Inhibition factors and Kinetic model for ammonium inhibition on the anammox process of the SNAD biofilm

The aim of the present work was to evaluate the anaerobic ammonium oxidation (anammox) activity of simultaneous partial nitrification, anammox and denitrification (SNAD) biofilm with different substrate concentrations and pH values. Kaldnes rings taken from the SNAD biofilm reactor were incubated in batch tests to determine the anammox activity. Haldane model was applied to investigate the ammonium inhibition on anammox process. As for nitrite inhibition, the NH₄⁺-N removal rate of anammox process remained 87.4% of the maximum rate with the NO₂⁻-N concentration of 100 mg/L. Based on the results of Haldane model, no obvious difference in kinetic coefficients was observed under high or low free ammonia (FA) conditions, indicating that ammonium rather than FA was the true inhibitor for anammox process of SNAD biofilm. With the pH value of 7.0, the r_max, Ks and K_I of ammonium were 0.209 kg NO₂⁻-N/kg VSS/day, 9.5 mg/L and 422 mg/L, respectively. The suitable pH ranges for anammox process were 5.0 to 9.0. These results indicate that the SNAD biofilm performs excellent tolerance to adverse conditions.     

羟胺对氨氧化菌和亚硝酸盐氧化菌的竞争性选择

有效抑制亚硝酸盐氧化菌(NOB)是实现稳定短程硝化的关键.使用运行方式为厌氧/好氧/缺氧(A/O/A)的SBR反应器,探究羟胺(NH_2OH)对氨氧化菌(AOB)和NOB的竞争性选择.在混合液NH_2OH浓度分别为3 mg·L~(-1)和5 mg·L~(-1)条件下采用不同处理频率观察短程硝化的启动情况.结果表明,每2个周期投加1次混合液浓度为5mg·L~(-1)的NH_2OH时,亚硝态氮积累率(NAR)在6 d内从0.1%增长到57.4%,并保持在(62.0±4. 6)%至实验结束;通过分析第6 d的典型周期中可以看出:好氧阶段结束时,氨氮浓度由26. 05 mg·L~(-1)降至8. 06 mg·L~(-1),同时生成9.02 mg·L~(-1)的亚硝态氮和6.70 mg·L~(-1)的硝态氮;AOB最大活性(rAOB)与NOB最大活性(rNOB)的比值从第1 d的1.05增长到第9 d的4.22;通过进一步qPCR分析可以看出:实验第9 d时, AOB与NOB丰度分别下降至处理前的30. 2%和19. 1%.因此,基于NH_2OH对AOB和NOB的竞争性选择有望为城市污水短程硝化的快速启动提供可能.     

The effect of salinity on waste activated sludge alkaline fermentation and kinetic analysis

The effect of salinity on sludge alkaline fermentation at low temperature(20°C) was investigated, and a kinetic analysis was performed. Different doses of sodium chloride(Na Cl, 0–25 g/L) were added into the fermentation system. The batch-mode results showed that the soluble chemical oxygen demand(SCOD) increased with salinity. The hydrolysate(soluble protein, polysaccharide) and the acidification products(short chain fatty acids(SCFAs), NH+4–N, and PO_4~(3-)–P) increased with salinity initially, but slightly declined respectively at higher level salinity(20 g/L or 20–25 g/L). However, the hydrolytic acidification performance increased in the presence of salt compared to that without salt.Furthermore, the results of Haldane inhibition kinetics analysis showed that the salt enhanced the hydrolysis rate of particulate organic matter from sludge particulate and the specific utilization of hydrolysate, and decreased the specific utilization of SCFAs. Pearson correlation coefficient analysis indicated that the importance of polysaccharide on the accumulation of SCFAs was reduced with salt addition, but the importance of protein and NH+4–N on SCFA accumulation was increased.     

