采用杂多酸化合物溶液同时脱硫脱氮的实验研究

本文对液相催化氧化脱硫脱氮的新方法进行了研究，在鼓泡反应发生器内进行了液相催化氧化脱硫脱氮的实验。采用钼硅酸溶液及其还原产物脱除烟气中的SO2和NOx，分别就吸收液的浓度、pH值、温度、停留时间等因素对SO2和NOx去除效率的影响及其变化规律进行了研究。实验结果表明，钼硅酸能十分有效地吸收SO2，将SO2氧化成H2SO4，并使杂多酸还原为杂多蓝。随后又被用于去除NOx，把NOx还原成N2，蓝色溶液再次被氧化成为黄色溶液。     

软锰矿催化氧化脱除烟气中的SO2

对软锰矿催化氧化法去除烟气中SO2的方法进行了探索，研究了各工艺参数对烟气中SO2去除率的影响。结果表明：MnO2与Mn^2 的催化效果较好，传质过程对脱硫过程的影响较大，软锰矿浆在合适条件下能有效吸收低浓度的SO2。     

Fenton氧化法同时脱硫脱硝的实验研究

应用Fenton液相氧化吸收法进行同时脱硫脱硝实验。首先,利用单因素实验,分别考察了H2O2浓度、Fe2+投加量、初始pH值、UV照射和温度对脱硫脱硝的影响。结果表明,SO2和NO去除率随着H2O2浓度和Fe2+投加量的增大而提高;初始pH对SO2和NO的去除有较大影响;UV能促进SO2和NO的净化;温度对脱硫效率影响不大,但对NO的去除有显著作用,适当升温可以提高脱硝效率。随后,考察了SO2对NO去除率的影响。通过单独脱硝和同时脱硫脱硝的对比实验发现,SO2的加入对NO的去除有一定的促进作用,Fenton法可同时获得起始约80%的脱硝效率和98%以上的脱硫效率。     

环保催化剂在环境保护中的应用研究进展

环境问题是人类不能回避的现实问题 ,以环境保护为目的的催化化学在解决环境保护问题中起着核心作用。本文从狭义上综述了除去SO2 、NOX、CO2 及N2 O等污染物质用的环保催化剂的种类和应用研究进展以及未来环保催化剂的研究发展方向。重点介绍了环保催化剂在脱硫、脱氮及净化汽车尾气方面的应用情况     

湿式烟气脱硫系统同时脱汞研究

研究表明,湿法烟气脱硫装置(WFGD)可去除烟气中绝大部分Hg²⁺,但对单质汞的吸收效果不明显,因此研究提高湿法烟气脱硫系统中单质汞的氧化率的方法对控制汞的排放具有重要意义。综述了WFGD及在此系统中各种添加剂的脱汞性能,认为在添加剂中,气态的臭氧、液态的次氯酸和氯化钠稀溶液、 黄磷乳浊液、氢硫化钠溶液及EDTA的汞去除效果较好,且不会被SO₂大量消耗,可在WFGD系统实现同时脱硫脱汞;而气态的氯气,液态的K₂S₂O₈溶液虽然也有较好的汞去除效果,但因易被SO₂或亚硫酸盐溶液消耗,当在WFGD系统中用其氧化单质汞时,需要对脱硫塔进行分层或其他改造,使烟气中的SO₂被吸收后再控制汞,提高经济性。     

液相催化氧化法用于燃煤工业锅炉烟气脱硫的研究

对采用金属离子液相催化氧化脱硫进行了较详细的实验研究。在鼓泡反应器上的研究结果显示Mn Fe协同催化氧化脱硫具有较好的效果 ,研究结果可以为金属离子液相催化氧化脱硫提供参考。     

液相催化氧化法用于燃煤工业锅炉烟气脱硫的研究

对采用金属离子液相催化氧化脱硫进行了较详细的实验研究。在鼓泡反应器上的研究结果显示Mn—Fe协同催化氧化脱硫具有较好的效果，研究结果可以为金属离子液相催化氧化脱硫提供参考。     

