活性炭吸附化学战剂——沙林染毒水的试验研究

研究了5种国产活性炭吸附水中沙林的性能及影响因素，果壳质活性炭的吸附性能优于煤质活性炭。果壳活性炭WP－202的吸附等温线方程为qe=11.45Ce^0.39，其粉状炭为10min时能达到吸附容量的98％。活性炭颗粒小则吸附速度快，温度升高不利于吸附。活性炭与水中的氯反应后，吸附性能下降30％，在含盐量2000mg/L的苦咸水中吸附量降低5％。处理化学战剂－沙林染毒水宜多种水处理技术相结合，并采用活性炭吸附作为最后一级处理单元。     

去除饮用水中三卤甲烷和腐殖酸的活性炭选型方法

三卤甲烷(THMs)是水中天然有机物在氯化消毒过程中产生的对人体有致癌作用的挥发性有机物,腐殖酸是生成消毒副产物的主要前驱物.活性炭吸附是去除THMs和腐殖酸最常用的方法.不同炭型的活性炭对THMs和腐殖酸的吸附容量并不相同.以饮用水中最常见的THMs(即三氯甲烷)和腐殖酸为吸附对象,进行煤、椰壳和果壳3种不同材质活性炭的吸附容量实验.实验结果验证了苯酚值预测各类活性炭对小分子THMs吸附性能以及丹宁酸值预测各类活性炭对大分子腐殖酸吸附性能的有效性.具有丰富微孔和表面氧化程度较低的上海椰壳炭YK-2和上海果壳专用炭对三氯甲烷的吸附容量比上海原煤破碎高,大孔丰富的上海果壳专用炭和上海原煤破碎对腐殖酸的吸附性能高.将实验结果与美国环保局RREL(Risk Reduction Engineering Laboratory)水污染物处理数据库中相关信息对比发现,相比国外常用活性炭,国产活性炭对三氯甲烷的吸附性能与之相当或略高,具有更好的性价比,应用前景广阔.     

活性炭吸附-超临界CQ解吸附四氯乙烯的特性研究

应用Boyd理论研究了活性炭吸附水中四氯乙烯（PCE）的吸附速率以及超临界CO2萃取PCE饱和活性炭的解吸附速率。结果表明，在0．5～48．0h内，吸附速率曲线具有直线相关关系，R^2=0．9960，其吸附速率可用粒内扩散系数D．表示，Di=4．00×10^-10cm2／s；在超临界CO2解吸附过程中，在1～5min内，时间与解吸附率存在直线相关关系，R2=0．9475，其解吸附速率用粒内扩散系数Di／SF表示，Di/SF=-5．19×10^-5cm2／s，比Di大10^5倍，说明超临界流体具有优越的传输性能；用Boyd理论可粗略描述活性炭吸附-超临界C02解吸附PCE的过程。     

载锆活性炭吸附水中对硝基苯酚和磷的研究

为了研究能有效同步去除水中有机、无机污染物的吸附剂,通过前驱体原位沉积法在活性炭表面负载锆氧化物制备得到复合吸附剂载锆活性炭,并对其去除水中对硝基苯酚(PNP)和磷的性能进行评价。结果表明:载锆活性炭对PNP和磷的吸附效果优于未改性活性炭;Langmuir吸附等温模型均能很好地描述载锆活性炭对两种污染物的吸附过程;载锆活性炭对PNP和磷的吸附过程分别符合准二级动力学模型和准一级动力学模型;离子强度对载锆活性炭的吸附磷能力影响不大,说明载锆活性炭对磷具有较好的吸附选择性。PNP和磷共存时,载锆活性炭依然有较好的吸附性能,表明该复合吸附剂可用于同步去除水中的有机、无机污染物。使用5%(质量分数)氯化钠溶液和5%(质量分数)氢氧化钠溶液可对吸附饱和的载锆活性炭进行再生,通过多次循环实验后脱附率较高且稳定,说明载锆活性炭具有良好的再生潜能。     

活性炭吸附-超临界CO2解吸附四氯乙烯的特性研究

应用Boyd理论研究了活性炭吸附水中四氯乙烯(PCE)的吸附速率以及超临界CO2萃取PCE饱和活性炭的解吸附速率.结果表明,在0.5～48.0 h内,吸附速率曲线具有直线相关关系,R2=0.996 0,其吸附速率可用粒内扩散系数Di表示,Di=4.00×1010cm2/s;在超临界CO2解吸附过程中,在1～5 min内,时间与解吸附率存在直线相关关系,R2=0.947 5,其解吸附速率用粒内扩散系数Di/SF表示,Di/SF=-5.19×10-5cm2/s,比Di大105倍,说明超临界流体具有优越的传输性能;用Boyd理论可粗略描述活性炭吸附-超临界CO2解吸附PCE的过程.     

