沉淀法回收聚苯乙烯泡沫塑料的工艺研究

研究沉淀法回收聚苯乙烯泡沫塑料(EPS)的工艺,利用石油裂解副产物为溶剂回收废旧聚苯乙烯泡沫塑料,以废治废,回收利用。溶剂低毒,对聚苯乙烯泡沫塑料溶解速度快,溶解量大,价廉易得。采用转式间歇投料并附加溶剂挥发分回收装置的工艺,溶剂回收率高,无二次污染,可循环使用。聚苯乙烯塑料(PS)回收率可达99%。     

沉淀法回收聚苯乙烯泡沫塑料的工艺研究

研究沉淀法回收聚苯乙烯泡沫塑料（EPS）的工艺，利用石油裂解副产物为溶剂回收废旧聚苯乙烯泡沫塑料，以废治废，回收利用。溶剂低毒，对聚苯乙烯泡沫塑料溶解速度快，溶解量大，价廉易得。采用转式间歇投料并附加溶剂挥发分z收装置的工艺，溶剂回收率高，无二次污染，可循环使用。聚苯乙烯塑料（PS）回收率可达99％。     

硝基修饰的超高交联树脂对酚类化合物的吸附研究

对超高交联聚苯乙烯树脂进行硝基修饰,制得硝基修饰超高交联聚苯乙烯树脂JN-5(简称JN-5).JN-5树脂具有比表面积高、亲水性强等优点.对酚类化合物在水溶液中进行静态吸附研究,平衡吸附试验数据和吸附热力学计算结果都表明,JN-5对4种酚类化合物(对甲基苯酚、苯酚、对氯苯酚、对硝基苯酚)的吸附性能优于大孔吸附树脂XAD-4.这主要得益于JN-5的高比表面积和丰富的微孔结构.动态小柱吸附试验中,在流速4.77mL/h、303K的条件下,JN-5对苯酚的穿透吸附量为2.43mmol/g,总吸附量为3.26mmol/g,吸附后的树脂能用8%(质量分数)的NaOH溶液完全洗脱.     

树脂固载纳米铁对偶氮染料直接湖蓝5B的脱色性能研究

以FeSO4和NaBH4水溶液为前驱溶剂,以聚苯乙烯型阳离子交换树脂为载体,制备了树脂固载的纳米铁,室温下用于对偶氮染料直接湖蓝5B水溶液进行脱色研究。研究结果发现,脱色反应遵循准一级反应动力学,在初始pH为3~10的范围内,反应进行14 m in时,50 mg/L的染料溶液脱色率均能达到83%以上。固载的纳米铁材料可多次重复利用,溶液中释放的铁离子浓度不超过0.1 mg/L。     

洗相废水中银回收技术研究

采用电解法和离子交换法回收洗相废水中的银.结果表明,电解法对高浓度含银洗相废水的银回收处理是一种行之有效的方法.对于中低浓度洗相废水中的银的回收,采用4%硫酸再生IRA-68离子交换树脂,树脂的交换能力可以增加4倍,再生时由于已交换的银被直接固定在树脂上,结果使得再生剂处置和银回收过程更加简单方便.IRA-68离子交换树脂回收中低浓度洗相废水中银的技术具有银回收效率更高、离子交换运行时间更长和操作更为简便等优点,使得传统的离子交换技术得到极大的改进和提高.     

吸附邻氯酚的超高交联树脂微波辅助再生研究

以NDA-150超高交联树脂为吸附剂,邻氯酚为吸附质,氢氧化钠稀溶液为脱附剂,采用微波间歇辐照的方法,对吸附氯酚树脂的再生过程进行了研究.系统分析了微波功率、辐照时间、碱液浓度对脱附效果的影响,并确定了最佳脱附条件.结果表明,微波辐照再生速度非常快.与传统热脱附不同,微波再生过程中脱附效率并不随碱浓度的增加而升高,微波辐照功率和辐照时间对脱附效果影响明显.树脂经多批次微波辐照,吸附性能和化学结构保持稳定.     

