Improving methane storage on wet activated carbons at various amounts of water 被引量：7

Improving methane storage on wet activated carbons at various amounts of water

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摘要 Different mesoporous activated carbons were prepared by both chemical and physical activation processes and were examined for methane uptake in the presence of water.Methane isotherms were obtained at wet condition by wetting samples with water at mass ratio of water/carbon(R) close to 1.0.To compare,the amount of methane storage were also measured at dry situation.The maximum amount of methane stored was attained as 237 V/V at R=1.0 by hydrate formation at the methane critical pressure.In the next step,mass ratios of water/carbon were changed to investigate various amount of water for methane storage enhancement.Two other values of mass ratio of water/carbon(R=0.8 and 1.4) were selected and methane isotherms were obtained at the same conditions.Maximum values of 210 and 248 V/V were reached for methane storage,respectively.It was also observed that,in the pressure range lower than hydrate pressure,by increasing water ratio the hydrate formation pressure was decreased and methane uptake was much less than that of dry condition due to pore filling by water. Different mesoporous activated carbons were prepared by both chemical and physical activation processes and were examined for methane uptake in the presence of water.Methane isotherms were obtained at wet condition by wetting samples with water at mass ratio of water/carbon（R） close to 1.0.To compare,the amount of methane storage were also measured at dry situation.The maximum amount of methane stored was attained as 237 V/V at R=1.0 by hydrate formation at the methane critical pressure.In the next step,mass ratios of water/carbon were changed to investigate various amount of water for methane storage enhancement.Two other values of mass ratio of water/carbon（R=0.8 and 1.4） were selected and methane isotherms were obtained at the same conditions.Maximum values of 210 and 248 V/V were reached for methane storage,respectively.It was also observed that,in the pressure range lower than hydrate pressure,by increasing water ratio the hydrate formation pressure was decreased and methane uptake was much less than that of dry condition due to pore filling by water.

作者 MOHAMMAD JABER DARABI MAHBOUB ALI AHMADPOUR HAMED RASHIDI

机构地区 Department of Chemical Engineering

出处《燃料化学学报》 EI CAS CSCD 北大核心 2012年第4期385-389,共5页 Journal of Fuel Chemistry and Technology

基金 Shahid Hashemi Nejad Gas refinery for supporting this project

关键词 methane storage HYDRATE ISOTHERM WATER WETTING methane storage hydrate isotherm water wetting

分类号 TE624.4 [石油与天然气工程—油气加工工程]

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参考文献2

1李明,姚金花.活性炭含水量对甲烷吸附量的影响[J].天津化工,2001,15(5):4-6. 被引量：19
2E.Salehi,V.Taghikhani,C.Ghotbi,E.Nemati Lay,A.Shojaei.Theoretical and Experimental Study on the Adsorption and Desorption of Methane by Granular Activated Carbon at 25℃[J].Journal of Natural Gas Chemistry,2007,16(4):415-422. 被引量：4

二级参考文献10

1[1]Sir car S,Golden T C,Rao M B.Activat ed Carbon for Gas Separation and Storage [J].Carbon,1996,34(1):1-12.
2[2]Boehm H P.Some Aspects of the Surface Chemistry of Carbon Blacks and other Carbons[J].Carbon,1994,32(5):759-769.
3[3]J Miyawaki,el al Macroscopic Evidence of Enhanced Formati on of Met hane Nanohydrates in Hydrophobic Nanospaces [J].J Phys Chem,1998,102(12):2178- 2192
4[4]K Kaneko,el al.Nanoclathrate-assisted Adsorption of Super rcritical Gases in Hydrophobic Pores[C].Proceedings of the Sixth International Conferen ce of Fundamentals of Adsorption,1998,May 24-28;Elsevier,1998,51-56.
5[5]Zhouli,Zhouyaping.Experimental Study on High-pressure Ads orption o f Hydrogen on Activated Carbon[J].Science in China(B),1996,26(5):473-480.
6[6]N J Foley,et al.Kinetics of Water Vapor Adsorption on Act ivated Carbon[J].Langmuir,1997,13(7):2083-2089.
7[7]T Iiyama,et al.An Ordered Water Molecular Assembly Struct ure in a Slit-Shaped Carbon Nanospace[J].J Phys Chem,1995,99(25):10075-10076.
8[8]ErichA Muler,et al.Adsorption of Water on Activated Carbo ns:A Molecular Simulation Study[J].J Phys Chem,1996,100(4):1189-1196.
9[9]John L Cox.Natural Gas Hydrates:Properties,Occurrence and Recovery[J].Buttorworth:Boston,1983,70.
10[10]K Fujie,el at.NO/H2O Clathrate Formation in Sub-na no Graphitic Slit Spaces[J].Chem Phys Letters,1995,236:427-430.

