不同比例乙酸和丙酸对活性污泥微生物合成聚羟基脂肪酸酯的影响

聚羟基脂肪酸酯（PHA）是一种生物可降解塑料,利用活性污泥合成PHA具有节约成本、操作方便的优点。研究选择污泥发酵液挥发性脂肪酸（VFAs）中比重相对较高的乙酸和丙酸作为碳源自配营养液,深入研究不同质量浓度比对PHA合成的影响。结果表明,乙酸为主要碳源时更有利于PHA的合成,最大合成量12.3%出现在乙酸作为唯一碳源的条件下。此外,PHA合成量随着底物中有机酸比重的增加而增加,充分展现了利用挥发性脂肪酸大量合成PHA的良好前景。     

碱预处理污泥产酸效果及其生物群落研究

为了提高污泥水解酸化过程中的挥发酸产量,获取污水脱氮除磷所需的内碳源,以深圳市罗芳污水厂的二沉池污泥为研究对象,采用不同的碱量对其进行预处理。通过测定碱预处理污泥水解酸化过程中的挥发酸浓度,并采用聚合酶链式反应-变性梯度凝胶电泳(polymerase chain reaction denature gradient gel electrophoresis,PCR-DGGE)技术对参与碱预处理污泥水解酸化产酸过程的主要微生物种群进行分析,结果表明,当碱投加量为0.20 g NaOH/g VSS时,初始溶出的蛋白浓度为1 780 mg/L;水解酸化15 d时,挥发酸总量达到3 473 mg/L;参与产酸的主要细菌属于Firmicutes、Proteobacteria、Bacteroidetes三个门类。     

以剩余污泥水解酸化液为外加碳源的污水生物脱氮

为解决低碳氮比污水生物脱氮过程反硝化碳源不足的问题,利用剩余污泥水解酸化液为外加碳源,通过具有曝气段与非曝气段的一体化曝气生物滤池（BAF）,研究低碳氮比污水生物脱氮的性能与工艺条件。实验结果表明,预处理后的水解酸化液VFAs为3134．9～5251．4mg／L、ThODVFAs／COD为59．87％～91．85％,适合作为生物脱氮的外加碳源;水解酸化液的投配量、进水TN浓度对系统生物脱氮效果的影响较大,气水比、曝气段与非曝气段比例对系统的硝化和反硝化性能有重要的影响;在温度为25±1℃,水解酸化液COD平均为7555．1mg／L,进水TN、NH4-N和COD分别平均为43．88mg／L、39．04mg／L和56．8mg／L,碳源与污水投配的流量比为1：75的条件下,当BAF水力停留时间（HRT）为8h、曝气段与非曝气段比例为3：3、气水比为10：1、回流比为2：1时,NH4-N和TN的去除率分别超过98％和75％,出水COD平均为28．6mg／L。研究指出,剩余污泥水解酸化液经过预处理后可用作低碳氮比污水生物脱氮的外加碳源,有效地提高了反硝化效果,并不会造成二次污染,同时又可以实现剩余污泥的减量化和资源化。     

温度对木质纤维素水解与挥发性脂肪酸累积的影响

木质纤维素厌氧消化过程产生的挥发性脂肪酸（VFAs）可作为外加碳源投加到人工湿地,解决人工湿地反硝化碳源不足的问题,但温度对木质纤维素厌氧消化生产VFAs过程的影响还有待深入探明。考察上述木质纤维素厌氧消化过程中有机碳源、糖与VFAs的变化规律,试图探明温度（10-55℃）对木质纤维素水解与VFAs累积的影响。研究结果表明,温度升高对木质纤维素的水解具有促进作用,对VFAs产量的影响显著。35℃时是生物质发酵产酸的最优条件,VFAs累积量不仅最早（第10天）达到最高值154mgCOD／g生物质,而且碳源的数量和品质均达到较高的水平。     

Biodegradation of 4-aminobenzenesulfonate by Ralstonia sp. PBA and Hydrogenophaga sp. PBC isolated from textile wastewater treatment plant

