苦土处理氮磷废水的研究

采用苦土为沉淀剂对模拟氮磷废水和实际氮磷废水进行了脱氮除磷实验研究,探讨了苦土投加量、pH及反应时间对废水中氮磷去除率的影响。此外,对苦土处理氮磷废水的动力学进行了研究,并对苦土及反应沉淀物进行了XRD分析。结果表明,以苦土为沉淀剂,处理氨氮浓度为200 mg/L的模拟废水的最佳条件为:苦土与氨氮(NH4+-N)的质量比为25∶1,平衡时间10 min,氨氮去除率可达到93%,磷去除率达到99%。用苦土为沉淀剂处理南京某厂的实际氮磷废水(氨氮浓度为590 mg/L,磷浓度为1 630 mg/L),氨氮的去除率达到92%,磷的去除率达到99%。苦土处理氮磷废水的动力学数据符合二级动力学模型,主要以化学反应为主。处理后废水中沉淀物的XRD分析表明其主要成分为磷酸铵镁,进一步证明苦土处理氮磷废水主要以化学反应为主。     

投药方式对鸟粪石法脱氮除磷的影响

鸟粪石法脱氮除磷过程中,投药方式对反应产生很大影响.以MgCl2·6H2O和Na2HPO4·12H2O为沉淀剂进行脱氮除磷的实验研究,结果表明,药剂的投加顺序影响不大,加药速度以缓慢加药为宜,pH值调节时机对氮磷的去除率影响很大,pH值调节时机由前调改为后调,氨氮的去除率由70%左右提高至80%～85%,磷的去除率由6...     

以改进的化学沉淀法处理硫酸铵废水

针对MAP化学沉淀法处理氨氮废水中存在的问题。如处理成本高、处理后的废水中磷浓度高，对化学沉淀法进行了改进研究，考察Mg^2＋以外的二价金属离子（Ni^2＋，Mn^2＋，Zn^2＋，Cu^2＋，Fe^2＋）在磷酸根作用下对氨氮的去除效果。针对废水中磷浓度高的问题，进行了MAP沉淀法的条件优化实验。结果表明。通过体系pH值和沉淀剂投加比例的合理控制，可以使在高浓度氨氮废水在出水氨氮浓度达标的同时，实现废水中的氮磷浓度同时控制；针对NaOH作pH调节剂成本过高，而以Ca（OH）2作pH调节剂时，钙离子严重影响MAP沉淀效果。对硫酸铵废水体系提出了CaSO4沉淀——MAP沉淀新工艺。结果表明，这一改进完全可以消除钙离子的影响。实现以石灰取代传统的NaOH调节剂。     

沉淀-絮凝结合法处理磷化废水的研究

采用沉淀-絮凝结合法处理高浓度的磷化废水，以生石灰、氟化钠为沉淀剂，聚炳烯酰胺为絮凝剂对高浓度磷化废水进行了水处理与研究，实验结果表明，对于磷化废水磷酸盐含量高达158 mg/L时，通过控制反应的pH值、沉淀剂及絮凝剂的投加量、沉淀时间等参数，使出水磷含量＜0.5 mg/L，达到国家综合污水排放一级标准, 磷的去除率达99.5%，分别较氯化铁和硫酸铝等传统絮凝剂的磷去除率提高17.4%和15.2%；同时磷化废水中的COD和SS的去除率也能达到78.6%和83.6%, 絮凝剂及其处理成本均明显低于传统絮凝剂，具有明显的经济效益和环境效益。     

丝绸厂汰头废水除磷试验研究

针对丝绸厂汰头废水高有机物浓度高氮磷的特点,对该废水的化学除磷工艺及生物化学组合除磷工艺的除磷效能进行了对比研究,考察了有机负荷、运行工况、工艺组合、药剂种类和投加量等对除磷效能的影响.试验结果表明:对汰头废水采用厌氧-生物除磷-生物脱氮-化学除磷组合工艺除磷经济高效,当生物除磷SBBR工艺单元有机负荷为3 kgBOD5/m3·d,运行工况为进水0.5 h-厌氧2 h-曝气4 h-沉淀1 h-排水0.5 h,化学除磷工艺单元投加60 mg/L聚合氯化铝(PAC)时,可使COD及PO3-4分别为10 000 mg/L和114 mg/L的进水,出水COD及PO3-4分别为93 mg/L和0.23 mg/L;总ηCOD91.5%,ηPO3-4为99.8%.其中生物除磷工艺单元承担的ηPO3-4为75%;化学除磷工艺单元承担的ηPO3-4为24.8%.     

