Highly efficient CO_(2) capture using 2-methylimidazole aqueous solution on laboratory and pilot-scale

To date,the primary industrial carbon capture approach is still absorption using aqueous solutions of alkanolamines.Here,to pursue a substitute for the amine-based approach to improve the CO_(2) capture efficiency and decrease the energy cost further,we report a new carbon capture approach using a 2-methylimidazole(mIm)aqueous solution.The properties and sorption behaviors of this approach have been experimentally investigated.The results show that the mIm solution has higher CO_(2) absorption capacity under relatively higher equilibrium pressure(>130 kPa)and lower desorption heat than the methyldiethanolamine solution.91.6%sorption capacity of mIm solution can be recovered at 353.15 K and 80 kPa.The selectivity for CO_(2)/N_(2) and CO_(2)/CH_(4) can reach an exceptional 7609 and 4324,respectively.Furthermore,the pilot-scale tests were also performed,and the results demonstrate that more than 98%of CO_(2) in the feed gas could be removed and cyclic absorption capacity can reach 1 mol·L^(-1).This work indicates that mIm is an excellent alternative to alkanolamines for carbon capture in the industry.

一体式A^(2)O-MBR系统处理高速公路服务区污水的研究

为解决高速公路服务区污水中污染物浓度高、处理设施普遍存在效能低下等问题,采用一体式A^(2)O-MBR反应器处理该目标污水。在反应器启动成功的基础上,研究了不同溶解氧(DO)、硝化液回流比和C/N下A^(2)O-MBR工艺对污染物的去除性能。结果表明,在控制DO为4 mg/L,硝化液回流比为300%,C/N为6时,A^(2)O-MBR获得了最佳污染物去除效果,A^(2)O-MBR工艺的COD、BOD_5和TP去除率分别为90.57%、93.75%和93.00%。反应器稳定运行时,出水NH_(4)^(+)-N和SS分别为4.2 mg/L和4.5 mg/L,出水指标均达到了《城市污水再生利用城市杂用水水质》(GB/T 18920—2020)中冲厕、车辆冲洗的要求。一体式A^(2)O-MBR在一定程度上可以降低膜组件的污染程度,从而降低系统的维护运行成本,可为高速公路服务区污水处理实际工程改造提供参考。

Fenton耦合A/O-MBR工艺体系处理印染废水

近年来,印染行业水处理标准不断提高,印染废水中难降解有机物浓度高、传统缺氧/好氧工艺(A/O工艺)达标难等问题亟待解决。本研究开发了Fenton、A/O工艺与MBR(膜生物反应器)的耦合工艺处理印染废水,开展Fenton+A/O-MBR工艺和A/O-MBR+Fenton工艺对比研究,对反应器中微生物菌群结构进行了初步分析。结果表明,该组合工艺对印染废水中常规污染物均具有良好的去除能力,在水力停留时间(HRT)为72 h条件下,两套工艺对COD的总去除率分别为93%与81%,NH3-N的去除率分别为97.9%与92.2%,表现出高效的除碳脱氮特性。反应器内的微生物16S rRNA多样性结果表明,活性污泥在A/O-MBR系统内仍然可以保持较好的生物种类多样性,前置Fenton预处理对A/O-MBR系统内的异养微生物与氮循环微生物菌群结构产生一定影响,从而造成污染物去除效果的差异。然而,Proteobacteria、Chloroflexi、Bacteroidetes和Planctomycetes是两套A/O-MBR反应器中缺氧和好氧池污泥的优势菌门。

核化工乏燃料后处理厂A2O-MBR污水处理站的设计应用

A2O-MBR是处理生活污水的一种经济有效工艺,一体化污水处理设备适用于中小水量的分散式污水处理。某核化工乏燃料后处理站污水站采用A2O-MBR工艺的一体化污水处理设备进行设计,出水达到《城镇污水处理厂污染物排放标准》(GB 18918—2002)一级A排放标准,并满足《城市污水再生利用城市杂用水水质》(GB/T 18920—2020)中道路清扫和城市绿化指标的要求,吨水运行电费1.10元,药剂费不含碳源时0.91元,含碳源时1.43元。同时,污水处理站采用三维正向设计,保证设计正确率,缩短设计和施工期。

