短期有机冲击下船用景观一体化反硝化除磷装置的处理效能

为高效、稳定处理船舶生活污水,研究了船用景观一体化反硝化除磷装置面对短期水质波动的效能变化,采用富集反硝化聚磷菌(DPAOs)的ABR-CSTR连续流组合工艺耦合生态单元处理船舶生活污水,对比了ABR进水容积负荷(VLR)为1.2 kg·(m~3·d)~(-1)、COD为350 mg·L~(-1)的基准条件,通过短期内提高进水中有机底物的浓度,来模拟1.5倍和2.0倍进水有机负荷的有机冲击,此外通过控制硝化液回流比及溶解氧获得应对冲击的调控策略。结果表明:在2种短期冲击下,COD去除率分别为94.1%和92.6%,出水BOD和TN可达标,生物单元出水磷平均为0.76 mg·L~(-1)和1.14 mg·L~(-1),缺氧吸磷量为7.13 mg·L~(-1)和5.82 mg·L~(-1),生态单元可深度降解氮磷及缓冲波动;在1.5倍VLR下,调整硝化液回流比由200%至300%,反硝化吸磷量由7.10 mg·L~(-1)升至7.41 mg·L~(-1),在2.0倍冲击下,提高硝化液回流比对系统除磷帮助甚微,将DO从1.5 mg·L~(-1)升至2.0 mg·L~(-1),吸磷量由5.17 mg·L~(-1)升至6.01 mg·L~(-1),系统反硝化除磷效果得以提升;污泥特性方面,ABR内MLVSS/MLSS比值和EPS量随有机底物浓度的提高而上升,厌氧段EPS增幅最大,可由154.5 mg·g~(-1)升至164.2 mg·g~(-1)和183.4 mg·g~(-1)。ABR-CSTR-生态单元一体化装置面对短期有机冲击具有稳定处理效果,研究结果可为船舶生活污水的治理提供参考。     

侧流化学除磷对AO连续流生物除磷系统的影响

为解决城市污水高效除磷和磷回收的问题,开发厌氧释磷上清液侧流除磷工艺(anaerobic supernatant phosphate strip process,简称ASPS工艺),在侧流比为33%下运行,发现该工艺对生物除磷系统的影响主要表现在以下几个方面:(1)系统磷和有机物的去除性能不受影响,出水可溶性磷和COD浓度分别为(0.53±0.12)mg/L、(42.00±5.69)mg/L;(2)活性污泥分布松散并与大量丝状菌结合成难沉降的絮状结构,沉降性能变差,粒径变小;(3)从系统内微生物能量代谢角度分析知,胞内PHA和糖原含量水平无明显变化;但胞内聚磷颗粒含量减少,厌氧释磷受阻,侧流厌氧释磷浓度从22.17mg/L下降至5.20 mg/L,最终导致侧流部分失去高浓度磷化学沉淀的优势;(4)化学磷回收量占进水磷量比由133.02%下降至31.20%,可实现磷的有效去除和回收利用;(5)对微生物种群变化的影响还有待进一步探究。     

SBBR与人工湿地组合工艺脱氮除磷

以人工合成污水为原水,以第二代生态碳纤维作为SBBR填料,考察了SBBR和人工湿地组合工艺脱氮除磷的性能。结果表明,SBBR系统能够实现同步硝化反硝化且可出现明显的释磷、吸磷现象,当SBBR厌氧75 min,曝气240 min,溶解氧在3.07~4.09 mg·L~(-1)之间时,组合工艺实现了能耗最低情况下的达标出水。此模式下,SBBR系统对COD、氨氮、TN和TP的去除率分别达到94.6%、94.8%、85.4%和61.1%。人工湿地采取间歇运行模式以进一步脱氮除磷,其中进水12h,放空复氧12 h,稳定后湿地对COD、氨氮、TN和TP的去除率分别达到39.3%、47.3%、61.5%和70.7%。此模式下整体组合工艺表现出了良好的脱氮除磷性能,系统出水COD、氨氮、TN和TP浓度均值分别为13.89、0.535、2.047和0.286 mg·L~(-1),去除率分别能够达到96.7%、97.3%、94.4%和88.6%。     

温度对SBR强化生物除磷工艺除磷性能的影响

以厌氧/好氧交替运行的序批式反应器(SBR)为对象,利用荧光原位杂交技术(FISH),研究了温度(20、25和30℃)对强化生物除磷(EBPR)的影响。结果表明,温度为20℃时,系统的磷去除率高于98%,厌氧释磷速率和好氧吸磷速率分别为55.70 mg P·(gVSS·h)~(-1)和45.16 mg P·(gVSS·h)~(-1),聚磷菌(PAOs)占总细菌(EUB)的比例达到90%,而聚糖菌(GAO)的比例只有1%;温度升高到25℃后,除磷效果不断降低,释磷速率和吸磷速率逐渐下降,PAOs的比例下降,而聚糖菌(GAOs)的比例不断增加;温度为30℃时,出水水质恶化,磷去除率仅为67%,释磷速率和吸磷速率分别为33.66 mg P·(gVSS·h)~(-1)和17.55 mg P·(gVSS·h)~(-1),GAOs的比例高达87%,而PAOs的比例仅为5%,在与PAOs的竞争中,GAOs处于优势,导致除磷效果降低。     

