Modeling of environmental-energy efficiency of the biogas installation with heat supplying of the biomass fermentation process

Ratushniak, Georgiy; Biks, Yuriy; Lyalyuk, Olena; Ratushnyak, Olga; Lyalyuk, Andriy

doi:10.21307/ACEE-2020-036

Artykuł - szczegóły

Tytuł artykułu

Modeling of environmental-energy efficiency of the biogas installation with heat supplying of the biomass fermentation process

Autorzy

Ratushniak Georgiy , Biks Yuriy , Lyalyuk Olena , Ratushnyak Olga , Lyalyuk Andriy

Wybrane pełne teksty z tego czasopisma

Identyfikatory

DOI

10.21307/ACEE-2020-036

Warianty tytułu

Języki publikacji

Abstrakty

The determinants of profitability and environmental friendliness of bioconversion are noted in the paper. As one of the major factors the reduction of thermal energy costs for the fermentation of organic wastes in their utilization is proposed to take into consideration. The expediency of using renewable energy sources for thermal stabilization of the fermentation process, especially in the thermophilic mode of organic fermentation, is emphasized. The energy efficiency biogas installation with structural and technological scheme is given as an example. It receives thermal energy to increase its efficiency from a solar collector and a heat pump. It is proposed to evaluate the energy efficiency of a biogas plant taking into account the cost of bioconversion products and the costs of providing this process. A mathematical model was proposed to substantiate the environmental-economic efficiency of a biogas installation with the minimum energy costs for the thermal stabilization of the biomass fermentation process. The model is based on fuzzy set theory which uses linguistic variables. Linguistic variables take into account the influence of quantitative and qualitative factors on the objective function.

Słowa kluczowe

biogas installation biomass eco-energy efficiency fermentation fuzzy logic renewable energy sources thermal stabilization

instalacja biogazowa biomasa efektywność ekoenergetyczna fermentacja logika rozmyta odnawialne źródła energii stabilizacja termiczna

Wydawca

Silesian University of Technology

Czasopismo

Architecture Civil Engineering Environment

Rocznik

2020

Tom

Vol. 13, no. 4

Strony

115--124

Opis fizyczny

Bibliogr. 33 poz.

Twórcy

autor

Ratushniak Georgiy

ratusnakg@gmail.com

PhD, Prof.; Department of Engineering Systems in Construction, Vinnytsia National Technical University, Voiniv Internatsionalistiv, 7. Vinnytsia, 21000 Ukraine

autor

Biks Yuriy

biksyuriy@gmail.com

PhD, Assosiated Prof.; Department of Construction, Architecture and Municipal Economy, Vinnytsia National Technical University, Voiniv Internatsionalistiv, 7. Vinnytsia, 21000 Ukraine

autor

Lyalyuk Olena

lyalyuk74@gmail.com

PhD, Assosiated Prof.; Department of Construction, Architecture and Municipal Economy, Vinnytsia National Technical University, Voiniv Internatsionalistiv, 7. Vinnytsia, 21000 Ukraine

autor

Ratushnyak Olga

ogratushnyak@gmail.com

PhD, Assosiated Prof.; Department of Enterprise Economics and Production Management, Vinnytsia National Technical University, Khmelnyts’ke shosse, 95. Vinnytsia, 21000 Ukraine

autor

Lyalyuk Andriy

1b16b.lyalyuk@gmail.com

Master’s student; Department of Construction, Architecture and Municipal Economy, Vinnytsia National Technical University, Voiniv Internatsionalistiv, 7. Vinnytsia, 21000 Ukraine