A co-culture consisting of Hydrogenophaga sp. PBC and Ralstonia sp. PBA, isolated from textile wastewater treatment plant could tolerate up to 100 mM 4-aminobenzenesulfonate (4-ABS) and utilize it as sole carbon, nitrogen and sulfur source under aerobic condition. The biodegradation of 4-ABS resulted in the release of nitrogen and sulfur in the form of ammonium and sulfate respectively. Ninety-eight percent removal of chemical oxygen demand attributed to 20 mM of 4-ABS in cell-free supernatant could be achieved after 118 h. Effective biodegradation of 4-ABS occurred at pH ranging from 6 to 8. During batch culture with 4-ABS as sole carbon and nitrogen source, the ratio of strain PBA to PBC was dynamic and a critical concentration of strain PBA has to be reached in order to enable effective biodegradation of 4-ABS. Haldane inhibition model was used to fit the degradation rate at different initial concentrations and the parameters μ_max, K_s and K_i were determined to be 0.13 h⁻¹, 1.3 mM and 42 mM respectively. HPLC analyses revealed traced accumulation of 4-sulfocatechol and at least four unidentified metabolites during biodegradation. This is the first study to report on the characterization of 4-ABS-degrading bacterial consortium that was isolated from textile wastewater treatment plant.     

VFA generation from waste activated sludge: effect of temperature and mixing

The success of enhanced biological phosphorus removal (EBPR) depends on the constant availability of volatile fatty acids (VFAs). To reduce costs, waste streams would be a preferred source. Since VFAs were shown to vary in the incoming sewage and fermentate from primary sludge the next available source is waste activated sludge (WAS). The opportunity is particularly good in plants where WAS is stored before shipment. Little information is however available on the rate of VFA release from such sludge, especially at the lower temperatures and under the storage conditions typically found in colder climates. Bench-scale batch tests were performed to investigate the effect of temperature and requirement for mixing on VFA generation from WAS generated in full scale non-EBPR wastewater treatment plant. WAS fermentation was found highly temperature-dependent. Hydrolysis rate constant (k_h) values of 0.17, 0.08 and 0.04 d⁻¹ at 24.6, 14 and 4 °C were obtained, respectively. Arrhenius temperature coefficient was calculated to be 1.07. It took 5 d to complete hydrolysis at 24.6 °C, 7 d at 14 °C, and 9 d at 4 °C. The fermentation lasted for 20 d. At 24.6 °C the mixed reactor reached 84% of the overall VFA production only in 5 d. When temperature dropped to 14 and 4 °C, the ratio of VFA production at day 10 to overall VFA production in the mixed reactor were 62% and 48%, respectively. The overall VFA-COD concentration in the non-mixed reactors was much lower than the mixed reactors. The information is important for the designer as there was uncertainty with the effect of temperature and mixing on sludge fermentation.     

剩余污泥在微氧条件下利用VFAs合成PHAs的工况优化

针对2种脱氮除磷工艺的剩余污泥,在微氧条件下,以花生渣厌氧发酵产生的VFAs为碳源,控制反应时间为5 h,DO≤0.2 mg·L⁻¹,COD为650~750 mg·L⁻¹,对比2种不同工艺的剩余污泥合成聚羟基脂肪酸酯(PHAs)的量,并探究了增设前置曝气对微氧条件下剩余污泥合成PHAs的影响。结果表明,在微氧条件下,连续流中同步亚硝化反硝化脱氮除磷系统二沉池的剩余污泥(R1)和采用A²O工艺的实际水厂的剩余污泥(R2)合成PHAs最高量分别为108.6 mg·g⁻¹和58.58 mg·g⁻¹,R1比R2更具有合成PHAs的能力;在增设前置曝气实验中,曝气时间的延长和曝气量的增大均可促进PHAs的合成;当曝气气量为50 L·h⁻¹时,曝气20 min后,R1合成的PHAs最高为172.5 mg·g⁻¹。氧化还原电位(Eh)是微氧条件下PHAs合成过程中的重要指示参数,当Eh值为最低时,PHAs合成量最多。以上结果可为脱氮除磷工艺剩余污泥利用廉价碳源合成PHAs提供参考。     

活性污泥吸附联合发酵产酸资源化回收污水碳源

利用活性污泥源头吸附回收污水中的有机碳源,然后进行厌氧发酵产酸,可以改变污水碳源在传统工艺中的迁移与转化途径。研究结果表明,本工艺大大提高了有机碳源的利用率,降低了后续水解释碳成本。在30 min内,活性污泥对污水COD、氨氮和总磷的吸附去除率分别达到69%、57%和58.2%。热碱水解（t=90℃,pH=11）能够实现吸附碳源污泥（富碳污泥）中有机物的快速释放,水解污泥上清液中COD、溶解性蛋白质和溶解性多糖含量分别达到8 173.8、1 508.8和1 936.0 mg·L-1。将获得的有机物进行厌氧发酵产酸,挥发性有机酸总量达到6 025.4 mg·L-1,与普通活性污泥相比,提高了27.7%;但是有机酸的组成和发酵所需时间变化不大。本研究结果为污水处理厂节能降耗以及污泥资源化处理处置提供参考。     