Advanced treatment of wet-spun acrylic fiber manufacturing wastewater using three-dimensional electrochemical oxidation

A three-dimensional electrochemical oxidation(3D-EC) reactor with introduction of activated carbon(AC) as particle micro-electrodes was applied for the advanced treatment of secondary wastewater effluent of a wet-spun acrylic fiber manufacturing plant. Under the optimized conditions(current density of 500 A/m~2, circulation rate of 5 mL/min, AC dosage of 50 g, and chloride concentration of 1.0 g/L), the average removal efficiencies of chemical oxygen demand(COD_(cr)), NH3–N, total organic carbon(TOC), and ultraviolet absorption at 254 nm(UV_(254)) of the 3D-EC reactor were 64.5%, 60.8%, 46.4%, and 64.8%, respectively; while the corresponding effluent concentrations of COD_(cr), NH_3–N, TOC, and UV_(254) were 76.6, 20.1, and42.5 mg/L, and 0.08 Abs/cm, respectively. The effluent concentration of COD_(cr) was less than 100 mg/L, which showed that the treated wastewater satisfied the demand of the integrated wastewater discharge standard(GB 8978-1996). The 3D-EC process remarkably improved the treatment efficiencies with synergistic effects for COD_(cr), NH_3–N, TOC, and UV_(254) during the stable stage of 44.5%, 38.8%, 27.2%, and 10.9%, respectively, as compared with the sum of the efficiencies of a two-dimensional electrochemical oxidation(2D-EC) reactor and an AC adsorption process, which was ascribed to the numerous micro-electrodes of AC in the 3D-EC reactor. Gas chromatography mass spectrometry(GC–MS) analysis revealed that electrochemical treatment did not generate more toxic organics, and it was proved that the increase in acute biotoxicity was caused primarily by the production of free chlorine.     

碱度对沸石序批式反应器亚硝化的影响

本研究采用沸石序批式反应器(ZSBR)在常温(25℃±1℃)下实现快速稳定的亚硝化,亚硝酸盐氮积累率维持在90.0%以上,并且考察了在进水氨氮500 mg·L~(-1)时,4个不同碱度(以CaCO_3计)对ZSBR亚硝化的影响.结果表明,ZSBR实现快速亚硝化的关键是游离氨(FA)对亚硝酸盐氧化菌(NOB)的抑制作用远大于其对氨氧化菌(AOB)的抑制作用,并且经此过程转化后的含氨氮的废水,可以作为厌氧氨氧化的进水,进一步脱除水中的氨氮与总氮,当系统投加碱度(以CaCO_3计)为2 500mg·L~(-1)时,ZSBR亚硝化效果最好,平均氨氮转化率为66.7%,平均亚硝酸盐氮积累率为98.1%,平均亚硝酸盐氮产率为0.74 kg·(m~3·d)~(-1).高通量测序分析表明ZSBR长时间运行后微生物群落发生显著变化,AOB得到富集,NOB在FA的抑制作用下不断被淘洗出反应器.     

Comparison between UV and VUV photolysis for the pre- and post-treatment of coking wastewater

In this study, ultraviolet (UV) and vacuum ultraviolet (VUV) photolysis were investigated for the pre-treatment and post-treatment of coking wastewater. First, 6-fold diluted raw coking wastewater was irradiated by UV and VUV. It was found that 15.9%–35.4% total organic carbon (TOC) was removed after 24 hr irradiation. The irradiated effluent could be degraded by the acclimated activated sludge. Even though the VUV photolysis removed more chemical oxygen demand (COD) than UV, the UV-irradiated effluent demonstrated better biodegradability. After 4 hr UV irradiation, the biological oxygen demand BOD₅/COD ratio of irradiated coking wastewater increased from 0.163 to 0.224, and its toxicity decreased to the greatest extent. Second, the biologically treated coking wastewater was irradiated by UV and VUV. Both of them were able to remove 37%–47% TOC within 8 hr irradiation. Compared to UV, VUV photolysis could significantly improve the transparency of the bio-treated effluent. VUV also reduced 7% more ammonia nitrogen (NH₄⁺–N), 17% more nitrite nitrogen (NO₂⁻–N), and 18% more total nitrogen (TN) than UV, producing 35% less nitrite nitrogen (NO₃⁻–N) as a result. In conclusion, UV irradiation was better in improving the biodegradability of coking wastewater, while VUV was more effective at photolyzing the residual organic compounds and inorganic N-species in the bio-treated effluent.     

