煅烧温度对γ-Fe_2O_3催化剂结构及其脱硝活性的影响

采用沉淀-微波热解法,以Fe SO4·7H2O为铁源制备环境友好的γ-Fe2O3催化剂,结合XRD(X射线衍射)、N2等温吸附-脱附、SEM(扫描电子显微镜)、EDS(能谱仪)等手段对催化剂样品的晶相、孔结构、表面形貌、表面元素组成等进行表征,并考察其NH3-SCR(选择性催化还原)脱硝性能,研究煅烧温度对γ-Fe2O3催化剂物性及NH3-SCR脱硝性能的影响规律.结果表明:300、350和450℃下煅烧制备的催化剂中生成的杂质α-Fe2O3对SCR反应不利,而400℃煅烧制备的γ-Fe2O3催化剂脱硝性能最优,NOx转化率最高可达95%以上,XRD结果表明其纯度高,并且在60~100 nm孔径区间具有发达的孔隙结构,有利于SCR反应进行;随着煅烧温度升高,γ-Fe2O3催化剂表面晶格氧逐渐增加,颗粒形貌经历了片状颗粒(300、350℃)→球状颗粒(400℃)→针状颗粒(450℃)的变化过程,均匀的球状颗粒形貌及其表面丰富的晶格氧是400℃煅烧制得催化剂具备最优脱硝性能的重要因素.     

沿面放电氧活性物质注入协同SCR脱除烟气中NO_x

为了提高选择性催化还原(SCR)在低温区(200℃)的脱硝性能,提出利用插在烟道中的沿面放电反应器生成氧活性物质,部分氧化NO以实现低温快速SCR脱硝过程.同时,研究了氧活性物质注入实现快速SCR的脱硝性能,考察了氧活性物质注入降低二氧化硫和水蒸汽对SCR反应的影响.实验结果表明:在模拟烟气温度为150℃时,采用氧活性物质注入,部分氧化烟气中的NO以实现快速SCR反应条件下(NO/NO2浓度比为1),脱硝效率为51.9%,比标准SCR提升23%;当模拟烟气中存在SO2或H2O时,氧活性物质注入可有效降低SO2、H2O对SCR脱硝效率的影响.     

过渡金属元素掺杂改性SCR对零价汞的催化氧化性能

为提高商用SCR催化剂对Hg0(零价汞)的催化氧化活性,研究了过渡金属对其进行掺杂改性的方法,并利用固定床反应平台考察了不同试验条件下改性催化剂对Hg0的氧化效率. 结果表明:Y、Zn、Ni和Zr等过渡金属的掺杂可明显抑制SCR催化剂的催化活性,而Fe、Cu掺杂改性SCR催化剂对Hg0的催化氧化性能有显著提升. 在反应温度为350 ℃、空速比为370 000 h-1、φ(HCl)为1×10-5的条件下,Fe、Cu掺杂改性的SCR催化剂对Hg0的氧化效率均能达到90%以上,并且Fe掺杂改性后的SCR催化剂的脱硝性能也未受到明显影响. 借助XRD和XPS等表征手段,对反应前后Fe掺杂改性SCR催化剂进行了研究,表明Fe改性SCR催化剂遵循Mars-Maessen和Langmuir-Hinshelwood机制,可明显提高对Hg0的催化氧化效率,因此,应用前景较好.      

