Combined anaerobic/aerobic digestion: effect of aerobic retention time on nitrogen and solids removal

A combined anaerobic/aerobic sludge digestion system was studied to determine the effect of aerobic solids retention time (SRT) on its solids and nitrogen removal efficiencies. After the anaerobic digester reached steady state, effluent from the anaerobic digester was fed to aerobic digesters that were operated at 2- to 5-day SRTs. The anaerobic system was fed with a mixture of primary and secondary sludge from a local municipal wastewater treatment plant. Both systems were fed once per a day. The aerobic reactor was continuously aerated with ambient air, maintaining dissolved oxygen level at 1.1 +/- 0.3 mg/L. At a 4-day or longer SRT, more than 11% additional volatile solids and 90% or greater ammonia were removed in the aerobic digester, while 32.8 mg-N/L or more nitrite/nitrate also was measured. Most total Kjeldahl nitrogen removal was via ammonia removal, while little organic nitrogen was removed in the aerobic digester.     

深型地下土壤渗滤系统中氮的去除途径

为了系统研究氮在深型地下土壤渗滤系统中的去除途径，本次实验采用直径30cm，高200cm的有机玻璃柱模拟地下土壤渗滤系统；柱内分层装填取自北京顺义的土壤。在水力负荷为8cm／d的条件下，取得了较好的脱氮效果；氨氮去除率为99．80％；TN去除率为83．68％。通过观察氮沿土柱深度的变化规律发现，在1．30m以上的区域随着氨氮浓度的降低硝氮浓度逐渐增大，同时总氮浓度也在不断降低，约有30．55％在此区域被去除；通过氮元素质量平衡证明这部分氮是通过厌氧氨氧化反应去除的。在1．30m以下反硝化反应是脱氮的主要途径，在此过程中难降解有机物被利用。     

微生物菌剂对好氧填埋垃圾稳定过程的影响

为加速好氧填埋场的稳定化进程,提出利用生物强化技术加速好氧填埋垃圾的生物降解,通过模拟实验,研究了微生物菌剂对填埋垃圾稳定过程的影响。结果表明:微生物菌剂降低了好氧填埋场的有机污染负荷,使渗滤液COD下降更加明显,整个填埋周期所产渗滤液的COD总量较对照组少20.20%;加速了含氮物质的生物转化,氨氮峰值出现较对照组提前6 d,经历峰值以后,氨氮快速下降,较对照组提前22 d达到国家生活垃圾填埋场污染控制标准(GB 16889-2008)所规定的渗滤液氨氮排放标准25 mg/L,并使整个填埋周期氨氮总量减少9.15%;微生物菌剂降低了渗滤液的产量,使整个填埋周期渗滤液累计产量减少8.29%;使垃圾中有机质降解加快并使其降解更加彻底,至实验结束时总有机质含量较对照组低8.82%,干重较对照组减少35.95%;沉降性能优于对照组,至填埋结束时较对照组沉降量提高6.35%。     

一株高效异养硝化-好氧反硝化菌的分离鉴定及脱氮性能

从经驯化的污泥中筛选出一株异养硝化-好氧反硝化细菌，编号为TN-05，通过形态学特征观察，生理生化特征试验和核酸序列分析鉴定其为门多萨假单胞菌（pseudomonasmendocina）。同时对其进行脱氮性能研究，结果表明，TN-05具有较好的异养硝化能力，菌株在培养至48h时对总氮和氨氮去除率均能达95％以上。通过反硝化能力验证实验发现，菌株对NO3-N和N0f—N也分别具有较好的去除效率。将菌株应用于人工合成废水中，发现对废水中氨氮优先利用并能在24h时使去除率接近100％，对硝态氮和亚硝态氮也具有一定的去除效率。因此，菌株TN-05是一株同时具备异养硝化和好氧反硝化能力的高效菌株。     

