Advancements and Applications of Polyurethane Curing Technology in Railway Track Bed Construction in China

This paper examines the application of polyurethane curing technology in the construction of railway track beds,with a specific focus on its implementation in China’s rapidly developing railway infrastructure.The study begins by identifying the limitations of traditional ballasted track beds,especially under the demands of high-speed and heavyload railways.It then methodically analyzes the advantages of polyurethane-cured track beds,highlighting their improved mechanical properties,including enhanced stability and durability.The paper further explores the benefits of transitioning to prefabricated polyurethane track beds,emphasizing significant cost reductions,better construction quality,and enhanced maintainability.Through a detailed review of experimental data and practical applications,the paper demonstrates the efficacy of polyurethane track beds in various railway settings.A critical part of the research involves optimizing the structural parameters of polyurethane track beds to achieve the best balance of mechanical and damping properties.The conclusion of the paper underscores the potential of polyurethane curing technology as a transformative approach to railway track bed construction,offering a solution to the challenges posed by traditional methods and aligning with the evolving needs of modern railways.

Influence of the Randomness of Longitudinal Resistance of Ballast Bed on Track-Bridge Interaction

To get the influence of the randomness of longitudinal resistance of ballast bed (LRBB) on track-bridge interaction, the statistical law of LRBB was studied with existing test data and the Shapiro-Wilk test. Based on the principle of track-bridge interaction, a rail-sleeper-bridge-pier integrated simulation model that could consider the randomness of LRBB was established. Taking a continuous beam bridge for the heavy-haul railway as an example, the effect of the randomness of LRBB on the mechanical behavior of continuous welded rail (CWR) on bridges under typical conditions was carefully examined with a random sampling method and the simulation model. The results show that the LRBB corresponding sleeper displacement of 2 mm obeys a normal distribution. When the randomness of LRBB is considered, the amplitudes of rail expansion force, rail bending force, rail braking force and rail broken gap all follow normal distribution. As the standard deviations of the four indexes are small, which indicates the randomness of LRBB has little effect on track-bridge interaction. The distributions of the four indexes make it possible to design CWR on bridges with the limit state method.

Incompatible thermal deformation of interlayers and corresponding damage mechanism of high-speed railway track structure

In the service period,the instability of ballastless track bed are mostly related to the damage of interlayers which are mainly resulted from the incompatible thermal deformation of interlayers.The temperature field within the ballastless track bed shows significant non-uniformity due to the large difference in the materials of various structure layers,leading to a considerable difference in the force bearing of different structure layers.Unit Ballastless Track Bed(UBTB)is most significantly affected by temperature gradient.The thermal deformation of interlayers within UBTB follows the trend of ellipsoid-shape buckling under the effect of the temperature gradient,resulting in a variation of the contact relationship between structure layers and a significant periodic irregularity on the rail.When the train travels on the periodically irregular rail,the structure layers are locally contacted,and the contact zone moves with the variation of the wheel position.This wheel-followed local contact greatly magnifies the interlayer stress,causes interlayer damage,and leads to a considerable increase in the bending moment of the track slab.Continuous Ballastless Track Bed(CBTB)is most significantly affected by the overall temperature variation,which may cause damage to the joint in CBTB.Under the combined action of the overall temperature rise and the temperature gradient,the interlayer damage continuously expands,resulting in bonding failure between structural layers.The thermal force in the continuous track slabs will cause the up-heave buckling and the sudden large deformation of the track slab,and the loss of constraint boundary of the horizontal stability.For the design of a ballastless track structure,the change of bearing status and structural damage related to the incompatible thermal deformation of interlayers should be considered.