吸附树脂组合工艺对微污染水的净化处理效果研究

利用江苏省盐城市串场河水作为源水,在常规处理工艺对源水进行前处理的基础上,结合树脂吸附处理工艺探讨了新型吸附树脂对水源水的处理效果和树脂吸附剂的再生效果.结果表明,新型吸附树脂按照ZH-02、ZH-03和ZH-00的顺序进行组合,对经沉淀砂滤预处理后的饮用水源水中微污染有机化合物具有较好的去除效果,处理2 000 BV后需对树脂进行再生,用2～2.5 BV的醇碱在常温下脱附,元素分析结果表明脱附效果较好,对水源水进行深度处理的原料成本大约为3.9元/t.     

树脂-气升式环流生物反应器的脱氮性能

为了提高废水生物处理过程的脱氮性能,设计了树脂-气升式环流生物反应器,通过实验考察了该反应器连续抗氨氮冲击的能力,并验证了反应器中吸附铵离子的强酸阳离子树脂生物再生的可行性,分析了生物再生机理。结果表明,原水中铵离子之外的阳离子的存在是实现树脂生物再生的关键。     

盐液浸提辅助微波再生废油脱水树脂及机制分析

对用于废油脱水的聚丙烯酸钠树脂在盐液浸提辅助微波脱附再生过程中的脱附特性和再生使用性能进行了研究。实验结果表明,盐液浸提辅助微波处理的脱附速率是普通热处理的5～6倍,且能耗更低,脱附率更高,树脂床层温升速率更快,温度峰值却更低,说明盐液浸提对微波处理具有明显辅助效果;树脂再生性能测试结果表明,盐液浸提辅助微波处理的树脂再生使用性能最好,孔结构破坏更少。分析认为,微波选择加热特性以及盐液浸提导致树脂内外渗透压降低和方向改变是盐液浸提辅助微波处理具有良好脱附效果的关键机制。     

树脂法去除并回收富营养化河涌水中的磷

磷作为一种重要的元素而被广泛应用于农业与工业中,然而磷的过量排放已成为许多封闭半封闭水体富营养化和沿海赤潮频繁发生的原因之一.去除水体中的营养盐特别是磷酸盐,是有效控制水体富营养化的关键.广州市某河涌水含总磷2.6 mg/L,采用并选择DS离子交换树脂对水中磷进行动态吸附和去除,可使水中的磷降至排放标准以内,解决河涌水含磷高的富营养化问题.由DS树脂所吸附的磷,通过淋洗可得到含磷富集液,使磷从水体中完全分离出来并获得回收.DS树脂的再生能力强,经6次吸附-解吸-再生后,树脂对河涌水中磷的去除率仍可达到90％以上.     

Sorption studies of heavy metal ions on a novel chelating resin and its application in the stripping of mercury (II)

A chelating resin containing a stable thiol group was synthesised, using polystyrene as the starting material. The resin is stable towards conc. HCl, 0.1M HNO(3) and 0.1M NaOH. The resin shows affinity towards Ag(+), Hg(2+), Bi(3+), Pb(2+), Cu(2+), Zn(2+) and Cd(2+). Extraction of these metal ions as a function of pH, kinetics of exchange and breakthrough capacities is evaluated. The selectivity of the resin for the metal ions is in the order Ag(+) > Hg2+ > Cu2+ > Pb2+ > Cd2+ > Zn2+. The equilibrium constants for exchange and kinetics of exchange are favourable for the recovery of mercury from lean sources. Application of the resin in the stripping of mercury from chlor-alkali plant affluent, and in the enrichment of mercury from seawater, have been investigated. Mercury sorbed resin can be regenerated using 5% thiourea in 0.1M HCl.     

Plastic waste as a valuable resource: strategy to remove heavy metals from wastewater in bench scale application

Environmental Science and Pollution Research - Single-use plastic waste is gradually considered a potential material for circular economy. Ion exchange resin obtained from polystyrene waste by...     

胺基树脂的合成及对水中重金属离子的吸附特征

研究了使用氯甲基化聚苯乙烯交联微球为前驱体与二乙烯三胺经回流反应合成胺基树脂及其对水中Cd2+和Ni2+的吸附特征。结果表明,胺基官能团成功地嫁接到树脂表面,胺基含量为5.6 mmol/g。胺基树脂对Cd2+和Ni2+的吸附等温线表明,温度的升高有利于吸附,且吸附等温线都符合Langmuir模型。pH值对吸附的影响较大,最佳吸附pH值范围为4~6。2种金属离子在胺基树脂上的吸附都符合准二级动力学方程。     

