长柄扁桃核壳活性炭的制备及表征

以长柄扁桃核壳为原料采用磷酸活化法制备活性炭，分别研究了温度、时间、浸渍比和磷酸浓度对活性炭吸附性能的影响；进而采用氮气吸附曲线和SEM对最佳工艺条件下的活性炭进行了表征。结果表明，长柄扁桃核壳是一种优质的活性炭原料；当温度为400℃，活化时间2 h，浸渍比2：1，磷酸浓度60%时，得到产率为46.46%，碘吸附值和亚甲基蓝吸附值分别为1 073 mg/g、255 mg/g，比表面积高达1 740 m²/g，中孔率为73.12%的孔隙发达的高中孔率活性炭。     

改性活性炭吸附净化黄磷尾气中的H2S

研究了以Cu2 离子活性溶液制备改性活性炭吸附净化黄磷尾气中H2S的相关问题,考察了改性活性炭制备过程中的浸渍液浓度、干燥温度和焙烧温度的影响,以及温度和氧含量对吸附的影响;并对空白活性炭、改性活性炭吸附前后做SEM表征.研究结果表明,浸渍液浓度0.05 mol/L、干燥温度120℃、焙烧温度250℃为改性活性炭制备的最佳条件;吸附反应阶段较适宜的温度为95℃,氧含量为1%;结合扫描电镜初步表明,改性后的活性炭S容量增加,吸附效果明显.     

改性活性炭吸附净化黄磷尾气中的H2S

研究了以Cu²⁺离子活性溶液制备改性活性炭吸附净化黄磷尾气中H₂S的相关问题，考察了改性活性炭制备过程中的浸渍液浓度、干燥温度和焙烧温度的影响，以及温度和氧含量对吸附的影响；并对空白活性炭、改性活性炭吸附前后做SEM表征。研究结果表明，浸渍液浓度0.05 mol/L、干燥温度120℃、焙烧温度250℃为改性活性炭制备的最佳条件；吸附反应阶段较适宜的温度为95℃，氧含量为1%；结合扫描电镜初步表明，改性后的活性炭S容量增加，吸附效果明显。     

废椰壳制备活性炭负载CuO处理活性艳红X-3B废水的工艺优化

为了综合利用废椰壳,进行了废椰壳制备活性炭并负载氧化铜处理活性艳红X-3B废水的研究。采用正交实验法,以COD和色度去除率为目标函数确定了活性炭的最佳制备工艺条件为：磷酸浓度65%（质量百分数）,m（磷酸）/m（椰壳）比3∶1,活化时间2.5 h,活化温度500℃。在该活性炭上负载氧化铜处理活性艳红X-3B染料废水,其COD和色度去除率分别为83.70%和99.72%。用扫描电镜（SEM）和X衍射仪（XRD）对裸活性炭和载铜活性炭样品表面形貌和结构进行了表征和分析。通过单因素实验法确定了废水处理的最佳工艺条件为：pH值5,曝气时间4 h和催化剂用量0.55 g,在此条件下,COD和色度去除率分别为86.70%和99.75%,相应的出水指标为75 mg/L和32稀释倍数。     

基于响应曲面法优化生物质污泥活性炭的制备方法

针对传统技术制备污泥活性炭的比表面积不高、吸附值低等不足,通过在污泥中添加核桃壳以改善污泥原料缺陷,研究了活化剂种类、核桃壳加量、活化温度、活化时间、活化剂浓度及浸渍比等影响活性炭吸附能力的制备条件。在优化后的条件下制备出了高吸附性能的生物质污泥复合活性炭。结果表明:选择氯化锌作为活化剂,核桃壳加量20%、活化温度500℃、活化时间60 min、活化剂浓度2.5 mol·L-1、浸渍比1∶2.5为最优化制备条件。制备出的生物质污泥复合活性炭碘吸附值为574.11 mg·g-1,产率为43.93%。     

