the ECRD model when subjected to strong excitation. The acceleration amplification factors decreased as the input peak acceleration increased. The maximum acceleration occurred at the top of the ECRD model, while it occurred at 0.6–0.9 dam height of the CFRD model. Seismic residual deformations of the two models were very small. When subjected to strong earthquake excitation, the residual deformation of the CFRD model was smaller than that of the ECRD model. The dominant failure pattern of the two models was shallow sliding at the height of 3/4 on the downstream slope. The above analysis indicated that seismic performance of CFRD was superior to ECRD.     

强震区高面板堆石坝抗震安全性评价

针对西部强震区高面板堆石坝,在三维非线性动力有限元分析基础上分析评价了面板堆石坝的加速度和应力反应、面板的应力及接缝变形、坝体地震残余变形、坝体单元抗震安全性、坝坡的抗震稳定性,对大坝的抗震安全性进行了综合评价。所提出的抗震安全性评价方法以及有关规律和结论可供工程建设参考。     

先期震动对土石坝地震永久变形的影响研究

针对经历了5.12汶川大地震的紫坪铺面板堆石坝工程,进行了坝料的大型动三轴试验,研究了先期振动对坝料残余应变的影响。在此基础上,采用基于3维非线性动力反应的地震永久变形计算方法,进行了紫坪铺面板坝地震永久变形的计算,重点分析了先期震动对坝体地震永久变形的影响。结果表明,如果考虑先期已遭受强震作用影响,大坝的地震残余变形明显减小。     

THE EFFECT OF HARD INTERLAYER THICKNESS ONTHE SITE SEISMIC RESPONSE

Studies on the effect of near-surface overburden soil layers on seismic motion have shown that the overburden soil layers have a significant impact on the seismic effect of the site due to the formation age, genetic type, thickness difference, structure, and dynamic characteristics of the soil layers. In this paper, the one-dimensional seismic response analysis of a nuclear power plant site containing a thick hard interlayer was conducted to discuss the influence of the hard interlayer thickness on the site seismic response, so as to provide a basis for determining the seismic motion parameters for seismic design of similar sites. Based on the engineering geological data of a nuclear power plant site, five models of one-dimensional soil-layer seismic response analysis were built, and the equivalent linear method of the one-dimensional site seismic response was applied to analyze the effect of the interlayer thickness on the peak acceleration and the acceleration response spectra of the site seismic response. The seismic response characteristics of the site and influence rules of the hard interlayer thickness are summarized as follows:1)Under different input seismic motion levels, the peak acceleration at the top of the hard interlayer was less than the input peak acceleration, and the peak acceleration at the ground surface of site was greater than the input peak acceleration. 2)Under the same input seismic motion, the ratios of the peak accelerations at the top of hard interlayer to the input peak accelerations were smaller than the ratios of the peak accelerations at the ground surface to the input peak acceleration, and these ratios first decreased and then increased gradually with the increase of the hard interlayer thickness; while for the same hard interlayer thickness, these ratios gradually decreased as the input peak acceleration increasing. 3)For the same input seismic motion, the ratios of the peak accelerations at the ground surface of site to those at the top of the hard interlayer increased gradually as the hard interlayer thickness increased; however, corresponding to different hard interlayer thicknesses, the variation characteristics of ratios which are the peak accelerations at the ground surface of site to those at the top of the hard interlayer were inconsistent with the increase of the input peak acceleration. 4)The hard interlayer had a significant influence on the short-period acceleration response spectrum and the thicker the hard interlayer was, the wider the influence frequency band would be; while for a special hard interlayer thickness, the influence frequency band is certain, and the hard interlayer had little effect on the acceleration response spectrum coordinates outside this frequency band, the longer the period is, the less the influence of the hard interlayer on the acceleration response spectrum coordinates. The seismic response characteristics of the site and influence rules of the hard interlayer thickness indicate that the hard interlayer thickness has a significant impact on the peak acceleration and the acceleration response spectra of the site seismic response, and the hard interlayer has obvious isolation effect at the seismic motion, and the increase of its thickness reduces the nonlinear effect of the site and leads to the wider influence frequency band. Meanwhile, the higher the input peak acceleration is, the stronger the nonlinear effect of the site, and it's remarkable that the soft layer overlying the hard interlayer has a significant amplification effect on the seismic motion.     

一种深厚覆盖层场地地震动参数的确定方法

基于欧美规范确定了坐落在深厚覆盖层上KH抽水蓄能电站上、下库场地基本运行和最大设计地震动峰值加速度、反应谱和时程等动参数。首先依据场地区域地震烈度区划图、特征周期区划图和依据场地地质地震条件选取的5条种子实测地震动确定场地基岩输入加速度时程、峰值加速度和设计反应谱,进而基于各土层地质参数和一维弹性波传播模拟程序确定覆盖层表面的平均峰值加速度、平均反应谱和5条地震动时程,对所得到的平均反应谱和峰值加速度进行光滑处理后确定可用于各建筑物结构抗震设计的地震动参数,包括覆盖层表面水平向动力响应加速度时程、峰值加速度和设计反应谱。该方法可较好地保留输入地震动的真实动力特性,如持时、相位和频率等,为我国规范中建议的确定场地地震动参数的方法提供有益的补充。     