Magnetic ion exchange treatment of stabilized landfill leachate

Stabilized landfill leachate is characterized by a high concentration of non-biodegradable organic matter, which is similar in chemistry to dissolved organic matter (DOM) in the natural aquatic environment. Magnetic ion exchange (MIEX) resin treatment is well-studied in drinking water for removal of DOM from natural waters. There are fewer studies evaluating MIEX treatment of waste waters, and there is no previous work evaluating MIEX treatment of landfill leachate. This work systematically evaluated MIEX treatment of stabilized landfill leachate and evaluated the results in the context of previous studies of MIEX treatment of natural and waste waters. Five leachates from four landfills were evaluated as a function of MIEX resin dose, mixing time, and regeneration efficiency. MIEX resin removed DOM from landfill leachate, even in the presence of a reported high background concentration of inorganic ions. MIEX resin that was exhausted with leachate DOM was effectively regenerated with a concentrated NaCl solution, and regenerated MIEX resin performed similarly to virgin resin. For a majority of the leachates, the removal trend for MIEX resin was color > UV-absorbing substances > dissolved organic carbon ≈ COD > total nitrogen. Finally, MIEX resin removed a wider range of DOM from leachate than coagulation. The most important contribution of this work is that MIEX treatment of leachate followed very similar trends as MIEX treatment of natural waters, which will allow previous MIEX data to be used to estimate the treatment efficiency of other waste waters.     

Removal of phosphate from water by a highly selective La(III)-chelex resin

A new polymer ligand exchanger (PLE) has been developed for the removal of phosphate in wastewater. This PLE, consisting of lanthanum(III) bound to chelex-100 resin, was prepared by passing LaCl3 solution through a column of chelex-100. Uptake of phosphate from water by this La-chelex resin was investigated in the column mode. The La-chelex resin was able to remove phosphate efficiently from water, and the uptake of phosphate was not affected by the presence of large amounts of anions (0.1M) such as chloride and sulfate. The La-chelex resin was also able to efficiently remove phosphate from seawater to <0.1mg-Pl(-1), and regenerated for reuse by removing the sorbed phosphate by eluting with 6M HCl.     

Microwave regeneration of activated carbon used for removal of solvents from vented air

A microwave regeneration of activated carbon used to remove organic solvents from vented air has been investigated. Methyl ethyl ketone (MEK), acetone, and tetrachloroethylene (TCE) vapors were removed from vented air through adsorption onto granular activated carbon. The saturated carbon was then regenerated in a microwave field, where the solvent was quickly desorbed and recovered from the inner pores of the carbon granules. The microwave-induced regeneration restored the original adsorption capacity and surface area of the activated carbon.     

Characterization and adsorption capacity of modified 3D porous aerogel from grapefruit peels for removal of oils and organic solvents

With the rapid industrialization, especially offshore oil exploitation, frequent leakage incidents of oils/organic solvents have adversely affected ecological systems and environmental resources. Therefore, great interest has been shown in developing new materials to eliminate these organic pollutants, which have become worldwide problems. In this study, a cost-effective, environmentally friendly porous aerogel with three-dimensional (3D) structure was prepared from grapefruit peel by a facile hydrothermal method as the adsorbent of oils/organic solvents. The as-prepared modified grapefruit peel aerogel (M-GPA) showed mesoporous structure with high specific surface area of 36.42 m²/g and large pore volume of 0.0371 cm³/g. The excellent hydrophobicity of M-GPA with a water contact angle of 141.2° indicated a strong potential for adsorption of oils and organic solvents. The high adsorption capacity of M-GPA for a series of oils and organic solvents was 8 to 52 times as much as its own weight. Moreover, the M-GPA was easily regenerated and a high adsorption capacity recovery above 97% was maintained after five adsorption–regeneration cycles. Therefore, the M-GPA is a promising recyclable adsorbent for the removal of oils/organic solvents from polluted water.

     

Microwave Regeneration of Activated Carbon Used for Removal of Solvents from Vented Air

ABSTRACT

A microwave regeneration of activated carbon used to remove organic solvents from vented air has been investigated. Methyl ethyl ketone (MEK), acetone, and tetrachloroethylene (TCE) vapors were removed from vented air through adsorption onto granular activated carbon. The saturated carbon was then regenerated in a microwave field, where the solvent was quickly desorbed and recovered from the inner pores of the carbon granules. The microwave-induced regeneration restored the original adsorption capacity and surface area of the activated carbon.