Hydrogen storage and distribution systems

Hydrogen storage and transportation or distribution is closely linked together. Hydrogen can be distributed continuously in pipelines or batch wise by ships, trucks, railway or airplanes. All batch transportation requires a storage system but also pipelines can be used as pressure storage system. Hydrogen exhibits the highest heating value per weight of all chemical fuels. Furthermore, hydrogen is regenerative and environment friendly. There are two reasons why hydrogen is not the major fuel of toady’s energy consumption: First of all, hydrogen is just an energy carrier. And, although it is the most abundant element in the universe, it has to be produced, since on earth it only occurs in the form of water. This implies that we have to pay for this energy, which results in a difficult economic task, because since the industrialization we are used to consuming energy for free. The second difficulty with hydrogen as an energy carrier is the low critical temperature of 33 K, i.e. hydrogen is a gas at room temperature. For mobile and in many cases also for stationary applications the volumetric and gravimetric density of hydrogen in a storage system is crucial. Hydrogen can be stored by six different methods and phenomena: high pressure gas cylinders (up to 800 bar), liquid hydrogen in cryogenic tanks (at 21 K), adsorbed hydrogen on materials with a large specific surface area (at T < 100 K), absorbed on interstitial sites in a host metal (at ambient pressure and temperature), chemically bond in covalent and ionic compounds (at ambient pressure), oxidation of reactive metals e.g. Li, Na, Mg, Al, Zn with water. These metals easily react with water to the corresponding hydroxide and liberate the hydrogen from the water. Finally, the metal hydroxides can be thermally reduced to the metals in a solar furnace.     

甘蔗糖蜜酒精废液培养食用菌丝的研究

以甘蔗糖蜜酒废液作为唯一原料对多种食用菌丝进行培养比较，筛选出最适于废液生长的菌种--灵芝菌，并研究了种龄、温度、pH值等对菌丝生长的影响。在不需添加其它营养物质的情况下，培养周期力为4d，菌丝得率达1.1g/100ml。废液的糖浓度从2.1g/100ml降到0.5g/100ml，COD除去率为39％左右。     

加强IS014000环境管理体系在医院推广

简介了1S014000环境管理体系,并论述了IS014001标准在医院的实施步骤,进一步详细分析了环境管理体系对医院安全处置医疗废弃物,加强环境保护工作的推动作用。     

城市模化垃圾焚烧烟气中二氧化硫的生态特性

对模化广州市城市生活垃圾进行焚烧处理 ,从燃烧温度、炉内停留时间、过量空气系数以及垃圾尺寸等方面研究了 SO2 的生成特性和控制条件。     

用改装船处理船舶含油废水

用停封旧船改造油污水接收处理船,统一回收处理运输船舶含油废水,与建造新船相比,缩短了工程周期,节约大量投资,并最快地解决了长江油污染问题。     

大孔强碱阴树脂去除饮用水中微量有机物

比较了大孔强碱阴树脂和颗粒活性炭在饮用水的深度处理中对有机物的去除效果。结果表明：(1)大孔强碱阴树脂的吸附容量比颗粒活性炭的大。在pH为8时,大孔强碱阴树脂对TOC的去除率最高。pH6～8时,对TOC的去除率没有明显的区别,而颗粒活性炭在pH为2时。对TOC的去除率最高;水温低能提高2种吸附材料的吸附容量。(2)在动态实验条件下。当流速相同,大孔强碱阴树脂的穿透时间明显比颗粒活性炭的长,大孔强碱阴树脂的制水量约是吸附床的10000倍。而颗粒活性炭却只有吸附床的4000倍。在饮用水的深度处理中,大孔强碱阴树脂可作为活性炭的最佳替代品。     

生活污水回用作循环冷却水补充水处理方案的研究

分析了自来水及经膜生物反应器处理后的生活污水的水质指标，计算了水质判断指数，结果表明两者均为腐蚀性水质。通过静态缓蚀实验筛选合理的药剂，结果表明HEDP，ATMP，PBTCA的最高缓蚀率均高达90％以匕，HEDP，PBTCA与Zn^2＋复配的协同效果较好，复配后最高缓蚀率提高到98％以上。研究了考虑阻垢问题时的水处理药剂配方，通过正交试验筛选出最佳药剂浓度配方为：T-325：PBTCA：Zn^2＋=8：4：3。     

基于QuickBird卫星影像的徐径镇城市景观格局分析

以2000年和2004年的QuickBird卫星影像解译的徐径镇土地利用类型图为基础，对土地利用类型变化的幅度和土地利用类型之间转换的空间关系进行了研究，同时选取合适的景观格局指数对该区域的景观格局进行了分析。最后，给出结论和建议。     

臭氧室内空气质量评价标准的研究制订

通过分析O3毒理学研究和流行病学研究结果，参考国际权威机构制订的O3健康基准和国外相关标准，在考虑O3室内污染特点和我国目前污染水平的基础上，提出我国室内空气质量标准推荐值。     

壳聚糖絮凝剂在活性污泥调理中的应用

研究了自制的壳聚糖絮凝剂在活性污泥调理中的应用,通过污泥比阻、上清液剩余浊度、泥饼含水率及沉降性能等的测定,重点分析了活性污泥脱水的pH范围、絮凝剂投量和壳聚糖分子量及其脱乙酰度对调理效果的影响,并与絮凝剂聚丙烯酰胺(PAM)和聚合氯化铝(PAC)作了比较,在此基础上还进行了双絮凝剂两段法处理污泥的初步探索。研究发现,壳聚糖作为活性污泥调理剂,投量(干污泥质量百分比)在0.8％～1.2％,pH值在5～8时即有较好的调理效果,与PAM效果基本相当,接近于8％～16％的PAC;壳聚糖相对分子量在30×10~4左右,脱乙酰度在70％左右时有较好的调理效果;双絮凝剂两段法处理污泥,在同等用量时效果好于单絮凝剂一段法。