钨对高钒燃气脱硝催化剂的改性及SCR反应历程研究

针对燃气工况特点,以高钒SCR脱硝催化剂为研究对象,采用共浸渍法添加钨进行改性,考察了V_2O_5-WO_3/Ti O_2催化剂的SCR脱硝活性,表征了WO_3掺杂对V_2O_5氧化还原能力和酸性位的影响,并研究了该类型催化剂的SCR反应历程。结果表明:对于高钒脱硝催化剂,WO_3掺杂可以显著拓宽催化剂在280～440℃内的活性区间,但无法大幅提高催化剂的最高脱硝效率。活性温度区间得以拓宽的主要原因是WO_3掺杂后与V_2O_5发生强相互作用,在TiO_2表面形成V—O—W物种并提高V~(5+)物种比例,从而增加表面Br■nsted酸和Lewis酸位。在SCR脱硝反应中,催化剂表面酸性位对NH_3的吸附和活化是反应决速步骤,其后与气相NO反应,由气相中O_2补缺催化剂活化NH_3过程中消耗的晶格氧或—OH氧。     

强化SCR脱硝催化剂转化零价汞的初步研究

常规的选择性还原脱硝(SCR)催化剂对烟气中的零价汞具有一定的催化氧化作用,从而有利于提高下游的除汞效率。但在烟气HCl浓度较低时,SCR催化剂对燃煤烟气中的零价汞催化氧化效果较差。为了提高SCR催化剂对零价汞的催化氧化效果,在现有SCR催化剂基础上,通过负载其它金属元素的方法,对其进行改性掺杂。结果发现,负载锰氧化物的Mn/SCR催化剂,对零价汞的催化氧化作用明显提高,而将其再掺杂Mo后,其催化氧化性能得到更进一步提高。在反应温度350℃的条件下,加入7.5 mg/m3HCl,Mo-Mn/SCR对零价汞的催化氧化效率接近90%,而常规SCR催化剂只有35%左右。另外,Mo只有在与Mn结合使用,其促进作用才能较显著地体现出来。对改性后的SCR催化剂的脱硝性能研究表明,掺杂Mo-Mn元素对于SCR的脱硝性能无明显影响。     

氧化铁催化甲烷脱硝的实验研究

文章使用固定床反应器在350℃~850℃范围内对氧化铁催化甲烷脱硝进行了实验研究。研究结果发现在有2%氧气存在条件下,氧化铁催化甲烷脱硝的效果最高只有20%,而且在350℃~750℃范围的氧化铁催化甲烷脱硝反应机理与850℃时的脱硝反应机理并不相同。在高温的850℃~950℃范围无氧气条件下,NOx转化率随着温度升高而单调增加,随CH4/NO摩尔比的增加而升高,氧化铁催化甲烷脱硝的最佳效果可以达到将近100%。通过进一步分析发现高温850℃~950℃无氧气条件下的脱硝反应机理是在催化剂表面进行了氧化还原反应,即首先发生了CH4与Fe2O3的气固反应,将Fe2O3还原为Fe3O4,而后Fe3O4再与NO反应将其还原为N2。     

高梯度磁场中磁性可吸入颗粒物脱除试验研究

在高梯度磁场中,分别对钡铁氧体、Fe3O4和γ-Fe2O3等3种磁性可吸入颗粒物进行了脱除实验研究.通过改变外加磁场磁通密度、格栅排数、气溶胶流量、磁性可吸入颗粒物的种类,研究其脱除效率的变化规律.确定影响磁性可吸入颗粒物脱除效率的因素.结果表明:外加磁场的磁通密度越大,颗粒物的脱除效率越高,但有一定限度;格栅排数增加后,颗粒物的脱除效率得到提高;随着流量的增加,颗粒物的脱除效率有所下降;磁性颗粒的磁化率越大.颗粒脱除效率越高.     

