场地条件对高速铁路地基土振动影响的研究

发展高速铁路是解决城市间交通问题的有效途径,但其所产生的振动和噪声引起的环境问题,对铁路沿线居民及周围建筑等造成不利影响。在对高速铁路引起的振动问题进行的研究中,关于高速列车引起的地基土振动随深度变化的相对较少。因此,本文针对Ⅱ、Ⅲ和Ⅳ类场地条件下的路堤式和高架桥式高速铁路,对0—5m不同深度处地基土的振动加速度响应进行了现场测试,并以测试数据为基础,分析了不同场地条件下高速列车引起的地基土振动加速度响应随深度的变化规律。结果表明,不同场地条件下,高速列车引起的振动加速度响应随深度的变化规律具有显著差异;Ⅱ类和Ⅲ类场地条件下,高速列车引起的地基土振动加速度响应总体随深度的增加而逐渐减小,并呈先快后慢的衰减趋势;而Ⅳ类场地条件下,高速列车引起的地基土振动加速度响应随深度的增加呈现先减小后放大的趋势,在深3m处加速度达到最大值。高速列车运行引起的振动频带随深度的变化特征与场地相关。     

地面线城轨列车引起的地面振动预测模型研究

通过建立地面线路城轨列车引起的自由场地振动分析模型,并对模型中不同影响因素进行分析,建立地面振动预测模型。分析模型包括振源和场地两个部分,由列车运行作用于道碴上的力进行联系。影响因素包括:钢轨类型,轨道不平顺,列车速度、编组、载客量,场地土性质。利用课题组在京广铁路沿线进行的自由场地振动测试对振动分析模型进行验证,结合统计软件的相关程度来评价本文所建立的振动预测模型的适用性。     

基于相似分析的季节性冻土区铁路桥墩—基础场地振动特性研究

为了研究季节性冻土区铁路桥墩及周围场地的振动特性,选取哈大(哈尔滨—大连)高速铁路沿线某桥墩及周围不同场地进行了现场测试,并利用相似分析定义了无量纲参数a/(v~2/L)(列车运行引起的场地加速度峰值a与列车速度v~2除以列车总长度L的比值)和R/L(场地到桥墩的距离R与列车总长度L的比值),同时结合数值模拟对不同场地在不同季节的振动衰减特性进行了分析。研究表明:桥墩与场地的振动特性明显不同,在桥墩两侧0.8 m范围内场地的振动特性不受冻结作用的影响;在堆积填土侧Y和Z方向的振动都出现了放大,而在未堆积人工填土侧仅Z方向的振动出现了放大;在冻结季振动衰减要小于非冻结季,且冻结作用对堆积填土侧振动的影响更加显著。     

高速列车移动震源地震记录

地球上的环境噪声作为被动震源已被用于地球内部结构研究,在地球科学与工程方面取得了良好的应用效果.随着人类活动频繁加剧,由移动交通工具产生的交通噪声,已经成为一种特别需要关注的环境噪声被动震源.高速运行列车产生的交通噪声,相比其他交通噪声能量强,连续稳定,并且具有可重复性,特别是近十几年来,中国高速铁路发展迅速,形成了覆盖中国大陆的高速铁路网络,为大范围、长期观测高速列车产生的交通噪声并研究其应用提供了基础.我们利用地震勘探检波器,分别采集高速列车运行产生的地震记录以及相同位置无高速列车运行的环境噪声,对地震记录信号以及环境噪声进行了频谱分析以及地震波干涉等处理.频谱分析结果显示,高速列车运行产生的地震信号能量约是环境噪声能量的10~3倍,而地震信号频率成分与高速列车运行速度相关.我们分别对高速列车运行产生的地震信号与环境噪声进行了地震波干涉处理,重建出地震初至波以及续至波信息,经过初步分析,重建的初至波地震波场揭示了地表地震波传播特征,而续至波波场十分复杂.高速列车作为一种移动被动震源产生的地震记录具有应用潜力.     

