冰区航行船舶推进轴系扭转振动研究

本文以低速柴油机船舶推进轴系为研究对象,在对4叶螺旋桨单片桨叶与冰块相互作用激励力矩时域曲线基础之上,得到螺旋桨与冰块作用的总激励力矩时域曲线和频域曲线；采用集总参数法和系统矩阵法分别构建轴系振动模型和振动方程,对未考虑冰载荷和考虑冰载荷激励力矩作用下进行了轴系振动理论计算；同时通过实船测试验证了未考虑冰载荷激励力矩作用时振动数学模型和理论分析方法的正确性,对降低船舶轴系振动和提高船舶安全性具有一定的理论指导意义。     

基于数据驱动的隧道地质信息精细化管理系统研发与应用

针对现阶段隧道超前地质预报系统管理粗放、数据利用率低等问题，结合数据驱动原理重塑业务逻辑，研发新的隧道地质信息系统TGIS。通过高度集成隧道勘察设计阶段地质、施工阶段超前预报地质及掌子面开挖揭示地质，实现基于数据驱动的预报方法优选、临近预报提醒、分级实时预警与有效处置、掌子面自动素描、预报成果辅助判识等功能，达到隧道地质信息精细化管理的目的。经现场使用表明： 基于数据驱动的隧道地质信息精细化管理系统界面友好、运行稳定、效果良好，各项功能达到设计要求，相对于传统超前地质预报系统具有明显的优势，可普遍服务于隧道建设。     

浅埋隧道爆破施工中邻近框架结构的振动响应分析

为研究隧道爆破作用下邻近框架结构的振动响应机制，以某5层框架结构住宅楼为例，借助ANSYS/LS-DYNA建立基于隧道爆破-围岩-框架结构的三维耦合数值计算模型，分析隧道爆破施工中邻近框架结构的振动响应。研究结果表明： 数值模拟清晰地展示了隧道爆破作用下围岩和框架结构应力场、位移场的变化情况，给出了爆破振动波从围岩至框架结构的传播过程。通过对比实测测点与数值模拟中对应测点的振动速度时程曲线和频率分布，验证了数值模拟方法的可靠性。在隧道爆破作用下，邻近框架结构梁、柱以及外墙等构件的振动响应并不一致，随结构高度呈现出不同的变化规律。此外，应力集中现象主要发生在建筑物底层外墙、外墙与柱结合处、外墙与梁结合处以及外墙与楼板结合处等非承重部位，表明这些部位更易在隧道爆破过程中发生损伤开裂。     

Vertical random vibration analysis of vehicle–track coupled system using Green's function method

A vertical vehicle–track coupled dynamic model, consisting of a high-speed train on a continuously supported rail, is established in the frequency-domain. The solution is obtained efficiently by use of the Green's function method, which can determine the vibration response over a wide range of frequency without any limitations due to modal truncation. Moreover, real track irregularity spectra can be used conveniently as input. The effect of the flexibility of both track and car body on the entire vehicle–track coupled dynamic response is investigated. A multi-body model of a vehicle with either rigid or flexible car body is defined running on three kinds of track: a rigid rail, a track stiffness model and a Timoshenko beam model. The results show that neglecting the track flexibility leads to an overestimation of both the contact force and the whole vehicle vibration response. The car body flexibility affects the ride quality of the vehicle and the coupling through the track and can be significant in certain frequency ranges. Finally, the effect of railpad and ballast stiffness on the vehicle–track coupled vibration is analysed, indicating that the stiffness of the railpad has an influence on the system in a higher frequency range than the ballast.     

Dynamic model for the wheel–rail contact friction

Accurately estimating the coefficient of friction (CoF) is essential in modelling railroad dynamics, reducing maintenance costs, and increasing safety in rail operations. The typical assumption of a constant CoF is widely used in theoretical studies; however, it has been noticed that the CoF is not constant, but rather depends on various dynamic parameters and instantaneous conditions. In this paper, we present a newly developed three-dimensional nonlinear CoF model for the dry rail condition and test the CoF variation using this model with estimated dynamic parameters. The wheel–rail is modelled as a mass–spring–damper system to simulate the basic wheel–rail dynamics. Although relatively simple, this model is considered sufficient for the purpose of this study. Simulations are performed at a train speed of 20 m/s using rail roughness as an excitation source. The model captures the CoF extremes and illustrates its nonlinear behaviour and instantaneous dependence on several structural and dynamic parameters.     

