Sludge ozonation and its effect on performance of submerged membrane bio-reactor

To investigate the effects of ozonation on minimizing the excess sludge and enhancing the nitrogen removal in an effluent, batch and continuous experiments in two MBRs with and without sludge ozonation （ namely combined and reference run） were carried out. Through ozonation at a dose of 0. 16 mg O3/mg MLVSS, 53.1% of the treated MLVSS was solubilized, and soluble SCOD/TN ratio of ozonized sludge （OS） was about 8. 6 due to the release of cellular nitrogen-contained materials and SCOD loss by ozone mineralization. In addition, the results of batch nitrification and denitrification tests with OS supernatant indicated that solubilized sludge could act as a reducing power for denitrification and a nitrogen source for nitrification. 40-day operation of-two MBR systems demonstrated that the recirculation of OS into a bioreaetor enabled the combined system have two advantages over the control one. The observed sludge yield （Yobs） was decreased from 0. 13 to 0. 06g MLSS/g COD, while the nitrogen removal was increased from 64. 6% to 72. 3%. And sludge ozonation elevated the inorganic fraction of MLSS, but did not impact sludge activities.

Negative Effects of Sludge Bulking in Membrane Bio-Reactor

Sludge bulking property of membrane bio-reactor was investigated in this study through contrast research. When the sludge bulking appeared, the removal efficiency of COD in membrane bio-reactor increased slightly through the function of filamentous bacteria. However, the negative effects of the higher net water-head differential pressures, the high block rate of membrane pore and the great quantity of filamentous bacteria at the external surface presented at the same time. Thus, plenty of methods should be performed to control sludge bulking once it happened in membrane bio-reactor.

Sludge Bulking Property of Membrane Bio-reactor in Albumen Wqastewater Treatment

Albumen wastewater was treated by Membrane Bio-reactor. Sludge bulking property of Membrane Bio-Reactor was investigated in this study through contrast research. When the sludge bulking appeared, the removal efficiency of COD in Membrane Bio-reactor increased slightly under the function of filamentous bacteria. However, the negative effects of the higher net water-head differential pressures,the higher block rate of membrane pore and the great quantity of filamentous bacteria at the externalsurface pres...

城市污水处理厂进水水质分析及MBR膜生物处理工艺研究

为提高城市污水的处理效率,在分析了某城市污水处理厂进水水质指标的基础之上,对目标城市污水开展了MBR膜生物处理工艺技术研究,并对其处理效果进行了分析。结果表明,目标城市污水处理厂进水水样中污染物的浓度较高,其中COD、NH_(3)-N、TN、TP、SS的平均浓度分别为202.8mg·L^(-1)、38.3mg·L^(-1)、50.8mg·L^(-1)、6.1mg·L^(-1)、261.6mg·L^(-1)。采用MBR膜生物处理工艺对目标城市污水进行处理后,12个月的出水水质中污染物的含量均大幅降低,其中COD、NH3-N、TN、TP、SS的浓度平均值分别为9.82mg·L^(-1)、0.94mg·L^(-1)、8.41mg·L^(-1)、0.35mg·L^(-1)、1.93mg·L^(-1),各项指标均能达到国家标准GB 18918-2002中的一级A标准要求。研究结果认为,MBR膜生物处理工艺对目标城市污水具有较好的处理效果,可为同类城市污水的高效处理提供一定的借鉴。

增强型中空纤维膜及MBR数值模拟的研究

中空纤维膜作为膜生物反应器(MBR),由于其高效性及灵活性被广泛应用于污水处理领域。文中介绍了纤维管增强型中空纤维膜,包括针织管增强膜、编织管增强膜及无纺管增强膜,综述了计算流体力学在MBR优化设计及膜污染清洗等方面的研究,并对增强型中空纤维膜及MBR数值模拟的应用前景进行展望。在未来的研究中,将计算流体力学与理论试验相结合可以提升研究效率,更好地解决水处理问题。

A pilot scale anoxic/oxic membrane bioreactor(A/O MBR) for woolen mill dyeing wastewater treatment

A pilot scale(10 m 3/d) anoxic/oxic membrane bioreactor(A/O MBR) was tested for dyeing wastewater treatment of woolen mill without wasting sludge in 125 days operation. Results showed that the effluent quality was excellent, i.e. effluent COD less than 25 mg/L, BOD 5 under 5 mg/L, turbidity lower than 0 65 NTU, and colour less than 30 DT, and met with the reuse water standard of China. The removal rates of COD, BOD 5, colour, and turbidity were 92 4%, 98 4%, 74% and 98 9%, respectively. Constant flux operation mode was carried out in this study, and backwash was effective for reducing membrane fouling and maintaining constant flux. Membrane fouling had heavy impact on energy consumption. More attention should be paid on pipe selection and design for the sidestream MBR system, too.

