强震区高面板堆石坝抗震安全性评价     

赵剑明  刘小生  陈宁  刘启旺  王宏 《地震工程学报》2011,33(3):233-238

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。  相似文献   

猴子岩高面板坝振动台模型试验——大坝结构动力特性研究     

刘小生  杨正权  刘启旺  陈宁  汪小刚  杨玉生 《世界地震工程》2010,26(4)

利用大型振动台模型试验,测得了猴子岩高面板堆石坝缩尺模型坝的动力特性参数,包括大坝结构的自振频率、阻尼比和振型系数等;分析了多种因素对坝体动力特性的影响规律;根据模型试验相似率推算得到原型坝的相应动力特性参数。研究表明:大坝结构有相对稳定的振型;坝体的动力特性参数值受激振白噪声强度和振动历史等因素影响;水库蓄水使得模型坝结构自振频率小幅提升。这些试验结果和研究结论,可以为该坝的动力分析提供基本资料和定性参考。  相似文献   

龙首二级面板堆石坝地震永久变形分析   总被引：3，自引：0，他引：3  

赵剑明  陈宁  常亚屏  刘云龙 《世界地震工程》2003,19(4):57-62

针对龙首二级(西流水)面板堆石坝工程，根据面板坝土石料的大型动三轴试验结果，确定了坝料的残余应变模式，特别是残余体应变模式。在所建立的面板坝三维非线性动力反应有限元法基础上，建立了一套同时计人残余体应变和残余剪应变的面板堆石坝地震永久变形计算方法，对龙首二级面板坝工程进行了地震永久变形的计算，分析了坝体地震永久变形的量值和分布情况，为大坝的抗震设计提供了有力的技术依据。  相似文献   

先期震动对土石坝地震永久变形的影响研究     

赵剑明  刘小生  刘启旺  陈宁  常亚屏  王宏 《世界地震工程》2011,27(1)

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。  相似文献   

特殊地形条件下面板堆石坝的动力反应特性及抗震能力研究     

《地震工程与工程振动》2016,(1)

受地形地质条件所限,抽水蓄能电站上水库的面板堆石坝工程通常不得不修筑在山腰、山坡等地形条件复杂的区域,特殊地形条件对面板堆石坝抗震安全性能的影响如何是值得关心的问题。采用基于ABAQUS的UMAT子程序二次开发的等价黏弹性模型,研究了此类特殊地形条件下面板堆石坝的动力反应特性,提出应该从防渗系统的安全性、坝坡动力稳定性以及地震最大残余变形三个方面综合评价大坝的极限抗震能力,研究了此类特殊地形条件下面板堆石坝的地震破坏模式。研究结果表明:大坝在地震荷载作用下的动加速度,动位移,动应力等动反应值均较小,坝体竖向最大残余变形值小于坝高的1%,大坝具有较强的抗震能力;大坝沿顺河方向的最大动位移出现在坝高3/4靠近下游侧的坝坡处,倾斜的坝基地形会影响大坝的动力反应特性;倾斜坝基地形条件下大坝的破坏模式以防渗系统破坏和下游坝坡失稳为主,其极限抗震能力为0.50 g~0.58 g。  相似文献   

苗家坝面板堆石坝材料动力特性试验研究     

《世界地震工程》2010,(Z1)

在清华大学2 000 kN大型静/动三轴试验机上进行了苗家坝水电站砼面板堆石坝筑坝材料的大型三轴动力特性试验,包括动剪切模量与阻尼比试验、动残余变形特性试验、动强度试验等。基于试验结果分析了坝料的动力变形规律,为该工程的应力变形计算和设计施工提供了试验依据。  相似文献   

混凝土重力坝FRP片材表面加固抗震性能研究     

王娜丽  钟红  林皋 《地震学刊》2012,(2):138-144

如何提高混凝土重力坝薄弱位置的抗震性能是国内外大坝抗震研究的热点问题。本文基于等价静力非线性方法,采用考虑混凝土细观非均匀特性的混凝土损伤模型,研究FRP片材表面加固大坝薄弱位置的抗震有效性。以2座不同形态的混凝土重力坝A、B为例,分别进行坝踵FRP片材表面加固研究和折坡处FRP片材表面加固研究,分析加固前后坝体的应力状态、裂缝扩展情况和破坏形态。数值模拟结果表明：坝踵处采用FRP片材加固可以很好地增强坝体的抗震性能,有效地抑制裂缝的产生和发展;折坡处采用FRP片材加固在一定程度上可以提高坝体的抗震性能,下游坝身加固与否对提高大坝的抗震性能影响不大。  相似文献   

