三维沥青路面多层体系的黏弹性力学分析

基于改进的无单元Galerkin方法(Improved Element-Free Galerkin,简称IEFG),建立了三维沥青路面多层体系的黏弹性力学模型。对交通荷载作用下沥青混凝土路面的位移及应力进行了计算,分析了不同的节点数及影响域比例参数对计算结果的影响,得到了沥青路面多层体系计算模型的合适节点数目和影响域比例参数的选择范围。同时,分析了中面层厚度对路面抗车辙性能的影响。结果表明:改进的无单元Galerkin方法在分析沥青路面黏弹性方面是有效的;节点数在1800以上、影响域比例参数在1.8～1.9之间取值时计算结果较好;中面层厚度越小,沥青路面车辙变形越大。本文结果可为沥青路面设计提供参考。     

沥青混合料车辙变形的离散元数值模拟

采用Burgers模型描述沥青基质的粘弹性,根据实验数据确定Burgers模型参数。借助数字图像处理方法建立试件几何模型,利用离散元法开展了车辙变形的离散元数值模拟,研究了沥青混合料在不同骨料分布、不同载荷和不同温度条件下的车辙深度变化情况。结果表明：温度对车辙变形的影响在沥青软化点附近较大,在离开软化点的范围较小;当温度较低时,混合料的整体性比较好,骨料分布对局部车辙变形的影响比较小,超载引起的车辙增量不太明显,而当温度达到或超过沥青软化点时,混合料的整体性明显下降,骨料分布对局部车辙变形的影响非常突出,超载引起的车辙增量也非常显著。因此,当超载和高温组合到一起时,车辙变形会大幅度增加,将给路面安全带来严重隐患。     

现场实测结构温度对半刚性沥青路面性能的影响

针对中国特色的半刚性基层沥青路面,在广韶高速公路瓮城段进行为期一个月高温期的现场温度观测。运用三维有限元方法,结合现场实测温度,分析了半刚性沥青路面结构的最大拉应力、最大剪应力和最大路表弯沉在荷载和荷载耦合作用下的变化情况。结果表明,随着路面深度增加,温度波动的幅度逐渐减小;路面内的最高温度相对大气和路表温度滞后约1小时;沥青路面内部温度高于表面温度;大气、路表和路面内部温度变化基本同步,温度波峰与波谷的出现频率相同;在温度和荷载综合作用下,路表以下2cm深度范围内易出现因拉应力不足造成的开裂破坏;路表以下10cm深度范围内,较易出现剪切破坏;高温温度场的存在虽不会明显增大路面结构各层的拉应力与剪应力,但会明显增大路表弯沉,故易产生车辙破坏。     

基于动量原理的大坡度沥青路面动水压力计算及影响因素分析Calculation and influence factors analysis for hydrodynamic pressure of asphalt pavement with large slope based on momentum theorem

在多雨地区长大纵坡沥青路面是雨天事故多发区域。应用动量定理,建立了沥青路面动水压力的力学计算模型,并系统分析了车辆荷载、行车速度和道路纵坡对动水压力的影响。结果表明,当水膜厚度＜3 mm时,动水压力随车速及车辆荷载的增大而增大,上坡时,动水压力随着纵坡坡度的增大而增大,下坡时,动水压力随着纵坡坡度的增大而减小。当水膜厚度＞3 mm时,动水压力随车速、车辆荷载增大而增大,上坡时,动水压力随着纵坡坡度的增大而增大,下坡时,动水压力随着纵坡坡度的增大呈先缓慢增加然后又缓慢减小的变化趋势;无论是上坡还是下坡,动水压力都随着车轮半径的增大而增大。本研究成果为多雨地区长大纵坡沥青路面重载交通高速行车易发生交通事故提供了理论分析依据。     

基于动量原理的大坡度沥青路面动水压力计算及影响因素分析

在多雨地区长大纵坡沥青路面是雨天事故多发区域。应用动量定理,建立了沥青路面动水压力的力学计算模型,并系统分析了车辆荷载、行车速度和道路纵坡对动水压力的影响。结果表明,当水膜厚度3mm时,动水压力随车速及车辆荷载的增大而增大,上坡时,动水压力随着纵坡坡度的增大而增大,下坡时,动水压力随着纵坡坡度的增大而减小。当水膜厚度3mm时,动水压力随车速、车辆荷载增大而增大,上坡时,动水压力随着纵坡坡度的增大而增大,下坡时,动水压力随着纵坡坡度的增大呈先缓慢增加然后又缓慢减小的变化趋势;无论是上坡还是下坡,动水压力都随着车轮半径的增大而增大。本研究成果为多雨地区长大纵坡沥青路面重载交通高速行车易发生交通事故提供了理论分析依据。     

旧路拓宽全过程三维有限元分析

旧路拓宽是西部山区高等级公路建设中的重要课题。运用岩土工程专业软件包P laxis 3D Tunnel,对旧路拓宽进行了全过程的三维弹塑性有限元数值模拟,包括新路基的填筑,路面各结构层的铺筑及轮载最不利位置的施加等,重点分析了新旧路基不均匀沉降变形及应力分布的规律,比较了拓宽方式、新老路基土模量差异对路面变形和使用寿命的影响,并就实际施工提出了一些建议。     

