连续式泡沫分离法去除废水中铬(Ⅲ)离子的动力学

采用铁盐共沉淀连续式泡沫分离法脱除废水中的铬(Ⅲ)离子,实验考察了pH值、Fe2+/Cr(Ⅵ)摩尔比、十二烷基苯磺酸钠(SDBS)浓度、空气流量、分离时间等因素的影响.结果表明,最佳分离工艺条件为,Fe2+/Cr(Ⅵ)摩尔比5∶1,pH值9.0,空气流量450 mL/min,SDBS浓度60 mg/L,分离时间30 m...     

内循环式泡沫浮选塔处理含铬废水

采用自制的内循环泡沫浮选塔处理含铬废水,考察pH值、Fe(NO3)3浓度、十二烷基硫酸钠(SDS)浓度、气体流量、分离时间等因素对分离效率的影响,并与常规泡沫塔比较. 结果表明,在12~35 min内,内循环式浮选塔分离效率更高,35 min时塔内铬离子浓度为0.6 mg/L,常规泡沫塔内铬离子浓度为10 mg/L. 内循环浮选塔最佳分离工艺条件为,对初始铬浓度为20 mg/L的废水,在pH 5.5、SDS 100 mg/L、Fe(NO3)3 60 mg/L、气体流量800 mL/min条件下处理效果最好,泡沫夹带率约为10%,Cr(III)脱除率可达97%以上.     

泡沫分离法处理结晶紫染料废水的工艺

以结晶紫模拟染料废水为研究体系,对泡沫分离法脱除结晶紫染料废水色素的工艺进行了研究,考察了以表面活性剂十二烷基苯磺酸钠(SDBS)为捕收剂时,pH、气体流速、表面活性剂浓度、装液量对脱色效果的影响,利用正交实验确定了优化操作条件. 结果表明,当pH为11.0、气速0.018 m3/h、SDBS浓度450 mg/L、装液量500 mL时,富集比为10.3,废水中结晶紫脱色率为93.5%.     

含铜和含锌稀溶液的吸附泡沫分离技术的研究

运用自制的泡沫分离塔,以十二烷基硫酸钠为表面活性剂对泡沫吸附分离含铜及含锌溶液的操作参数进行了研究。考察了料液浓度、pH值、气体流量、表面活性剂浓度等因素对含铜和含锌溶液泡沫分离效果的影响。结果表明：最佳操作参数为pH值5．0,料液浓度0．125mmol／L,进料流速50mL/min,气体流量100mL/min,表面活性剂浓度0．25mmol／L。同时从理论上推算出泡沫吸附分离铜离子的最佳pH值范围为5．0左右。实验还通过改变孔板的孔径大小以改变气泡的尺寸,特别研究了泡沫尺寸对泡沫吸附分离的影响。     

卧式加压溶气泡沫分离水溶液中低含量蛋白质

以大豆蛋白为目标蛋白,蛋白水溶液为模拟体系,采用卧式加压溶气泡沫分离装置考察了原料液流量、pH值、溶气水流量等因素对蛋白质脱除率的影响,并根据其分子结构特征从过程工程视角分析了以卧式泡沫分离装置由水中去除的优势.结果表明,最佳操作条件为:原料液浓度8mg/L,原料液流量50L/h,pH值4.5,溶气水流量275L/h,该条件下水中蛋白质的脱除率可达90.5%.     

泡沫分离法脱除铜离子色素工艺

在水溶液中,相当一部分色素在一定条件下带正电荷或负电荷,因此文中以水溶液中的铜离子为色素研究体系,十二烷基硫酸钠(SDS)为起泡剂,探索泡沫分离法脱除水溶液中离子色素的工艺。单因素实验研究了铜离子色素脱除率和富集比随pH值、鼓泡气体流量、表面活性剂质量浓度及泡沫塔装液量的变化规律和机理,结果表明,十二烷基硫酸钠对泡沫分离法脱除铜离子色素具有良好的效果。在此基础上通过正交实验得到最佳操作工艺为:pH值5.0,气体流量80 mL/min,表面活性剂质量浓度0.15 g/L,装液量220 mL,此工艺下铜离子色素脱除率为99.4%,富集比为20.8。     

大豆蛋白废水中乳清蛋白的泡沫分离实验

采用泡沫分离法回收大豆蛋白废水中蛋白,考察了pH值、气体的流速、进料浓度、液柱和泡沫层高度等因素对分离效果的影响.低进气速度、高泡沫层高度、适当的pH值以及低进料浓度有利于较好的分离.结果表明:当进料浓度为0.54 g/L、pH值为5、泡沫层与液池高度比4∶1,通气量为15.0 L/h 时,富集比可以达到3.25;当进料浓度为0.54 g/L、pH值为5、泡沫层与液池高度比3∶1,通气量为15.0 L/h,此时脱除率可以达到48.5%.     