高速铁路运行引发场地振动的空沟隔振分析

为研究高速列车作用下,层状地基中空沟对场地振动的隔振效果,基于车辆-轨道耦合动力学理论及有限元法,对建立完善高速车辆-无砟轨道-地基耦合系统动力学模型进行仿真计算,分析设置空沟对场地振动的影响,并探讨了空沟的深度、位置、宽度以及列车速度的影响。结果表明：设置空沟加强了沟前场地的振动,但可使空沟后方地基的竖向和水平振动水平大幅减小,但在特定位置存在振动放大区,引起隔振效果减弱;过浅或过深的空沟均不能达到最优隔振效果;对于在线路旁需要特殊隔振的场地,存在一个适用于其本身的空沟最佳位置;空沟的宽度对隔振效果无明显影响;空沟对更高速度运行列车引起场地竖向和横向振动的隔振效果更明显。     

列车引起的地基土应力状态变化的三维有限元分析

将列车移动荷载简化为多个移动轮轴荷载,基于列车-轨道-路基解析模型推求的列车运行时不同时刻、不同位置时作用于路基的振动荷载时程,采用多点输入方式实现列车荷载的移动施加方式,建立路(地)基-场地体系三维有限元动力分析模型,基于Abaqus软件的并行计算集群平台,对轨道交通振动荷载下路(地)基-场地体系的动力反应进行数值模拟,研究了列车荷载作用线正下方地基中的动应力特征及土单元应力状态变化,分析了列车轮轴荷载移动过程中不同深度处土单元的应力路径和主应力轴的旋转。     

高速地铁列车竖向振动特性分析

高速地铁列车是一种运行速度可达160 km/h远高于普通地铁最高速度80 km/h的新型地铁列车。其车辆力学特性与高铁列车基本相同,其轨道运行条件与普速列车轨道运行条基本相同。地铁列车竖向振动影响列车上部结构供电及受力性能,目前高铁及普速列车在各自轨道上运行时列车的振动特性研究较为成熟,但高铁列车在普速铁路上运行时的振动特性的研究尚属空白。聚焦高速地铁列车在普速轨道上运行时的车辆振动特性,基于OpenSees软件建立普速及高速地铁列车的车-轮-轨二维有限元模型;利用我国普速轨道谱考虑其频谱特征随机生成20个440 m长轨道不平顺样本;通过有限元法分析了普速和高速地铁列车在不同运行速度及不同平顺程度下的竖向位移响应及统计参数,研究了高速及普速地铁列车竖向振动随运行速度的变化规律。研究表明：高速地铁列车与普速地铁列车的不平顺轨道振动远大于平顺轨道振动。高速列车与普速列车在竖向振动随速度变化特性上存在差异,高速列车的竖向振动位移幅值远小于普速列车,相较于普速列车振动更加稳定。     

季节冻土区冬季列车行驶路基振动反应研究

为了研究季节冻土区行驶列车引起的含冻土层铁路路基的振动反应特性,在大庆地区季节冻土场地进行了冬季现场试验。试验结果表明:列车行驶产生的路基振动加速度在近轨处具有周期性变化的特征,随着监测点距轨道距离的增大,其周期特性逐渐减弱并消失;季节冻土层的存在对路基竖向振动具有放大作用;列车行驶引起的路基振动加速度随与铁轨距离的增加而减小,并以竖向振动衰减最快;列车行驶过程中会引起环境振动问题,随着距铁轨距离的增大,垂向加速度振级呈递减趋势,时速越小则降幅越大,货车由于轴重大,衰减幅度低于普通客车。     

轨道附近地面振动模型中的饱和地层动力格林函数

列车引起场地振动的建模需要能够表达地层的动力格林函数.本文兼顾饱和土的流固两相耦合性、场地土的分层性和波动的三维传播性,构建了半解析的场地动力格林函数.首先,基于Biot方程,在傅里叶变换域求解固体骨架和流体的位移和应力.然后采用传递矩阵方法建立地表位移和应力间的关系,得到格林函数矩阵.进而讨论矩阵的一些固有特征,提出改善竖向位移计算效率的措施.最后利用推导的格林函数计算了几个典型算例.数值结果与文献中其他方法得到的结果十分接近,与场地振动的现场观测试验基本符合.软土场地振动的计算结果高于饱和砂土场地,高速列车场地振动强度高于低速列车.当车速接近场地瑞利波速,模拟结果中显示出马赫锥.数值结果还显示,即使车速略低于瑞利波速,马赫锥也可能出现.本文推导的格林函数将有助于深入理解列车等移动激励作用下层状饱和土场地的振动特征.     