深厚库底回填料上面板堆石坝动力反应分析          下载免费PDF全文

刘彦辰  杨贵  王建新 《地震工程学报》2015,37(2):336-341

深厚库底回填料是影响面板堆石坝动力响应的重要因素之一。为深入研究深厚库底回填料对面板堆石坝动力响应的影响,基于某拟建抽水蓄能电站,采用三维动力有限元分析系统研究其上库面板坝的地震反应,主要包括坝体加速度、面板动力响应、接缝变位情况以及库底防渗土工膜的动应变等。计算结果表明:由于库底回填料的存在,坝体加速度放大效应被明显削弱;面板周边以受拉为主,中部大部分区域受压;垂直缝呈现出周边张开、中间闭合的趋势;土工膜的顺河向和坝轴向的动拉应变皆小于屈服应变,最大应变出现在库底材料分界处,为提高坝体渗透安全性,建议对主堆石区与连接板相接处的回填料进行适当范围换填的处理措施。研究成果可以为类似工程提供参考。  相似文献   

新丰江水库大坝强震动监测及其动力特性分析     

《华南地震》2016,(4)

新丰江水库大坝是世界上第一座经受六级地震考验的超百米高混凝土大坝,并且至今库区周围仍然有地震不断发生,因此对其进行抗震分析十分必要。首先利用大坝强震动台阵的监测数据进行模态分析,然后结合模态分析结果建立大坝典型引水坝段ANSYS有限元模型并对其进行静力和动力分析,探讨坝体的变形和应力分布规律。结果表明:大坝模态频率与水位负相关;大坝在地震作用下,上游坝面突变处出现最大拉应力,这一现象与挡水坝段上游坝面突变处出现贯穿裂缝的破坏结果是一致的,应当引起一定重视,静力作用和地震作用下其他部位均有一定的安全储备;动力时程分析结果与反应谱分析结果相比,前者更加偏于安全。  相似文献   

超宽河谷上面板堆石坝地震响应特性分析     

《世界地震工程》2010,(Z1)

国内外未见有关在宽高比超过8.0的河谷上建高面板堆石坝的相关报道。文中采用非线性有限单元法,对一座拟建中的河谷宽高比为9.5的139 m高的混凝土面板堆石坝进行了地震响应分析,重点分析大坝的绝对加速度、动位移和动应力等动力响应情况。分析结果表明,在现有设计条件下,由于河谷宽高比较大,大坝在8度地震作用下地震响应不强烈,但坝顶出现明显的鞭稍效应,需采取相应的抗震工程措施。  相似文献   

干湿循环作用对堆石长期变形影响的试验研究   总被引：1，自引：0，他引：1  

王海俊  殷宗泽 《地震学刊》2012,(4):488-493,501

堆石体存在流变,不仅与荷载有关,而且与日晒雨淋引起的干湿循环有关。通过室内试验模拟日晒雨淋引起的干湿循环作用,研究其对堆石体长期变形的影响。试验结果表明,荷载作用流变很快趋于稳定,测得的流变量也相对较小;偏应力状态干湿循环作用引起的长期变形非常明显,其变形占后期变形总量的50%~70%,且后期变形的衰减远小于荷载单独作用引起的流变,这对于坝体的安全和稳定的影响是不容忽视的。根据试验研究揭示的变形规律,本文建立了相应的计算干湿循环变形的数值模型,可用于有限元计算。  相似文献   

Analysis on residual strain of Zipingpu Concrete Faced Rockfill Dam after Wenchuan earthquake     

Zhenping Liu  Shichun Chi 《地震工程与工程振动(英文版)》2013,12(2):221-228

The Zipingpu Concrete Faced Rockfill Dam (CFRD) was subjected to significant local damage in the “5.12” Wenchuan earthquake. It is the first rockfill dam of more than one hundred meters high to encounter a strong earthquake anywhere in the world. Based on the finite element smoothing method, the residual strains at a typical cross-section and a downstream slope of the dam were obtained by processing the dam monitored displacement data. The position of and reason for the dam settlement and deformation of rockfill dilatancy in the earthquake were analyzed according to the section residual strain. The results show that the maximum settlement ratio on the dam body approximately occurs at 2/3 of the dam height; dilatancy occurs from the dam crest to 25–30 m in the upstream and downstream slope; the immediate cause of the face slabs horizontal construction joint dislocation is excessive residual shear strain. Meanwhile, the position of and reason for the dam fissure in the earthquake were analyzed according to the dam slope residual strain.  相似文献   

两河口水电站混合料流变模型研究   总被引：2，自引：1，他引：1  

李海芳  张茵琪  金伟  温彦锋  陈宁 《地震工程学报》2011,33(Z1)

对两河口水电站混合料进行了三轴流变试验研究,对其流变机理和模型进行了探讨。两河口水电站混合料的轴向和体积流变特性可以用幂函数来描述,模型参数可根据试验得到的流变特性确定,并对流变模型参数的影响因素及取值进行了分析。  相似文献   

Numerical investigation of the response of the Yele rockfill dam during the 2008 Wenchuan earthquake     

