共查询到19条相似文献,搜索用时 468 毫秒
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分析了造成波浪衰减几种力学机制,并针对不同模型海底底床下的波浪衰减,以及有限深底床和无限深底床的波浪衰减进行了计算比较,认为造成波浪衰减的力学机制直接和底床砂质的性质相关。 相似文献
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对结构-土相互作用体系中结构基础底面积和结构基础埋深对体系地震反应的影响进行了研究.基于有限元分析方法建立了结构-土相互作用三维计算模型,通过改变结构底面积及基础埋深在不同地震动下进行了地震反应分析.结果表明,考虑相互作用时,在同一种地震动作用下,结构顶层总位移及基础转动随着结构底面积的增大而明显减小,上部结构本身位移在总位移中所占比例随着底面积的增加而增大;底面积相同,结构顶层总位移及基础转动均随着埋置深度的增大而减小,上部结构本身位移在总位移中所占比例随着埋置深度的增加而增大.比较不同特性的地震动,不同底面积及埋深结构顶层总位移、基础转动、基础平动和结构自身位移的变化规律趋势相同. 相似文献
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浪作用下海洋底床动态响应的研究 总被引:4,自引:0,他引:4
有关波浪作用下的底床动态响应越来越引起人们的重视。本文从海洋土的特点出发,针对各向同性底床和各向异性底床,详细论述了在线性波加载下,波浪衰减和底床动态响应这两方面的研究现状,在分析和比较已有研究成果的基础上,对今后的研究方向提出了自己的看法。 相似文献
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基于通用软件ABAQUS,建立了扩底抗拔桩三维弹塑性有限元模型,通过对模型的计算与分析,探讨了扩底桩的抗拔承载特性。为验证数值模型的可靠性,将数值计算得到的荷载-位移关系曲线与试桩资料进行比较,两者吻合较好,表明本文所建立的模型可较好地模拟扩底抗拔桩的工作性状。通过计算与分析,探讨了扩底抗拔桩的轴力、侧摩阻力分布特征,桩身和扩大头周围土体变形与塑性应变的发展规律,以及扩大头的挤压作用对扩大头周围土体竖向应力的影响。同时,通过变动参数研究了扩大头的形状、土体的性质对扩底桩抗拔承载力的影响,结果表明,扩大头直径和扩大头周围土体的性质对抗拔承载力的影响较大,而扩底高度的影响相对较小。 相似文献
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本文对国内外10条地震断层实测位移分布特征进行了分析,并将不同形态的实测位移分布曲线与有限元计算曲线对比.结果表明:破裂状态不同的地震断层,其位移曲线不同;位移的分布与发震断层闭锁区强度及闭锁区的破裂程度有关. 相似文献
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以西安万寿寺塔纠偏工程为研究背景,分别建立增加圈梁、圈梁-地梁组合以及圈梁-地梁-托盘组合模型下的塔体与基础协同工作模型。采用时程分析法,对不同基础刚度条件下塔体的地震响应进行分析及评估,结果表明:(1)增大基础刚度的同时结构的地震位移响应将会被放大,但应力时程曲线的波动范围随之缩小、幅值减小;(2)增设圈梁时由于塔底三向受力,塔底应力将被放大;(3)进行基础完全托换能够大幅改善塔底在地震作用下的受力状态。在塔体加固维修时应综合考虑地震作用下塔体的位移放大效应与塔体应力分布的影响,选取合适的基础刚度。 相似文献
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研究表明,西天山大中型富铁矿床主要赋存于伊犁石炭纪弧后盆地,铁的成矿应与早石炭世海相火山诱发的熔流体喷溢与热液交代密切相关,且盆地建造制约矿化类型及其分布.区域航磁测量获得了近东西走向的高磁异常带和北西向、东西向的低磁异常带相间分布的格局,磁场梯度变化较大,客观反映了不同构造单元中地壳物质组分的明显差异,且很好地反映了阿吾拉勒铁矿带的区域分布特点.赋存于大哈拉军山组熔岩-火山碎屑岩建造中的铁矿床主要定位于火山机构断裂系中,大多与容矿火山岩系呈不协和接触关系,其产状取决于矿床在火山机构/火山穹窿中所处的具体位置,成矿物质主要来源于火山晚期高温熔流体和岩浆热液;而赋存于伊什基里克组的铁矿床主要属于化学沉积铁矿,其定位和规模主要受控于水下沉积洼地的古地貌特征,因而它们大多与上下盘地层呈整合接触关系.因此,伊犁盆地石炭纪海相火山岩建造与海相火山-沉积建造之间的差异性,很可能是控制不同类型矿床形成与定位的第一要素. 相似文献
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在GSA标准分析法基础上提出两阶段分析法,采用ANSYS/LS-DYNA建立了一个7层底框砌体结构的三维有限元模型,对爆炸荷载作用下底框砌体结构连续倒塌过程进行模拟。根据爆炸荷载引起的结构局部性破坏,对局部采取适当的防爆抗爆措施防止结构的连续倒塌。通过改变砌体材料的强度等级、纵向配筋率、粘贴玻璃纤维复合材料、粘贴钢板、柱网尺寸、墙体开洞以及底框层数,得到底框砌体结构在爆炸荷载作用下的响应规律和破坏情况以及结构墙体中砌体材料、钢筋的应力和位移随时间的变化规律,为底框砌体结构的防爆设计提供理论基础和有价值的参考数据。 相似文献
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The dynamic soil-structure interaction of a shear wall embedded in elastic isotropic and homogeneous soil layers underlain by bedrock, subjected to SH waves, is modeled in the present article. The soil layers consist of irregular interfaces and it has been shown that the scattering due to the roughness of the layers has significant effect on the displacement of both the foundation and the shear wall. To demonstrate the phenomena indirect boundary element method(IBEM) has been used on the basis of its validation in previous problems of similar type. The system response is compared with the analytical solution of the same type of model for vertically propagating incident SH waves. It is observed that for the low frequency of wave, displacement is abruptly high, and as a result the combination of shear wall and foundation perceives resonance. The thickness of the soil layer, mass of the shear wall, stiffness of the bedrock and the soil layers all affects the system frequency and displacement. 相似文献
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Yasser E. Mostafa M. Hesham El Naggar 《Soil Dynamics and Earthquake Engineering》2006,26(12):1127-1142