Investigation of the effects of sleeper-passing impacts on the high-speed train

The sleeper-passing impact has always been considered negligible in normal conditions, while the experimental data obtained from a High-speed train in a cold weather expressed significant sleeper-passing impacts on the axle box, bogie frame and car body. Therefore, in this study, a vertical coupled vehicle/track dynamic model was developed to investigate the sleeper-passing impacts and its effects on the dynamic performance of the high-speed train. In the model, the dynamic model of vehicle is established with 10 degrees of freedom. The track model is formulated with two rails supported on the discrete supports through the finite element method. The contact forces between the wheel and rail are estimated using the non-linear Hertz contact theory. The parametric studies are conducted to analyse effects of both the vehicle speeds and the discrete support stiffness on the sleeper-passing impacts. The results show that the sleeper-passing impacts become extremely significant with the increased support stiffness of track, especially when the frequencies of sleeper-passing impacts approach to the resonance frequencies of wheel/track system. The damping of primary suspension can effectively lower the magnitude of impacts in the resonance speed ranges, but has little effect on other speed ranges. Finally, a more comprehensively coupled vehicle/track dynamic model integrating with a flexible wheel set is developed to discuss the sleeper-passing-induced flexible vibration of wheel set.     

水泥混凝土路面翘曲脱空与面板破坏原因分析

文章针对广西近年来水泥混凝土路面翘曲脱空与面板破坏的情况，分析产生病害的原因，介绍采用有限元程序对翘曲脱空后的路面在荷载作用下的受力进行计算的方法，对翘曲脱空后的路面寿命进行预估，同时提出翘曲脱空的防治对策。     

基于深度学习的破碎带盾构施工沉降预测分析

为进一步提高复杂地层条件下盾构沉降预测的准确性，以广州地铁7号线1期工程谢村站-钟村站区间盾构工程为依托，针对破碎带盾构隧道沉降控制难题，提出基于深度学习的人工智能预测模型。通过分析开挖面破碎带分布规律，确定将破碎带面积比作为地层特性参数。采用相关系数矩阵分析不同施工参数与破碎带面积比的相关性，确定采用刀盘转矩代表破碎带面积比实时描述地层分布特性。以刀盘转矩、盾尾间隙与注浆量作为输入值，地面沉降作为输出值训练深度学习模型，并利用训练后的深度学习模型进行沉降预测分析。通过分析预测结果与沉降实测值的对比验证预测模型的有效性。     

综合勘察与超前地质预报技术在兰渝铁路长寿山隧道中的应用研究

长寿山隧道为特长隧道,其工程规模大,埋深大,需勘察范围广,地形地质条件十分复杂,为了详细查清隧道的工程地质与水文地质条件,并及时对地质勘察资料进行补充和完善,指导并保证隧道施工的安全顺利进行,通过在勘察阶段采用遥感、大面积地质调绘、物探、钻探、综合试验、测试相结合的地质综合勘察技术,在施工阶段,采用地质编录、TSP、地质雷达、红外探测、超前水平钻探等相结合的综合地质超前预报技术,提高勘察效率及质量,补充地质资料、指导及保证安全施工,取得很好的效果。实践证明,山区长大、深埋、地形地质复杂隧道,在勘察及施工阶段分别采用综合勘察与地质超前预报技术,其方法是必要、合理、恰当的。     

Influence of some vehicle and track parameters on the environmental vibrations induced by railway traffic

A study is performed on the influence of some typical railway vehicle and track parameters on the level of ground vibrations induced in the neighbourhood. The results are obtained from a previously validated simulation framework considering in a first step the vehicle/track subsystem and, in a second step, the response of the soil to the forces resulting from the first analysis. The vehicle is reduced to a simple vertical 3-dof model, corresponding to the superposition of the wheelset, the bogie and the car body. The rail is modelled as a succession of beam elements elastically supported by the sleepers, lying themselves on a flexible foundation representing the ballast and the subgrade. The connection between the wheels and the rails is realised through a non-linear Hertzian contact. The soil motion is obtained from a finite/infinite element model. The investigated vehicle parameters are its type (urban, high speed, freight, etc.) and its speed. For the track, the rail flexural stiffness, the railpad stiffness, the spacing between sleepers and the rail and sleeper masses are considered. In all cases, the parameter value range is defined from a bibliographic browsing. At the end, the paper proposes a table summarising the influence of each studied parameter on three indicators: the vehicle acceleration, the rail velocity and the soil velocity. It namely turns out that the vehicle has a serious influence on the vibration level and should be considered in prediction models.