高速公路可变收费标准模型研究

在介绍可变收费的理论基础上,分析影响高速公路可变收费标准制定的主要因素,并讨论不同时段收费费率同交通量的关系。在设定的可变收费方案下,建立了出行者选择的二元logit模型,根据调研样本,采用最小二乘法对模型参数标定并对设定的可变收费方案进行评价,结果证明可变收费能使交通流在各时段合理分布,从而提高了高速公路的服务水平。     

压弯荷载共同作用下肋板结构剪力滞分析

利用最小势能原理分别建立了肋板结构仅在轴力及压弯荷载作用下考虑剪滞剪切变形综合效应控制微分方程，在获得方程解析解后，导出了可广泛应用的有限元列式。算例表明，该方法计算精度较高，便于实际应用，具有很高的工程应用价值。     

CeO2改性阴极扩散层对质子交换膜燃料电池性能的影响

采用水热法制备纳米CeO2空心球,以一定比例与碳粉、PTFE混合,经超声震荡后均匀喷涂在经疏水处理过的碳纸表面上形成微孔层.将改性扩散层与传统扩散层进行比较,通过扫描电子显微镜、能谱测试分析、接触角、接触电阻表征,扩散层的物理性能几乎不会改变.再将扩散层组装成单电池进行一系列的电池性能测试,结果表明:掺杂CeO2的阴极扩散层组装而成的单电池无论是电池性能、交流阻抗谱还是动态响应测试均优于传统扩散层组装的单电池.即证明了掺杂CeO2制备的改性阴极扩散层由于其储放氧功能,可以加速氧气传质,增加催化剂表面氧分压,进而提升PEMFC的单电池的动态响应性能.     

轨道交通车辆的工艺流程标准化

从生产线建立、工艺流程编制、工艺布局设计和生产能力等方面进行分析,提出了轨道交通车辆工艺流程标准化设计方法和优化方法。基于精益管理理念和工序能力测算法,可以合理编制标准化工艺流程,从而降低劳动强度,提高生产效率。     

船舶低硫柴油系统设计的分析与优化

就新辟航线首制船“汉亚直达”集装箱船的低硫柴油系统,叙述了船舶低硫柴油系统的设计经验,从当前国内外对船用燃油硫含量的要求、应对方案到船舶低硫柴油冷却方式选择、低硫柴油冷却系统设计、高/低硫柴油转换、使用低硫柴油风险分析及处理等方面进行详细叙述,为业内同行提供参考。     

成昆铁路矮塔斜拉桥索梁锚固区模型试验研究北大核心

为研究铁路矮塔斜拉桥索梁锚固区的受力形式,以成昆铁路金沙江大桥为工程背景,针对该桥采用的新型梁顶混凝土锚固构造,通过缩尺模型试验研究其在不同荷载下的应力分布和开裂特征。结果表明:在斜拉桥成桥恒载索力作用以及最不利荷载组合索力作用下,C7锚固块更容易发生破坏,将其作为试验构件开展缩尺模型试验,发现锚固块在不同张拉荷载作用下张拉至设计索力的过程中,应变增幅基本上线性增加,卸载后同样呈线性减小,说明混凝土受力处在线弹性阶段,且应力在规范要求范围内。在试验荷载加载至140%设计索力时,锚固块前端倒角位置开始出现细小裂纹且随荷载的增加不断开展。当荷载卸载至0时,之前出现的裂缝随荷载的减小逐渐闭合,宽度肉眼不可见,表明该构造能够满足正常使用要求且具备足够的安全储备。     

基于准平面假定的外贴CFRP板加固宽缺口混凝土梁刚度研究

宽缺口混凝土梁是为研究CFRP板与混凝土界面特性而构造一种新型混凝土梁.为分析该新型梁的变形与刚度特性,对11根外贴CFRP板加固的各类混凝土梁进行静载试验,并对其变形刚度进行详细的测试和研究.基于FRP类材料加固混凝土梁应变协调的准平面假定并考量CFRP板的刚度贡献,对加固后宽缺口混凝土梁的刚度计算公式进行理论推导,并将理论公式计算结果与实测结果进行比对.研究结果表明:外贴CFRP混凝土梁的刚度有小幅度提高,CFRP板能延缓裂缝的发展,减小梁的变形.     

Development of knowledge based body structure concept design model

The purpose of this study is to propose a concept design process for an automotive body structure using technical information on the major joints and members of vehicles. First, in order to collect the technical information on major joints and members, 17 vehicles were selected using benchmark data. The collected technical information for the selected vehicles was the cross sectional shapes of each joint and member which were used for the analysis of joint stiffness, crashworthiness and static stiffness of the member to make a database along with cross section properties. This study applied a ‘What If Study’ technique to perform a concept design of an automotive body using the analyzed information and selected cross section meeting the design objectives. The criteria for the selection of the cross section were defined by subdividing the defined design objectives of an automotive body structure and constraints into members and joints. In order to configure an analysis model of an automotive body structure using the selected cross section, a shape parametric model was used and static stiffness, dynamic stiffness and crashworthiness were assessed to evaluate the configured automotive body structure. The evaluation result showed that the crashworthiness and static/dynamic stiffness were improved compared to an existing body structure. In addition, the weight of the body structure was reduced. Through this study, the process that can rapidly and effectively derive and evaluate the concept design of an automotive body structure was defined. It is expected that, henceforth, this process will be helpful for the study of automotive body structures.     

Occupant injury risk analysis at NASS/CDS database

Injury information for vehicle occupants from the body regions of the head, thorax, abdomen, and upper and lower extremities, due to the restraints and interior parts of the vehicle, were extracted from the 2009 ~ 2012 NASS/CDS database. For those cases with high occurrence frequency, a detailed and comprehensive data analysis was performed to find the relationship between the accident, occupant, vehicle, and injury data. A numerical frontal impact sled model with the Hybrid III dummy and the GHBMC human body model was constructed to simulate and identify those injury risks according to NASS/CDS. Among the 5,734 injuries to the aforementioned body regions from frontal crashes are, listed by frequency of occurrence, the lower extremity (27.8 %), upper extremity (21.3 %), thorax (15.1 %), face (10.9 %), spine (8.7 %), head (7.3 %), and abdomen (6.9 %). The main injury sources to the head were the windshield, side structure, and steering wheel. For the thorax and abdomen they were the seat belt and steering wheel. For the lower extremity it was the instrument panel. The main injury patterns for the head were the concussion and the contusion. For the thorax they were vessel laceration and lung contusion. For the abdomen they were laceration and contusion of the organs. For the lower extremity they were bone fracture and ligament rupture. The steering wheel and seat positions were main factors affecting head and thorax injury risks. From the sled impact simulation, high injury risks of the head and thorax were assessed respectively at conditions of steering column tilt down and rear most seat position, which correlated well with the findings from the NASS/CDS data analysis.