Dairy Manure Treatment,Digestion and Nutrient Recovery as a Phosphate Fertilizer

A combined approach of biological treatment, solids digestion and nutrient recovery was tested on dairy manure. A sequencing batch reactor (SBR) was operated in three modes, in order to optimize nutrient (nitrogen and phosphorus) removals. The highest average removal efficiencies of 91% for NH₄-N, 59% for PO₄-P and 80% for total chemical oxygen demand (COD) were achieved. Staining experiments suggested the coexistence of glycogen and phosphorus accumulating organisms. Anaerobic digestion of wasted bio-solids was able to produce a PO₄-P concentration of 70 mgL^?1 in the supernatant. A pilot-scale experiment, designed to recover phosphorus in the supernatant as struvite (magnesium ammonium phosphate), was able to remove 82% of soluble PO₄-P.     

High efficiency chlorine removal from polyvinyl chloride (PVC) pyrolysis with a gas–liquid fluidized bed reactor

In this research a gas–liquid fluidized bed reactor was developed for removing chlorine (Cl) from polyvinyl chloride (PVC) to favor its pyrolysis treatment. In order to efficiently remove Cl within a limited time before extensive generation of hydrocarbon products, the gas–liquid fluidized bed reactor was running at 280–320 °C, where hot N₂ was used as fluidizing gas to fluidize the molten polymer, letting the molten polymer contact well with N₂ to release Cl in form of HCl. Experimental results showed that dechlorination efficiency is mainly temperature dependent and 300 °C is a proper reaction temperature for efficient dechlorination within a limited time duration and for prevention of extensive pyrolysis; under this temperature 99.5% of Cl removal efficiency can be obtained within reaction time around 1 min after melting is completed as the flow rate of N₂ gas was set around 0.47–0.85 Nm³ kg^?1 for the molten PVC. Larger N₂ flow rate and additives in PVC would enhance HCl release but did not change the final dechlorination efficiency; and excessive N₂ flow rate should be avoided for prevention of polymer entrainment. HCl is emitted from PVC granules or scraps at the mean time they started to melt and the melting stage should be taken into consideration when design the gas–liquid fluidized bed reactor for dechlorination.     

Insights into a novel nitrogen removal process based on simultaneous anammox and denitrification(SAD) following nitritation with in-situ NOB elimination

Simultaneous anammox and denitrification(SAD) is an efficient approach to treat wastewater having a low C/N ratio; however, few studies have investigated a combination of SAD and partial nitritation(PN). In this study, a lab-scale up-flow blanket filter(UBF) and zeolite sequence batch reactor(ZSBR) were continuously operated to implement SAD and PN advantages, respectively. The UBF achieved a high total nitrogen(TN) removal efficiency of over 70% during the start-up stage(days 1–50), and reached...     

混合基质3D打印可见光催化系统对病毒气溶胶的去除

利用3D打印灵活可控的特点和复合材料混合打印的优势，将可见光响应的ZnO/g-C₃N₄催化剂掺入ABS塑料，利用3D打印制成催化剂均匀稳定分布的光催化系统，使用流体动力学仿真模拟对反应器结构进行优化设计，用于处理相对密闭的室内空间中的病毒气溶胶.结果表明，病毒气溶胶比细菌气溶胶具有更强的抗逆性，添加螺旋导流板可以显著提升反应器传质性能并有效改善系统光催化效果，以提高对病毒气溶胶的去除率.以商业LED灯为光源的螺旋式反应器对高浓度病毒气溶胶（MS2、PhiX174噬菌体）和细菌气溶胶（大肠杆菌）具有高效去除效果，在3.75min停留时间可以实现对气溶胶的完全去除.     

沿面放电氧活性物质注入协同SCR脱除烟气中NO_x

为了提高选择性催化还原(SCR)在低温区(200℃)的脱硝性能,提出利用插在烟道中的沿面放电反应器生成氧活性物质,部分氧化NO以实现低温快速SCR脱硝过程.同时,研究了氧活性物质注入实现快速SCR的脱硝性能,考察了氧活性物质注入降低二氧化硫和水蒸汽对SCR反应的影响.实验结果表明:在模拟烟气温度为150℃时,采用氧活性物质注入,部分氧化烟气中的NO以实现快速SCR反应条件下(NO/NO2浓度比为1),脱硝效率为51.9%,比标准SCR提升23%;当模拟烟气中存在SO2或H2O时,氧活性物质注入可有效降低SO2、H2O对SCR脱硝效率的影响.     