响应面分析法优化造纸污泥吸附剂除磷工艺

以造纸厂废水污泥为原料,采用微波加热法制备造纸污泥吸附剂。利用制备的造纸污泥吸附剂对模拟含磷废水进行了吸附研究,探讨了吸附时间、投加量、pH值、转速和温度等因素对除磷效果的影响,并采用响应面设计法优化吸附工艺条件。结果表明,获得了最佳除磷工艺条件为吸附时间97 min,投加量6.9 g/L,pH=6,转速200 r/min,温度30℃,在此条件下磷的去除率可达99%以上。因此,造纸污泥吸附剂对磷的吸附效果良好,具有重要的实际应用价值。     

养殖废水SBR碳源投加实时控制研究

畜禽养殖废水是典型的高氨氮、低C/N比有机废水。常规生物处理工艺由于反硝化碳源不足导致脱氮效率较低。在2个平行运行的序批式反应器(SBR)中建立实时控制体系以研究投加猪粪浓浆作为外部碳源对脱氮除磷效果的影响。结果表明,根据ORP实时曲线特征优化碳源投加方案,可按水质变化情况适量补充所需碳源,增强体系脱氮效果,同时加强对磷的去除。在优化碳源投加的运行期NH4+-N及PO43-的去除率分别达到99%和69%。     

铁屑粉煤灰组合处理含磷废水

实验研究了铁屑粉煤灰组合处理含磷废水的除磷效果.通过单因素实验,考查了铁屑粉煤灰质量比、反应时间、pH值和投加量对除磷效果的影响.实验结果表明,该法除磷的最优条件为铁屑和粉煤灰的质量比为2∶1,反应时间为20 min,pH值为6,投加量为20 g/L.在最优实验条件下磷的去除率达到了97.5％.对比了该法和粉煤灰吸附法与传统铁屑法的除磷效果.与单一粉煤灰吸附法和传统铁屑法除磷的结果相比较,铁屑粉煤灰组合除磷的方法具有明显优势.     

鸟粪石沉淀法去除酿酒废水中磷的研究

以氧化镁和硫酸镁作为镁源采用鸟粪石(MAP)沉淀法对酿酒废水开展了除磷实验研究,考察不同因素对TP去除效果的影响。结果表明:除磷效果影响因素重要性排序为pH转速Mg~(2+)与P的摩尔比。以氧化镁为镁源时,MAP沉淀法的最佳反应条件为pH=10.0,转速150r/min,Mg~(2+)与P摩尔比为1.2;以硫酸镁为镁源时,MAP沉淀法的最佳反应条件为pH=10.0,转速50r/min,Mg~(2+)与P摩尔比为1.0。正交实验与单因素实验结果基本一致,最佳条件下TP去除率均可达90%以上。受酿酒废水矿物成分影响,MAP沉淀中的MgNH_4PO_4·6H_2O纯度较低,综合考虑,采用MAP沉淀法去除酿酒废水中的磷时宜选用氧化镁作为镁源。     

MAP法沉淀回收装置的运行条件优化研究

采用一种简易的MAP回收装置,研究了间歇运行条件下反应时间和曝气量对MAP法除磷效果的影响,确定出最佳反应时间为90 min,最佳曝气量为1.2 L/min,相应的除磷率可达98.26%,沉淀回收率为74.54%。当增加一个漏斗形隔板分离反应区和沉淀区并连续运行时,除磷率和沉淀回收率分别为92.11%和63.66%。当不投加镁盐和铵盐而仅调控实际污泥脱水滤液的pH值为9.8时,其连续运行的平均除磷率和MAP回收率分别可达95.16%和70%,运行性能比较稳定。     

改性蛭石结合鸟粪石沉淀法回收垃圾渗滤液中氨氮的实验研究

研究了使用氯化镁改性蛭石,利用磷酸铵镁沉淀的原理,在垃圾渗滤液中按比例加入PO43-,处理垃圾渗滤液中氨氮的同时,在蛭石上生成磷酸铵镁沉淀,以便于磷酸铵镁沉淀的回收利用。结果表明,筛取蛭石粒径为60～80目,配制浓度20%的氯化镁溶液浸泡改性蛭石20 min,取25 g改性蛭石,100 mL垃圾渗滤液调节pH为9,按n(NH4+)∶n(PO34-)=1∶1.2的比例加入PO43-离子,垃圾渗滤液中氨氮去除率为85.06%,实验并对磷酸铵镁沉淀进行了结构成分分析,为垃圾渗滤液中氨氮的处理及磷酸铵镁沉淀的回收提供了一种新的方法。     

