湿法烟气脱硫关键影响因素及新型单塔双循环技术

分析了石灰石-石膏湿法烟气脱硫(LGWFGD)技术的关键影响因素:液气比、浆液pH值、浆液密度的影响规律,发现在浆液pH值和浆液密度的选择时不能同时满足高脱硫效率和高石膏品质的要求。为解决这一矛盾,提出一种新型的单塔双循环技术,在两个相对独立的浆液循环系统中可以分别调节浆液pH值和浆液密度,使得高脱硫效率和高石膏品质的需求同时得到满足。     

A review of textile industry: Wet processing,environmental impacts,and effluent treatment methods

The word “textile” means to weave and was taken from the Latin word “texere.” Nowadays, textiles not only fulfill humankind's basic necessity for clothing, they also allow individuals to make fashion statements. As one of the oldest industries, the textile industry occupies a unique place in India. It is responsible for 14% of the total industrial manufacture in India. However, the textile industry is also considered to be one of the biggest threats to the environment. Pretreatment, dyeing, printing, and finishing operations are among the various stages of the industrial textile manufacturing process. These fabrication operations not only utilize huge quantities of power and water, they also generate considerable amounts of waste. The textile industry utilizes a number of dyes, chemicals, and other materials to impart the required qualities to the fabrics. These operations produce a significant amount of effluents. The quality of effluents is such that they cannot be put to other uses, and they can create environmental problems if they are disposed of without appropriate treatment. This review discusses different textile processing stages, pollution problems associated with these stages, and their eco‐friendly alternatives. Textile wet processing is described in detail, as it is the key process in the industry and it also generates the greatest amount of pollutants in textile processing. The environmental impact of textile effluents is discussed, as textile effluents not only impose negative effects on the quality of water and soil, they also imperil plant and animal health. In this paper, various methods for treating textile effluents are described. Discussion of physical, chemical, biological, and advanced treatment technologies of effluent treatment are included in this paper.     

接地极雾化电晕放电旋风除尘器的实验研究

静电旋风除尘器的除尘效率高,占地面积小,安装方便,得到了广泛的应用。比较了接地极雾化电晕放电旋风除尘器,静电旋风除尘器和传统旋风除尘器的放电特性、捕集效率、分割粒径、分级效率和对高比电阻的适应能力。研究表明:首先,流量为80 m L/min时,接地极雾化电晕放电旋风除尘器的起晕电压和放电电流均优于静电旋风除尘器;其次,接地极雾化电晕放电旋风除尘器的分割粒径和分级效率都明显优于静电旋风除尘器,而分级效率更是较传统旋风除尘器提高了15%以上。最后,当粉尘的比电阻增大时,接地极雾化电晕放电旋风除尘器的收集效率保持稳定,几乎不随工作时间改变,而静电旋风除尘器的效率则随着工作时间的增加而降低。因此,接地极雾化电晕放电技术更有利于高比电阻粉尘的捕集,应用前景广阔。     

滇池流域入湖河流丰水期大型底栖动物群落特征及其与水环境因子的关系

研究了滇池流域入湖河流丰水期大型底栖动物群落特征及其与水环境因子的关系.在滇池流域29条入湖河流2009年7～8月进行大型底栖动物群落调查,并在2008年9月～2009年8月进行逐月17项水环境指标监测,目的是阐明滇池流域入湖河流丰水期大型底栖动物群落特征,识别影响大型底栖动物群落特征的主要水环境因子,比较大型底栖动物群落Shannon-Weaver多样性指数与水环境质量评价空间分布格局的特点.滇池流域入湖河流丰水期共检出大型底栖动物3门7科8属(其中环节动物门4科5属,软体动物门2科2属,节肢动物门1科1属),群落结构以环节动物门的水丝蚓属(耐污生物)为优势属;TN、 NH⁺₄-N、 TP和DO是影响大型底栖动物群落特征的主要水环境因子,分别为2.03～32.00、 0.34～26.66、 0.09～3.20、 0.10～6.80 mg/L;大型底栖动物群落Shannon-Weaver多样性指数与水环境质量评价的空间分布格局一致,均为流域北部入湖河流(王家堆渠、新运粮河、老运粮河、乌龙河、大观河、西坝河、船房河、采莲河、金家河、盘龙江、大青河、海河、六甲宝象河、小清河、五甲宝象河、虾坝河、老宝象河、新宝象河和马料河)污染状况严重程度>流域南部入湖河流(淤泥河、老柴河、白鱼河、茨巷河、东大河、中河和古城河)>流域东部入湖河流(洛龙河、捞鱼河和南冲河).     