磁性活性炭的制备及其对水中甲基橙的吸附

活性炭被广泛应用于水处理领域,然而吸附饱和后难以分离和再生的缺点却限制了其应用。本研究采用化学共沉淀法将铁氧化物和活性炭进行复合,制备出同时具有磁分离性能和较强的吸附性能的磁性活性炭复合材料,并对制备的复合材料进行表征,考察其对水中甲基橙的吸附性能。结果表明,制备的磁性活性炭的比表面积为666.72 m2/g,平均孔径为3.16 nm,具有良好的磁性能,在外加磁场下能快速地从溶液中分离出来且磁性能相对稳定,铁氧化物对活性炭吸附性能的影响不大。在温度为25℃、p H为5、吸附剂用量为3 g/L的情况下,吸附3 h后,该磁性活性炭对甲基橙的吸附率可达99.1%,预示着该磁性活性炭在水处理方面具有潜在的应用前景。     

活性炭去除水中余氯的研究

通过对5种不同活性炭的去除余氯量实验、余氯穿透实验以及化学反应产物Cl-的质量平衡数据,探讨了活性炭去除余氯的性能和机制.活性炭去除余氯是吸附与化学反应共同作用的结果.活性炭与水中余氯接触后的初期,去除余氯以吸附作用为主;达到吸附平衡后,余氯浓度继续下降则是由于化学反应的作用.接触时间越长、余氯初始浓度越高、pH较低,活性炭去除余氯量越大.由Cl-的生成量可以确定化学反应去除余氯量是余氯总去除量的一部分;接触时间越长,活性炭剂量越大,化学反应去除余氯量占余氯总去除量的比例越高.使用粒径<180目活性炭进行余氯去除实验,吸附容量在1～2h即达到饱和.活性炭对余氯吸附量(2h的余氯去除量)的大小与其苯酚值排行相同.苯酚值及碘值较高的煤质炭与余氯有较强的化学反应,果壳炭其次,而椰壳炭的化学性相对稳定.     

活性炭吸附对印染废水深度处理的研究

活性炭吸附处理可使印染废水生化出水符合直接排放或回用的标准.对不同活性炭进行性能指标测试,据此筛选出对大分子有机物吸附性能较好的3种不同材质的括性炭(混合炭、原煤炭和果壳炭),并进行吸附容量实验.同时,考察不同空床接触时间(EBCT)下的微型快速穿透(MCRB)实验.结果表明,果壳炭在3种备选炭中COD去除率和活性炭吸附容量利用率最高;1个大中型炭柱中的EBCT为20 min的果壳炭床至少可以连续使用8 d才需更换新炭,而后置炭床的串联会保证出水在8 d后继续达到<纺织染整工业污染物排放标准>(GB 4287-1992)中一级排放标准(COD<50 mg/L).     

改性核桃果皮基活性炭对Cu~(2+)的吸附

以核桃外果皮制备活性炭及改性活性炭,对制得的活性炭进行表征,研究了5种活性炭对重金属Cu~(2+)的吸附性能。研究表明,以氯化锌为活化剂制得的活性炭,其碘吸附值及表面酸性基团含量均高于磷酸活化制备的活性炭,改性后的活性炭吸附性能明显增强,碘吸附值最高达到678.53 mg·g~(-1),对Cu~(2+)的最高去除率达到91.43%。吸附量和Cu~(2+)去除率随时间、温度和p H的升高而增大,5种活性炭投加量增加,导致吸附量减小,但Cu~(2+)去除率增大,吸附平衡时间为3 h。5种活性炭对Cu~(2+)的吸附均符合准二级动力学模型。磷酸和氯化锌活化的活性炭吸附等温线符合Tempkin模型,而3种改性活性炭的吸附等温线则较好地符合Langmuir模型。     

污泥活性炭的制备及其对酸性红G的吸附行为

以城市污水处理厂的脱水污泥为原料,用Zn Cl2活化法制备污泥活性炭,并研究其对水中酸性红G的吸附、脱附行为。选取活化剂浓度、固液比、活化温度及活化时间等因素,通过正交实验确定了最佳工艺,即Zn Cl2浓度30%,固液比1∶2,碳化温度500℃,碳化时间1.5 h。吸附实验结果表明,该污泥活性炭对水中酸性红G的吸附量随着温度升高而增加,在15、25和35℃条件下的最大吸附量分别为153.6、165.6和180.4 mg/g,且吸附等温线能较好用Langmuir方程进行模拟。酸性红G在污泥活性炭上的吸附动力学符合准二级反应动力学模型。污泥活性炭对酸性红G的吸附量随着溶液p H的增大而减小,污泥活性炭的最佳投加量为0.26 g/L。吸附饱和的污泥活性炭可通过碱处理和热处理方法进行脱附,脱附后的吸附剂对酸性红G仍具有很强吸附性能。     