热处理天然褐铁矿制备γ-Fe2O3及其NH3-SCR活性探究

以天然褐铁矿为前驱体,通过热处理制备γ-Fe_2O_3作为NH3-SCR催化剂.借助XRD、XRF、XPS、NH3-TPD、FR-IR等表征方法,考察反应温度、褐铁矿中的锰氧化物以及H_2O和SO_2对催化剂选择催化还原NO活性的影响并与α-Fe_2O_3作对比.结果表明,由于γ-Fe_2O_3表面比α-Fe_2O_3具有更强的酸性,使得γ-Fe_2O_3的脱硝温度窗口(200~350℃)宽于α-Fe_2O_3(200~300℃),且在活性温度窗口下,催化剂脱硝效率达到99%以上;γ-Fe_2O_3催化剂中少量MnO_2的存在,提高了催化剂低温段(100~200℃)脱硝活性,降低了高温段(400~450℃)脱硝活性;SO_2的存在会使γ-Fe_2O_3的脱硝温度窗口向高温区偏移100℃、体积分数为5%的H_2O对脱硝反应的抑制作用很小,但当SO_2和5%H_2O同时存在,尤其是SO_2的体积分数达到0.12%时,硫酸铵盐类的迅速生成会大大降低γ-Fe_2O_3的脱硝活性;此外,γ-Fe_2O_3经过NH3-SCR反应后,其磁化率略有降低,催化剂仍然具有磁回收循环利用的潜力.     

用于燃气轮机的钼改性高钒SCR脱硝催化剂

由于燃机烟气具有浓度低、NO_2及H_2O含量高等特点,传统催化剂难以直接用于其脱硝处理。文章针对高钒SCR脱硝催化剂低温活性好、宽温域、抗水性好等优势,开展高钒催化剂性能与反应机理的研究。采用浸渍法制备了一系列不同钒、钼添加量的催化剂。结果表明钒、钼的添加量(质量分数)分别为3%和4%时,催化剂具有最佳的脱硝性能,在220～440℃保持95%以上的脱硝效率。该催化剂具有较好的抗水性,O_2浓度对催化性能的影响不大,NO_x浓度过高或过低时,脱硝效率有所降低,烟气中适量NO_2的存在对催化性能有促进作用。表征结果显示,该催化剂具有较大的比表面积,活性组分均匀分散,Br?nsted酸和Lewis酸位显著增加。     

V2O5/TiO2催化剂中毒机理的试验研究

选择性催化还原(SCR)催化剂是SCR烟气脱硝技术的核心,是整个SCR系统脱硝效率和经济性的决定因素.本文工作的主要研究思路是以钒钛SCR催化剂为研究对象,研究了H2O和SO2,以及相同含量下K、Na、Ca、Pb的氧化物对钒钛催化剂NO转化率的影响.H2O的存在会抑制V2O5/TiO2催化剂脱硝活性,而SO2在一定程度上促进(V2O5/TiO2)催化剂的SCR脱硝反应,提高NO转化率;碱金属K对钒钛催化剂的钝化作用都是最强,K2O和Na2O的掺入会抑制钒钛催化剂上V2O5的还原能力,而CaO和PbO的掺入对钒钛催化剂上V2O5的还原能力影响较小.     

Kinetics of selective catalytic reduction of NO by NH_3 on Fe-Mo/ZSM-5 catalyst

The catalyst of Fe-Mo/ZSM-5 has been found to be more active than Fe-ZSM-5 and Mo/ZSM-5 separately for selective catalytic reduction (SCR) of nitric oxide (NO) with NH_3.The kinetics of the SCR reaction in the presence of O_2 was studied in this work.The results showed that the observed reaction orders were 0.74-0.99,0.01-0.13,and 0 for NO,O_2 and NH_3 at 350-450℃,respectively. And the apparent activation energy of the SCR was 65 kJ/mol on the Fe-Mo/ZSM-5 catalyst.The SCR mechanism was also deduced. Adsorbed NO species can react directly with adsorbed ammonia species on the active sites to form N_2 and H_2O.Gaseous O_2 might serve as a reoxidizing agent for the active sites that have undergone reduction in the SCR process.It is also important to note that a certain amount of NO was decomposed directly over the Fe-Mo/ZSM-5 catalyst in the absence of NH_3.     