Simultaneous nitrogen and phosphor removal in an aerobic submerged membrane bioreactor

Simultaneous nitrification and denitrification （SND） effect and phosphor removal were investigated in a one-staged aerobic submerged membrane bioreactor on pilot-scale with mixed liquor suspended solids （MLSS） 19--20 g/L. The effects of DO concentration, sludge floc size distribution on SND were studied. Test results suggested that SND was successfully performed in the membrane bioreactor （MBR） and about 70% total nitrogen removal efficiency was achieved when DO concentration was set to 0.2-- 0.3 mg/L. The main mechanisms governing SND were the suitable sludge floc size and the low DO concentration which was caused by low oxygen transfer rate with such a high MLSS concentration in the MBR. In the meantime, phosphor removal was also studied with polymer ferric sulfate （PFS） addition and 14 mg/L dosage of PFS was proper for the MBR to remove phosphor. PFS addition also benefited the MBR operation owing to its reduction of extracellular polymer substances （EPS） of mixed liquor.

Improvement of antifouling characteristics in a bioreactor of polypropylene microporous membrane by the adsorption of Tween 20

Surface modification by physical adsorption of Tween 20 was accomplished on polypropylene microporous membranes （PPMMs）. Attenuated total reflection-Fourier transform infrared spectroscopy （ATR/FT-IR） and field emission scanning electron microscope （FE- SEM） were used to characterize the chemical and morphological changes on the membrane surfaces. Water contact angles and relative pure water fluxes were measured. The data showed that the hydrophilic performance for the modified membranes increased with the increase in the adsorption amount of Tween 20 onto the surface or into the pores of polypropylene microporous membranes. To test the antifouling property of the membranes by the adsorption of Tween 20 in a membrane bioreactor （MBR）, filtration for active sludge was performed using synthetic wastewater. With the help of the data of water fluxes and the FE-SEM photos of the modified PPMMs before or after operating in a MBR for about 12 d, the PPMMs with monolayer adsorption of Tween 20 showed higher remained flux and stronger antifouling ability than unmodified membrane and other modification membranes studied.

Study on membrane fouling of submerged membrane bioreactor in treating bathing wastewater

A pilot-scale submerged membrane bioreactor (MBR) was used to treat the bathing wastewater for more than 90 d. Several factors a?ecting membrane fouling were studied, including the variation in transmembrane pressure (TMP), changes in extracellular polymeric substance (EPS), and distribution of membrane resistance (R). The relationships between R and EPS concentration were found to be R = 0.00008(EPSS)2.915 in the mixed liquor (EPSS) and R = 0.2853(EPSm) – 0.824 on the membrane surface (EPSm). The constant ...

Inorganic nitrogen removal of toilet wastewater with an airlift external circulation membrane bioreactor

Removal of inorganic nitrogen （inorganic-N） from toilet wastewater, using a pilot-scale airlift external circulation membrane bioreactor （AEC-MBR） was studied. The results showed that the use of AEC-MBR with limited addition of alkaline reagents and volumetric loading rates of inorganic-N of 0.19-0.40 kg inorganic-N/（m^3·d） helped achieve the desired nitrification and denitrification. Furthermore, the effects of pH and dissolved oxygen （DO） on inorganic-N removal were examined. Under the condition of MLSS at 1.56-2.35 g/L, BODs/ammonia nitrogen （NH4＋-N） at 1.0, pH at 7.0-7.5, and DO at 1.0-2.0 mg/L, the removal efficiencies of NH4^＋-N and inorganic-N were 91.5% and 70.0%, respectively, in the AEC-MBR. The cost of addition of alkaline reagent was approximately 0.5-1.5 RMB yuan/m^3, and the energy consumption was approximately 0.72 kWh/m^3 at the flux of 8 L/（m^2-h）.

