城市垃圾能量估算方法探讨

本文根据Ｄｕｌｏｎｇ公式的计算结果，建立了根据城市垃圾组成的重量百分比估算城市垃圾能量的经验公式，并对它进行了检验。估算结果与Ｄｕｌｏｎｇ公式的计算结果进行相关分析，相关系数在０．９８以上，该经验公式具有较好的推广价值，用此公式对我国部分城市垃圾的能量进行了估算。     

3OCrMnSiA钢的快速循环球化退火的研究

通过对30CrMnSiA钢的球化退火工艺进行的研究,推荐了一种适用于该材料的最佳快速循环球化退火工艺,不仅节能效果明显,而且工艺操作简单,质量稳定。所得结果对生产中正确选择球化工艺有一定的指导意义。     

煤矿生活污水强化一级处理的可行性研究

叙述煤矿生活污水的水质特点和处理现状，分析强化一级处理工艺与效果，对其应用于煤矿生活污水进行了可行性研究，认为煤矿生活污水强化一级处理技术可行，经济实用。     

低药耗费通试剂氧化乙二醇废水的实验研究

对排放量小，间歇排放的乙二醇废水进行费通试剂催化氧化处理的条件研究。结果表明，在合适的条件下，采用费通试剂催化氧化－－加碱凝聚分离－－处理水循环回流的工艺。ＣＯＤＣｒ去除率达９６％，处理水可稳定达标排放。此工艺具有降低药耗，提高ＣＯＤｃｒ去除率的双重效果。     

新世纪的清洁能源--燃料电池

介绍了一种高效，环境良好的发电方式-燃料电池发电技术，阐述了燃料电池的发电原理及其开发现状，对其发展前景作了展望。     

能源安全观助解我国《能源法》之结

中国已相继出台诸如《煤炭法》、《电力法》、《节约能源法》、《可再生能源法》等一系列与能源有关的法律法规,但严峻的能源形势使得一部能源领域的基本法的制定成为迫切需要.美国《能源政策法2005》在一定程度上对我国《能源法》的构建有很好的借鉴意义,但中国要制定《能源法》首先应结合中国的国情对《能源法》进行科学定位.能源安全观作为一种基本理念对把能源安全放在首位的《能源法》来说有着特殊重要的意义,这个基本理念将对《能源法》的基本原则和基本制度的理性建构产生深刻的影响.     

"猪、沼、果(蔬菜)"能源生态工程实例

新安江万秋生态养殖场实施"猪、沼、果(蔬菜)"能源生态模式工程,其采用三级厌氧消化工艺,以沼气为纽带,连接种养业,不仅有效处理养殖污染物,保护农村生态环境,而且通过农业废弃物的资源化利用,增收节支,提高生态农业生产能力,实现农业增效,农民增收的目的.该工程不仅做到经济和环境保护双赢,而且为建设社会主义新农村起到了很好的示范作用.     

能源结构调整与生态建设并举根治呼和浩特市大气污染

针对呼和浩特市大气污染问题，本文分析了现存问题提出了具体的解决思路。     

Revisit ocean thermal energy conversion system

The earth, covered more than70.8% by the ocean, receives most of itsenergy from the sun. Solar energy istransmitted through the atmosphere andefficiently collected and stored in thesurface layer of the ocean, largely in thetropical zone. Some of the energy isre-emitted to the atmosphere to drive thehydrologic cycle and wind. The wind fieldreturns some of the energy to the ocean inthe form of waves and currents. Themajority of the absorbed solar energy isstored in vertical thermal gradients nearthe surface layer of the ocean, most ofwhich is in the tropical region. Thisthermal energy replenished each day by thesun in the tropical ocean represents atremendous pollution-free energy resourcefor human civilization. Ocean ThermalEnergy Conversion (OTEC) technology refersto a mechanical system that utilizes thenatural temperature gradient that exists inthe tropical ocean between the warm surfacewater and the deep cold water, to generateelectricity and produce other economicallyvaluable by-products. The science andengineering behind OTEC have been studiedin the US since the mid-seventies,supported early by the U.S. Government andlater by State and private industries.There are two general types of OTECdesigns: closed-cycle plants utilize theevaporation of a working fluid, such asammonia or propylene, to drive theturbine-generator, and open-cycle plantsuse steam from evaporated sea water to runthe turbine. Another commonly known design,hybrid plants, is a combination of the two.OTEC requires relatively low operation andmaintenance costs and no fossil fuelconsumption.OTEC system possesses a formidablepotential capacity for renewable energy andoffers a significant elimination ofgreenhouse gases in producing power. Inaddition to electricity and drinking water,an OTEC system can produce many valuableby-products and side-utilizations, such as:hydrogen, air-conditioning, ice,aquaculture, and agriculture, etc. Thepotential of these by-products, especiallydrinking water, aquaculture andmariculture, can easily translate intobillions of dollars in businessopportunities. The current status of theOTEC system definitely deserves to becarefully revisited. This paper willexamine recent major advancements intechnology, evaluate costs andeffectiveness, and assess the overallmarket environment of the OTEC system anddescribe its great renewable energypotential and overall benefits to thenations of the world.     

Bioenergy to mitigate for climate change and meet the needs of society,the economy and the environment

Changes towards environmental improvementsare becoming more politically acceptableglobally, especially in developedcountries. Society is slowly moving towardsseeking more sustainable productionmethods, waste minimisation, reduced airpollution from vehicles, distributed energygeneration, conservation of native forests,and reduction of greenhouse gas (GHG)emissions. Modern biomass, when used tosupply useful bioenergy services, has arole to play in each one of theseenvironmental drivers at both the large andsmall scales.This paper describes recent developments inbiomass supply and the technologies for itsconversion to bioenergy including biofuelsfor transport. It examines the economic,environmental and social benefits andidentifies barriers to bioenergy projectimplementation. Future opportunities forbiomass as a carbon (C) sink, a C offsetand a potential source of renewablehydrogen are discussed.Whether or not a bioenergy project iseconomically viable, as well as being trulyrenewable, sustainable and environmentallysound, is determined mainly by the sourceof biomass. The social benefits from usingbiomass are also valuable, though they areoften not clearly presented when proposingnew bioenergy projects or conductinganalyses of existing plants. Employmentrates per MWh or per GJ exceed those whenusing fossil fuel supplies to provide thesame energy service. `Ownership' bystakeholders and local communities at anearly stage in the development process isthe key to successful project developmentin order to share the benefits. Bioenergyhas a significant global role to play inthe mitigation of atmospheric GHG concentrations.