人TSHR膜外区cDNA克隆及真核表达载体的构建

目的通过生物技术获得促甲状腺激素受体膜外区表达载体,为TSHR膜外区的研究提供有力工具。方法从人甲状腺组织中提取总RNA,RT-PCR分离得到TSHR膜外区cDNA,双酶切后插入真核表达载体pcDNA3.1(+)。结果经酶切鉴定、测序分析表明TSHR膜外区片段与GenBank提供的完全相同。结论成功构建了人TSHR膜外区真核表达载体。     

空车调整最小费用的合理分摊

借助多人合作对策的思想建立了铁路空车调整问题中最小费用合理分摊的数学模型，给出了建立理想分摊向量和特征函数的一种方法，并提供了具体解法，比较有效地解决了空车调整中最小费用的合理分摊问题，为最优调运方案的实际实施提供了前提和保障。     

254例糖尿病患者的死因分析

目的分析糖尿病(DM)死亡原因,为防治提供依据。方法回顾性分析西安交通大学医学院第一、二附属医院自1991年1月1日至2003年12月31日期间住院的DM死亡病例。结果13年两院DM死亡254例,占住院总死亡人数3.2%;死因依次为:慢性并发症42.5%(心脑血管病28.3%,肾病14.2%),肿瘤20.1%,感染11.4%,急性并发症6.7%,肝硬化6.3%;慢性并发症死因中合并高血压66.7%(72/108)。结论慢性并发症已成为DM的主要死因,其中心脑血管病变是最重要的,高血压是增加其死亡率的主要危险因素。因此,严格控制血糖和血压,对降低DM心脑血管病变的病死率有重要意义。     

规则迎浪中船舶参数横摇的三维时域预报方法研究

参数横摇是船舶因复原特性改变而引起的典型非线性现象。文章采用三维时域方法预报规则迎浪中船舶的参数横摇运动。该方法引入匹配面将流域分为内域和外域,内域中采用Rankine源来满足物面条件和线性自由面条件,而外域中应用时域格林函数来满足线性自由面条件和远场辐射条件。数值方法中,Froude-Krylov力和恢复力是通过对船舶瞬时湿表面积积分获得,同时考虑了横摇、垂荡和纵摇三自由度之间的耦合作用,以及非线性横摇阻尼的影响。数值结果与试验结果吻合很好,说明该方法可以有效地预报参数横摇。     

基于AT89S52单片机的民用地震报警器的设计

为实现地震信息的报警及生命信息的探测,设计了地震检测报警系统。根据地震波的特点,采用加速度传感器检测地震波,经单片机分析、处理后,判断地震发生与否。如果检测到地震发生,警报系统第一时间向人们发出地震警报和逃生语音提示,之后通过内置的生命探测红外传感器探测周围的生命信息,当检测到被困人员时,无线发射模块向外界发送两种不同频率的电磁波,进行无线求救和语音求助,以求最大限度地减少地震灾害造成的损失。     

基于RT-LAB的电力推进船舶半物理仿真研究

实验室内电推船舶的研究常采用小比例模型的方式。考虑到场地和经费的因素,仿真技术也被应用于电推船舶的研究,但是数字仿真存在置信度不足的缺点。本文以实时仿真机RT-LAB为基础,将受场地经费限制的设备以模型的形式在仿真机中运行,与实物一起搭建电推船半物理仿真平台。既可以克服数字仿真置信度不足的缺点,同时也便于进行工况的修改。     

Application of a modified thermostatic control strategy to parallel mild HEV for improving fuel economy in urban driving conditions

A modified thermostatic control strategy is applied to the powertrain control of a parallel mild hybrid electric vehicle (HEV) to improve fuel economy. This strategy can improve the fuel economy of a parallel mild HEV by operating internal combustion engine (ICE) in a high-efficiency region. Thus, in this study, experiments of a parallel mild HEV were conducted to analyze the characteristics of the hybrid electric powertrain and a numerical model is developed for the vehicle. Based on the results, the thermostatic control strategy was modified and applied to the vehicle model. Also, battery protection logic by using electrochemical battery model is applied because the active usage of battery by thermostatic control strategy can damage the battery. The simulation results of the vehicle under urban driving conditions show that the thermostatic control strategy can improve the vehicle’s fuel economy by 3.7 % compared with that of the conventional strategy. The results also suggest that the trade-off between the fuel economy improvement by efficient ICE operation and the battery life reduction by active battery usage should be carefully investigated when a thermostatic control strategy is applied to a parallel mild HEV.     

Real-time empirical NO<Subscript>x</Subscript> model based on In-cylinder pressure measurements for light-duty diesel engines

This paper proposes a real-time empirical model of NO_x emissions for diesel engines. The proposed model predicts the level of NO_x emissions using an empirical model developed based on the thermal NO formation mechanism, the extended Zeldovich mechanism. Since it is difficult to consider the exact physical NO formation phenomena in real-time applications, the proposed algorithm adapts the key factors of the NO formation mechanism from the extended Zeldovich mechanism: temperature of the burned gas, concentration of the gas species, and combustion duration where NO is generated. These factors are considered in a prediction model as four parameters: exhaust gas recirculation rate (EGR rate), crank angle location of 50 % of mass fraction burned (MFB50), exhaust lambda value, and combustion acceleration. The proposed prediction model is validated with various steady engine experiments that showed a high linear correlation with the NO_x emission measured by a NO_x sensor. Furthermore, it is also validated for transient experiments.     

Flamelet combustion model for stratified EGR distribution in a diesel engine

Numerous research has been devoted to finding a method to simultaneously reduce NOx and soot emissions from diesel engines. In-cylinder EGR stratification is a technique that simultaneously reduces NOx and soot using a nonuniform EGR distribution in the combustion chamber. To study the potential of in-cylinder EGR stratification, a new combustion model is required that considers the non-uniform EGR distribution and the chemical kinetics. In this study, a new combustion model, the Flamelet for Stratified EGR (FSE) model, was developed to consider the non-uniform in-cylinder gas distribution based on chemical kinetics. The concept of the FSE model is based on using multiple flamelets with the multizone concept. To describe the non-uniform gas distribution, the combustion chamber is divided into several zones by oxygen concentration at the start of injection. Then, the flamelet equations are solved at the boundary of each zone. The final species mass fraction of each cell is calculated using linear interpolation between two results from the boundaries. In this paper, the FSE model was validated under in-cylinder EGR stratification conditions, and then, the potential of in-cylinder EGR stratification was studied by using the FSE model. The effect of in-cylinder EGR stratification was verified under various injection timing, engine speed, and road conditions with optimized engine geometries. The results shows simultaneous NOx and soot reductions under the stratified EGR condition.