1. bookVolume 25 (2021): Issue 1 (January 2021)
Journal Details
License
Format
Journal
First Published
12 Mar 2016
Publication timeframe
1 time per year
Languages
English
access type Open Access

Concept of Biohydrogen Production by Agricultural Enterprises

Published Online: 24 May 2021
Page range: 63 - 72
Received: 01 Mar 2021
Accepted: 01 Apr 2021
Journal Details
License
Format
Journal
First Published
12 Mar 2016
Publication timeframe
1 time per year
Languages
English
Abstract

Biohydrogen production in agricultural enterprises is an urgent matter. It is appropriate to utilize two methods of biohydrogen production: a thermochemical method – from crop-based biomass and anaerobic digestion (fermentation) method – from animal-based biomass.. It is appropriate to use gasifiers for the thermochemical method and biore-actors for fermentation method.

The theoretical potential of biohydrogen was established with due regard to the amount of biomass which is necessary for utilization in livestock agriculture, for fields fertilization as well as with the consideration of the coefficients of concordance with hydrogen equivalent and loss factor under biohydrogen production. The theoretical potential of biohydrogen from crop-based biomass in Ukraine amounts to 77 billion m3, during the period of three years (on average 25.6 billion m3 per year).

Keywords

Avcıoğlu, A.O., Dayıoğlu, M.A., Türker, U. (2019). Assessment of the Energy Potential of Agricultural Biomass Residues in Turkey. Renewable Energy, 138, 610-619. https://doi.org/10.1016/j.renene.2019.01.053. Search in Google Scholar

Baeyens, J., Zhang, H., Nie, J., Appels, L., Dewil, R., Ansart, R., Deng, Y. (2020). Reviewing the potential of bio-hydrogen production by fermentation. Renewable and Sustainable Energy Reviews, 131, 1-16. https://doi.org/10.1016/j.rser.2020.110023. Search in Google Scholar

Bhoopendra, P., Yogesh, K.P., Pratik, N.S. (2019). Recent progress in thermochemical techniques to produce hydrogen gas from biomass: A state of the art review. International Journal of Hydrogen Energy, 44(47), 25384-25415. https://doi.org/10.1016/j.ijhydene.2019.08.031 Search in Google Scholar

Cao, L., Yu, I.K.M., Xiong, X., Tsang, D.C. W., Zhang, S., Clark, J.H., Hu, C., Ng, Y.H., Shang, Y., Ok, Y.S. (2020). Biorenewable hydrogen production through biomass gasification: A review and future prospects. Environmental Research, 186, 1-13. https://doi.org/10.1016/j.envres.2020.109547 Search in Google Scholar

Gas Decarbonisation Methods 2020–2050. Gas for Climate. Retrieved: https://fuelcellsworks.com/news/gas-for-climate-study-describes-gas-decarbonisation-pathways-from-2020-to-2050-identifies-required-investments-to-scale-up-hydrogen-and-biomethane/. Access: 5.09.2020. Search in Google Scholar

Golub, G., Kukharets, S., Skydan, O., Yarosh, Y., Chuba, V., Golub, V. (2020a). The Optimization of the Gasifier Recovery Zone Height When Working on Straw Pellets. Іnternational Journal of Renewable Energy Research, 10(2), 529-536. Search in Google Scholar

Golub, G., Kukharets, S., Tsyvenkova, N., Yarosh, Ya., Chuba, V. (2018) Experimental study into the influence of straw content in fuel on parameters of generator gas. Eastern-European Journal of Enterprise Technologies. 5/8(95), 76-86. https://doi.org/10.15587/1729-4061.2018.142159. Search in Google Scholar

Golub, G., Kukharets, S., Yarosh, Y., Zavadska, O. (2017). Diversified production and bioenergy conversion for rural development. Proceedings of the 8th International Scientific Conference Rural Development 2017, 333-337. http://doi.org/10.15544/RD.2017.186. Search in Google Scholar

Golub, G., Skydan, O., Kukharets, V., Yarosh, Y., Kukharets, S. (2020b). The estimation of energetically self-sufficient agroecosystem’s model. Journal of Central European Agriculture, 21(1), 168-175. https://doi.org/10.5513/JCEA01/21.1.2482. Search in Google Scholar

