Changes in fuel economy: An analysis of the Spanish car market

This paper estimates the role that technological change and car characteristics have played in the rate of fuel consumption of vehicles over time. Using data from the Spanish car market from 1988 to 2013, we estimate a reduced form equation that relates fuel consumption with a set of car characteristics. The results for the sales-weighted sample of vehicles show that energy efficiency would have improved by 30% and 42% for petrol and diesel cars respectively had car characteristics been held constant at 1988 values. However, the shift to bigger and more fuel-consuming cars reduced the gains from technological progress. Additionally, using the results of the fuel equation we show that, besides a natural growth rate of 1.1%, technological progress is affected by both the international price of oil and the adoption of mandatory emission standards. Moreover, according to our estimations, a 1% growth in GDP would modify car characteristics in such a way that fuel consumption would increase by around 0.23% for petrol cars and 0.35% for diesel cars.     

Driving cycle prediction model based on bus route features

Bus fuel economy is deeply influenced by the driving cycles, which vary for different route conditions. Buses optimized for a standard driving cycle are not necessarily suitable for actual driving conditions, and, therefore, it is critical to predict the driving cycles based on the route conditions. To conveniently predict representative driving cycles of special bus routes, this paper proposed a prediction model based on bus route features, which supports bus optimization. The relations between 27 inter-station characteristics and bus fuel economy were analyzed. According to the analysis, five inter-station route characteristics were abstracted to represent the bus route features, and four inter-station driving characteristics were abstracted to represent the driving cycle features between bus stations. Inter-station driving characteristic equations were established based on the multiple linear regression, reflecting the linear relationships between the five inter-station route characteristics and the four inter-station driving characteristics. Using kinematic segment classification, a basic driving cycle database was established, including 4704 different transmission matrices. Based on the inter-station driving characteristic equations and the basic driving cycle database, the driving cycle prediction model was developed, generating drive cycles by the iterative Markov chain for the assigned bus lines. The model was finally validated by more than 2 years of acquired data. The experimental results show that the predicted driving cycle is consistent with the historical average velocity profile, and the prediction similarity is 78.69%. The proposed model can be an effective way for the driving cycle prediction of bus routes.     

铁路路基动态变形模量的数值模拟分析

介绍铁路路基动态变形模量理论计算公式的推导及动态变形模量的测试原理,采用有限元软件模拟动态变形模量的测试过程,分析承载板与土体接触压力、路基动态变形模量的影响因素,并计算动态变形模量的有效测试深度.结果表明:在承载板中心一定范围内,接触压力模拟结果较理论计算值大;土体的动弹性模量对接触压力影响很小,可以忽略;路基动态变形模量测试冲击荷载作用下,土体只发生弹性变形;动态变形模量与土体动弹性模量呈线性关系,路基动态变形模量的模拟结果大于理论计算值;土体的泊松比对动态变形模量影响较小;动态变形模量有效测试深度建议取0.5~0.6 m.     

基于KENTRACK的铁路沥青混凝土底砟层疲劳特性评价

重复动载疲劳损伤是沥青混凝土底砟层的破坏形式之一。本文建立了沥青混凝土底砟层的三维有限元分析模型,分析其在列车荷载作用下的受力变形特性。采用KENTRACK设计方法分析了沥青混凝土底砟层的疲劳寿命。结果表明:沥青混凝土底砟层等厚度替代基床表层的路基结构形式在列车荷载作用下基床表层的竖向动变形和振动加速度明显减小;沥青混凝土底砟层的层底拉应变在10×10^-6~90×10^-6,处于较低水平;沥青混凝土底砟层具有良好的疲劳耐久性,可用于工程实践。     

两船并靠状态下的运动响应数值模拟研究

针对两船并靠工况复杂,各种运动相互间存在耦合的情况,基于三维势流理论和波浪的辐射/衍射理论,应用多体水动力学软件,建立了船体、护舷和缆绳的模型,开展了两船在风、浪、流作用下的运动响应数值模拟。模拟结果可作为并靠方案设计和优化的参考依据,也可为两船并靠状态下的护舷力学性能计算提供支撑。     

25t轴重荷载作用下隧底脱空区域受力特性分析

为了研究在役铁路隧道在通车之后隧底脱空病害的问题,采用有限元理论,建立隧道脱空区域在围岩压力与25 t轴重列车动载作用下的数值计算模型,主要研究80 cm与40 cm脱空宽度分别距隧道中心线0,80 cm与160 cm时脱空区域的受力特性。结果表明:在围岩压力下,脱空区域中线上壁和外侧顶角混凝土中产生拉应力及内侧顶角中产生压应力,其中压应力对脱空的宽度更为敏感;同时施加列车动载作用时,脱空区域上壁出现了竖向动应力与横向拉应力,得到了脱空区域力学指标的最大响应值及其出现的具体位置,宽度的增加对脱空区上壁横向拉应力更为显著,上壁横向拉应力增幅超过200%,竖向动应力增幅达50%。因此,隧底脱空区周围应力分布复杂,拉应力与压应力在脱空区域同时存在,应力突变严重,对脱空现象应及时组织处理。     

粉质黏土层大直径泥水盾构掘进地层扰动分析

针对盾构机在粉质黏土层中推进引起的地层扰动进行分析尤为重要。以新建京张高铁JZSG-1标段清华园隧道2号～1号盾构区间为例,采用现场实测与数值模拟相结合的方法,研究大直径泥水平衡盾构隧道穿越粉质黏土层引起的地层扰动,得到土体横向水平位移及地表沉降的变化规律。需对横向1.5D范围内地表及建(构)筑物进行地层加固、加强监控量测;在盾构掘进过程中,应根据沉降数据实时调整盾构掘进参数及加固方案,以期更好地控制地表沉降。针对掌子面释放系数和注浆层软化模量进行参数分析数值计算,提出地表沉降的有效控制方法,在条件允许情况下适当提早管片的拼装及适当加快注浆层的硬化速度,可有效控制地表沉降。     

考虑游览船运营特征的航道通过能力评价方法

为构建客货船舶协同动态运行控制技术体系，以经典航道通过能力模型为基础，构建基于游览船运营特征(发船高峰性和航线集中度)的航道通过能力模型.根据黄浦江游览核心区船舶自动识别系统(AIS)数据，对所提出的航道通过能力模型进行实证分析.研究结果表明，本文航道通过能力模型能够较为准确地评价研究区域的实际航道通过能力.游览船发船高峰时期与现有航线规划条件下，黄浦江游览核心区航道通过能力(76艘/h)趋近饱和状态；当过境船到达超过69艘/h时，建议海事相关部门采取“错峰”航行等相关政策.     

基于分子动力学的车流运行动态特性及其模型

车辆跟驰行为受前导车和道路环境等的影响,将车辆抽象成相互作用的分子,基于分子动力学构建相互作用势函数,建立基于相互作用势函数的分子跟驰模型.采集试验路段不同点位的交通流样本,从视频中获得所需数据,并对加速度波动特性进行分析.将车辆运行状态分为常态行驶,起动加速和减速停车3种,根据实测交通数据对3种车辆运行状态进行模型参数标定,同时对分子跟驰模型进行稳定性分析验证,结果表明,相对于经典GM模型,分子跟驰模型稳定性更好,对实际交通状态拟合程度更高.