Impact of train speed on the mechanical behaviours of track-bed materials

For the 30,000 km long French conventional railway lines(94% of the whole network),the train speed is currently limited to 220 km/h,whilst the speed is 320 km/h for the 1800 km long high-speed lines.Nowadays,there is a growing need to improve the services by increasing the speed limit for the conventional lines.This paper aims at studying the influence of train speed on the mechanical behaviours of track-bed materials based on field monitoring data.Emphasis is put on the behaviours of interlayer and subgrade soils.The selected experimental site is located in Vierzon,France.Several sensors including accelerometers and soil pressure gauges were installed at different depths.The vertical strains of different layers can be obtained by integrating the records of accelerometers installed at different trackbed depths.The experimentation was carried out using an intercity test train running at different speeds from 60 km/h to 200 km/h.This test train was composed of a locomotive(22.5 Mg/axle) and 7 'Corail'coaches(10.5 Mg/axle).It was observed that when the train speed was raised,the loadings transmitted to the track-bed increased.Moreover,the response of the track-bed materials was amplified by the speed rise at different depths:the vertical dynamic stress was increased by about 10% when the train speed was raised from 60 km/h to 200 km/h for the locomotive loading,and the vertical strains doubled their quasistatic values in the shallow layers.Moreover,the stressestrain paths were estimated using the vertical stress and strain for each train speed.These loading paths allowed the resilient modulus Mrto be determined.It was found that the resilient modulus(M_r) was decreased by about 10% when the train speed was increased from 100 km/h to 200 km/h.However,the damping ratio(D_r) kept stable in the range of speeds explored.

运营地铁盾构隧道基底沉降的影响因素分析

隧道基底沉降不仅影响地铁列车的正常运行和乘客的舒适性,严重时会造成隧道结构病害,目前的研究主要集中在长期沉降预测和单因素影响分析,非常有必要开展隧道基底沉降的多影响因素分析。以郑州地铁1号线某盾构隧道区间为工程实例,构建三维有限元数值模型,采用人工激振力模拟地铁列车竖向荷载,提取数值模拟结果的动应力和静偏应力数据,引入循环荷载作用下累积塑性应变计算公式,采用分层总和法计算得到隧道基底沉降,研究了隧道周围土层性质、道床脱空深度和地铁列车运行速度等因素对隧道基底沉降的影响,研究结果表明:数值模拟的隧道基底沉降和发展规律与现场实测结果具有较高的吻合度,验证了有限元模拟的准确性;隧道基底沉降随着周围土层砂粒含量的提高而减小;道床脱空尺寸会加剧隧道和道床板中应力集中和振动放大现象,增大隧道下卧土层的动偏应力和基底沉降;提高车速会增大基底沉降的横向影响范围;采用正交试验法、极差分析法和方差分析法得到了隧道沉降对各因素的敏感性,从大到小依次为:土层性质、车速和道床脱空,其中,土层性质为高度显著水平、车速为显著水平。研究成果对运营地铁盾构隧道的变形监测、安全评估和加固处理具有一定的参考价值。

基于准动态评估的桥上有砟轨道最优级配研究

道砟级配是有砟轨道的重要参数,对桥上有砟道床准动态稳定性和容重有较大影响。通过离散元法建立桥上有砟道床模型,研究各国级配下道床准动态稳定性差异;采用极限思维法,揭示各粒径含量对桥上有砟道床准动态稳定性的影响程度,并对道床容重特性进行初探。结果表明:当桥上道床密度为1.7 g/cm~3时,道床横向阻力值为:俄罗斯B类>中国特级>中国一级>美国4A;大粒径道砟含量越高,道床横向阻力值越大;小粒径道砟含量增加,道床横向阻力值先减小后略有增大;为保证道床具有较高稳定性,建议小粒径道砟含量应大于0但不超过30%,中粒径道砟含量应不为0,大粒径道砟含量应不低于15.5%;采用最优级配区间所建立的桥上有砟道床具有工程上所青睐的道床容重特性。

