缺氧MBBR耦合部分厌氧氨氧化强化城市生活污水深度脱氮

缺氧MBBR是强化传统城市污水处理系统脱氮的一种方法,本研究通过向城市污水后置反硝化SBR中投加填料构建了缺氧双污泥系统,实现了城市生活污水部分厌氧氨氧化深度脱氮.在250d的运行中脱氮性能逐渐提高并实现稳定,出水总氮在5 mg·L~(-1)左右. 211～250 d的平均硝氮、氨氮和总氮去除率分别为(97. 7±2. 9)%、(93. 3±2. 9)%和(94. 3±2. 7)%.长期运行中观测到氨氮和硝氮的同步去除.针对氨氮去除途径进行分析,系统同化、硝化作用微弱.缺氧MBBR中存在厌氧氨氧化活性且对脱氮有不可忽视的作用.实时定量PCR结果进一步说明缺氧MBBR中厌氧氨氧化菌富集,特别是缺氧填料生物膜中厌氧氨氧化菌丰度由初始的4. 37×10~7copies·g~(-1)增长到了2. 28×10~(10)copies·g~(-1).本研究表明缺氧填料生物膜在厌氧氨氧化的富集强化城市污水深度脱氮中或许具有可应用的潜能.     

Household organic waste composting using bins with different types of passive aeration

The objective of this study was to study the performances of six 200-L polyethylene bins, each with different design for passive aeration to organic wastes composting. Food scraps and dry leaves (1.6 kg) were added to each bin once a day until the bin was full. Temperatures at the middle portion were measured daily. The compost from each bin was taken once a week for 120 days for analysis of C, N, volatile solids, and a germination index once a week for 120 days. After 120 days, the compost sample from each bin was taken to determine the mass reduction, size distribution, CEC, N, P and K values. The results showed that the temperatures inside the bins were in the ranges of 24 °C-57 °C. The composts in all bins were found to be stable at around 56-91 days. The wastes decayed fastest in bins with lateral and vertical systems of natural ventilation. It took about two months to stabilize the organic wastes, with a 59-62% decrease of mass. The C/N ratio, CEC, N, P, and K values of the final composts were 14.8-16.0, 66-68 cmol/kg, and 1.26-1.50% N, 0.52-0.56% P₂O₅ and 1.66-1.92% K₂O, respectively.     

提高水中BOD5测定质量的探讨

介绍了环境空气质量、分析用水、接种液加入量、曝气方法的选择等因素对BOD5测定的影响。提出测定过程中实验室空气质量、分析用水的选择、接种液的选择和加入量以及曝气方法应注意事项,以期得到较为准确的测定结果,提高废水中BOD5测定质量。     

Integrating soil carbon cycling with that of nitrogen and phosphorus in the watershed model SWAT: Theory and model testing

In this paper we describe and test a sub-model that integrates the cycling of carbon (C), nitrogen (N) and phosphorus (P) in the Soil Water Assessment Tool (SWAT) watershed model. The core of the sub-model is a multi-layer, one-pool soil organic carbon (S_C) algorithm, in which the decomposition rate of S_C and input rate to S_C (through decomposition and humification of residues) depend on the current size of S_C. The organic N and P fluxes are coupled to that of C and depend on the available mineral N and P, and the C:N and N:P ratios of the decomposing pools. Tillage explicitly affects the soil organic matter turnover rate through tool-specific coefficients. Unlike most models, the turnover of soil organic matter does not follow first order kinetics. Each soil layer has a specific maximum capacity to accumulate C or C saturation (S_x) that depends on texture and controls the turnover rate. It is shown in an analytical solution that S_x is a parameter with major influence in the model C dynamics. Testing with a 65-yr data set from the dryland wheat growing region in Oregon shows that the model adequately simulates the S_C dynamics in the topsoil (top 0.3 m) for three different treatments. Three key model parameters, the optimal decomposition and humification rates and a factor controlling the effect of soil moisture and temperature on the decomposition rate, showed low uncertainty as determined by generalized likelihood uncertainty estimation. Nonetheless, the parameter set that provided accurate simulations in the topsoil tended to overestimate S_C in the subsoil, suggesting that a mechanism that expresses at depth might not be represented in the current sub-model structure. The explicit integration of C, N, and P fluxes allows for a more cohesive simulation of nutrient cycling in the SWAT model. The sub-model has to be tested in forestland and rangeland in addition to agricultural land, and in diverse soils with extreme properties such high or low pH, an organic horizon, or volcanic soils.     

