大力发展现代服务业促进廊坊产业升级

现代服务业是驱动现代城市经济发展的重要产业部门，其发展的程度，对于城市经济发展水平提升和产业结构优化具有重要的作用。本文通过深入分析廊坊现代服务业发展的优势和劣势，系统地提出了廊坊现代服务业的发展方向和政策建议。     

The water cycle in closed ecological systems: Perspectives from the Biosphere 2 and Laboratory Biosphere systems

To achieve sustainable, healthy closed ecological systems requires solutions to challenges of closing the water cycle – recycling wastewater/irrigation water/soil medium leachate and evaporated water and supplying water of required quality as needed for different needs within the facility. Engineering Biosphere 2, the first multi-biome closed ecological system within a total airtight footprint of 12,700 m² with a combined volume of 200,000 m³ with a total water capacity of some 6 × 10⁶ L of water was especially challenging because it included human inhabitants, their agricultural and technical systems, as well as five analogue ecosystems ranging from rainforest to desert, freshwater ecologies to saltwater systems like mangrove and mini-ocean coral reef ecosystems. By contrast, the Laboratory Biosphere – a small (40 m³ volume) soil-based plant growth facility with a footprint of 15 m² – is a very simplified system, but with similar challenges re salinity management and provision of water quality suitable for plant growth. In Biosphere 2, water needs included supplying potable water for people and domestic animals, irrigation water for a wide variety of food crops, and recycling and recovering soil nutrients from wastewater. In the wilderness biomes, providing adequately low salinity freshwater terrestrial ecosystems and maintaining appropriate salinity and pH in aquatic/marine ecosystems were challenges. The largest reservoirs in Biosphere 2 were the ocean/marsh with some 4 × 10⁶ L, soil with 1 to 2 × 10⁶ l, primary storage tank with 0 to 8 × 10⁵ L and storage tanks for condensate and soil leachate collection and mixing tanks with a capacity of 1.6 × 10⁵ L to supply irrigation for farm and wilderness ecosystems. Other reservoirs were far smaller – humidity in the atmosphere (2 × 10³ L), streams in the rainforest and savannah, and seasonal pools in the desert were orders of magnitude smaller (8 × 10⁴ L). Key technologies included condensation from humidity in the air handlers and from the glass space frame to produce high quality freshwater, wastewater treatment with constructed wetlands and desalination through reverse osmosis and flash evaporation were key to recycling water with appropriate quality throughout the Biosphere 2 facility. Wastewater from all human uses and the domestic animals in Biosphere 2 was treated and recycled through a series of constructed wetlands, which had hydraulic loading of 0.9–1.1 m³ day⁻¹ (240–290 gal d⁻¹). Plant production in the wetland treatment system produced 1210 kg dry weight of emergent and floating aquatic plant wetland which was used as fodder for the domestic animals while remaining nutrients/water was reused as part of the agricultural irrigation supply. There were pools of water with recycling times of days to weeks and others with far longer cycling times within Biosphere 2. By contrast, the Laboratory Biosphere with a total water reservoir of less than 500 L has far quicker cycling rapidity: for example, atmospheric residence time for water vapor was 5–20 min in the Laboratory Biosphere vs. 1–4 h in Biosphere 2, as compared with 9 days in the Earth’s biosphere. Just as in Biosphere 2, humidity in the Laboratory Biosphere amounts to a very small reservoir of water. The amount of water passing through the air in the course of a 12-h operational day is two orders of magnitude greater than the amount stored in the air. Thus, evaporation and condensation collection are vital parts of the recycle system just as in Biosphere 2. The water cycle and sustainable water recycling in closed ecological systems presents problems requiring further research – such as how to control buildup of salinity in materially closed ecosystems and effective ways to retain nutrients in optimal quantity and useable form for plant growth. These issues are common to all closed ecological systems of whatever size, including planet Earth’s biosphere and are relevant to a global environment facing increasing water shortages while maintaining water quality for human and ecosystem health. Modular biospheres offer a test bed where technical methods of resolving these problems can be tested for feasibility.     

V-22“鱼鹰”倾转旋翼机研制历程与关键技术

倾转旋翼机具有速度快、噪声小、航程远、载重大和耗油率低等优点,本文介绍了贝尔直升机公司V-22"鱼鹰"倾转旋翼机从原理验证阶段的XV-3机到方案验证阶段的XV-15机,再到实用工程研制阶段的V-22"鱼鹰"机循序渐进的研制历程,并叙述了倾转旋翼机研制中的几项关键技术。     

对我国航天制造技术发展的探讨

在分析航天制造技术的重要作用及特征的基础上，总结了我国航天制造技术发展取得的成绩，剖析了现存在的主要问题，结合我国航天事业发展的需要，提出了发展航天制造技术需要重点采取的对策。     

多媒体CBT教育技术探讨

简介了我院成人教育学院新近建成的多媒体ＣＢＴ教学系统，指出其特点、对教学改革的作用，以及对教学软件的开发应注意的几个方面     

变循环涡扇冲压组合发动机发展现状及关键技术分析

总结了国内外变循环涡扇冲压组合发动机的发展现状,对比分析了有/无能量传递构型的变循环涡扇冲压组合发动机的工作原理及优缺点。提炼了变循环涡扇冲压组合发动机的关键技术,包括总体性能仿真技术、高速宽工况风扇设计技术、加力/冲压燃烧室设计技术、热管理系统设计技术以及模态转换设计技术。基于国内需求和相关技术研究现状,给出了变循环涡扇冲压组合发动机后续重点研究方向的建议,包括发动机总体性能设计与仿真工具、发动机多设计点多学科耦合设计方法、发动机热管理系统设计与仿真建模以及关键部件的设计与试验。     

现代军用涡轮喷气发动机主燃油系统燃油积沉实验

通过实验,采用称重法研究了国产航空燃油RP-3在高热负荷下的燃油积沉率与温度的关系.结果表明,在一般情况下,其积沉率低于美国JP-4,JP-,Jet-A,高于Jet-8.实验发现燃油滤网和离心喷嘴切向槽道上均有不同程度的积沉物.      

“两能三元四步”现代学徒制人才培养模式构建探究

现代学徒制是"师带徒"与现代职业教育体系深度融合的一种新型校企合作育人模式,是当前职教改革发展的一个热点方向。针对我国职业院校面临的传统技能人才培养困境,从制度设计、任职资格、师资队伍等维度系统地提出了"两能三元四步"现代学徒制人才培养新模式,为企业技能人才培养途径和职业院校教学质量的提高提供了新的参考。     

网络安全体系分析

阐明了网络安全体系是一个保证网络安全的体系结构,涉及到法律、技术、管理等方面;从 TCP/IP 协议体系角度对网络安全存在的问题入手分析,并对目前采用的安全策略及安全技术进行了剖析。     

空间核反应堆电源技术概览

空间核反应堆电源具有环境适应性好、功率覆盖范围广、结构紧凑以及大功率条件下质量功率比小等突出优点,在军民航天任务中具有广阔的应用前景,是改变未来航天动力格局的颠覆性技术之一。对空间核反应堆电源的原理、特点、适用范围、应用前景、历史发展情况及现状、典型方案、应用安全等进行了系统介绍,对技术发展趋势进行了分析总结,并就我国该技术发展给出一些见解。