Nitrifying population dynamics in a redox stratified membrane biofilm reactor (RSMBR) for treating ammonium-rich wastewater

Nitrogen removal performance and nitrifying population dynamics were investigated in a redox stratified membrane biofilm reactor (RSMBR) under oxygen limited condition to treat ammonium-rich wastewater. When the NHt₄⁺-N loading rate increased from 11.1±1.0 to 37:2 ± 3:2 gNHt₄⁺-N·m⁻²·d⁻¹, the nitrogen removal in the RSMBR system increased from 18.0±9.6 mgN·d⁻¹ to 128.9±61.7 mgN·d⁻¹. Shortcut nitrogen removal was achieved with nitrite accumulation of about 22:3 ± 5:3 mgNO₂⁻-N·L⁻¹. Confocal micrographs showed the stratified distributions of nitrifiers and denitrifiers in the membrane aerated biofilms (MABs) at day 120, i.e., ammonia and nitrite oxidizing bacteria (AOB and NOB) were dominant in the region adjacent to the membrane, while heterotrophic bacteria propagated at the top of the biofilm. Real-time qPCR results showed that the abundance of amoA gene was two orders of magnitude higher than the abundance of nxrA gene in the MABs. However, the nxrA gene was always detected during the operation time, which indicates the difficulty of complete washout of NOB in MABs. The growth of heterotrophic bacteria compromised the dominance of nitrifiers in biofilm communities, but it enhanced the denitrification performance of the RSMBR system. Applying a high ammonia loading together with oxygen limitation was found to be an effective way to start nitrite accumulation in MABs, but other approaches were needed to sustain or improve the extent of nitritation in nitrogen conversion in MABs.     

膜曝气生物膜反应器同步硝化反硝化研究

炭膜作为膜曝气生物膜反应器膜组件处理人工合成废水,在单一反应器内实现了同时去碳脱氮.结果表明,当进水COD和NH^＋₄-N浓度分别为338 mg/L和75 mg/L,HRT为14 h,炭膜腔内压力为13.6 kPa时,COD、NH⁺₄-N和TN的去除效率分别为82.5%、 95.1%和84.2%.但是在反应器运行的后期TN去除效率明显下降,主要是因为高有机负荷导致无纺布上的微生物过度繁殖,严重影响了硝化过程的进行.通过荧光原位杂交和扫描电镜技术观察生物膜微生物结构,得出厌氧或兼氧菌主要分布在生物膜外层的缺氧区,而氨氧化菌主要分布在生物膜内层的好氧区.硝化细菌和反硝化细菌在生物膜内的共存实现了炭膜曝气生物膜反应器的同步硝化反硝化.     

Differences in nitrite-oxidizing communities and kinetics in a brackish environment after enrichment at low and high nitrite concentrations

Nitrite accumulation in shrimp ponds can pose serious adverse effects to shrimp production and the environment.This study aims to develop an effective process for the enrichment of ready-to-use nitrite-oxidizing bacteria(NOB)inocula that would be appropriate for nitrite removal in brackish shrimp ponds.To achieve this objective,the effects of nitrite concentrations on NOB communities and nitrite oxidation kinetics in a brackish environment were investigated.Moving-bed biofilm sequencing batch reactors and continuous moving-bed biofilm reactors were used for the enrichment of NOB at various nitrite concentrations,using sediment from brackish shrimp ponds as seed inoculum.The results from NOB population analysis with quantitative polymerase chain reaction(q PCR)show that only Nitrospira were detected in the sediment from the shrimp ponds.After the enrichment,both Nitrospira and Nitrobacter coexisted in the reactors controlling effluent nitrite at 0.1 and 0.5 mg-NO_2~--N/L.On the other hand,in the reactors controlling effluent nitrite at 3,20,and 100 mg-NO_2~--N/L,Nitrobacter outcompeted Nitrospira in many orders of magnitude.The half saturation coefficients(Ks)for nitrite oxidation of the enrichments at low nitrite concentrations(0.1 and 0.5 mg-NO_2~--N/L)were in the range of 0.71–0.98 mg-NO_2~--N/L.In contrast,the Ksvalues of NOB enriched at high nitrite concentrations(3,20,and 100 mg-NO_2~--N/L)were much higher(8.36–12.20 mg-NO_2~--N/L).The results suggest that the selection of nitrite concentrations for the enrichment of NOB inocula can significantly influence NOB populations and kinetics,which could affect the effectiveness of their applications in brackish shrimp ponds.     