Nutrients removal and recovery by crystallization of magnesium ammonium phosphate from synthetic swine wastewater

With synthetic swine wastewater, lab-scale batch experiments were carried out to investigate the effects of pH value, magnesium dosage, calcium and carbonate concentrations on magnesium ammonium phosphate (MAP) crystallization. The morphology of the precipitates obtained was observed by using scanning electron microscopy with energy dispersive X-ray analysis, and the composition of the precipitates was analyzed with X-ray diffraction. The results show that the optimum pH value for MAP crystallization is in the range of 9.5-10.5; the phosphorus removal efficiency increases with the increase of Mg/P molar ratio; the optimum Mg/P molar ratio is 1.4, and excessive Mg dosage does not show significant effect on the efficiency improvement of MAP crystallization; the co-existing of Ca in solution disturbs the morphology and purity of the MAP product, and amorphous calcium phosphate will form when Ca increases to a certain concentration; CO3(2-) can affect the P removal efficiency, but does not obviously affect the morphology and purity of MAP.     

共存杂质对磷酸铵镁结晶法回收磷的影响研究

研究用磷酸铵镁（MAP）结晶法去除、回收废水中的磷，分析含磷废水中各类共存杂质对MAP法去除、回收磷的影响。结果表明，废水中无机钙离子的存在可提高磷的去除率，而大分子有机物杂质的存在会使磷的去除率显著降低，小分子有机物对磷的去除基本无影响。在反应体系中引入外来晶种烟煤、石英砂和铁屑可显著提高低浓度含磷废水磷的去除效率，其中娴煤作为晶种的效果最明显。     

Repeated use of MAP decomposition residues for the removal of high ammonium concentration from landfill leachate

The residues of magnesium ammonium phosphate (MAP) decomposed by heating under alkali conditions were repeatedly used as the sources of phosphate and magnesium for the removal of high ammonium concentration from landfill leachate. Up to 96% of ammonium in MAP powder could be released under the following conditions: NH4(+):OH- molar ratio, 1:1; temperature, 90 degrees C; heating time, 2 h. Fourier transform infrared spectra and X-ray diffraction analysis of MAP before and after heating demonstrated that MAP was mainly transformed to amorphous magnesium sodium phosphate (MgNaPO4), which makes it possible for the NH4(+) to replace Na+ in MgNaPO4 to form more stable struvite. Successful ammonium removal was achieved by using the MAP decomposition residues as the sole phosphate and magnesium sources. The ammonium removal decreased gradually following the increase of MAP reuse cycles, and in the 6th cycle, ammonium removals of 84% and 62% were achieved for synthetic wastewater and landfill leachate, respectively. Analysis of the surfaces of MAP powders acquired at different reuse cycles using scanning electron microscopy with energy dispersive X-ray suggested that the existence of calcium, kalium and aluminum ions in landfill leachate might have inhibited the formation of MAP through competition with ammonium ions for phosphate ions. It is estimated that reuse of MAP for 3 cycles could save about 44% chemical costs.     

The Effects of Magnesium and Ammonium Additions on Phosphate Recovery from Greenhouse Wastewater

Phosphorus recovery from greenhouse wastewater, using precipitation-crystallization, was conducted under three levels of calcium concentration, 304 mg/L (7.6 mmol/L), 384 mg/L (9.6 mmol/L), and 480 mg/L (12 mmol/L), and also with additions of ammonium and magnesium into the wastewater. Jar test results confirmed high phosphate removal, with more than 90% of the removal achieved with a pH as low as 7.7. Under the low calcium concentration, ammonium addition affected the chemical reactions at pH lower than 8.0, where struvite was produced; when the pH was raised to 8.8, other calcium compounds dominated the precipitation. Under the medium calcium concentration, ammonium and magnesium addition helped struvite precipitation in the low pH range. Hydroxyapatite (HAP) was the main product. Under the high calcium concentration, ammonium addition showed no effects on the precipitation.     

