低浓度苯系物在室温下的MnOx/Al2O3催化O3氧化

采用固定床连续流动反应器,研究在室温下MnOx/Al2O3催化剂催化臭氧(O3)氧化.结果表明,在室温下,MnOx/Al2O3催化剂具有良好的催化O3分解和催化臭氧氧化苯系物的性能,Mn的最佳负载量为5%.当入口O3和苯系物浓度分别为70,15 mg/m3时,苯、甲苯、对二甲苯和O3的转化率分别为75%,84%,88%,90%.随着入口O3浓度的升高,苯系物转化率先升高然后基本不变,而O3转化率略有下降;随着入口苯系物浓度的升高,苯系物转化率明显降低,O3转化率略有下降.苯系物及O3转化率皆随催化反应时间的延长而缓慢降低.苯系物催化氧化反应中生成的芳香醛、芳香酸和甲酸等中间产物在催化剂表面的堆积是导致催化剂活性降低的主要原因.     

Fe掺杂Mn-Ce多孔催化剂低温脱硝性能及甲苯的影响机制

采用硬模板法制备了Fe掺杂Mn-Ce多孔催化剂,评价了催化剂低温NH₃-SCR性能及甲苯对低温NH₃-SCR性能的影响;并通过XRD、BET、SEM、HRTEM、H₂-TPR、NH₃-TPD、XPS和原位红外等对催化剂理化性质进行了表征.结果表明Fe掺杂Mn-Ce多孔催化剂具有优异的低温NH₃-SCR性能.高浓度甲苯抑制低温NH₃-SCR性能是因为甲苯的不完全氧化消耗催化剂表面的吸附氧.同时甲苯及其不完全氧化产物(主要为苯甲酸盐)不断覆盖催化剂表面的活性位点,与NH₃/NO_x的吸附和活化形成竞争关系,从而阻碍E-R和L-H机理.Fe的掺杂使得催化剂表面晶格氧浓度上升,并提高了晶格氧的迁移能力.当NH₃-SCR反应中存在甲苯时,通过Mn⁴⁺+Ce³⁺?Mn³⁺+Ce⁴⁺、Fe²⁺+Ce...     

相对干燥条件下甲苯,苯和氯仿的光催化降解

研究了甲苯,苯和氯仿3种挥发性有机物在相对干燥条件下的动态气相光催化降解,考察了进口浓度,流量(停留时间),催化剂,光源等因素的影响.研究表明,在较低污染物浓度,流量小于0.2L/min(停留时间大于3.825min)时,甲苯,苯和氯仿的光催化去除率均大于90%,遵循一级反应动力学,甲苯和苯的半衰期分别在1.0～1.34min和0.65～1.1min;在研究的负荷范围内,甲苯和苯的去除量随负荷增加达到一个最大值,而氯仿则一直随之增大;催化剂的光催化性能与污染物种类有关,同样功率的杀菌灯效果好于黑光灯.     

纳米CeO2催化氧化甲苯的形貌效应研究

采用水热法合成CeO2纳米棒、纳米颗粒和纳米立方体,利用XRD、BET-N2、TEM/HRTEM、Raman、O2-TPD和H2-TPR等表征手段进行表征,并利用连续流固定床反应法研究各催化剂对甲苯的催化氧化性能.结果表明,CeO2纳米棒因具有高比表面积和细颗粒尺寸,且表面主要暴露高活性的{100}/{110}晶面,拥有更多的氧空位和高活性氧物种,因此,催化活性最高,CeO2纳米颗粒次之,立方体最低.原位红外甲苯催化氧化机理分析进一步表明,CeO2纳米颗粒和纳米立方体上生成的羧酸盐物质难以进一步深度氧化,而纳米棒能在贫氧和低温条件下诱导甲苯的完全氧化和产物脱附,使甲苯得以快速降解.     

