Fixed-Bed Column Adsorption Modeling of MnO4- Ions from Acidic Aqueous Solutions on Activated Carbons Prepared with the Biomass

Activated carbons calcined at 400˚C and 600˚C (AC-400 and AC-600), prepared using palm nuts, collected in the town of Franceville in Gabon, were used to study the dynamic adsorption of MnO4- ions in acidic media on fixed bed column and on the kinetic modeling of experimental data of breakthrough curves of MnO4- ions obtained. Results on the adsorption of MnO4- ions in fixed-bed dynamics obtained on AC-400 and AC-600 adsorbents beds indicated that the AC-400 bed appears to be the most efficient in removing MnO4- ions in acidic media. Indeed, the adsorbed amounts, the adsorbed capacities at saturation and the elimination percentage of MnO4- ions obtained with AC-400 (31.24 mg;52.06 mg·g-1 and 41.65% respectively) were higher compared to those obtained with AC-600 (9.87 mg;16.45 mg·g-1 and 17.79% respectively). The breakthrough curves kinetic modeling revealed that the Thomas model and the pseudo-first-order kinetic model were the most suitable models to describe the adsorption of MnO4- ions on adsorbents studied in our experimental conditions. The results of the intraparticle diffusion model showed that intraparticle diffusion was involved in the adsorption mechanism of MnO4- ions on investigated adsorbents and was not the limiting step and the only process controlling MnO4- ions adsorption. In contrast to AC-400, the intraparticle diffusion on AC-600 bed plays an important role in the adsorption mechanism of MnO4- ions.

Characterization and Methanol Adsorption of Walnutshell Activated Carbon Prepared by KOH Activation

Walnut-shellactivated carbons（WSACs）were prepared by the KOH chemicalactivation.The effects of carbonization temperature,activation temperature,and ratio of KOH to chars on the pore development of WSACs were investigated.Fourier transform infrared spectroscopy（FTIR）,X-ray powder diffraction（XRD）,and scanning electron microscopy（SEM）were employed to characterize the microstructure and morphology of WSACs.Methanoladsorption performance onto the optimalWSAC and the coal-based AC were also investigated.The results show that the optimalpreparation conditions are a carbonization temperature of 700 ℃,an activation temperature of 700 ℃,and a mass ratio of 3.The BET surface area,the micropore volume,and the micropore volume percentage of the optimalWASC are 1636 m^2/g,0.641 cm^3/g and 81.97%,respectively.There are a lot of micropores and a certain amount of meso-and macropores.The characteristics of the amorphous state are identified.The results show that the optimalWSAC is favorable for methanoladsorption.The equilibrium adsorption capacity of the optimalWSAC is 248.02mg/g.It is shown that the equilibrium adsorption capacity of the optimalWSAC is almost equivalent to that of the common activated carbon.Therefore the optimalWSAC could be a potentialadsorbent for the solar energy adsorption refrigeration cycle.

CaCl_(2)/石墨烯复配对活性炭-甲醇工质对吸附解吸特性的影响

为同步增强活性炭-甲醇吸附制冷系统的热质传递能效,本文在压块活性炭制备工艺中引入炭素前驱体原位CaCl_(2)浸渍嵌合与石墨烯复配过程,制备了中、微孔同步发达的新型炭材料CA-GC及石墨烯复配炭SC-GC;并对其吸附/解吸特性、导热系数及制冷特性进行对比研究。结果表明:CaCl_(2)浸渍嵌合显著提升了炭表面及炭骨架内部的钙氧化物吸附点位丰度(灰分达到19.38%),从而显著提升了CA-GC的Sokoda&Suzuki平衡吸附量((533.38±6.97)mg/g)和导热系数((1.058±0.77)W/(m·K))。石墨烯的复配过程进一步强化了复合炭材料SC-GC的导热系数((2.61±0.15)W/(m·K))和平衡吸附量((712.84±30.66)mg/g)。当解吸温度为100℃,循环时间60 min时,基于SC-GC构建的吸附制冷床连续制冷循环脱附量、制冷量和制冷功率分别达到(533.10±14.17)mg/g、(486.95±9.79)kJ/kg和(973.86±15.28)kJ/(kg·h)。

