不同乙酸钠/甘油比对好氧/延长闲置SBR除磷性能的影响

以合成废水为研究对象,以甘油和生活污水中常见的乙酸钠作为碳源,建立了5个好氧/延长闲置序批式反应器(乙酸钠/甘油比分别为1∶0、4∶1、1∶1、1∶4和0∶1),考察了各反应器长期运行过程中的除磷效果,并通过分析典型周期内磷及微生物体内各储能物质的变化,初步探究不同乙酸钠/甘油比对除磷性能的影响机理.研究表明,当乙酸钠/甘油比由1∶0逐渐降至4∶1和1∶1时,平均除磷率由90.1%升至92.5%、97.3%.乙酸钠/甘油比继续降至1∶4及0∶1时,系统除磷率降至65.7%、53.4%.当乙酸钠/甘油比为1∶1时,聚磷菌体内合成大量聚羟基脂肪酸酯(PHAs)(2.55 mmol·g-1,以每g VSS积累的C(mmol)计,下同),为后续磷的吸收及聚磷合成提供更多的能量,而以甘油作为单一碳源时,PHAs合成量最少(0.82 mmol·g-1),糖原合成量最大(2.56 mmol·g-1,以每g VSS积累的C(mmol)计).     

溶解氧对好氧/延长闲置SBR除磷性能的影响

以合成废水为研究对象,乙酸钠为外加碳源,考察不同溶解氧(DO)浓度下好氧/延长闲置(O/EI)序批式反应器的除磷效果,并通过分析典型周期内磷元素及微生物体内各储能物质的变化,探究DO浓度对O/EI工艺除磷性能的影响机制.结果表明,低DO浓度(1 mg·L-1)条件下,O/EI系统具有良好的除磷效果,除磷率高达96%,单位污泥除磷量为5.02 mg·g-1;而当DO浓度较高(4 mg·L-1)时,反应器内磷的去除率降至50%,单位污泥除磷量仅2.81 mg·g-1.研究表明,在DO浓度为1 mg·L-1时,微生物能合成较多聚羟基脂肪酸酯(PHAs),糖原的合成及利用较少,系统好氧吸磷量远高于其他反应器,并在闲置期释放出更多聚磷酸盐.可见,DO可通过影响微生物体内PHAs和糖原的合成及转化,闲置期释磷,好氧前期释磷及好氧吸磷,进而影响系统的除磷性能.     

Water treatment sludge for phosphate removal from the effluent of UASB reactor treating municipal wastewater

Aluminium-based water treatment sludge was used as a coagulant for removing/recovering phosphate from the effluent of upflow anaerobic sludge blanket (UASB) reactor treating municipal wastewater. The effect of three variables, namely sludge dose, initial pH and fresh coagulant (poly-aluminium chloride, PACl) dose was studied using response surface methodology. About 87% phosphate removal could be obtained at the optimum conditions of sludge dose 13.8 g/L, initial pH 6, and fresh PACl dose 5.8 mg Al/L. In order to achieve a similar phosphate removal, a dose in the range of 30–40 mg Al/L of fresh PACl was required. The results suggest that water treatment sludge can be reused as a coagulant for post-treatment of UASB reactor effluent treating municipal wastewater and can be considered as a promising alternative for removing phosphate which can substantially reduce the consumption of fresh PACl. The sludge generated during this process could potentially be used in land application which results in recycling of phosphate.     

Steel slag carbonation in a flow-through reactor system: The role of fluid-flux

Steel production is currently the largest industrial source of atmospheric CO₂. As annual steel production continues to grow, the need for effective methods of reducing its carbon footprint increases correspondingly. The carbonation of the calcium-bearing phases in steel slag generated during basic oxygen furnace (BOF) steel production, in particular its major constituent, larnite {Ca₂SiO₄}, which is a structural analogue of olivine {(MgFe)₂SiO₄}, the main mineral subjected to natural carbonation in peridotites, offers the potential to offset some of these emissions. However, the controls on the nature and efficiency of steel slag carbonation are yet to be completely understood. Experiments were conducted exposing steel slag grains to a CO₂-H₂O mixture in both batch and flow-through reactors to investigate the impact of temperature, fluid flux, and reaction gradient on the dissolution and carbonation of steel slag. The results of these experiments show that dissolution and carbonation of BOF steel slag are more efficient in a flow-through reactor than in the batch reactors used in most previous studies. Moreover, they show that fluid flux needs to be optimized in addition to grain size, pressure, and temperature, in order to maximize the efficiency of carbonation. Based on these results, a two-stage reactor consisting of a high and a low fluid-flux chamber is proposed for CO₂ sequestration by steel slag carbonation, allowing dissolution of the slag and precipitation of calcium carbonate to occur within a single flow-through system.     