曝气复氧对底泥氮素生物地球化学循环影响的作用机制研究

通过分析底泥氮污染物释放规律和转化过程,以及底泥生境、氮形态变化和氮循环功能微生物群落结构变化的规律,探讨了不同曝气复氧条件影响底泥氮生物地球化学循环的生物代谢、物理化学联合作用的机制。结果表明：曝气复氧对底泥中氮的生物地球化学循环影响是一个包括微生物代谢作用和物理化学作用的复杂联合作用过程。水体好氧环境的改变主要引起参与底泥氮循环的硝化、亚硝化和反硝化功能菌群群落结构的演变,对异养菌和氨化菌的影响不大,证明环境好氧条件的改变对底泥有机质生物分解产生氨氮的微生物代谢过程影响不大,主要对底泥释放的氨氮硝化、反硝化等生物转化过程产生大的影响。不同溶解氧条件下,底泥释放的氮素在微生物作用下主要以NH4＋-N和NO3--N的形式进入试验体系,并在特定的氧化还原电位（临界值-200 mV）和pH（临界值6.70）条件下通过物理化学作用在底泥中以离子交换态氮（IEF-N）、碳酸盐结合态氮（CF-N）、铁锰氧化态氮（IMOF-N）及有机态和硫化物结合态氮（OSF-N）等不同形态氮相互转化,同时,在氮的转化和循环过程中部分输入上覆水体。在低溶解氧组实验条件下[ρ（DO）〈0.5 mg.L-1],底泥向水体输出氮总量为底泥可转化态氮的19.7%,主要为氨氮,最大释放速率达到289.13 mg.m-2.d-1,释放的质量浓度可达到18.8 mg.L-1;好氧条件下（DO饱和）,底泥向水体输出氮总量为底泥可转化态氮的1.8%;好氧-缺氧条件下为11.7%,主要以N2的形式释出系统。     

射流曝气MBR处理啤酒废水的试验

射流曝气提高了系统的氧利用效率及传质效率.通过逐渐提高进水的容积负荷来考察系统的处理效果, 试验表明, 利用射流曝气MBR处理模拟啤酒废水是可行的, 系统对COD、氨氮、浊度平均去除率为95.74%,97.84%,99.5%.由于系统运行期间不排泥, 因此系统对P O43-的去除效果不佳, 平均去除率为42.9%.膜对...     

基于地理标记照片的入境游客空间特征与移动轨迹——以南京市为例

随着互联网与社交媒体的兴起,用户分享内容中的地理标记数据成为旅游流研究的重要对象。以南京入境旅游流空间特征为研究对象,以2010—2018年Flickr平台内南京地理标记照片为基础,利用DBSCAN算法、ArcGIS 10.2等方法与技术探究南京入境旅游热点区域、游客移动轨迹特征及模式。研究结果显示：（1）南京入境游客访问峰值出现在3-6月及10月,以一日游为主。（2）南京AOI空间分布差异明显,历史城区是南京入境旅游最热门区域,其AOI分布与旅游景区、商业购物等相关产业空间高度重合;中心城区的AOI分布数量次之,钟山风景区是其热度核心,深受热衷历史文化的游客追捧;郊区的AOI分布数量最少,基本与当地旅游景区相吻合。（3）单日游和多日游的游客移动轨迹网具有显著差异性,分别体现在网络范围、网络体系、旅游对流及转移差值4个方面。（4）南京入境游客移动轨迹模式可划分为区域内部移动轨迹模式和区域间移动轨迹模式。根据上述研究结果,分别针对历史城区、中心城区及郊区提出相应的发展建议。     