切应力对牛骨蠕变变形的影响研究

骨尤其是湿骨,在恒定载荷作用下会发生蠕变变形。为了确定切应力是否影响骨的蠕变变形,采用对骨薄板试样分别施加集中载荷和均布载荷的方式,测量试样挠度实时的变化曲线。结果显示,在载荷恒定时,骨试样的挠度随时间不断增加,体现了典型的蠕变特性。集中荷载下骨的蠕变变形远大于均布荷载下骨的蠕变变形,湿骨的蠕变位移比干骨高近7倍。分析认为,对试样粘弹性性质的影响不仅有正应力的作用,也有切应力的作用;切应力产生的蠕变变形约为正应力所产生蠕变变形的0.85倍。     

耦合路面损伤的车辆随机动荷载特性研究

为准确分析车辆对不平整路面作用的实际动荷载,在传统计算方法的基础上,进一步考虑了永久变形和平整度劣化等路面损伤累积的影响,提出了耦合损伤的车辆随机动荷载分析方法.通过计算轴载作用下路面各点的永久变形,推导路面不平整度的更新方程,将其引入车-路系统动力方程,采用Matlab编制求解程序,即可得到任意时间路面各点受到的车辆随机动荷载序列.基于该方法分析了车辆随机动荷载沿轮迹的分布变化,研究了随机动荷载系数随轴次的演化规律.结果 表明,车辆随机动荷载是随时间逐渐增大的动态演化过程,其沿轮迹的分布具有空间可重复性,随着轴载作用,动荷载的离散程度增大,将引起路面各点的损伤累积差异增大;而车辆行驶速度越低,新建路面越不平整,动荷载随时间演化速率越快,对路面造成的损伤越大.     

一种轿车车轮应力状态测量与分析方法

基于台架应变测试试验方法,研究轿车车轮在疲劳试验中的应力状态。结果表明:车轮的径向疲劳试验时,轮胎会对车轮的载荷产生较大的影响,轮胎与转鼓的挤压变形以及正反转动都会对车轮的应力状态产生影响;车轮径向疲劳试验时,最大应变出现在轮辋与轮胎接触位置沿车轮圆周方向,而在靠近轮心位置的应变较小;车轮弯曲疲劳试验时,最大应变出现在轮辐靠近轮心的位置,最大应变出现在轮辐的长度方向;不同的载荷对车轮应变的变化规律并没有影响,但是会对最大和最小峰值产生影响。     

低温荷载下沥青路面非线性疲劳损伤数值模拟

为了研究沥青路面结构在温度荷载作用下的疲劳损伤特性,运用通用有限元软件ABAQUS及其二次开发平台,建立了考虑路面材料非线性疲劳损伤的沥青路面结构数值计算模型。分析了沥青路面结构损伤、水平拉应力基于温度荷载重复作用,随空间与时间的变化规律,以及沥青路面裂纹形成寿命。结果表明:损伤主要分布在沥青面层;随着温变次数的增加,面层表面的损伤度呈线性增加;面层表面损伤度均随着面层模量与温变幅度的增加而增加;面层表面水平拉应力随着温度变化次数的增加,以线性特征逐步减小;面层表面水平拉应力随着面层模量与温变幅度的增加均是先增大后减小,有一个峰值点;沥青路面面层的温度型裂纹疲劳形成寿命与面层模量有关,模量越大,裂纹形成疲劳寿命越短,因此从温度疲劳寿命的角度来说,面层不宜选择模量过大的沥青混合料。     

柔性路面的各向异性疲劳损伤数值模型研究

根据柔性路面在交通荷载作用下的力学响应特点,推导了一个各向异性疲劳损伤本构方程,并基于ABAQUS软件及其二次开发平台,建立了考虑各向异性疲劳损伤的路面结构有限元模型。通过建立的模型计算车辆作用下路面结构的疲劳寿命,其结果与试验数据吻合良好,误差最高仅为3.8%,证明该模型精确可靠。最后,分析了疲劳损伤的演化规律,以及路面结构参数对疲劳性能的影响。结果表明,路面纵向疲劳损伤演化速率比横向大得多,随着车辆循环作用,路面结构的各向异性逐渐增强,进而又加剧疲劳损伤的演化。另外,沥青层越厚、土基弹性模量越大,路面疲劳损伤演化得越慢;而当土基较弱、沥青层较薄时,增加级配碎石层厚度可以显著延缓柔性路面的疲劳开裂。     

Slip-based experimental studies of a vehicle interacting with natural snowy terrain