准好氧矿化垃圾反应床＋超声／芬顿联用技术处理垃圾渗滤液

针对垃圾渗滤液污染物浓度高、可生化性差等特点，采用准好氧矿化垃圾反应床＋超声／芬顿联用技术对垃圾渗滤液进行预处理。准好氧矿化垃圾床处理后渗滤液中COD、氨氮、总磷、色度的去除率分别为80％、85％、92％和85％。通过单因素实验和正交实验，确定了超声／Fenton法最佳工艺条件。经该组合工艺后，渗滤液中COD、氨氮、总磷和色度的最高去除率分别可达96％、86％、94％和95％，且出水无臭，颜色为淡黄色，BOD5／COD从0．16增至0．35左右，可生化性基本满足后续生物处理需要，且COD、总磷这2个指标达到《生活垃圾填埋场污染控制标准》（GB16889—2008）规定的排放标准。     

间歇曝气潜流人工湿地的污水脱氮效果

采用间歇曝气运行方式,提升潜流人工湿地生活污水处理系统中的溶解氧浓度,强化脱氮效果。结果表明,间歇曝气运行方式有效提高了湿地内部溶解氧水平,曝气时溶解氧浓度可达6~9 mg/L,停止曝气后,溶解氧浓度迅速下降至0.5 mg/L以下,在湿地内部营造了一种交替的好氧和缺氧环境,分别促进好氧硝化和缺氧反硝化作用。在水力停留时间为3 d的情况下,间歇曝气潜流人工湿地系统对氨氮、总氮和COD的去除率分别可达到98.0%、87.6%和96.3%,较常规潜流人工湿地系统分别提高了74.1%、56.4%和18.1%,实现了氨氮、总氮和COD的同步高效去除。     

复合型人工湿地脱氮效能及其水力负荷影响规律

复合型人工湿地越来越多地被应用在面源污染管理中。不同类型的人工湿地对氮素的去除机理和去除性能是不同的。氮素在湿地生态系统中的去除受多种因素的影响和制约,不同的研究中氮素的去除效率变化较大。通过对韩国西部一复合型人工湿地中氮素的去除能力研究,分析了氮素的去除效率以及水力负荷对去除性能的影响,进而分析了人工湿地去除氮素的主要机理。结果表明,氨氮（NH＋4-N）、硝酸盐氮（NO-3-N）、凯式氮（TKN）和总氮（TN）的平均去除效率分别为13%、29%、35.3和26%。其中有机氮的去除是该复合型人工湿地中氮素去除的主要原因。水力负荷和先行干期天数对氮素的去除能力有一定影响。较长的先行干期天数和较低水力负荷可以提高氮素的去除效率。     

一株反硝化细菌的分离鉴定及脱氮能力

本研究从水产养殖环境中分离出39株反硝化细菌，并从中筛选出具有较强反硝化能力的菌株DB-33，对其脱氮能力测定的结果表明，在培养基中亚硝酸盐氮浓度高达54．16mg／L，硝酸盐氮浓度高达306．91mg／L时，DB-33菌株对其去除率均达99％以上，且在去除过程中氨氮不累积；在模拟养殖水体中，DB-33可将亚硝酸盐氮和硝酸盐氮分别在24h和第3天彻底去除，对氨氮48h的去除率也可达51．52％。通过形态学特性和生理生化分析以及16SrDNA基因序列分析，菌株DB-33初步鉴定为施氏假单胞菌（Pseudomonasstutzeri）。     

Nitrogen removal via the nitrite pathway during wastewater co-treatment with ammonia-rich landfill leachates in a sequencing batch reactor

The biological treatment of ammonia-rich landfill leachates due to an inadequate C to N ratio requires expensive supplementation of carbon from an external carbon source. In an effort to reduce treatment costs, the objective of the study was to determine the feasibility of nitrogen removal via the nitrite pathway during landfill leachate co-treatment with municipal wastewater. Initially, the laboratory-scale sequencing batch reactor (SBR) was inoculated with nitrifying activated sludge and fed only raw municipal wastewater (RWW) during a start-up period of 9 weeks. Then, in the co-treatment period, consisting of the next 17 weeks, the system was fed a mixture of RWW and an increasing quantity of landfill leachates (from 1 to 10 % by volume). The results indicate that landfill leachate addition of up to 10 % (by volume) influenced the effluent quality, except for BOD₅. During the experiment, a positive correlation (r ²?=?0.908) between ammonia load in the influent and nitrite in the effluent was observed, suggesting that the second step of nitrification was partially inhibited. The partial nitrification (PN) was also confirmed by fluorescence in situ hybridisation (FISH) analysis of nitrifying bacteria. Nitrogen removal via the nitrite pathway was observed when the oxygen concentration ranged from 0.5 to 1.5 mg O₂/dm³ and free ammonia (FA) ranged from 2.01 to 35.86 mg N-NH₃/dm³ in the aerobic phase. Increasing ammonia load in wastewater influent was also correlated with an increasing amount of total nitrogen (TN) in the effluent, which suggested insufficient amounts of assimilable organic carbon to complete denitrification. Because nitrogen removal via the nitrite pathway is beneficial for carbon-limited and highly ammonia-loaded mixtures, obtaining PN can lead to a reduction in the external carbon source needed to support denitrification.     

