Kinetics of methane fermentation of selected post-processed poultry beddings — possibilities of process intensification and limitations
DOI:
https://doi.org/10.24426/eco-energetics.v2i2.115Słowa kluczowe:
poultry breeding manure, methane fermentation, process kinetics, batch biogas production process, modified Gompertz modelAbstrakt
The kinetics of methane fermentation of selected post-processed poultry beddings was analyzed. A modified nonlinear Gompertz model was applied for the calculations. The presented kinetic parameter may be useful for design or optimization calculations of agricultural-biogas installations integrated with industrial-scale poultry breeding.
Bibliografia
Al-Masalha, I., Elayyan, M., Issa, H.A.B. (2017). Use of biogas energy in poultry farming heating. The International Journal of Engineering and Science (IJES), 6(3), 58–63.
Batista, A.P., Gouveia, L., Marques, P.A.S.S. (2018). Fermentative hydrogen production from microalgal biomass by a single strain of bacterium Enterobacter aerogenes — Effect of operational conditions and fermentation kinetics. Renewable Energy, 119, 203–209.
Bolado-Rodriguez, S., Toquero, C., Martin-Juarez, J., Travaini, R., Garcia-Encina, P.A. (2016). Effect of thermal, acid, alkaline and alkaline-peroxide pretreatments on the biochemical methane potential and kinetics of the anaerobic digestion of wheat straw and sugarcane bagasse. Bioresource Technology, 201, 182–190.
Dalkılıc, K., Ugurlu, A. (2015). Biogas production from chicken manure at different organic loading rates in a mesophilic-thermopilic two stage anaerobic system. Journal of Bioscience and Bioengineering, 120(3), 315–322.
Kafle, G.K., Chen, L. (2016). Comparison on batch anaerobic digestion of five different livestock manures and prediction of biochemical methane potential (BMP) using different statistical models. Waste Management, 48, 492–502.
Karaalp, D., Doruk, N., Dizge, N., Keskinler, B., Azbar, N. (2015). A novel solution for biogas applications in poultry industry: CLAMBS approach. Journal of Bioprocessing and Biotechniques, 5(2), 1–6.
Leppikorpi, M., Virkajärvi, I. (2016). Unlocking the potential of poultry manure. Biogas Journal, 5, 40–42.
Miah, M.R., Rahman, A.K.M.L., Akanda, M.R., Pulak, A., Rouf, M.A. (2016). Production of biogas from poultry litter mixed with the co-substrate cow dung. Journal of Taibalh University of Science, 10, 497–504.
Ojolo, S.J., Oke, S.A., Animasahun, K., Adesuyi, B.K. (2007). Utilization of poultry, cow and kitchen wastes for biogas production: a comparative analysis. Iranian Journal of Environmental Health Science and Engineering, 4(4), 223–228.
Pechan, Z., Knappova, O., Petrovicova, B., Adamec, O. (1987). Anaerobic digestion of poultry manure at high ammonium nitrogen concentrations. Biological Wastes, 20, 117–131.
Phukoetphim, N., Salakkam, A., Laopaiboon, P., Laopaiboon, L. (2017). Kinetic models for batch ethanol production from sweet sorghum juice under normal and high gravity fermentations: Logistic and modified Gompertz models. Journal of Biotechnology, 243, 69–75.
Recebli, Z., Selimli, S., Ozkaymak, M., Gonc, O. (2015). Biogas production from animal manure. Journal of Engineering Science and Technology, 10(6), 722–729.
Syaichurrozi, I. (2018). Biogas production from co-digestion Salvinia molesta and rice straw and kinetics. Renewable Energy, 115, 76–86.
Webb, A.R., Hawkes, F.R. (1985). The anaerobic digestion of poultry manure: variation of gas yield with influent concentration and ammonium-nitrogen levels. Agricultural Wastes, 14, 135–156.