2种磷酸盐生长环境对同步去除与富集磷酸盐工艺的影响

针对同步去除与富集磷酸盐溶液的问题,研究了在低磷环境和低磷高磷交替环境下悬浮填料生物膜反应器的除磷能力和释磷能力,采用扫描电子显微镜(SEM)和高通量测序对第0、45和95天的污泥进行了表征。结果表明:低磷环境下好氧出水磷酸盐浓度稳定在0.5 mg·L~(-1)以下,厌氧阶段的最大释磷量为6.05 mg·L~(-1);在低磷高磷交替环境中,好氧出水磷酸盐浓度基本在0.5 mg·L~(-1)以下,富磷溶液浓度最高可达63 mg·L~(-1)。SEM结果表明,同步去除与富集磷酸盐的悬浮填料生物膜反应器中的主要微生物是杆状菌。高通量测序结果表明:第0、45和95天的变形菌门(Proteobacteria)的相对丰度分别为48.3%、57.1%和89.1%,占主导地位;而红环菌科(Rhodocyclaceae)的相对丰度分别为18.1%、19.0%和30.8%,是反应器中的优势菌科;动胶菌属(Zoogloea)是同步去除与富集磷酸盐的悬浮填料生物膜工艺中的主要功能菌。在悬浮填料生物膜工艺中,低磷高磷交替的生长环境下培养的聚磷生物膜能够使好氧出水的磷酸盐浓度达到国家排放标准,并在厌氧阶段得到高浓度的磷酸盐富集溶液,且这种生长环境更适合聚磷微生物的生长。     

固定化微生物深度降解垃圾渗滤液氨氮

采用固定化微生物深度处理垃圾渗滤液,研究水力停留时间(HRT)、溶解氧(DO)和进水pH对系统脱氮效果的影响。通过对厌氧出水和好氧出水的脱氮效果比较,探讨固定化微生物构筑物的合理位置。结果表明:固定化微生物处理厌氧出水时最佳HRT为72 h最佳DO为5 mg·L~(-1),最佳进水pH为7.5±8.5;处理好氧出水时最佳HRT为84 h最佳DO为5 mg·L~(-1),最佳进水pH为7.5±8.5;处理厌氧出水和好氧出水时氨氮平均去除率分别达到63.8%和92.6%將固定化微生物构筑物单元设置在好氧处理之后更合理,可以充分发挥固定化微生物处理渗滤液脱氮方面的独特优势,切实解决渗滤液高效脱氮的问题。     

侧流磷回收强化低碳源污水脱氮除磷效果的模拟与实验研究

以实验室营养物(BNR)去除工艺为研究对象,通过模拟预测与实验验证,对侧流磷回收强化低碳源污水脱氮除磷效果的影响进行研究.实验结果与模拟预测均显示,在低碳源生活污水(BOD5/TKN=3.2,COD/TKN=4.8,COD/TP=48.9)前提下,厌氧上清液侧流磷沉淀/回收可以使得出水氮、磷达标(TP≤0.5 mg P/L、TN≤15 mg N/L).研究结果表明,侧流磷回收可以相对提高后续生物脱氮除磷所需C/N、C/P比,从而强化低碳源污水生物营养物去除效果.模拟预测与实验验证几乎一致的结果表明,数学模拟技术完全可以取代传统实验,对所关心的工艺运行问题进行准确预测.     

生物絮凝-AAAO中试系统污染物去除特性及反硝化除磷菌的培养

为降低污水处理成本并实现出水稳定达标,采用中试规模生物絮凝-AAAO工艺处理城镇生活污水,并模拟生物絮凝污泥厌氧消化所产生的碳源,用于强化反硝化除磷菌(DPAO)驯化效果。实验结果表明:生物絮凝系统抗冲击负荷能力较强,化学需氧量(COD)、总氮(TN)和总磷(TP)平均去除率可达67.23%、 27%与68.93%。将模拟厌氧消化后产生的碳源投加至厌氧池促进DPAO的驯化后,AAAO系统对COD、TN和TP去除率分别提升31.53%、37.67%和26.37%,反硝化吸磷率最高可达62.97%,二沉池出水COD、TN均满足一级A出水标准,TP可低于0.30 mg·L-1。生物絮凝-AAAO工艺脱氮除磷效果较好,可为污水处理厂节能降耗运行奠定基础并有望得到广泛应用。     

