硝酸盐对反硝化除磷过程的影响分析

在厌氧/缺氧间歇反应器内考察了硝酸盐进水浓度及进水方式对反硝化除磷过程的影响。结果表明：在缺氧阶段，反硝化除磷菌(DPBs)可将硝酸盐转化为亚硝酸盐，当硝酸盐浓度较低时，DPBs以亚硝酸盐为电子受体吸磷。进水COD浓度为220 mg/L，正磷浓度为6.8 mg/L，硝酸盐初始浓度为26 mg/L时，系统达到最佳脱氮除磷效果，期间亚硝酸盐浓度积累至10.71 mg/L。采用连续流投加硝酸盐的方式更利于氮磷的高效去除。     

以亚硝酸盐为电子受体的反硝化除磷过程中N_2O积累的影响因素

接种稳定运行140 d的反硝化除磷污泥,通过批次实验,研究了亚硝态氮投加方式、进水COD浓度和p H对反硝化除磷过程N_2O代谢的影响。结果表明,60 mg/L的亚硝态氮均分3次投加与1次投加相比,系统内N_2O最大积累量从14.23 mg/L降低为2.90 mg/L,经缺氧吸磷后N_2O剩余量由8.20 mg/L降低至0.02 mg/L,表明多次投加亚硝态氮可有效避免N_2O的积累。当初始进水COD浓度为150、300和450 mg/L时,经3 h缺氧代谢后出水中N_2O剩余量分别为11.70和7.59、4.77 mg/L,较高进水COD浓度可有效降低N_2O的产量。不同p H值的实验结果表明,较高p H可促进N_2O的代谢,并最终减少N_2O的产生量。     

硝酸盐浓度及投加方式对反硝化除磷的影响

采用SBR反应器，详细研究了硝酸盐浓度及其投加方式对反硝化除磷过程的影响。结果表明，缺氧环境下的反硝化吸磷速率与作为电子受体的硝酸盐浓度有很大的关系，硝酸盐浓度越高．吸磷速率越快。当硝酸盐浓度较低．不足以氧化反硝化聚磷菌细胞内的PHB从而导致体系反硝化除磷效率的下降。相同浓度的硝酸盐，采用流加的方式可以获得比一次性投加更高的反硝化吸磷速率。缺氧环境下，反硝化脱氮量与磷的吸收量成良好的线性关系．借助于反硝化聚磷菌，反硝化脱氮与除磷可在一种环境中完成，有效解决了废水中COD不足的问题．同时达到了节省能源和降低污泥产量的目的。     

厌氧／缺氧SBR反硝化除磷效能的研究

采用厌氧 缺氧SBR反应器对以硝酸盐作为电子受体的反硝化除磷过程进行了研究。结果表明 ,反硝化聚磷菌完全可以在厌氧 缺氧交替运行条件下得到富集。稳定运行的厌氧 缺氧SBR反应器的反硝化除磷效率 >90 % ,出水磷浓度 <1mg L。进水COD浓度对反硝化除磷的效率影响很大 ,在COD浓度 <180mg L时 ,进水COD浓度越高 ,除磷效率也就越高。较高浓度的进水COD浓度将导致有剩余的COD进入缺氧段 ,对反硝化吸磷构成不利影响。污泥龄为 16d时 ,厌氧 缺氧SBR反应器取得稳定和理想的反硝化除磷效果。污泥龄减少到 8d ,由于反硝化聚磷菌的流失导致反硝化除磷效率的下降。当污泥龄恢复到 16d时 ,经过一段时间的运行 ,反硝化聚磷菌重新得到富集 ,除磷效率恢复到 90 %以上。     

不同电子受体浓度对反硝化除磷的影响及动力学特性

以A~2/O-移动床生物膜反应器(MBBR)长期稳定运行的反硝化除磷污泥为研究对象,通过在厌氧段投加乙酸钠、缺氧段投加NO_3~--N,考察反硝化聚磷菌(DPAOs)在不同电子受体浓度(NO_3~--N:10、20、30、40、50 mg·L~(-1))下的脱氮除磷特性以及内碳源转化利用规律。实验结果表明:缺氧段电子受体不足导致吸磷受限,微生物由于处于饥饿状态出现糖原(GLY)降解,增加二次释磷的风险;而电子受体过量会抑制DPAOs的生物活性,降低内碳源的转化利用效率和同步脱氮除磷效果。当NO_3~--N浓度为30～40 mg·L~(-1)时,NO_3~--N和PO_4~(3-)-P去除率分别为92.28%～96.37%和99.39%～100%,聚-β-羟基链烷酸脂(poly-β-hydroxyalkanoate,PHAs)利用率为84.6%～86.2%,达到较好的同步脱氮除磷效果且实现了内碳源的高效利用。动力学参数对比结果表明,不同电子受体浓度下比吸磷速率(PUR)和比反硝化速率(DNR)在4.32～8.18 mg·(g·h)~(-1)、1.81～6.08 mg·(g·h)~(-1)(以VSS计)范围内波动,且NO_3~--N/PO_4~(3-)-P比值可间接反映DPAOs生物活性。     