尿素/高锰酸钾湿法烟气脱氮的试验研究

采用高锰酸钾和尿素配制成不同浓度的吸收溶液,在填有金属鲍尔环的管式吸收反应器中,对模拟烟气进行湿法烟气脱氮的研究。试验结果表明,用尿素和高锰酸钾配制成的吸收液进行湿法烟气脱氮,可以高效地脱除模拟烟气中的氮氧化物,高锰酸钾含量的增加可以显著提高脱氮效率,是决定脱氮效率高低的重要因素,在尿素和高锰酸钾含量分别为5%和0.60g/L时可以达到91.5%的平均脱氮效率;尿素含量、吸收液有效柱高和外加的SO2气体均对脱氮效率产生不同程度的影响。     

尿素／高锰酸钾湿法烟气脱氮的试验研究

采用高锰酸钾和尿素配制成不同浓度的吸收溶液，在填有金属鲍尔环的管式吸收反应器中，对模拟烟气进行湿法烟气脱氮的研究。试验结果表明，用尿素和高锰酸钾配制成的吸收液进行湿法烟气脱氮，可以高效地脱除模拟烟气中的氮氧化物，高锰酸钾含量的增加可以显著提高脱氮效率，是决定脱氮效率高低的重要因素，在尿素和高锰酸钾含量分别为5％和0.60g／L时可以达到91．5％的平均脱氮效率；尿素含量、吸收液有效柱高和外加的SO2气体均对脱氮效率产生不同程度的影响。     

氧化锌吸收-空气氧化法烟气脱硫实验研究

采用次氧化锌配制成的悬浮浆液脱除吸收模拟烟气中的SO2,吸收产物亚硫酸锌浆液再通过鼓风湿式氧化成硫酸锌溶液,以验证氧化锌吸收空气氧化法烟气脱硫的效果。通过改变气体流量、SO2浓度、浆液温度及pH值等工艺参数,探索吸收和氧化过程的最佳控制条件。结果表明,氧化锌浆液对含SO2浓度从5800～8600mg/m3的烟气脱除效率均可达到90%以上,吸收容量为39gSO2/15g次氧化锌;氧化过程控制吸收终点浆液pH值为50以及浆液温度在38℃,氧化率可达95%。     

Predicting extents of mercury oxidation in coal-derived flue gases

The proposed mercury (Hg) oxidation mechanism consists of a 168-step gas phase mechanism that accounts for interaction among all important flue gas species and a heterogeneous oxidation mechanism on unburned carbon (UBC) particles, similar to established chemistry for dioxin production under comparable conditions. The mechanism was incorporated into a gas cleaning system simulator to predict the proportions of elemental and oxidized Hg species in the flue gases, given relevant coal properties (C/H/O/N/S/Cl/Hg), flue gas composition (O2, H2O, HCl), emissions (NO(X), SO(X), CO), the recovery of fly ash, fly ash loss-on-ignition (LOI), and a thermal history. Predictions are validated without parameter adjustments against datasets from lab-scale and from pilot-scale coal furnaces at 1 and 29 MWt. Collectively, the evaluations cover 16 coals representing ranks from sub-bituminous through high-volatile bituminous, including cases with Cl2 and CaCl2 injection. The predictions are, therefore, validated over virtually the entire domain of Cl-species concentrations and UBC levels of commercial interest. Additional predictions identify the most important operating conditions in the furnace and gas cleaning system, including stoichiometric ratio, NO(X), LOI, and residence time, as well as the most important coal properties, including coal-Cl.     

