TJ376Q二气门汽油机准均质稀混合气燃烧实验研究

本文对夏利TJ376Q汽油机进气系统进行了改造，大大提高了涡流和滚流比，强化空气运动的结果有利于组织燃料在缸内的浓度分布，从而为在二气门汽油机上实现稀燃烧打下基础；原发动机油器式供油系统被改为电控气道内燃油喷射系统。在此基础上，采用了两次燃油喷射技术。通过对这两次喷油时刻、喷油量的分别调节，在缸内形成精细分层的混合气即所谓准均质混合气，从而优化了油耗和排放指标，成功地在产品二气门汽油机上实现了稀薄燃烧。     

液化石油气／柴油双燃料发动机放热规律分析

利用CB366燃烧分析仪测录的液化石油气（LPG）／柴油双燃料发动机和原柴油机示功图，比较了LPG／柴油双燃料发动机和原柴油机的燃烧特性及负荷对二者的影响，分析了供油提前角、掺烧比两因素对最高燃烧压力、燃烧放热率、着火开始时刻等双燃料发动机燃烧特性的影响，得出了有关双燃料发动机燃烧特性的结论。     

LPG/汽油双燃料发动机台架试验研究

对两种汽油机和在其基础之上改装成的LPG(液化石油气 )发动机进行了性能对比试验和理论分析。试验结果表明 ,LPG主要优点是降低了CO和HC排放。但并不是所有结构的汽油机都有同样的改善效果 ,还取决于原机结构与LPG燃料特征的适配性。     

汽油机缸内直喷的关键技术和发展现状

讨论了缸内直喷发动机的优缺点和当前对该种发动机出了要求，认为缸内直喷技术的关键是掌握和控制好混合气浓度在空间的分布和随时间的变化，其控制是在一定的喷油，点火控制策略下靠燃油射系统与缸内流场的合理匹配实现的，阐述了缸内直喷对上述两个方面提出的要求，并讨论了发动机排放及其解决方法。     

燃油带电荷辅助雾化的激光全息摄影研究

利用发动机点火线圈次级电压作为脉冲电源，在发动机稳流气道试验台上模拟１７５单缸机的进气，用ＹＳＣ－１型运动粒子瞬态激光全息测试仪折摄了燃油油滴带电雾化和不带电雾化的粒子全息图，经再现后得到实际的粒子图，编制了专用软件进行粒子图像处理和粒径统计分布，统计结果证明燃油油滴带电后粒子粒径约减少了３／４倍左右，改善了雾化效果。     

温度和麻醉对神经几种兴奋性指标的影响——兼论何者可以正确反映兴奋性

在蟾蜍坐骨神经-腓神经观察了温度和麻醉对几种兴奋性指标的影响。结果表明,标准电量(a)随兴奋性的变化而有规律地变化。兴奋性愈高。a值愈小。而Weiss式中的b、基强度(Rh)、时值(Chr)及强度—时间曲线均不能正确反映兴奋性。细胞膜时间常数(RC)与兴奋性的变化无规律性联系。结论,a是兴奋性的可靠定量指标。     

A study of the environmental impacts of intelligent automated vehicle control at intersections via V2V and V2I communications

This article presents a novel intersection traffic management system for automated vehicles and quantifies its impact on fuel consumption and greenhouse gas emissions of CO₂ relative to traditional traffic signal and roundabout intersection control. The developed intelligent traffic management (ITM) techniques, which are based on a spatiotemporal reservation scheme, ensure that vehicles proceed through the intersection without colliding with other vehicles while at the same time reducing the intersection delay and environmental impacts. Specifically, the spatiotemporal reservation scheme provides each vehicle a collision-free path that is decomposed into a speed profile along with navigational instructions. The integration of the developed microscopic traffic simulator with instantaneous emission model, provides improved assessments of the environmental impact of traffic control strategies at intersections. The simulator architecture integrates several ITM algorithms, vehicle sensors, V2V/V2I communications, and emission and fuel consumption models. Each vehicle is modeled by an agent and each agent provides information depending on the specific vehicle sensors. The ITM system is supported by V2V and V2I communications, allowing the exchange of information among vehicles and infrastructure. The data include the estimated vehicle position and speed. Compared with traditional traffic management techniques, the simulation results prove that the proposed ITM system reduces CO₂ emissions significantly. The research also shows that these reductions are more significant when the traffic flow increases.     

喷油泵装配线中拧紧技术的研究及应用

本论文介绍了拧紧技术的原理和方法,以及拧紧技术在喷油泵装配线中的应用.最后说明了拧紧程序在喷油泵装配线中的程序防错方法.     

自行式沥青路面养护车工程配置的量化分析

基于提高作业效率、降低工程成本和实现合理的养护设备保有量的目的,根据道路病害的成因和长期实地观测的结论,分析了沥青混凝土路面病害数量与自然光候、铺筑质量、行车荷载、养护里程和道路通车年限的关系,并以此为基础,提出了自行式多功能沥青路面养护车工程配置的量化方法。     

Comparing rail fuel efficiency with truck and waterway

This paper presents a railroad energy efficiency model used to estimate the fuel economies for classes of trains transporting various commodities. Comparable procedures are used to estimate truck and waterway fuel consumption. The results show that coal unit trains are 4.5–5.0 times more energy efficient than movements in the largest trucks allowed in the eastern and western regions of the US, unit grain train movements in the central US are 4.6 times more fuel efficient, soda ash unit train and non-unit train shipments are 4.9 and 3.2 times more efficient, and ethanol unit train and non-unit train movements are 4.8 and 3.0 times more efficient. In terms of barge traffic, coal unit train and non-unit train are 1.3 and 0.9 times as energy efficient in the eastern US, grain unit train and non-unit train movements are 1.7 and 1.0 times more efficient from Minneapolis to the Gulf of Mexico, and grain unit train and non-unit train movements are 1.0 and 0.7 times more fuel efficient from the Upper Ohio River to the Gulf of Mexico.