聚合铝盐混凝剂混凝除藻机理与强化除藻措施

针对微污染水处理中藻细胞的去除,研究聚合氯化铝形态分布对混凝除藻效率的影响。结果表明,混凝剂水解产物中,中等聚合物含量影响混凝过程中藻细胞去除率。中等聚合物含量越大,藻细胞去除率越高;在一定条件下,藻细胞去除率与中等聚合物含量线性相关,混凝出水中残铝含量与单体和低聚物含量线性相关。对聚合氯化铝,中等聚合物含量与碱化度线性相关。适量加聚磷酸根、硅酸根可以提高混凝除藻效率,并能显著降低混凝出水中残铝含量,所阐述的混凝除藻机理可以较好地解释实验现象。

改性植物单宁对铜绿微囊藻的去除效果与机理

研究了改性植物单宁(Tanfloc)絮凝对铜绿微囊藻的去除效果、影响因素及机理。10 mg/L的Tanfloc投加量下,10 min内即可获得94%的高去除率,而当投加量进一步增加时,去除率反而略有下降。Tanfloc具有较宽的初始pH值适用范围,在酸性条件下和弱碱性条件下(pH值不大于9.0),藻去除率均超过90%;而在强碱性条件下(pH值不小于10.0),藻去除率逐渐下降。Tanfloc在高藻细胞密度(大于4.87×10^(9)个/L)下可以获得大于95%的高除藻效果。水体pH值会影响除藻机理,pH值为5.5、8.0和9.5时,电中和、静电簇和架桥作用分别是除藻的主要影响因素。

低温等离子体除藻应用的研究进展

低温等离子体具有操作简单、处理效率高、能耗低、环境友好的特点,在水体除藻方面已有研究和应用。在对国内外相关文献归纳和整理的基础上,系统梳理了低温等离子体除藻的机理、不同类型反应器及其应用与除藻效果;综述了低温等离子体除藻效率的影响因素,分析了该技术应用于除藻的优势,并对技术的发展趋势和应用前景进行了展望,以期为低温等离子体除藻的工程化应用提供参考。

聚合硅酸铝铁与聚合氯化铝混凝除藻比较研究

针对武汉市莲花湖湖水,采用聚合硅酸铝铁(PAFSC)和聚合氯化铝(PAC)进行混凝实验,比较了两种混凝剂的混凝效果及原水处理前后藻类群落变化。主要结论如下:(1)无论在低投加量还是在高投加量时,PAFSC的除藻、除浊效果均明显优于PAC。聚合硅酸铝铁与聚合氯化铝投加量增加时,两种混凝剂对原水Chl-a和浊度的去除率均呈现先迅速上升再趋于平缓的过程;(2)PAFSC在去除藻类细胞、浊度方面均优于PAC;(3)PAFSC混凝处理微囊藻为主体的水华原水时,其效果比PAC更好。文章研究后表明:PAFSC是一种新型高效混凝剂,其混凝效果明显优于PAC,当水体以微型藻为主时,可使用PAFSC替代PAC,能提高混凝效果。

溶藻菌与改性黏土对中肋骨条藻去除效果及机理的比较研究

以中国近海典型赤潮藻中肋骨条藻为对象:比较研究了一株类芽孢杆菌属溶藻菌发酵制备的生物絮凝剂和改性黏土的除藻效果;通过扫描电镜观察、Zeta电位、叶绿素荧光特征、溶解性有机质(DOM)组成特征分析,探讨它们的除藻机理。结果表明,两种除藻方法对中肋骨条藻的去除效果高效,24 h去除率均超过94%,但除藻机理存在显著差异:改性黏土通过电中和作用迅速絮凝藻细胞,而溶藻菌则通过直接或间接的方式(如抑制藻类光合作用)裂解并杀死藻细胞。与改性黏土相比,溶藻菌在除藻过程中会产生溶解性微生物产物、类蛋白质和类富里酸等藻源DOM组分,但这些组分会随时间推移被溶藻菌降解或吸收。为应急性联合控藻技术的开发及在赤潮防治领域的应用提供了新思路。

聚合硅酸铝铁与聚合氯化铝混凝除藻比较研究

针对武汉市莲花湖湖水,采用聚合硅酸铝铁(PAFSC)和聚合氯化铝(PAC)进行混凝实验,比较了两种混凝剂的混凝效果及原水处理前后藻类群落变化。主要结论如下:(1)无论在低投加量还是在高投加量时,PAFSC的除藻、除浊效果均明显优于PAC。聚合硅酸铝铁与聚合氯化铝投加量增加时,两种混凝剂对原水Chl-a和浊度的去除率均呈现先迅速上升再趋于平缓的过程;(2)PAFSC在去除藻类细胞、浊度方面均优于PAC;(3)PAFSC混凝处理微囊藻为主体的水华原水时,其效果比PAC更好。文章研究后表明:PAFSC是一种新型高效混凝剂,其混凝效果明显优于PAC,当水体以微型藻为主时,可使用PAFSC替代PAC,能提高混凝效果。