Effects of sulfur dioxide and nitric oxide on mercury oxidation and reduction under homogeneous conditions

This paper is particularly related to elemental mercury (Hg0) oxidation and divalent mercury (Hg2+) reduction under simulated flue gas conditions in the presence of nitric oxide (NO) and sulfur dioxide (SO2). As a powerful oxidant and chlorinating reagent, Cl2 has the potential for Hg oxidation. However, the detailed mechanism for the interactions, especially among chlorine (Cl)-containing species, SO2, NO, as well as H2O, remains ambiguous. Research described in this paper therefore focused on the impacts of SO2 and NO on Hg0 oxidation and Hg2+ reduction with the intent of unraveling unrecognized interactions among Cl species, SO2, and NO most importantly in the presence of H2O. The experimental results demonstrated that SO2 and NO had pronounced inhibitory effects on Hg0 oxidation at high temperatures when H2O was also present in the gas blend. Such a demonstration was further confirmed by the reduction of Hg2+ back into its elemental form. Data revealed that SO2 and NO were capable of promoting homogeneous reduction of Hg2+ to Hg0 with H2O being present. However, the above inhibition or promotion disappeared under homogeneous conditions when H2O was removed from the gas blend.     

Simultaneous absorption of NO and SO2 into hexamminecobalt(II)/iodide solution

An innovative catalyst system has been developed to simultaneously remove NO and SO2 from combustion flue gas. Such catalyst system may be introduced to the scrubbing solution using ammonia solution to accomplish sequential absorption and catalytic oxidation of both NO and SO2 in the same reactor. When the catalyst system is utilized for removing NO and SO2 from the flue gas, Co(NH3)(6)2+ ions act as the catalyst and I- as the co-catalyst. Dissolved oxygen, in equilibrium with the residual oxygen in the flue gas, is the oxidant. The overall removal process is further enhanced by UV irradiation at 365 nm. More than 95% of NO is removed at a feed concentration of 250-900 ppm, and nearly 100% of SO2 is removed at a feed concentration of 800-2500 ppm. The sulfur dioxide co-existing in the flue gas is beneficial to NO absorption into hexamminecobalt(II)/iodide solution. NO and SO2 can be converted to ammonium sulfate and ammonium nitrate that can be used as fertilizer materials. The process described here demonstrates the feasibility of removing SO2 and NO simultaneously only by retrofitting the existing wet ammonia flue-gas-desulfurization (FGD) scrubbers.     

The importance of the location of sodium chlorite application in a multipollutant flue gas cleaning system

In this study, removing sulfur dioxide (SO2), nitrogen oxides (NO(x)), and mercury (Hg) from simulated flue gas was investigated in two laboratory-sized bubbling reactors that simulated an oxidizing reactor (where the NO and Hg(0) oxidation reactions are expected to occur) and a wet limestone scrubber, respectively. A sodium chlorite solution was used as the oxidizing agent. The sodium chlorite solution was an effective additive that enhanced the NO(x), Hg, and SO2 capture from the flue gas. Furthermore, it was discovered that the location of the sodium chlorite application (before, in, or after the wet scrubber) greatly influences which pollutants are removed and the amount removed. This effect is related to the chemical conditions (pH, absence/presence of particular gases) that are present at different positions throughout the flue gas cleaning system profile. The research results indicated that there is a potential to achieve nearly zero SO2, NO(x), and Hg emissions (complete SO2, NO, and Hg removals and -90% of NO(x) absorption from initial values of 1500 ppmv of SO2, 200 ppmv of NO(x), and 206 microg/m3 of Hg(0)) from the flue gas when sodium chlorite was applied before the wet limestone scrubber. However applying the oxidizer after the wet limestone scrubber was the most effective configuration for Hg and NO(x) control for extremely low chlorite concentrations (below 0.002 M) and therefore appears to be the best configuration for Hg control or as an additional step in NO(x) recleaning (after other NO(x) control facilities). The multipollutant scrubber, into which the chlorite was injected simultaneously with the calcium carbonate slurry, appeared to be the least expensive solution (when consider only capital cost), but exhibited the lowest NO(x) absorption at -50%. The bench-scale test results presented can be used to develop performance predictions for a full- or pilot-scale multipollutant flue gas cleaning system equipped with wet flue gas desulfurization scrubber.     

