低浓度废水厌氧处理中不同动力学模型对比研究

采用厌氧颗粒污泥处理低浓度废水来启动实验规模的沼气提升厌氧反应器,以啤酒废水为例,厌氧反应器在温度(35±1)℃和进水COD浓度在2100~2400mg/L条件下,通过提高进水量方式,来缩短水力停留时间HRT和提高有机负荷OLR.用First-order、Monod and Contois、Grau second-order和Modified Stover–Kincannon动力学模型,考察在不同的HRT和进水浓度Si条件下,出水浓度Se与前两者的关系,确定动力学参数.实验结果表明:First-order和Monod and Contois模型不适用本实验,Grau second-order和Modified Stover–Kincannon模型适用,通过后两个模型公式分别比较实验值Se与计算值Se的差别,Grau second-order模型比Modified Stover–Kincannon模型更接近实验值.     

改性膨润土对J酸溶液和废母液处理效果

研究了改性膨润土对Ｊ酸溶液和Ｊ酸废母液的处理效果,结果表明,改性膨润土对Ｊ酸溶液的处理效果比Ｊ酸废母液要好,对Ｊ酸废母液的去除效果与ｐＨ和硫酸钠含量有关,在中性或弱碱性条件下,硫酸钠含量越低。对Ｊ酸废母液的去除率越高,最高可达到５０％左右。     

改性玉米秸秆吸附去除废水中四环素的研究

应用平衡吸附法,研究了不同投加量（改性玉米秸秆）、温度及pH条件下,改性玉米秸秆对水体中四环素的吸附作用,并利用等温曲线及吸附动力学方程对试验结果进行了拟合。结果表明：在吸附剂用量0．4g,温度30℃,振荡时间30min,pH值7的条件下,对水体中四环素浓度为50．136mg／L的吸附率可达93．4％。四环素废水吸附均符合Langmuir及Freundlich等温模式。但Langmuir方程拟合得较好,Elovich方程能更好地拟舍改性玉米秸秆对水体中四环素的吸附动力学曲线。     

高氨氮浓度下改良型倒置A~2/O工艺的脱氮性能研究

针对高氨氮生活污水,设计了一种新型的脱氮除磷工艺。该工艺是对传统倒置A~2/O工艺的改进,它采用了后置预缺氧区以提高系统的脱氮效果。试验探讨了工艺关键因素与脱氮效果的相关性。试验表明水力停留时间为25 h,内回流比为200%,DO浓度在2 mg/L时,对NH_3-N、TN、TP的去除率分别可达96.17%、73.83%和92.38%。     

同步硝化反硝化影响因素的研究

试验采用改良SBR工艺处理人工模拟生活废水,研究不同的C/N,DO和好氧区与缺氧厌氧区体积比对同步硝化反硝化的影响,结果表明:C/N为12,ρ(DO)为1.0～2.0mg·L-1、好氧区与缺氧厌氧区体积比为1∶1时,反应器内高效稳定地实现了同步硝化反硝化脱氮过程。     

塞曼效应石墨管原子吸收法测定人尿痕量镉

以磷酸二氢铵（ＮＨ４、Ｈ２ＰＯ４）作基体改良剂，用塞曼效应扣除背景直接进行石墨管原子吸收法测定尿中痕量镉，该法最低检出限为０．０２４μｇ／Ｌ，相对标准在４．５％，回收率达９５－１１２％。．     

Electrochemical analysis of endosulfan using a C18-modified carbon-paste electrode

Successful applications of different analytical procedures to determine quantitatively endosulfan and its metabolites in aqueous media can be found in recent literature. Fundamentally, they have made use of solid-phase extraction (SPE) and gas (GC) or liquid chromatography (LC), sometimes coupled to mass spectrometry (MS). In this paper, a new and alternative methodology to determine quantitatively endosulfan in aqueous media is reported. A C18-modified carbon-paste electrode has been used to determine voltammetrically endosulfan, despite its unfavourable electrochemical properties and behaviour. The methodology proposed is based on the decrease experienced by the peak intensity corresponding to voltammetric signals of Cu(II) when successive and constant additions of endosulfan are carried out. This decrease is directly proportional to the concentration of endosulfan what allows to perform an indirect quantification of the pesticide. The detection limit obtained is 40 ng l⁻¹, this value being under the limits specified by European norms and EPA reports.     

