Reaction characteristics research of coal char chemical looping gasification for hydrogen production with an Fe-Zr oxygen carrier modified by K<sub>2</sub>CO<sub>3</sub>

HU Shun-xuan; YU Zhong-liang; LI Chun-yu; WANG Zhi-qing; GUO Shuai; HUANG Jie-jie; FANG Yi-tian

Volume 43 Issue 04

Apr. 2015

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Article Navigation > Journal of Fuel Chemistry and Technology > 2015 > 43(04): 385-392

HU Shun-xuan, YU Zhong-liang, LI Chun-yu, WANG Zhi-qing, GUO Shuai, HUANG Jie-jie, FANG Yi-tian. Reaction characteristics research of coal char chemical looping gasification for hydrogen production with an Fe-Zr oxygen carrier modified by K2CO3[J]. Journal of Fuel Chemistry and Technology, 2015, 43(04): 385-392.

Citation:

HU Shun-xuan, YU Zhong-liang, LI Chun-yu, WANG Zhi-qing, GUO Shuai, HUANG Jie-jie, FANG Yi-tian. Reaction characteristics research of coal char chemical looping gasification for hydrogen production with an Fe-Zr oxygen carrier modified by K₂CO₃[J]. Journal of Fuel Chemistry and Technology, 2015, 43(04): 385-392.

Citation:

HU Shun-xuan, YU Zhong-liang, LI Chun-yu, WANG Zhi-qing, GUO Shuai, HUANG Jie-jie, FANG Yi-tian. Reaction characteristics research of coal char chemical looping gasification for hydrogen production with an Fe-Zr oxygen carrier modified by K₂CO₃[J]. Journal of Fuel Chemistry and Technology, 2015, 43(04): 385-392.

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Reaction characteristics research of coal char chemical looping gasification for hydrogen production with an Fe-Zr oxygen carrier modified by K₂CO₃

1.
State Key Laboratory of Coal Conversion, Institute of Coal Chemistry, Chinese Academy of Sciences, Taiyuan 030001, China;
2.
University of Chinese Academy of Sciences, Beijing 100049, China

Received Date: 2014-09-29
Publish Date: 2015-04-30

Abstract

Abstract

In this study, an Fe-Zr oxide (Fe₂O₃ and ZrO₂) modified by K₂CO₃ was used as the oxygen carrier (denoted as K3-Fe70Zr30) to analyze the effects of the temperature and the char mass ratio on the gas yield and composition during coal char chemical looping gasification for hydrogen production. The results of temperature-programmed experiments show that the reaction of oxygen carrier and coal char starts at 500 ℃, and the reaction rate increases sharply after 750 ℃; the reduced oxygen carrier begins to react with steam when the temperature reaches 400 ℃, and the concentration of hydrogen significantly increases after 500 ℃. The results of isothermal experiments indicate that the reaction rate accelerates with increasing reaction temperature. However, the ratio of CO/CO₂ volume ratio increases, resulting in the H₂ production decreases as the temperature raises. In addition, an increase in char ratio increases the ratio of CO/CO₂ volume ratio in the outlet gas increases, which leads to the hydrogen production firstly increase and reaches a maximum value of 1.734 L/g, and then decrease. The activity of oxygen carrier can keep stable during the first 2 redox cycles, but it decreases in the 3rd cycle. The activity can be renewed by supplement of K₂CO₃, which suggests that the loss of K₂CO₃ can contribute to the decreased activity.
- oxygen carrier,
- K₂CO₃,
- coal char,
- H₂ production

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References(13)

References

徐振刚, 吴春来. 煤气化制氢技术[J]. 低温与特气, 2000, 18(6):28-31. (XU Zhen-gang, WU Chun-lai. Technology of gasification for hydrogen production by coal[J]. J Low Temp Spec Gases, 2000, 18(6):28-31.)

谢继东, 李文华, 陈亚飞. 煤制氢发展现状[J]. 洁净煤技术, 2007, 13(2):77-81. (XIE Ji-dong, LI Wen-hua, CHEN Ya-fei. Development status of hydrogen production from coal[J]. J Clean Coal Technol, 2007, 13(2):77-81.)

任相坤, 袁明, 高聚忠. 神华煤制氢技术发展现状[J]. 煤质技术, 2006, 1:4-7. (REN Xiang-kun, YUAN Ming, GAO Ju-zhong. Development status of the technology for hydrogen production from coal in Shenhua[J]. J Coal Qual Technol, 2006, 1:4-7.)

SHOKO E, MCLELLAN B, DICKS A L, DINIZ DA COSTA J C. Hydrogen from coal:Production and utilisation technologies[J].J Coal Geol, 2006, 65(3):213-222.

ZENG L, HE F, LI F, FAN L. Coal-direct chemical looping gasification for hydrogen production:Reactor modeling and process simulation[J]. Energy Fuels, 2012, 26(6):3680-3690.

FAN L, LI F, RAMKUMAR S. Utilization of chemical looping strategy in coal gasification processes[J]. Particuology, 2008, 6(3):131-142.

CHIESA P, LOZZA G, MALANDRINO A, ROMANO M, PICCOLO V. Three-reactors chemical looping process for hydrogen production[J]. Int J Hydrogen Energy, 2008, 33(9):2233-2245.

GNANAPRAGASAM N V, REDDY B V, ROSEN M A. Hydrogen production from coal using coal direct chemical looping and syngas chemical looping combustion systems:Assessment of system operation and resource requirements[J]. Int J Hydrogen Energy, 2009, 34(6):2606-2615.

YANG J, CAI N, LI Z. Hydrogen production from the steam-iron process with direct reduction of iron oxide by chemical looping combustion of coal char[J]. Energy Fuels, 2008, 22(4):2570-2579.

YU Z, LI C, FANG Y, HUANG J, WANG Z. Reduction rate enhancements for coal direct chemical looping combustion with an iron oxide oxygen carrier[J]. Energy Fuels, 2012, 26(4):2505-2511.

YU Z, LI C, JING X, ZHANG Q, FANG Y, ZHAO J, HUANG J. Effects of CO₂ atmosphere and K₂CO₃ addition on the reduction reactivity, oxygen transport capacity, and sintering of CuO and Fe₂O₃ oxygen carriers in coal direct chemical looping combustion[J]. Energy Fuels, 2013, 27(5):2703-2711.

余钟亮, 李春玉, 景旭亮, 丁亮, 房倚天, 黄戒介. 碳酸钾催化的铁基氧载体煤催化化学链燃烧[J]. 燃料化学学报, 2013, 41(7):826-831. (YU Zhong-liang, LI Chun-yu, JING Xu-liang, DING Liang, FANG Yi-tian, HUANG Jie-jie. Catalytic chemical looping combustion of coal with iron-based oxygen carrier promoted by K₂CO₃[J]. J Fuel Chem Technol, 2013, 41(7):826-831.)

YU Z, LI C, JING X, ZHANG Q, WANG Z, FANG Y, HUANG J. Catalytic chemical looping combustion of carbon with an iron-based oxygen carrier modified by K₂CO₃:Catalytic mechanism and multicycle tests[J]. Fuel Process Technol,in press.

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