干湿球法测量烟气湿度的准确性探讨

通过选择典型的温湿度污染源,利用干湿球法在不同湿球水套环境条件下对污染源烟气湿度进行现场比对测试,监测结果分析表明,干湿球法测定污染源烟气湿度在湿球水套温度改变的情况下,测量结果会随着外环境温度升高而变大,两者之间呈正相关关系。     

工业废水催化湿式氧化处理的研究

采用系列贵金属-半导体氧化物催化剂,在高压釜中250℃液相条件下对焦化厂等工业废水以及由氨、吡啶等组成的模拟废水进行液相氧化试验。结果发现几种催化剂对不同污染物有不同序列的催化氧化活性,其净化作用有各自的选择性。WT-501催化剂对氨和有机污染物均有高活性,焦化废水经WT-501催化氧化处理后’COD、NH_3分別从9302mg/L和5230mg/L降至619mg/L和47mg/L,去除率高达93.2％和99％。     

废水中氨氮湿式空气氧化和超临界水氧化研究进展

湿式空气氧化法(WAO)和超临界水氧化法（SCWO)废水处理技术近年已有广泛研究。当催化剂存在于氧化体系时,不仅能降低反应温度、压力,而且可提高废水中有害物质的降解效率。介绍了氨的湿式空气氧化和超临界水氧化催化剂应用的研究进展、各种催化剂在超临界水中的稳定性能及氨的催化超临界水氧化情况。     

石灰/石灰石湿法脱硫中添加剂的研究

在φ150旋流板塔烟气脱硫装置上,试验了不同液气比和进口气SO₂浓度时有机废液（NaAd）作添加剂的影响。结果表明,添加NaAd有利于提高脱硫率和吸收剂利用率,并减缓结垢。添加适量的NaAd可使脱硫率提高5个百分点以上,气相单板效率Emv相应提高12个百分点以上。实验还研究了添加NaAd对浆液pH值、粘度,以及浆液中颗粒沉降、凝聚、粒度等物理化学特性的影响,并根据实验结果,提出了NaAd添加剂的作用机理。     

H－酸废母液的湿式空气氧化处理

研究了用湿式氧化法处理染料中间体Ｈ－酸废母液。在２００－２５０℃,Ｐｏ２＝１－３Ｍｐａ下,Ｈ－酸的湿式氧化反庆可分为２个阶段,最初１０ｍｉｎ为快反应段。ＣＯＤ快速下降,ＵＶ／可见光吸光度先急剧升高,之后快速降低;慢反应段延续到３０ｍｉｎ,ＣＯＤ和吸光度缓慢下降,其后变化不大,经过湿式氧化处理之后,可生化性大幅度改善,在１６０℃,充氧３ＭＰａ,反应１ｈ,可使１０ｇ／Ｌ的Ｈ－酸液的ＣＯＤ降低５０％,Ｄ     

Impact of Fly Ash from Coal-Fired Power Stations in Delhi, with Particular Reference to Metal Contamination

Indraprastha Power Station (IPP Stn) and Rajghat Power House (RPH), owned by Delhi Electric Supply Undertaking, are both coal-fired power stations located on Ring Road in New Delhi. Ash content of the coal used ranges between 38–47%. The ash is collected in electrostatic precipitators which have an efficiency of 99.3% (IPP station), and 99.7% (RPH). There are instances of major dust pollution around the power stations from fly ash dispersal. The main method of disposal of fly ash from the power stations is by mixing with water, the resultant slurry is pumped through pipes to ash disposal ponds. The supernatant from these ponds is discharged into River Yamuna. Field studies have revealed large quantities of fly ash being deposited into the river. Local populations of Eichhornia crassipes have reduced dramatically between 1987–1995, with a marked reduction in the year 1994–1995. Field studies, conducted in January, 1995 have investigated the impact of fly ash dispersal in the Delhi region with particular reference to metal contamination. Elemental concentrations for a range of elements are determined by ICP-AES in fly ash and top soils along four transects from the power stations up to a distance of 8 km. The effects of fly ash leachates from the ash settling ponds on the river are determined by analyzing river overbank soils and vegetation for their elemental contents. It is concluded that fly ash dispersal from the stacks are a source of alkali, alkaline-earth and to some extent heavy metals in soils in the vicinity of the power stations, and enrichment of elements in river overbank soils are a result of discharge of fly ash leachates from ash disposal ponds. However, the impact from both these sources of metal contamination is not large enough to give cause for concern. Marked reduction in populations of Eichhornia crassipes downstream of the river where it receives leachates from the ash disposal ponds are attributed to turbidity of the ash pond leachates and metal toxicity. Elemental enrichment in the floodplain soils, as a result of fly ash particle deposition during monsoons, may enhance the horticultural value of these soils as is shown by a healthy cultivated crop of Brassica juncea.