The adsorption of benzene and methylethylketone onto activated carbon: thermodynamic aspects.

The adsorption of volatile organic compounds (VOCs), exemplified by benzene and methylethylketone (MEK), onto seven different types of activated carbon was investigated. Results show that for benzene adsorption the adsorption characteristic energy, enthalpy, free energy and entropy are in the range 17.12-36.86, -20.8 to -44.7, -11.89 to -16.22 kJ/mole and -29.4 to -85.3 J/mole/K, respectively. For the adsorption of MEK, the adsorption characteristic energy, enthalpy, free energy and entropy are in the range 14.47-32.34, -18.3 to -40.8, -10.78 to -15.56 kJ/mole and -24.8 to approximately -60.3 J/mole/K, respectively. The adsorption enthalpy can be calculated indirectly from statistical thermodynamic method and directly from the immersion enthalpy method. The adsorption characteristic energy is calculated by the Dubinin-Astokhov equation. The free energy is calculated by the measured equilibrium adsorption constant.     

甲苯气体的动态吸附净化及吸附剂再生实验研究

研究了活性炭纤维(ACF)对甲苯气体的动态吸附净化过程及热空气解吸脱附再生过程.采用3种经验方程对ACF的吸附等温线进行拟合,其中Langmuir方程拟合效果最好,拟合相关系数R2 =0.9960,说明在给定的浓度范围内,ACF对甲苯的吸附是以单分子层吸附为主.穿透曲线实验表明,ACF对甲苯吸附效果较好,Yoon-Ne...     

活性炭孔隙结构在其甲苯吸附中的作用

选用4种商用活性炭(AC),利用氮气绝热吸附、扫描电子显微镜(SEM)和傅立叶变换红外光谱(FTIR)测试了活性炭的物化性质。以甲苯为吸附质,在温度为298.15 K下进行了静态和动态吸附实验,研究了活性炭孔结构对其吸附性能、吸附行为、表面覆盖率和吸附能的影响。结果表明:活性炭的比表面积和孔容是其吸附性能主要影响因素,孔径在0.8～2.4 nm之间的孔容和甲苯吸附量之间存在较好的线性关系,且线性斜率随甲苯浓度增加而变大。甲苯吸附行为符合Langmuir吸附等温模型和准一阶动力学方程式。活性炭孔结构是甲苯吸附速率的主要制约因素。在甲苯快速吸附阶段,微孔为吸附速率主要制约因素,在甲苯颗粒内扩散阶段,微孔和表面孔为吸附速率的主要制约因素,在吸附末尾阶段,中孔和大孔为吸附速率的主要制约因素。4种活性积炭对甲苯的吸附能随其比表面变大而变大。     

活性炭吸附硫化氢及微波辐照解吸研究

研究了两种活性炭对硫化氢的平衡吸附性能力,并对活性炭床层的穿透性进行了考察;吸附饱和和活性炭在微波辐射的作用下进行解吸。实验表明,解吸效率与微波作用时间及温度有关,在本实验条件下H2S解吸效率达90．1％。     

一次性废竹筷制备活性炭及热解过程分析

以一次性废竹筷为原料,K2CO3为活化剂,通过炭化和活化2步制备活性炭。采用全自动比表面和孔径分布分析仪、傅里叶变换红外光谱仪（FTIR）、X射线衍射分析仪（XRD）对样品的孔隙性质、表面官能团和晶相变化进行了表征,并研究了活性炭对亚甲基蓝的吸附等温线。利用热重分析（TGA）对活性炭的制备过程进行了研究,并用Coats-Redfern法确定了热解反应活化能和反应模型。结果表明,活性炭的比表面积为1 262 m2·g-1,总孔体积为0.624 cm3·g-1。K2CO3活化可导致热解炭的脂肪烃侧链断裂,并发生脱氢缩聚,其石墨微晶的轴向（100）堆积被破坏,径向（002）芳香环网状结构则更为有序。活性炭对亚甲基蓝的吸附过程符合Langmuir模型,最大吸附量为336 mg·g-1。废竹筷的2个主要热解阶段符合一维扩散模型和二级反应模型,其热解反应活化能分别为76.23和104.24 kJ·mol-1;活化过程中残存木质素的热解可由一维扩散模型描述,K2CO3浸渍使其热解反应活化能降低了44.28 kJ·mol-1。     

