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《地震工程与工程振动》2015,(6)
为探明动荷加载过程中黄土结构损伤的耗能机制及其对变形特性的影响规律,针对原状Q3黄土,开展了一系列固结比=1.5、含水量=15%、18%、21%、24%和围压=50、100、200、300 k Pa试验条件下等幅循环加载的动三轴试验。通过引入能量耗散比定义的损伤变量,研究了结构性土动力损伤的耗能机制,分析了结构性黄土动力损伤对动模量、阻尼比和动残余变形模量的影响变化规律。研究表明:初始结构性和应力状态相同的同一种结构性土的动力损伤的破坏耗能与动荷载无关;不同固结应力水平下,动模量和阻尼比随结构损伤累积呈现出不同的变化规律,但最终都会趋于土破坏状态的某一稳定值;动残余变形模量随结构损伤累积呈单调递减关系,低围压条件下的递减幅度逐渐趋缓,高围压条件下则全程较缓;动残余变形模量与损伤变量之间的变化关系可用二次函数拟合,拟合结果与实验结果具有很好的一致性。 相似文献
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为了解曲线段下普通整体道床和钢弹簧浮置板道床对既有建筑物内楼板位置振动影响情况,对后期同类项目地铁线路规划提供指导参考。以郑州地铁7号线下穿某体育馆项目为背景,首先对体育馆内部振动评估点位置与外部地面进行同步背景振动测试,将各测点进行1/3倍频程频谱分析,分析体育馆内、外的传递规律。其次,结合已通车的同类地铁线路进行振源模拟测试,对隧道壁及地面位置进行1/3倍频程频谱分析,分析不同道床形式下地铁列车振动源强数据以及土体模型仿真计算校核参数。再次,建立有限元模型计算不同道床形式下地面振动速度响应。最后,结合体育馆内、外传递规律,预估地铁通车后体育馆内评估点位置振动响应。研究表明:若采用普通整体道床,地面位置水平向振动速度响应峰值在63 Hz达到0.03 mm/s,传递至体育馆内顶层楼面处会放大至4.50 mm/s,超过其控制标准2.50 mm/s的限制,若采用钢弹簧浮置板道床,竖直向最大振动速度峰值为0.04 mm/s,水平向为1.36 mm/s,均满足体育馆振动控制标准。 相似文献
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通过循环三轴试验,研究了k0固结饱和粘土在0.5 Hz、0.1 Hz与0.01 Hz循环应力作用下,循环强度与土样破坏时最终累积孔压的变化。结果表明,当循环频率从0.1 Hz减少至0.01 Hz时,若循环应力作用下三轴土样发生应力反向,k0固结饱和粘土循环强度大约降低3%左右;若没有应力反向,且当循环破坏次数从10变化至1 000时,循环强度的降低不超过1%,若循环破坏次数大于1 000时,循环频率的改变对循环强度基本没有影响。对于有应力反向情况,循环频率减小将导致最终累积孔压比增加;对于无应力反向情况,循环频率改变对最终累积孔压比的影响并不显著。循环频率对最终累积孔压比的影响与其对循环强度的影响一致。 相似文献
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以片状颗粒成分为主的片状结构砂与常用的圆形颗粒标准石英砂相比,在物理力学特性上有显著的差异。循环荷载作用下,饱和砂土振动孔压上升会导致土体刚度发生软化,当振动孔压累积达到一定水平时,会产生液化现象,从而引起土体结构发生破坏。采用英国WFI动三轴仪,研究了南京片状细砂在循环荷载作用下,静偏应力水平、循环应力比水平和循环次数对其动应力一应变关系的影响,考虑每一次循环过程中动应力—应变关系滞回曲线的卸载及再加载割线动剪切模量Gsec和最大割线模量Gmax的变化特性,建立了动剪模量软化的经验公式;静偏应力水平对动剪模量软化有显著影响,随着循环次数的增加,动应力—应变滞回圈逐渐向应变累积方向滑移和向应变轴方向倾斜,且彼此分离;考虑循环软化特性,采用修正的Masing准则,描述了循环荷载下南京片状细砂的动应力—应变关系。 相似文献
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针对黄土地区实现工程施工材料本土化和科学利用粉煤灰问题,对不同配比条件下粉煤灰改性黄土进行重塑非饱和试件的动三轴震陷试验,研究其在动荷载作用下的震陷特性,分析粉煤灰掺入量对动变形模量和动残余应变的影响变化规律。研究结果表明:粉煤灰掺入量对黄土震陷性质的影响较大。相同固结应力水平下,动变形模量和动残余应变随粉煤灰掺入量呈现出不同的变化规律,随着粉煤灰掺入量的增加,黄土动变形模量也随之增大,残余应变则减小。动变形模量与动残余应变之间的变化趋势满足幂函数关系;黄土掺加约20%粉煤灰改性后就能够有良好的抗震陷性能。研究成果可为黄土地区地基的抗震防震设计提供借鉴依据,具有重要的工程实用价值。 相似文献
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通过建立三维数值模型,对隐伏正断层在均匀错动和倾斜错动方式下土体的破裂过程进行研究。利用应力罗德参数和等效塑性应变分别对断层错动过程中上覆土体的应力状态和破坏形式进行分析,并提出土体破裂的判别方法。通过对数值模拟结果的分析得到以下结论:① 在断层错动过程中,下盘一侧受断层错动影响的上覆土体的应力状态经压剪→纯剪→拉剪逐渐变化,而上盘一侧上覆土体的应力状态变化较为复杂,经压剪→纯剪→拉剪→纯剪→压剪重复变化;② 在断层均匀错动过程中,断层下盘一侧土体的破裂率先出现在地表拉剪区内,随错动量的增大,破裂带向两侧、向深部扩展;同时,下盘一侧土体的底部产生破坏,并斜向上扩展,逐渐与顶部破裂相连;③ 在断层倾斜错动过程中,地表破裂出现的位置和上覆土体的厚度有关。对于厚度较大的土体,正断层倾斜错动能够在地表形成与断层走向有一定夹角、且与断层长度相比长度很短的地表破裂或地裂缝,而数值模拟可对正断层错动导致的地表破裂的模式加以补充,为研究地裂缝的形成机理和分布形式提供依据。 相似文献
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土石坝(超)深厚覆盖层中的深埋细粒土难以完全挖除(换填),其在地震作用下的动力变形特性和强度特性是科研设计人员关注的问题。本文进行某大型土石坝工程超深厚覆盖层地基中的深埋粉砂层土动力特性三轴试验,研究其在地震荷载作用下的动力变形与强度特性,并为大坝—地基系统动力分析和抗震设计提供基础资料。研究表明:试验土料最大动剪模量和平均有效应力在双对数坐标中呈良好的线性关系,不同围压力条件下的模量衰减(阻尼比增长)曲线可以采用参考剪应变的方式进行归一,可用试验确定特定围压力条件下的模量衰减(阻尼比增长)曲线外延推求任意围压力条件下的相应曲线;试验土料在地震荷载作用下的动强度特性主要受土体密度、固结条件和围压力条件等控制,当土体处在不等向固结状态时,不同动力破坏标准下确定的土体动强度特性参数差异较大。 相似文献
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建立精细化的足尺轨道-路基-地基耦合系统非线性数值分析模型,考虑岩土材料的非线性应力-应变关系、路基填筑完成后的静应力状态对其后动力计算的影响、底座板底面与路基基床表层表面之间的动力相互作用,模拟轨道与路基系统的建造过程和与8辆编组动车组轮对相对应的荷载以350 km/h的速度的移动过程。结果显示,以实体单元模拟钢轨能获得更符合事实的钢轨空间振动响应,比采用梁单元更具优势;路基各层底面的动位移具有随时间和空间变化的特征;沿路基断面横向,不同时刻的竖向动位移在轨道板宽度范围内的最大波动值约0.04 mm,可认为均匀分布;沿深度方向,竖向动位移在不同时刻的分布相似,按照指数函数衰减,最大值约为0.8 mm,小于我国高速铁路3.5 mm的控制标准;沿线路纵向,竖向动位移峰值出现的位置与该时刻移动荷载所处的空间位置对应,在同一深度条件下,不同时刻的竖向动位移分布形态相似;基床底层底面以上,同一转向架上前后轮对对应的荷载引起的竖向动位移具有可观的叠加效应。 相似文献
