甲、乙型肝炎病毒重复感染的血清学检测

本文分析60例甲、乙型肝炎病毒重复感染的血清学检测结果,提示重复感染占当时住院肝炎病人的14.8%。在重复感染中,同时感染甲、乙两型肝炎者9例;乙肝抗原携带者及慢性肝炎基础上感染甲肝者41例;乙肝隐性感染免疫后又感染甲肝者10例.同时观察到部分病人重复感染时,HBsAg 滴度下降或消失。并探讨了肝炎复发或突然加重的原因,认为两种肝炎病毒重复感染是肝炎复发或者突然加重的主要因素.故预防HBV 携带者及慢性乙肝重复感染其他肝炎病毒十分重要.     

采用B／S模式来实现C／S模式下物资管理系统的优化

本文通过对C／S和B／S模式物资管理系统在使用中优缺点的分析,提出了采用以C／S模式为主,B／S模式为辅的混合模式对当前单一的C／S模式物资管理系统进行改造的设想。在这种混合模式下,物资管理部门内部采用C／S模式,便于实现复杂的管理功能及可靠的安全机制：对于非物资管理部门的用户,采用B／S模式,便于统一管理与维护。最后,本文还对系统改造的开发环境和技术做了探讨。     

无限长电缆单位长度上自感一种新的计算方法

根据导体回路自感的定义,给出了计算"无限长"电缆单位长度上自感的一般计算方法.结果表明:其近似结果与常用的求"无限长"电缆中部附近单位长度上自感的结果相同,故可简单的取其中部附近单位长度的自感作为"无限长"电缆单位长度上的自感的近似值.     

线性绞车电控系统开发与应用

基于广州打捞局120 000 kN抬浮力打捞工程船配套4 500 kN线性绞车的技术要求,提出线性绞车电控系统设计方案。从线性绞车在打捞工程船中的作业工况、电控系统的通讯架构、线性绞车单台控制及远程联动的自动控制、人机界面操作等方面进行研究,介绍线性绞车电控系统的设计思路,为线性绞车在打捞沉船工作中的正确运用提供了理论支撑和技术保障。     

新能源电力推进对比分析

文章基于全球低碳节能政策,研究并概述了直流微网新能源电力推进系统及其关键技术,对比了以太阳能、蓄电池、氢燃料电池等为主动力的电力推进系统,并分析其性能、综合效率及实际船舶应用,对推进绿色船舶、节能减排等具有重要的实际意义。     

防止电力机车进入无电单元(区)的安全预警方法

针对目前计划内接触网停电时电力机车进入无电单元(区)的问题,提出了基于动态停电作业区域数据对比库语音、屏幕鼠标点击坐标和高清成像分析进行"三元素二阶段"处理对比方法,以减少人员操作失误和损失.机车/车次信息及对应机车属性先由操作人员办理接发列预告(办理闭塞)的语音识别获取,再通过TDCS/CTC终端机非上位机获取并核对...     

考虑电动自行车骑行的非机动车道最大纵坡探讨

现行规范要求非机动车道的最大纵坡不超过3.5%,但要在山地城市、跨江桥梁两岸慢行系统衔接等场景下满足该要求存在工程占地大、造价高、可实施性差等问题,考虑到电动自行车在非机动车出行方式中占比越来越高的实际情况,以《电动自行车安全技术规范》（GB 17761—2018）规定的国标电动自行车为研究对象对骑行过程进行受力分析,提出了可满足电动自行车骑行要求的非机动车道最大纵坡参考值,可供电动车骑行占比高的类似项目参考。     

提高客车电气系统可靠性的措施

客车质量的好坏离不开电气系统的可靠性。简要介绍如何提高客车电气系统的可靠性。     

一种单片机控制的水温测试系统

由于现代多样的电子控制技术和电子控制理论的迅猛发展,高精度的机械在各类工业控制系统、生产线等方面的需求越来越大.其中以单片机为核心实现的数字控制器,因其体积小、简便易行等优点,而被广泛应用于各行各业.本文将单片机的温度控制系统作为设计核心,通过温度传感器、单片机等软件系统图,并利用软件编程,从而达到实现水温控制的目的....     

Economic and ecological optimization of electric bus charging considering variable electricity prices and CO2eq intensities

In many cities, diesel buses are being replaced by electric buses with the aim of reducing local emissions and thus improving air quality. The protection of the environment and the health of the population is the highest priority of our society. For the transport companies that operate these buses, not only ecological issues but also economic issues are of great importance. Due to the high purchase costs of electric buses compared to conventional buses, operators are forced to use electric vehicles in a targeted manner in order to ensure amortization over the service life of the vehicles. A compromise between ecology and economy must be found in order to both protect the environment and ensure economical operation of the buses.In this study, we present a new methodology for optimizing the vehicles’ charging time as a function of the parameters CO_2eq emissions and electricity costs. Based on recorded driving profiles in daily bus operation, the energy demands of conventional and electric buses are calculated for the passenger transportation in the city of Aachen in 2017. Different charging scenarios are defined to analyze the influence of the temporal variability of CO_2eq intensity and electricity price on the environmental impact and economy of the bus. For every individual day of a year, charging periods with the lowest and highest costs and emissions are identified and recommendations for daily bus operation are made. To enable both the ecological and economical operation of the bus, the parameters of electricity price and CO₂ are weighted differently, and several charging periods are proposed, taking into account the priorities previously set. A sensitivity analysis is carried out to evaluate the influence of selected parameters and to derive recommendations for improving the ecological and economic balance of the battery-powered electric vehicle.In all scenarios, the optimization of the charging period results in energy cost savings of a maximum of 13.6% compared to charging at a fixed electricity price. The savings potential of CO_2eq emissions is similar, at 14.9%. From an economic point of view, charging between 2 a.m. and 4 a.m. results in the lowest energy costs on average. The CO_2eq intensity is also low in this period, but midday charging leads to the largest savings in CO_2eq emissions. From a life cycle perspective, the electric bus is not economically competitive with the conventional bus. However, from an ecological point of view, the electric bus saves on average 37.5% CO_2eq emissions over its service life compared to the diesel bus. The reduction potential is maximized if the electric vehicle exclusively consumes electricity from solar and wind power.