The potential use of constructed wetlands in a recirculating aquaculture system for shrimp culture

A pilot-scale constructed wetland unit, consisting of free water surface (FWS) and subsurface flow (SF) constructed wetlands arranged in series, was integrated into an outdoor recirculating aquaculture system (RAS) for culturing Pacific white shrimp (Litopenaeus vannamei). This study evaluated the performance of the wetland unit in treating the recirculating wastewater and examined the effect of improvement in water quality of the culture tank on the growth and survival of shrimp postlarvae. During an 80-day culture period, the wetland unit operated at a mean hydraulic loading rate of 0.3 m/day and effectively reduced the influent concentrations of 5-day biochemical oxygen demand (BOD5, 24%), suspended solids (SS, 71%), chlorophyll a (chl-a, 88%), total ammonium (TAN, 57%), nitrite nitrogen (NO2-N, 90%) and nitrate nitrogen (NO3-N, 68%). Phosphate (PO4-P) reduction was the least efficient (5.4%). The concentrations of SS, Chl-a, turbidity and NO3-N in the culture tank water in RAS were significantly (P相似文献   

矿物载体锯末碳源低温生物修复硝酸盐污染地下水

研究了低温条件下,沸石和火山岩为载体,锯末为碳源的生物反应器对地下水中硝酸盐氮的去除效果。结果表明,在（14±1）℃,水力停留时间18 h,进水硝酸盐氮浓度为27 mg/L的条件下,以锯末为碳源能有效去除地下水中的硝酸盐,沸石为载体时对硝酸盐氮的平均去除率为98%;火山岩为载体时对硝酸盐氮的平均去除率为95%。实验过程中出现铵盐和亚硝酸盐的积累,出水中氨氮浓度为1～2.55 mg/L,亚硝酸氮浓度为0～0.98 mg/L。出水pH均介于7～8,满足饮用水标准中pH的要求（6.5～8.5）。     

生物法/人工湿地工艺处理采油废水及其生态毒性削减研究

采用2种生物法/人工湿地工艺(水解酸化/好氧/人工湿地工艺和水解酸化/人工湿地(进水区强化曝气)工艺)处理胜利油田某联合处理站经隔油、混凝处理的采油废水,并运用发光细菌技术研究采油废水在处理过程中的生态毒性削减规律.研究结果表明,在水解酸化段水力停留时间(HRT)为20 h,好氧段HRT为10 h,人工湿地HRT为2 d的工况下,水解酸化/好氧/人工湿地工艺与水解酸化/人工湿地(进水区强化曝气)工艺的出水水质均能满足COD≤80 mg/L、NH_4~+-N≤15 mg/L的处理要求.发光细菌法试验结果表明,经隔油、混凝处理后的采油废水属高毒性废水,再经水解酸化/人工湿地(进水区强化曝气)工艺处理后生态毒性大幅削减,出水生态毒性降至低毒.     

两级混合稳定表流湿地处理生活污水

为了提高一级稳定表流湿地(stable surface flow wetland,SSFW)的出水水质,在单级稳定表流湿地后串联一级潜流人工湿地,构成两级混合稳定表流湿地(two steps hybrid stable surface flow wetland,TSHSSFW),研究气候变化对其净化效果的影响,并同一级潜流人工湿地(one step subsurface flow wetland,OSSFW)进行对比。研究表明,气候变化对TSHSSFW的COD和总磷去除率影响较小,去除率均在80%左右;而对氨氮和总氮的去除率影响比较大,夏季TSHSSFW的氨氮和总氮去除率分别为87.77%和77.74%,而冬季氨氮和总氮的去除率分别为54.07%和48.84%。相比单级潜流人工湿地(OSSFW),有SSFW作为前处理的潜流人工湿地对氨氮和总氮的去除率较高。     