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基于轨道结构-路基-地基动力相互作用理论,建立考虑地震-列车移动荷载耦合输入的轨道结构-路基-地基动力学模型,研究高速铁路路基及轨道在耦合荷载作用下的振动响应问题。通过编制DLOAD子程序并与ABAQUS有限元计算程序联立,实现地震荷载与列车移动荷载耦合作用的施加,以高速铁路桩承式路基及自由式路基为研究对象,对地震-列车移动荷载耦合作用下两种路基系统的动力响应进行数值计算并比较两者的振动响应差异。结果表明,耦合荷载对桩承式路基动力响应影响显著,该荷载作用下桩承式路基会发生共振现象,使得桩承式路基中轨道和路基振动位移幅值均大于自由式路基的振动位移幅值;桩承式路基不会影响路基系统的振动频率,但会改变路基系统的振动大小,桩承式路基中轨道X方向加速度、路肩边及路基坡脚处的竖向加速度分别减小6.2%、50%、28.6%。 相似文献
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深季节冻土区列车行驶路基振动数值模拟研究 总被引:1,自引:0,他引:1
分析大庆深季节冻土区铁路路基的冬季现场加速度监测结果,获得了列车经过时铁路路基冻结地表振动加速度的时程特性及其衰减规律,并运用动力有限元方法进行了动力响应分析。研究结果表明:①随着列车行驶速度的增大,路基振动加速度亦增大,且重载货车振动响应大于高速客车;②列车行驶引起的路基振动加速度幅值,随着距线路中心距离的增加而迅速衰减;③应用有限元方法分析列车行驶路基振动特性是可行的。本文为研究深季节冻土区铁路路基振动特性提供了一种分析方法,对加深了解深季节冻土区铁路路基振动特性具有重要意义。 相似文献
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The use of ballastless slab track is significantly increasing in HST line technology. This development is due to some structural and operational advantages over ballasted track. In addition, floating slab tracks can be used to control ground-borne vibrations generated by surface and underground rail transportation systems. In this paper, a general and fully three dimensional multi-body-finite element-boundary element model is used to study vibrations due to train passage on ballast and non-ballast tracks. The vehicle is modelled as a multi-body system, the track, in both cases, using finite elements and the soil is represented using boundary elements. The three components of the load are considered; the quasi-static excitation (force generated by moving axle loads), the parametric excitation due to discrete supports of the rails and the excitation due to wheel and rail roughness and track unevenness. Track receptances are computed for both track systems and vibrations induced by high-speed train passage at the track and the free-field are evaluated for different train speeds. Soil behaviour changes significantly with the track system. Finally, a floating slab track is studied to show how this type of solution leads to a significant vibration reduction for surface tracks. 相似文献
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Model testing in laboratory, as an effective alternative to field measurement, provides valuable data to understand railway׳s dynamic behaviors under train moving loads. This paper presents comprehensive experimental results on track vibration and soil response of a ballastless high-speed railway from a full-scale model testing with simulated train moving loads at various speeds. A portion of a realistic ballastless railway comprising slab track, roadbed, subgrade, and subsoil was constructed in a larger steel box. A computer-controlled sequential loading system was developed to generate equivalent vertical loadings at the track structure for simulating the dynamic excitations due to train׳s movements. Comparisons with the field measurements show that the proposed model testing can accurately reproduce dynamic behaviors of the track structure and underlying soils under train moving loads. The attenuation characteristics of dynamic soil stresses in a ballastless slab track is found to have distinct differences from that in a ballasted track. The model testing results provide better understanding of the influence of dynamic soil–structure interaction and train speed on the response of track structure and soils. 相似文献
