含盐量对好氧颗粒污泥稳定性及微生物组成的影响

研究了不同含盐量(以NaCl质量分数计)对好氧颗粒污泥稳定性及微生物组成的影响.扫描电镜观察发现,高含盐量(5.0%)与低含盐量(1.0%和2.5%)下好氧颗粒污泥微生物的组成有较大的差异.低含盐量下好氧颗粒污泥的微生物以细菌(杆菌和球菌)为主;高含盐量下易出现大量的丝状菌,并形成白色和黑色的丝状颗粒污泥,而且丝状颗粒污泥在短期内(1个月左右)仍具有较好的沉降性能和密实性.但这些丝状颗粒污泥在实验后期易变得大而疏松,最终导致反应器运行失败.因此,维持丝状颗粒污泥的密实成长并抑制其发散成长成为控制好氧颗粒污泥稳定运行的关键,尚需进一步研究.     

好氧颗粒污泥对膜生物反应器污泥性能的影响

采用膜生物反应器进行含酚废水的处理,探讨投加好氧颗粒污泥对反应器中污泥性能的影响。结果表明,在膜生物反应器中投加好氧颗粒污泥能有效改善污泥性能,提高处理效果。从采用絮状污泥到逐渐增加好氧颗粒污泥投加量为100%的过程中,反应器中污泥浓度明显提高,MLSS由5 582 mg/L增加到8 168 mg/L;沉降性能得到改善,SVI由135.85 mL/g下降到29.36 mL/g;疏水性增强,Zeta电位由-20.302 mV升高到-4.325 mV;对含酚废水中COD、NH3-N的降解能力明显提高,COD、NH3-N、NO3-N去除率分别由87.3%、83.2%、55.3%增加到99.2%、94.9%、66.3%。改善了膜污染现象,膜通量衰减率由63.3%降低到42.8%。用二元多项式三维回归分析,得到污染物去除率关于好氧颗粒污泥投加量和反应器运行时间的二元方程,对指导好氧颗粒污泥膜生物反应器的连续运行具有重要意义。     

颗粒污泥与絮状污泥处理垃圾渗滤液的耐盐性能比较

通过批次实验系统研究了好氧颗粒污泥和絮状污泥处理垃圾渗滤液时的耐盐性能。实验结果表明,进水含盐量小于10 000 mg/L时,实验所用好氧颗粒污泥和絮状污泥的有机物去除能力、沉降性能、污泥活性基本上不受进水含盐量变化的影响。当进水含盐量大于10 000 mg/L时,随着进水含盐量的增大,絮状污泥的污泥沉降指数(SVI)快速减小,污泥活性及去除有机物的能力下降;相比而言,好氧颗粒污泥沉降性能更为稳定,SVI基本维持在30 mL/g左右,污泥活性及去除有机物的能力缓慢下降。当进水含盐量重新降低时,好氧颗粒污泥沉降性能变化不大,污泥活性及去除有机物的能力恢复迅速;而絮状污泥沉降性能变差,污泥活性及去除有机物的能力仍受较大抑制。     

好氧颗粒污泥形成与运行稳定性的影响因素试验分析

用普通絮状污泥作为接种污泥,用SBR作为反应器,分析了高径比、污泥容积负荷以及营养比例(BOD5:N:P)等因素对好氧颗粒污泥形成的影响.试验结果表明,高径比对好氧颗粒污泥的形成有直接关系;污泥容积负荷越高、碳氮比正常、磷源缺乏越易诱导好氧颗粒污泥的骨架丝状菌的生长,可以促进好氧颗粒污泥的提前形成,但是越易引起粘性膨胀的出现.在高径比为38;6,污泥容积负荷为1.67 kg/(m3·d).BOD5:N:P为100:5:1,沉淀时同为2 h时,其好氧颗粒污泥形成时间为17个周期,成熟时间为23个周期,粒径为2～3 mm,平均污泥沉降比(SV)为29.0%,对模拟废水COD的平均去除率达94.3%.     

耐药菌E.coli K12:RK2负荷下群感效应对好氧颗粒污泥稳定性的影响

研究了在携带RK2质粒的供体菌E.coli K12:RK2负荷下群体感应对好氧颗粒污泥稳定性的影响,同步运行了2个反应器(R1与R2),分别向反应器中添加E.coli K12和携带RK2质粒的供体菌E.coli K12:RK2,考察了其对系统污染物去除效率、污泥形态、EPS以及AHL含量的影响,分析并验证群体感应在维持好氧颗粒污泥稳定中的作用。结果表明,R1和R2中氨氮降解及污泥形态变化趋势一致,系统氨氮降解率下降,反应器中大颗粒污泥解体、絮状污泥增多。投菌作用下,R1和R2中胞外聚合物(EPS)含量显著降低(P<0.05),分别由(369.28±67.70) mg·g^-1和(372.22±86.53) mg·g^-1(以MLSS计)降至(242.47±20.25) mg·g^-1和(175.66±37.99) mg·g^-1,且组间存在显著差异(P<0.05)。通过荧光定量PCR及荧光显微镜镜检发现RK2质粒在系统中发生接合转移。C4-HSL为系统的主要响应AHLs,在投菌后出现,R1和R2...     