温度对A/O-MBR联合人工湿地系统处理污水的影响

以温度为主要特征参数,采用实验室模拟方法,研究A/O-MBR联合人工湿地系统处理农村污水的效果,一个处理周期内,温度分别设置9℃、13℃、18℃、23℃、30℃,探究系统对COD、总氮、总磷的处理效果。结果显示:温度会影响A/O-MBR联合人工湿地系统处理农村生活污水的效果,A/O-MBR系统随温度升高对COD的处理效率提升,对TP和TN的处理效率下降;A/O-MBR联合人工湿地系统对COD、TN、TP的处理效率均随温度升高而略有升高。

Petrochemical wastewater treatment with a pilot-scale bioaugmented biological treatment system

In solving the deterioration of biological treatment system treating petrochemical wastewater under low temperatures, bioaugmentation technology was adopted by delivering engineering bacteria into a pilot-scale two-stage anoxic-oxic (A/O) process based on previous lab-scale study. Experimental results showed that when the concentrations of COD and NH4+-N of the influent were 370~910 mg/L and 10~70 mg/L, the corresponding average concentrations of those of effluent were about 80 mg/L and 8 mg/L respectively, which was better than the Level I criteria of the Integrated Wastewater Discharge Standard (GB8978-1996). According to GC-MS analysis of the effluents from both the wastewater treatment plant (WWTP) and the pilot system, there were 68 kinds of persistent organic pollutants in the WWTP effluent, while there were only 32 in that of the pilot system. In addition, the amount of the organics in the effluent of the pilot system reduced by almost 50% compared to that of the WWTP. As a whole, after bioaugmentation, the organic removal efficiency of the wastewater treatment system obviously in- creased.

Combination of a crude oil-degrading bacterial consortium under the guidance of strain tolerance and a pilot-scale degradation test

Under the guidance of strain tolerance, a new combination method for crude oil-degrading bacterial consortium was studied. Firstly, more than 50 efficient crude oil-degrading and biosurfactant producing bacteria were isolated from petroleum-contaminated soil and water in Tianjin Binhai New Area Oil field, China. Twenty-four of them were selected for further study. These strains were identified as belonging Pseudornonas aeruginosa, Bacillus subtilis, Brevibacillus brevis, Achrornobacter sp., Acinetobacter venetianus, Lysinibacillus rnacroides, Klebsiella oxytoca, Stenotrophornonas rhizophila, Rhodococcus sp. and Bacillus thuringiensis. A shake-flask degradation test revealed that 12 of these strains could degrade over 50% of 1% crude oil concentration in 7 d. Of these, 8 strains were able to produce biosurfactants. Furthermore, environmental tolerance experiments indicated that the majority of the strains had the ability to adapt to extreme environments including high temperatures, alkaline en- vironments and high salinity environments. A mixed bacterial agent comprising the strains WB2, W2, W3 and HA was developed based on the environmental tolerance tests and subjected to the pilot-scale degradation test indicating that this bacterial agent could degrade 85.2% of 0.8% crude oil concentration in 60 d. Our results suggest that the application of this mixed agent could remediate crude oil polluted soils in saline and alkaline environments.