Influence of resorcinol chemical oxidation on the removal of resulting organic carbon by activated carbon adsorption

Activated carbon adsorption and chemical oxidation followed by activated carbon adsorption of resorcinol in water has been studied. Three chemical oxidants have been used: hypochlorite, permanganate and Fenton's reagent. The influence of concentrations of resorcinol and activated carbon on adsorption removal rates has been investigated. Both isotherm and adsorption kinetics have been studied. Results are fit well by Freundlich isotherms and adsorption rates of resorcinol were found to follow a pseudo-second-order kinetic model. However, pyrogallol, an intermediate of resorcinol oxidation with permanganate and Fenton's reagent, showed an unfavourable isotherm type. At the conditions investigated, chemical oxidation allows slight reductions of TOC and intermediates formed were found to inhibit the adsorption rate of TOC in the case of permanganate and Fenton's reagent oxidation, likely due to formation of some polymer pyrogallol product. The adsorption process was found to be controlled by pore internal diffusion, which justifies the poor affinity of oxidation intermediates toward activated carbon since molecules of larger size should diffuse rapidly for the adsorption to be effective.     

Application of Fenton's reagent to regenerate activated carbon saturated with organochloro compounds

In this work Fenton's reagent was used to treat activated carbon saturated with organochloro compounds for the oxidation of the adsorbed contaminants and the regeneration of the carbon adsorbent. Activated carbon containing adsorbed chlorinated model substrates such as chlorobenzene, tetrachloroethylene, chloroform or 1,2-dichloropropane was treated with Fenton's reagent at room temperature resulting in a rapid consumption of the organochloro compounds. Thermogravimetric, infrared, BET surface area and MIMS adsorption studies showed that Fenton's treatment has no significant effect on the physico-chemical properties of the activated carbon. The used carbon adsorbents can be efficiently regenerated and recycled with no loss of its adsorption capacity even after five consecutive treatments with Fenton's reagent.     

微波加热对活性炭表面基团及其对SO2吸附性能的影响

采用了微波加热技术,通过在不同微波功率和辐射时间条件下对不同粒径活性炭进行改性,研究了改性前后活性炭的表面化学基团、元素组成的变化,以及对SO2吸附性能的影响.结果表明,经过微波改性后活性炭的SO2吸附性能大为提高,微波功率是影响改性活性炭脱硫性能的主要因素.活性炭经微波热处理后,酸性基团发生分解,表面含氧量减少,碱性特征增强,是吸附性能增加的主要原因之一.     

过渡金属浸渍改性ACF去除H_2S研究

为探讨活性炭纤维（ACF）去除恶臭气体H2S的性能,采用过渡金属浸渍改性ACF吸附H2S,揭示出改性ACF前后吸附H2S的性能差异及浸渍剂的浓度和种类对ACF吸附性能的影响。结果表明,通过过渡金属改性后的ACF吸附性能有显著提高,对H2S吸附是物理吸附和化学吸附共同作用的结果,改性后的ACF硫容量大小依次为：5%硝酸铜改性ACF〉5%硝酸钴改性ACF〉5%硝酸锰改性ACF。不同浓度浸渍剂改性后的ACF吸附H2S性能有所不同,硫容量呈现出随着浓度升高先增大后减小的趋势。不同浸渍剂改性后的ACF吸附穿透曲线也不同,穿透时间依次为：TCu-ACF〉TCo-ACF〉TMn-ACF。混合金属溶液改性ACF吸附H2S,5%硝酸铜-3%硝酸钴溶液改性ACF吸附性能最佳,硫容量可达166.7 mg/g;而5%硝酸铜-3%硝酸钴-1%硝酸锰溶液改性的ACF效果最差,硫容量仅为83.3 mg/g。     

褐煤活性炭吸附处理焦化废水

研究褐煤活性炭吸附处理焦化废水的性能，为褐煤活性炭用于废水处理提供理论依据和技术指导。以河南某气化厂的焦化废水为吸附原水，进行褐煤活性炭对酚吸附性能的静态和动态实验。静态实验表明，褐煤活性炭对酚的吸附性能符合弗兰德里希（Freundlich）吸附方程式。在室温条件下，对于150 mL焦化废水，当活性炭的用量为10 g，吸附反应时间为1 h，酚的去除率可达92%以上。动态实验研究表明，当进水酚浓度为3 800 mg/L，吸附1.5 h，活性炭的吸附容量可达21.38 mg/g。水处理的实验研究表明，利用褐煤制备的活性炭，对焦化废水具有良好的处理效果。     

花生壳活性炭对亚甲基蓝的吸附特性

以花生壳为原料,氯化锌为活化剂制备花生壳活性炭,采用高分辨电子扫描电镜(SEM)和氮吸脱附曲线对花生壳活性炭进行了表征.从热力学和动力学的角度,研究了花生壳活性炭对亚甲基蓝溶液的吸附行为.热力学研究表明,花生壳活性炭对亚甲基蓝的吸附符合Langmuir等温吸附方程,该吸附是自发吸热过程,吸附自由能为-52.4017～-95.1765 kJ/mol,吸附熵变为214 J/(mol·K),吸附焓变为57.49796 kJ/mol.动力学研究表明,花生壳活性炭对亚甲基蓝的吸附符合二级反应动力学方程反应特征.     