活性碳纤维吸附甲苯废气吸附等温方程的研究

研究了固定床吸附器中粘胶基活性碳纤维(viscose rayon-based ACFs)吸附甲苯废气的特性,通过实验测定活性碳纤维吸附不同浓度甲苯废气的穿透曲线,作出等温吸附曲线,根据实验数据拟合出几个吸附平衡方程,并与实验结果进行比较.实验结果可为工业设备设计提供参考.     

活性碳纤维吸附甲苯废气吸附等温方程的研究

研究了固定床吸附器中粘胶基活性碳纤维（viscose rayon-based ACFs）吸附甲苯废气的特性，通过实验测定活性碳纤维吸附不同浓度甲苯废气的穿透曲线，作出等温吸附曲线。根据实验数据拟合出几个吸附平衡方程，并与实验结果进行比较。实验结果可为工业设备设计提供参考。     

Enhanced mercuric chloride adsorption onto sulfur-modified activated carbons derived from waste tires

A number of activated carbons derived from waste tires were further impregnated by gaseous elemental sulfur at temperatures of 400 and 650 degrees C, with a carbon and sulfur mass ratio of 1:3. The capabilities of sulfur diffusing into the micropores of the activated carbons were significantly different between 400 and 650 degrees C, resulting in obvious dissimilarities in the sulfur content of the activated carbons. The sulfur-impregnated activated carbons were examined for the adsorptive capacity of gas-phase mercuric chloride (HgC1) by thermogravimetric analysis (TGA). The analytical precision of TGA was up to 10(-6) g at the inlet HgCl2 concentrations of 100, 300, and 500 microg/m3, for an adsorption time of 3 hr and an adsorption temperature of 150 degrees C, simulating the flue gas emitted from municipal solid waste (MSW) incinerators. Experimental results showed that sulfur modification can slightly reduce the specific surface area of activated carbons. High-surface-area activated carbons after sulfur modification had abundant mesopores and micropores, whereas low-surface-area activated carbons had abundant macropores and mesopores. Sulfur molecules were evenly distributed on the surface of the inner pores after sulfur modification, and the sulfur content of the activated carbons increased from 2-2.5% to 5-11%. After sulfur modification, the adsorptive capacity of HgCl2 for high-surface-area sulfurized activated carbons reached 1.557 mg/g (22 times higher than the virgin activated carbons). The injection of activated carbons was followed by fabric filtration, which is commonly used to remove HgCl2 from MSW incinerators. The residence time of activated carbons collected in the fabric filter is commonly about 1 hr, but the time required to achieve equilibrium is less than 10 min. Consequently, it is worthwhile to compare the adsorption rates of HgCl2 in the time intervals of < 10 and 10-60 min.     

Ozonation of activated carbon and its effects on the adsorption of VOCs exemplified by methylethylketone and benzene

Ozonation can modify the surface property of an activated carbon such as specific surface area, pore volume, and functional group. Results indicate that ozonation can increase the specific surface area of an activated carbon from 783+/-51 to 851+/-25 m2/g due in part to increasing micropores (those below 15 A). However, there is no change in macropore and mesopore upon ozonation. The amount of oxygen functional group (OFG) increases from 197+/-4 to 240+/-4 microeq/g, mostly in hydroxyl and carboxyl groups upon ozone treatment. These oxygen-containing functional groups are stable in the temperature range 30-250 degrees C, but begin to decompose when temperature increases beyond 300 and 350 degrees C. When the temperature reaches 1200 degrees C, all OFGs virtually disappear. The effect of ozone treatment on the adsorption of volatile organic carbon (VOC) was exemplified by methylethylketone (MEK) and benzene. The adsorption density of MEK and benzene by ozone treated activated carbon (AC(O3)) are greater than that by the untreated (AC), with MEK being more adsorbable than benzene. Results of factorial analysis indicate that physical characteristics, namely, micropore, BET surface area, pore diameter (PD), micropore volume (MV) play an important role on benzene and MEK adsorption.     