Catalytic performance of copper and cerium oxides-based γ-Al_2O_3 on combustion of toluene

以γ-Al2O3为载体,以复合氧化物CuxCe1-xO2为活性组分,其中,x=0.1,0.2,0.4,0.6,0.8,通过浸渍法制备了一系列CuxCe1-xO2/γ-Al2O3催化剂.在固定床反应器中评价了催化剂对甲苯的催化活性,通过XRD、SEM对催化剂进行表征,并运用ICP-MS分析并计算Cu、Ce的摩尔比以及活性组分的负载量.结果表明,在CuxCe1-xO2/γ-Al2O3催化剂中Cu、Ce摩尔比的实际值与理论值相近,活性组分的负载量在19%以上,而且对甲苯都有较好的低温催化活性,其中当x=0.2时,即Cu0.2Ce0.8O2/γ-Al2O3催化剂对甲苯的催化活性最高,其中T10=160℃,T90=265℃;当甲苯的进口浓度在700～3000mg·m-3时,进口浓度对Cu0.2Ce0.8O2/γ-Al2O3催化剂的催化活性影响较小,且经过连续80h的稳定性操作后转化率仍然保持在90%以上.     

LaBO3钙钛矿催化剂的VOCs催化燃烧特性

采用共沉淀法制备了LaBO3(B=Cr、Fe、Mn、Co、Ni)钙钛矿催化剂,并用XRD、BET、H2-TPR、O2-TPD等手段对其进行了表征,考察了催化剂对苯、甲苯、乙酸乙酯和丙酮的催化燃烧性能.结果表明,Cr、Fe钙钛矿晶相中存在少量的La2CrO6和La2O3杂晶相,破坏了其活性结构.Mn、Co、Ni则能与La形成完善的钙钛矿晶相,且表现出优良的催化性能,其中LaMnO3为阳离子缺陷结构,存在较丰富的晶格氧,更适合催化燃烧C—H键键能较高和难以活化的有机分子(如苯);LaCoO3、LaNiO3属于阴离子缺陷钙钛矿结构,存在更丰富的表面氧,更适合催化燃烧易在低温下活化的含氧类有机分子(如乙酸乙酯、丙酮).     

Au/γ-Al2O3催化剂的制备及其对气相三苯系污染物的催化消除

采用沉积一沉淀法制备了负载型Au/γ-Al2O3,催化剂,对模拟污染气体的三苯系(苯,甲苯,二甲苯)蒸气进行催化消除反应,探讨了金含量、活化条件对催化剂活性的影响.结果表明,负载型Au/γ-Al2O3催化剂用量为0.50g、反应气流速为20 mL·min-1时,295℃下可完全催化消除浓度为7.57 g·m-3的苯;在252℃下可完全催化消除浓度为7.49 g·m-3的甲苯;在235 ℃下能完全催化消除浓度为3.07 g·m-3的二甲苯.苯、甲苯和二甲苯最后都完全矿化为CO2和H2O,没有生成新的有机物.对催化反应进行了动力学研究,上述催化反应都是准一级反应.测定得到苯、甲苯和二甲苯催化反应的总包反应表观活化能分别为118.47 kj·mol-1、101.43 kJ·mol-1和85.18 kJ·mol-1.     

常压非平衡态等离子体降解挥发性烃类污染物

采用无声放电产生的非平衡态等离子体,对含有易挥发性有机化合物正己烷、环己烷、苯和甲苯4种典型的烃类废气的空气进行了处理．结果表明,对于一个大气压下正己烷含量（体积分数）为0．26％、0．79％、13％的宁气,在12kV的电压下放电ls,正己烷的降解率分别为88％、81.8％、64．9％．含有环己洗、苯及甲苯浓度为0．26％的空气,在同样的条件下,放电ls后,环己烷、苯及甲苯降解率分别为87．4％、8l％和70．3％,其主要降解产物为CO₂和H₂O．还研究了污染物浓度与氧含量对非平衡态等离子体法降解挥发性烃类污染物的影响     

β-环糊精/Ce/TiO2 光催化氧化气相甲苯

为提高光催化剂对气相污染物的吸附和光催化净化效果,选取不锈钢网作载体,由溶胶－凝胶法、2 次涂敷和烧结制备活性较高的1%Ce/TiO₂ 催化剂,经浸渍吸附β-环糊精(β-CD),获得β-CD 修饰的Ce/TiO₂ 催化剂;用X 射线衍射、扫描电镜、透射电镜等手段表征了催化剂的结构性质;考察了该催化剂对空气中甲苯污染物的光催化氧化活性.结果表明,反应4~5h,修饰薄膜催化剂可将初始浓度为70mg/m³的甲苯100%氧化去除,且重复使用3 次后去除率仍为100%;反应3h 可将初始浓度为97mg/m³ 的甲苯100％氧化;初始浓度为208mg/m³ 时,甲苯氧化转化率为80%以上.实验表明,β-CD修饰的催化剂单位面积比活性比未修饰的Ce/TiO₂催化剂提高0.59 倍,对甲苯的去除率分别增加35%和20%.     

