基于过渡金属氧化物载氧体的煤矿通风瓦斯处理性能

Performance of ventilation air methane combustion over transition metal oxide oxygen carriers

  • 摘要: 采用反应管对基于过渡金属氧化物载氧体的煤矿通风瓦斯(VAM)处理性能展开了研究.结果表明,经活化后的三种载氧体均能将CH4完全转化为CO2,其活性顺序为CuO60/γ-Al2O3 > NiO60/γ-Al2O3 > Fe2O360/γ-Al2O3;基于CuO60/γ-Al2O3的CH4转化率随空速的增加而减小,随CuO负载量和床层温度的升高而增大;煤矿通风瓦斯中的CH4浓度越低,CH4转化率达到90%所需的床层温度就越低;对活性物质低分散高负载的CuO60/γ-Al2O3和活性物质高分散低负载的CuO5.5/γ-Al2O3两种CuO/γ-Al2O3系载氧体进行了比较,发现两种载氧体的CH4转化机理均包含有化学链燃烧和催化燃烧两种机理,基于催化燃烧机理的CH4转化率在一定温度下存在极大值,当床层温度高于该极大值温度时,化学链燃烧对CH4转化率的贡献明显大于催化燃烧对CH4转化率的贡献;相同条件下,CuO5.5/γ-Al2O3的初期活性优于Cu60/γ-Al2O3,但CuO60/γ-Al2O3的活性稳定性优于CuO5.5/γ-Al2O3.

     

    Abstract: The performance of combustion of ventilation air methane (VAM) over transition metal oxide oxygen carriers was studied through experiments with using tube reactors. The results show that the activity of activated oxygen carriers in converting CH4 to CO2 is as follows:CuO60/γ-Al2O3 > NiO60/γ-Al2O3 > Fe2O360/γ-Al2O3. CH4 conversion based on CuO60/γ-Al2O3 decreases with increasing gas hourly space velocity, but increases with increasing bed temperature and CuO loading. The lower the initial CH4 concentration of ventilation air methane, the lower is the temperature for the CH4 conversion of 90%. There are catalytic combustion mechanisms and chemical-looping combustion mechanisms for CH4 combustion over both CuO60/γ-Al2O3, for which dispersion of the active component is low but loading is high, and CuO5.5/γ-Al2O3, for which dispersion of the active component is high but loading is low. There exists a maximum for CH 4 conversion based on the catalytic combustion mechanism at some temperatures, and when the bed temperature is higher than this temperature, the contribution of chemical-looping combustion is greater than that of catalytic combustion. The initial activity of CuO5.5/γ-Al2O3 is higher than that of CuO60/γ-Al2O3, while the stability of CuO60/γ-Al2O3 activity is better than that of CuO5.5/γ-Al2O3 activity under the same conditions.

     

/

返回文章
返回