Effect of C/N Ratio on DHA Production by Schizochytrium sp.JN-3 and Its Pilot-scale Fermentation

[ Objective] This study aimed to explore the effect of C/N ratio on DHA production by Schizochytrium sp. , and the results were verified by pilot-scale fermentation. [ Method] Effect of C/N ratio on DHA production by Schizochytrium sp. JN-3 was explored. The industrial fermentation potential of Schizochytrium sp. JN-3 was investigated by pilot-scale fermentation in a 200 L fermentation tank. [ Result] Results of fermentation in a 7 L fermentation tank showed that the maximum biomass and total lipid content were 34.3 and 20.1 g/L, respectively, when C/N ratio was 10 ; the maximum DHA yield was 46.9% when C/N ratio was 20. When pilot-scale fermentation was conducted in a 200 L fermentation tank, the biomass was 30. 2 g/L, total lipid content was 18.4 g/L, accounting for 63.2% of the dry weight of cells; DHA content was 7.4 g/L, accounting for 40. 2% of the total lipid content. [ Condasion ] Schizochytrlum sp. JN-3 has good industrial fermentation notential.

UASB-A/O-MBR组合工艺处理餐厨垃圾废水研究

随着垃圾分类的政策的实行,餐厨垃圾成为我国亟待解决的一大生态环境难题,随着餐厨垃圾的产生,必然也会产生大量的餐厨垃圾废水。餐厨垃圾废水具有水质复杂、水质波动性大、有机污染物及营养物质含量高,且不同地区餐厨废水水质含量区别较大等特点。为能有效处理餐厨垃圾废水,本文采用了UASB-A/O-MBR的组合工艺,探究了UASB工艺对餐厨垃圾废水中COD的去除效果及工艺参数,进而考察UASB-A/O-MBR整体工艺对COD、NH_(3)-N、TN的去除效果及工艺参数。研究表明,当UASB反应器中pH控制在6.5~7.3之间、上流速度控制在0.58 m/h~0.65 m/h之间、温度控制在35℃±3℃、HRT为24h, A/O-MBR工艺中HRT为48h,回流比为300%时,此套系统对COD、NH_(3)-N、TN的去除效果最低可达到95%、97%、75%。可以为以后在处理餐厨垃圾废水的实际工程应用中提供一种优良技术。

电解/AO-MBR组合工艺对渗滤液膜浓缩液的处理性能

以垃圾渗滤液纳滤与反渗透浓缩液为处理对象,采用电解工艺预处理纳滤浓缩液,考察在不同电解工况下的COD去除效果,确定最佳电解预处理参数;采用A/O-MBR工艺,以30 g/L氯化钠驯化的污泥为种污泥,电解处理的纳滤与反渗透浓缩液混合液为处理对象,考察不同电解处理纳滤与反渗透浓缩液混合比进水运行期间的COD、氨氮与总氮去除效果。结果表明,纳滤浓缩液的最佳电解处理条件为1 cm极板间距、10 mA/cm^(2)电流密度、2 h反应时间,COD和盐度去除率分别为65%~75%和24%。A/O-MBR运行实验中发现,进水中电解处理纳滤与反渗透浓缩液的混合比不超过1∶1时,氨氮与总氮去除率分别在92%及86%以上,混合比在2∶1以上时,氨氮与总氮去除率分别降至50%及60%左右。进水电解处理纳滤与反渗透浓缩液的混合比对COD去除率的影响不明显。

A/O-MBR系统运行测试及相关动力学分析

以生活污水为处理对象，考察A／O－MBR系统稳态运行状况及抗冲击负荷能力，探讨系统运行过程中基质降解动力学方程。研究结果表明，系统对实际生活污水波动（COD：70～200mg／L；NH_4^＋-N：18～45mg／L）的适应性较强，能抗击1．53kgCOD／（m^3·d）的容积负荷，连续运行出水的COD均在40mg／L以下，NH_4^＋-N均在1．5mg／L以下，达到GB8978－1996的一级A标；采用Mond模型对COD降解动力学过程进行解析，获得动力学参数Vmax=0．38d^-1及Ks=100．98；实验验证该动力学方程能较好地预测A/O－MBR出水水质，可以为A/O－MBR系统处理生活污水工艺设计提供参考。

