桥梁检测技术研究及工程运用

简述了桥梁结构检测的主要内容与评定方法，结合目前桥梁检测技术发展的现状，对桥梁检测技术进行了综合评价，并介绍了桥梁检测技术的发展前景。     

菜园坝长江大桥主桥Y形刚构施工技术

重庆菜园坝长江大桥主桥采用Y形刚构与钢箱系杆拱、钢桁梁组合结构，系杆拱主跨420m。介绍有大悬臂、不对称三维空间特点的Y形刚构支架法施工技术。     

真空堆载联合预压加固软基试验分析

根据真空堆载联合预压法加固路基的试验成果,对真空堆载联合预压法的规律性进行了分析,为软土基础的加固提供了依据。     

黄果树隧道软弱地带初期支护下沉侵限的整治技术

黄果树隧道是上瑞高速公路镇宁~胜境关段的一座公路隧道,出口右洞YK18 067~ 092的煤系地段处于F 12断层破碎带内,围岩为炭质泥页岩,呈软流塑状,属Ⅰ类围岩。该段施工后,初期支护发生严重变形,钢支撑被压弯,下沉量严重侵入建筑限界。文中介绍了侵入建筑限界部位及继续向前掘进的施工技术。     

黄陵洞大桥水平转体施工关键技术研究

黄陵洞大桥为主跨152m的上承式拱桥，拱肋为劲性钢管骨架混凝土箱形结构。从施工工艺和受力角度对磨心、磨盖的制作方式进行了重点阐述，并着重介绍了该桥转体施工中钢管骨架的受力性能和混凝土徐变带来的影响，对转体施工脱架索力的控制、劲性骨架施工受力和变形监测、劲性骨架箱拱温度效应进行了分析。     

汽油机活塞组—气缸套整体耦合传热模型及应用

采用直接耦合的有限元分析方法对一汽油机的活塞组—气缸套系统的瞬态传热过程进行了研究。通过将润滑油膜假设为一维热阻,建立了活塞组—气缸套整体耦合系统的三维传热模型,应用所开发的三维流体动压润滑分析程序对活塞环组沿周向瞬时变化的油膜厚度进行了计算与分析。以LJ377MV汽油机活塞组—气缸套零部件为对象进行了应用研究,获得了更为清晰的多部件间的相互传热关系。     

基于有机朗肯循环的车用柴油机排气余热回收系统性能分析

利用设计的有机朗肯循环系统回收某重型车用柴油机的排气能量,通过台架试验,获得了变工况下柴油机排气余热能分布特性。分析了有机工质蒸发压力、过热度以及柴油机工况变化对有机朗肯循环系统性能的影响,以系统净输出功率和热效率为优化目标,确定了适用于有机朗肯循环系统的最佳蒸发压力。研究结果表明,当有机工质蒸发压力为1.8 MPa时,有机朗肯循环系统的净输出功率最大可以达到12.69kW,热效率可以达到11.19%;将有机工质加热至过热状态并不能明显提高有机朗肯循环系统的净输出功率。     

高速公路软土路基高路堤拓宽设计

以横沥立交接人京珠高速公路的拓宽设计为基础,介绍了高路堤高速公路拓宽需注意的问题,包括旧路基坡面开挖、软基处理、路基填筑、新旧沥青路面拼接以及施工监测等。     

Thermal design of automobile exhaust based thermoelectric generators: Objectives and challenges

The potential for thermoelectric power generation (via waste heat recovery onboard automobiles) to displace alternators and/or provide additional charging to a vehicle battery pack has increased with recent advances in thermoelectric material processing. In gasoline fueled vehicles (GFVs), about 40% of fuel energy is wasted in exhaust heat, while a smaller amount of energy (30%) is ejected through the engine coolant. Therefore, exhaust-based thermoelectric generators (ETEG) have been a focus for GFV applications since the late 1980s. The conversion efficiency of modern thermoelectric materials has increased more than three-fold in the last two decades; however, disputes as to the thermal design of ETEG systems has kept their overall efficiency at limited and insufficient values. There are many challenges in the thermal design of ETEG systems, such as increasing the efficiency of the heat exchangers (hot box and cold plate), maintaining a sufficient temperature difference across the thermoelectric modules during different operating conditions, and reducing thermal losses through the system as a whole. This paper focuses on a review of the main aspects of thermal design of ETEG systems through various investigations performed over the past twenty years. This paper is organized as follows: first, the construction of a typical ETEG is described. The heat balance and efficiency of ETEG are then discussed. Then, the third section of this paper emphasizes the main objectives and challenges for designing efficient ETEG systems. Finally, a review of ETEG research activities over the last twenty years is presented to focus on methods used by the research community to address such challenges.     

3-D numerical and experimental analysis for airflow within a passenger compartment

People use cars so frequently that they always consider the air-conditioning, and thermal comfort of the driver and passenger when buying a new car. Therefore accurate simulation of the thermal performance of automobile air conditioners to improve human comfort has become increasingly important. In order to improve the thermal comfort of passengers, 3-D flow motion and thermal behavior within vehicles must be analyzed. In this paper, a numerical simulation was used to investigate thermal behavior in a vehicle. Because air temperature at an air vent is related to the cooling capacity of the air conditioner, the cooling capacity was calculated using ɛ-NTU (effective number of transfer unit) theoretical equations. Using the air temperature relationship between inlet and outlet vents as boundary conditions, a 3-D unsteady κ-ɛ turbulent model was used to give a transient analysis simulation of the temperature field and flow conditions in a vehicle’s passenger cabin. Cooling cycle analysis and conjugate heat transfer analysis at the inside surface of the cabin’s ceiling, floor and sides were also considered. The predicted temperature distributions in the vehicles passenger cabin were in good agreement with those obtained experimentally.