地震频谱特性对高速列车车体振动的影响分析

为研究不同频谱特性的地震作用对高速列车振动的影响,本文建立31自由度的机车模型,利用三角级数法生成轨道不平顺。通过在水平、竖直两个方向输入不同频谱特性的三条地震波,主要从频域角度分析总结了不同车速和不同地震峰值加速度下车体的垂直和横向加速度。结果表明,地震对车体横向振动的影响大于垂向;地震动的低频成分居多时,会使得车体振动响应增大。地震峰值加速度对车体振动有较大影响且车速和地震峰值加速度共同控制车体的横向和垂向振动主频。列车运行时,若遇到卓越频率低且峰值加速度较大的地震激励。     

Prediction of high-speed train induced ground vibration based on train-track-ground system model

The development of analysis on train-induced ground vibration is briefly summarized. A train-track-ground integrated dynamic model is introduced in the paper to predict the ground vibration induced by high-speed trains. Representative dynamic responses of the train-track-ground system predicted by the model are presented. Some major results measured from two field tests on the ground vibration induced by two high-speed trains are reported. Numerical prediction with the proposed train-track-ground model is validated by the high-speed train running experiments. Research results show that the wheel/rail dynamic interaction caused by track irregularities has a significant influence on the ground acceleration and little influence on the ground displacement. The main frequencies of the ground vibration induced by high-speed trains are usually below 80 Hz. Compared with the ballasted track, the ballastless track structure can produce much larger train-induced ground vibration at frequencies above 40 Hz. The vertical ground vibration is much larger than the lateral and longitudinal components.     

Finite element analysis of structure-borne vibration from high-speed train

Finite element analyses were used to investigate the behavior of the building vibration induced by high-speed trains moving on bridges. The model includes the bridge, nearby building, soil and train. Finite element results indicate that trainload frequencies are more important than the natural frequencies of bridges and trains for building vibrations. If the building natural frequencies approach to the trainload frequencies, which equal an integer times the train speed over the compartment length, the resonance occurs and the building vibration will be large. Moreover, the vibration shape is similar to the mode shape of the resonance building frequency. To isolate the building vibration induced by moving trains, this paper investigates three common types of foundations, which include the extension of retaining walls, pile foundation and soil improvement around the building. Soil improvement around the building is the best way to reduce the building vibration both in horizontal and vertical directions.     

沪宁城际铁路高架桥段CRH动车组运行引起的地面振动现场测试与分析

对沪宁城际铁路CRH动车组运行引起的高架桥段地面振动竖向速度和加速度进行了现场测试,分析了地面振动特征及其传播的衰减规律。结果表明：CRH动车组运行引起的地面振动主频在70Hz以下,属于低频振动;地面振动峰值速度和加速度随着离高架桥距离的增大而减小,20m以内地面振动衰减幅度较大;地面振动峰值随列车时速的提高而增大,车厢数量对地面振动峰值和主频成分的影响不明显;CRH动车组运行引起的地面振动对一般性建筑物影响不大,列车时速为300km左右时,地面振动速度超过办公室等公共建筑的允许值,列车时速为200km左右时,地面振动速度超过居民住宅的允许值;与其他高速铁路的地面振动实测值相比,沪宁城际铁路CRH动车组运行引起的高架桥段地面振动强度相对较低。     

Experimental investigation into ground vibrations induced by very high speed trains on a non-ballasted track

A field measurement of ground vibration was performed on the Beijing−Shanghai high-speed railway in China. In this paper, the experimental results of vertical ground vibration accelerations induced by very high speed trains running over a non-ballasted track on embankment with speeds from 300 to 410 km/h are reported and analyzed in detail for the first time. Characteristics of ground vibration accelerations in both time and frequency domains are analyzed based on the test data. It is shown that the periodic exciting action of high-speed train bogies can be identified in time histories of vertical accelerations of the ground within the range of 50 m from the track centerline. The first dominant sensitive frequency of the ground vibration acceleration results from the wheelbase of the bogie, and the center distance of two neighboring cars plays an important role in the significant frequencies of the ground vibration acceleration. Variations of time–response peak value and frequency-weighted vertical acceleration level of ground vibration in relation with train speed as well as the distance from the track centerline are also investigated. Results show that the time-domain peak value of ground vibration acceleration exhibits an approximately linear upward tendency with the increase of train speed. With the increasing distance from the track centerline, the frequency-weighted vertical acceleration level of the ground vibration attenuates more slowly than the time-domain peak value of the ground vibration acceleration does. Severe impact of high-speed railway ground vibration on human body comfort on the ground occurs at the speed of 380–400 km/h. The results given in the paper are also valuable for validating the numerical prediction of train induced ground vibrations.     

