造气吹风气烟尘污染治理的技术措施

该文叙述了合成氨生产造气工段吹风气烟尘治理的技术措施与注意事项 ,指出在改进工况操作、减少吹风带出物的同时 ,设置干式旋风除尘与水膜除尘 ,可取得很好的治理效果 ,烟尘达标排放 ,经济效益显著     

敞开式微气泡富氧曝气活性污泥新工艺

活性污泥法在降解污水中所含有机物时,如增加污水中的溶解氧量,可大幅度提高污泥中微生物的活力,显著改善污水处理效率.但过去由于氧气成本高,纯氧曝气法一直处于试验阶段,未能很好地推广应用.变压吸附现场制氧可提供廉价氧气源,结合微气泡富氧曝气技术,同时实现了充氧和混合工艺,氧的利用率大幅提高,显著降低了纯氧曝气处理污水的综合投资和运行成本,是一种高效、低能耗的污水处理新工艺,具有很好的应用前景.     

电凝聚法在垃圾渗滤液处理中的应用

采用电凝聚方法,作为垃圾渗滤液前处理工艺,且研究中采用槽底曝气装置,既起到了搅拌作用,同时也起到了气浮作用。以铝板为极板材料,当处理进水COD浓度为9399.3mg/L,电流密度为1.2A/dm2,极板间距为10mm,处理时间为40min时,COD的去除率达到43.3%,NH3-N的处理效率最高可达到80.1%。     

Effect of intermittent aeration mode on nitrogen concentration in the water column and sediment pore water of aquaculture ponds

Nitrogen in pond sediments is a major water quality concern and can impact the productivity of aquaculture. Dissolved oxygen is an important factor for improving water quality and boosting fish growth in aquaculture ponds, and plays an important role in the conversion of ammonium-nitrogen (NH₄⁺-N) to nitrite-nitrogen (NO₂^?-N) and eventually nitrate-nitrogen (NO₃^?-N). A central goal of the study was to identify the best aeration method and strategy for improving water quality in aquaculture ponds. We conducted an experiment with six tanks, each with a different aeration mode to simulate the behavior of aquaculture ponds. The results show that a 36 hr aeration interval (T_c = 36 hr: 36 hr) and no aeration resulted in high concentrations of NH₄⁺-N in the water column. Using a 12 hr interval time (T_c = 12 hr: 12 hr) resulted in higher NO₂^?-N and NO₃^?-N concentrations than any other aeration mode. Results from an 8 hr interval time (T_c = 8 hr: 8 hr) and 24 hr interval time (T_c = 24 hr: 24 hr) were comparable with those of continuous aeration, and had the benefit of being in use for only half of the time, consequently reducing energy consumption.     

间歇梯度曝气的生活污水好氧颗粒污泥脱氮除磷

本研究设置了3个SBR反应器R1、R2和R3,分别采用(A/O)_3-SBR梯度曝气、(A/O)_3-SBR恒定曝气和传统(A/O)-SBR方式运行,以实际城市生活污水为进水基质,探讨了不同曝气方式下的营养物去除性能和好氧颗粒污泥特性,为低强度城市污水的碳源合理利用提供合理的方式.由实验结果可知,R1、R2和R3中颗粒在稳定时期对COD的平均去除率分别为88.68%、 89.05%和88.96%,对TN的平均去除率分别为76.97%、 71.99%和64.92%,对TP的平均去除率分别为96.28%、 85.05%和78.97%,且反硝化聚磷菌占聚磷菌的比例分别为25.52%、 19.60%和12.77%.结果表明,厌氧、好氧和缺氧交替的运行方式更有利于反硝化聚磷菌(DPAOs)的富集,且梯度曝气较恒定曝气方式富集更多,这对碳源不足的低强度城市生活污水处理有重要意义;同时R1中曝气段溶解氧逐级降低,提高了颗粒同步硝化反硝化率和降低了能耗,有利于总氮(TN)的高效去除. 3组反应器在运行后期颗粒粒径分别为727.368、 815.072和895.041μm,且通过对颗粒进行显微观察可以看出, R2和R3中颗粒不如R1中密实.此外,R1、R2和R3运行后期PN/PS值分别为6.31、 5.63和4.83,颗粒稳定时期EPS含量(以VSS计)分别为103.97、 92.22和76.98 mg·g~(-1),表明间歇梯度曝气的方式有利于刺激EPS的分泌,尤其是PN的分泌,使PN/PS值较高,细胞疏水性增强,颗粒密实稳定.     