Golub, G.A., Skydan, O.V., Kukharets, S.M., Marus, O.A. (2019). Substantiation of motion parameters of the substrate particles in the rotating digesters. INMATEH – Agricultural Engineering, 57(1), 179-186. Search in Google Scholar

Gomiero, T. (2018). Large-scale biofuels production: A possible threat to soil conservation and environmental services. Applied Soil Ecology, 123, 729-736. https://doi.org/10.1016/j.ap-soil.2017.09.028. Search in Google Scholar

Kukharets, S. (2016). Improvement of Agroecosystems Energy Sufficiency. Mechanical and Technological Grounds: monograph. ZhNAEU, Zhytomyr. pp. 192. Search in Google Scholar

Kukharets, S., Golub, G. (2015). Source of raw materials and production efficiency of biogaz. Scientific Journal NUBaN Ukraine. A series of «Technology and Energy AIC». 212(1). 11-20. Retrieved: http://journals.nubip.edu.ua/index.php/Tekhnica/article/view/6902. Access: 29.04.2021. Search in Google Scholar

Mortensen, A. W., Mathiesen, B.V., Hansen, A.B., Pedersen, S.L., Grandal, R.D., Wenzel, H. (2020). The role of electrification and hydrogen in breaking the biomass bottleneck of the renewable energy system – A study on the Danish energy system. Applied Energy, 275, 1-14. https://doi.org/10.1016/j.apenergy.2020.115331 Search in Google Scholar

Ovcharuk, O., Hutsol, T., Ovcharuk, O., Rudskyi, V., Mudryk, K., Jewiarz, M., Wróbel, M., Styks, J. (2020). Prospects of Use of Nutrient Remains of Corn Plants on Biofuels and Production Technology of Pellets. Renewable Energy Sources: Engineering, Technology, Innovation, 1, 293-300. https://doi.org/10.1007/978-3-030-13888-2_29 Search in Google Scholar

Pandey, B., Prajapati, Y.K., Sheth P.N. (2019). Recent progress in thermochemical techniques to produce hydrogen gas from biomass: A state of the art review. International Journal of Hydrogen Energy, 44(47), 25384-25415. https://doi.org/10.1016/j.ijhydene.2019.08.031 Search in Google Scholar

Roslynnytstvo Ukrainy 2019. Statystychnyi zbirnyk. Derzhavna sluzhba statystyky Ukrainy. Retrieved: http://www.ukrstat.gov.ua/druk/publicat/kat_u/publ7_u.htm/. Access: 29.04.2021. Search in Google Scholar

Rzeznik, W., Mielcarek, P. (2018). Agricultural biogas plants in Poland. Engineering for rural development, 17, 1760-1765. http://doi.org/10.22616/ERDev2018.17.N310 Search in Google Scholar

Tryhuba, A., Hutsol, T., Glowacki, S., Tryhuba, I., Tabor, S., Kwasniewski, D., Sorokin, D., Yermakov, S. (2021a). Forecasting Quantitative Risk Indicators of Investors in Projects of Biohydrogen Production from Agricultural Raw Materials. Processes 2021, 9(2), 258. https://doi.org/10.3390/pr9020258 Search in Google Scholar

Tryhuba, A., Hutsol, T., Tryhuba, I., Pokotylska, N., Kovalenko, N., Tabor, S., Kwasniewski, D. (2021b). Risk Assessment of Investments in Projects of Production of Raw Materials for Bioethanol. Processes 2021, 9(1), 12. https://doi.org/10.3390/pr9010012 Search in Google Scholar

Verdade, L.M., Piña, C.I., Rosalino, L.M. (2015). Biofuels and biodiversity: Challenges and opportunities. Environmental Development, 15, 64-78. https://doi:10.1016/j.envdev.2015.05.003 Search in Google Scholar

Yarosh, Ya. (2020). Energy Sufficiency of Agroecosystems: monograph. ZhNAEU, Zhytomyr. pp. 316 Search in Google Scholar

Recommended articles from Trend MD

Plan your remote conference with Sciendo