微波辐照碳酸钾化学活化法制备菌渣活性炭

以食用菌渣为原料,以K2CO3为活化剂,利用微波辐照加热法制备活性炭。采用正交实验设计,研究了活化功率、活化时间、K2CO3与菌渣质量比、浸渍时间对活性炭碘值及得率的影响。实验结果表明,活化时间、活化功率、K2CO3与菌渣质量比对活性炭碘值影响显著,浸渍时间对活性炭碘值影响不显著;对活性炭得率,各因素影响均不显著。综合考虑碘值和得率2个指标,实验得出的最佳活性炭制备工艺条件为:活化功率560 W,活化时间20 min,K2CO3与菌渣质量比0.8,浸渍时间20 h。     

棉秆基活性炭的制备及其对2,4-二硝基苯酚的吸附

以棉秆为原料，以KOH为活化剂，制备了高比表面棉秆基生物质活性炭。分析了制得的活性炭的元素组成、表面官能团、吸附能力等物化性能，探讨了浸渍比，活化温度，活化时间等工艺参数对制备活性炭得率、表面官能团、碘值、亚甲基蓝值等性能的影响，并通过静态吸附实验比较了不同条件下制备活性炭对2，4-二硝基苯酚的吸附性能，探讨了典型炭样品对2，4-二硝基苯酚的等温吸附特性。结果表明，KOH活化棉秆基生物质活性炭的表面物化性质随浸渍比、活化温度等工艺参数变化而变化，活化适宜条件为浸渍比1：3、活化温度800℃、活化时间90 min，在此条件下制得的炭样的碘值为1 251 mg/g，亚甲基蓝吸附值为478 mg/g，分别是国家一级品标准的1.25倍与3.54倍；对2，4-二硝基苯酚的Langmuir最大吸附量为747 mg/g，与Freundlich模型相比，Langmuir模型能较好地描述2，4-二硝基苯酚在炭样上的吸附行为，表明制备活性炭样品表面吸附位的能量分布较为均一。     

微波法污水厂污泥制备活性炭的研究

研究了以污水厂污泥为原料、微波辐照下磷酸活化法制备污泥活性炭的工艺条件,探讨了微波功率、辐照时间以及磷酸浓度对活性炭碘值的影响.结果表明,微波功率480 W、辐照时间315 s、磷酸浓度40%～45%的条件下,制备的污泥活性炭碘值为301 mg/g,总孔孔容是0.37 mL/g,平均孔径8.8 nm,比表面积168 m2/g.将该污泥活性炭用于处理TNT红水,吸附效果良好.     

一种污泥活性炭的制备及其在兰炭废水处理中的应用

以城市生活污水厂脱水污泥和木屑的混合物为原料,利用ZnCl_2为活化剂制备污泥活性炭。研究了活化温度、活化时间、固液比和活化剂浓度对吸附性能的影响。在活化温度为650℃、活化时间30 min、固液比1∶1.5、活化剂浓度为5 mol·L~(-1)的最佳工艺条件下,制备得到的活性炭碘吸附值为584.85 mg·g~(-1),利用扫描电镜可以观察到其发达的孔隙结构。将制备的污泥活性炭应用于兰炭废水处理中,结果表明,污泥活性炭的投加量为180 g·L~(-1),pH为7,吸附时间60min,挥发酚和氨氮的去除率分别为73.38%和48.27%,废水中污染物浓度明显降低。     

微波法污水厂污泥制备活性炭的研究

研究了以污水厂污泥为原料、微波辐照下磷酸活化法制备污泥活性炭的工艺条件,探讨了微波功率、辐照时间以及磷酸浓度对活性炭碘值的影响.结果表明,微波功率480 W、辐照时间315 s、磷酸浓度40%～45%的条件下,制备的污泥活性炭碘值为301 mg/g,总孔孔容是0.37 mL/g,平均孔径8.8 nm,比表面积168 m2/g.将该污泥活性炭用于处理TNT红水,吸附效果良好.     