A Novel Sulfided Mo/C Catalyst for Direct Vapor Phase Carbonylation of Methanol at Atmospheric Pressure

The direct carbonylation of methanol, without any halide in the feed as apromoter, is presented. A series of Mo catalysts supported on activated carbon, γ-Al_2O_3 and SiO_2were prepared. The results show that the support greatly affects the Mo catalyst in the directvapor-phase carbonylation of methanol, and activated carbon is the best supports of the investigatedsupports. In addition, the relationships between adsorptions of NH_3 and CO and carbonylation ofmethanol were investigated. A novel sulfided Mo/C catalyst had high activity and selectivity for thevapor phase carbonylation of methanol to methyl acetate without the addition of a CH_3I promoter tothe feed. The reaction conditions were optimized at a reaction temperature of 573 K, a methanolconcentration of 23 mol% and a carbon monoxide space velocity of 3,000 L/(kg·h). Under theseoptimal conditions a methanol conversion of 50%, carbonylation selectivity of 80 rnol%, andspace-time yield of 8.0 mol/(kg·h) were obtained. The active phase of this novel sulfided Mo/Ccatalyst is the non-crystalline phase, and the active component is present as MoS_(2.5) on thesurface of the activated carbon.

一种有潜力的吸附式制冷工作对——活性炭纤维-甲醇

吸附式制冷具有无ＣＦＣｓ问题、可利用低品位热能驱动、价格效用比高等一系列优点。由于一般吸附剂吸附／解吸时间长和单位质量制冷功率小使吸附式制冷的产品化受阻。活性炭纤维是一般吸附剂活性炭的较好替代物，其对甲醇的吸附容量为活性炭的２—３倍，而吸附／解吸时间仅为活性炭的１／１０左右。对紧凑式吸附式冰箱，活性炭纤维－甲醇是一种好的工作对。

草酸二甲酯对甲醇-碳酸二甲酯二元物系汽液平衡的影响

用气相单循环平衡蒸馏器测定了甲醇 ( 1) -碳酸二甲酯 ( 2 )物系的常压汽液相平衡数据 ,用积分法对其进行了热力学一致性检验 ,并用Wilson方程对试验数据进行了关联 ,得到了液相活度系数参数。测定了加入萃取剂草酸二甲酯 (DMO)对甲醇 ( 1) -碳酸二甲酯 ( 2 )

CeO_(2)载体在CO_(2)加氢制甲醇中的应用和研究进展

随着经济的快速发展,CO_(2)排放导致的温室效应日益严峻,通过与绿氢反应将其转化为甲醇等有价值的化工产品是减少CO_(2)排放、缓解全球气候变暖的有效途径。近年来,CeO_(2)负载金属催化剂在CO_(2)加氢制甲醇反应中得到了广泛关注。本文主要综述了CeO_(2)表面氧空位和碱性位点、Ce3+/Ce4+可逆氧化还原能力、几何形貌等特性在CO_(2)/H_(2)吸附活化和甲醇形成过程中所起到的重要作用,比较了CeO_(2)与ZrO_(2)、ZnO以及复合金属氧化物等载体在反应中的差异,提出了CeO_(2)载体催化剂在确认活性关键中间体、兼顾CO_(2)转化率和甲醇选择性、提高催化活性与稳定性等方面的不足和挑战,以期为新型CO_(2)加氢制甲醇催化剂的设计提供有益参考。