填埋场原位好氧稳定化技术的应用现状及研究进展

综述了原位好氧稳定化技术的原理、系统构成、关键单元的设计和优化及终点评价,结合我国填埋场及垃圾特点,展望了该技术在我国的发展前景和挑战.均匀布气及配水是原位好氧稳定化项目实施过程中主要的难点.做好渗滤液导排保证堆体最优含水率、优化曝气及提气管道布局、分层整治并辅以高压局部曝气有望提高氧气利用率;采用分层回灌或者压力回灌以及控制回灌速率可分别改善液体回灌过程中的屏障效应和大孔隙出流效应,保障堆体布水均匀.好氧稳定化处理后垃圾腐殖土及场底土壤的风险评价体系及最终出路尚未明确,后期加强相关基础研究以指导工程应用是必要的.     

EGSB-CANON工艺启动及动力学特性

采用EGSB（Expanded Granular Sludge Bed）反应器,在启动全程自养脱氮（CANON）工艺中通过改变曝气方式以及优化曝气/非曝气逐步实现CANON工艺的稳定运行.通过研究不同曝气/非曝气条件下CANON工艺的脱氮性能的变化,探究系统内不同污泥粒径中功能菌的活性,揭示EGSB反应器不同的运行条件以及系统内不同粒径的微生物聚集体在CANON工艺启动过程中的影响机制与菌群结构特性.结果表明,当恒定曝气量为0.5L/min,曝气/非曝气为2：1（60min：30min）时,实现了AerAOB（Aerobic Ammonia-Oxidizing Bacteria）与AnAOB（Anaerobic Ammonium-Oxidation Bacteria）协同脱氮的目的,并成功将NOB（Nitrite-Oxidizing Bacteria）的活性由3.41mgN/（h·gVSS）抑制到0.75mgN/（h·gVSS）.在对AnAOB的双底物（NO₂^--N和NH₄⁺-N）抑制动力学结果进行Haldane拟合时,得到NH₄⁺-N和NO₂^--N的半饱和常数（k_s）、抑制动力学常数（k_h）分别为106.8,331.9mg/L,272.4,66.61mg/L,相关性系数（R²）分别为0.98133和0.99142.在CANON污泥颗粒化形成过程中,污泥粒径在0.154~0.335mm范围内主要以AerAOB为主,污泥粒径在1mm以上主要以AnAOB为主.不同粒径下微生物聚集体的协同作用以及稳定的群落结构实现了CANON工艺的稳定运行.     

Mechanistic insight into the biofilm formation and process performance of a passive aeration ditch (PAD) for decentralized wastewater treatment

• A Passive Aeration Ditch was developed to treat decentralized wastewater. • A model was developed to describe the process performance. • A high C/N ratio facilitates microbial growth but nitrification deteriorates. • A high salinity decreases both organic and nitrogen contaminants removal. Decentralized wastewater containing elevated salinity is an emerging threat to the local environment and sanitation in remote coastal communities. Regarding the cost and treatment efficiencies, we propose a passive aeration ditch (PAD) using non-woven polyester fabric as a feasible bubbleless aerator and biofilm carrier for wastewater treatment. Consideration has been first given to PAD’s efficacy in treating saline decentralized wastewater, and then to the impact of chemical oxygen demand-to-nitrogen (C/N) ratio and salinity on biofilm formation. A multispecies model incorporating the salinity effect has been developed to depict the system performance and predict the microbial community. Results showed that the PAD system had great capacity for pollutants removal. The biofilm thickness increased at a higher C/N ratio because of the boost of aerobic heterotrophs and denitrifying bacteria, which consequently improved the COD and total nitrogen removal. However, this led to the deterioration of ammonia removal. Moreover, while a higher salinity benefited the biofilm growth, the contaminant removal efficiencies decreased because the salinity inhibited the activity of aerobic heterotrophs and reduced the abundance of nitrifying bacteria inside the biofilm. Based on the model simulation, feed water with salinity below 2% and C/N ratio in a range of 1 to 3 forms a biofilm that can reach relatively high organic matter and ammonia removal. These findings not only show the feasibility of PAD in treatment of saline decentralized wastewater, but also offer a systematic strategy to predict and optimize the process performance.