| Title | European Green Deal: Substantiation of the Rational Configuration of the Bioenergy Production System from Organic Waste |
|---|---|
| ID_Doc | 63043 |
| Authors | Tryhuba, I; Tryhuba, A; Hutsol, T; Szufa, S; Glowacki, S; Andrushkiv, O; Padyuka, R; Faichuk, O; Slavina, N |
| Title | European Green Deal: Substantiation of the Rational Configuration of the Bioenergy Production System from Organic Waste |
| Year | 2024 |
| Published | Energies, 17, 17 |
| Abstract | A review of the current state of the theory and practice of bioenergy production from waste allowed us to identify the scientific and applied problem of substantiating the rational configuration of a modular anaerobic bioenergy system, taking into account the volume of organic waste generated in settlements. To solve this problem, this paper develops an approach and an algorithm for matching the configuration of a modular anaerobic bioenergy production system with the amount of organic waste generated in residential areas. Unlike the existing tools, this takes into account the peculiarities of residential areas, which is the basis for accurate forecasting of organic waste generation and, accordingly, determining the configuration of the bioenergy production system. In addition, for each of the scenarios, the anaerobic digestion process is modeled, which allows us to determine the functional indicators that underlie the determination of a rational configuration in terms of cost and environmental performance. Based on the use of the developed tools for the production conditions of the Golosko residential area, Lviv (Ukraine), possible scenarios for the installation of modular anaerobic bioenergy production systems are substantiated. It was found that the greatest annual benefits are obtained from the processing of mixed food and yard waste. The payback period of investments in modular anaerobic bioenergy production systems for given conditions of a residential area largely depends on their configuration and ranges from 3.3 to 8.4 years, which differ from each other by 2.5 times. This indicates that the developed toolkit is of practical value, as it allows the coordination of the rational configuration of modular anaerobic bioenergy production systems with real production conditions. In the future, it is recommended to use the proposed decision support system to model the use of biomass as an energy resource in residential areas, which ensures the determination of the rational configuration of a modular anaerobic bioenergy production system for given conditions. |
| https://doi.org/10.3390/en17174513 |
Similar Articles
| ID | Score | Article |
|---|---|---|
63017
|
Tryhuba, I; Tryhuba, A; Hutsol, T; Lopushniak, V; Cieszewska, A; Andrushkiv, O; Barabasz, W; Pikulicka, A; Kowalczyk, Z; Vasyuk, V European Green Deal: Justification of the Relationships between the Functional Indicators of Bioenergy Production Systems Using Organic Residential Waste Based on the Analysis of the State of Theory and Practice(2024)Energies, 17, 6 | |
| 74577
|
Bijarchiyan, M; Sahebi, H; Mirzamohammadi, S A sustainable biomass network design model for bioenergy production by anaerobic digestion technology: using agricultural residues and livestock manure(2020)Energy Sustainability And Society, 10, 1 | |
| 25868
|
Ragazzi, M; Maniscalco, M; Torretta, V; Ferronato, N; Rada, EC Anaerobic digestion as sustainable source of energy: A dynamic approach for improving the recovery of organic waste(2017) | |
| 24198
|
Vlachokostas, C; Achillas, C; Agnantiaris, I; Michailidou, AV; Pallas, C; Feleki, E; Moussiopoulos, N Decision Support System to Implement Units of Alternative Biowaste Treatment for Producing Bioenergy and Boosting Local Bioeconomy(2020)Energies, 13, 9 | |
| 8492
|
Lindkvist, E; Johansson, MT; Rosenqvist, J Methodology for Analysing Energy Demand in Biogas Production Plants-A Comparative Study of Two Biogas Plants(2017)Energies, 10.0, 11 | |
| 10455
|
Sevillano, CA; Pesantes, AA; Carpio, EP; Martínez, EJ; Gómez, X Anaerobic Digestion for Producing Renewable Energy-The Evolution of This Technology in a New Uncertain Scenario(2021)Entropy, 23, 2 | |
| 18887
|
Misrol, MA; Alwi, SRW; Lim, JS; Abd Manan, Z Biogas production from multiple feedstock at the district-level centralized facility for multiple end-use options: a case study in Johor Bahru, Malaysia(2022)Clean Technologies And Environmental Policy, 24.0, 1 | |
| 14320
|
Gungor, B; Dincer, I Development of a waste-to-energy gasification system for sustainable communities(2022)International Journal Of Energy Research, 46, 14 | |
| 25549
|
Szyba, M; Mikulik, J Analysis of Feasibility of Producing and Using Biogas in Large Cities, Based on the Example of Krakow and Its Surrounding Municipalities(2023)Energies, 16, 22 | |
| 26533
|
Cusenza, MA; Longo, S; Guarino, F; Cellura, M Energy and environmental assessment of residual bio-wastes management strategies(2021) |