好氧颗粒污泥法处理石化废水

实验以吉林石化污水处理厂初沉池出水为原水在SBR中培养好氧颗粒污泥。实验初期,依次以比例为40%、60%的含石化废水的培养液进行培养,于第15天SBR中出现颗粒污泥,此后直接采用石化废水培养,同时逐步缩短沉降时间,第27天起反应器出水稳定,COD去除率达到89%,TN、NH3-N和TP去除率分别达到56%、86%和90%。采用此方法培养的颗粒污泥平均粒径约为1.3 mm,外表棕黄色,颗粒表面粗糙,在扫描电子显微镜(SEM)下观察到好氧颗粒污泥主要由杆状菌和丝状菌组成,颗粒内部存在若干孔隙。研究结果表明,在SBR中通过逐步增加石化废水进水比例,缩短沉降时间可以快速培养出好氧颗粒污泥,好氧颗粒污泥处理石化废水效果良好。     

好氧颗粒污泥的培养及其对污染物去除特性研究

采用序批式活性污泥反应器(SBR)进行好氧颗粒污泥(AGS)培养,比较仅接种普通絮状污泥培养(R1)与接种普通絮状污泥及部分厌氧颗粒污泥培养(R2)下污泥颗粒化进程、污泥特性及污染物去除特性。结果表明,通过逐渐缩短SBR沉淀时间、提高有机负荷,R1、R2分别在17、23d时出现乳白色颗粒,颗粒粒径较小(0.1～0.5mm),颗粒污泥成熟时由白色转变为黄色,污泥容积指数(SVI)均保持在40mL/g左右;培养60d时,R1、R2内污泥基本实现颗粒化,颗粒化程度分别为90.0%、84.4%;R1、R2中胞外聚合物(EPS)质量浓度均在56d时分别为84.75、64.05mg/g(以单位质量挥发性悬浮固体(VSS)中的质量计,下同),其中R1、R2中多糖(PS)在EPS中占主要比重;R1、R2中培养的AGS均具有密实的结构和良好的沉降性能,对污染物具有良好的去除效果,培养后期R1、R2对COD平均去除率分别为96%、94%,对TN平均去除率分别为60%、56%,对TP平均去除率分别为65%、61%。R2中接种的部分厌氧颗粒污泥可能对EPS的分泌起到一定抑制作用,从而影响污泥的颗粒化进程。     

好氧颗粒污泥处理高浓度氨氮废水的研究

在不同接种源污泥颗粒化过程中污泥理化性状对比研究的基础上,采用成熟好氧颗粒污泥处理高浓度氨氮废水,对其脱氮行为以及不同C/N条件下好氧颗粒污泥微生物的比耗氧速率、好氧颗粒污泥对氨氮的比降解速率随时间的变化等进行了研究.实验结果表明,在进水氨氮质量浓度较高(480 mg/L)、温度30℃左右的条件下,稳定运行15 d,氨氮的去除率维持在85%左右;进水氨氮的浓度越高,随着微生物对环境的逐渐适应,硝化菌的活性也逐步增加;随着进水氨氮浓度的提高,好氧颗粒污泥对氨氮的比降解速率也逐渐上升.     

负荷及盐度对好氧颗粒污泥EPS的影响

研究了序批式反应器(SBR)内好氧颗粒污泥在不同有机负荷(1.6 kg COD/（m³·d）和8 kg COD/（m³·d)）和不同含盐(2.5%和5.0%)条件下胞外聚合物(EPS)的变化情况,并对EPS、比耗氧速率(SOUR)和孔隙率之间的关系作了进一步探讨。结果表明：在SBR反应器中,负荷较含盐量对好氧颗粒污泥EPS变化的影响要显著,且EPS糖成分和SOUR之间、EPS蛋白成分和孔隙率之间均呈负相关。另外,高负荷条件下的系统稳定性要优于低负荷。     