Removal of Di-2-Ethyl Hexyl Phthalates by Membrane Bioreactor

A lab scale membrane bioreactor system was built to investigate the removal of Di-2-Ethyl Hexyl Phthalates (DEHP) in wastewater under variation of three runs: two hydraulic retention time (HRT) 24 and 36 hours in addition to two biomass: concentrated and light sludge. Solid phase extraction (SPE) followed by high performance liquid chromatography coupled with tandem mass spectrometry (HPLC-MS/MS) was applied to quantitatively identify DEHP in wastewater samples. Membrane bioreactor was built and operated to investigate DEHP removal. Higher HRT removed DEHP more efficiently than lower HRT. The concentrated MLSS could achieve higher removal efficiency than the lighter MLSS at the same HRT value. The performance of MBR in removing DEHP, TOC and COD from wastewater with a maximum removal efficiency were 29%, 85%, and 98%, respectively. Mass balance of DEHP in the system indicated that a majority was removed by adsorption process rather than filtration or microbiological process.

Effect of components in activated sludge liquor on membranefouling in a submerged membrane bioreactor

By a membrane bioreactor with a settle tank in long-term operation and batch experiments, the effects of floes, soluble microorganism products （SMPs） and metal ions in activated sludge liquor on membrane fouling were investigated. The results showed that foulants absorbed each other and formed a fouling layer as a ＂second membrane＂ influencing the permeability of the membrane. The ＂gel layer＂ caused by SMPs and ＂cake layer＂ by floes showed great differences in morphology by analysis of scanning electron microscope and atomic force microscope. The ＂gel layer＂ was more compact and of poor permeability. When the membrane flux was 40 L/（m^2·h）, the rate of membrane fouling caused by supernatant （0.011 MPa/h） was greater than that by sludgc liquor （0.0063 MPa/h）. SMPs played very important roles on membrane fouling. In the bulking sludge, with SMPs increasing, the rate of membrane fouling （0.0132 MPa/h） was faster. While after flocculation of the SMPs, the rate of fouling decreased to 0.0034 M Pa/h. Floes could keep holes in their overlaps. They could alleviate membrane fouling by preventing the SMPs directly attaching on membrane surface.

MBR+臭氧催化氧化处理工业废水的设计优化及存在问题分析

针对苏南某工业废水处理厂现状出水难以达到《太湖地区城镇污水处理厂及重点工业行业主要水污染物排放限值》(DB 32/1072—2018)排放标准的问题,提出了膜生物反应器(MBR)+臭氧催化氧化的改造思路。原改良式序列间歇反应器(MSBR)工艺改造为AAO-MBR工艺,原絮凝沉淀池改造为臭氧催化氧化池,着重分析了臭氧催化氧化单元中催化剂污染及清洗措施等因素对COD_(Cr)去除率的影响。结果表明:MBR+臭氧催化氧化作为化工废水提标改造技术路线,占地少,运行效果稳定,出水水质可稳定达标,但臭氧催化氧化单元受催化剂污染等因素影响较大,需加强预处理及清洗措施;工程新增投资为1596元/m^(3),新增运行成本为0.73元/m^(3),具有较好的经济效益。

MBR膜生物反应器在城镇污水处理厂中的应用

近年来,我国城镇化进程的步伐越来越快,城镇人口的规模也越来越大,城市污水处理成为环境保护和可持续发展的重要议题。传统的污水处理工艺在处理效率和出水水质要求方面已经面临一定的挑战,MBR膜生物反应器是一种相对新型的污水处理技术及装备,它结合了微生物降解技术和膜分离技术,近年来在城镇污水处理领域引起了广泛的关注。本文以某城镇地区X污水处理厂为例,分析MBR膜生物反应器系统的布置以及实施应用,结果表明,X污水处理厂在应用了MBR膜生物反应器后的污水处理效果有显著的提升。

MBR膜污染、影响因素及其控制策略研究进展

膜生物反应器(MBR)在废水处理领域应用广泛,然而膜污染是制约其可持续发展的主要瓶颈。探讨了MBR的膜污染问题,介绍了MBR工艺的基本原理和类型,阐述了膜污染的分类。分析了膜表面特性、污泥混合液性质和系统操作条件等因素对膜污染的影响,总结了膜污染的控制措施。旨在为MBR工艺的进一步优化和发展提供理论指导。

医院污水处理MBR膜工艺的优化管理

以某三甲医院污水处理MBR膜工艺的优化管理为例,介绍了MBR膜系统的组成和运行参数、日常运行中的关注内容、优化管理措施,分析了运行效果,总结了MBR膜工艺应用发展方向。

