基于MES的生产管理系统应用

通过对某航空企业车间生产管理特点的分析,采用B/S模式以及ASP.NET C# SQL Server2000设计开发基于MES的生产管理系统.介绍该系统的设计原理、软硬件结构图,着重分析说明计划管理系统的开发过程、技术关键及具体实现方法和运行结果.该系统为某航空企业的车间实施计算机管理、提高生产效率提供了有效的工具.     

基于二维码技术的高校大型仪器设备信息管理系统

针对高校大型仪器设备的基本信息管理特点和使用情况,结合二维条形码技术的特点,提出了一种基于二维码技术的高校大型仪器设备管理信息系统,并对实现这一系统的管理模型、系统的结构与特点以及实现这一系统相关的技术方案以及要解决的关键技术进行了探讨,并着重就二维条形码PDF 417的模板定制和手持数据采集器MC 50的程序设计等问题进行了有益的探讨。     

航空复杂系统技术状态管理方法研究

通过介绍航空复杂系统技术状态管理的需求与现状,剖析了其技术状态管理过程中存在的问题及原因,结合航空复杂系统产品的特点,提出了复杂系统桌面设计与实物技术状态综合管理的新方法,给出了控制系统技术状态管理新思路实践过程中的实施要点,最后提出了复杂系统技术状态管理的关注点建议,供相关行业产品技术状态管理参考.     

一种手持设备的条形码技术

主要讨论条形码（BARCODE）技术中的解码技术,文中详细地讲述了条形码解码过程中可能出现的问题以及解决的方法、解码系统的识别性能问题,最后列出了一个条形码解码的具体算法。     

航空复杂系统技术状态管理方法研究

介绍了航空复杂系统技术状态管理的需求与现状,剖析了其技术状态管理过程中存在的问题及原因,结合航空复杂系统产品的特点,提出了复杂系统桌面设计与实物技术状态综合管理的新方法,以及控制系统技术状态管理新思路实践过程中的实施要点;提出了复杂系统技术状态管理的关注点及建议。     

氧分析仪在微量氧分析中的应用

论述了磁氧型、氧化锆型和电池型氧分析仪的原理和应用,介绍了几款分析仪器的特点,并阐述了取样系统的材料的选择和使用中注意点.     

我国航空企业生产物流系统现状分析与改进

介绍了制造型企业生产物流系统特性 ;分析了我国航空企业生产特点及物流管理的现状 ,针对物流管理上存在的问题 ,提出建立集中下料中心 ,实现物流系统信息管理的方法。     

在PDM中实现工艺更改过程管理

 针对工艺设计中更改活动的原因及特点，分析了工艺更改管理中普遍存在的问题，结合军工制造企业研制生产的特点，研究了基于工作流理念建立工艺更改过程的建模方法与控制方法，提出一种基于PDM进行工艺更改过程管理的方案。在PDM软件—TeamCenter Engineering系统中建立了支持工作流的工艺更改过程模型，实现了工艺更改过程的自动运行，同时，通过PDM系统能对工艺更改流程和更改文档进行有效的控制和管理。     

面向作业车间的调度系统研究与实现

通过对航天某厂生产管理现状的分析,针对该厂计划层控制层相互脱节,生产管理缺乏过程监控手段等问题,提出了面向作业车间的生产调度系统的设计思想,详细介绍了该系统的功能模块以及实现系统的关键技术,并开发了较为实用的生产调度系统.通过图形化的生产计划制定和调整,并基于工作流实时控制和管理从计划下达到成品完工全过程,极大地提高了计划编制效率,实现了对生产过程的规范和监控,以及异常情况的实时反馈和快速响应.     

现代企业管理的新理念——PDM

本文介绍了现代企业管理技术－－PDM,重点论述了PDM对企业产品数据管理,生产过程管理以及产品结构管理的特殊功能及特点。     

Industrial battery technologies and markets

Industrial battery market segments generally fall into two major categories--traction batteries, also called motive power batteries; and stationary batteries, also referred to as standby power batteries. The major industrial battery subcategories are discussed. Industrial trucks and rail and mine vehicles represent two major subcategories of motive power batteries. Industrial trucks include forklifts, automated guided vehicles (AGVs), various types of towing vehicles, floor cleaning equipment and so forth. Battery-powered rail and mine vehicles are used in mines where gas is present that could be ignited by spark ignition engines. Locomotive starting batteries and railcar emergency power batteries are also included in the second subcategory. The distinction is beginning to blur between valve-regulated industrial batteries and golf cart or marine batteries. Both industrial and SLI(starting/lighting/ignition)-derivative batteries are competing for markets in the future. The future trends in industrial battery production in Japan, USA and Europe are discussed     

Battery configurations for multi-megawatt pulse power

The capability of lead-acid batteries for supplying very high power for a short time is explored. The application of such a battery for accelerating a hypersonic plane is used to illustrate the requirements. A technique for analyzing batteries and controlling voltage for pulse loads is described. Evaluation of lead-acid batteries in production and voltage regulation by switching batteries in and out are covered. Alternatives to batteries, including superconducting magnetic energy storage, are discussed     

Safety testing of lithium ion batteries for navy devices

Lithium ion battery technology is being introduced into power supplies used by our armed forces for a variety of applications. In many cases, the same cells and design parameters that support commercial battery packs are being used in military battery packs. This approach is expected to result in a major decrease in the total life cycle cost of the equipment these batteries support. On June 13, 1991, NAVSEA issued INST9310.1B1, which states that all lithium battery powered equipment must undergo safety evaluation and approval prior to fleet use. This safety program governs a process whereby approvals are issued for lithium batteries to be used in specific equipment on ground facilities, surface combatants, air combatants, and/or submarines. The Naval Ordnance Safety and Security Activity (NOSSA) manages the program. The chief technical advisors are Code 644 at NSWC Carderock Division and Code 609A at NSWC Crane Division. This paper describes three battery designs that incorporate lithium ion technology, and the results of battery safety tests conducted in accordance with navy requirements.     