反硝化除磷颗粒污泥培养方式的对比实验研究

采用两完全相同的气升式间歇反应器（SBAR）进行反硝化除磷颗粒污泥培养方式的对比实验研究。R1始终以厌氧/好氧/缺氧（A/O/A）模式运行,在颗粒化的同时富集反硝化除磷菌（DPAOs）;R2以厌氧/好氧（A/O）模式培养颗粒,待颗粒形成后加入缺氧段,形成A/O/A模式,强化富集DPAOs。结果表明,R2中颗粒化时间较短,但所形成颗粒的沉降速率和比重分别为30.4 m/h和1.022 g/cm³,低于R1培养颗粒的35.9 m/h和1.061 g/cm³;R1中颗粒对于COD、NH⁺₄-N、TN和TP的平均去除率分别是86%、98%、82%和91%,高于R2中的86%、99%、74%和66%;反应器运行至183 d时,DPAOs所占比例分别为44.7%和20.9%。     

Characteristics of granular sludge developed in an upflow anaerobic sludge fixed-film bioreactor treating palm oil mill effluent.

In the present study, characteristics of the granular sludge (including physical characteristics under stable conditions and process shocks arising from suspended solid overload, soluble organic overload, and high temperature; biological activity; and sludge kinetic evaluation in a batch experiment) developed in an upflow anaerobic sludge blanket fixed-film reactor for palm oil mill effluent (POME) treatment was investigated. The main aim of this work was to provide suitable understanding of POME anaerobic digestion using such a granular sludge reactor, particularly with respect to granule structure at various operating conditions. The morphological changes in granular sludge resulting from various operational conditions was studied using scanning electron microscopy and transmission electron microscopy images. It was shown that the developed granules consisted of densely packed rod- (Methanosaeta-like microorganism; predominant) and cocci- (Methanosarsina) shaped microorganisms. Methanosaeta aggregates functioned as nucleation centers that initiated granule development of POME-degrading granules. Under the suspended solid overload condition, most of the granules were covered with a thin layer of fiberlike suspended solids, so that the granule color changed to brown and the sludge volume index also increased to 24.5 from 12 to 15 mL/g, which caused a large amount of sludge washout. Some of the granules were disintegrated because of an acidified environment, which originated from acidogenesis of high influent organic load (29 g chemical oxygen demand [COD]/L d). At 60 degrees C, the rate of biomass washout increased, as a result of disintegration of the outer layer of the granules. In the biological activity test, approximately 95% COD removal was achieved within 72 hours, with an initial COD removal rate of 3.5 g COD/L d. During POME digestion, 275 mg calcium carbonate/L bicarbonate alkalinity was produced per 1000 mg COD(removed)/ L. A consecutive reaction kinetic model was used to simulate the data obtained from the sludge activity in the batch experiment. The mathematical model gave a good fit with the experimental results (R2 > 0.93). The slowest step was modeled to be the acidification step, with a rate constant between 0.015 and 0.083 hours(-1), while the rate constant for the methanogenic step was obtained to be between 0.218 and 0.361 hours(-1).     

Enhanced sludge granulation in upflow anaerobic sludge blanket (UASB) reactors by aluminum chloride.

Two upflow anaerobic sludge blanket (UASB) reactors were concurrently operated for 146 days to examine the effects of aluminum chloride (AlCl3) on the sludge granulation process during start-up. Sludge granulation (defined as that over 10% of granules were larger than 2.0 mm) was achieved in the control reactor (R1) in approximate three months. Introduction of Al3+ at a concentration of 300 mg/l reduced the sludge granulation time by approximate one month. Throughout the experiment the AlCl3-added reactor (R2) had a higher biomass concentration, e.g., 13.8 g-MLVSS/l versus 12.8 g-MLVSS/l on Day 146. Granules became visible earlier in R2 compared with R1 (35 days versus 65 days). The average size of granules from R2 was larger than that from R1. The results demonstrated that AlCl3 enhanced the sludge granulation process in the UASB reactors.     

Adaptation to osmotic stress provides protection against ammonium nitrate in Pelophylax perezi embryos

The negative effects of pollution on amphibians are especially high when animals are additionally stressed by other environmental factors such as water salinity. However, the stress provoked by salinity may vary among populations because of adaptation processes. We tested the combined effect of a common fertilizer, ammonium nitrate (0-90.3 mg N-NO₃NH₄/L), and water salinity (0-2‰) on embryos of two Pelophylax perezi populations from ponds with different salinity concentrations. Embryos exposed to the fertilizer were up to 17% smaller than controls. Survival rates of embryos exposed to a single stressor were always below 10%. The exposure to both stressors concurrently increased mortality rate (>95%) of embryos from freshwater. Since the fertilizer was lethal only when individuals were stressed by the salinity, it did not cause lethal effects on embryos naturally adapted to saline environments. Our results underscore the importance of testing multiple stressors when analyzing amphibian sensitivity to environmental pollution.     