Competitive effects and interactions during sorption of SMP fractions on activated carbon: response surface approach for visualization of sorption profiles

The objectives of this study were to investigate the significance of the effects and interactions for during competitive sorption of soluble microbial products (SMP). Batch experiments were conducted to assess the competitive sorption characteristics and individual affinity of glucose (carbohydrate) and bovine serum albumin (BSA) (protein) as two representative fractions of SMP. The influence of surface availability was investigated by using carbon particles with different particle sizes (5-75 μm, 75-850 μm, and 850-1000 μm) and different carbon amounts. Competitive effects and interactions were evaluated for each adsorbate and surface availability. Competitive sorption mechanisms were quantified in relation to surface affinity of the SMP fractions. Sorption capacity profiles of the SMP fractions at equilibrium were developed using second-degree polynomial models for the experimental data and compared with the estimates obtained from the modified Langmuir-like model which uses single parameter sorption data to estimate competitive sorption profiles of systems with two adsorbates. Adequacy limitations of the modified Langmuir-like model for each SMP fraction were evaluated based on the significance of the synergistic and antagonistic effects between the two SMP fractions and the carbon surface availability.     

Profiles of and variations in aluminum species in PAC-MC used for the removal of blooming microalgae

Polyaluminum chloride modified clay (PAC-MC) is a safe and efficient red tide control agent that has been studied and applied worldwide. Although it is well known that the distribution of hydrolytic aluminum species in PAC affects its flocculation, little is known about the influence of particulars aluminum species on the microalgae removal efficiency of PAC-MC; this lack of knowledge creates a bottleneck in the development of more efficient MCs based on aluminum salts. The ferron method was used in this study to quantitatively analyze the distributions of and variations in different hydrolytic aluminum species during the process of microalgae removal by PAC-MC. The results showed that Al_a, which made up 5%–20% of the total aluminum, and Al_p, which made up 15%–55% of the total aluminum, significantly affected microalgae removal, with Pearson's correlation coefficients of 0.83 and 0.89, respectively. Most of the aluminum in the PAC-MC sank rapidly into the sediments, but the rate and velocity of settlement were affected by the dose of modified clay. The optimal dose of PAC-MC for precipitating microalgae was determined based on its aluminum profile. These results provide guidance for the precise application of PAC-MC in the control of harmful algal blooms.     

Influence of zeta potential on the flocculation of cyanobacteria cells using chitosan modified soil

Using chitosan modified soil to flocculate and sediment algal cells has been considered as a promising strategy to combat cyanobacteria blooms in natural waters. However, the flocculation efficiency often varies with algal cells with different zeta potential (ZP) attributed to different growth phases or water conditions. This article investigated the relationship between ZP of Microcystis aeruginosa and its influence to the flocculation efficiency using chitosan modified soil. Results suggested that the optimal removal efficiency was obtained when the ZP was between − 20.7 and − 6.7 mV with a removal efficiency of more than 80% in 30 min and large floc size of > 350 μm. When the algal cells were more negatively charged than − 20.7 mV, the effect of chitosan modified soil was depressed (< 60%) due to the insufficient charge density of chitosan to neutralize and destabilize the algal suspension. When the algal cells were less negative than − 6.7 mV or even positively charged, a small floc size (< 120 μm) was formed, which may be difficult to sink under natural water conditions. Therefore, manipulation of ZP provided a viable tool to improve the flocculation efficiency of chitosan modified soil and an important guidance for practical engineering of cyanobacteria bloom control.