腐殖酸影响剩余污泥厌氧消化过程实验研究

以实验室培养、几乎不含腐殖质和金属离子的剩余污泥作为研究对象,选择与市政污泥中腐殖酸特征相近的市售腐殖酸为外加填充物,实验研究污泥中所含腐殖质对污泥厌氧消化过程的抑制作用.通过设置腐殖酸不同投加比例(0、5%、10%、15%和20%,以VSS计),探究腐殖酸对厌氧消化不同过程的影响.实验结果表明,腐殖酸抑制厌氧消化生物气产气量.填加15%腐殖酸时对厌氧消化产气量抑制作用最为明显,较未添加腐殖酸对照组产气量下降了35%;但并未对生物气中CH_4体积比产生太大影响,说明抑制影响是对生物气整体性的.腐殖酸亦可抑制厌氧水解过程,投加20%腐殖酸实验组实验结束时残留于上清液中的溶解性多糖、蛋白质浓度分别是对照组的2.2和1.6倍.然而,腐殖酸作为外源电子受体,可以在一定程度上促进酸化过程,其程度在填加20%腐殖酸实验组表现最高,较对照组VFAs提高了11.3%.腐殖酸投加未对系统pH产生明显影响,各实验组pH值均在7.09~7.54间变化.     

Health hazards related to conidia of Cladosporium—biological air pollutants in Poland, central Europe

The spores of Cladosporium Link. are often present in the air in high quantities and produce many allergenic proteins, which may lead to asthma. An aerobiological spore monitoring program can inform patients about the current spore concentration in air and help their physicians determine the spore dose that is harmful for a given individual. This makes it possible to develop optimized responses and propose personalized therapy for a particular sensitive patient. The aim of this study was to assess the extent of the human health hazard posed by the fungal genus Cladosporium. For the first time, we have determined the number of days on which air samples in Poland exceeded the concentrations linked to allergic responses of sensitive patients, according to thresholds established by three different groups(2800/3000/4000 spores per 1 m~3 of the air). The survey was conducted over three consecutive growing seasons(April–September, 2010–2012) in three cities located in different climate zones of Poland(Poznan, Lublin and Rzeszow). The average number of days exceeding 2800 spores per cubic meter(the lowest threshold) ranged from 61(2010) through 76(2011) to 93(2012), though there was significant variation between cities. In each year the highest concentration of spores in the air was detected in either Poznan or Lublin, both located on large plains with intensive agriculture. We have proposed that an effective, science-based software platform to support policy-making on air quality should incorporate biological air pollutant data,such as allergenic fungal spores and pollen grains.     

不同基质配比对农村生活垃圾厌氧发酵效率及稳定性的影响

以典型农村生活垃圾餐厨垃圾(Food Waste,FW)与纸类垃圾(Paper Waste,PW)为基质,通过中温(35℃)批次厌氧共发酵试验,探明不同配比的基质在厌氧共发酵4阶段(水解阶段、酸化阶段、乙酸化阶段、产甲烷阶段)的动力学特性,再结合挥发性脂肪酸(Volatile fatty acids,VFAs)在系统运行过程中的变化,确定FW与PW的最佳配比。结果表明,水解阶段是纸类垃圾的主要限速步骤,而VFAs积累限制了餐厨垃圾甲烷化进程的提高,且VFAs积累主要以丙酸与丁酸为主。当w(FW)≥35%时,产甲烷速率随VFAs质量浓度增大而线性减小,过高的VFAs质量浓度抑制了产甲烷菌的活性。FW与PW最佳基质配比为35∶65(质量比),在此条件下反应速率最为突出,系统运行高效,VFAs能及时被产甲烷菌利用,无有机酸积累,系统运行平稳。     

矿井生产环境下光透过性实验研究

通过实验模拟巷道生产作业环境,分析了矿井生产环境下光照衰减的机理,研究了普通LED灯、金卤灯、荧光灯、头戴LED矿灯4种灯具在不同环境参数下的透射性,得出其在不同矿井因素（粉尘浓度、风速、相对湿度）下光的透过性影响规律,结果表明:在矿井中风速和相对湿度的增加均能降低光的透过率,相对湿度变化对光的透过率影响较大,且风速和相对湿度的增加对粉尘浓度有一定的积聚作用。研究结果为井下照明灯具的合理选用提供了依据。     

埋地输氢管道泄漏爆炸事故后果模拟分析

为了输氢管道的安全建设与运营,基于计算流体力学FLACS软件,模拟了埋地输氢管道在半受限空间内的泄漏爆炸事故后果,探讨了泄漏孔径、泄漏时长、输氢压力和环境风速对爆炸事故后果的影响规律,并得出相应的危险区域。结果表明:泄漏孔径、输氢压力和最大爆炸超压均与危险区域呈正相关关系,泄漏时长对事故后果几乎无影响;随着输氢压力的增大,危险区域受建筑物和风速的影响更为明显,在建筑物附近形成了狭长的危险区域带;最大爆炸超压和危险区域随环境风速的增大均呈现出先增大后减小的趋势。     