两级自养反硝化实现垃圾渗滤液的深度脱氮

针对目前生物工艺难以解决垃圾渗滤液深度脱氮的问题,探究了短程硝化反硝化-厌氧氨氧化-硫自养反硝化(两级自养)工艺处理高氨氮、低C/N比垃圾渗滤液的脱氮效果。结果表明,当进水垃圾渗滤液中氨氮平均浓度为2 560 mg·L~(-1),COD值为4 000～5 000 mg·L~(-1)时,经过短程硝化反硝化-厌氧氨氧化处理后,总氮去除负荷可达1.19 kg·(m~3·d)~(-1)、总氮去除率可达93.1%(出水TN=176.3 mg·L~(-1))、COD去除率可达52.2%。但是,厌氧氨氧化反应器出水中NO_x~--N浓度为154.5 mg·L~(-1),仍未达到我国生活垃圾填埋场垃圾渗滤液处理排放标准(TN≤40 mg·L~(-1))。在厌氧氨氧化反应器之后串联硫自养反硝化,整体工艺最终出水NH_4~+-N、NO_2~--N、NO_3~--N平均浓度分别为1.9、0.6、9.7 mg·L~(-1),TN≤15 mg·L~(-1),进水总氮去除率为99.5%。在短程硝化反硝化-厌氧氨氧化-硫自养反硝化两级自养深度脱氮反应系统中实现了垃圾渗滤液深度脱氮。     

一段式短程反硝化耦合厌氧氨氧化工艺处理厌氧膜生物反应器出水

采用移动床生物膜反应器,通过一段式短程硝化-厌氧氨氧化耦合短程反硝化工艺处理主流厌氧消化出水.在溶解氧浓度(DO)维持在(1.45±0.15)mg·L-1的条件下,出水TN低至(10.7±2.4)mg·L-1、NH4+-N转化率达到(86.8±4.5)％,平均TN去除率为(78.9±4.9)％(最高达84.0％)、TN...     

黄磷尾气中总磷及磷化氢的测定

电炉法生产黄磷的过程中会产生大量的尾气,其主要成分是CO(85％～95％)．还有磷、硫、氟、砷、CO2、N2、H2等杂质。黄磷尾气中的磷主要以P4、PH3、P2O5等形式存在。一般尾气经过水洗后．P2O5大部分被水吸收,尾气中主要是P4、PH3。采用分光光度法分析总磷和气体检测管测定磷化氢,效果良好。     

反硝化聚磷一体化设备中的聚磷菌

研究了新型生物脱氮除磷新工艺反硝化聚磷一体化设备中反硝化厌氧池活性污泥的兼性厌氧微生物组成，数量及其在该除磷系统中功能，结果表明，稳定运行期反硝化厌氧池内活性污泥混合液的兼性厌氧微生物总数大大多于启动期，稳定期和启动期分离的兼性厌氧微生物有假单胞菌属，副球菌属和肠杆菌科，通过对三种纯菌株进行吸放磷研究，三种菌都有不同程度的聚磷功能，说明反硝化菌也具有聚磷作用。     

污泥消化液的磷浓度对anammox-HAP系统磷回收的影响

厌氧氨氧化-羟基磷酸钙(anammox-hydroxyapatite,anammox-HAP)技术可实现污泥厌氧消化液高效自养脱氮同步磷回收.污泥厌氧消化液中磷的浓度与污泥性质、厌氧消化过程相关,变化范围很大.为探索anammox-HAP 系统中的磷回收效率,通过基于anammox-HAP长期运行的膨胀颗粒污泥床反应器...     

Phytoextraction of excess soil phosphorus

In the search for a suitable plant to be used in P phytoremediation, several species belonging to legume, vegetable and herb crops were grown in P-enriched soils, and screened for P accumulation potentials. A large variation in P concentrations of different plant species was observed. Some vegetable species such as cucumber (Cucumis sativus) and yellow squash (Cucurbita pepo var. melopepo) were identified as potential P accumulators with >1% (dry weight) P in their shoots. These plants also displayed a satisfactory biomass accumulation while growing on a high concentration of soil P. The elevated activities of phosphomonoesterase and phytase were observed when plants were grown in P-enriched soils, this possibly contributing to high P acquisition in these species. Sunflower plants also demonstrated an increased shoot P accumulation. This study shows that the phytoextraction of phosphorus can be effective using appropriate plant species.     