CeO_2改性MnO_2/γ-Al_2O_3催化剂的制备及在有机废水处理中的应用

利用浸渍焙烧法制得CeO2改性MnO2/γ-Al2O3催化剂,在常温常压下采用微波诱导氧化技术,将废水中有机污染物氧化分解。初步探讨了催化剂的制备条件,结果显示,当Ce(NO3)3浸渍浓度0.01mol/L,Mn(NO3)2浸渍浓度0.05mol/L,焙烧温度350℃,焙烧时间3h时,催化剂性能达到最佳。研究了微波辐照时间、催化剂投加量、微波功率、pH值、初始浓度等因素对甲基橙处理效果的影响。在优化条件下对甲基橙的处理效果达95%以上。     

Pt/CeO2催化氧化甲苯反应机制研究

采用浸渍法制备了Pt/CeO_2和Pt/Al2O_3催化剂,并通过XRD、BET、ICP-OES、H2-TPR、XPS等手段表征其物理化学性质.结果发现,Pt/CeO_2和Pt/Al2O_3催化剂上Pt负载量约为0.6%,Al2O_3载体上Pt颗粒尺寸更小,Pt/CeO_2的可还原性更强.甲苯催化氧化活性评价结果表明,Pt/CeO_2催化剂表现出更好的催化活性,T50=170℃,T90=190℃.通过UV-Raman、甲苯TPD、GC/MS、In-situ FTIR等手段进一步研究发现,Pt/CeO_2活化甲苯及反应供氧的机制与Pt/Al2O_3存在区别,其活性更好是因为:(1)负载在CeO_2表面存在高电子密度的Pt原子,具有更强的活化甲苯能力,可以直接使苯基和甲基间的C—C链发生断裂;(2)Pt的负载促进了CeO_2氧空位形成,进一步提高了CeO_2的储氧性能,加速氧循环.除了Pt解离气相氧之外,CeO_2还可以提供活性氧物种参与催化氧化甲苯的反应,进一步提高甲苯催化氧化效率.     

Synergistic effect of Pt nanoparticles and micro-mesoporous ZSM-5 in VOCs low-temperature removal

Micro-mesoporous ZSM-5 zeolites were obtained by the post-treatment of tetrahydroxy ammonium hydroxide (TPAOH) solution with different concentration. The hierarchical pore structure formed during the desilication process facilitates the dispersion of Pt nanoparticles and Pt/ZSM-5 catalysts exhibit rather high catalytic activity for the deep oxidation of various VOCs at low temperature. The catalyst treated with TPAOH of 0.1 mol/L (Pt/ZSM-5(0.1)) shows the lowest degradation temperature (T_90%) of 128 and 142°C, respectively for benzene and n-hexane. Compared with the untreated Pt/ZSM-5 catalyst, the abundant mesopores, small Pt particle size and finely dispersed Pt contribute to the superior catalytic activity and stability of the Pt/ZSM-5 catalysts for VOCs removal. More importantly, the existence of H₂O in the feed gases hardly affected the activity of Pt/ZSM-5(0.1) catalyst at the low reaction temperature of 128°C, which is very important for VOCs low-temperature removal in the future practical applications.     