地铁连续刚构桥上无砟轨道无缝线路纵向力分析

【目的】为研究地铁连续刚构桥上无砟轨道无缝线路纵向受力与变形规律,对地铁连续刚构桥上无砟轨道无缝线路设计改进、运营养护维修提供理论指导。【方法】根据梁-板-轨相互作用原理,建立地铁连续刚构桥上整体道床式无砟轨道无缝线路空间耦合模型,计算伸缩、挠曲、制动、断轨工况下轨道结构和桥梁纵向力及位移,并对轨道结构静力特性进行对比分析,为地铁连续刚构桥上无缝线路轨道结构设计提供参考。【结果】结果表明:双线列车荷载中点与中部梁端处重合时为列车垂向荷载最不利工况,此时钢轨纵向力与钢轨、桥梁纵向位移均为最大,均出现在中部梁端附近,数值分别为70.3 kN与0.6,0.8 mm;双线制动荷载列车尾部位于两侧梁端时为列车制动荷载最不利工况,此时钢轨纵向力与钢轨、桥梁纵向位移均为最大,数值分别为107.8 kN与1.6,1.7 mm。【结论】伸缩力作用下各个端部桥缝处为薄弱部位,在平时养护中应特别注意梁端部桥缝处轨道结构,防止因伸缩力过大而产生断轨;钢轨发生断轨时,在断缝处纵向力、纵向位移均发生突变,严重影响线路行车安全。

力稳定车稳定装置-有砟轨道耦合系统动力学特性研究

提出了一种针对动力稳定车作业过程动力学响应分析的稳定装置-轨排-道床耦合动力学模型。参照铁路行业标准设定了5种道床状态,基于ADAMS建立了虚拟样机仿真模型。系统地讨论了道床状态和作业参数对耦合系统横向振动响应的影响效果,以及各研究对象间的相互作用关系。研究结果表明:在5种道床范围内,系统共振频率随道床状态参数提升而增大;垂向下压力与系统振动响应幅值呈线性负相关,且其对振幅的影响效果显著低于激振频率;稳定装置与轨枕的横向加速度、速度和位移振幅相近,显著大于道床振幅,激振器振动能量主要为道床吸收;2级道床状态下,稳定作业过程中,自第3号响应输出点起,轨枕和道床块的各响应参数振幅急剧减小。

三枕捣固作业过程中道砟细观运动及能量演变分析

使用大型捣固车对有砟轨道进行作业,是改善道床质量状态最有效方法和通用手段,是保障列车安全运营的必然选择。但我国大型养路机械源于引进国外技术,对捣固车捣固作业机理认识不足,无法进行科学养护维修。为加深对目前铁路养修作业中常用DWL-48捣固稳定车的三枕捣固装置作业过程的认识,该文借助离散元与多体动力学协同仿真分析方法,建立了三枕捣固装置-轨排-有砟道床三维空间精细化耦合仿真模型,并结合现场实测结果验证了模型的正确性,分析了捣固作业动态过程中道砟颗粒平动、转动特性及能量演变规律。研究结果表明:捣镐对道砟颗粒平动、转动和能量的影响主要位于枕下0 mm~175 mm区域;道砟颗粒速度与角速度变化规律具有很好的同步性,有助于快速填充枕下空隙。捣固作业过程中捣镐采用“道砟平动为主,转动为辅”的方式填充枕下空隙,并且在该过程中伴随着道砟颗粒平动动能、旋转动能逐渐向道砟颗粒势能的不断演变。

重载铁路钢轨焊接不平顺对道床动力特性的影响

在车轮反复碾压作用下,钢轨接头区域易出现马鞍形不平顺、低塌等缺陷。为分析重载铁路钢轨焊接不平顺对有砟道床动力特性的影响,首先建立车辆-轨道耦合动力学模型,计算钢轨焊接不平顺影响下的轨枕上动压力;然后采用离散元分析方法,建立有砟轨道结构二维模型,将焊接不平顺影响下的轨枕上动压力作为荷载输入,模拟分析钢轨焊接不平顺对有砟轨道结构道床动力特性的影响。结果表明:钢轨焊接不平顺显著增加了接头两侧轨枕上动压力,且不平顺短波波长越长,影响范围越大,当波长为0.2 m、波深为0.7 mm时,接头两侧轨枕上动压力增加显著,最大值相较于随机不平顺时增加了50.52%;随着焊接不平顺短波波长的减小及波深的增加,道床垂向加速度、摩擦耗能以及累积变形均随之增加;道砟颗粒间最大接触力受焊接不平顺影响较为显著,尤其当短波波深大于0.5 mm时,最大接触力随波深增加而显著增大;当短波波长为0.1 m、波深为0.7 mm时,相较于随机不平顺,道床应力增加55.89%,距道床顶面0.15 m深度处的道砟颗粒加速度增加了449.42%。