A/A/O-MBR组合工艺强化去除氨氮及其硝化速率

将PVDF帘式中空纤维膜组件与A/A/O工艺结合,构建"A/A/O-MBR"强化生物脱氮的中试系统,用于处理太湖流域城镇污水。针对组合工艺的脱氮效果,以组合工艺MBR池内活性污泥的硝化速率为研究对象,分析了溶解氧(DO)浓度、进水氨氮浓度和温度对硝化速率的影响。结果表明,组合工艺在夏季和冬季的氨氮平均去除率分别稳定为96.56%和96.68%;低温(T<15℃)条件下,进水氨氮浓度对硝化速率影响不大;温度升高硝化速率加快,温度为30.5℃时组合工艺的硝化速率为11.8℃时的2.6倍;与常规工艺相比,组合工艺的硝化速率是氧化沟工艺的2.3倍。组合工艺两级硝化空间形成的较长水力停留时间和MBR内膜的截留作用补偿了低温对硝化速率的影响。

A^2/O-MBR研究与应用进展

我国污水处理厂面临着升级改造强化脱氮除磷的需求,A2/O-MBR由于其脱氮除磷效率高和出水水质好的特性在我国得到了广泛的关注和规模化应用.介绍了A2/O-MBR工艺研究及应用进展,对我国主要大型A2/O-MBR污水处理厂的运行参数、处理效果、影响因素及MBR单元运行稳定性进行了讨论分析.结果表明A2/O-MBR虽然在我国已得到工程化应用,但仍存在污泥脱水性能恶化、膜污染严重、水处理成本和能耗高等问题;A2/O-MBR适用于用地资源紧张的大城市污水处理厂的改造和建设,但需要十分重视其膜污染控制、降低处理能耗和成本问题的研究.

A^2/O-MBR工艺城镇污水处理厂能耗特征与运行优化

针对当前A^2/O-MBR工艺高排放标准城镇污水处理厂普遍存在运行能耗过高和精细化管理水平不高的实际问题,基于稳定达标和节能降耗,以滇池流域某典型A^2/O-MBR工艺污水处理厂为例,依托能耗监测平台,从单位水量电耗分布、能耗结构和单元能耗等方面对其能耗特征进行了分析,并结合生产运行实际对其优化运行措施进行了研究,结果表明:年平均单位水量电耗为0.580kW·h/m^3,日单位水量电耗主要集中于0.550~0.650kW·h/m^3,其累积频率为83.66%,并且膜单元能耗占比高达43.0%;优化膜擦洗曝气强度降低膜单元能耗的优化运行措施的节能效果显著,通过采取将膜池DO控制在4mg/L左右的技术措施,膜单元单耗年均降低0.091kW·h/m^3,年均下降39.7%;调整好氧池容积强化工艺脱氮的优化运行措施的强化脱氮效果良好,通过采取增加后置缺氧池容积并控制好氧池DO的技术措施,工艺系统平均脱氮效率由66%提高到79%。

基于污泥减排的A^2/O-MBR工艺除磷效果研究

以沉砂池出水为研究对象,采用A2/O-MBR组合工艺,对混合型城市污水进行中试研究,考察了该工艺在高效除磷和污泥减排方面的优势,并分析了除磷影响因素。结果表明,系统正常运行情况下,TP的平均去除率为93.83%,最高去除率可达98.21%,出水TP优于城镇污水处理厂污染物排放标准(GB 18918-2002)一级A标准;系统的COD平均污泥产率为0.22 kg/kg,低于常规除磷工艺的COD污泥产率即0.60 kg/kg,实现了剩余污泥减排。厌氧区硝酸盐质量浓度升高会导致TP去除效果下降,当回流比为2时TP的去除效果稳定而且平均去除率最高,而进水COD(<1 000 mg/L)的增减与TP去除率的增减基本趋于一致,试验期间温度、pH等对除磷效果无明显影响。