CoCuMnOx光催化氧化多组分VOCs特性及其动力学

实验采用共沉淀法制备太阳能吸收涂料Co Cu Mn O_x,探究可见光下甲苯、乙酸乙酯和丙酮混合3组分VOCs的光催化氧化性能,并从动力学角度分析各自的反应速率变化.结果表明,单组分VOCs初始浓度400 mg·m~(-3)、光照距离120 mm,350cm~2镜面载体负载1 g Co Cu Mn O_x下用100 W卤钨灯照射6 h后,甲苯转化率为57%、乙酸乙酯为62%、丙酮为58%;由于3组分VOCs之间相互竞争,甲苯、乙酸乙酯和丙酮的转化率较单组分下降了5%~26%.单组分与3组分VOCs的光催化均符合假一级反应动力学,单组分甲苯、乙酸乙酯和丙酮的反应速率分别为0.002、0.002 8和0.002 33 min~(-1);混合3组分中其反应速率为单组分的0.49~0.88倍.     

Absorption and recovery of n-hexane in aqueous solutions of fluorocarbon surfactants

n-Hexane is widely used in industrial production as an organic solvent. As an industrial exhaust gas, the contribution of n-hexane to air pollution and damage to human health are attracting increasing attention. In the present study, aqueous solutions of two fluorocarbon surfactants(FSN100 and FSO100) were investigated for their properties of solubilization and dynamic absorption of n-hexane, as well as their capacity for regeneration and n-hexane recovery by thermal distillation. The results show that the two fluorocarbon surfactants enhance dissolution and absorption of n-hexane, and their effectiveness is closely related to their concentrations in solution. For low concentration solutions(0.01%–0.30%), the partition coefficient decreases dramatically and the saturation capacity increases significantly with increasing concentration, but the changes for both are more modest when the concentration is over 0.30%. The FSO100 solution presents a smaller partition coefficient and a greater saturation capacity than the FSN100 solution at the same concentration,indicating a stronger solubilization for n-hexane. Thermal distillation is a feasible method to recover n-hexane from these absorption solutions, and to regenerate them. With 90 sec heating at 80–85°C, the recovery of n-hexane ranges between 81% and 85%, and the regenerated absorption solution maintains its original performance during reuse. This study provides basic information on two fluorocarbon surfactants for application in the treatment of industrial n-hexane waste gases.     

Highly catalytic activity of Mn/SBA-15 catalysts for toluene combustion improved by adjusting the morphology of supports

Rod-like, hexagonal and fiber-like SBA-15 mesoporous silicas were synthesized to support MnO_x for toluene oxidation. This study showed that the morphology of the supports greatly influenced the catalytic activity in toluene oxidation. MnO_x supported on rod-like SBA-15(R-SBA-15) displayed the best catalytic activity and the conversion at 230°C reached more than 90%, which was higher than the other two catalysts. MnO_x species consisted of coexisting MnO_2 and Mn_2O_3 on the three kinds of SBA-15 samples. Large amounts of Mn_2O_3 species were formed on the surface and high oxygen mobility was obtained on MnO_x supported on R-SBA-15, according to the H_2 temperature programmed reduction(H_2-TPR)and X-ray photoelectron spectroscopy(XPS) results. The Mn/R-SBA-15 catalyst with greater amounts of Mn_2O_3 species possessed a large amount of surface lattice oxygen, which accelerated the catalytic reaction rate. Therefore, the surface lattice oxygen and high oxygen mobility were critical factors on the catalytic activity of the Mn/R-SBA-15 catalyst.     

Fe/Zn-TMS体系吸收去除催化裂化干气中H2S的性能

本研究采用FeCl3·6H2O、ZnCl2和环丁砜(TMS)复配形成的Fe/Zn-TMS体系脱除催化裂化(FCC)干气中的H2S,并用30%H2O2氧化再生Fe/Zn-TMS体系.同时,研究了各活性成分比例、吸收液体积浓度、吸收液pH值等对脱硫效率的影响,以及H2O2用量、吸收富液pH值对Fe2+氧化率的影响.结果表明,n(FeCl3·6H2O)∶n(ZnCl2)∶n(TMS)为0.45∶0.55∶1,吸收液pH为0.75,体积浓度(W)为50%的条件下能长时间高效脱硫,最高脱硫率达99.9%;在n(Fe2+)∶n(H2O2)为2∶1,吸收富液pH为0.65的条件下,Fe2+氧化率达96.7%.体系可循环使用3次,且能耗低、操作简单.     