Utilization of agricultural waste corn cob for the preparation of carbon adsorbent

In the present study, a series of activated carbons were prepared from agricultural waste corn cob by chemical and physical activations with potassium hydroxide (KOH)/potassium carbonate (K2CO3) and carbon dioxide (CO2). The effect of process variables such as impregnation ratio, impregnation time, activation temperature and soaking time of CO2 was studied in order to relate these preparation parameters with the physical properties of final carbon products. The resulting activated carbons were characterized by nitrogen adsorption-desorption isotherms at 77 K. The surface areas and pore volumes of carbons were estimated by the BET equation, the Langmuir equation and the t-plot method. Under the experimental conditions investigated, the main parameters in the activation of corn cob were found to be the impregnation ratio and activation temperature. The soaking time of CO2 is another important variable, which had a strong effect on the pore volume development. The BET surface area and total pore volume were as large as about 2000 m2/g and about 1.0 cm3/g, respectively. This study showed that the activation of agricultural waste corn cob with KOH/K2CO3 and CO2 was suitable for the preparation of large-surface-area activated carbons.     

UTILIZATION OF AGRICULTURAL WASTE CORN COB FOR THE PREPARATION OF CARBON ADSORBENT

In the present study, a series of activated carbons were prepared from agricultural waste corn cob by chemical and physical activations with potassium hydroxide (KOH)/potassium carbonate (K₂CO₃) and carbon dioxide (CO₂). The effect of process variables such as impregnation ratio, impregnation time, activation temperature and soaking time of CO₂ was studied in order to relate these preparation parameters with the physical properties of final carbon products. The resulting activated carbons were characterized by nitrogen adsorption[ch-[chdesorption isotherms at 77 K. The surface areas and pore volumes of carbons were estimated by the BET equation, the Langmuir equation and the t-plot method. Under the experimental conditions investigated, the main parameters in the activation of corn cob were found to be the impregnation ratio and activation temperature. The soaking time of CO₂ is another important variable, which had a strong effect on the pore volume development. The BET surface area and total pore volume were as large as about 2000 m²/g and about 1.0 cm³/g, respectively. This study showed that the activation of agricultural waste corn cob with KOH/K₂CO₃ and CO₂ was suitable for the preparation of large-surface-area activated carbons.     

水枝锦活性炭对孔雀石绿的吸附性能研究

以水枝锦为原料,采用磷酸活化法制备成水枝锦活性炭,通过静态实验研究其对孔雀石绿的吸附性能.考察了水枝锦活性炭投加量、接触时间、pH和孔雀石绿初始浓度对孔雀石绿吸附效果的影响.结果表明,在温度为723 K、活化时间为1 h条件下,水枝锦活性炭得率为36.7%,比表面积为1 223m2/g;在298K、孔雀石绿初始质量浓度为250mg/L、接触270min条件下,水枝锦活性炭的最佳投加量为0.5 g/L,适宜pH为7～12;吸附量随温度的升高而增大,提高温度有利于吸附的进行;水枝锦活性炭静态吸附孔雀石绿的动力学行为符合伪二级动力学方程.静态吸附动力学研究为投加粉状活性炭的吸附池的设计和污水处理装置的运行提供基础信息,对于去除水中孔雀石绿技术的应用具有重要的实际意义.     

Production of activated carbons from pyrolysis of waste tires impregnated with potassium hydroxide

Activated carbons were produced from waste tires using a chemical activation method. The carbon production process consisted of potassium hydroxide (KOH) impregnation followed by pyrolysis in N2 at 600-900 degrees C for 0-2 hr. The activation method can produce carbons with a surface area (SA) and total pore volume as high as 470 m2/g and 0.57 cm3/g, respectively. The influence of different parameters during chemical activation, such as pyrolysis temperature, holding time, and KOH/tire ratio, on the carbon yield and the surface characteristics was explored, and the optimum preparation conditions were recommended. The pore volume of the resulting carbons generally increases with the extent of carbon gasified by KOH and its derivatives, whereas the SA increases with degree of gasification to reach a maximum value, and then decreases upon further gasification.     