强化除磷曝气生物滤池反冲洗优化及其污泥特性

为探讨BAF(曝气生物滤池)最佳反冲洗强度及其选择依据,以某处理石化二级出水的强化除磷BAF为研究对象,采取不同的反冲洗强度进行气-水联合反冲洗,探讨反冲洗过程中出水污泥量峰值出现时间、污泥的SOUR(比好氧呼吸速率)变化、反冲洗前后微生物量和微生物脱氢酶活性(DHA)的变化以及反冲洗后的恢复效果,并对反冲洗强度参数的选择进行了优化. 结果表明:在该研究条件下,采用气洗〔强度为12 L/(m2·s)〕4 min,气-水联合洗〔气洗强度为12 L/(m2·s),水洗强度为6 L/(m2·s)〕5 min,最后用清水漂洗9 min的反冲洗方式,排水中污泥的ρ(SS)可在最短时间(3 min)达到峰值;反冲洗排水中污泥的SOUR较低,平均值为0.5 mg/(mg·h);距离底端进水口1.3和2.2 m处的滤料层微生物的量损失较小,分别为4.4%和5.3%,其相应微生物的活性有所增加. 研究显示,该条件下反冲洗可有效清除滤料颗粒间所截留及滤料表面脱落的老化生物膜,并可保留适量活性较高的生物膜,强化了传质条件,反冲洗后对污染物的处理能力能恢复迅速.      

曝气强化非离子表面活性剂洗涤法修复柴油污染土壤

采用异位修复法,利用非离子表面活性剂洗涤柴油污染土壤,并在洗涤过程中曝气强化。考察了洗涤效果的影响因素,并通过表面张力和接触角的测定探讨了洗涤机理。实验结果表明:曝气对污染土壤中柴油的洗脱有强化作用,可提高洗脱率10%~20%;3种非离子表面活性剂的洗脱效果优劣次序为聚氧乙烯月桂醚(Brij-35)曲拉通X-100(TX-100)吐温-80(Tw-80);在表面活性剂浓度为1倍临界胶束浓度、曝气量为7.5 L/min、洗涤时间为60 min、洗涤液pH为11.0的优化条件下,Brij-35对柴油的洗脱率达77.4%,污染土样的含油率从7.0%降至1.6%,接触角从24.12°降至6.65°,可基本恢复土壤的亲水性;洗涤液的表面张力随表面活性剂浓度的增加而降低,但不受洗涤液pH的影响。     

水动力条件对全程自养脱氮工艺启动研究

CANON工艺需要部分短程硝化提供亚硝酸盐,所以CANON工艺存在溶解氧难控制的问题,特别是在反应器较小的情况。本文采用设有挡板的改良SBR,通过机械搅拌形成剧烈水流搅动,精确控制溶解氧,研究了不同搅拌速率对CANON工艺启动的影响。结果表明,机械曝气能成功启动了CANON工艺,且获得平均总氮去除率达79.40%,剪切应力的提高有利于脱氮性能的提升,机械曝气启动方式相比于鼓风曝气更加容易控制。     

强化曝气对潜流人工湿地堵塞物分布规律的影响

构建曝气及未曝气潜流人工湿地小试实验系统,研究曝气对人工湿地堵塞物组分及分布规律的影响.结果表明:两系统中堵塞物组成均以无机物为主,曝气对堵塞物累积总量影响不大,但对堵塞物化学组分影响较大,使堵塞物中有机物组分比例降低.未曝气及曝气系统堵塞物平均累积量分别为5.18 mg·g~(-1)及5.21 mg·g~(-1),有机物所占比例分别为28.4%和15.6%.曝气对堵塞物在水平及深度方向的分布影响不大,两系统均表现为底层累积物含量略高于表层,出水端累积物含量略高于进水端.电镜及能谱分析结果显示,受溶解氧因素的影响,两系统中表层填料元素种类均较底层丰富,且曝气系统较未曝气系统丰富.     

Numerical simulation of landfill aeration using computational fluid dynamics

The present study is an application of Computational Fluid Dynamics (CFD) to the numerical simulation of landfill aeration systems. Specifically, the CFD algorithms provided by the commercial solver ANSYS Fluent 14.0, combined with an in-house source code developed to modify the main solver, were used. The unsaturated multiphase flow of air and liquid phases and the biochemical processes for aerobic biodegradation of the organic fraction of municipal solid waste were simulated taking into consideration their temporal and spatial evolution, as well as complex effects, such as oxygen mass transfer across phases, unsaturated flow effects (capillary suction and unsaturated hydraulic conductivity), temperature variations due to biochemical processes and environmental correction factors for the applied kinetics (Monod and 1st order kinetics). The developed model results were compared with literature experimental data. Also, pilot scale simulations and sensitivity analysis were implemented. Moreover, simulation results of a hypothetical single aeration well were shown, while its zone of influence was estimated using both the pressure and oxygen distribution. Finally, a case study was simulated for a hypothetical landfill aeration system. Both a static (steadily positive or negative relative pressure with time) and a hybrid (following a square wave pattern of positive and negative values of relative pressure with time) scenarios for the aeration wells were examined. The results showed that the present model is capable of simulating landfill aeration and the obtained results were in good agreement with corresponding previous experimental and numerical investigations.