Surface water phosphorus dynamics in rice fields receiving fertiliser and manure phosphorus

A long-term randomised block field experiment was established in 1997 to study the dynamics of total P and dissolved P in the surface waters of rice fields receiving two application rates of fertiliser P and one rate of combined fertiliser and manure P. Preliminary results from the first two crops show that concentrations of both total P and dissolved P in the surface waters increased significantly following P application, especially during the first 2 weeks after application. P concentrations subsequently declined sharply within about 10 days, then declined steadily and remained almost constant from about 1 month after application. The initial increase in P concentration of surface waters was higher with increasing rate of fertiliser P, and the P concentration at the highest fertiliser rate peaked within about 1 week of application. The elevated P concentrations following fertiliser P application declined more rapidly than those following the combined application of fertiliser and manure P. When fertiliser and manure P were applied together, about 7 days later the surface water P concentrations were significantly higher than when the same rate of P (or double) was applied as fertiliser only. Disturbance of the surface soil by hand harrowing further increased the P concentrations in surface waters, with a subsequent decline to a steady value after about 1 week. Application of P fertiliser to the high P status soil in this experiment gave no crop yield response and may have increased the risk of pollution of adjacent surface waters through drainage from heavy rainfall events during the rice growing season. Therefore, fertiliser P should not be applied to such soils. If, however, fertiliser or manure P is applied, the application should be made during the dry winter to reduce P losses. Manure should be applied with particular care because of the higher risk of P losses to surface water arising from the relatively long period of high P concentrations in surface waters and the potential for greater release of P to field surface waters from the soil. Hand harrowing should also be avoided during wet weather to protect water quality.     

Capturing the lost phosphorus

Minable phosphorus (P) reserves are being depleted and will need to be replaced by recovering P that currently is lost from the agricultural system, causing water-quality problems. The largest two flows of lost P are in agricultural runoff and erosion (∼46% of mined P globally) and animal wastes (∼40%). These flows are quite distinct. Runoff has a very high volumetric flow rate, but a low P concentration; animal wastes have low flow rates, but a high P concentration together with a high concentration of organic material. Recovering the lost P in animal wastes is technically and economically more tractable, and it is the focus for this review of promising P-capture technologies. P capture requires that organic P be transformed into inorganic P (phosphate). For high-strength animal wastes, P release can be accomplished in tandem with anaerobic treatment that converts the energy value in the organic matter to CH₄, H₂, or electricity. Once present as phosphate, the P can be captured in a reusable form by four approaches. Most well developed is precipitation as magnesium or calcium solids. Less developed, but promising are adsorption to iron-based adsorbents, ion exchange to phosphate-selective solids, and uptake by photosynthetic microorganisms or P-selective proteins.     

Effect of low levels of dietary available phosphorus on phosphorus utilization,bone mineralization,phosphorus transporter mRNA expression and performance in growing pigs

A study was conducted to examine the effects of different dietary levels of available phosphorus (aP) on P excretion, bone mineralization, performance and the mRNA expression of sodium-dependent P transporters in growing pigs. Sixty-day old growing pigs (n = 54) with an average initial BW of 19.50 ± 1.11 kg were randomly allocated to a control diet (C) containing 0.23% available phosphorus (aP), T1 containing 0.17% aP and T2 containing 0.11% aP. There were 6 pens per treatment with 3 pigs per pen. Body weight and feed intake were measured weekly. At the end of each week, one pig from each pen was housed in a metabolic crate for 24 h to collect fecal and urine samples and then sacrificed to obtain third metacarpal (MC3) bones and jejunal and kidney samples. Bones were scanned by Dual Energy X-ray Absorptiometry (DEXA). Fecal and urine samples were sub-sampled and analyzed for P content. The expression of P transporter mRNA in jejunum and kidney samples was measured using quantitative real-time polymerase chain reaction (qRT-PCR). Data were analyzed using GLM procedure of the Statistical Analysis System (SAS Institute version 9.2). Pigs fed the T2 diet had reduced (P < 0.05) average daily gain (ADG) and gain to feed (G:F) compared to those fed the C diet during week 2. Overall, ADG and G:F were also reduced (P < 0.05) in pigs fed the T2 diet compared to those fed the C and T1 diets. Bone mineral density (BMD) and bone mineral content (BMC) were reduced (P < 0.05) in pigs fed the T2 diet compared to those fed the C diet throughout the experiment. At week 1, jejunal mRNA expression of Na (+)-dependent phosphate transporter 2 (SLC34A2) was increased (P < 0.01) in pigs fed the T2 diet compared to C diet. Renal mRNA expression of Na(+)-dependent phosphate transporter 1 (SLC34A1) and SLC34A3 were increased (P < 0.05) in pigs fed the T2 diet compared to those fed the C diet at week 2 and was accompanied by lower (P < 0.05) urinary P in pigs fed the T2 diet during week 2 and week 3. In conclusion, growing pigs are highly sensitive to low dietary P as shown by reduced ADG, bone mineralization and urinary P level, but moderate reduction in dietary P up to 0.17% aP in the diet has the potential to reduce environmental pollution by reducing P concentration in swine manure and without compromising performance.