甲醇气相氧化羰化法合成碳酸二甲酯的Cu-AC催化剂活性研究

采用连续流动固定床反应器,研究了用于甲醇直接氧化羰化合成碳酸二甲酯的负载型Cu-AC催化剂。分别考察了铜离子价态、浸渍溶剂、铜含量和载体活性炭孔修饰对催化剂活性的影响。结果表明,由浓氨水为浸渍溶剂,AC为载体,CuCl活性组分制得的Cu-AC催化剂具有较高的催化活性和DMC选择性;催化剂中Cu质量分数达7.5%时,催化剂的活性最高,Cu质量分数过高,易使催化剂表面富集大量CuO物种,导致DMC选择性及收率明显下降;以CuCl_2为活化剂,制得的AC可明显改善载体的孔结构性质和孔径分布,孔径分布主要由修饰前的1.5 nm较大微孔区转变为2.5 nm左右的中孔区域;中孔分布比例较大且孔径范围在2.5 nm左右的AC载体有利于该活性组分的分散及甲醇氧化羰化催化活性的提高;在Cu质量分数5%时,甲醇转化率可达35.0%,DMC时空收率为211.9 g/(kg·h),且DMC选择性仍在95%以上。

活性炭-甲醇工质对吸附制冷相关性能研究

以活性炭-甲醇作为工质对,采用静态重量法对其进行吸附等温线测定,目的在于研究该工质对与吸附制冷相关的吸附率、吸附速度和吸附热等性质.试验数据分析表明,吸附率可以D-A方程较好的描述,回归得出了相应的方程参数.吸附速度一般以Sakoda-Suzuk i方程描述,研究发现,方程中的吸附速度常数不只是温度的函数,它同时还受系统压力的影响,因此对原方程作了相应的改进.吸附热通过两种途径分别求取,一是利用实测吸附等温线,二是利用由特性吸附曲线预测的吸附等温线,第二种方法可以更为清晰地描述吸附热的变化规律.

污泥基活性炭-甲醇工质对吸附/解吸特性

将市政生物污泥资源转化与吸附制冷能效提升相交叉融合,通过炭素前驱体进行复配、KOH催化炭化及磷酸催化活化相结合的压块炭改进工艺对污泥基活性炭的孔结构进行原位调控,制备了4种新型污泥基活性炭(WNC-4/3/2/1);对比研究了以污泥炭和甲醇制冷剂为工质对的吸附制冷床的吸附/脱附循环、制冷量及制冷功率变化特性.结果表明:KOH和磷酸浸渍过程可分别促进微孔及中孔结构的发育,WNC-4的总孔、微孔及中孔容积分别达到0.6960,0.1641和0.5319cm^(3)/g.比表面积与孔结构容积水平的同步提升与甲醇制冷剂吸附/脱附量呈良好的相关性(R^(2)>0.90).基于Langmuir吸附等温模型(R^(2)=0.9939)计算的最大吸附量Q_(L)^(*)达到(552.67±23.83)mg/g;基于Sokoda-Suzuki方程计算的40min内的平衡吸附量和脱附量分别为(372.94±9.504)和(412.55±8.309)mg/g.脱附温度为100℃时,WNC-4吸附制冷系统的稳定脱附量、制冷量和制冷功率分别达到(328.81±10.74)mg/g,(300.34±9.81)kJ/kg和(600.68±19.62)kJ/(kg·h).

改性活性炭-甲醇工质对吸附性能的研究

本文根据活性炭在吸附制冷系统中所处的环境特点,制备了多个试样,通过实验的方式表征了这些试样的pH值、吸附量及失重率等参数,并获得了吸附等温曲线和热重/微商热重(TG/DTG)曲线。通过数据对比可知,被大气粉尘或铜离子Cu2+污染及高浓度酸碱的浸泡会降低活性炭-甲醇的吸附性能,低浓度酸碱浸泡会提高活性炭-甲醇的吸附性能,蒸馏水对活性炭-甲醇的吸附性能无影响。此外,经大气污染和酸碱浸泡后的活性炭热稳定性下降。

活性炭-甲醇系统Sakoda-Suzuki方程的修正

目前吸附制冷研究中广为采用的吸附速度方程是Sakoda-Suzuki方程,对于确定的工质对,该方程中的吸附速度常数一直被认为只是温度的函数.采用改进的静态重量法进行活性炭甲醇系统吸附速度的试验研究,结果表明,吸附速度常数还随着系统压力的升高而减小.据此,对Sakoda-Suzuki方程进行修正,提出新的吸附速度常数表达形式,并利用微孔吸附机理分析系统压力对吸附速度常数产生影响的原因.修正后的吸附速度方程与试验结果更为接近.