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Vehicle load is among the main factors affecting the deformation of subgrade soil.In this research study,the concept of impact type traffic load is introduced to investigate the effects of vehicle load based on the dynamic stress and displacement time histories acquired from seasonal frozen subgrade soils.Using freezing-thawing and dynamic triaxial tests and considering the amplitude and loading sequence of impact type traffic load,the residual deformation characteristics of subgrade soil under impact type traffic loads and freezing-thawing cycles is studied.It was found that under impact type traffic load,the residual deformation of soils increased sharply as the amplitude of impact type traffic load increased.It was also found that the increase in the amplitude of impact type traffic load led to the increase of residual deformation in a scale of power and exponential function.The amplitudes of impact type traffic load affect the development stress-strain path of the residual strain.After the soil experienced the proper amount of pre-vibration of the light load,residual deformation decreased by 15%.After freezing-thawing,the residual strain of soil increased as the amplitude of the impact type traffic loads increased.Also,when the amplification effect of freezing-thawing on the residual strain was basically stable,the residual deformation increased by about 10%.The peak impact type traffic load had a large effect on soil deformation after the freezing-thawing process,leading to the observation that of the earlier the peaks,the stronger the effect of freezing-thawing.After the soil was subjected to preloading with a small load,the influence of the freezing-thawing cycles gradually stabilized.The results may be useful in preventing and controlling the risk of subgrade soil failure when construction takes place spring thaw periods. 相似文献
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Train-induced wave propagation in layered soils using finite/infinite element simulation 总被引:1,自引:0,他引:1
In this paper, the transmissibility of soils for vibrations induced by trains moving at different speeds is studied. The 2.5 D finite/infinite element approach adopted herein allows us to consider the load-moving effect of the train in the direction normal to the two-dimensional profile of the soils considered, and, therefore, to obtain three-dimensional responses for the soils using only plane elements. The moving train is simulated by a sequence of moving wheel loads that may vibrate with certain frequency. Two train speeds are considered, one is smaller and the other is greater than the Rayleigh wave speed of the layered soils, to represent the effects of speed in the sub-critical and super-critical ranges. In order to evaluate the effect of each parameter on the ground response induced by moving trains, parametric studies are conducted for the following parameters: the shear wave speed, damping ratio and stratum depth of the supporting soils, and the moving speed and vibration frequency of the traveling trains. Conclusions concerning the mechanism of wave propagation in layered soils are drawn from the parametric studies, which should prove useful to practicing engineers. 相似文献