CuFe2O4/activated carbon composite: a novel magnetic adsorbent for the removal of acid orange II and catalytic regeneration

CuFe2O4/activated carbon magnetic adsorbents, which combined the adsorption features of activated carbon with the magnetic and the excellent catalytic properties of powdered CuFe2O4, were developed using a simple chemical coprecipitation procedure. The prepared magnetic composites can be used to adsorb acid orange II (AO7) in water and subsequently, easily be separated from the medium by a magnetic technique. CuFe2O4/activated carbon magnetic adsorbents with mass ratio of 1:1, 1:1.5 and 1:2 were prepared. Magnetization measurements, BET surface area measurements, powder XRD and SEM were used to characterize the prepared adsorbents. The results indicate that the magnetic phase present is spinel copper ferrite and the presence of CuFe2O4 did not significantly affect the surface area and pore structure of the activated carbon. The adsorption kinetics and adsorption isotherm of acid orange II (AO7) onto the composites at pH 5.2 also showed that the presence of CuFe2O4 did not affect the adsorption capacity of the activated carbon. The thermal decomposition of AO7 adsorbed on the activated carbon and the composite was investigated by in situ FTIR, respectively. The results suggest that the composite has much higher catalytic activity than that of activated carbon, attributed to the presence of CuFe2O4. The variation of the adsorption capacity of the composites after several adsorption-regeneration cycles has also been studied.     

改性污泥活性炭对水中镉离子的吸附性能

以城市污水处理厂的剩余污泥为原料,氯化锌为活化剂制备污泥活性炭,对一部分污泥活性炭用6.0 mol/L的硝酸进行改性,并研究了未改性和改性的污泥活性炭对Cd2＋的吸附行为的影响。结果表明,在pH为5.0、Cd2＋初始浓度为100 mg/L、吸附剂投加量为2.0 g/L、反应温度为25℃时,未改性的污泥活性炭吸附容量为8.45 mg/g,硝酸改性的污泥活性炭吸附容量达到了23.35 mg/g。改性和未改性的污泥活性炭对Cd2＋都有较好的吸附容量,硝酸改性大幅度提高了污泥活性炭对Cd2＋的吸附性能。常温下改性污泥活性炭对Cd2＋的吸附符合Langmuir吸附等温式。     

Adsorption of pharmaceutical compounds and an endocrine disruptor from aqueous solutions by carbon materials

Adsorption has been used to study the removal of atenolol, caffeine, diclofenac and isoproturon, pharmaceutical compounds as emerging contaminants and an endocrine disruptor from ultrapure water and a municipal wastewater treatment plant effluent with three carbonaceous materials: activated carbon, multiwalled carbon nanotubes and carbon nanofibers. The adsorption capacities were studied in the temperature range of 25-65°C and pH range from 3 to 9. Several model isotherms were used to model the adsorption equilibrium data. Also, the competitive adsorption was evaluated.     

Remediation of MTBE from drinking water: air stripping followed by off-gas adsorption

The widespread use of methyl tertiary butyl ether (MTBE) as an oxygenate in gasoline has resulted in the contamination of a large number of ground and surface water sources. Even though air stripping has been proven to be an effective treatment technology for MTBE removal, off-gas treatment often is required in conjunction with it. This study evaluated the combined treatment technologies of air stripping followed by off-gas adsorption on a pilot scale for the treatment of MTBE-contaminated water. The effect of air/water ratios on the treatment efficiency was studied, and the mass transfer coefficient was determined. Air/water ratios of 105:1, 151:1, 177:1, 190:1, 202:1, and 206:1 were used, and a treatment efficiency of >99% was achieved for all the runs conducted. The depth of packing required to achieve maximum treatment efficiency decreased with increasing air/water ratio. Relative humidity (RH) impacts on the MTBE adsorption capacity of a granular activated carbon (GAC) and carbonaceous resin were determined from pilot plant studies. Breakthrough profiles obtained from the pilot plant studies conducted at 20, 30, and 50% RH indicated that GAC has a higher adsorptive capacity than resin. The adsorptive capacity of GAC decreased with increasing RH, whereas RH did not impact the resin adsorptive capacity.