焦炉煤气甲烷重整制氢热力学分析和实验研究(英文) Hydrogen Production from Coke Oven Gas by Methane Reforming:Thermodynamic Analysis and Experimental Study期刊界 All Journals 搜尽天下杂志传播学术成果专业期刊搜索期刊信息化学术搜索

按检索

焦炉煤气甲烷重整制氢热力学分析和实验研究(英文)

引用本文：	杨志彬,张玉文,张云妍,丁伟中,沈培俊,刘勇,周宇鼎,黄少卿.焦炉煤气甲烷重整制氢热力学分析和实验研究(英文)[J].物理化学学报,2010,26(2):350-358.

作者姓名：	杨志彬张玉文张云妍丁伟中沈培俊刘勇周宇鼎黄少卿

作者单位：	Shanghai Key Laboratory of Modern Metallurgy and Materials Processing, Shanghai University, Shanghai 200072, P. R. China

基金项目：	China，National Engineering Research Center of Advanced Steel Technology，China，Innovation Fund for Graduate Student of Shanghai University;China. 国家高技术研究发展计划(863)，上海市科委重点科研项目，先进钢铁材料技术国家工程研究中心，上海大学研究生创新基金

摘要：	对焦炉煤气甲烷部分氧化重整热力学进行分析,考察反应温度、CH4/O2摩尔比及水蒸气加入量等因素对重整性能的影响,并分析焦炉煤气原始氢含量对其部分氧化重整性能的影响.分析结果表明甲烷转化率均随CH4/O2摩尔比和水蒸气加入量的增大以及反应温度的升高而增大.在CH4/O2摩尔比1.7-2.1,温度825-900℃及压力1.01×105Pa的反应条件下,可得较好重整性能;甲烷转化率,氢及一氧化碳的选择性分别为91.0%-99.9%,87.0%-93.4%和100%-107%,重整后得到的氢量增大到原始氢量的1.95-2.05倍,每摩尔焦炉煤气消耗的热量仅为2.94J,同时得出在CH4/O2摩尔比2,温度825-900℃及1.01×105Pa条件下,往焦炉煤气内添加体积分数为2%-4%的水蒸气时重整性能得到较大提高;重整后甲烷转化率、氢及一氧化碳选择性分别由92.6%、87.2%、104%增大到98.6%、96.4%、107%.并在BaCo0.7Fe0.2Nb0.1O3-δ透氧膜反应器上研究NiO/MgO固溶体催化剂焦炉煤气部分氧化重整性能.结果表明该重整反应效果较好,于875℃下获得16.3mL.cm-2.min-1透氧量,95%甲烷转化率及80.5%氢和106%一氧化碳选择性.且所得实验结果与热力学分析结果符合较好,表明NiO/MgO固溶体催化剂有较好的催化重整性能.
关键词：	焦炉煤气氢热力学分析混合导体透氧膜反应器 NiO/MgO固溶体催化剂
收稿时间：	2009-05-05
修稿时间：	2009-11-24
Hydrogen Production from Coke Oven Gas by Methane Reforming:Thermodynamic Analysis and Experimental Study

YANG Zhi-Bin,ZHANG Yu-Wen,ZHANG Yun-Yan,DING Wei-Zhong,SHEN Pei-Jun,LIU Yong,ZHOU Yu-Ding,HUANG Shao-Qing.Hydrogen Production from Coke Oven Gas by Methane Reforming:Thermodynamic Analysis and Experimental Study[J].Acta Physico-Chimica Sinica,2010,26(2):350-358.

Authors:	YANG Zhi-Bin ZHANG Yu-Wen ZHANG Yun-Yan DING Wei-Zhong SHEN Pei-Jun LIU Yong ZHOU Yu-Ding HUANG Shao-Qing

Institution:	Shanghai Key Laboratory of Modern Metallurgy and Materials Processing, Shanghai University, Shanghai 200072, P. R. China

Abstract:	A thermodynamic analysis of the partial oxidation of methane (POM) in coke oven gas (COG) was carried out. The optimized conditions were CH_4/O_2 molar ratios of 1.7-2.1 and reaction temperatures of 825-900 ℃. We obtained CH_4 conversions of 91.0%-99.9%, H_2 selectivity of 87.0%-93.4%, and CO selectivity of 100%-107% at 1.01×10~5 Pa. The effect of H_2 in the COG on the performance of POM was also investigated between 825 and 900 ℃. The optimized volume ratio of steam addition was 2%-4% and the molar ratio of CH_4/O_2 was 2 at 1.01×10~5 Pa and 825-900 ℃. A maximum conversion rate of 98.6% was achieved for CH_4 using COG, while the maximum selectivities of H_2 and CO were 96.4% and 107%, respectively. The amount of hydrogen obtained after reforming was doubled despite a thermal consumption of only 2.94 J·mol~(-1) for the COG. The performance of a NiO/MgO solid solution catalyst packed on a BaCo_(0.7)Fe_(0.2)Nb_(0.1)O_(3-δ) (BCFNO) membrane reactor was also investigated for the POM in COG. The reforming process was successfully performed. At 875 ℃, 95% CH_4 conversion, 80.5% H_2 selectivity, and 106% CO selectivity at an oxygen permeation flux of 16.3 mL·cm~(-2)·min~(-1) were achieved. The results for POM reforming in COG on the membrane reactor were consistent with the thermodynamic analysis. The NiO/MgO solid solution catalyst, therefore, has good activity and is suitable for application in hydrogen production.

Keywords:	Coke oven gas Hydrogen Thermodynamic analysis Mixed-conducting membrane reactor NiO/MgO solid solution catalyst
本文献已被 CNKI 万方数据等数据库收录！
	点击此处可从《物理化学学报》浏览原始摘要信息
	点击此处可从《物理化学学报》下载免费的PDF全文

设为首页 | 免责声明 | 关于勤云 | 加入收藏