Kinetics of selective catalytic reduction of NO by NH3 on Fe-Mo/ZSM-5 catalyst

The catalyst of Fe-Mo/ZSM-5 has been found to be more active than Fe-ZSM-5 and Mo/ZSM-5 separately for selective catalytic reduction (SCR) of nitric oxide (NO) with NH3. The kinetics of the SCR reaction in the presence of O2 was studied in this work. The results show that the observed reaction orders were 0.74-0.99, 0.01-0.13, and 0 for NO, O2 and NH3, respectively, at 350-450℃. And the apparent activation energy of the SCR was 65 kJ/mol on the Fe-Mo/ZSM-5 catalyst. The SCR mechanism was also deduced. Adsorbed NO species can react directly with adsorbed ammonia species on the active sites to form N2 and H2O. Gaseous O2 might serve as a reoxidizing agent for the active sites that have undergone reduction in the SCR process. It is also important to note that a certain amount of NO was decomposed directly over the Fe-Mo/ZSM-5 catalyst in the absence of NH3.     

Mn-CeOx/Ti-PILCs for selective catalytic reduction of NO with NH3 at low temperature

Titanium-pillared clays (Ti-PILCs) were obtained by different ways from TiCl₄, Ti(OC₃H₇)₄ and TiOSO₄, respectively. Mn-CeO_x/Ti-PILCs were then prepared and their activities of selective catalytic reduction (SCR) of NO with NH₃ at low-temperature were evaluated. Mn-CeO_x/Ti-PILCs were characterized by X-ray diffraction, N₂ adsorption, Fourier transform infrared spectroscopy, thermal analysis, temperature-programmed desorption of ammonia and H₂-temperature-programmed reduction. It was found that Ti-pillar tend to be helpful for the enlargement of surface area, pore volume, acidity and the enhancement of thermal stability for Mn-CeO_x/Ti-PILCs. Mn-CeO_x/Ti-PILCs catalysts were active for the SCR of NO. Among three resultant Mn-CeO_x/Ti-PILCs, the catalyst from TiOSO₄ showed the highest activity with 98% NO conversion at 220℃, it also exhibited good resistance to H₂O and SO₂ in flue gas. The catalyst from TiCl₄ exhibited the lowest activity due to the unsuccessful pillaring process.     

Review on the NO removal from flue gas by oxidation methods

Due to the increasingly strict emission standards of NOx on various industries, many traditional flue gas treatment methods have been gradually improved. Except for selective catalytic reduction (SCR) and selective non-catalytic reduction (SNCR) methods to remove NOx from flue gas, theoxidation method is paying more attention to NOx removal now because of the potential to simultaneously remove multiple pollutants from flue gas. This paper summarizes the efficiency, reaction conditions, effect factors, and reaction mechanism of NO oxidation from the aspects of liquid-phase oxidation, gas-phase oxidation, plasma technology, and catalytic oxidation. The effects of free radicals and active components of catalysts on NO oxidation and the combination of various oxidation methods are discussed in detail. The advantages and disadvantages of different oxidation methods are summarized, and the suggestions for future research on NO oxidation are put forward at the end. The review on the NO removal by oxidation methods can provide new ideas for future studies on the NO removal from flue gas.     

锰铈脱硝催化剂的制备及其再生性能研究

采用等体积浸渍法制备了一系列Mn-Ce-Ox复合氧化物脱硝催化剂用于NH3选择性催化还原(NH3-SCR)NO。考察了Mn/Ce摩尔比、焙烧温度、H2O和SO2对Mn-Ce-Ox复合氧化物脱硝催化剂活性的影响及催化剂中毒再生性能。结果表明:当NH3:NO=1:1,空速为5 000 h-1,550℃焙烧制得的Mn/Ce摩尔比为5∶1的Mn-Ce-Ox复合脱硝催化剂活性最佳,活性温度窗口为100~260℃,在此温度区间内催化剂活性大于90%。200℃时,Mn-Ce-Ox复合催化剂活性最高为97.84%;在10%(V/V)H2O蒸汽和300×10-6SO2共存条件下,200℃时,催化剂活性在开始反应2.5 h内迅速下降至53%左右,并在之后的6 h内没有明显变化;中毒催化剂经常温水洗再生处理、质量分数为3%的硝酸溶液再生处理和550℃焙烧2 h再生处理后200℃活性均能恢复到90%以上,其中中毒催化剂经质量分数为3%硝酸处理后活性恢复率最高。     

