混凝条件对再生水处理效果的影响试验研究

为研究混凝沉淀试验的最佳工艺条件和各种因素对再生水处理效果的影响,采用混凝剂FeCl3、Al2(SO4)3和PAC与絮凝剂聚丙烯酰胺PAM复配,对污水处理厂二级出水进行静态正交试验和动态混凝沉淀试验.研究结果表明混凝剂投加量是再生水水质最主要的影响因素,聚丙烯酰胺PAM投加量是再生水水质的第二影响因素.最佳处理效果时动态试验混凝剂投加量高于静态试验混凝剂投加量.     

Raney Ni催化4-溴联苯加氢降解研究

以4-溴联苯为模型化合物,研究在H2作氢源、RaneyNi作催化剂条件下4-溴联苯的加氢脱溴反应,并调查了溶剂、碱及温度对加氢脱溴的影响,以及不同催化剂的催化效果.结果表明:相比贵金属催化剂(Ru/C、Pt/C、Pd/C),RaneyNi价廉且有较高的催化活性,具有实际应用价值;有机溶剂中添加适量的水可显著促进加氢脱溴反应,在乙醇/水(V/V)=85/15的溶液中,仅30min4-溴联苯就可100%脱溴;而在纯乙醇中,反应60min,尚有10%的4-溴联苯没有降解.另外,碱(NaOH)的加入可明显提高催化剂的活性,n(NaOH)∶n(HBr)=1.1∶1时,仅需30min4-溴联苯就完全被RaneyNi催化加氢降解;而n(NaOH)∶n(HBr)=2∶1时,反应60min,只有约93%的4-溴联苯发生了加氢降解,因此,碱的加入量以超过其化学反应剂量10%为宜.在温和条件(30～45℃、常压约101kPa)下,RaneyNi可催化4-溴联苯完全脱溴产生联苯,同时,联苯作为重要的化工产品可回收再利用.由此可见,多相催化加氢脱溴有望发展成为控制和消减多溴二苯醚等持久性卤代有机污染物的绿色降解技术.     

4-烷基酚的GC／MS检测及长江南京段的污染状况

于2007年平水期和丰水期及2008年枯水期分别对长江南京段采样,分析调查水质4-烷基酚的污染状况。使用的气相色谱／质谱联用测试方法在10μg/L～500μg/L线性良好,RSD为7．2％－17．9％,平均回收率为76．1％～125％。长江南京段水质受到4-烷基酚一定程度的污染,江水中4－烷基酚的质量浓度枯水期〉平水期和丰水期,4-叔丁基酚的质量浓度〉其他4－烷基酚质量浓度。长江南京段江水中4-壬基酚的含量虽然低于其他水体,但应采取应对措施保护环境。     

高效液相色谱法检测土壤中的壬基酚

建立一种土壤中壬基酚的提取和含量测定方法。土壤样品经二氯甲烷索氏提取、旋转蒸发仪浓缩蒸干后,用色谱流动相溶解。以色谱甲醇与高纯水（体积比为85：15）为流动相,经C18色谱柱分离,在检测波长277nm进行紫外光检测。土壤样品中4-壬基酚的捡出限为20ng／g,4-壬基酚混合标准检测相对标准偏差范围在2．39％-4．56％之间。加入标准溶液后,土壤中壬基酚的加标回收率为98．73％～101．78％,标准偏差小于2．97％。该方法简便快速,灵敏可靠,适用于土壤样品中环境类激素4-壬基酚的含量检测。     

钙基吸收剂液相氧化法协同脱硫脱硝试验

采用CaCO3作为吸收剂,利用单隔板喷射鼓泡实验装置研究了NaCl02作为氧化剂的协同脱硫脱硝效果,并与KMnO4进行了对比.考察了不同试验条件对NO和SO2脱除效率的影响.实验结果表明,同等条件下NaClO2的脱硫脱硝效果优于KMnO4;低pH值有利于NaClO2氯化脱硝,但对于KMnO4氧化脱硝,pH值无明显影响;提高SO2浓度或降低NO浓度均可提高NO脱除效率,NaClO2的氧化脱硝特性较KMnO4显著;提高氧化剂加入量和喷射管浸没深度均可以提高脱硫脱硝效率.     