共引文献21

1周理,孙艳,苏伟,周亚平.Natural Gas Storage in Wet Active Carbons-A Report on Research Progress[J].Chinese Journal of Chemical Engineering,2005,13(6):824-829. 被引量：2
2孙艳,刘聪敏,苏伟,周亚平,周理.天然气在炭材料上湿储研究进展[J].炭素技术,2007,26(6):31-34.
3杨雄,刘应书,李永玲,郭广栋,刘文海,孟宇,张传钊.基于活性炭的真空变压吸附提浓煤层气甲烷的实验研究[J].煤炭学报,2010,35(6):987-991. 被引量：22
4贾铮,黎海波,于振兴,王鹏,范雪蕾.甲烷吸附储存条件下状态方程的选用[J].油气储运,2011,30(7):517-519. 被引量：3
5龚飞飞,孙斌,张宝刚,余雄.吸附剂GY-1对牛舍内NH_3吸附性能的研究[J].新疆农业大学学报,2013,36(1):7-11. 被引量：2
6陆豪,吴祖良,高翔.吸附法净化挥发性有机物的研究进展[J].环境工程,2013,31(3):93-97. 被引量：26
7龚飞飞,孙斌,张浩,邵伟,任万平,余雄.不同季节吸附剂GY-3对牛舍内NH_3吸附性能的研究[J].中国奶牛,2013(17):39-44. 被引量：1
8周亚平,吴頔,刘佳,郑娟娟,孙艳.玉米芯活性炭的制备及储气性能[J].天津大学学报（自然科学与工程技术版）,2013,46(10):939-944. 被引量：6
9谢会芳,刘延纯,冯宝民,楚文玲.甲烷存储材料的研究进展[J].大连大学学报,2014,35(3):43-50. 被引量：2
10杨云安,彭国亮,邵伟,张浩,邓海峰,余雄.吸附剂X对新疆冬季马厩内CH_4、CO_2和NH_3三种气体吸附性能的研究[J].新疆农业科学,2015,52(8):1526-1534.

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2YANG DingHui1 & XU WenYue2 1 Department of Mathematical Sciences, Tsinghua University, Beijing 100084, China,2 School of Earth & Atmospheric Sciences, Georgia Institute of Technology, Atlanta, GA 30332, USA.Effects of salinity on methane gas hydrate system[J].Science China Earth Sciences,2007,50(11):1733-1745. 被引量：5
3张晋,杨亮,张毅,王春磊.液体表面张力产生机理及方向分析[J].中国石油和化工标准与质量,2012,32(5):73-74. 被引量：9
4何余生,李忠,奚红霞,郭建光,夏启斌.气固吸附等温线的研究进展[J].离子交换与吸附,2004,20(4):376-384. 被引量：183
5潘云仙,刘道平,黄文件,徐新亚,周文铸.气体水合物形成的诱导时间及其影响因素[J].天然气地球科学,2005,16(2):255-260. 被引量：35
6孙登林,吴强,张保勇.“记忆效应”对瓦斯水合物生成诱导时间的影响[J].哈尔滨工业大学学报,2006,38(12):2177-2179. 被引量：8
7Yeon S H, Osswald S, Gogotsi Y, et al. Enhanced methane storage of chemically and physically activated carbide-derived carbon [ J ]. Journal of Power Sources, 2009,191 ( 2 ) :560 - 567.
8Policicchio A, Maccallini E, Agostino R G, et al. Higher methane storage at low pressure and room temperature in new easily scalable large-scale production activated carbon for static and vehicular ap- plications [ J ]. Fuel,2013,104 : 813 - 821.
9Liu J, Zhou Y, Sun Y, et al. Methane storage in wet carbon of tailor- ed pore sizes[J]. Carbon,2011,49(12) :3731 -3736.
10Guan C, Loo L S, Wang K,et al. Methane storage in carbon pellets prepared via a binderless method[ J]. Energy Conversion and Man- agement ,2011,52 ( 2 ) : 1258 - 1262.

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