废水中总氮含量低于氨氮含量原因探讨

针对废水水质分析过程中出现的氨氮含量高于总氮含量的情况,对氨氮测定过程和总氮测定过程中的金属离子干扰、标准曲线绘制、消解时间等进行了分析,提出氨氮含量高于总氮含量是由于总氮消解时间不够,导致过硫酸钾的转化不完全造成的。实验结果表明,将总氮消解时间设定为40min可以解决此问题。为提高测定的准确性,在实验中还应注意实验环境、计量器具及高压灭菌锅的密封性等问题。     

一种利用粉煤灰和生物质制备催化剂的方法及应用

正该专利涉及一种利用粉煤灰和生物质制备催化剂的方法及其电化学氧化降解处理有机废水的方法。催化剂的制备方法如下:先将生物质破碎、筛分后,用去离子水清洗、烘干,将烘干的生物质加入到过渡金属离子溶液中浸渍吸附;同时将粉煤灰烘干后加入到过渡金属离子溶液中浸渍吸附;将吸附过渡金属离子后的粉煤灰和生物质过滤、洗涤、烘干;将二者按一定比例混合均匀,加入黏结剂、水玻璃和液体石蜡,挤压成型,烘干,高温煅烧活化,得到催化剂。该催化剂可用于电化学氧化降解     

PVA降解混合菌系生长和产酶的营养条件分析

研究碳源、氮源以及不同金属离子对PVA降解混合菌系生长和产酶的影响。结果表明,混合菌系生长过程中无机氮源优于有机氮源;补充碳源可促进混合菌系的生长,但酶活比不添加时稍有降低。金属离子对酶活影响的正交实验表明Mg2＋浓度影响最大,其次是Fe2＋和K＋浓度,Ca2＋、Mn2＋、Zn2＋和Cu2＋浓度影响较小;最佳浓度分别为Mg2＋0.05 g/L、Fe2＋0.04 g/L、K＋2 g/L和Ca2＋0.05 g/L。     

微量金属元素及其配合物对厨余垃圾甲烷发酵的影响

生物可利用的微量金属元素不仅能够保证污染物以最大的速率转化，而且还可以使某些特殊的转化得以发生，并提高微生物对有毒污染物质的耐受能力。在研究厨余垃圾总固体浓度(total solid, TS)、接种量和C/N比对厨余垃圾厌氧发酵影响的基础上，重点探讨微量金属元素钴及其配合物丝氨酸对厨余垃圾厌氧发酵甲烷产量及关键酶含量的影响。结果表明，当TS为0.5%、接种污泥量为100 mL/L和C/N比为20∶1时，厨余垃圾厌氧发酵的甲烷产率较高，为367 mL/g COD；添加2 μmol/L的微量金属元素钴-配合物丝氨酸时，甲烷产率则提高到432 mL/g COD，相应地，辅酶M的含量由空白实验的41.21 μmol/g VSS提高到54.64 μmol/g VSS，辅酶F₄₂₀的含量由0.31 μmol/g VSS提高到0.48 μmol/g VSS。     

金属离子对δ-MnO2 去除对叔辛基酚抑制作用的研究

研究了pH 4.0的水溶液中各种金属离子对合成的δ-MnO2去除对叔辛基酚(4-t-OP)的影响.实验表明反应150 min时,δ-MnO2对4-t-OP的去除率达到100%,但当反应体系中含有金属离子时,去除效果受到抑制.抑制效果随金属离子浓度的增加而增大,并随金属离子的不同表现出较大的差异.在pH 4.0条件下,Pb2+和Mn2+的抑制效果最强,其次为过渡金属离子,再次是碱土金属离子,而碱金属离子基本上不产生抑制作用.还比较了δ-MnO2对多种金属离子的吸附能力,其对Pb2+的吸附作用最强,在其余的金属离子中,对过渡金属离子的吸附量稍大于碱土金属离子.结果表明,金属离子所产生抑制作用的源于其占据了δ-MnO2表面反应位点并与4-t-OP形成竞争,而抑制作用大小的差异主要来源于δ-MnO2与金属离子间吸附作用强弱的差别,MnO2表面结构的变化,以及溶液中自由态金属离子的分布比例及其离子半径的不同.     