Enhanced removal of organics by permanganate preoxidation using tannic acid as a model compound – Role of in situ formed manganese dioxide

The effect of permanganate preoxidation on organic matter removal during the coagulation with aluminum chloride was investigated using tannic acid as a model compound. Results showed that a small amount of KMnO4 (0.75 mg/L) increased the removal efficiency of tannic acid up to 20%, as compared to the process of coagulation by aluminum chloride alone. The key factor enhancing the removal efficiency of tannic acid in preoxidation process was the in situ formation of a reductant manganese dioxide. The complexation model was used to describe the reaction between MnO2 and tannic acid. Under weak pH condition, tannic acid was difficult to be adsorbed by MnO2 due to the static electrical repulsive forces. The presence of Ca2+ served as a bridge to hold the negative charged MnO2 and tannic acid together, which could be a crucial factor influencing tannic acid adsorption by in-situ manganese dioxide.     

测定高氯废水CODcr的方法探讨——硫酸汞添加法

化学需氧量是评价水体中有机物污染的重要指标,通常采用CODcr来表示。在其测定过程中氯离子是影响结果准确性的重要因素。由于氯离子的干扰,高氯废水中化学需氧量测定误差较大,尤其对于高氯低化学需氧量的水样,其干扰更为严重。本文对高氯废水化学需氧量的测定方法以及原理进行了阐述,针对不同范围的化学需氧量,对应采用高浓度重铬酸钾氧化法、低浓度重铬酸钾氧化法来测定,最终确定了一种最直接、简便、准确的方法-硫酸汞添加法来测定高氯废水的CODcr。     

COD_(CH_4)/COD值评价垃圾渗滤液厌氧可生化性的研究

基于理论分析,提出CODCH4/COD值作为废水厌氧可生化性的评价指标,确定了CODCH4/COD值表示厌氧可生化性的数值界限。同时,在BMP分析的基础上,采用CODCH4/COD值考察了垃圾渗滤液的厌氧可生化性,并与BOD5/COD值评价结果进行了对比。实验结果显示,CODCH4/COD值与BOD5/COD值用于垃圾渗滤液可生化性的评价,得出的结论具有相似性,但CODCH4/COD值大于BOD5/COD值。究其原因:好氧条件下,总的生化耗氧量(BOD)u小于理论完全需氧量(COD);厌氧条件下,有机物完全去除时CODCH4(理)等于理论完全需氧量。此外,BOD5测试时间仅5 d,而BMP测试时间一般在30 d以上,从而使微生物有足够的时间去适应废水水质,故能较好地反映废水的可生化性。     

Carbon dioxide emissions from spring ploughing of grassland in Ireland

Grassland re-seeding or land-use change requires ploughing, which may enhance carbon dioxide (CO₂) emissions from soil. This study observed the short to intermediate-term (37 days) effects of ploughing on CO₂ emissions from poorly drained grassland using automated soil respiration chambers. Immediately after ploughing, a brief peak in CO₂ emissions from soil occurred with a maximum observed flux of 6.91 g CO₂ m⁻² h⁻¹. Contradictory to other reported results, ecosystem respiration after ploughing was lower on the ploughed than on the grass site. After including estimates of photosynthesis in the analysis, ploughing led to significantly higher net CO₂ emissions than from grassland. The main mechanism of C loss during ploughing was most likely due to a reduction in gross primary production rather than enhanced soil respiration.     

Humic acid and metal ions accelerating the dechlorination of 4-chlorobiphenyl by nanoscale zero-valent iron

Transformation of polychlorinated biphenyls (PCBs) by zero-valent iron represents one of the latest innovative technologies for environmental remediation. The dechlorination of 4-chlorobiphenyl (4-ClBP) by nanoscale zero-valent iron (NZVI) in the presence of humic acid or metal ions was investigated. The results showed that the dechlorination of 4-ClBP by NZVI increased with decreased solution pH. When the initial pH value was 4.0, 5.5, 6.8, and 9.0, the dechlorination efficiencies of 4-ClBP after 48 hr were 53.8%, 47.8%, 35.7%, and 35.6%, respectively. The presence of humic acid inhibited the reduction of 4-ClBP in the first 4 hr, and then significantly accelerated the dechlorination by reaching 86.3% in 48 hr. Divalent metal ions, Co2+, Cu2+, and Ni2+, were reduced and formed bimetals with NZVI, thereby enhanced the dechlorination of 4-ClBP. The dechlorination percentages of 4-ClBP in the presence of 0.1 mmol/L Co2+, Cu2+ and Ni2+ were 66.1%, 66.0% and 64.6% in 48 hr, and then increased to 67.9%, 71.3% and 73.5%, after 96 hr respectively. The dechlorination kinetics of 4-ClBP by the NZVI in all cases followed pseudo-first order model. The results provide a basis for better understanding of the dechlorination mechanisms of PCBs in real environment.