纳米氧化锌颗粒抑制蛋白核小球藻的作用及其机理

目的研究纳米氧化锌颗粒对蛋白核小球藻的抑制作用及其机理，为船舶压舱水赤潮藻的杀灭提供理论依据。方法采用小球藻培养计数法和生物测定方法，对纳米氧化锌颗粒抑制蛋白核小球藻的作用及其作用机理进行实验室观察。结果用浓度为0．5mg／L纳米氧化锌颗粒作用48h，对蛋白核小球藻的抑制率达到60％。悬液内加入0．5-5mg／L纳米氧化锌颗粒，作用96h，蛋白小球藻悬液内抗氧化歧化酶含量升高，叶绿素a和b及总含量均随着投加量的增加而增加。结论纳米氧化锌颗粒对水中小球藻具有一定的抑制作用，其对藻细胞的除藻机理是通过改变蛋白核小球藻叶绿素等生化组成，引起藻细胞抗氧化物酶活性的变化抑制藻类增长。

Biosorption Behavior and Mechanism of Lead(II) from Aqueous Solution by Aerobic Granules(AG) and Bacterial Alginate(BA)

Lead(Pb) and its compounds are common pollutants in industrial wastewaters.To develop appropriate Pb 2+ treatment technologies,aerobic granules(AG) and bacterial alginates(BA) were studied as alternative biosorbents to remove Pb 2+ from aqueous solutions.The biosorption mechanism of AG and BA were further analyzed to determine which functional groups in AG and BA are active in Pb 2+ biosorption.In this paper,the Pb 2+ biosorption behavior of AG and BA was respectively investigated in batch experiments from the perspectives of the initial pH,contact time,and initial Pb 2+ concentration.The results showed that biosorption of Pb 2+ by AG and BA occurred within 60min at the initial Pb 2+ concentrations(0 150 mg L-1).The actual saturated Pb 2+ biosorption capability of AG was 101.97 mg g-1(dry weight of aerobic granular biomass).When the initial pH was 5,the biosorption capability of AG and BA was highest at the initial Pb 2+ concentrations(0 20mg L-1).During the process of Pb 2+ biosorption,K +,Ca 2+,and Mg 2+ were released.The Ion Chromatography(IC) and Fourier Transform Infrared Spectroscopy(FTIR) further highlighted the main role of ion exchange between Ca 2+ and Pb 2+ and sequestration of Pb 2+ with carboxyl(-COO) of AG and BA.This analogical analysis verifies that BA is responsible for biosorption of Pb 2+ by AG.At the same optimal pH,AG cultivated with different carbon source has different Pb 2+ biosorption capacity.The Pb 2+ biosorption by AG with sodium acetate as the sole carbon source is higher than AG with glucose as carbon source.

Fluoride Removal by Lanthanum Alginate Bead: Adsorbent Characterization and Adsorption Mechanism

Lanthanum alginate bead is a new, highly active adsorbent. In the present study, we investigated its ad- sorption performance and its adsorption mechanism. The adsorption isotherm for fluoride onto lanthanum alginate b ead fits the Langmuir model well, and the maximum adsorption capacity is 197.2 mg·g-1. X-ray diffraction shows the amorphous nature of lanthanum alginate bead, which allows for better accessibility to fluoride and thus better activity. Infrared spectra of lanthanum alginate bead before and after adsorption confirm its stable skeletal structure. Scanning electron microscopy shows that the dense surface structure of the adsorbent appear cracks after adsorption. T he adsorption mechanism of lanthanum alginate bead is considered as an ion exchange between F- and Cl- or OH-, as verified from the adsorbent and the solution by pH effect, energy dispersive X-ray, and ion chromatography.

复合高铁酸盐对含铜绿微囊藻原水的净化效果

采用复合高铁酸盐处理含铜绿微囊藻原水，考察了其除藻的影响因素和对原水的净化效果，同时考察了其与聚合氯化铝（PAC）的联用效果及除藻机理。结果表明，原水pH值和复合高铁酸盐的氧化时间均对铜绿微囊藻的去除具有明显影响，最佳pH值为5～6、最佳氧化时间为15min；在一定范围内增加复合高铁酸盐的投量可明显提高除藻效果。另外，复合高铁酸盐预氧化可降低TP浓度，但由于藻细胞的破裂，TN和UV254值会升高。当复合高铁酸盐与PAC联用时，两者对除藻及去除TP和UV254具有协同效果。复合高铁酸盐的除藻机理为直接破坏铜绿微囊藻的细胞壁．使胞内物盾流出从而导致藻细胞死亡．