微波法对吸附扑热息痛废水活性炭的再生

通过微波加热的方式对用于扑热息痛废水的吸附的活性炭进行再生处理。考察了再生温度和再生时间两个因素对活性炭吸附性能和得率的影响。在最佳微波再生条件(温度为600℃,微波再生时间为15 min)下结果表明,活性炭在的亚甲基蓝吸附值和得率分别为187.5 mg/g和41.82%。对最佳条件下再生得到的活性炭进行孔结构表征,结果为,比表面积达947.9 m2/g,总孔体积为0.97 m L/g。中孔的比例占到71.18%说明活性炭主要以中孔为主。同时对废活性炭和再生活性炭进行了扫描电镜分析,结果表明,通过微波再生后的活性炭表面杂质明显减少。     

废食用油活性炭脱色工艺的研究

脱色处理是提高废食用油油品质量、利用其生产生物柴油的关键环节之一.研究餐饮废食用油活性炭吸附脱色工艺,考察典型木质活性炭和煤基活性炭对脱色效果的影响,并将活性炭结构、性能指标与其脱色能力进行关联.结果表明,以弱粘性煤和褐煤为原料制备的活性炭对废食用油脱色效果较好;活性炭的总孔容积、总比表面积、微孔比表面积、微孔容积、碘值和亚甲基蓝值等性能指标与脱色效果关联度不大,而活性炭的孔径和中孔容积是决定活性炭脱色效果的主要指标.优化后废食用油活性炭脱色工艺的主要参数是:活性炭用量7%,炭粒度100～300目,脱色温度90～120℃,吸附时间为30 min,搅拌速度为10 r/min,废食用油的脱色率在50%～65%.     

活性炭处理甲苯气体吸附再生实验研究

研究了活性炭对甲苯废气的吸附穿透过程及热空气解吸过程.穿透曲线实验结果表明,在常规空塔气速范围内,传质区高度基本在5.06～9.75 cm,传质区不饱和度在0.4～0.7.在动态运行情况下,活性炭对甲苯的饱和吸附容量在0.16～0.24 g/g.热空气吹脱实验表明,适宜的脱附工况条件为脱附温度180 ℃、脱附空气流速0.106 m/s、脱附时间40 min.     

微波辐照载甲苯活性炭再生研究

研究在微波辐照条件下,活性炭量、微波功率、载气量、加热时间等因素对载甲苯活性炭脱附的影响,在正交实验中,各个影响因素的重要性排序为：氮气流量、活性炭量、辐照时间、微波功率,最佳的操作工况为：活性炭量9 g、载气流量300 mL/min、辐照时间120 s、微波功率500W,活性炭的脱附率在99.74%.     

微波辐照载甲苯活性炭再生研究

研究在微波辐照条件下,活性炭量、微波功率、载气量、加热时间等因素对载甲苯活性炭脱附的影响,在正交实验中,各个影响因素的重要性排序为:氮气流量、活性炭量、辐照时间、微波功率,最佳的操作工况为:活性炭量9 g、载气流量300 mL/min、辐照时间120 s、微波功率500W,活性炭的脱附率在99.74%.     

An adsorption diffusion model for removal of para-chlorophenol by activated carbon derived from bituminous coal

Batch adsorption experiments were carried out to study the adsorptive removal and diffusion mechanism of para-chlorophenol (p-CP) onto Calgon Filtrasorb 400 (F400) activated carbon. The external mass transfer resistance is negligible in the adsorption process carried out under different conditions in batch operation. Intraparticle diffusion model plots were used to correlate the batch p-CP adsorption data; three distinct linear sections were obtained for every batch operation. The textural properties of F400 activated carbon showed that it has a large portion of supermicropores, which is comparable to the size of the p-CP molecules. Due to the stronger interactions between p-CP molecules and F400 micropores, p-CP molecules predominantly diffused and occupied active sites in micropore region by hopping mechanism, and eventually followed by a slow filling of mesopores and micropores. This hypothesis is proven by the excellent agreement of the intraparticle diffusion model plots and the textural properties of F400 activated carbon.     