活性炭选择性催化还原(SCR)烟道气中NO_X

研 究了几 种已商业 化的 沥青 基活 性 炭纤 维经 硫 酸进 一 步活 化处 理 后， 对烟 道 气 中 Ｎ Ｏ Ｘ 进行选择 性催化还 原。结果 表明，当 气体中氧 含量 约低 于１０ ％ 时，硫 酸 活化 处理 可 提高 沥青 基 活性炭纤维 对 Ｎ Ｏ Ｘ 选择性催 化还原的 活性。在 本实验 条件 下，获 得 较高 的 Ｎ Ｏ Ｘ 还 原 率的 重要 条 件是气体中 氧含量 大于１０ ％ 和较 低的温度 ；将气体 中 Ｎ Ｏ 预氧化为 Ｎ Ｏ２ 可 显著提高 Ｎ Ｏ Ｘ 的还 原率；气体中水 分的存 在降低活 性炭纤维 的活性     

V_2O_5/TiO_2催化剂用于烟气同时脱硫脱硝的研究

研究了用V2O5/TiO2催化剂同时脱除烟气中的SO2和NO,考察了H2还原温度及其它反应条件对SO2和NO脱除率的影响。结果表明,经H2还原后所制得的V2O5/TiO2催化剂可以提高脱硫脱硝活性,最佳还原温度为700℃;在450～500℃的烟气温度范围内,该催化剂有较佳的脱硫脱硝活性;在相同反应温度下,空速越大,SO2和NO的脱除率越低;烟气中的氧气可大大提高V2O5/TiO2的脱硫脱硝活性,且氧气体积含量在5%～10%范围内变化时,对SO2和NO脱除率的影响较小。     

ACF负载催化剂制备对烟气脱硝影响的研究

介绍了采用浸渍法在活性炭纤维(ACF)上负载铜盐制备烟气脱硝催化剂的方法,探索了催化剂制备过程中焙烧温度、催化剂的负载方式、铜盐负离子的种类、催化组分负载量对催化剂催化活性的影响规律,实验结果表明,最佳焙烧温度范围为250～300℃,多次浸渍负载比一次浸渍负载效果要好,采用Cu(NO3)2作为负载铜离子的溶液,催化性能更好。     

Morphology-dependent interfacial interactions of Fe2O3 with Ag nanoparticles for determining the catalytic reduction of p-nitrophenol

In this work,we fabricated three kinds of Ag/Fe_2O_3 model catalysts with different morphologies to study the interfacial interactions between Ag and Fe_2O_3,and how they affected the catalytic activity in hydrogenation of p-nitrophenol was explored.The hydrothermal method was used to synthesize the metal oxide supported silver catalyst,with various morphologies including nanoplates(NPs),nanospheres(NSs),and nanocubes(NCs).The crystal structure,morphology and surface elements of the composite were investigated by various measurements,such as X-ray diffraction(XRD),scanning electron microscopy(SEM),transmission electron microscopy(TEM) and X-ray photoelectron spectroscopy(XPS).The catalytic activity was also evaluated by the reduction of p-nitrophenol to p-aminophenol.It was found that the activities of the above catalysts varied with the morphology of the support.Among them,Ag/Fe_2O_3 NPs promoted the highest performance,Ag/Fe_2O_3 NSs were slightly inferior,and Ag/Fe_2O_3 NCs were the worst.At last,we ascribed the remarkable activity of Ag/Fe_2O_3 NPs to the strong metal-support interactions between Ag and Fe_2O_3.