亚硝酸盐对反硝化聚磷菌除磷性能的影响

为考察亚硝酸盐对反硝化聚磷菌（DPB）的影响，试验以模拟污水为研究对象，采用2个相同的SBR反应器，分别进行亚硝酸盐浓度对DPB的抑制影响和亚硝酸盐对DPB驯化过程的研究。结果表明，当亚硝酸盐浓度高于20 mg/L时，未经亚硝酸盐驯化的DPB反硝化除磷性能受到明显抑制，而经过亚硝酸盐驯化后的DPB在亚硝酸盐浓度为32 mg/L左右时，依然保持良好的反硝化吸磷性能，但以亚硝酸盐为电子受体的反硝化吸磷速率要比硝酸盐为电子受体的低21%。由此说明，亚硝酸盐对DPB反硝化除磷的抑制作用是相对的，可通过亚硝酸盐对DPB的诱导驯化来降低此抑制作用，但硝酸盐比亚硝酸盐更适合作为DPB反硝化除磷的电子受体。     

螺旋升流式反应器脱氮除磷系统的运行效果与污泥性能分析

对螺旋升流式反应器脱氮除磷及去除COD的运行效果进行了研究 ,该系统连续稳定运行 6个月的结果表明 ,能保证出水平均质量浓度TN小于 1 0mg/L ,TP小于 0 5 0mg/L ,COD小于 31mg/L ,对TN、TP和COD的去除率分别达 86 %、96 %和 94 %以上。并且对SUFR系统的污泥性能进行了分析 :(1 )螺旋升流特征使本反应系统中的污泥易于颗粒化 ;(2 )SUFR系统中的微生物种群具有多样性 ;(3)污泥在好氧反应器中表现出了同步硝化反硝化功能 ;(4 )污泥在缺氧反应器表现出了反硝化吸磷现象     

硝态氮为惟一氮源时异养微生物增长特性

采用SBR研究了缺氧条件下硝态氮为惟一氮源时异养微生物的增长特性。结果表明,异养微生物能利用硝态氮作为氮源进行增殖。当进水COD浓度为1 400 mg/L,硝态氮浓度为280 mg/L时,COD和硝态氮的去除率分别达到97%和99%;污泥中微生物的含氮量为8.8%,低于常规利用氨氮作为氮源的微生物;在实验条件下活性污泥的产率系数为0.30 g VSS/g COD。反硝化菌可利用硝态氮作为氮源进行细胞合成对含硝氮的废水处理具有重要意义。一方面由于无需投加氨氮降低了废水处理成本,另一方面由于污泥产率低,降低了污泥处理成本。     

进水氨氮浓度对好氧/缺氧/延长闲置SBR脱氮除磷性能的影响

以合成废水为研究对象,考察了不同进水氨氮浓度(20,40和60 mg/L)条件下好氧/缺氧/延长闲置SBR的脱氮除磷效果,并通过分析典型周期内氮磷元素及微生物体内各储能物质的变化,探究了进水氨氮浓度对好氧/缺氧/延长闲置SBR脱氮除磷性能的影响机理。结果表明,进水氨氮浓度为20,40和60 mg/L时,系统总磷(TP)去除率分别为96.6%、90.1%和81.8%,总氮去除率分别为93.1%、74.9%和60.0%。研究表明,进水氨氮浓度可影响好氧释磷与吸磷、聚羟基脂肪酸酯(PHAs)合成、缺氧反硝化以及闲置段释磷。进水氨氮浓度越高,用于微生物生长的碳源越多,PHAs的合成量越少,则好氧段吸磷减少;较高的进水氨氮浓度使缺氧段反硝化不彻底,较多的硝态氮将抑制下一周期好氧段释磷,系统脱氮除磷性能减弱。     

螺旋升流式反应器脱氮除磷系统的运行效果与污泥性能分析

对螺旋升流式反应器脱氮除磷及去除COD的运行效果进行了研究，该系统连续稳定运行6个月的结果表明．能保证出水平均质量浓度TN小于10mg／L，TP小于0．50mg／L，COD小于31mg／L，对TN、TP和COD的去除率分别达86％、96％和94％以上。并且对SUFR系统的污泥性能进行了分析：(1)螺旋升流特征使本反应系统中的污泥易于颗粒化；(2)SUFR系统中的微生物种群具有多样性；(3)污泥在好氧反应器中表现出了同步硝化反硝化功能；(4)污泥在缺氧反应器表现出了反硝化吸磷现象。     

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.     

溶解氧对EBPR主流除磷及侧流磷回收性能的影响

采用交替厌氧/好氧(An/O)模式下运行的SBR,考察不同溶解氧(DO)浓度(1.0、0.5、0.1 mg·L~(-1))对同步侧流磷回收的强化生物除磷(enhanced biological phosphorus removal,EBPR)主流系统除磷及侧流磷回收性能的影响。结果表明,整个实验阶段主流系统对COD、NH_4~+-N及TN的去除均能稳定达到《城镇污水处理厂污染物综合排放标准》一级A标准,其中TN因出水NO_3~--N浓度的降低而降低,故TN去除率升高。DO为1.0 mg·L~(-1)和0.5 mg·L~(-1)时对磷的去除率分别为99.0%和95.4%,主流系统出水磷达标率分别为96.0%和84.0%。而当DO浓度过低(0.1 mg·L~(-1))时,硝化与吸磷对有限电子受体的竞争及吸磷时间不足导致反应结束时系统内平均磷残留量达1.02 mg·L~(-1),除磷率降至87.2%。鉴于侧流磷回收是对主流系统的磷剥夺,会影响污泥的好氧吸磷能力,继而厌氧阶段释磷量因侧流提取降低。与此同时,DO为1.0 mg·L~(-1)时,侧流磷回收率较其余2个工况高,且此工况下主流系统的厌氧释磷及好氧吸磷能力均最高,考虑到主流工艺的可靠运行及出水稳定性,认为DO=1.0 mg·L~(-1)为最优工况。     

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.