Hydrogen Production with High Evolution Rate and High Yield by Immobilized Cells of Hydrogen-producing Bacteria Strain B49 in a Column Reactor 被引量：6

Hydrogen Production with High Evolution Rate and High Yield by Immobilized Cells of Hydrogen-producing Bacteria Strain B49 in a Column Reactor

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摘要 To improve the hydrogen evolution rate in continuous hydrogen production of a novel fermentative hydrogen producing bacteria strain B49 (AF481148 in EMBL), 4 % immobilized cells by polyvinyl alcohol boric acid method, with the addition of a small amount of calcium alginate in a column reactor obtain hydrogen yield of 2.31 mol H2/mol glucose and hydrogen evolution rate of 1435.4 ml/L culture·h respectively at medium retention time of 2.0 h with a medium containing 10g glucose/L. Moreover, as the cell density in gel beads is increased to 8%, hydrogen yield and hydrogen evolution rate for 10g glucose/L are 2.34 mol H2/mol glucose and 2912.4 ml/L culture·h respectively at medium retention time of 1.0 h, and for molasses wastewater COD of 7505.9 mg/L hydrogen production potential of 205.6 ml/g COD and hydrogen evolution rate of 2057.7 ml/L culture·h at hydraulic retention time of 0.75 h are observed. In the continuous culture pH value keeps around 3.9 by self regulating. To improve the hydrogen evolution rate in continuous hydrogen production of a fermentative hydrogen-producing bacteria strain B49 (AF481148 in EMBL), 4% immobilized cells by polyvinyl alcohol-boric acid method, with the addition of a small amount of calcium alginate in a column reactor obtain hydrogen yield of 2.31 mol H2/mol glucose and hydrogen evolution rate of 1435.4 ml/L culture&middoth respectively at medium retention time of 2 h with a medium containing l0 g glucose/L. As the cell density in gel beads is increased to 8%, hydrogen yield and hydrogen evolution rate for l0 g glucose/L are 2.34 mol H2/mol glucose and 2912.4 ml/L culture &middot h respectively at medium retention time of 1 h, and for molasses wastewater COD of 7505.9 mg/L hydrogen production potential of 205.6 ml/g COD and hydrogen evolution rate of 2057.7 ml/L culture&middoth at hydraulic retention time of 0.75 h are observed. In the continuous culture pH value keeps around 3.9 by self regulation.

作者任南琪 Wang Xiangjing Xiang Wensheng Lin Ming Li Jianzheng Guo Wanqian

机构地区 School of Municipal & Environmental Engineering Research Center of Life Science and Biotechnology

出处《High Technology Letters》 EI CAS 2002年第4期21-25,共5页 高技术通讯（英文版）

基金 Sponsoredby"863"ProjectofChina (2 0 0 1AA5 15 0 3 0 )&"973"FundamentalScienceProgramofChina (G2 0 0 0 0 2 64 0 2 )

关键词 hydrogen-producing BACTERIA STRAIN B49 immobilized cells continuous hydrogen production Bacteria Calcium compounds Cell immobilization Production Wastewater

分类号 Q935 [生物学—微生物学]

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参考文献14

1[1]Christopher F. Sustainable energy for tomorrows world: the case for an optimistic future, in the energy crisis. Feldman D L ed., the Johns Hopkins University Press, 1996.230
2[2]Li J Z, Ren N Q, Wang B Z, Biotechnology of hydrogen production: review, problems and advice.In: Proceedings of the 13th World Hydrogen Energy Conference, Beijing, China: 2000.588～593.
3[3]Nandi R, Sengupta S. Critical Reviews in Microbiology, 1998, 24(1): 61
4[4]Benemann J. Nature Biotechnology, 1996, 14: 1101
5[5]Zhu H, Suzuki T, et al. Int J hydrogen,1999, 24: 305
6[6]Yokoi H, Tokushige T, Hirose J et al. J Ferment Bioeng 1997,83(5):481
7[7]Kumar N, Das D. Biological hydrogen production in a packed bed reactor using agroresidues as solid matrices. In:Proceedings of the 13th World Hydrogen Energy Conference, Beijing, China: 2000.364
8[8]Yokoi H, Maeda Y, Hirose J, et al. Biotechnol Techniques.1997,11(6):431
9[9]Lin M. Hydrogen production mechanism and ecology of a new species of high efficiency hydrogen production by fermentation[dissertation]. Harbin: Harbin Institute of Technology, 2002,29
10[10]APHA. Standards Methods for the Examination of Water and Wastewater, 19th ed. Washington D C:American Public Health Association

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High Technology Letters

2002年第4期

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Hydrogen Production with High Evolution Rate and High Yield by Immobilized Cells of Hydrogen-producing Bacteria Strain B49 in a Column Reactor 被引量：6

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