Hubble performance on-orbit

A summary of the Hubble Space Telescope (HST) nickel-hydrogen (NiH/sub 2/) battery performance from launch to the present. Over the life of HST vehicle configuration, charge system degradation and failures, together with thermal design limitations, have had a significant effect on the capacity of HST batteries. Changes made to the charge system configuration to protect against power system failures and to maintain battery thermal stability resulted in undercharging of the batteries. This undercharging resulted in decreased usable battery capacity as well as battery cell voltage/capacity divergence. This cell divergence was made evident during on-orbit battery capacity measurements by a relatively shallow slope of the discharge curve following the discharge knee. Early efforts to improve battery performance have been successful. On-orbit capacity measurement data indicates increases in the usable battery capacity of all six batteries as well as improvements in the battery cell voltage/capacity divergence. Additional measures have been implemented to improve battery performance, however, failures within the HST Power Control Unit (PCU) have prevented verification of battery status.     

航空电瓶内阻测量与剩余容量探讨

论述了电瓶内阻的基本测量方法。利用３５５０电瓶内阻测试仪对典型的航空电瓶进行实际测量，结果表明，对于酸性电瓶判断比较正确，而对碱性电瓶判断不正确。     

Field evaluation of Honda's EV PLUS battery packs

The EV PLUS demonstration program provides an opportunity to evaluate battery life while gaining expertise in managing Ni-MH battery technology under real-world conditions. Since individual customers use the vehicles, Honda developed a battery service and evaluation system convenient to customers, yet not burdensome to dealer service. This paper discusses the method of detection of low battery capacity, the technique used to convey this information to users, the bench evaluation system of returned batteries, and explains how the analysis is utilized to enhance the EV PLUS' battery control strategy.     

Satellite lithium-ion battery remaining useful life estimation with an iterative updated RVM fused with the KF algorithm

Lithium-ion batteries have become the third-generation space batteries and are widely utilized in a series of spacecraft. Remaining Useful Life (RUL) estimation is essential to a spacecraft as the battery is a critical part and determines the lifetime and reliability. The Relevance Vector Machine (RVM) is a data-driven algorithm used to estimate a battery’s RUL due to its sparse feature and uncertainty management capability. Especially, some of the regressive cases indicate that the RVM can obtain a better short-term prediction performance rather than long-term prediction. As a nonlinear kernel learning algorithm, the coefficient matrix and relevance vectors are fixed once the RVM training is conducted. Moreover, the RVM can be simply influenced by the noise with the training data. Thus, this work proposes an iterative updated approach to improve the long-term prediction performance for a battery’s RUL prediction. Firstly, when a new estimator is output by the RVM, the Kalman filter is applied to optimize this estimator with a physical degradation model. Then, this optimized estimator is added into the training set as an on-line sample, the RVM model is re-trained, and the coefficient matrix and relevance vectors can be dynamically adjusted to make next iterative prediction. Experimental results with a commercial battery test data set and a satellite battery data set both indicate that the proposed method can achieve a better performance for RUL estimation.     

Advanced lithium ion solid polymer electrolyte battery development

Lockheed Martin Missiles & Space (LMMS), Ultralife Batteries, Inc. (UBI), Eagle Picher Technologies, LLC (EPT), Sandia National Laboratories (SNL) and Rentech, Inc. (RTI) are developing lithium ion solid polymer electrolyte (Li-ion SPE) batteries. Under a new Advanced Technology Program (ATP), this team will develop new high-energy density cells and batteries for space and portable electronics applications. These new batteries will utilize new high-energy density anode and cathode active materials developed by SNL and RTI. UBI will incorporate these new materials into an optimized Li-ion SPE electrode laminate. EPT will develop batteries for aerospace applications based on this electrode laminate technology while LMMS will design the battery charge management controller and provide system expertise     

Electric-vehicle batteries

Electric vehicles that can't reach trolley wires need batteries. In the early 1900's electric cars disappeared when owners found that replacing the car's worn-out lead-acid battery costs more than a new gasoline-powered car. Most of today's electric cars are still propelled by lead-acid batteries. General Motors in their prototype Impact, for example, used starting-lighting-ignition batteries, which deliver lots of power for demonstrations, but have a life of less than 100 deep discharges. Now promising alternative technology has challenged the world-wide lead miners, refiners, and battery makers into forming a consortium that sponsors research into making better lead-acid batteries. Horizon's new bipolar battery delivered 50 watt-hours per kg (Wh/kg), compared with 20 for ordinary transport-vehicle batteries. The alternatives are delivering from 80 Wh/kg (nickel-metal hydride) up to 200 Wh/kg (zinc-bromine). A Fiat Panda traveled 260 km on a single charge of its zinc-bromine battery. A German 3.5-ton postal truck traveled 300 km with a single charge in its 650-kg (146 Wh/kg) zinc-air battery. Its top speed was 110 km per hour