Effect of transition metal doping under reducing calcination atmosphere on photocatalytic property of TiO2 immobilized on SiO2 beads

TiO₂ immobilized on SiO₂ (TiO₂/SiO₂) have been prepared by sol-gel method and various ions of transition metals (Cr³⁺, Co²⁺, Ni²⁺, Cu²⁺, and Zn²⁺) were doped on the photocatalyst using wet impregnation method under reducing calcination atmosphere. The photocatalytic activity of metal doped TiO₂/SiO₂ towards phenol degradation under black light irradiation were investigated and compared with undoped TiO₂/SiO₂. The results showed that the photoresponse of Cu²⁺ and Zn²⁺ doped TiO₂/SiO₂ were larger than undoped TiO₂/SiO₂, indicating that the photogenerated carriers were separated more efficiently in Cu²⁺ and Zn²⁺ doped TiO₂/SiO₂. The reactivity was in the order of Cu²⁺ > Zn²⁺ > Ni²⁺ > Cr³⁺ > Co²⁺. The different photoreactivity was ascribed to combine effect of the different ionic radii and photocorrison tendency of the dopants. The sample was also characterized by surface analytical methods such as X-ray diffraction, scanning electron micrograph/electron dispersive X-ray analyzer and UV-Vis absorption spectrum.     

Iron and lead ion adsorption by microbial flocculants in synthetic wastewater and their related carbonate formation

Although microbial treatments of heavy metal ions in wastewater have been studied, the removal of these metals through incorporation into carbonate minerals has rarely been reported. To investigate the removal of Fe^3＋ and Pb^2＋, two representative metals in wastewater, through the precipitation of carbonate minerals by a microbial flocculant （MBF） produced by Bacillus mucilaginosus. MBF was added to synthetic wastewater containing different Fe^3＋ and Pb^2＋ concentrations, and the extent of flocculation was analyzed. CO2 was bubbled into the mixture of MBF and Fe^3＋/Pb^2＋ to initiate the reaction. The solid substrates were analyzed via X-ray diffraction, transmission electron microscopy and energy dispersive spectroscopy. The results showed that the removal efficiency decreased and the MBF adsorption capacity for metals increased with increasing heavy metal concentration. In the system containing MBF, metals （Fe^3＋ and Pb^2＋）, and CO2, the concentrated metals adsorbed onto the MBF combined with the dissolved CO2, resulting in oversaturation of metal carbonate minerals to form iron carbonate and lead carbonates. These results may be used in designing a method in which microbes can be utilized to combine CO2 with wastewater heavy metals to form carbonates, with the aim of mitigating environmental problems.     

小球藻培养条件优化及油脂积累特征

为探索小球藻光生物反应器培养和油脂积累的最佳条件,就pH和不同浓度的NO3-N、Mg2+、Fe3+和Zn2+等环境因素对小球藻生长的影响进行了探讨,同时应用尼罗红染色荧光法对各环境因子条件下小球藻细胞内油脂积累状况进行了动态监测;继而应用正交实验对显著影响小球藻生长和油脂积累的培养条件进行了组合优化。结果表明:高浓度的NO3-N、Mg2+、Fe3+可促进小球藻的生长,而Zn2+则抑制其生长,pH对其生长及油脂积累影响不明显;在一定范围内,氮限制和高浓度的金属离子可以有效地促进小球藻油脂的积累;小球藻最优培养条件组合为:Fe3+浓度为12μmol/L,Zn2+浓度为7.2μmol/L,NO3-N浓度为0.3 mmol/L。     

聚合铝铁对A2/O系统 EPS及生物絮凝性能的影响

通过向实验室构建的A2/O模型好氧池末端投加聚合铝铁(PAFC)来强化系统的生物除磷,使得出水总磷达到《城市污水处理厂污染物排放标准GB 18918-2002》中的一级A标准,并重点分析投加的PAFC对A2/O系统中活性污泥胞外聚合物(EPS)和活性污泥生物絮凝性能的影响.结果表明,随着PAFC投药量的增加,A2/O系统活性污泥EPS总量变化不大,但EPS组分中蛋白/多糖含量的比值逐渐降低,由投药前的3.30降低至投药后的2.30;EPS中金属离子含量逐渐增加,在厌氧-缺氧-好氧的运行周期内,各处理单元污泥的EPS中金属铝离子含量增加.投加PAFC后,活性污泥颗粒变大,二沉池出水的Zeta电位明显降低,由投药前-15.83 mV降低至-21.20 mV,污泥产量增加.因此,适量投加PAFC后,生物絮凝性能得到改善,出水中悬浊颗粒减少,出水水质变好.     

Removal of copper ions from aqueous solution by calcium alginate immobilized kaolin

Kaolin has been widely used as an adsorbent to remove heavy metal ions from aqueous solutions. However, the lower heavy metal adsorption capacity of kaolin limits its practical application. A novel environmental friendly material, calcium alginate immobilized kaolin (kaolin/CA), was prepared using a sol-gel method. The e ects of contact time, pH, adsorbent dose, and temperature on Cu2+ adsorption by kaolin/CA were investigated. The Langmuir isotherm was used to describe the experimental adsorption, the maximum Cu2+ adsorption capacity of the kaolin/CA reached up to 53.63 mg/g. The thermodynamic studies showed that the adsorption reaction was a spontaneous and endothermic process.