Performance of completely autotrophic nitrogen removal over nitrite process under different aeration modes and dissolved oxygen

In this study, three sequential batch biofilm reactors (SBBRs) were operated for 155 days to evaluate the performance of completely autotrophic nitrogen removal over nitrite (CANON) process under different aeration modes and dissolved oxygen (DO). Synthetic wastewater with 160-mg NH4 ⁺-N/L was fed into the reactors. In the continuously-aerated reactor, the efficiency of the ammonium nitrogen conversion and total nitrogen (TN) removal reached 80% and 70%, respectively, with DO between 0.8–1.0 mg/L. Whereas in the intermittently-aerated reactor, at the aeration/non-aeration ratio of 1.0, ammonium was always under the detection limit and 86% of TN was removed with DO between 2.0–2.5 mg/L during the aeration time. Results show that CANON could be achieved in both continuous and intermittent aeration pattern. However, to achieve the same nitrogen removal efficiency, the DO needed in the intermittently-aerated sequential batch biofilm reactor (SBBR) during the aeration period was higher than that in the continuously-aerated SBBR. In addition, the DO in the CANON system should be adjusted to the aeration mode, and low DO was not a prerequisite to CANON process.     

Phosphate recovery from anaerobic digester effluents using CaMg(OH)4

Dolomite lime(DL)(CaMg(OH)_4) was used as an economical source of Mg~(2+)for the removal and recovery of phosphate from an anaerobic digester effluent of a municipal wastewater treatment plant(MWWTP) wastewater. Batch precipitation results determined that phosphate was effectively reduced from 87 to less than 4 mg-P/L when the effluent water was mixed with 0.3 g/L of DL. The competitive precipitation mechanisms of different solids in the treatment system consisting of Ca~(2+)–Mg~(2+)–NH_4~+–PO_4~(3-)CO_3~(2-)were determined by comparing model predictions with experimental results. Thermodynamic model calculations indicated that hydroxyapatite(Ca_(10)(PO_4)_6(OH)_2), Ca_4H(PO_4)_3?3H_2O, Ca_3(PO_4)_2(beta), and Ca_3(PO_4)_2(am2)were more stable than struvite(MgNH_4PO_3?6H_2O) and calcite(CaCO_3). However, X-ray diffraction(XRD) analysis determined the formation of struvite and calcite minerals in the treated effluent. Kinetic experimental results showed that most of the phosphate was removed from synthetic effluent containing NH_4~+within 2 hr, while only 20% of the PO_4~(3-)was removed in the absence of NH_4~+after 24 hr of treatment. The formation of struvite in the DL-treated effluent was due to the rapid precipitation rate of the mineral. The final pH of the DL-treated effluent significantly influenced the mass ratio of struvite to calcite in the precipitates. Because more calcite was formed when the p H increased from 8.4 to 9.6, a p H range of 8.0–8.5 should be used to produce solid with high PO_4~(3-)content. This study demonstrated that DL could be used for effective removal of phosphate from the effluent and that resultant precipitates contained high content of phosphate and ammonium.     

悬浮载体生物膜内硝化菌群空间分布规律

利用16S rRNA寡核苷酸探针荧光原位杂交和共聚焦激光扫描显微镜联用技术,对悬浮载体生物膜内硝化菌群的空间分布规律进行了分析.试验采用3组结构完全相同的悬浮载体生物膜反应器,每个反应器的曝气区为6L,沉淀区为2L,水力停留时间为1.0h,3个反应器的进水COD/NH₄⁺-N分别为15、10和5,从反应器中取出载体颗粒表面的生物膜进行分析,研究各反应器中生物膜的微生物群落结构的变化规律.结果表明,SCBR内载体表面生物膜的总体厚度在80～120μm左右,氨氧化菌和亚硝酸盐氧化菌主要分布在生物膜表面的20～30μm左右范围内.随着进水中COD/NH₄⁺-N的增加,氨氧化菌和亚硝酸盐氧化菌在整个生物膜中所占的比例逐步下降.     

用氧吸收速率(OUR)表征活性污泥硝化活性的研究

研究了用氧吸收速率（ＯｘｙｇｅｎＵｐｔａｋｅＲａｔｅ，简称ＯＵＲ）表征活性污泥硝化活性的方法．利用生物抑制剂丙烯基硫脲（ａｌｙｌｔｈｉｏｕｒｅａ，简称ＡＴＵ）和氯酸钠（ＮａＣｌＯ３）可以选择性地抑制亚硝酸细菌和硝酸细菌的活性．通过测量不同时间的ＯＵＲ，可以分别计算出污泥的亚硝化活性和硝化活性．结果表明：该方法的测量结果与实际反应器中的硝化反应情况相当一致．该方法简单易行，快速方便，适用于硝化系统中硝化活性的测量．     