地铁隧道道床沉降整治研究

在软弱地层条件下,临近地铁的新建工程会引起地铁隧道位移,进而引起道床沉降、改变道床线型、影响行车安全。为研究整治这一类地铁道床结构病害,文中结合某地铁工程的实际案例,通过多方案比选,选定原位浇筑薄支墩法,并通过理论计算、调整临时支撑间距来减少整治工程量,在实现安全的、不中断运营效果的同时,也快速地完成了整治隧道结构沉降带来的道床线形病害问题,可为同类型道床病害处理提供借鉴与参考。

基于轨道质量指数的地铁预制板道床动态精调施工技术研究

为保证地铁运营的舒适性,以深圳地铁16号线预制板轨道工程为例,围绕铁路轨道质量指数(TQI)开展了一系列调整与优化过程研究,并建立了相对完备的参数标准、数据采集、分析处理及优化调整技术体系,显著提高了焊轨后区间无缝线路的平顺度,有效解决了地铁轨道工程中因铺设预制轨道板、25m标准轨排导致的整体轨道不平顺。结合工程实例对TQI在城市轨道交通结构施工中的应用重难点问题进行了分析。

城际铁路曲线地段梯形轨枕有砟轨道动力性能分析

围绕梯形轨枕有砟轨道在城际铁路中适应性问题,测试城际列车以80~176 km/h通过半径为1432 m曲线地段时梯形轨枕有砟轨道系统动力性能指标,对比梯形轨枕有砟轨道和普通Ⅲ型枕动力性能。运用车辆与轨道动力相互作用原理和有限元方法建立曲线地段梯形轨枕有砟轨道动力学模型,进一步评估城际列车以不同速度通过时的行车安全性及舒适性。研究结果表明:(1)列车实际通过曲线地段梯形轨枕有砟轨道时的安全性和轨道结构稳定性均满足规范要求;(2)梯形轨枕有砟轨道较普通Ⅲ型枕有更良好的减振性能,车速从80提高至176 km/h时,减振效果从8.3降低至6.2 dB;(3)考虑道床横向阻力非线性特性的车辆与轨道动力相互作用分析表明,随着车速增大,梯形轨枕有砟轨道动力响应增大,列车运行安全性和舒适性均降低,但仍满足规范要求,其中车辆与轨道的横向动力响应受车速影响更为明显。

新型钢岔枕结构设计及力学特性研究

首先介绍钢岔枕的应用和研究情况,提出既有钢岔枕在应用过程中存在的系列问题,并设计一种整体铸造形式的新型钢岔枕。新型钢岔枕材料采用QT400-18,其断面尺寸与普通混凝土岔枕相当,不影响大机捣固。其次,计算并提出一种新型钢岔枕,主振频率分别为127.4 Hz和130.9 Hz的扭转振动模态和主振频率为169.7 Hz的弯曲振动模态,其他高频振动模态主要来源于其侧壁顶部自由端的振动变形。最后,为研究新型钢岔枕在实际应用中的受力和变形特性,利用有限元法,建立新型钢岔枕在实际应用中的静力学模型,以此为基础,研究列车轴重、通过速度和钢岔枕下道床刚度取值对其自身受力情况和竖向位移量值的影响。经计算:新型钢岔枕强度满足要求,自身变形较小;当列车轴重为17 t、通过速度为80 km/h时,新型钢岔枕最大等效应力为64.4 MPa,轨头顶面最大竖向位移为1.42 mm,新型钢岔枕最大竖向位移为1.36 mm;仅提高速度至120 km/h时,新型钢岔枕受力增加16.7%,位移指标增加16.2%;仅提高列车轴重至29 t时,新型钢岔枕受力增加71.3%,位移指标增加71.1%;当底部道床刚度增加1倍时,新型钢岔枕受力增加22.5%,位移指标降低12.7%。

