用离子交换法从β盐母液中分离1-萘磺酸钠的研究

比较了Ｄ２９０、Ｄ２９６、Ｄ３０１、Ｄ３７０、Ｄ３７２、Ｄ３８０ ６种树脂对β盐母液中１－萘磺酸的静态交换性能,筛选出Ｄ２９６用以回收β盐母液中的１－萘磺酸钠,进行了ＰＨ、接触时间、交换温度等影响因素的条件试验及树脂再生试验,得到１－萘磺酸钠收率８０％以上。     

树脂吸附法处理分散蓝NKF脱磺母液

对NDA－9大孔吸附树脂吸附法处理分散蓝NKF生产过程中产生的脱磺母液（废水）进行了研究。在试验条件下，废水经吸附处理后COD由7500mg/L以上降至700mg/L以下，去除率达90％以上，树脂的脱附率大于98％。吸附出水经Fenton试剂氧化处理后，出水COD降至100mg/L以下，去除率达98％以上。     

苯基周位酸生产废水处理试验研究

采用CHA－111大孔吸附树脂对苯基周位酸生产过程排放的汽提苯胺盐析废水和苯基周位酸酸析母液进行处理试验,效果良好。汽提苯胺盐析废水苯胺质量浓度＞1600mg／L,经树脂吸附处理后苯胺质量浓度＜2mg／L,苯胺去除率＞99．9％,COD去除率＞97％,树脂工作吸附量达120g／L,脱附率＞98％;苯基周位酸酸析母液经树脂吸附、混凝沉淀处理后,苯基周位酸质量浓度＜190mg／L,苯基周位酸去除率为94．8％,COD去除率为94．3％,氨基值去除率为80％,脱附率＞99％。     

树脂吸附法处理对氨基苯酚废水

采用自制的NDA-99特种复合功能树脂处理对氨基苯酚（PAP）生产废水，考察了各种因素对吸附和脱附效果的影响。小试实验结果得出的工艺条件为：吸附流量2．0BV／h，吸附温度15℃，单柱吸附量10BV；脱附剂为2BV盐酸（质量分数1．5％）＋2BV水。中试试验结果表明，在上述工艺条件下，NDA-99树脂处理PAP废水的吸附性能和脱附性能稳定，平均COD去除率约为93％，平均PAP脱附率达98％。     

用棉籽油皂脚制备棉籽油甲酯

以002CR型阳离子交换树脂为催化剂，在固定床反应器中用高酸值棉籽油皂脚制备棉籽油甲酯，考察了各种因素对酯化反应的影响。实验结果表明，在甲醇与脂肪酸摩尔比为2、反应温度为60℃、停留时间为80min的条件下，酯化率为94．67％。工业化生产中可选用经脱水处理后的工业甲醇为原料，以降低生产成本。所得棉籽油甲酯的收率为90％，主要性能指标基本达到美国生物柴油标准要求。     

旋转填充床中催化氧化脱硫的试验研究

对在新型强化传质设备－旋转填充床中用Mn^2 催化氧化脱除烟气中SO2的工艺进行了试验研究,其脱硫率可达99％,比传统设备的氧化脱硫率提高4％－69％。该设备体积小,操作简单,具有工业化应用前景。     

强碱性离子交换树脂再生新工艺的研究

用还原性的硫酸亚铁溶液作为再生剂，对吸附Cr^6 的强碱性离子交换树脂的再生机理进行了初步的探讨和再生工艺的研究，试验结果表明，用硫酸亚铁溶液作为再生剂，可以降低铬离子对树脂骨架的破坏，再生效率可以保持在0．85以上，再生工艺条件如下：再生剂硫酸亚铁溶液的浓度为0．5－1．0mol/L，用量为树脂体积的3－5倍，PH为1－2，流速为2－4m/h，再生温为25－45℃。     

离子交换树脂法吸附分离水中的邻二甲苯-4-磺酸

采用阴离子交换树脂吸附分离水中的邻二甲苯-4-磺酸。实验结果表明:201×7型阴离子交换树脂(简称树脂)对邻二甲苯-4-磺酸有很强的吸附能力,即使在4 mol/L NH_4Cl存在的情况下,树脂对邻二甲苯-4-磺酸的静态吸附率仍超过90%;适宜的动态吸附—解吸条件为吸附液流速为0.50 L/h、吸附液体积2 L,用含60%(质量分数)乙醇和1 mol/L盐酸的解吸剂解吸、解吸剂流速1.0 L/h、解吸剂体积1.5 L;该方法可有效回收水中的邻二甲苯-4-磺酸。     