连续式泡沫分离法去除废水中Cr~(3+)的研究

采用连续式泡沫分离法分离废水中的Cr3+离子。考察了废水的pH、表面活性剂的加入量、空气流量和反应时间对Cr3+的脱除率的影响,确定最佳的操作工艺条件为混合废水pH=6.0、空气流量350 mL/min、表面活性剂质量浓度为170 mg/L、反应时间为30 min,此时Cr3+的脱除率可达95.31%,浮选塔排出的残液中Cr3+的质量浓度0.5 mg/L,完全符合排放标准。     

荷电膜去除水中表面活性剂十二烷基苯磺酸钠研究

采用自制等离子体改性聚砜荷电膜对表面活性剂十二烷基苯磺酸钠(SDBS)进行截留测试,通过改变溶液的初始SDBS质量浓度(40～400 mg· L-1)、操作压力(0.15～0.35 MPa),离子强度(NaCl质量浓度100～300 mg·L-1)以及pH(2～12)等影响因素,观察荷电膜对SDBS溶液的截留率以及通量的变化,分析作用机理.结果表明,静电斥力为主要作用力,同时伴有机械筛分作用.初始SDBS含量低时比高时截留效果好,SDBS初始质量浓度为40 mg· L-1时截留率可达85.68％;低离子强度时静电斥力发挥主要作用,截留率比高离子强度时高;压力越大,截留率越高;溶液pH接近中性时截留效果最好.     

泡沫分离-Fenton氧化工艺处理表面活性剂废水

采用泡沫分离-Fenton氧化工艺进行处理某炼油公司含SDBS和Brij30废水,研究了气体流速、废水流速、塔内液体高度、pH和Fenton试剂用量对处理效果的影响。得到了优化后的工艺条件为:Fenton试剂用量0.05 mol/L,气体流速0.054~0.072 m3/h,分离塔内液体量为1.8~1.9 L,废水流速2.0~2.2 L/h,Fenton氧化处理pH=3~4。在此最佳工艺基础上进行了工业侧线实验,实验表明,采用泡沫分离-Fenton氧化工艺可将废水中SDBS和Brij30分别降至2 mg/L和5 mg/L以下。     

Study on Riboflavin Recovery from Wastewater by a Batch Foam Separation Process

Abstract

A batch recovery of riboflavin via foam separation from industrial simulative wastewater was studied using a cationic surfactant, cetyltrimethyl ammonium bromide (CTAB). The experimental parameters examined were the surfactant concentration, air flow rate, pH, and foam height. Under optimal operating conditions obtained through an orthogonal experiment, the maximum enrichment ratio of 48.7 was achieved for riboflavin along with 99.3% removal efficiency. The optimal operating conditions had the concentration of CTAB at 0.3 g/L, air flow rate at 400 ml/min, foam height at 90 cm, and pH at 12. Therefore foam separation proved to be an effective method to recover the riboflavin in terms of the good enrichment and removal efficiency.     

Surfactant Recovery by Foam Fractionation using the Gas-Liquid Contactor,Emulsion Venturi

Sodium dodecylbenzene sulfonate (SDBS), an anionic surfactant, was removed from its aqueous solution by foam fractionation in an emulsion venturi, a gas-liquid contactor functioning in self-aspiration. The performance of the reactor was evaluated by measuring the self-aspired gas flow and the mass transfer coefficient in the presence and the absence of SDBS. Data confirmed that both the gas flow self-aspired and the mass transfer coefficient increased with increasing the recirculated liquid flow. However, the presence of SDBS decreased the mass transfer capacity of the reactor influencing self-aspiration capacity in a positive manner. The percentage removal of SDBS in the emulsion venturi increased with increasing the recirculated liquid flow; at the highest liquid flow value used in this work (1.4 m³/h), 96% of SDBS was removed from the solution after 20 min of foam operating. The process was dependant on initial surfactant concentration. Neutral pH and temperature of 25°C were the optimal conditions for the foam separation of SDBS in the emulsion venturi.     