中温碱解预处理促进剩余污泥厌氧产甲烷的研究

采用4 mol/L NaO H碱液在中温下处理城市生活污水处理厂剩余污泥6 h,对比原剩余污泥和中温碱解污泥厌氧消化产甲烷的能力,分析了中温碱解及厌氧消化过程中剩余污泥胞内物质的释放规律,结果表明:碱解预处理有效促进了有机物、氨氮的释放,对磷酸盐释放促进作用不明显。原剩余污泥的沼气转化效率为387.5 L/kg(以VS计,下同),中温碱解处理组的沼气转化效率为402.5 L/kg;中温碱解处理组沼气转化效率比原剩余污泥组高3.87%;中温碱解预处理提高了污泥减量化程度及甲烷产量。改进的Gompertz模型结果表明:碱解处理后剩余污泥最大甲烷产量为1 480.7 mL,最大产甲烷速率为77.8 mL/d,细菌产甲烷的延迟时间为3.38 d。     

危险废物处理处置企业清洁生产案例研究

为了给危险废物处理处置企业开展清洁生产提供一些基础性引导,先对比分析了危险废物处理处置企业和常规企业开展清洁生产的异同,然后以采用水泥回转窑协同处置危险废物的R公司为例,从8个方面进行产排污和清洁生产潜力分析,并结合危险废物处理全过程开展物料平衡分析,提出可行的无/低费方案和中/高费方案共19项。研究结果表明,危险废物处理处置企业存在可观的清洁生产和节能减排潜力,通过开展清洁生产可有效从源头防治二次污染,实现节能减排。     

Simultaneous denitrification and denitrifying phosphorus removal in a full-scale anoxic–oxic process without internal recycle treating low strength wastewater

Performance of a full-scale anoxic-oxic activated sludge treatment plant(4.0×10~5 m~3/day for the first-stage project) was followed during a year.The plant performed well for the removal of carbon,nitrogen and phosphorus in the process of treating domestic wastewater within a temperature range of 10.8℃ to 30.5℃.Mass balance calculations indicated that COD utilization mainly occurred in the anoxic phase,accounting for 88.2% of total COD removal.Ammonia nitrogen removal occurred 13.71% in the anoxic zones and 78.77% in the aerobic zones.The contribution of anoxic zones to total nitrogen(TN) removal was 57.41%.Results indicated that nitrogen elimination in the oxic tanks was mainly contributed by simultaneous nitrification and denitrification(SND).The reduction of phosphorus mainly took place in the oxic zones,51.45% of the total removal.Denitrifying phosphorus removal was achieved biologically by 11.29%.Practical experience proved that adaptability to gradually changing temperature of the microbial populations was important to maintain the plant overall stability.Sudden changes in temperature did not cause paralysis of the system just lower removal efficiency,which could be explained by functional redundancy of microorganisms that may compensate the adverse effects of temperature changes to a certain degree.Anoxic-oxic process without internal recycling has great potential to treat low strength wastewater(i.e.,TN 35 mg/L) as well as reducing operation costs.     

Aerobic N2O emission for activated sludge acclimated under different aeration rates in the multiple anoxic and aerobic process

Nitrous oxide (N₂O) is a potent greenhouse gas that can be emitted during biological nitrogen removal. N₂O emission was examined in a multiple anoxic and aerobic process at the aeration rates of 600 mL/min sequencing batch reactor (SBR_L) and 1200 mL/min (SBR_H). The nitrogen removal percentage was 89% in SBR_L and 71% in SBR_H, respectively. N₂O emission mainly occurred during the aerobic phase, and the N₂O emission factor was 10.1% in SBR_L and 2.3% in SBR_H, respectively. In all batch experiments, the N₂O emission potential was high in SBR_L compared with SBR_H. In SBR_L, with increasing aeration rates, the N₂O emission factor decreased during nitrification, while it increased during denitrification and simultaneous nitrification and denitrification (SND). By contrast, in SBR_H the N₂O emission factor during nitrification, denitrification and SND was relatively low and changed little with increasing aeration rates. The microbial competition affected the N₂O emission during biological nitrogen removal.     

An advanced anaerobic biofilter with effluent recirculation for phenol removal and methane production in treatment of coal gasification wastewater

An advanced anaerobic biofilter (AF) was introduced for the treatment of coal gasification wastewater (CGW), and effluent recirculation was adopted to enhance phenol removal and methane production. The results indicated that AF was reliable in treating diluted CGW, while its efficiency and stability were seriously reduced when directly treating raw CGW. However, its performance could be greatly enhanced by effluent recirculation. Under optimal effluent recirculation of 0.5 to the influent, concentrations of chemical oxygen demand (COD) and total phenol in the effluent could reach as low as 234.0 and 14.2 mg/L, respectively. Also, the rate of methane production reached 169.0 mL CH₄/L/day. Though CGW seemed to restrain the growth of anaerobic microorganisms, especially methanogens, the inhibition was temporary and reversible, and anaerobic bacteria presented strong tolerance. The activities of methanogens cultivated in CGW could quickly recover on feeding with glucose wastewater (GW). However, the adaptability of anaerobic bacteria to the CGW was very poor and the activity of methanogens could not be improved by long-term domestication. By analysis using the Haldane model, it was further confirmed that high effluent recirculation could result in high activity for hydrolytic bacteria and substrate affinity for toxic matters, but only suitable effluent recirculation could result in high methanogenic activity.