Preparation and characterisation of activated carbon from waste tea by physical activation using steam

ABSTRACT

In this study, the feasibility of preparing activated carbon from waste tea by physical activation using steam was investigated. The effects of activation temperature on yield and pore properties of the prepared activated carbon were studied. The yield decreased with increased activation temperature owing to the decomposition of cellulose and hemicellulose. The specific surface area and pore volume of the activated carbon were estimated using the Brunauer–Emmett–Teller method, Langmuir equation, and t-plot method. The specific surface area and micropore volume increased with increases in activation temperature, as additional volatile materials were released. The specific surface area significantly decreased at first but slightly increased with increasing activation time. The maximum specific surface area reached 995 m²/g at an activation temperature of 800 °C with a water flow rate of 0.075 g/min and a constant hold time of 0.5 hr. According to the nitrogen adsorption isotherms, micropores mainly developed when the activation temperature was below 800 °C, and both micropores and mesopores developed when it was above 800 °C. The results showed that activation temperature significantly affected micropore and mesopore volumes, as well as the specific surface area of the activated carbon. Overall, waste tea was found to be an attractive raw material for producing low-cost activated carbon.

Implications: Every year, a large amount of waste tea is generated after extraction. The high carbon content of waste tea showed that it can be used as raw material to produce activated carbon. This study investigated the feasibility of preparing activated carbon from waste tea by physical activation using steam. Temperature and time were found to have clear effects on pore properties. Our proposed method and raw material are more environmentally friendly and involve low cost. Furthermore, this offers a potential solution to the problems of waste tea disposal and low-cost activated carbon production.     

Characterization of activated carbons prepared from sugarcane bagasse by ZnCl2 activation.

Activated carbons were prepared from the agricultural waste of sugarcane bagasse by the chemical activation with zinc chloride (ZnCl2) at the activation temperature of 500 degrees C with soaking time of 0.5 hour. The influence of activation parameters on the final carbon products was examined by varying the impregnation ratio (i.e., mass ratio of added ZnCl2 to bagasse) and bagasse size. The physical properties of carbon products were characterized by nitrogen adsorption/desorption isotherms (at 77 K) and helium displacement method. The surface area and pore volume of carbons were thus obtained by the BET equation and t-plot method. Also, the particle density and porosity of carbons were estimated by the total pore volume and true density. The increases of the values of surface area and pore volume are approximately proportional to the impregnation ratio. The microporous carbon product with the BET surface area of 905 m2/g and total pore volume of 0.44 cm3/g was obtained in the present study. Further, the adsorption isotherms of two acid dyes from aqueous solutions onto the carbon products were performed at 30 degrees C. The results show that the adsorption isotherms of acid dyes with high molecular weight or large molecular size on the microporous adsorbents of activated carbons are plateau forms, indicating multilayer adsorptions, which may be attributed to the steric hindrance of the adsorbate molecules.     

Production of Activated Carbons from Pyrolysis of Waste Tires Impregnated with Potassium Hydroxide

ABSTRACT

Activated carbons were produced from waste tires using a chemical activation method. The carbon production process consisted of potassium hydroxide (KOH) impregnation followed by pyrolysis in N₂ at 600-900 °C for 0-2 hr. The activation method can produce carbons with a surface area (SA) and total pore volume as high as 470 m²/g and 0.57 cm³/g, respectively. The influence of different parameters during chemical activation, such as pyrolysis temperature, holding time, and KOH/tire ratio, on the carbon yield and the surface characteristics was explored, and the optimum preparation conditions were recommended. The pore volume of the resulting carbons generally increases with the extent of carbon gasified by KOH and its derivatives, whereas the SA increases with degree of gasification to reach a maximum value, and then decreases upon further gasification.     

生物基质活性炭对挥发性有机物的吸附

以咖啡渣和柚子皮生物基质为原料用磷酸活化法制成活性炭,探讨了制备条件对活性炭制备的影响,并研究了其对正丁烷的吸附行为。磷酸活化过程中磷酸的用量为生物基质质量的1.5倍为宜,咖啡渣采用超声干燥法,柚子皮采用水热法制备。制备的活性炭对正丁烷均有较好的吸附能力,以柚子皮为原料、磷酸用量为原料质量两倍活化制成的活性炭吸附性能最佳,最大吸附量约为商用活性炭的2倍。吸附剂均能较好地与兰格缪尔曲线相拟合,计算了不同正丁烷覆盖度下的等量吸附热,其变化规律与吸附曲线变化规律相一致。