Phytoremediation of petroleum hydrocarbons in tropical coastal soils I. selection of promising woody plants

GOAL, SCOPE AND BACKGROUND: This glasshouse study is aimed at evaluating tropical plants for phytoremediation of petroleum hydrocarbon-contaminated saline sandy subsurface soils. Tropical plants were selected for their ability to tolerate high salinity and remove No. 2 diesel fuel in coastal topsoil prior to further investigation of the phytoremediation feasibility in deep contaminated soils. The residual petroleum-hydrocarbon contaminant at the John Rogers Tank Farm site, a former petroleum storage facility, at Hickam Air Force Base, Honolulu, Hawaii, is located in a coastal area. It lies below a layer of silt in the subsurface, in loamy sand characterized by moderate salinity and high pH. Little is known regarding the ability of tropical plants to remediate petroleum hydrocarbon-contaminated subsurface soil in Hawaiian and other Pacific Island ecosystems although suitable plants have been identified and utilized for bioremediation in surface soil or marine sediments. METHODS: The experiments were conducted in long narrow pots under glasshouse conditions in two phases. A preliminary experiment was done with nine tropical plants: kiawe (Prosopis pallida), milo (Thespesia populnea), common ironwood (Casuarina equisetifolia), kou (Cordia subcordata), tropical coral tree (Erythrina variegata), false sandalwood (Myoporum sandwicense), beach naupaka (Scaevola sericea), oleander (Nerium oleander), and buffelgrass (Cenchrus ciliaris). These plants were screened for resistance to high salinity treatment (2% NaCl) and two diesel fuel levels (5 and 10 g No. 2 diesel fuel/kg soil) in separate treatments. Plants that showed good tolerance of both factors were further evaluated in a second phase for their efficacy in the phytoremediation of diesel-fuel petroleum hydrocarbons under moderate salinity treatment (1% NaCl). RESULTS: Tropical coral tree and buffelgrass were susceptible to either 2% NaCl or diesel fuel at 10 g/kg soil, but tolerant of diesel fuel at 5 g/kg soil. Kiawe, milo, kou, common ironwood, N. oleander, beach naupaka and false sandalwood were tolerant of high salinity (2% NaCl) or high diesel fuel level (10 g/kg soil). These seven plants were also tolerant of the combined adverse effects of a moderate salinity (1% NaCl) and 10 g diesel fuel/kg soil. Three trees, kiawe, milo and kou significantly accelerated the degradation of petroleum hydrocarbons in the soil spiked with 10 g diesel fuel/kg soil under a moderate salinity treatment (1% NaCl). CONCLUSION: Thus the tropical woody plants, kiawe, milo and kou showed potential for use in phytoremediation of petroleum hydrocarbons in coastal tropical soils. RECOMMENDATIONS AND OUTLOOK: Two fast growing trees, milo and kou, appeared promising for further phytoremediation evaluation in experiments that simulate the soil profile at the field site.     

生物活性炭填料反应器处理含盐水体的硝化性能

以颗粒活性炭为填料,采用盐度梯度两步驯化法构建含盐水体生物滤器硝化功能,研究了生物滤器稳定后水力停留时间(hydraulic retention time,HRT)、进水氨氮负荷和CODMn/N等对反应器硝化性能的影响。结果表明,25～27℃,盐度30的含盐水体生物滤器硝化功能构建需73 d,其中淡水生物滤器硝化功能构建需28 d,淡水驯化为盐度15的生物滤器需19 d,盐度15驯化为盐度30的生物滤器需26 d;实验条件下生物活性炭填料反应器中生物量达到146～742.1 nmolP/g-BAC;调节进水氨氮浓度2 mg/L左右时,最佳HRT为1 h,氨氮去除率达到84.98%,相应的氨氧化菌和硝酸菌氧吸收速率(oxygen uptake rate,OUR)分别为2.091和1.948 mg O2/(g-BAC.h);HRT为1 h时,随着进水氨氮负荷的加大,氨氮去除率逐渐降低,当进水氨氮负荷由0.12增加到0.48 g-N/(kg-BAC.d)时,氨氮去除率由84.98%降低到41.68%,同时氨氧化菌OUR由2.091降低到0.625 mg O2/(g-BAC.h);随着CODMn/N的升高,氨氮去除率下降,CODMn/N从1～8时,氨氮去除率由84.98%降低到53.64%,CODMn去除率却逐渐增加,由40.86%增加到93.59%,异养菌OUR随着CODMn/N升高呈上升趋势,最大达到0.914 mg O2/(g-BAC.h)。     