高铁震源地震信号的稀疏化建模

我国每天有数千趟高铁列车运行在两万多公里的高铁线路上,不但会引起高铁路基的振动,还会激发出地震波.地震检波器所接收到的数据中不仅包含窄带分立谱特性的高铁震源地震信号,还包含宽频带特性的背景信号.如何实现从检波器所接收到的高铁震源地震数据中分离出高铁震源地震信号和宽频带背景信号是准确利用该类信号的关键.考虑到高铁震源地震信号与宽频带信号在频率域明显的形态特征差异,本文首次将形态成分分析这种信号分离手段引入到高铁震源地震信号处理中,实现高铁震源地震信号的稀疏化建模并进而实现从接收数据中分离出高铁震源地震信号以及宽频带背景信号.对北京大学在中国南方某高铁沿线采集到的大量高铁震源地震数据进行处理,结果表明:采用形态成分分析并结合分块坐标松弛算法,能够实现实际采集高铁震源地震数据中的高铁震源地震信号和宽频带信号的分离.     

Free field vibrations caused by high-speed lines: Measurement and time domain simulation

In recent years, the high-speed train (HST) network has developed considerably, unfortunately increasing vibration nuisances in its neighbourhood. This paper aims to present some vibration measurements collected on a Belgian site located between Brussels and Paris/London and travelled by the Thalys and Eurostar high-speed trains, and to compare them with the results obtained by a recently developed model, involving the compound vehicle/track/soil system. Assuming that the soil can be reasonably decoupled from the track, the approach first considers the train/track subsystem. The latter is studied by combining a multibody model of the vehicle with a finite element model of the track, both so far limited to the vertical motion. The ground forces given by this first simulation are then applied on a finite/infinite element model of the soil subsystem, where the infinite elements are placed on the border of the mesh in order to properly represent an unbounded domain. Both simulations are performed in the time domain, offering the opportunity to include non-linearities. The good correspondence between numerical and experimental results shows that the model is reliable for predicting the vibration produced by the high-speed vehicles. Finally, the paper presents some cases showing the importance of including the complete vehicle and the soil layering to the model.     

Prediction and mitigation analysis of ground vibration caused by running high-speed trains on rigid-frame viaducts

In this study a 3D numerical analysis approach is developed to predict the ground vibration around rigid-frame viaducts induced by running high-speed trains. The train-bridge-ground interaction system is divided into two subsystems: the train-bridge interaction and the soil-structure interaction. First, the analytical program to simulate bridge vibration with consideration of train-bridge interaction is developed to obtain the vibration reaction forces at the pier bottoms. The highspeed train is described by a multi-DOFs vibration system and the rigid-frame viaduct is modeled with 3D beam elements. Second, applying these vibration reaction forces as input external excitations, the ground vibration is simulated by using a general-purpose program that includes soil-structure interaction effects. The validity of the analytical procedure is confirmed by comparing analytical and experimental results. The characteristics of high-speed train-induced vibrations, including the location of predominant vibration, are clarified. Based on this information a proposed vibration countermeasure using steel strut and new barrier is found effective in reducing train-induced vibrations and it satisfies environmental vibration requirements. The vibration screening efficiency is evaluated by reduction VAL based on 1/3 octave band spectral analysis.     

轨道交通运行引起的场地振动实测研究现状

随着快速轨道交通的发展,轨道交通运行所带来的振动影响越来越严重,而已有的轨道交通运行引起的场地振动实测研究,大多集中在列车速度较低的情况下,已无法解决现行问题。本文通过对轨道交通运行引起的场地振动的现场测试进行评述,总结了目前该实测研究中存在的问题,提出尚需进一步研究的建议。今后的研究需综合分析各种因素对地面振动和地基动应力的影响,从而更好地控制振动,以便提出有效且经济的减振隔振措施,以期为该领域的深入研究提供一些建设性意见。     

Field vibration mitigation by honeycomb WIB for pile foundations of a high-speed train viaduct

Environmental vibrations from recent high-speed trains are becoming a special concern in the civil and environmental engineering field since they can give detrimental effects to residents, sensitive equipments and high-tech production facilities in the vicinity of train tacks. Herein, aiming at the vibration mitigation for a specific high-tech industrial area, the low-frequency vibrations from a train viaduct are targeted over an anticipated range. A theoretically designed innovative countermeasure, called honeycomb wave impeding barrier (WIB) for a wave impeding barrier, is introduced and its effects are investigated by computer simulation. The present WIB is based on the wave dispersion phenomenon that can modulate the incoming wavelengths into the shorter wavelengths, creating an apparent wave cut-off characteristic in the wave field across WIB installation area. The shorter wavelengths are further impeded due to the impedance ratio of the WIB walls and in-fill materials and absorbed by the in-fills more. The three-dimensional FEM simulation demonstrates a dramatic reduction effect that is difficult to achieve by conventional measures.