箱体型正压式平板负离子抗菌陶瓷膜MBR在城市新鲜垃圾渗滤液处理应用实例

山东某垃圾焚烧厂中产生的新鲜垃圾渗滤液有机物和氨氮浓度高,同时含有多种重金属,属于难处理的废水。本工程采用气浮预处理+两级UASB+A/O+平板式MBR膜过滤+后续深度处理(纳滤+反渗透)工艺。厌氧处理阶段采用投加零价铁来提高处理效果。MBR工艺采用箱体型正压式优化结构,比传统的浸没式结构能提高膜通量和优化操作。MBR膜采用能抑菌杀菌的负离子抗菌平板陶瓷膜,具有膜通量大,缓解膜污染能力强的特点。工程运行表明,出水水质低于≤生活垃圾卫生填埋场污染控制标准≥(GB 16889-2008)表3中的标准要求,即COD≤60 mg/L,BOD_(5)≤20 mg/L,ρ(氨氮)≤8 mg/L,ρ(总氮)≤20 mg/L,ρ(SS)≤2.0 mg/L等。工程投资总成本500万左右。吨水成本将核算后为14.9元。

Start-up and contaminants removal characteristics of aerobic granules-membrane bioreactor at low temperature

In order to understand the effect of low temperature on the formation process of aerobic granules and contaminants removal characteristics,the aerobic granules-membrane bioreactor (AGS-MBR) has been started up and operated at low temperature using the carbon resource of sodium acetate. Aerobic granules cultivated in AGS-MBR possess smooth surface and compact structure in morphology as well as better settling property and higher biomass after 38 days. The average parameters of aerobic granules are: diameter 3. 1 mm,wet density 1. 041 g/mL,sludge volume index 42. 35 mL/g and settling velocity 20. 6 - 45. 2 cm/min. During the start-up of AGS-MBR,the respectively average contaminants removal efficiencies at low temperature are 91. 9% for chemical oxygen demand (COD) ,89. 2% for NH4 + -N and 86. 3% for PO43- -P,and the overgrowth of filamentous bacteria has been well controlled. In addition,the hollow fiber microfiltration (MF) membrane fouling is light and the regime membrane layer is capable of enhancing membrane filtration as well as the average growth of trans-membrane pressure (TMP) is 1. 07 kPa/d. Compared with the conventional cultivation of aerobic granules,the sludge granulation time significantly decreases from 73 days to 38 days by the application of microfiltration membrane at low temperature.

间歇性投加Fe(Ⅱ)控制陶瓷膜MBR膜污染的机理分析

以陶瓷膜膜生物反应器(MBR)为研究对象,考察了间歇性投加Fe(Ⅱ)对合成废水中营养物质的去除效果,并分析了膜污染的控制机理。当n_(Fe)∶n_(P)为2时,TP、TOC和TN的去除率最高,分别为99.2%、97.5%和87.2%,出水达到《城镇污水处理厂污染物排放标准》(GB 18918—2002)中一级A标准;当nFe∶nP为1和2时,出水Fe浓度分别为0.14μmol/L和0.16μmol/L(达到中水回用标准),膜过滤时间由12 d分别延长至92 d和41 d(跨膜压差30 kPa)。间歇性投加Fe(Ⅱ)可增大污泥粒径及减少污泥混合液中有机物含量,从而提高体系的过滤性能,有效降低膜污染阻力并缓解膜污染;n_(Fe)∶n_(P)为1时,含Fe不可逆污染层的阻力较小,膜污染控制效果最好。

Diatomite Precoated Nonwoven Membrane Bioreactor for Domestic Wastewater Reclamation

Nonwoven was selected as filtration materials in submerged membrane bioreactor( MBR) for domestic wastewater reclamation. For its hydrophobic membrane surface,diatomite was precoated on nonwoven to improve membrane hydrophilicity. In the precoating stage,diatomite dynamic membrane could be formed on10 μm polyethylene nonwoven surface efficiently and effluent turbidity could be below 5 nephelometric turbidity units( NTU).The MBR system was operated steadily under gravity flow and scanning electron microscope( SEM) analysis showed that nonwoven membrane was only partially fouled at the membrane flux of 5 L/( m2·h). Average removal efficiencies of chemical oxygen demand( COD) and NH +4-N were above 86 % and 50 %,respectively. The effluent turbidity and chromaticity were below 5 NTU and 25°,respectively. Those results could meet the requirements for wastewater reuse.