椰壳颗粒活性炭活化过硫酸钠预处理促进高固污泥水解产酸性能

为探究椰壳颗粒活性炭活化过硫酸钠(PS)预处理对高固污泥厌氧发酵水解产酸性能的影响,通过调节挥发性脂肪酸(VFAs)产量、溶解性化学需氧量(SCOD)、溶解性蛋白质及多糖等指标,探究了不同剂量颗粒活性炭(GAC)与PS预处理对高固污泥产酸发酵的最佳条件。结果表明,当PS和GAC投加量分别为1.50 mmol·g⁻¹(以总固体计)和0.65 g g⁻¹(以总固体计)时,在发酵前期产酸速率相比于对照组提高了341.43%,后续发酵过程中,VFAs最大产量相比于对照组提高了28.43%。其中,乙酸作为优质碳源,其质量浓度增加了48.98%;继续增加GAC剂量时,反应器厌氧发酵性能下降,其原因可能是过量GAC会消耗已生成的SO₄⁻·,降低污泥水解作用,同时GAC表面对VFAs的吸附也导致产酸量下降。三维荧光分析表明,在产酸量较高的反应器中,氨基酸、芳香族蛋白质等溶解性有机物的质量浓度较低,这说明适量椰壳颗粒活性炭活化PS预处理方式可提高高固厌氧发酵中微生物对于水解底物的利用率,从而提高污泥的厌氧产酸性能。本研究结果可为炭活化PS预处理技术在高固污泥厌氧消化中的应用提供参考。     

3种短链脂肪酸对活性污泥储存PHA的影响

采用经乙酸钠驯化培养具有一定聚羟基烷酸酯(PHA)储存能力的活性污泥,考察乙酸、丙酸和丁酸3种短链脂肪酸,以及乙酸、丁酸分别与丙酸按1∶1、1∶2、2∶1比例组合成的6种混合酸作为碳源时对活性污泥中PHA的储存和转化的影响。实验结果表明,在3种短链脂肪酸中,以丁酸为碳源得到活性污泥PHA储存量最高,为40.53 mg/g;在混合酸中,乙酸与丙酸按1∶2组合时,系统PHA储存量最高,为773.4 mg/g。混合酸相对于单一的脂肪酸碳源更有利于活性污泥储存PHA。在混合酸总量一定的条件下,随着丙酸比例的增加,乙酸与丙酸混合比丁酸与丙酸混合更有利于微生物的PHA储存。     

干式厌氧消化过程挥发酸对硫酸盐还原菌的影响

在牛粪干式厌氧消化过程中,通过添加不同挥发酸(乙酸、丙酸、丁酸),考察消化稳定阶段,挥发性脂肪酸的分布特征,挥发性脂肪酸酸组成变化对硫酸盐还原菌(SRB)的影响,微生物种群组成和种群间关系。实验结果表明,挥发性脂肪酸对SRB还原速率的贡献依次为:丙酸丁酸乙酸。相比乙酸和丁酸,添加一定量的丙酸,更有利于激活SRB的活性,从而加强SRB与产甲烷菌(MB)的种间协同,保证厌氧系统的稳定运行。     

限氮和限磷对活性污泥合成聚羟基烷酸的影响

聚羟基烷酸(PHA)是微生物在不平衡营养条件下贮存的一种胞内聚合物,限磷和限氮两种方式均有助于活性污泥中的混合菌群合成PHA,研究考察了两种不同方式下活性污泥合成PHA的情况。实验结果表明,当C∶N为125时,活性污泥中PHA的合成量达到细胞干重的59%;当C∶P为750时,活性污泥积累的最大PHA含量占细胞干重的37%,说明限氮和限磷两种方式对活性污泥合成PHA均有很大影响,且限氮方式更有效。     

Effects of selected pharmaceutically active compounds on the ammonia oxidizing bacterium Nitrosomonas europaea