As longitudinal slip affects vehicle–pavement interactions on roads and hard surfaces, so too does it play an important role in interactions between vehicles and soft terrains, including snow. Although many slip-based models have been developed recently for tire–snow interactions (e.g., [1] and references cited therein), these models have only been partially validated, due to a lack of relevant experimental data. This paper presents comprehensive data from tests that were performed using a newly-developed test vehicle traversing natural snowy terrain, over a wide range of values for longitudinal slip, vertical load and torque via an effective accelerate/brake maneuver. Drawbar pull, motion resistance, wheel states and tire stiffness were presented as a function of slip; tire sinkage was obtained using a laser profilometer; strength and depth of snow were found using a snow micropenetrometer. The effects of the rear tire going over snow compacted by the front tire were also studied. The maximum traction force normalized by the vertical load is found to be ≈0.47, maximum motion resistance normalized by the vertical load is ≈0.4. Comparison of the trend and order-of-magnitude of test results with those from existing slip-based numerical model [1] shows good comparison in motion resistance, tire sinkage, and longitudinal stiffness, but indicates that a better traction model is needed to improve the comparison.     

A high-fidelity approach for vehicle mobility simulation: Nonlinear finite element tires operating on granular material

Assessing the mobility of off-road vehicles is a complex task that most often falls back on semi-empirical approaches to quantifying the vehicle–terrain interaction. Herein, we concentrate on physics-based methodologies for wheeled vehicle mobility that factor in both tire flexibility and terrain deformation within a fully three-dimensional multibody system approach. We represent the tire based on the absolute nodal coordinate formulation (ANCF), a nonlinear finite element approach that captures multi-layered, orthotropic shell elements constrained to the wheel rim. The soil is modeled as a collection of discrete elements that interact through contact, friction, and cohesive forces. The resulting vehicle/tire/terrain interaction problem has several millions of degrees of freedom and is solved in an explicit co-simulation framework, built upon and now available in the open-source multi-physics package Chrono. The co-simulation infrastructure is developed using a Message Passing Interface (MPI) layer for inter-system communication and synchronization, with additional parallelism leveraged through a shared-memory paradigm. The formulation and software framework presented in this investigation are proposed for the analysis of the dynamics of off-road wheeled vehicle mobility. Its application is demonstrated by numerical sensitivity studies on available drawbar pull, terrain resistance, and sinkage with respect to parameters such as tire inflation pressure and soil cohesion. The influence of a rigid tire assumption on mobility is also discussed.     

用热光弹法研究路面裂缝稳定性问题

半刚性基层沥青路面在修建过程中,由于路表面气温的变化及其他因素的影响很容易产生裂纹,这就出现了在温度梯度作用下,路面开裂后是否稳定的问题.本文探讨用脆性断裂力学研究这些问题,研究结果表明,路面结构产生裂纹后,温变梯度作用是引起裂纹继续扩展的重要因素.     

Finite element modeling of interfacial forces and contact stresses of pneumatic tire on fresh snow for combined longitudinal and lateral slips

Significant challenges exist in the prediction of interaction forces generated from the interface between pneumatic tires and snow-covered terrains due to the highly non-linear nature of the properties of flexible tires, deformable snow cover and the contact mechanics at the interface of tire and snow. Operational conditions of tire-snow interaction are affected by many factors, especially interfacial slips, including longitudinal slip during braking or driving, lateral slip (slip angle) due to turning, and combined slip (longitudinal and lateral slips) due to brake-and-turn and drive-and-turn maneuvers, normal load applied on the wheel, friction coefficient at the interface and snow depth. This paper presents comprehensive three-dimensional finite element simulations of tire-snow interaction for low-strength snow under the full-range of controlled longitudinal and lateral slips for three vertical loads to gain significant mechanistic insight. The pneumatic tire was modeled using elastic, viscoelastic and hyperelastic material models; the snow was modeled using the modified Drucker-Prager Cap material model (MDPC). The traction, motion resistance, drawbar pull, tire sinkage, tire deflection, snow density, contact pressure and contact shear stresses were obtained as a function of longitudinal slip and lateral slip. Wheel states - braked, towed, driven, self-propelled, and driving - have been identified and serve as key classifiers of discernable patterns in tire-snow interaction such as zones of contact shear stresses. The predicted results can be applied to analytical deterministic and stochastic modeling of tire-snow interaction.     

多亚层柔性节点模型及其在双材料4ENF试件界面分析中的应用

提出了多亚层柔性节点模型用于分析双材料裂纹尖端的应力和变形。该模型考虑了胶层的变形,各亚层视为独立的剪切变形梁,采用两个界面柔度系数考虑界面应力对各亚层界面变形的影响,界面变形包括双材料界面和胶层的变形。通过对FRP-混凝土末端切口四点弯试件(Four-point bending end-notched flexure specimen,简称4ENF)进行界面分析,并与其他模型和有限元分析对比表明:刚性节点模型忽略了裂纹尖端的应力和变形集中,只能粗略地估计构件的整体变形和界面应力;半刚性节点容许裂纹尖端的转动,对裂纹尖端的变形估计优于刚性节点模型,但精度依然不高;多亚层柔性节点模型反映了裂纹尖端的应力和变形集中,与数值分析结果吻合很好,该研究对进行双材料结构的工程设计具有理论指导和参考价值。