Abstract
A two-stage rumen-derived anaerobic digestion process was tested for the conversion of water hyacinth shoots and a mixture of the shoots with cowdung (7:3) into biogas. Under conditions similar to those of the rumen and loading rates (LR) in the range of 11.6–19.3g volatile solids (VS) l−1d−1 in the rumen reactor, the degradation efficiencies were 38% for the shoots and 43% for the mixture. The major fermentation products were volatile fatty acids (VFA) with a maximum yield of 7.92mmolg−1 VS digested, and biogas with a yield of 0.2lg−1 VS digested. The effect of varying LR, solid retention time (SRT) and dilution rates on the extent of degradation of the water hyacinth–cowdung mixture was examined. Overall conversion of the substrate was highest at the loading rate of 15.4gVS.l−1d−1. Varying the retention times between 60 and 120h had no effect on the degradation efficiency, but a decrease was observed at retention times below 60h. The overall performance of the reactor was depressed by changing the dilution rate from 0.5 to 0.34h−1. By applying a LR of 15.4VS. l−1d−1, a SRT of 90h and a dilution rate of 0.5h−1 in the rumen reactor, and connecting it to a methanogenic reactor of the upflow anaerobic sludge blanket type, 100% conversion efficiency of the VFA into biogas with a methane content of 80% was achieved. The average methane gas yield was 0.44lg−1 VS digested.
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References
Ahring, B.K. 1995 Methanogenesis in thermophilic biogas reactors. Antonie van Leeuwenhoek 67, 91–102.
Alexiou, T.E. & Anderson, G.K. 1994 Pre-acidification: concept, guidelines and parameters for application. Proceedings of the Seventh International Symposium on anaerobic digestion, 23-27 January 1994, Cape Town, R.S.A.
Baader, W., Schuchardt, F. & Grabbe, K. 1981 Gewinnung von biogas und organischen Rückstanden. Der champignon 236, 26–32.
Benner, R., Maccubin, A.E. & Hodson, R.E. 1984 Anaerobic biodegradation of the lignin and polysaccharide components of lignocellulose and synthetic lignin by sediment microflora. Applied and Environmental Microbiology 47, 998–1004.
Chin, K.K. & Goh, T.N. 1978 Bioconversion of solar energy: Methane production through water hyacinth. Symp. Energy from Biomass and Waste, 215–228.
Gijzen, H.J. 1987 Anaerobic digestion of cellulosic waste by rumen a rumen-derived process. PhD thesis. University of Nijmegen, The Netherlands.
Gijzen, H.J., Zwart K.B., van Gelder, P.T. & Vogels, G.D. 1986 Continuous cultivation of rumen microorganisms in a system with possible application to anaerobic degradation of lignocellulosic waste materials. Applied Microbiology and Biotechnology 25, 155–165.
Gijzen, H.J., Zwart, K.B., Verhagen, F.J. & Vogels, G.D. 1988 High rate two-phase process for the anaerobic degradation of cellulose employing rumen microorganisms for an efficient acidogenesis. Biotechnology and Bioengineering 31, 418–425.
Goering, H.K. & van Soest, P.J. Forage fibre analysis. 1970 USDA, ARS Agricultural handbook No. 379.
Han, Y.W., Lee, J.S. & Anderson, A.W. 1975 Chemical composition and digestibility of rye grass straw. Journal of Agricultural Chemistry 23, 928–931.
Hanaki, K., Matsuo, T., Nagase, M. & Tabata, Y. 1987 Evaluation of effectiveness of two-phase anaerobic digestion process degrading complex substrate. Water Science Technology 19, 311–322.
Hanisak, M.D., Williams, L.D. & Ryther, J.H. 1980 Recycling the nutrients in residues from methane digesters of aquatic macrophytes for new biomass production. Resource Recovery and Conversion 4, 313–323.
Hills, D.J. & Roberts, D.W. 1981 Anaerobic digestion of dairy manure and field crop residues. Agricultural Wastes 3, 179–189.