Pharmaceutically active compounds (PhACs) are commonly found in wastewater influent. However, little research has focused on determining their impact on fundamental processes in wastewater treatment such as nitrogen removal. In this study, focus was placed on 4 commonly occurring PhACs (ketoprofen, naproxen, carbamazepine and gemfibrozil). Their effect was ascertained in the ammonia oxidizing bacterium (AOB), Nitrosomonaseuropaea in terms of membrane integrity and nitrite production. These PhACs were shown to inhibit nitrite production at concentrations of 1 and 10 μM while no effect was observed at 0.1 μM. The maximum observed nitrification inhibition was 25%, 29%, 22% and 26% for ketoprofen, naproxen, carbamazepine and gemfibrozil, respectively. A decrease in the live/dead ratio ranging from 10% to 16% suggests that these PhACs affect membrane integrity in N.europaea. The difference in nitrite production between PhACs treated cells and non PhAC treated controls was still significant following washing suggesting that inhibition is irreversible. Finally, nitrite production when adjusted to the live fraction of cells was also found to decrease suggesting that PhACs inhibited the activity of surviving cells. These results suggest that the presence of PhACs may affect AOB activity and may impact nitrogen removal, a key function in wastewater treatment. Follow up studies with additional AOB and in mixed culture are needed to further confirm these results.     

The use of naturally generated volatile fatty acids for herbicide removal via denitrification

This research focuses on the removal of 2, 4-D via denitrification, with a particular emphasis on the effect of adding naturally generated volatile fatty acids (VFAs) as a carbon source. These VFAs had been produced from an acid-phase anaerobic digester (mean VFA concentration of 3153 ± 801 mg/L [as acetic acid]). The first step involved developing 2, 4-D degrading bacteria in a sequencing batch reactor (SBR) fed with both sewage and 2, 4-D (30–100 mg/L). Subsequent denitrification batch tests demonstrated that the specific denitrification rate increased from 0.0119 ± 0.0039 to 0.0192 ± 0.0079 g NO₃-N/g volatile suspended solids (VSS) per day, when using 2, 4-D alone versus 2, 4-D plus natural VFAs from the digester as a carbon source. Similarly, the specific 2, 4-D consumption rate increased from 0.0016 ± 0.0009 to 0.0055 ± 0.0021 g 2,4-D/g VSS per day, when using 2, 4-D alone as compared to using 2, 4-D plus natural VFAs. Finally, a parallel increase in the percent 2, 4-D removal was observed, rising from 28.33 ± 11.88 using 2, 4-D alone to 54.17 ± 21.89 using 2, 4-D plus natural VFAs.     

pH对蛋白类餐厨垃圾发酵产酸的影响

为了将蛋白类餐厨垃圾厌氧发酵产挥发性脂肪酸（VFAs）用作强化生物除磷过程中的碳源,实现其资源化利用,考察了在35 ℃条件下,pH的改变对其产酸的影响。结果表明：将起始pH调节为碱性,VFAs的产量显著高于酸性,且随着发酵时间的增加,VFAs的产量也逐渐增加,在pH=10,第8天时达到最高值36 193 mg?L-1,此时是初始值的28倍。其中,乙酸占50.3%,其次为丙酸30.9%。同时发现,pH调节为碱性也有利于溶解性COD（SCOD）、溶解性蛋白质（SPN）和溶解性碳水化合物（SPS）的溶出;在pH=10,第3天时SCOD和SPN分别达到最大值135 680 mg?L-1和44 188 mg?L-1,此时是对照组的17倍和8倍。只有在强碱性条件下,SPN产量才明显提高。酸碱调节对SPS的溶出影响并不是太大,其在较短时间1 d内达到最大,然后减少并逐渐趋于稳定。通过分析可知,起始pH调节为强碱性有利于蛋白类餐厨垃圾的发酵产酸及有机质溶出的过程。     

剩余污泥水解酸化液磷去除的影响因素研究

城市污水厂剩余污泥水解酸化后可产生高浓度挥发性有机酸(VFAs),其中的乙酸和丙酸是增强生物除磷(EBPR)工艺的有利基质.但水解酸化液中含有大量的磷,如不进行处理就作为碳源回用到污水处理工艺中,势必增加除磷负荷.利用鸟粪石沉淀法可以去除污水中的磷.对城市污水厂剩余污泥水解酸化液形成鸟粪石的影响因素进行了试验研究.结果表明,在最佳工艺条件下,正磷和总磷的去除率分别可达92.5%和83.8%.     