废弃物基活性炭吸附挥发性有机污染物特性的研究

研究了废弃物基活性炭对挥发性有机污染物中的典型组分--甲苯的吸附特性.结果表明,废弃物基活性炭吸附甲苯等温线的类型系优惠型吸附等温线,表明具有良好的吸附能力;同时其吸附甲苯时穿透时间的对数与甲苯入口浓度的对数之间具有良好的线性相关性,即可由吸附高浓度甲苯时的穿透时间估算低浓度时的穿透时间;动态吸附时废弃物基活性炭的中孔对甲苯亦具有一定的吸附性能.     

微波辐照载甲苯活性炭升温研究

研究了微波功率、活性炭量和载气速度3个因素对载甲苯活性炭在微波场中升温行为的影响,并应用数值模拟,发现活性炭在微波场中的升温可以分为2个阶段,其中第1阶段升温较快,可以用线性关系式描述,而第2个阶段升温较缓慢,可以用对数函数描述.     

不同孔结构对活性炭动态吸附高浓度甲苯的影响

研究不同孔结构的活性炭对于高浓度甲苯的吸附性能、吸附行为和吸附位的影响。结果表明,微孔活性炭对甲苯的吸附量随着微孔孔容的增大而增大,0.6~1.2 nm的微孔孔容和甲苯吸附量存在良好的线性正相关。当中孔孔容达到微孔孔容的0.32倍时,微孔利用率达到100%,甲苯首先吸附在微孔中,待微孔吸附饱和,吸附位向中孔转移,中孔不仅起到通道作用,同时也起到吸附作用;当中孔孔容继续增大,增加的中孔容量主要起到吸附作用,最高吸附量达565 mg·g-1,是已有研究的2.5倍。随着吸附温度升高,饱和吸附量减少,表明活性炭吸附甲苯是以物理吸附主。     

Removal of methanol from pulp and paper mills using combined activated carbon adsorption and photocatalytic regeneration

Methanol is one of the major hazardous air pollutants emitted from chemical pulp mills. Its collection and treatment is required by the Maximum Achievable Control Technology portion of the 1998 Cluster Rule. The objective of this study is to investigate the technical feasibility of combined adsorption and photocatalytic regeneration for the removal and destruction of methanol. To facilitate the regeneration, activated carbon (AC) was coated with commercially available photocatalyst by a spray desiccation method. Laboratory-scale experiments were conducted in a fixed-bed reactor equipped with an 8 W black light UV lamp (peak wavelength at 365 nm) at the center. The photocatalyst loaded onto AC had no significant impact on the adsorption capacity of the carbon. High humidity was found to greatly reduce the material's capacity in the adsorption and simultaneous adsorption and photocatalytic oxidation of methanol. The photocatalytic regeneration process is limited by the desorption of the adsorbate. Increasing desorption rate by using purge air greatly increased the regeneration capacity. When the desorption rate was greater than the photocatalytic oxidation rate, however, part of the methanol was directly desorbed without degradation.     

沸石分子筛和活性炭吸附/脱附甲苯性能对比

考察了甲苯在NaY型沸石分子筛(简写为NaY)、13X型沸石分子筛(简写为13X)、Hβ型沸石分子筛(简写为Hβ)、MCM-22型沸石分子筛(简写为MCM-22)和ZSM-5型沸石分子筛(简写为ZSM-5)上的吸附/脱附性能,同时与椰壳活性炭(AC)的吸附/脱附性能进行对比.结果表明,各吸附剂对甲苯的平衡吸附量大小依次为:AC>NaY>Hβ>13X>MCM-22>ZSM-5,甲苯从吸附剂表面脱附难易程度依次为:AC>NaY、13X>Hβ>MCM-22>ZSM-5>ZSM-5对甲苯的平衡吸附量和吸附强度都最小,这是由于甲苯无法进入ZSM-5的内部孔道造成的;在低甲苯质量浓度(<1 000 mg/m3)时.NaY平衡吸附量超过AC,因此NaY更适合应用在低浓度有机废气吸附治理中,Langmuir吸附方程比Freundlich吸附方程更符合沸石分子筛吸附甲苯的行为.