《Soil Dynamics and Earthquake Engineering》2016

In this paper the seismic response of a well-documented Chinese rockfill dam, Yele dam, is simulated and investigated employing the dynamic hydro-mechanically (HM) coupled finite element (FE) method. The objective of the study is to firstly validate the numerical model for static and dynamic analyses of rockfill dams against the unique monitoring data on the Yele dam recorded before and during the Wenchuan earthquake. The initial stress state of the dynamic analysis is reproduced by simulating the geological history of the dam foundation, the dam construction and the reservoir impounding. Subsequently, the predicted seismic response of the Yele dam is analysed, in terms of the deformed shape, crest settlements and acceleration distribution pattern, in order to understand its seismic behaviour, assess its seismic safety and provide indication for the application of any potential reinforcement measures. The results show that the predicted seismic deformation of the Yele dam is in agreement with field observations that suggested that the dam operated safely during the Wenchuan earthquake. Finally, parametric studies are conducted to explore the impact of two factors on the seismic response of rockfill dams, i.e. the permeability of materials comprising the dam body and the vertical ground motion.  相似文献   

Discussion on “Nonlinear seismic response of tall concrete-faced rockfill dams in narrow canyons”     

《Soil Dynamics and Earthquake Engineering》2013

This discussion is based on the paper by Panos Dakoulas [1]. In this paper, the author has presented a comprehensive study on the seismic behavior of tall concrete face rockfill dams in narrow canyons, based on numerical simulation of the staged construction, creep settlements, reservoir impoundment and seismic shaking of the dam. This discussion presents some comments on the input motions for dynamic response analysis, numerical simulated dynamic deformation and the conclusions of that paper, which imply that some aspects need further clarification and/ or improvement.  相似文献   

Influence of seismic wave type and incident direction on the dynamic response of tall concrete-faced rockfill dams          下载免费PDF全文

Chen-guang Zhou  De-gao Zou  Xiang Yu 《地震科学（英文版）》2022,35(5):343-354

Owing to the stochastic behavior of earthquakes and complex crustal structure, wave type and incident direction are uncertain when seismic waves arrive at a structure. In addition, because of the different types of the structures and terrains, the traveling wave effects have different influences on the dynamic response of the structures. For the tall concrete-faced rockfill dam (CFRD), it is not only built in the complex terrain such as river valley, but also its height has reached 300 m level, which puts forward higher requirements for the seismic safety of the anti-seepage system mainly comprising concrete face slabs, especially the accurate location of the weak area in seism. Considering the limitations of the traditional uniform vibration analysis method, we implemented an efficient dynamic interaction analysis between a tall CFRD and its foundation using a non-uniform wave input method with a viscous-spring artificial boundary and equivalent nodal loads. This method was then applied to investigate the dynamic stress distribution on the concrete face slabs for different seismic wave types and incident directions. The results indicate that dam-foundation interactions behave differently at different wave incident angles, and that the traveling wave effect becomes more evident in valley topography. Seismic wave type and incident direction dramatically influenced stress in the face slab, and the extreme stress values and distribution law will vary under oblique wave incidence. The influence of the incident direction on slab stress was particularly apparent when SH-waves arrived from the left bank. Specifically, the extreme stress values in the face slab increased with an increasing incident angle. Interestingly, the locations of the extreme stress values changed mainly along the axis of the dam, and did not exhibit large changes in height. The seismic safety of CFRDs is therefore lower at higher incident angles from an anti-seepage perspective. Therefore, it is necessary to consider both the seismic wave type and incident direction during seismic capacity evaluations of tall CFRDs.  相似文献   

Nonlinear seismic response of tall concrete-faced rockfill dams in narrow canyons   总被引：1，自引：0，他引：1  

Panos Dakoulas 《Soil Dynamics and Earthquake Engineering》2012,34(1):11-24

The seismic behavior of tall concrete face rockfill dams in narrow canyons is investigated, based on numerical simulation of the staged construction, creep settlements, reservoir impoundment and seismic shaking of the dam. The study takes into account the flexibility of the canyon rock, the hydrodynamic effects and potential dynamic rockfill settlements. The static analysis uses a hyperbolic model for the rockfill, whereas the dynamic analysis uses a nonlinear hysteretic model, which accounts for the initial dynamic stiffness and produces hysteresis loops in agreement with the experimental data regarding the shear modulus and damping ratio. A damage plasticity model is used for the reinforced concrete, whereas frictional contact behavior is considered at the base and vertical walls of the concrete slab panels. An existing 150-m-high dam is used to investigate some key issues on the seismic behavior of such dams subjected to upstream−downstream and vertical excitation. Emphasis is placed on the evaluation of the tensile stresses within the slab panels, the compressive stresses at the slab-to-slab vertical interfaces and the opening of the joints. Moreover, the effect of potential dynamic settlements on both the slab stresses and joint openings is investigated. Recommendations for increasing the dam safety and reducing the water leakage through the dam body are given.  相似文献