DS—Ⅱ催化剂脱硫脱氮技术的实验研究

以纯SO2及燃煤电厂烟气作实验气,利用积分法固定床CFB方式进行了DS－Ⅰ型催化剂与活性炭催化性能的对比试验,对不同还进行了不同烟气温度、SO2浓度、湿度、烟气流速等工艺参数对DS－Ⅰ型催化剂催化性能的影响试验。对不同催化剂进行优化组合,可在除尘器后直接脱硫、脱氮、其脱硫率达86％、脱氮率达68％。催化剂经再生,可反复使用。     

脂肪磺酸基阳离子交换树脂对Cr3+的吸附和解吸性能

研究了脂肪磺酸基阳离子交换树脂（简称树脂）对Cr3＋的吸附和解吸性能。在溶液初始Cr3＋质量浓度为250m∥L、吸附温度为25℃、溶液pH为5的条件下，树脂对Cr3＋的吸附量最大。Cr3＋质量浓度在实验范围内，等温吸附过程均符合Langmuir和Freundlich方程，最大吸附量为18．6208mg／g。树脂对Cr3＋的吸附在吸附时间为180min时趋于平衡，且吸附为液膜扩散控制。随吸附温度的升高（10～55℃），树脂对Cr3＋的吸附量略有增加。用质量分数为5％的HCl溶液可将吸附在树脂上的Cr3＋解吸，解吸率近100％，且重复5次吸附和解吸过程，树脂对Cr3＋的吸附量基本保持不变。     

阳离子交换树脂生产中废酸的回收利用及树脂质量控制

采用 酸套洗工艺代替传统的加水稀释洗涤工艺，成功地解决了阳离子交换树脂生产中废酸的回收利用问题，研究了采用新洗涤工艺后树脂变红的机理和防止对策，结果表明，树脂发红帅微生物的参与而引起的。采以完善洗涤 灭菌措施可防止树脂 ，从而确保了稀酸套洗工艺的顺利实施。     

强碱性阴离子交换树脂对苦味酸的吸附与解吸性能

研究了强碱性阴离子交换树脂(简称树脂)对苦味酸的吸附与解吸性能,探讨了吸附的热力学和动力学特性以及吸附机理.实验结果表明:树脂对苦味酸的吸附量随吸附温度升高而增大；溶液pH为2.7 ～12.0时树脂的苦味酸吸附量最大,稳定在120 mg/g以上；树脂对苦味酸的等温吸附规律符合Freundlich模型,相关系数大于0.9...     

Converting Waste Polystyrene into Adsorbent: Potential Use in the Removal of Lead and Cadmium Ions from Aqueous Solution

Waste of polystyrene was converted into a cation exchange resin and was used for the removal of lead and cadmium metals from aqueous solution. Wastes consisting of coffee cups were crushed into small pieces and immersed into a solution of sulfuric acid in order to attach sulfonic group to polymer chain, these groups are responsible for the exchange properties of the modified plastic. The cation exchange capacity (CEC) was determined and was comparable to commercial exchangers. The adsorption isotherms of resin with synthetic wastewater containing lead and cadmium ions were tested. Adsorption analysis results obtained at various concentrations showed that the adsorption pattern on the resin followed Langmuir isotherms.     

离子交换树脂D001对罗丹明B的吸附特性

采用强酸性阳离子交换树脂D001作为吸附剂吸附脱除水溶液中的罗丹明B(Rh B)。SEM和FTIR表征结果显示:D001树脂表面存在孔隙,可增加树脂的比表面积;树脂表面的磺酸基团可通过与阳离子染料Rh B络合而将其吸附。实验结果表明:Langmuir等温吸附模型能更好地描述树脂对Rh B的吸附规律,升高温度有利于树脂吸附Rh B;吸附过程符合Lagergren准一级动力学方程,初始Rh B质量浓度为20 mg/L时吸附活化能为7.06 k J/mol;树脂对Rh B的吸附是一个自发的、吸热的、熵推动的过程;颗粒扩散为吸附过程的控制步骤;树脂具有良好的重复使用性能。     

几种焦化废水深度处理技术的比较

分别采用Fenton试剂氧化法、固定床离子交换树脂吸附法和流化床磁性树脂吸附法对某焦化厂焦化废水生化工艺出水进行深度处理.试验结果表明:Fenton试剂氧化法处理后出水COD去除率最高达75.4％,色度去除率达89.1％;固定床离子交换树脂吸附法COD去除率为49.4％,色度去除率为96.5％;流化床磁性树脂吸附法COD去除率为58.2％,色度去除率为90.2％.Fenton试剂氧化法COD去除率较高,固定床离子交换树脂吸附法和流化床磁性树脂吸附法色度去除率较高.综合考虑,Fenton试剂氧化法具有更高的工程应用价值.     

Treatment of chromium plating process effluents with ion exchange resins.