陈垃圾反应床＋芦苇人工湿地处理垃圾渗滤液

研究了陈垃圾反应床与芦苇人工湿地串联对垃圾渗滤液中污染物的去除效果， 并探讨了湿地中芦苇生长和对渗滤液中总氮的吸收能力。结果表明： 在进水负荷为0.1 m³/（m²·d）的条件下，经过3个月的运行，陈垃圾反应床与芦苇人工湿地对陈年渗滤液中COD、氨氮、总氮及总磷的最大去除率分别达到90.3%、95.0%、79.3%和99.8%。通过对人工湿地中芦苇的分析表明，芦苇在6—8月份生长迅速，地上部分生物量与其氮含量增加较快，最大值均出现在8月底，植株总含氮量可以达到28.5 g/m²。此时收割芦苇可从湿地中最大限度除氮。如能增加芦苇种植密度，陈垃圾床与芦苇湿地串联处理渗滤液污染物以及深度去氮是可行的。     

水质净化高效复合微生态制剂的研制

在室内模拟条件下,采用正交实验的方法对光合细菌、枯草芽孢杆菌和反硝化细菌的复配比例进行了研究,筛选一种用于水产养殖水质净化的高效复合微生态制剂。结果表明,当光合细菌(菌细胞浓度约为2×109CFU/mL)、枯草芽孢杆菌(菌细胞浓度约为8×108CFU/mL)和反硝化细菌(菌细胞浓度约为8×108CFU/mL)按菌液体积比为1∶2∶1进行复配利于水中溶解氧的提高和COD、氨氮、亚硝态氮、硝态氮的降解。验证实验表明,筛选组合各指标均优于商品微生态制剂和空白对照,其中溶解氧含量显著高于商品微生态制剂EM和复合芽孢菌处理,在实验第5天对COD的降解率为95%,显著优于EM和复合芽孢菌处理的66.3%和47.9%,实验第7天对氨氮、亚硝态氮和硝态氮的降解率分别达到70%、89%和56%。     

Simultaneous nitrification-denitrification and clarification in a pseudoliquified activated sludge system.

This paper describes results from a pilot study of a novel wastewater treatment technology, which incorporates nutrient removal and solids separation to a single step. The pseudoliquified activated sludge process pilot system was tested on grit removal effluent at flowrates of 29.4 to 54.7 m3/d, three different solid residence times (SRT) (15, 37, and 57 days), and over a temperature range of 12 to 28 degrees C. Despite wide fluctuations in the influent characteristics, the system performed reliably and consistently with respect to organics and total suspended solids (TSS) removals, achieving biochemical oxygen demand (BOD) and TSS reductions of > 96% and approximately 90%, respectively, with BOD5 and TSS concentrations as low as 3 mg/L. Although the system achieved average effluent ammonia concentrations of 2.7 to 3.2 mg/L, nitrification efficiency appeared to be hampered at low temperatures (< 15 degrees C). The system achieved tertiary effluent quality with denitrification efficiencies of 90 and 91% total nitrogen removal efficiency at a total hydraulic retention time of 4.8 hours and an SRT of 12 to 17 days. With ferric chloride addition, effluent phosphorous concentrations of 0.5 to 0.8 mg/L were achieved. Furthermore, because of operation at high biomass concentrations and relatively long biological SRTs, sludge yields were over 50% below typical values for activated sludge plants. The process was modeled using activated sludge model No. 2, as a two-stage system comprised an aerobic activated sludge system followed by an anoxic system. Model predictions for soluble BOD, ammonia, nitrates, and orthophosphates agreed well with experimental data.     

