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Al2O3为载体的催化剂净化贫燃汽车尾气研究 总被引:2,自引:0,他引:2
在富氧条件下,考察了C3H6和C2H5OH在Ag/Al2O3、In/Al2O3、Sn/Al2O3、Co/Al2O3、Pt/Al2O3和Ag/Al2O3+Pt/Al2O3组合催化剂上选择性还原NO的性能.结果表明,Ag/Al2O3具有最高的NO还原活性.在负载型过渡金属氧化物催化剂上,会生成显著量的CO,其HC和CO氧化转化温度也远远高于Pt/Al2O3催化剂.串联组合Ag/Al2O3+Pt/Al2O3催化剂可显著拓宽活性温度范围,促进HC和CO氧化,降低N2O和CH3CHO生成量. 相似文献
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采用稀燃-富燃交替运行方式,研究存储-还原型催化剂Pt/MgO的NOx存储性能以及C3H6还原NOx反应性能.氧化存储段,NOx可被有效存储;当氧化性气氛转换为还原性气氛后,出现一个NOx峰,降低了总的转化效果.NOx峰的大小与存储段和还原段时间之比、温度等因素有关;400℃时NOx峰最小,总转化率最高.5 h循环实验表明,400℃时Pt/MgO催化剂再生良好,NOx转化率稳定在96%.于反应气氛中添加100 mg/m3SO2进行了5 h抗硫性实验,Pt/MgO催化剂的抗硫中毒能力明显强于Pt/BaO/Al2O3. 相似文献
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Li Junhua Kang Shoufang Fu Lixin Hao Jiming 《Frontiers of Environmental Science & Engineering in China》2007,1(2):143-146
A highly effective Ag-Al2O3 catalyst was prepared using the in-situ sol-gel method, and characterized by surface area using nitrogen adsorption, scanning electron microscopy (SEM), and transmission
electron microscopy (TEM) techniques. The catalyst performance was tested on a real lean-burn gasoline engine. Only unburned
hydrocarbons and carbon monoxide in the exhaust were directly used as reductant (without any external reductant), the maximum
NO
x
conversion could only reach 40% at 450°C. When an external reductant, ethanol was added, the average NO
x
conversion was greater than 60%. At exhaust gas temperature range of 350–500°C, the maximum NO
x
conversion reached about 90%. CO and HC could be efficiently oxidized with Pt-Al2O3 oxidation catalyst placed at the end of SCR converter. However, NO
x
conversion drastically decreased because of the oxidation of some intermediates to NO
x
again. The possible reaction mechanism was proposed as two typical processes, nitration, and reduction in HC-SCR over Ag-Al2O3. 相似文献
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贫燃条件Ag-Rh/CeO_2-ZrO_2-Al_2O_3协同催化C_3H_6选择性还原NO的原位红外研究 总被引:1,自引:1,他引:0
将Ag-Rh浸渍到共沉淀法合成的Ce-Zr-Al上,制备出Ag(0.04)-Rh(x)/Ce0.5Zr0.5O2-75%Al2O3系列催化剂,采用BET比表面积、X射线衍射光谱(XRD)和原位漫反射傅里叶变换红外光谱(DRIFTS)对催化剂进行表征,并探讨催化剂在贫燃条件下选择性还原NO的活性和反应机理.结果表明,Ag-Rh双组分催化剂的活性较单组分Ag、Rh催化剂的高.Rh负载量为0.7%(质量分数)时,NO转化率达最佳(90.3%),且反应的起燃温度低、活性温度范围宽(300~500℃).DRIFTS结果显示,Rh的添加不仅有利于催化剂表面NO的吸附,而且能促进Ag催化生成关键反应中间体—CO—NH—,进而显著提高NO的转化率. 相似文献
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