Preparation of MnO2 decorated Co3Fe1Ox powder/monolithic catalyst with improved catalytic activity for toluene oxidation

In this paper, KMnO₄ was used to pre-treat Co₃Fe-layered double hydroxides (LDH) precursor to prepare MnO₂ decorated Co₃Fe₁O_x catalyst. The toluene oxidation performance of the catalyst was investigated systematically. The optimized 0.1MnCF-LDO catalyst exhibited the best catalytic performance, and the temperatures of 50% and 90% toluene conversion (T₅₀ and T₉₀) were 218 and 243°C, respectively. The apparent activation energy (E_a) was 31.6 kJ/mol. The characterization results showed that the pre-redox reaction by KMnO₄ could increase the specific surface area, Co³⁺ species amount and oxygen defect concentration of the catalyst, which are the main reason of the improved toluene catalytic activity. Besides, this method was also applied to enhance toluene oxidation of iron mesh based monolithic catalyst. The 0.1MnCF-LDO/Iron mesh (IM) catalyst showed a 90% toluene conversion at around 316°C which was much lower than that of without MnO₂ addition (359°C). In addition, the water resistant of all the catalysts was studied as well, all the samples showed relatively good water resistance. The toluene conversion still remained to be over >80% even in the presence of 10 vol.% water vapor.     

Toluene decomposition performance and NOx by-product formation during a DBD-catalyst process

Characteristics of toluene decomposition and formation of nitrogen oxide (NOx) by-products were investigated in a dielectric barrier discharge (DBD) reactor with/without catalyst at room temperature and atmospheric pressure. Four kinds of metal oxides, i.e., manganese oxide (MnOx), iron oxide (FeOx), cobalt oxide (CoOx) and copper oxide (CuO), supported on Al₂O₃/nickel foam, were used as catalysts. It was found that introducing catalysts could improve toluene removal efficiency, promote decomposition of by-product ozone and enhance CO₂ selectivity. In addition, NOx was suppressed with the decrease of specific energy density (SED) and the increase of humidity, gas flow rate and toluene concentration, or catalyst introduction. Among the four kinds of catalysts, the CuO catalyst showed the best performance in NOx suppression. The MnOx catalyst exhibited the lowest concentration of O₃ and highest CO₂ selectivity but the highest concentration of NOx. A possible pathway for NOx production in DBD was discussed. The contributions of oxygen active species and hydroxyl radicals are dominant in NOx suppression.     

液相氧化-吸收脱除模拟烟气中NOx的研究

分别采用Na Cl O2和Na2SO3溶液作为氧化液和吸收液,在自行设计的鼓泡塔反应系统进行了液相氧化-吸收脱除模拟烟气NOx的研究,考察了气相SO2浓度、Na Cl O2和Na2SO3投加量以及p H值等因素对NO氧化和NOx脱除的影响.结果表明,SO2会优先于NO与氧化剂反应,从而增大氧化剂消耗量.偏酸性条件有利于NO氧化,但酸性太强会导致Na Cl O2分解为Cl O2逸出.碱性吸收液对NO几乎不具吸收脱除效果,但共存NO2能促进NO的吸收脱除.SO2对NO2吸收脱除具有促进作用.     

Numerical evaluation of the effectiveness of NO2 and N2O5 generation during the NO ozonation process

Wet scrubbing combined with ozone oxidation has become a promising technology for simultaneous removal of SO₂ and NO_x in exhaust gas. In this paper, a new 20-species, 76-step detailed kinetic mechanism was proposed between O₃ and NO_x. The concentration of N₂O₅ was measured using an in-situ IR spectrometer. The numerical evaluation results kept good pace with both the public experiment results and our experiment results. Key reaction parameters for the generation of NO₂ and N₂O₅ during the NO ozonation process were investigated by a numerical simulation method. The effect of temperature on producing NO₂ was found to be negligible. To produce NO₂, the optimal residence time was 1.25 sec and the molar ratio of O₃/NO about 1. For the generation of N₂O₅, the residence time should be about 8 sec while the temperature of the exhaust gas should be strictly controlled and the molar ratio of O₃/NO about 1.75. This study provided detailed investigations on the reaction parameters of ozonation of NO_x by a numerical simulation method, and the results obtained should be helpful for the design and optimization of ozone oxidation combined with the wet flue gas desulfurization methods (WFGD) method for the removal of NO_x.