A study of response spectra for different geological conditions in Gujarat,India

In this study, the effect of ground geology on the acceleration response spectra is studied at 32 sites in Gujarat, India. The sites are grouped into Proterozoic, Mesozoic, Tertiary and Quaternary. The normalized acceleration response spectra at 5% damping of 407 strong ground motions (horizontal and vertical components) recorded at these sites varying in magnitude from 3.0 to 5.7 are determined. The study shows that the shape of the acceleration response spectra is influenced by the regional geology and local site conditions. The peak of maximum horizontal spectral amplification is between 0.03 and 0.05 s in Proterozoic formations, 0.06 and 0.10 s in Mesozoic formations, 0.06 and 0.08 s in Tertiary and 0.12 s in Quaternary formations. The maximum vertical spectral acceleration is at 0.025 s in Proterozoic, 0.07 s in Mesozoic, 0.05 s in Tertiary and 0.10 s in Quaternary formations. The average acceleration amplification factor in all the geological formations is between 2.5 and 3.0 both in horizontal and vertical components. It has been observed that acceleration response spectra at sites having same geological formations are also influenced by local site conditions. The study shows that the acceleration response spectrum in the current Indian code applicable for the entire country underestimates the seismic forces at hard-rock sites and overestimates at soft-soil sites. Using recorded strong motion data with Mw ranging from 3.5 to 5.7, an attenuation relationship is developed at six periods to predict geometric mean of horizontal spectral amplitudes for rock and soil sites. The spectral amplitudes predicted with the attenuation relationship match well with the observed one within statistical limits for hypocentral distances less than 200 km.     

Tunnel flexibility effect on the ground surface acceleration response

Flexibility of underground structures relative to the surrounding medium, referred to as the flexibility ratio, is an important factor that influences their dynamic interaction. This study investigates the flexibility effect of a box-shaped subway tunnel, resting directly on bedrock, on the ground surface acceleration response using a numerical model verified against dynamic centrifuge test results. A comparison of the ground surface acceleration response for tunnel models with different flexibility ratios revealed that the tunnels with different flexibility ratios influence the acceleration response at the ground surface in different ways. Tunnels with lower flexibility ratios have higher acceleration responses at short periods, whereas tunnels with higher flexibility ratios have higher acceleration responses at longer periods. The effect of the flexibility ratio on ground surface acceleration is more prominent in the high range of frequencies. Furthermore, as the flexibility ratio of the tunnel system increases, the acceleration response moves away from the free field response and shifts towards the longer periods. Therefore, the flexibility ratio of the underground tunnels influences the peak ground acceleration (PGA) at the ground surface, and may need to be considered in the seismic zonation of urban areas.     

川滇甘陕地区地震的加速度峰值比和竖向反应谱的统计分析

本文以国内川滇甘陕地区263个有详细场地资料的强震台站获得的802组地震动加速度记录为基础,研究了该地区加速度峰值比的总体分布特征,分别探讨了震中距和震级对加速度峰值比的影响特征,按照水平反应谱的标定方法对竖向反应谱进行标定并对其进行了统计分析。统计分析结果显示:竖向与水平向加速度峰值比的概率分布总体服从极值Ⅱ型分布,加速度峰值比均值为0.6,加速度峰值比≤0.65的累积频率为64%;Ⅱ类场地的加速度峰值比随震中距增大而减小;大震近场的加速度峰值比基本上远高于0.65;最后本文给出了不同场地类别下竖向反应谱特征参数,并与水平向反应谱特征参数进行了比较。     

坝料流变对高面板堆石坝的应力变形影响研究

在高应力状态下坝料的流变较为明显。为研究坝料流变对混凝土面板坝应力变形的影响,采用长科院九参数幂级数流变模型及其试验参数,对某高混凝土面板堆石坝进行应力、变形分析。结果表明,坝料流变使坝体变形明显增加,坝体应力有所减小。考虑坝料的流变特性后的面板法向位移(挠度)明显增加,面板坝轴向和顺坡向应力极值增加。对于分期浇筑面板和分期蓄水的高混凝土面板堆石坝,选用合适的流变本构模型正确地模拟堆石体的流变特性,可以为大坝填筑进度及面板分期浇筑时间的确定提供参考,并有助于正确地预测大坝的应力变形。     

AP1000核电厂模型基底隔震振动台试验研究

为研究AP1000核电厂基底隔震性能,设计了缩尺比为1/40的AP1000核电厂模型结构,进行了AP1000核电厂模型基底隔震振动台试验。试验中采用铅芯橡胶隔震支座进行隔震,并选取RG1.60人工波、El Centro波和Kobe波作为地震动输入。本文从加速度响应、楼层加速度反应谱、加速度峰值放大系数、减震率等方面对隔震与非隔震核电厂结构的地震响应特性进行了研究。试验结果表明:隔震能明显减小上部结构水平向加速度响应和加速度反应谱峰值,而在隔震频率处隔震模型加速度反应谱有所增加;隔震模型由于摇摆效应在隔震频率处的水平向楼层加速度反应谱随楼层高度的升高先减小后增大;在三向输入地震动作用下,隔震和非隔震AP1000模型各楼层在竖向基频附近的竖向加速度反应谱较竖向输入的地震动放大较为明显。