电化学法去除SO2/NOX的研究进展

本文对采用电化学方法去除SO2/NOx废气这一新的研究方法进行了综述.在用酞花青钴(CoPc)修饰的碳气体扩散电极上,SO2在空气中的体积百分数在20%以下时可以完全被氧化为硫酸,以连二硫酸盐(S2O2-4)作还原剂,Fe2+-EDTA作络合剂时,NO以90%以上的程度还原为NH+4与NH2(SO3H)等低价含氮化合物,产物中未见N2、N2O与NO2等气体,氧化产物SO2-3(或HSO-3)在Pb阴极上还原再生为S2O2-4.用Ce4+作氧化剂可将SO2/NO2氧化为相应的酸,还原产物Ce3+经电解氧化后循环使用.     

脉冲电晕法脱硫脱硝研究概述

本文概述了脉冲电晕脱硫脱硝研究所得的重要成果，着重总结了国内外有关电晕特性、反应机理、电源与反应器系统研究所得的重要结论。最后对该技术的前景作一展望。     

H2O2溶液同时脱硫脱硝实验研究

二氧化硫和氮氧化物是电厂产生的主要大气污染物,研究焦点越来越集中在在一个反应器内实现同时脱硫脱硝。实验以H2O溶液作为吸收液,在自制的鼓泡反应器内,对模拟烟气进行同时脱硫脱硝的实验研究,实验结果表明：H2O浓度、反应温度、NO浓度、SO2浓度、烟气流量对脱除率影响显著,pH、氧含量对脱硝率影响不大。在整个实验范围内脱硫效率总是保持在98．5％以上,脱硝效率最高达到67．4％。     

Effect of solution pH on SO2, NO(x), and Hg removal from simulated coal combustion flue gas in an oxidant-enhanced wet scrubber

This paper presents a study on the simultaneous removal of SO2, NO(x) and Hg (both Hg0 and Hg2+) from a simulated flue gas by oxidant injection in a bench-simulated wet limestone scrubber for a wide range of slurry pH. The slurry pH strongly influenced the chemical mechanism in the scrubber and, therefore, affected pollutant removal. This paper also examines the potential ClO2(gas) reemission from a developed multipollutant scrubber at different slurry pHs. To better understand the chemical mechanisms at each slurry pH and to apply a mass balance to the process, detailed product ion analyses were performed for all experiments. Ion analysis covered three different chlorine species (chlorite, chloride, chlorate), sulfate, nitrite and nitrate. Different NO(x) removal efficiencies and mechanisms were found in acidic and alkaline pHs in the multipollutant scrubber. The acidic solution was favorable for NO and Hg0 oxidation, but increasing the slurry pH above 7.0 was disadvantageous for NO and Hg oxidation/removal. However the rate of NO(x) absorption (by percentage) was higher for the alkaline solution.     

亚铁螯合剂液相脱除烟气中NOx

总结了近20多年来液相络合法脱除烟气中NOx的研究成果,详细叙述了亚铁氨羧和亚铁含-SH基二类螯合剂单独脱氮和同时脱硫脱氮的反应机理、动力学、吸收液的再生和过程的影响因素,指出了该工艺存在的主要问题,提出了今后的研究方向.     

K2Cr2O7溶液同时脱硫脱硝实验研究

采用K2Cr2O7溶液作为吸收液,在自制的鼓泡反应器内,对模拟烟气进行同时脱硫脱硝的实验研究,考察多种因素对SO2脱除率(即脱硫率)和NO脱除率(即脱硝率)的影响。实验结果表明:K2Cr2O7浓度、反应温度、NO浓度、SO2浓度、烟气流量对脱硫率、脱硝率影响显著;当烟气流量为0.4L/min,气相中O2体积分数为6%,SO2体积分数为0.09%,NO体积分数为0.100%,K2Cr2O7摩尔浓度为10mmol/L,反应温度为40℃时,脱硫率、脱硝率分别达到100%和64.3%。