零距离暗挖下穿既有车站控沉效果研究

研究目的:新建地铁车站换乘节点的施工不可避免地会对既有线的运营造成影响。本文通过列举新建车站零距离暗挖下穿既有线的案例,通过数值模拟,对比不同方案下的沉降影响分析,从而得出可靠的设计施工方案。研究结论:(1)按常规设计方案,先施工既有车站结构两侧主体结构,并在衔接处预留后浇带,暗挖完成后再进行后浇带施工,通过数值分析可以发现,下穿段施工过程中,对既有车站结构竖向变形影响相对显著,既有车站道床隆起,车站底板发生不均匀沉降,最大沉降值约2.1 mm,超过规范预警值,存在一定的安全风险;(2)针对传统连接做法,提出了零距离下穿既有车站暗挖施工托举法施工理念,直接将新建结构与既有结构连成整体,从而形成暗挖段施工过程的新建结构对既有结构的托举体系,通过数值分析,托举法施工结束后,既有车站道床沉降可减小50%,控沉效果显著;(3)本研究成果可为新建工程暗挖下穿既有工程提供指导。

列车轴质量和土工格室加固道砟对路基沉降的影响

建立有砟轨道-路基三维有限元模型和土工格室模型,利用相位荷载模拟列车动荷载,研究列车轴质量和土工格室加固道砟对路基沉降的影响。模拟结果表明:在正弦相位荷载作用下,各轨枕之间位移变化基本一致;随着列车轴质量的增加,有砟轨道沉降显著增加;铺设土工格室加固后,有砟轨道的侧向位移和竖向沉降分别降低了约60%和11%;在重载情况下,土工格室加固效率有所降低,但改变土工格室刚度可以改变其加固效率;当土工格室刚度在400~800 MPa时,对重载路基的加固效果较好。

隧道内道床机械化清筛作业有害气体组成分布监测方法

针对采用柴油发动机为动力的既有工电检修装备在隧道内施工时尾气监测难题,选取典型的隧道内道床机械化清筛作业编组开展了测试。提出了以发动机附近定点检测为主,司机室和地面人员个体监测为辅的一体化有害气体监测方法,用于对隧道内的一氧化碳等致命性有害气体含量进行监测,超过安全标准值时发出声、光、电报警提示,以便及时采取应对措施。试验表明,该方法可以有效监测整个隧道机械化施工作业过程中重要点位的一氧化碳等有害气体的质量浓度变化,此外也能为发动机尾气净化装置、通风排烟排尘设施的研制提供技术支撑。

无缝线路施工期间道床刚度对速度的影响分析

为了解决因施工线路道床密实度不足导致的列车提速受限问题,依托国外某工程轨排成组铺设焊连无缝线路施工方案,建立了车辆-轨道耦合动力学模型。以轮轨动态作用指标及行车安全评价指标为评价依据,研究道床刚度和列车速度对钢轨接头动力响应的影响,确定施工线路合理的道床刚度及其速度阈值。结果表明:钢轨接头区的轮轨垂向力、钢轨和轨枕垂向加速度及行车安全评价指标受列车行车速度的影响较大,钢轨和轨枕的垂向位移受道床刚度影响较大;依据各指标的容许限值,应将施工期间的道床刚度控制在35~65 kN/mm;平车满载时的速度阈值显著高于空载时的速度阈值,合理道床刚度下平车满载及空载情况下速度最小值分别为53 km/h和23 km/h。研究结果对提高无缝线路施工效率,确保工程列车行车安全具有重要意义。

重载铁路有砟道床捣固作业参数的合理取值

根据朔黄铁路(朔州—黄骅)大型养路机械捣固作业实际情况,建立捣镐群和有砟道床的耦合模型,模拟大型养路机械捣固作业,分析捣固参数(捣镐振动频率、插镐速度、插镐深度)对道床密实度、道砟配位数、道床垂向刚度的影响,进而确定捣固参数的合理取值。结果表明:与捣固前相比,捣固后道床状态参数有所增加,道床密实度增幅在11.34%~13.21%,道砟配位数增幅在0.72%~4.34%,道床垂向刚度增幅在6.56%~64.27%,说明在一定范围内改变捣固参数对道床密实度和道床垂向刚度的影响比较明显,而对道砟配位数的影响不大;捣镐振动频率、插镐速度、插镐深度均主要影响道床垂向刚度;朔黄铁路捣固作业参数的合理取值为捣镐振动频率35 Hz,插镐速度1.0 m/s,插镐深度25 mm。