气水比对曝气生物活性炭处理原水的影响

针对从臭氧-活性炭工艺中开发出来的预臭氧-曝气生物活性炭,在不同气水比工况下进行实验,分析了不同气水比对曝气生物活性炭处理微污染原水的影响与作用。结果表明:在滤速为8～12 m/h,空床接触时间为11.5～15.4 min,装填密度为510 g/L条件下,不同气水比对去除氨氮的影响大于对CODMn的影响。气水比为0.3∶1时,对氨氮浓度为1.65～2.10 mg/L范围的进水平均去除率为81.9%,亚硝酸盐氮平均积累率为1.4%,CODMn去除率为70.6%。当气水比逐渐增加时,氨氮平均去除率有所提高,亚硝酸盐氮积累率则有所下降,对较低浓度的CODMn影响不大。     

Macroalgae mitigation potential for fish aquaculture effluents: an approach coupling nitrogen uptake and metabolic pathways using Ulva rigida and Enteromorpha clathrata

Aquaculture effluents are rich in nitrogen compounds that may enhance local primary productivity, leading to the development of algae blooms. The goal of this study was to assess the potential use of naturally occurring green macroalgae (Ulva and Enteromorpha) as bioremediators for nitrogen-rich effluents from a fish aquaculture plant, by evaluating their respective uptake dynamics under controlled conditions. Ulva and Enteromorpha were incubated separately in aquaculture effluent from a local pilot station. Algae tissue and water samples were collected periodically along 4 h. For each sample, nitrate, nitrite, and ammonia concentrations were quantified in the effluent, while internal algae reserve pools and nitrate reductase activity (NRA) were determined within the algae tissues. Both macroalgae absorbed all dissolved inorganic nitrogen compounds in less than 1 h, favoring ammonia over nitrate. Ulva stored nitrate temporarily as an internal reserve and only used it after ammonia availability decreased, whereas Enteromorpha stored and metabolized ammonia and nitrate simultaneously. These distinct dynamics of ammonia and nitrate uptake supported an increase in NRA during the experiment. This study supports the hypothesis that Ulva or Enteromorpha can be used as bioremediators in aquaculture effluents to mitigate excess of dissolved inorganic nitrogen.     

Characteristics of an aerobic denitrifier that utilizes ammonium and nitrate simultaneously under the oligotrophic niche

Introduction

An aerobic denitrifier was isolated from the Hua-Jia-Chi pond in China and identified as Pseudomonas mendocina 3-7 (Genbank No. HQ285879). This isolated strain could express periplasmic nitrate reductase which is essential for aerobic denitrification occurred when the dissolved oxygen (DO) level maintains at 3?C10?mg?L^?1.

Methods

To determine whether the ability of isolated strain is exhibited in the bioremediation of polluted drinking source water, the heterotrophic nitrification and aerobic denitrification characteristics of P. mendocina 3-7 under different cultural conditions such as oxygen level, nitrate and organic concentrations were studied from the nitrogenous balance in the paper.

Results and conclusions

By measuring the nitrogen balance in all experiments under different culture conditions, the removal of total organic carbon and ammonium was positively correlated with total nitrogen removal, especially under high substrate level. With substrate concentration decreasing, ammonium and nitrate removal occurred separately, and ammonium was completely utilized first under low substrate concentration. Compared to that under high substrate level, the specific growth rate of P. mendocina 3-7 was not low under the low substrate level and the pollutant removal efficiencies remained high, which implies the stronger nitrogen removal and acclimatization capacities of the strain in oligotrophic niches.     

Accumulation of nitrite in denitrifying barriers when phosphate is limiting

Permeable in situ denitrifying barriers can remove nitrate from groundwater. Barriers may be constructed by filling an excavated area with a porous mixture of sand, fine gravel, and substrate or by the injection of a nonaqueous phase substrate into an aquifer. The substrate stimulates the development of a denitrifying microbial community by providing an electron donor. The objective of this study was to determine the ability of denitrifying barriers to function under low-phosphate conditions. Sand columns injected with a soybean oil emulsion were used as laboratory models of denitrifying barriers. When a natural groundwater containing 17 mg l(-1) nitrate-N and 0.009 mg l(-1) phosphate-P was pumped through the columns, only a small amount of nitrate was removed from the water and, in some effluent fractions, 52% to 88% of the influent nitrate had converted to nitrite. Nitrite also accumulated when the phosphate concentration of the groundwater was increased to 0.040 or 0.080 mg l(-1) phosphate-P. Only when a 0.160 mg l(-1) phosphate-P supplement was added to the groundwater was there a loss of nitrate without a large accumulation of nitrite. The addition of solid calcium phosphate or rock phosphate to the sand columns was found to provide adequate phosphate for denitrification in short-term studies. These studies point out the need to ensure that adequate phosphate is present in denitrifying barriers especially when such barriers are used beneath phosphate-binding soils.