Storms, hurricanes, and earthquakes may cause seabed instability, especially if the seabed is weak. The seabed instability, manifested in movement of soil layers, exerts lateral forces that may cause large stresses in offshore foundations. The induced stresses may compromise the stability of the foundation and supported structure. The effect of seabed instability on a fixed offshore structure is examined in this study. The method used accounts for soil nonlinearity, dynamic soil resistance, and pile–soil–pile interaction within the stable soil layer. Dynamic p–y curves, dynamic t–z curves and q–z curves have been used to simulate the soil resistance in the lateral and axial directions. The effect of different parameters that influence the response of offshore structures to seabed instability is evaluated. The parameters considered include the value of soil movement, the sliding layer depth, the wave loading, the pile flexibility, the soil movement profile, and the axial loading at the pile head. The response predicted using the proposed analysis compared well with that calculated using a boundary element solution for a case history of a failed offshore platform. 相似文献
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The evaluation of the wave-induced excess pore pressure around a buried pipeline is particularly important for pipeline engineers involved in the design of offshore pipelines. Existing models for the wave-induced seabed response around submarine pipeline have been limited to poro-elastic soil behavior and de-coupled oscillatory and residual mechanisms for the rise in excess pore water pressure. To overcome the shortcoming of the existing models, in this study a three-dimensional poro-elasto-plastic soil model with submarine pipeline is established, in which both oscillatory and residual mechanisms can be simulated simultaneously. With the proposed model, a parametric study is conducted to investigate the relative differences of the predictions of the wave-induced pore pressure with poro-elasto-plastic model. Based on numerical examples, it can be concluded that the poro-elasto-plastic behaviors of soil have more significant influence on wave-induced pore pressure of seabed around submarine pipeline. As the seabed depth increases, the normalized pore pressures decrease rapidly at the upper part of seabed, and then change slightly at the lower part of the seabed. Soil permeability and wave period have obvious influence on the wave-induced normalized pore pressure. 相似文献
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Katsuto Uehara Pramot Sojisuporn Yoshiki Saito Thanawat Jarupongsakul 《地球表面变化过程与地形》2010,35(14):1701-1711
Seasonal variation in seabed elevation in the muddy intertidal zone of the Chao Phraya River delta, an area of serious coastal erosion for 40 years, was assessed using information on waves and tides predicted by numerical simulations. The study area is under the influence of the Southeast Asian monsoon climate and lies in the innermost part of a sheltered gulf, across which a low‐gradient slope has developed. Observations, aimed at evaluating the effectiveness of a prototype breakwater on mitigating coastal erosion, indicated that the seasonal variation in the seabed elevation, typically about 30 cm, was caused primarily by seasonal changes in wave direction and height. The breakwater seems to have contributed to a net rise in the seabed level at sites behind the structure. Seabed erosion was most apparent during the northeast monsoon, when waves are weak. Erosion under this low wave energy state was attributed to the combined effect of wave breaking and the low tidal level. A difference in the observed seabed accretion rate between the transitional intermonsoon period and the succeeding southwest monsoon period was attributed to the direction of the wave energy flux; offshore sediments seem to have been supplied efficiently to the study area by waves during the transitional period. Another potential cause of seabed erosion and accretion during the wet southwest monsoon season was the discharge of water and sediments from local canals associated with intense tropical rainfall; this discharge seems to be linked to land use in the coastal area. The results of this study show the importance of monitoring across‐shore sediment transport for better understanding of coastal erosion processes. Copyright © 2010 John Wiley & Sons, Ltd. 相似文献