SBBR处理腈纶生产废水的实验研究

二甲基乙酰胺湿纺腈纶废水是含有难降解物质的化工废水,碳氮比低,水质波动大。采用序批式生物膜反应器对二甲基乙酰胺湿纺腈纶废水进行实验研究,结果表明:在工艺参数为曝气时间3 h,溶解氧4.5~5.5 mg/L,补充无机碳源碳酸氢钠0.5 mg/L,缺氧停留时间2 h的工况下,COD去处理率为75%,BOD为98%,TOC为70%,NH4+-N为94%,TN为80%,DMAC达到99%。     

上推流厌氧反应器连续干发酵猪粪产沼气试验研究

为解决猪粪连续干发酵存在的氨抑制和出料难等难题,在温度(25±2)℃、有机负荷为干物质(TS)4.44 g.(L.d)-1的条件下,采用上推流式厌氧反应器(UPAR)对猪粪进行连续干式发酵试验,研究了猪粪干发酵过程的产气情况、氨抑制现象和出料流动性,并考察了上推流厌氧反应器进行猪粪干发酵的可行性.试验采用4种不同TS质量分数(20%、25%、30%、35%)的猪粪作为原料,经160 d的运行.结果表明,进料TS质量分数对发酵过程有很大的影响,4种不同进料TS质量分数稳定的池容产气率分别为2.40、1.73、0.89、0.62 L.(L.d)-1,进料TS质量分数为20%、25%和30%的产气效率明显优于进料TS=35%的产气效率.随着进料TS质量分数从20%增加到35%,氨氮质量浓度>2 300 mg.L-1会出现明显的产气抑制.在进料TS=35%时,氨氮质量浓度能达到3 800 mg.L-1,产气速率相对于进料TS=20%递减74.1%.当进料TS达到35%、出料TS质量分数达到17.1%、流速<0.002 m.s-1时,UPAR不能顺利出料.     

生物沥浸处理提高城市污泥脱水性能的中试研究：批式运行模式

为了考察生物沥浸法对城市污泥脱水性能的影响.利用一个兼有序批式与连续式运行模式、工作体积为700 L的生物沥浸反应器对城市污泥进行了连续3批生物沥浸中试研究,并采用厢式压滤机对处理后污泥进行脱水处理.结果表明,曝气量为1.2 m^3/h,含嗜酸性硫杆菌的酸化污泥与待处理的原始污泥体积比为1∶15时,在90 h内完成首批...     

生物沥浸处理提高城市污泥脱水性能的中试研究：连续运行模式

采用有效容积为700 L的推流式生物沥浸反应器对城市污泥进行连续10 d的生物沥浸处理,采用折流方式将反应器从进泥端到处理结束后的排泥端,沿程方向依次划分为1～6区.对试验过程中各区的pH变化趋势,各区污泥的脱水性能（用污泥比阻SRF表征）及生物沥浸污泥经厢式压滤脱水泥饼含水率及其水分蒸发速度进行了系统的研究.结果表明...     

SBR双颗粒污泥系统脱氮除磷性能研究

以模拟废水为研究对象,对SBR双颗粒污泥系统的脱氮除磷性能进行了考察.试验结果表明,A₂N双颗粒污泥系统能使硝化菌和聚磷菌分别在各自最佳的环境中生长,有利于系统脱氮除磷的稳定和高效运行,可控制性也得到了提高.在COD为300 mg·L^-1条件下,系统对COD的平均去除率达到78.8%,大部分COD被聚磷菌用来合成PHA;当溶解氧控制在3.55~4.90 mg·L^-1和5.60~6.60 mg·L^-1之间时,硝化SBR对氨氮的去除率分别为87.0%和94.5%.除磷SBR仅设置缺氧段时,磷去除率为72%;增设后曝气段后,磷去除率增至85%.NO_x^--N(NO₂^--N+ NO₃^--N)的去除主要发生在缺氧段,在反硝化除磷时作为电子受体被去除,平均去除率为90.6%.     

Photocatalytic degradation of bisphenol A using an integrated system of a new gas-liquid-solid circulating fluidized bed reactor and micrometer Gd-doped TiO2 particles

A new gas-liquid-solid circulating fluidized bed photocatalytic reactor (GLSCFBPR) with internally placed multi-layered UV lamps was developed. Micrometer Gd-TiO₂ particles and commercial nanometer P25-TiO₂ were chosen as the photocatalysts, and the hazardous substance bisphenol A (BPA) was chosen as the model pollutant to investigate the performance of this new photocatalytic system. The results showed that the photocatalytic degradation efficiency of the micrometer Gd-TiO₂ particles was similar to that of the nanometer P-25 particles at their respective optimum dosage but the former could be easily separated out by gravity. After investigating the effects of process parameters on the photocatalytic BPA degradation, the response surface method (RSM) was further used for process optimization. The interactions among process parameters, i.e., TiO₂ concentration, superficial gas velocity and superficial liquid velocity were discovered and a related analysis was carried out to explore the underlying mechanism. A quadratic mathematic model was established and performed satisfactorily when used for prediction. The optimum conditions for this new process were as follows: TiO₂ concentration 4.5 g/L, superficial gas velocity 7.83 × 10^-3 m/sec and superficial liquid velocity 8.65 × 10^-3 m/sec.