Bibliografia

[1] Geletuha, G. G., Zheleznaya, T. A., Kucheruk, P. P., & Olejnik, E. N. (2014). Sovremennoe sostoyanie i perspektivy razvitiya bioenergetiki v Ukraine (Modern state of the art and prospects of bioenergy development). Analiticheskaya zapiska BAU 9, (Analytical note of Bioenergy Association of Ukraine 9), 25.
[2] Kudria, S. O. (2015). Sostoyanie i perspektivy razvitiya vozobnovlyaemoj energetiki v Ukraine (State and prospects for development of renewable energy in Ukraine). Visnyk Natsionalnoi akademii nauk Ukrainy (Bulletin of the National Academy of Sciences of Ukraine), 12, 19-26.
[3] Ratushniak, H. S., Lialiuk, O. H., & Koshcheiev, I. A. (2017). Biohazovi ustanovky z vidnovliuvanymy dzherelamy enerhii termo-stabilizatsii protsesu fermentatsii biomasy (Biogas installations with renewable energy sources of thermo-stabilization biomass fermentation) Vinnytsia: VNTU, 110.
[4] Baader, W. (1978). Technische Voraussetzungen und Konsequenzen fur Biogasgewinnung im landwirtschaftlichen Bereich. Landtechnik.
[5] Dubrovin, V. O., Melnichuk, M. D., & Melnik, Y. F. (2009). Bioenergiya v Ukrayini - rozvitok silskih teritorij ta mozhlivosti dlya okremih gromad. (Bioenergy in Ukraine-rural development and opportunities for individual communities) K: NUBiP Ukrainy. (Kyiv: The National University of Life and Environmental Sciences of Ukraine), 111.
[6] Serbin, V. A. (2003). Netradicijni ta ponovlyuvani dzherela energiyi v sistemah TGP. (Non-conventional and renewable systems in HVAC)Makiyivka: Donbas National Academy of Civil Engineering and Architecture, 153.
[7] Drukovanyi, M. F. (2010). Suchasni tekhnolohii pererobky biomasy v biohaz ta orhanichni dobryva (Modern technologies of biomass processing into biogas and organic fertilizers). Zb. nauk. prats Vinnytskoho nats. ahrar. un-tu (Coll. of Science Works of Vinnytsia National Agrarian University), 42, 125-140.
[8] Joshua, O. S., Ejura, G. J., Bako, I. C., Gbaja, I. S., & Yusuf, Y. I. (2014). Fundamental principles of biogas product. Int J Sci Eng Res (IJSER), 2(8), 47-50.
[9] Golub, N., Kozlovets, O., & Voyevoda, D. (2016). Technology of anaerobic-aerobic purification of wastewater from nitrogen compounds after obtaining biogas. Eastern-European Journal of Enterprise Technologies, 3(10), 35-40.
[10] Geletuha, G. G., & Kobzar’, S. G. (2002). Sovremennye tekhnologii anaerobnogo sbrazhivaniya biomassy (Obzor) (Modern technologies of anaerobic digestion of biomass (Review)). Ekotekhnologii i resursosberezhenie (Ecotechnologies and resource conservation), 4, 3-10.
[11] Zhelykh, V. M., & Furdas, Yu. V. (2013). Pidtrymannia teplovoho rezhymu bioreaktora pid chas zastosuvannia soniachnoi enerhii (The bioreactor thermal regime maintaining when using solar energy). Suchasni tekhnolohii, materialy i konstruktsii v budivnytstvi (Modern Technology, Materials and Design in Construction), 1, 142-148.
[12] Borovska, T. M., & Severilov, P. V. (2009). Modeliuvannia y optymizatsiia system vyrobnytstva biohazu (Modeling and optimization of biogas production systems). Naukovi pratsi VNTU (Scientific works of VNTU), 2, 1-9.
[13] Ratushnyak, G. S. (2012). Intensification of Biogas Production By Means of Mechanical Mixing of The Substrate. Tap Chi Khoa hoc & Cong nghe, 8, 57.
[14] Redko, A. O., Bezrodnyi, M. K., Zahoruchenko, M. V., Redko, O. F., Ratushniak, H. S., & Khmelniuk, M. H. (2016). Nyzkopotentsiina enerhetyka (Low-potential energy). Kharkiv: TOV “Drukarnia Madryd”, 412.
[15] Tkachenko, S. Y., Stepanov, D. V., & Stepanova, N. D. (2020). Analiz sotsialnoi ta enerho-i pryrodozberezhnoi efektyvnosti realizatsii biohazovoi tekhnolohii (Analysis of social and energy-environmental efficiency of biogas technology’s realization). Visnyk Vinnytskoho politekhnichnoho instytutu (Herald of Vinnytsia politechnical institute), 2, 34-41.
[16] Ziemiński, K., & Frąc, M. (2012). Methane fermentation process as anaerobic digestion of biomass: Transformations, stages and microorganisms. African Journal of Biotechnology, 11(18), 4127-4139.