Johansson, D. 1976 Aquatic plants and man-made lakes in Africa. In Ecological Studies of Mtera Basin, ed Johansson, D. pp. 101–114. Uppsala: Almaquist and Wiksell.
Kivaisi, A.K. & Eliapenda, S. 1995 Application of rumen microorganisms for enhanced anaerobic degradation of bagasse and maize bran. Biomass and Bioenergy 8, 45–50.
Kivaisi, A.K., Gijzen, H.J., op den Camp, H.J.M. & Vogels, G.D. 1992 Conversion of cereal residues into biogas in a rumen derived process. World Journal of Microbiology and Biotechnology 8, 428–433.
Lequerica, J.L., Valles, S.S. & Flors, A. 1974 Kinetics of rice straw methane fermentation. Applied Microbiology and Technology 19, 70–74.
MacDougall, E. 1993 Two phase anaerobic digestion of coffee wastewater. Proceedings of the 48th Industrial Conference, 8-14 January 1993, Purdue: Lewis Publishers.
Mshigeni, K.E. & Kivaisi, A.K. 1995 Water resources, quality and hygiene, with special reference to Africa. Proceedings of the Tenth International Conference on Global Impacts of Applied Microbiology and Biotechnology 6-12 August 1995, Denmark: Elsinore.
Muller, H. & W. Trosch. 1986 Screening of white rot fungi for biological pretreatment of wheat straw for biogas production. Applied Microbiology and Biotechnology 24, 180–185.
Mwadamwar, D., Patel, A. & Patel, V. 1990 Effect of temperature and retention time on methane recovery from water hyacinth-cowdung. Journal of Fermentation and Bioengineering 70, 340–342.
Noike, T., Endo, G., Chang, J.E., Yaguchi, T.I. & Matsumoto, J.I. 1985 Characteristics of carbohydrate degradation and the rate limiting step in anaerobic digestion. Biotechnology and Bioengineering 27, 1485–1489.
Partos, J., Fardeau, M. & Belaich, J. 1983 Influence of pretreatment and the fermentation of barley straw by undefined mixed bacterial populations. European Journal of Applied Microbiology 18, 308–314.
Pinto, C.L.R., Cocania, A. & Sonza, M.M. 1987 Utilization of water hyacinth for removal and recovery of silver from industrial wastewater. Water Science and Technology 19, 89–102.
Pohland, F.G. & Ghosh, S. 1971 Developments in anaerobic stabilization of inorganic wastes: The two phase concept. Environmental Letters 1, 255–266.
Rogers, H.H. & Davis, D.E. 1972. Nutrient removal by water hyacinth Weed Science 20, 423–428.
Rufener, W.H. Jr, Nelson, W.O. & Wolin, M.J. 1963 Maintenance of rumen microbial population in continuous culture. Applied Microbiology 11, 196–201.
Shankar, G. & Tondon, G. 1986 A laboratory study of biogas production from water hyacinth. World Journal of Microbiology and Biotechnology 1, 72–77.
ShilapourA.& SmithP.H.1984Conversiofbiomassintomethane. Biomass 6, 85–94
Teherruzan, Q. & Kushani, D.P. 1989 Evaluation of some aquatic macrophytes cultivated in enriched water as possible source of protein and biogas. Hydrobiological Bulletin (Netherlands) 23, 207–212.
Tripathi, B.D. & Shukla, S. 1991 Biological treatment of wastewater by selected aquatic plants. Environmental Pollution 69, 69–78.
Vishniac, W. & Santer, M. 1957 The thiobacilli. Bacteriological Reviews 21, 195–213.
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Kivaisi, A., Mtila, M. Production of biogas from water hyacinth (Eichhornia crassipes) (Mart) (Solms) in a two-stage bioreactor. World Journal of Microbiology and Biotechnology 14, 125–131 (1997). https://doi.org/10.1023/A:1008845005155
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DOI: https://doi.org/10.1023/A:1008845005155