The surface treatment industry deals with various heavy metals, including the elements Cr, Zn, Ni, Cd, and Cu. Conventional treatments of effluents generate class I solid residue. The aim of this investigation was to study the viability of ion exchange as an alternative process for treatment of rinse water and to determine the efficacy of two ion exchange systems, System 1: "strong" cationic resin-"strong" anionic resin and System 2: "strong" cationic resin-"weak" anionic resin. Commercial resins and solutions taken from rinse tanks of chromium plating companies were used in this investigation. A two-column system, one for the cationic resin and another for the anionic resin, both with 150 ml capacity was mounted. The solution was percolated at a rate of 10 ml/min. The following solutions were used for regeneration of the resins: 2% H2SO4 for the cationic and 4% NaOH for the anionic. The percolated solutions revealed chromium contents of less than 0.25 mg/l, independent of the system used. The "strong" cationic resin-"weak" anionic resin gave excellent regeneration results. The "strong" cationic-"strong" anionic resin presented problems during regeneration, and did not release the retained ions after percolation of 2000 ml of 4% NaOH solution. It is concluded that for this type of treatment, the system composed of "strong" cationic resin and "weak" anionic resin is more appropriate.     

Effects of competitive ions,humic acid,and pH on removal of ammonium and phosphorous from the synthetic industrial effluent by ion exchange resins

The removal of the ammonium and phosphorous from the synthetic industrial effluent by the ion exchange resins was studied in this paper, aiming at the determination of the effects of competitive ions, humic acid, pH and resin amount. The kinetic experiments show that the equilibrium time for the removal of both contaminants in the absence and presence of the competing matters was 4 h. Na+ and K+ significantly reduced the ammonium removal percentage, while the existence of Mg2+, Ca2+ and humic acid also had a negative influence. Adsorption of ammonium ions in both absence and presence of Na+ and K+ observed the linear isotherm, however, it did not follow commonly used isotherms in the presence of Na+, K+, Mg2+, Ca2+ and humic acid. The phosphorous removal decreased in the presence of the competitive matters, such as Cl-, CO3(2-), SO4(2-) and humic acid. Higher pH can cause higher phosphorous removal percentage. A decrease in the solution pH was observed in the phosphorous removal experiments, possibly due to the ion exchange and the adsorption of OH-. Uptake of humic acid by the resins was observed. Finally, a series of fixed-bed experiments were performed, showing that the performance was dependent on the empty bed contact time (EBCT). Higher EBCT would cause higher bed volumes of both treated ammonium and phosphorous.     

火电厂离子交换树脂再生废水处理及减排

针对火电厂离子交换树脂再生废水中和处理过程中遇到的问题，探讨影响中和处理的因素，并提出减少火电厂离子交换树脂再生废水排放的措施.     

乙烯废碱液的再生

开发了除油-苛化-脱硫组合技术处理乙烯废碱液工艺,考察了影响各级处理效果的主要因素.实验结果表明:经石英砂-聚丙烯腈纤维膜-强碱性阴离子交换树脂组合装置除油后,碱液中油类物质质量浓度小于2 mg/L,NaOH,Na_2CO_3,Na_2S等无机组分含量基本不变;经苛化-脱硫处理后碱液中Na_2CO_3和Na_2S质量浓度分别小于4 430 mg/L和4 480 mg/L;再生碱液的流体力学性质及对酸性气体的吸收性能均可满足乙烯裂解气碱洗要求.     

Ion exchange resin for PFAS removal and pilot test comparison to GAC

Amec Foster Wheeler and Emerging Compounds Treatment Technologies, Inc. tested pilot‐scale ex situ treatment technologies for treatment of poly‐ and perfluorinated alkyl substances (PFAS) in groundwater. The pilot test compared ion exchange resin to granular activated carbon (GAC) and evaluated in‐place regeneration of the resin to restore PFAS removal capacity. During the pilot test, both resin and GAC removed perfluorooctane sulfonate (PFOS) and perfluorooctanoic acid (PFOA) below U.S. Environmental Protection Agency (USEPA) health advisories (HAs) of 0.070 micrograms per liter (μg/L) combined. Compared at a common empty bed contact time (EBCT) of five minutes, the resin treated over eight times as many bed volumes (BVs) of groundwater as GAC before PFOS exceeded the USEPA HA and six times as many BVs for PFOA. On a mass‐to‐mass basis, resin removed over four times as much total PFAS per gram as GAC before breakthrough was observed at the USEPA HA. A solution of organic solvent and brine was used to regenerate the resin in the lead vessel, which had treated water up to the point of PFOS and PFOA breakthrough exceeding the USEPA HAs. The pilot test demonstrated successful in‐place regeneration of the resin to near‐virgin conditions. The regenerated resin was then used to treat the contaminated groundwater up to the same breakthrough point. Compared to the virgin resin loading cycles, PFAS removal results for the regenerated resin were consistent with virgin resin.