[17] Zemlianka, O. O., & Hubynskyi, M. V. (2009). Vybir ratsionalnykh rezhymiv roboty reaktora biohazovoi ustanovky. (The choice of rational modes of operation of the biogas installation reactor). Tekhnichna teplofizyka ta promyslova teploenerhetyka (Technical thermophysics and industrial thermal power engineering), 1, 112-120.
[18] Weiland, P. (2003). Production and energetic use of biogas from energy crops and wastes in Germany. Applied biochemistry and biotechnology, 109(1-3), 263-274.
[19] Zuiev, O. O. (2009). Ekonomichni aspekty vprovadzhennia suchasnykh biohazovykh ustanovok (Economic aspects of modern biogas installations implementation). Proceedings of the Tavria State agrotechnological university, 5(9), 88-92. Retrieved from: http/www.nbuv.gov.ua/portal/chem.biol/ptdan/2009_9_5/5113.pdf.
[20] Rotshtein, O. P., Lariushkin, P., & Mitiushkin, Yu. I. (2008). Soft computing v biotekhnolohii: bahatofaktornyi analiz i diahnostyka (Soft computing in biotechnology: multivariate analysis and diagnostics). Vinnytsia: UNIVERSUM-Vinnytsia, 144.
[21] Baral, S., Pudasaini, S., Khanal, S., & Gurung, D. (2013). Mathematical modelling, finite element simulation and experimental validation of biogas-digester slurry temperature. International Journal of Energy and Power Engineering, 2(3), 128-135.
[22] Megonigal, J. P., Hines, M. E., & Visscher, P. T. (2004). Anaerobic metabolism: linkages to trace gases and aerobic processes. In Biogeochemistry, 317-392.
[23] Pham, C. H., Vu, C. C., Sommer, S. G., & Bruun, S. (2014). Factors affecting process temperature and biogas production in small-scale rural biogas digesters in winter in northern Vietnam. Asian-Australasian journal of animal sciences, 27(7), 1050-1056.
[24] Tkachenko, S. Y., & Rezydent, N. V. (2011). Teploobmin v systemakh biokonversii (Heat transfer in bioconversion systems). Vinnytsia: VNTU.
[25] Turkdogan-Aydınol, F. I., & Yetilmezsoy, K. (2010). A fuzzy-logic-based model to predict biogas and methane production rates in a pilot-scale mesophilic UASB reactor treating molasses wastewater. Journal of hazardous materials, 182(1-3), 460-471.
[26] Suganthi, L., Iniyan, S., & Samuel, A. A. (2015). Applications of fuzzy logic in renewable energy systems - a review. Renewable and sustainable energy reviews, 48, 585-607.
[27] Finzi, A., Oberti, R., Riva, E., & Provolo, G. (2014). A Simple Fuzzy Logic Management SupportSystem for Farm Biogas Plants. Applied Engineering in Agriculture, 30(3), 509-518.
[28] Blesgen, A., & Hass, V. C. (2010). Efficient biogas production through process simulation. Energy & fuels, 24(9), 4721-4727.
[29] Chen, T., Shen, D., Jin, Y., Li, H., Yu, Z., Feng, H., ... & Yin, J. (2017). Comprehensive evaluation of environ- economic benefits of anaerobic digestion technology in an integrated food waste-based methane plant using a fuzzy mathematical model. Applied Energy, 208, 666-677.
[30] Djatkov, D., Effenberger,M., &Martinov,M. (2014). Method for assessing and improving the efficiency of agricultural biogas plants based on fuzzy logic and expert systems. Applied energy, 134, 163-175.
[31] Latinwo, G. K., & Agarry, S. E. (2015). Modelling the kinetics of biogas production from mesophilic anaerobic co-digestion of cow dung with plantain peels. International Journal of Renewable Energy Development, 4(1), 55.
[32] Yordanova, S. N. E. J. A. N. A. (2007). Single input fuzzy control for nonlinear and time-varying plant. In Proc. of the 11th WSEAS international conference on Systems, 189-193.
[33] Wahmkow, C., Knape, M., & Konnerth, E. (2013, June). Biogas Intelligence-operate biogas plants using Neural Network and Fuzzy logic. In 2013 Joint IFSA World Congress and NAFIPS Annual Meeting (IFSA/NAFIPS), 1483-1488. IEEE.

Uwagi

Opracowanie rekordu ze środków MNiSW, umowa Nr 461252 w ramach programu "Społeczna odpowiedzialność nauki" - moduł: Popularyzacja nauki i promocja sportu (2020).

Typ dokumentu

Bibliografia

Identyfikator YADDA

bwmeta1.element.baztech-4f9fde84-5ff9-477b-95e2-d0171053cae8