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Finite element modelling for water waves-soil interaction 总被引:1,自引:0,他引:1
The soil permeability and shear modulus of many marine sediments vary with depth because of consolidation under overburden pressure. However, conventional theories for wave-induced soil response have assumed a homogeneous porous seabed, with constant soil permeability and shear modulus. This paper presents a finite element model for the wave-induced soil response in a porous seabed, with variable permeability and shear modulus as a function of burial depth. The soil matrix considered here is unsaturated and hydraulically anisotropic, and subjected to a three-dimensional short-crested wave system. The present finite element formulation is established by using a combination of semi-analytical techniques and the Galerkin method. The nodal effective stresses directly derived from the governing equations can be calculated accurately in the present model. Verification is available through the reduction to the simple case of homogeneous seabed. Three typical marine materials, course, fine sand and gravel, are considered in this study. The numerical results indicate that the soil permeability affects the wave-induced seabed response significantly especially for gravelled seabed, as does the soil shear modulus for sandy seabed. 相似文献
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爆破地震作用下桩-土-结构相互作用的数值模拟 总被引:1,自引:0,他引:1
土-结构动力相互作用是地震工程和结构抗震的重要研究内容,但目前对爆破地震作用下土-结构动力相互作用的研究较少。运用大型有限元软件ANSYS/LS-DYNA,建立了桩-土-结构相互作用体系的三维有限元模型,由桩尖输入实测爆破地震波,取得了良好的计算效果。计算结果表明:考虑桩-土-结构相互作用后,群桩基础中每个桩的位移、加速度和剪应力幅值均呈桩顶大、桩尖小的倒三角分布,桩与承台的接合部比较容易受到损坏;桩-土-结构相互作用体系在爆破地震波冲击后,还会发生几次振动,但是这些振动产生的影响要小于爆破地震产生的影响,这与实测结果相符合;爆破地震波冲击下,群桩基础中,角桩顶部表面的桩土接触压力较大,但在爆破地震波冲击后,中心桩顶部表面的桩土接触压力较大,且具有一定的周期性,直至衰减为零。 相似文献
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本文基于Biot动力固结理论和弹性动力学理论,考虑海床(土壤)的两相性、黏弹性人工边界及流(水)-固耦合作用,建立了隧道-土-流体相互作用的力学模型,讨论了P波作用下有无水的情况以及水深、水域隧道埋深、海床土性质和地震波入射角等因素对隧道及其周围海床应力的影响。结果表明:隧道周围海床土的孔隙水压力和隧道内应力随着水深的增加而增加;地震波特性和海床土特性对隧道的内应力和海床土的孔隙水压力均有较大的影响;海床土的渗透性和隧道埋深对隧道的内应力影响较小,而对隧道周围海床土的孔隙水压力影响较大;地震动的入射角对隧道的内应力和隧道附近土层的孔隙水压力均有较大影响。 相似文献
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By now, it is well known that long‐period surface waves can induce resonant response in high‐rise buildings, in particular those located in sedimentary basins. Rayleigh wave passage has been reported to induce rocking motion at the base of the buildings which can increase displacement demands significantly. However, the building behavior to base rocking has not been extensively studied because commercially available instruments do not record rotational components of ground motion, and thus, rocking time histories have not been available to the analysts. In a recent study, we proposed an effective method for estimating the rocking associated with Rayleigh waves, which takes into account their frequency‐dependent phase velocities. In the present work, we select a number of recorded seismic motions which include surface waves on sedimentary basins from recent well‐recorded earthquake events. Then, we proceed to identify and extract the recorded surface waves by using the technique mentioned above. Using realistic soil‐structure analytical models that have been proposed in the published literature for high‐rise buildings, we study their response to Rayleigh waves as they respond to both translational and rocking motions. Of particular interest is to compare the response of such structures with and without the presence of rotational motions due to surface waves. Using the roof displacement and the building interstory drift as response quantities, our results indicate that demands are controlled by rotational (rocking) motions associated with Rayleigh waves. 相似文献