孔结构分布对活性炭-甲醇工质对吸附制冷特性的影响

本文通过前体物复配、催化炭化、CO2接触氧化与梯度催化活化相结合的改进工艺,对压块活性炭的孔结构进行原位调控,制备了中微孔同步发达的GHUM型与中孔发达的SX-100型活性炭;以微孔炭GDWK-02为参比,研究了孔结构分布调控对活性炭-甲醇工质对的吸附/脱附特性及制冷性能的影响。结果表明:中微孔同步发达的GHUM炭孔结构促进了对制冷剂的凝聚与扩散作用,对甲醇的吸附量((368.04±4.64)mg/g)、脱附量((375.92±7.38)mg/g)及表面扩散系数(299.32±123.16)较SX-100和GDWK-02均有所提升;且脱附温度为100℃时,GHUM型吸附床内部传热温差高达50℃,制冷室平均温度维持在(23±1)℃,系统制冷量和制冷功率分别可达286.12 kJ/kg、357.65 kJ/(kg·h),满足夏季制冷送风空调系统维持室内恒温的需求,且显示了良好的传热和制冷性能。

铁盐浸渍强化污泥活性炭-甲醇热质传递特性

针对以市政污泥为核心的炭素前驱体开展原位铁盐浸渍磁修饰,通过响应曲面试验设计优化并制备了新型原位浸渍炭IM-WNC;以成品炭的后浸渍磁修饰炭PM-WNC为参比,考察了原位浸渍与后浸渍磁修饰过程对污泥活性炭-甲醇工质对的吸附/解吸速率、吸附等温线、吸附床传热性能、制冷量及制冷功率等方面的影响.结果表明:与后浸渍过程相比,原位铁盐浸渍有利于保持污泥炭总孔容积(0.6608cm^(3)/g)及比表面积(1122m^(2)/g)水平,能显著提升致密化污泥炭IM-WNC的导热系数(600kg/m^(3),4.586W/(m·K))、甲醇Sokoda&Suzuki平衡吸附量((528.74±15.86)mg/g)和Langmuir最大吸附量((673.99±13.52)mg/g).升温脱附与冷却吸附循环体系内,IM-WNC致密化吸附床中心温度峰谷差值可达到69.07℃.当循环时间为76min,解吸温度为100℃时,IM-WNC吸附制冷床的制冷量和制冷功率分别达到501.43kJ/kg和799.06kJ/(kg·h),较PM-WNC分别提升了15.61%和18.69%.

Pt-CeO2/聚苯乙烯磺酸盐功能化碳纳米管复合物的制备及对甲醇的电催化氧化性能

通过阴离子聚合物聚苯乙烯磺酸钠(PSS)对碳纳米管(CNTs)进行非共价功能化修饰得到PSS功能化的碳纳米管(PSS-CNTs),利用带负电的PSS和Ce3+之间的静电作用将Ce3+组装到CNTs表面,再利用Ce3+与Pt Cl2-4之间存在的静电作用和氧化还原反应实现CeO_2和Pt纳米粒子在CNTs表面的原位沉积,得到复合催化剂Pt-CeO_2/PSS-CNTs.采用透射电子显微镜(TEM)、X射线衍射仪(XRD)、能谱仪(EDS)及拉曼光谱仪(Raman)等对催化剂进行了表征.电化学性能测试结果表明,由于PSS-CNTs表面原位沉积的Pt纳米粒子相对于在原始CNTs上沉积的Pt纳米粒子具有更小的粒径、更好的分散均匀性和稳定性,同时Pt与CeO_2之间存在良好的协同效应,Pt-CeO_2/PSS-CNTs催化剂对甲醇电催化氧化具有较好的催化活性和化学稳定性,当nPt/nCe=2/3时催化性能最优.