ABR+生物接触氧化法处理高浓度有毒有机废水

本文采用ABR+生物接触氧化组合工艺处理含苯酚的高COD有毒有机废水,实验研究了ABR反应器的抗毒性及对COD、苯酚和NH3-N的处理效果。实验结果表明:废水COD和苯酚的去除主要发生在厌氧阶段;在苯酚质量浓度1 000 mg/L左右时,ABR反应器和常规厌氧反应器的处理效率均出现明显的下降趋势,但ABR反应器对苯酚的耐受浓度明显高于常规厌氧反应器;相比于常规厌氧反应器,ABR反应器推流式的特性实现了产酸和产甲烷优势菌群的分离,具有较高的COD、苯酚的去除率和较强的抗毒性;对NH3-N的去除,ABR反应器的强化效果不明显。     

煅烧温度对γ-Fe_2O_3催化剂结构及其脱硝活性的影响

采用沉淀-微波热解法,以Fe SO4·7H2O为铁源制备环境友好的γ-Fe2O3催化剂,结合XRD(X射线衍射)、N2等温吸附-脱附、SEM(扫描电子显微镜)、EDS(能谱仪)等手段对催化剂样品的晶相、孔结构、表面形貌、表面元素组成等进行表征,并考察其NH3-SCR(选择性催化还原)脱硝性能,研究煅烧温度对γ-Fe2O3催化剂物性及NH3-SCR脱硝性能的影响规律.结果表明:300、350和450℃下煅烧制备的催化剂中生成的杂质α-Fe2O3对SCR反应不利,而400℃煅烧制备的γ-Fe2O3催化剂脱硝性能最优,NOx转化率最高可达95%以上,XRD结果表明其纯度高,并且在60~100 nm孔径区间具有发达的孔隙结构,有利于SCR反应进行;随着煅烧温度升高,γ-Fe2O3催化剂表面晶格氧逐渐增加,颗粒形貌经历了片状颗粒(300、350℃)→球状颗粒(400℃)→针状颗粒(450℃)的变化过程,均匀的球状颗粒形貌及其表面丰富的晶格氧是400℃煅烧制得催化剂具备最优脱硝性能的重要因素.     

限量曝气进水时间对硝化颗粒污泥的影响特性研究

缺氧-好氧环境的交替循环对氨氧化细菌和亚硝酸盐氧化细菌具有重要影响.本研究通过逐渐增加限量曝气进水时间(从10 min至120 min)延长缺氧时段,考察柱形SBR中硝化颗粒污泥对不同缺氧-好氧环境交替循环的响应特性.整个研究过程中,硝化颗粒污泥保持着稳定的颗粒特征,粒径大于0.8 mm的颗粒污泥占总污泥量的质量分数始终在95%以上,颗粒平均沉降速率维持在125～130 m·h-1之间.尽管缺氧时段不断延长,但NH+4-N去除率和NO-2-N累积率分别稳定在(60±5)%、(85±5)%;此外,在每个周期的曝气反应时段,NH+4-N的去除速率以及NO-2-N和NO-3-N的累积速率分别保持在90mg·(L·h)-1、70 mg·(L·h)-1和15 mg·(L·h)-1左右.以上结果表明,限量进水时间的延长及其所造成的不同时间跨度的缺氧环境对硝化颗粒污泥没有较为显著的影响.     

间歇式生物反应器中PHACs的吸附降解性及动力学特性

利用间歇反应器考察了非那西丁(PNT)、吉非罗齐(GFZ)、咖啡因(CAF)、双氯芬酸(DCF)和胆固醇(CH)5种医药类污染物分别在厌氧、缺氧及好氧条件下的吸附与降解特性,并通过动力学拟合深入考察目标物的降解速率及所符合的反应级数.研究表明,PNT在4 h内就能得到100%的降解,GFZ与CH能通过吸附与降解得到部分或全部去除.好氧条件下目标物的泥水分配系数kp值与降解速率均高于缺氧与厌氧条件,好氧条件下CAF的去除率达到99%以上.5种目标物除PNT外都有不同程度的吸附,目标物的污泥吸附能力为CHDCFGFZCAF;动力学拟合结果表明,生物降解动力学一级反应速率PNTCAF,二级反应速率CHGFZ;DCF几乎不能被生物降解,但符合二级吸附动力学模型,其平衡吸附量最高可达总投加量的71%.     

Effect of alkalinity on nitrite accumulation in treatment of coal chemical industry wastewater using moving bed biofilm reactor

Nitrogen removal via nitrite （the nitrite pathway） is more suitable for carbon-limited industrial wastewater. Partial nitrification to nitrite is the primary step to achieve nitrogen removal via nitrite. The effect of alkalinity on nitrite accumulation in a continuous process was investigated by progressively increasing the alkalinity dosage ratio （amount of alkalinity to ammonia ratio, mol/mol）. There is a close relationship among alkalinity, pH and the state of matter present in aqueous solution. When alkalinity was insufficient （compared to the theoretical alkalinity amount）, ammonia removal efficiency increased first and then decreased at each alkalinity dosage ratio, with an abrupt removal efficiency peak. Generally, ammonia removal efficiency rose with increasing alkalinity dosage ratio. Ammonia removal efficiency reached to 88% from 23% when alkalinity addition was sufficient. Nitrite accumulation could be achieved by inhibiting nitrite oxidizing bacteria （NOB） by free ammonia （FA） in the early period and free nitrous acid in the later period of nitrification when alkalinity was not adequate. Only FA worked to inhibit the activity of NOB when alkalinity addition was sufficient.