序批式生物膜CANON工艺的运行与温度的影响

通过序批式生物膜反应器,研究了CANON工艺的运行规律,并研究了温度对CANON工艺的影响.研究发现,通过序批式生物膜反应器反应器可以成功实现CANON工艺,TN去除率可达到88.3%,TN去除负荷达到0.52kg/(m3·d).系统中的NO2--N变化规律可以分为浓度上升期,浓度稳定期与浓度下降期.pH值先降低后升高的拐点与DO突跃的拐点均可作为反应结束的指示参数,DO拐点比pH值拐点出现要提前.在26~35℃之间,可以获得较好的硝化效果与TN去除效果,温度降低到20℃时,厌氧氨氧化性能开始受到显著影响,造成反应器中大量NO2--N积累,而硝化效果在15℃才受到显著影响.反应器中厌氧氨氧化细菌的最适温度约为30℃.     

高氨氮废水短程硝化过程中N2O释放试验研究

试验采用序批式反应器(SBR)处理高氨氮废水,逐步提高废水氨氮(NH+4-N)浓度到800 mg·L-1,通过控制曝气量实现了短程硝化.SBR周期试验表明,在低溶解氧和高游离氨等共同作用下,氨氧化菌(AOB)活性较低,导致AOB以亚硝酸盐氮(NO_2~--N)作为电子受体进行好氧反硝化,氧化亚氮(N_2O)释放因子为9.8%.静态试验控制初始NH_4~+-N为100 mg·L-1且改变曝气量(0.22~0.88 L·min~(-1))条件下,溶解氧浓度的增加能够提高硝化菌活性,N2O释放因子为0.51%~0.85%.当初始NH_4~+-N浓度为100 mg·L~(-1)且曝气量控制在0.66 L·min-1时,初始NO-2-N浓度为0~100 mg·L~(-1)对硝化菌活性影响较小,N2O释放因子为0.50%~0.71%.当溶解氧和游离氨浓度控制在适宜范围内,可维持AOB较高活性,抑制AOB发生好氧反硝化作用,降低N2O释放率.     

Preparation and evaluation of aminopropyl-functionalized manganese-loaded SBA-15 for copper removal from aqueous solution

A novel material, aminopropyl-functionalized manganese-loaded SBA-15 (NH₂-Mn-SBA-15), was synthesized by bonding 3-aminopropyl trimethoxysilane (APTMS) onto manganese-loaded SBA-15 (Mn-SBA-15) and used as a Cu^2 + adsorbent in aqueous solution. Fourier transform infrared spectroscopy (FT-IR), X-ray diffraction spectra (XRD), N₂ adsorption/desorption isotherms, high resolution field emission scanning electron microscopy (FESEM) and X-ray photoelectron spectroscopy (XPS) were used to characterize the NH₂-Mn-SBA-15. The ordered mesoporous structure of SBA-15 was remained after modification. The manganese oxides were mainly loaded on the internal surface of the pore channels while the aminopropyl groups were mainly anchored on the external surface of SBA-15. The adsorption of Cu^2 + on NH₂-Mn-SBA-15 was fitted well by the Langmuir equation and the maximum adsorption capacity of NH₂-Mn-SBA-15 for Cu^2 + was over two times higher than that of Mn-SBA-15 under the same conditions. The Elovich equation gave a good fit for the adsorption process of Cu^2 + by NH₂-Mn-SBA-15 and Mn-SBA-15. Both the loaded manganese oxides and the anchored aminopropyl groups were found to contribute to the uptake of Cu^2 +. The NH₂-Mn-SBA-15 showed high selectivity for copper ions. Consecutive adsorption–desorption experiments showed that the NH₂-Mn-SBA-15 could be regenerated by acid treatment without altering its properties.     

低基质颗粒污泥反应器中亚硝化的实现过程及其污泥变化特征

在CSTR反应器中接种硝化颗粒污泥处理低氨氮浓度废水,研究其亚硝化的实现过程,并基于对颗粒污泥理化性质、功能菌群的空间分布规律及活性的分析,系统阐述了影响亚硝化稳定的关键因素.结果表明,通过协同调控进水氨氮负荷（NLR）和溶解氧（DO）水平等参数,亚硝化成功实现并可维持稳定,亚硝积累率达80%以上.所得亚硝化颗粒污泥为棕黄色,呈现出光滑、饱满的椭球形或球形,颗粒表面微生物以球菌为主;颗粒平均粒径1.3 mm,平均沉降速率为71.3 m·h^-1.批次试验显示,颗粒污泥（粒径>0.8 mm）中存在明显的成层分布结构,氨氧化细菌（AOB）主要占据颗粒表层空间,而亚硝酸盐氧化细菌（NOB）主要分布在颗粒内部;絮体或小粒径污泥（粒径<0.8 mm）与颗粒污泥（粒径>0.8 mm）呈现出不同的微生物空间分布特征.在颗粒污泥反应器中,良好的硝化菌群分层结构、较高的出水氨氮浓度（15~33 mg·L^-1）或较低的DO/NH₄⁺-N （0.08~0.15）是亚硝化实现过程中的关键影响因素.     