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Soft ground improvement using piles has increasingly been used as a rapid construction technique for railway and highway embankments over soft soil areas. While most studies conducted so far have addressed only issues of stability and settlement of pile-supported embankments under static loading, very limited attention has been paid to understanding their behaviors under transient loading of moving vehicles. In this study, vibration behaviors of this embankment system under high-speed train passage are investigated through three-dimensional finite element simulation. They include (1) characteristics of the surface wave field at high train speeds, (2) the dependence of vibration amplitude on the train speed and the phenomenon of critical speed, and (3) response at some typical locations in the system when the train moves at the critical speed. The study shows that there are breaks in the simulated wave fronts as transiting between different materials due to the difference in the Rayleigh wave speed among the materials relative to the train speed, and that the increase in train speed is accompanied by the increase in phase shift between the train load and the displacement pattern beneath the load. It is shown that the critical speed of the system is governed by the embankment, instead of the soft soil as commonly observed in previous studies in which the ground is not improved. Namely the vibration amplitude is maximally amplified when the train speed approaches the characteristic Rayleigh wave speed of the embankment material. In addition, the results also suggest that the sloping surfaces on the ballast and embankment along with the piles form a ‘trapping’ effect by which most of the train-induced waves, especially higher-frequency waves, incident to the sloping surfaces are trapped and dissipated within the pile-supported embankment system, and thus significantly reducing vibration amplitudes outside the embankment. 相似文献
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Railway ballast forms a major component of a conventional rail track and is used to distribute the load to the subgrade, providing a smooth running surface for trains. It plays a significant role in providing support for the rail track base and distributing the load to the weaker layer underneath. Ballast also helps with drainage, which is an important factor for any type of transportation structure, including railroads. Over time, ballast progressively deforms and degrades under dynamic loading and loses its strength. In this study, extensive laboratory tests were conducted to investigate the effect of load amplitude, geogrid position, and number of geogrid layers, thickness of ballast layer and clay stiffness on the behavior of the reinforced ballast layer and induced strains in a geogrid. A half full-scale railway was constructed for carrying out the tests, which consisted of two rails 800 mm in length with three wooden sleepers(900 mm × 10 mm × 10 