Joint methane fermentation poultry manure and waste of agro-industrial complex

The combined usage of poultry manure and agricultural waste cellulose to produce biogas in the fermentation process are shown. The concentration of cellulose-containing raw material affects on the yield of biogas and its qualitative consists. The maximum yield of biogas and energy carrier concentration will occur with substrate components at a ratio of manure/corn waste -3:2. With such component ratio speed of cellulose raw material conversion will rise. The yield of biogas has a sinusoidal structure as a result of acidity changes in substrate.

биогаз, ферментация, сельскохозяйственные отходы, помет, ассоциация микроорганизмов, biogas, fermentation, agricultural waste, manure, microorganisms associations

1. Гелетуха Г.Г., Желєзна Т.А., Кучерук П.П., Олійник Є.М. Сучасний стан та перспективи розвитку біоенергетики в Україні. Аналітична записка БАУ. 2014. № 9. [Ел. ресурс]. http://www.uabio.org/ img/files/docs/position-paper-uabio-9-ua.pdf/.

2. Teghammar A. Biogas production from lignocelluloses: pretreatment, substrate characterization, co-digestion, and economic evaluation. Chalmers university of technology. Department of Chemical and Biological Engineering. 2013.

3. Sims J.T., Badger D.D. A review of poultry manure management: Directions for the Future Agriculture and Agri-Food Canada Poultry Section. August 17, 1990. Pp. 60-63.

4. Koster J.W., Lettinga G. The influence of ammonium-nitrogen on the specific activity of pelletized methanogenic sludge // Agricultural Wastes. 1984. № 9. P. 205-216.

5. Pender S., Toomey M., Carton M., Eardly D., Patching J.W., Colleran E., O'Flaherty V. Long-term effects of operating temperature and sulphate addition on the methanogenic community structure of an aerobic hybrid reactors // Water Res. 2004. Vol. 38, № 3. P. 619-630.

6. Bergman I., Lundberg P., Nilsson M. Microbial carbon mineralization in an acid surface peat: effects of environmental factors in laboratory incubations // Soil Biol. Biochem. 1999. Vol. 31, № 13. P. 1867-1877.

7. Francese A.P., Aboagye-Mathiesen G., Olesen T., Cordoba P.R., Sineriz F. Feeding approaches for biogas production from animal wastes and industrial effluents // World J. Microbiol. Biotechnol. 2000. Vol. 16, № 2. P. 147-150.

8. Ionomer laboratornyj I-160 MI / Rukovodstvo po èkspluatacii. Obsestvo s ogranicennoj otvetst-vennost'û « «Izmeritel'naâ tehnika», 2007.

9. Lejbnic È., Struppe H.G. Rukovodstvo po gazovoj hromatografii. Cast' 1. M.: Mir, 1988.

10. Seina O.A., Sysoev V.A. Biohimiâ processa proizvodstva biogaza kak al'ternativnogo istocnika ènergii // Vestnik TGU. 2009. T. 14, vyp. 1. S. 73-76.

11. Hippler B., Thauer R.K. The energy conserving methyltetrahydromethanopter in: coenzyme M methyltransferase complex from methanogenic archaea: function of the subunit // FEBS Lett. 1999. Vol. 449, № 2-3. P. 165-168.

12. Shima S., Wakentin E., Thauer R.K., Ermler U. Structure and function of enzymes involved in the methanogenic pathway utilizing carbondioxide and molecular hydrogen // J. Biosci. Bioeng. 2002. Vol. 93, № 6. P. 519-530.

13. Bergman I., Lundberg P., Nilsson M. Microbial carbon mineralization in an acid surface peat: effects of environmental factors in laboratory incubations // Soil Biol. Biochem. 1999. Vol. 31, № 13. P. 1867-1877.