Oxygen tolerance capacity of upflow anaerobic solid-state (UASS) with anaerobic filter (AF) system

In order to investigate the oxygen tolerance capacity of upflow anaerobic solid-state(UASS)with anaerobic filter(AF) system, the effect of microaeration on thermophilic anaerobic digestion of maize straw was investigated under batch conditions and in the UASS with AF system. Aeration intensities of 0–431 m L O2/gvswere conducted as pretreatment under batch conditions. Aeration pretreatment obviously enhanced anaerobic digestion and an aeration intensity of 431 m L O2/gvsincreased the methane yield by 82.2%. Aeration intensities of 0–355 m L O2/gvswere conducted in the process liquor circulation of the UASS with AF system. Dissolved oxygen(DO) of UASS and AF reactors kept around 1.39 ±0.27 and 0.99 ± 0.38 mg/L, respectively. p H was relatively stable around 7.11 ± 0.04. Volatile fatty acids and soluble chemical oxygen demand concentration in UASS reactor were higher than those in AF reactor. Methane yield of the whole system was almost stable at 85 ± 7 m L/gvs as aeration intensity increased step by step. The UASS with AF system showed good oxygen tolerance capacity.     

添加原水改善SBR工艺处理猪场废水厌氧消化液性能

采用序批式反应器(SBR)工艺直接处理猪场废水厌氧消化液,处理系统的效率较低,COD去除率仅有10%左右,NH₄⁺-N去除率70%左右;处理出水水质较差,出水COD高于1 000mg/L,出水NH₄⁺-N在200mg/L左右;处理系统的工作不稳定,效能逐渐恶化.在猪场废水厌氧消化液中添加部分未经厌氧消化的猪场废水(原水),处理系统的处理效率明显提高,COD去除率高于80%,出水COD降到250～350mg/L;NH₄⁺-N去除率高于99%,出水NH₄⁺-N小于10mg/L;处理系统的稳定性也得到增强.添加原水后,猪场废水厌氧消化液的BOD₅/COD比值从0.19上升到0.54,BOD₅/TN比值从0.28上升到2.04,增加了微生物生长和反硝化所需的碳源,强化了反硝化作用,不仅提高了总氮去除效率,而且通过回补碱度,维持了处理系统的pH值稳定.     

海洋厌氧氨氧化菌处理含海水污水的基质抑制及其动力学特性

采用ASBR反应器通过改变单一基质浓度分别研究了NH_4~+-N和NO_2~--N对海洋厌氧氨氧化菌脱氮效能的影响及其动力学特性.结果表明,保持进水NO_2~--N为105.6 mg·L~(-1),当进水NH_4~+-N浓度提高至1 200 mg·L~(-1)时,海洋厌氧氨氧化反应器仍保持较好的脱氮能力,未受到明显的抑制作用,NO_2~--N的去除率稳定在80.70%左右;当进水NO_2~--N浓度提高至265.6mg·L~(-1)时,反应器开始受到明显的抑制作用,NH_4~+-N的去除率下降至63.01%左右,随着进水NO_2~--N浓度继续提高至305.6mg·L~(-1)时,NH_4~+-N的去除率进一步下降至43.93%左右.利用Haldane模型和Aiba模型拟合NH_4~+-N和NO_2~--N抑制作用的动力学特性,得到了NRRmax、KS、Ki这3个动力学参数及出水基质浓度与总氮容积负荷(TNRR)之间的关系,根据进一步分析可知,Haldane模型更适合描述NH_4~+-N抑制作用下的动力学特性,Aiba模型更适合描述NO_2~--N抑制作用下的动力学特性,并得到NH_4~+-N和NO_2~--N的出水抑制浓度分别为3 893.625 mg·L~(-1)和287.208 mg·L~(-1),为海洋厌氧氨氧化菌处理含海水污水提供了理论依据.