PtRu/LSC-s催化剂对甲醇的电化学氧化

以莲蓬壳(LS)为原料,经水热反应、盐封和碳化活化处理,得到O掺杂的介孔碳材料LSC-s。采用浸渍化学还原法负载PtRu纳米粒子,制得负载型催化剂PtRu/LSC-s。PtRu/LSC-s催化剂用于甲醇电氧化的起始氧化电位为0.29 V,峰电流为798.4 m A/mgPt,稳定电流为27.8 m A/mgPt,催化活性优于商业PtRu/C催化剂,还具有抗CO毒性强的优点。

RK-05低压甲醇催化剂在焦炉气制甲醇中的应用

介绍了RK-05型低压甲醇催化剂在焦炉气制甲醇装置上的升温还原及使用情况。结果显示,该催化剂在低温区(210℃～225℃)表现出较好的催化活性;在催化剂进入稳定期后,甲醇产量稳定,总碳平均利用率为95.5%,粗醇中副产物乙醇质量分数小于230×10-6。

Extraction of copper ions by supercritical carbon dioxide

Complexation combined with supercritical fluid extraction was used to extract Cu2+ in this study. The effects of pressure, temperature, volume of CO2 on the efficiency of extraction were systematically investigated. At the optimum condition a 57.32% recovery was achieved. Addition of suitable amount of methanol (v/v = 5%) to the supercritical CO2 can increase in the extraction of Cu2+ (72.69%, RSD = 2.12%, n = 3). And the recovery can further increase in the presence of non-ionic surfactant Triton X-100 because of its function of solubilization. Surfactant was first used in the extraction of metal ions in the present study, and the results are satisfied (90.52%, RSD = 2.20%, n = 3).

微波改性对活性炭及其甲醇吸附的影响

分别在600,700和800℃下对活性炭进行微波辐照加热改性.采用比表面积及孔径分析仪、Boehm滴定、傅立叶转换红外光谱对活性炭的物化性质进行表征.并且在10℃下以甲醇为吸附质进行固定床吸附实验.研究表明:微波改性后,活性炭的比表面积、总孔容小幅度减小,但微孔比表面积显著增大;随着温度升高,活性炭表面酸性基团大量分解,碱性基团逐渐形成.Langmuir方程和Freundlich方程均能较好的描述甲醇在活性炭上的吸附.准二阶动力学方程最适合描述甲醇的动态吸附过程,说明甲醇吸附是一个物理和化学复合的吸附过程,吸附受到活性炭表面官能团的影响.颗粒内扩散模型拟合结果分为3个线性阶段:表面吸附阶段、渐近吸附阶段和吸附平衡阶段.微波改性后活性炭对甲醇的吸附能均增大,吸附能与活性炭表面含氮官能团总量成正比.

国产活性炭－甲醇吸附式制冷性能研究

建立了一套活性炭－甲醇吸附容量测定试验台，对国产活性炭的吸附性能进行了测试，得到有关吸附方程式Ｄｕｂｉｎｉｎ－Ａｓｔａｋｈｏｖ（Ｄ－Ａ）的关联参数，并对国产活性炭－甲醇吸附式制冷循环进行了模拟计算，讨论了循环ＣＯＰ及单位质量活性炭制冷量Ｑｆ等主要参数。与国际上流行的活性炭ＡＣ－３５相比，国产活性炭材料作为固体吸附式制冷机的吸附剂；具有与ＡＣ－３５相近的ＣＯＰ，但单位质量制冷量Ｑｆ较ＡＣ－３５差些。