Temperature variation of reaction liquid of ultrafine corn stover in photosynthetic hydrogen production
Keywords:
corn stover, photosynthetic hydrogen production, ultrafine grinding, bioreactor, granularity, temperatureAbstract
The thermo-physical phenomena existing in the process of hydrogen production by photosynthetic bacteria with ultrafine corn stover directly affect the energy consumption of biological hydrogen production system, the activity of hydrogen production, and hydrogen production rate. In order to discover theoretical basis for optimizing process parameters of the photosynthetic bioreactor for ultrafine corn stover, experimental investigation was conducted to identify the effects of the granularity of ultrafine corn stover on the temperature variation using a self-developed photosynthetic bio-hydrogen thermal-effect experimental device. This paper describes experimental research on temperature variation of reaction liquid with ultrafine-ground corn stover in photosynthetic hydrogen production, and on the temperature field and change trend of reaction liquid of corn stover with different granularities in bio-hydrogen production. Experimental results showed that, the greater the granularity of corn stover, the slower the temperature rising speed of the reaction liquid with corn stover in the initial phase of photosynthetic hydrogen production, and the lower the relative average temperature of reaction liquid in photosynthetic hydrogen production. This result is of great significance in research on the photosynthetic hydrogen production technology from biomass, providing a theoretical basis for thermal effect in solar photosynthetic hydrogen production. Keywords: corn stover, photosynthetic hydrogen production, ultrafine grinding, bioreactor, granularity, temperature DOI: 10.3965/j.ijabe.20140705.009 Citation: Zhang Q G, Wang Y K, Hu J J, Guo J, Zhang Z P, Jing Y Y, Xu G Y, Wang Y. Temperature variation of reaction liquid of ultrafine corn stover in photosynthetic hydrogen production. Int J Agric & Biol Eng, 2014; 7(5): 65-71.References
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[3] Das D, Veziroǧlu T N. Hydrogen production by biological processes: a survey of literature. International Journal of Hydrogen Energy, 2001; 26(1): 13–28.
[4] Li D M, Chen H Z, Li Z H. Research and development of hydrogen production by biological technology. Biotechnology Information, 2003; 4: 1–5.
[5] Kawaguchi H, Hashimoto K, Hirata K, Miyamoto K. H2 production from algal biomass by a mixed culture of Rhodobium marine A-501 and lactobacillus amylovorus. Journal of Bioscience and Bioengineering, 2001; 91: 277–282. DOI: 10.1016/S1389-1723(01)80134-1.
[6] Yang Y, Lu D N, Cao Z A. Promising bioenergy in the 21st century. Chemical Industry and Engineering Progress, 2002; 21: 299–302.
[7] Li J Z, Ren N Q. Study and development in quo of hydrogen production biotechnology. Energy Engineering, 2001; 2: 18–20.
[8] Committee on Alternatives and Strategies for Future Hydrogen Production and Use, Board on Energy and Environmental Systems, Division on Engineering and Physical Sciences, National Research Council, National Academy of Engineering. 2004. The Hydrogen Economy: Opportunities, Costs, Barriers, and R&D Needs: National Academy Press.
[9] Li M, Wang H X. The analysis of comprehensive utilization
measures of agricultural waste. China Population Resources and Environment, 2012; 22(5): 37–39.
[10] Zhang Q G, Wang S L, You X F. Effects of the influencing factors of photosynthetic bacteria group on hydrogen production. Transactions of the CSAE, 2006; 22(10): 182–185.
[11] Zhang L N, Cai J. Modified material from Natural Polymers and their applications. Beijing: Chemical Industry Press. 2006.
[12] Zhang Z P, Yue J Z, Wang Y, Zhang Q G. The optimization of the ball milling pretreatment process for hydrogen production from straw biomass. Biomass Chem. Eng, 2012; 46(1): 19–22.
[13] Yue J Z, Xu G Z, Li G, Zhang Q G, Shen X W. Effects of microwave radiation pretreatment on enzymatic hydrolysis of sorghum straw. Journal of Henan Agricultural University, 2010; 44(5): 549–552.
[14] Yue J Z, Zhang Q G, Li G, Jiao Y Z, Shen X W. Effects of mechanical grinding on micro-structure of sorghum straw and enzymatic hydrolysis. Acta Energiae Solaris Sinica, 2010; 19(5): 51–53.
[15] Zhang Z P, Yue J Z, Zhou X H, Jing Y Y, Jiang D P, Zhang Q G. Photo-fermentative bio-hydrogen production from agricultural residue enzymatic hydrolyzate and the enzyme reuse. Bioresources, 2014; 9(2): 2299–2310.
[16] Hallenbeck P C, Ghosh D, Skonieczny M T, Yargeau V. Microbiological and engineering aspects of biohydrogen production. Indian J. Microbiol, 2009; 49(1): 48–59.
[17] Sasikala K, Ramana C V, Raghuveer R P, Kovacs K L. Anoxygenic phototrophic bacteria: Physiology and advances in hydrogen production technology. In: Neidleman S, LaskinA I (Ed.), editors. Advances in Applied Microbiology. New York: Academic Press, 1993; pp. 211–295.
[18] Won S G, Lau A K. Effects of key operational parameters on biohydrogen production via anaerobic fermentation in a sequencing batch reactor. Bioresour. Technol, 2011; 102(13): 6876–6883.
[19] Gao Z T, Liu Y, Huang Y P, Shen P, Qu S S. Thermokinetic study on the growth metabolism of ura-auxotrophic mutant of saccharomyces cerevisiae AY. Acta Physico-Chimica Sinica, 2002; 18(7): 590–594.
[20] Shi Y Z, Zhang Q G, Wang Y, Jing Y Y. Experimental study on continuous culture of photosynthetic bacteria for hydrogen production from biomass. Transactions of the CSAE, 2008; 24(6): 218–221.
[21] Wang S L, Zhang Q G, Zhou X H. Experimental study on change in temperature of the system during the biological hydrogen production. Acta Energiae Solaris Sinica, 2007; 28(11): 1253–1255.
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Quanguo, Z., Yingkuan, W., Jianjun, H., Jie, G., Zhiping, Z., Yanyan, J., … Yi, W. (2014). Temperature variation of reaction liquid of ultrafine corn stover in photosynthetic hydrogen production. International Journal of Agricultural and Biological Engineering, 7(5), 78–84. Retrieved from https://ijabe.migration.pkpps03.publicknowledgeproject.org/index.php/ijabe/article/view/1533
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Biosystems, Biological and Ecological Engineering
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