Removal of motor oil by continuous multistage froth flotation: Effect of operational parameters

A continuous multistage froth flotation column was employed to remove motor oil from water at a low concentration (500 mg/L) using an extended surfactant – branched alcohol propoxylate sulphate sodium salt (C_14-15–8PO–SO₄–Na) – as a frother. The highest separation efficiency (97% motor oil removal with the enrichment ratio of 16 for motor oil) was obtained at a foam height of 60 cm, an air flow rate of 40 L/min, a feed flow rate of 60 mL/min, a surfactant concentration of 0.3% (w/v), and an NaCl concentration of 1.5% (w/v). The process performance increased with increasing tray number but beyond 4 trays, the system could only offer lower concentrations of motor oil and surfactant in the effluent.     

Removal of Trace Cd2+ Using Continuous Multistage Ion Foam Fractionation: Part II—The Effects of Operational Parameters

A multistage ion foam fractionation column with bubble-cap trays was employed to study the removal of cadmium ions from simulated wastewater having low Cd concentrations (10–30 mg/L), examining the effects of foam height, air flow rate, feed flow rate, and feed Cd concentration. Sodium dodecyl sulfate (SDS) was used to generate foam in this study. An increase in foam height, which reduces liquid hold-up in the generated foam, resulted in the enhancement of the enrichment ratios of both SDS and Cd while the removal and residual factor of Cd showed insignificant change. An increase in air flow rate increased the foam generation rate, foamate volumetric ratio, and the removal efficiency of Cd but decreased the enrichment ratios of both Cd and SDS. The separation factors of both Cd and SDS decreased with increasing feed flow rate, which is mainly attributable to both the effects of the enhancement of foamate volumetric ratio and the increases in both SDS and Cd input rates. An increase in feed Cd concentration was found to increase Cd effluent concentration and SDS removal but to decrease the enrichment ratios of both Cd and SDS because of the increasing liquid entrainment in the produced foam.     

Simultaneous treatment of dye wastewater and surfactant wastewater by foam separation: Experimental and mesoscopic simulation study

Foam separation for simultaneous removal of rhodamine B (RhB) and cetyl trimethyl ammonium bromide (CTAB)/sodium dodecyl benzene sulfonate (SDBS) from model wastewater was studied. The effect of the surfactant type, aeration rate, temperature, and initial pH on the removal efficiency and enrichment ratio of dye/surfactant were investigated. The results indicated that electrostatic attraction between the dye and surfactant have a great effect on the recovery of the dye and surfactant. The aeration rate has significant influence on the CTAB and RhB removal and enrichment, while the initial pH has a great effect on the RhB removal, but little effect on CTAB removal. Moreover, dissipative particle dynamics (DPD) was employed to simulate the interaction between the surfactant and the dye.     

纳米颗粒作为稳泡剂泡沫分离酪蛋白的工艺

为了增强乳制品废水中低浓度酪蛋白（casein，CS）的泡沫性能进而提高其泡沫分离效果，首先采用十二烷基二甲基甜菜碱（dodecyl dimethyl betaine，BS12）改性疏水二氧化硅纳米颗粒（silica nanoparticle，SNP），以制备接触角为61.6°±3.1°的部分疏水二氧化硅纳米颗粒（BS12-SNP），分别从静态和动态泡沫性能两个角度来研究BS12-SNP作为稳泡剂的功效。实验结果表明，BS12-SNP作为稳泡剂可以抑制泡沫排液和泡沫聚并，进而增强20.0～60.0mg/L酪蛋白的泡沫稳定性。与不添加BS12-SNP相比，添加BS12-SNP后的酪蛋白废水泡沫半衰期最大可提高6.5倍。泡沫分离实验表明，在BS12-SNP浓度50mg/L、气速250mL/min、装液量500mL的条件下，上述浓度范围内的酪蛋白回收率最高可达94.2%，此时富集比为12.3。本文开发了一种表面功能化纳米颗粒代替表面活性剂的泡沫分离工艺，实现了废水中酪蛋白的有效回收。