厨余发酵液作为中试A/O-MBR外增碳源的脱氮特性

利用厨余发酵液作为A/O-MBR的外增碳源,考察在不同发酵液投加量和水力停留时间(HRT)条件下的脱氮性能以及膜污染特点.结果表明,发酵液的反硝化速率和COD利用率与乙酸钠接近,比葡萄糖高.通过A/O-MBR的运行发现,厨余发酵液作为碳源能够增强微生物活性,强化反硝化过程,从而提高脱氮效率.TN的去除效率随着发酵液投加量的增加而增大.发酵液投加前后,反应器内的EPS并没有积累,膜污染速率变化较小.化学清洗可以有效地去除膜污染物质,恢复膜通量.同时,延长HRT有助于提高脱氮效率和缓解膜污染.

A^2O-MBR工艺脱氮除磷的性能及稳定性

使用A2O-MBR工艺处理人工合成的污水,并考察了该工艺对污水中COD、NH4+-N、总氮和PO43--P的去除效果,同时也研究了污泥的形态及变化。结果显示,该系统对COD、NH4+-N、总氮和PO43--P的去除率分别达到95%、98%、68%和70%左右,出水中NO2--N和NO3--N含量平均分别为0.4、4 mg/L。显微镜的观察结果显示,活性污泥部分已经呈现颗粒化状态,且污泥中含有大量细菌和原生动物等微生物。研究揭示出使用A2O-MBR工艺处理污水,出水水质比较稳定,运行状态良好。

在线清洗对倒置A^2/O-MBR复合膜污染控制研究

采用自主研发的聚偏氟乙烯-聚对苯二甲酸乙二酯(PVDF-PET)复合膜与倒置A2/O工艺结合的MBR系统,以Na Cl O作为清洗剂对复合膜进行在线化学清洗,考察了Na Cl O在不同清洗周期下对膜污染的控制作用,对膜污染的主要污染物胞外聚合物(EPS)的去除效率及对膜结构和系统稳定性的影响。结果表明,Na Cl O对膜进行在线清洗,单次清洗后TMP恢复率达98%,整个阶段运行时间为24 d;循环清洗中,最初TMP恢复率达100%,运行时间为36 d,随着清洗次数的增加,恢复率逐渐下降,都有效延缓了膜污染进入快速增长阶段。Na Cl O对EPS具有较强的去除效果,相比纯水增加了20%。低含量Na Cl O并未对膜结构及系统的稳定性造成不利影响。

A/O-MBR处理高浓度氨氮农药废水的试验研究

试验采用了缺氧-好氧一体式膜生物反应器（A/O-MBR）工艺处理高浓度氨氮农药废水。经过120d左右的运行,试验结果表明：在一定DO、pH和温度条件下,进水COD为230～523mg/L,氨氮进水容积负荷在1.5kgNH3-N/（m3·d）以下时,系统逐渐取得良好的出水效果,COD、氨氮、总氮去除率平均分别为86%、91.58%、48%。而且MBR出水浊度〈0.2NTU、SS〈3mg/L,间歇抽吸、曝气冲刷以及填料的加入减缓了膜污染,保证系统可持续运行。

新型一体化A^2/O-MBR曝气能效研究

在普通曝气池内加装曝气能量聚集器,将反应池分隔成不同反应区,包括好氧区、膜区、缺氧-厌氧区,构建了新型一体化A2/O-MBR。通过测试不同曝气强度下普通曝气池与一体化A2/O-MBR内流体流速分布,比较2者的曝气能效。结果表明,新型一体化A2/O-MBR的曝气体积流量(3.5 m3/h)为普通曝气池(7.5 m3/h)的0.45倍时,膜区流体流速是普通曝气池的1.5倍;同时,曝气体积流量从3.5 m3/h增至7.5 m3/h,膜区内的流体流速提高有限,使新型一体化A2/O-MBR可选在低曝气强度下运行成为可能,可降低反应器曝气能耗50%以上;曝气能量聚集器可集中普通曝气池的曝气能量用于提高膜区流速和一体化A2/O-MBR反应器的曝气能效。