The effects of magnesium and ammonium additions on phosphate recovery from greenhouse wastewater

Phosphorus recovery from greenhouse wastewater, using precipitation-crystallization, was conducted under three levels of calcium concentration, 304 mg/L (7.6 mmol/L), 384 mg/L (9.6 mmol/L), and 480 mg/L (12 mmol/L), and also with additions of ammonium and magnesium into the wastewater. Jar test results confirmed high phosphate removal, with more than 90% of the removal achieved with a pH as low as 7.7. Under the low calcium concentration, ammonium addition affected the chemical reactions at pH lower than 8.0, where struvite was produced; when the pH was raised to 8.8, other calcium compounds dominated the precipitation. Under the medium calcium concentration, ammonium and magnesium addition helped struvite precipitation in the low pH range. Hydroxyapatite (HAP) was the main product. Under the high calcium concentration, ammonium addition showed no effects on the precipitation.     

Removal of nitrogen and phosphate from wastewater by addition of bittern

Removal of nitrogen and phosphate through crystallization of struvite (MgNH(4)PO(4).6H(2)O) has gained increasing interest. Since wastewaters tend to be low in magnesium relative to ammonia and phosphates, addition of this mineral is usually required to effect the struvite crystallization process. The present study evaluated the feasibility of using bittern, a byproduct of salt manufacture, as a low-cost source of magnesium ions. High reaction rates were observed; the extent of nitrogen and phosphorus removals did not change beyond 10 min. Phosphorus removals from pure solutions with bittern added were equivalent to those obtained with MgCl(2) or seawater. Nitrogen removals with bittern were somewhat lower than with the alternate Mg(2+) sources, however. Application of bittern to biologically treated wastewater from a swine farm achieved high phosphate removal, but ammonia removals were limited by imbalance in the nitrogen:phosphorus ratio.     

铁炭微电解-MAP沉淀法联合预处理垃圾渗滤液

采用铁炭微电解-磷酸氨镁(MAP)沉淀法对垃圾渗滤液进行预处理,实验结果表明,铁炭比为5∶1,pH值为3,反应时间为3 h时,铁炭微电解的COD的去除率为47.5%;在投加药剂n(Mg2+)∶n(PO43-)∶n(NH4+)为1.4∶1∶1,pH值为9,反应时间为1 h的条件下,垃圾渗滤液氨氮去除率达到79.7%。     

鸟粪石结晶法回收垃圾渗滤液氨氮研究

采用MgSO₄·7H₂O和Na₂HPO₄·12H₂O使NH₃-N生成MgNH₄PO₄·6H₂O（鸟粪石）结晶沉淀法回收渗滤液中NH₃-N。考察了pH值、反应时间、药剂配比对NH₃-N去除率的影响。结果表明，鸟粪石结晶回收NH₃-N反应的适宜pH值为9～9.5之间，过高的pH会破坏鸟粪石晶体结构，导致固定氨从MgNH₄PO₄中游离出来，不利于氨氮的去除。在pH值为9.5、反应时间为25 min、Mg²⁺∶NH⁺₄∶PO^3-₄=1.5∶1∶1.5的最佳条件下，渗滤液中NH₃-N浓度由初始3 500 mg/L,经结晶沉淀后降低至175 mg/L，去除率达95%。鸟粪石结晶沉淀过程中几乎不吸收重金属，同时回收了氨氮，其沉淀产物鸟粪石是一种优良的缓释肥原料。     

厌氧产氢ASBR对氮的脱除

在厌氧序批式人工有机污水生物产氢反应器(ASBR)中发现氮"丢失"现象,并对此产氢系统发生脱氮作用的机理和主要影响因素进行了研究。结果表明,在以葡萄糖为发酵底物的厌氧产氢系统中,微生物分别以铵和硫酸盐为电子供体和电子受体发生了硫酸盐型厌氧氨氧化;进水有机物负荷和pH主要通过影响不同种微生物的活性而影响脱氮性能,氨氮和硫酸盐的浓度直接与氮素去除率有关。在最大产氢能力为16 m3/(m3·d)、氢气体积百分比为65%的生物制氢系统中,最大脱氮效率约为64%。产氢效率与氮脱除率呈现负相关关系。研究表明,在控制条件下,可以实现高有机物废水厌氧脱除氨态氮,为生活污水直接厌氧脱氮开辟一条新途径。