AOA-SBR系统脱氮除磷性能及PAOs的代谢特性

以SBR反应器为研究对象,采用人工配水,考察在厌氧/好氧/缺氧（AOA）运行方式下系统的脱氮除磷性能,并通过对排水比、好氧停留时间和进水氨氮负荷的调试,优化运行条件。在优化工况下,通过分析典型周期系统中胞内聚合物的形成与转化情况,研究AOA-SBR系统中聚磷菌（PAOs）的代谢特性。结果表明：在AOA-SBR系统中,排水比为50%,好氧停留时间为110 min,进水氨氮负荷为0.20 kg N·（kg MLSS·d）-1是系统的优化工况;厌氧段合成PHA的能量主要来自于聚磷水解,还原力大多来自于糖酵解,只有25% 来自于TCA循环;PHA和糖原是驱动缺氧段反硝化的共同碳源。     

VFAs、TOC及COD作为生物除磷能力指标的探讨

在实际生活污水的处理中,研究了通过A/O运行模式对生物除磷过程中磷的变化情况及在厌氧释磷过程中COD、TOC与VFAs变化之间的关系。结果表明,在厌氧释磷过程中VFAs的变化更能准确地反映系统内释磷进程,实际生活污水中能直接用于磷释放的有机物含量占COD的13.33%,并且释放1 mg P所需VFAs为1.401 mg,此值明显低于前期研究结果。通过对COD、TOC和VFAs 3种组分的分析,可将实际生活污水中的有机底物分为3类:易生物降解含碳有机物、难降解的含碳有机物和水中存在的无机性还原物质,含量分别占COD的13.33%、31.7%和54.97%,其中只有13.33%的含量对生物释磷有直接作用,并可对实际生活污水除磷有指导意义。     

Production of polyhydroxyalkanoate during treatment of tomato cannery wastewater.

Polyhydroxyalkanoate (PHA) production was achieved using tomato cannery waste coupled with a mixed microbial culture during wastewater treatment. The two-stage PHA production process comprised a sequencing batch reactor (SBR), operating under a periodic feast-famine regime, to accomplish simultaneously wastewater treatment and selection of PHA-accumulating microbes, followed by a batch reactor for the production of PHA-rich biomass. The SBRs were efficient at removing soluble carbon (84%), ammonia (100%), and phosphorus (76%). Meanwhile, PHA-accumulating microbes were enriched under the SBR operating conditions, and PHA content on a cell-weight basis was within the range 7 to 11% in nonfiltered wastewater and 2 to 8% in filtered wastewater. Subsequently, batch studies were implemented with varying loading rates, ranging from 0.4 to 3.2 food-to-microorganism ratios. A maximum 20% PHA content on a cell-weight basis was obtained. Based on the experimental results, a PHA biosynthesis-degradation kinetic model was developed to (1) aid in the design of a pilot- or full-scale PHA production process coupled with wastewater treatment and (2) determine optimal conditions for harvest of PHA-rich biomass.     

Intrinsic degradation of volatile fatty acids in laboratory-compacted clayey soil

Volatile fatty acids (VFAs) represent the major organic constituent of landfill leachate and provide the greatest potential for leachate induced organic contamination of groundwater (e.g. as represented by an increase in the concentration of dissolved organic carbon and chemical oxygen demand). Long-term diffusion tests were performed for laboratory-compacted clayey soil plugs exposed to continuous supply of synthetic leachate containing VFAs. Significant microbial activity developed upon exposure of the soil's indigenous microorganisms to these degradable contaminants. The growth of heterotrophic aerobic bacteria (HAB, which include facultative anaerobes), sulfate reducing bacteria (SRB) and methanogenic bacteria carrying out fermentation and mineralization of the VFAs became evident after 30-50 days of testing. The maximum microbial counts of (2-8) x 10(8) and (0.1-1) x 10(8) cfu/g for HAB and SRB were localized in the soil layer at the interface with the source of organic and inorganic nutrients. Regardless of this rapid growth in microbial population, the VFA consumption was small and measurable only after a lag of 140-180 days. It is considered that this lag of otherwise readily degradable organic compounds (such as VFAs) persisted due to a combination of the effects of a high initial concentration of these acids (2.4 g/l as dissolved organic carbon, DOC) applied to carbon starved soil microorganisms and the small pore size of the compacted clay. Once the significant amounts of gas were generated from fermentation, conditions developed for improved mass transport and exchange of the nutrients and bacteria and the outcome of the intrinsic degradation was more apparent. The breakdown of VFAs that followed after the lag was localized near the top of the soil and was characterized by a short half-life of 0.75-5 days for DOC (total VFAs as dissolved organic carbon).