高声能密度超声波破碎污泥细胞效能的研究

采用超声波在较高声能密度下处理SBR的剩余污泥,主要考察了含固率、声能密度和作用时间对污泥细胞破碎效果的影响。结果表明,在声能密度0.5～3 W/mL内,含固率1%～1.5%的剩余污泥经超声波作用后,上清液SCOD随作用时间呈线性升高;在声能密度1～3 W/mL内,含固率0.25%～0.5%的剩余污泥经超声波作用后,上清液SCOD随作用时间呈平缓缓慢升高。高声能密度超声波更适合对较高含固率污泥的细胞破碎;此情况下,上清液SCOD增幅、NH4＋-N、TN及TP升幅均与声能密度正相关。经超声波作用6 min后,污泥形态结构已破坏。     

高盐条件下硝基苯降解菌的分离及降解特性

在高盐条件下,从某制药厂曝气池的活性污泥中分离、筛选得到6株硝基苯高效降解菌,其中菌株N18在高盐条件下对硝基苯降解效率最高.经形态特征和生理生化特征分析,初步鉴定N18属于棒状杆菌属(Corynebacterium sp.).硝基苯降解试验表明,菌株最佳培养条件为30℃、培养基pH 7、摇床转速150 r/min.最佳培养条件下,当硝基苯初始质量浓度低于150 mg/L时,菌株培养72 h后硝基苯降解率达75％以上.当盐度为1％～3％时,盐度对硝基苯降解率的影响不明显,当盐度为10％时菌株生长微弱,因此N18属于中度耐盐细菌.     

Effect of recycle-to-influent ratio on activities of nitrifiers and denitrifiers in a combined UASB-activated sludge reactor system

A laboratory study using a combined upflow anaerobic sludge bed (UASB)-activated sludge (AS) reactor system was undertaken to explore the effect of recycle-to-influent ratio (R(e)=1, 2, and 3) on the activities of nitrifiers and denitrifiers. Suspended-solids pre-settled piggery wastewater was used as the substrate-feed wastewater. At the R(e) of 1-3, the combined reactor system achieved efficient removal of COD (96-97%), TKN (100%) and total nitrogen TN (54-77%). Methanogenesis occurred with nearly-complete denitrification in the UASB reactor, whereas complete nitrification took place in the AS reactor. A higher R(e) (i.e., accompanied with a shorter solids retention time) resulted in a larger amount of high-activity denitrifiers and thereby achieved a higher TN removal efficiency. Compact granules and a high biomass concentration in the UASB reactor were observed. At the R(e) of 1-3, the maximum specific reaction rate of nitrifiers (0.45-0.49 NH(4)(+)-NmgVSS(-1)d(-1)) and the specific nitrification rates of mixed culture (0.18-0.22mg NH(4)(+)-NmgVSS(-1)d(-1)) in the AS reactor varied slightly; whereas the maximum specific reaction rate of denitrifiers (0.18-0.27mg NO(x)(-)-NmgVSS(-1)d(-1)) and the specific denitrification and COD removal rates of mixed culture (0.025-0.050mg NO(x)(-)-NmgVSS(-1)d(-1); 0.24-0.31mgCODmgVSS(-1)d(-1)) in the UASB reactor increased with increasing R(e). The primary finding of the study is that the combined UASB-AS reactor system should be operated at a higher R(e) to maintain high-activity denitrifiers to remove organic materials and nitrogen from piggery wastewater.     

西安采暖期PM2.5及其水溶性无机离子的时段分布特征

为了探讨西安市采暖期大气颗粒物PM2.5及其水溶性无机成分的污染水平,于2010年1月4日—2月1日按一天8个时段(每个时段3 h)连续采集PM2.5样品四周,每周更换一次滤膜。结果显示,西安市采暖期PM2.5的质量浓度时段差异较大,呈现明显的双峰分布特征:21:00—24:00时段(147.516μg/m3)和09:00—12:00时段(141.678μg/m3)。4种被测水溶性无机组分总浓度为39.801μg/m3,占PM2.5总浓度的30.5%。SO24-和NO3-是最主要组分,占到4种无机组分的86.2%。各离子间相关分析显示,Cl-只与NO3-有较强的相关性,表明机动车尾气对Cl-有较大的贡献。SO24-和NO3-时段分布规律较为相似,与PM2.5浓度的时段分布特征相反:在PM2.5污染最轻的15:00—18:00时段,SO24-和NO3-的相对含量达到一天中的最高浓度时段,而在PM2.5双峰时段,它们的含量有所降低。