mm). Three ballast thicknesses of 200, 300 and 400 mm were used in the tests. The ballast was overlying 500 mm thickness clay in two states, soft and stiff. The tests were carried out with and without geogrid reinforcement; the tests were performed in a well-tied steel box of 1.5 m length ×1 m width ×1 m height. Laboratory tests were conducted to investigate the response of the ballast and the clay layers where the ballast was reinforced by a geogrid. Settlement in ballast and clay, soil pressure and pore water pressure induced in the clay were measured in reinforced and unreinforced ballast cases. It was concluded that the amount of settlement increased as the simulated train load amplitude increased, and there was a sharp increase in settlement up to cycle 500. After that, there was a gradual increase that leveled out between, 2500 to 4500 cycles depending on the frequency used. There was a slight increase in the induced settlement when the load amplitude increased from 0.5 to 1 ton but it was higher when the load amplitude increased to 2 tons. The increased amount in settlement depended on the existence of the geogrid and other parameters studied. The transmitted average vertical stress for ballast thicknesses of 30 cm and 40 cm increased as the load amplitude increased, regardless of the ballast reinforcement for both soft and stiff clay. The position of the geogrid had no significant effect on the transmitted stresses. The value of the soil pressure and pore water pressure on ballast thicknesses of 20 cm was higher than for 30 cm and 40 cm thicknesses. This meant that the ballast attenuated the induced waves. The soil pressure and pore water pressure for reinforced and unreinforced ballast was higher in stiff clay than in soft clay. 相似文献
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Hideo Nagase 《Soil Dynamics and Earthquake Engineering》1987,6(4):239-249
In an effort to investigate the effects of irregular nature of load application on the behaviour of soils during earthquakes, a series of uni-directional irregular loading tests were performed on saturated Fuji river snad under undrained condition using a simple shear test apparatus. The samples prepared to three different densities in this test device were subjected to twelve irregular time histories of shear stress alteration. For comparison purposes, the conventional type of constant amplitude cyclic simple shear tests were also conducted on samples prepared under identical conditions. On the basis of the test results, values of coefficients allowing for the effect of load irregularity were elucidated for the samples with three different densities. It was then suggested that the values of coefficient thus determined be used to facilitate the evaluation of the soil strength under actual seismic loading conditions, on the basis of the cyclic shear strength obtained from the conventional type of constant-amplitude triaxial tests. 相似文献
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我国众多铁路干线分布于深季节冻土地区。铁路路基土层的冻融状态随着季节的交替变化而改变,相应的列车行驶时引起的路基动应力分布也有所不同。考虑路基土体的参振效应,通过改进车辆-轨道-路基垂向耦合动力学模型获取不同季节列车行驶振动荷载时程,进而通过动力有限元数值模拟方法,研究季节变化对列车行驶引起的路基动应力分布规律的影响。研究表明:路基土中的动应力幅值及其沿路基深度的分布规律与该时期路基土的冻融状态密切相关,基于此结论,提出深季节冻土地区不同季节铁路冻土下限范围内路基动应力的简化计算方法。该研究对于优化季节性冻土地区铁路路基设计方法,完善路基长期动力稳定性能评价方法等具有重要意义。 相似文献