Agrarian Economy 2024 Т. 17 № 1: 138-144

INTEGRATION OF THE ENERGY MANAGEMENT SYSTEM INTO THE FUNCTIONING OF INNOVATIVE AUTOMATED VERTICAL CITY FARMS

Barulina I., assistant
ORCID ID: 0009-0006-3408-0063
Barulin D., assistant
ORCID ID: 0000-0002-2904-2023
Kherson State Agrarian and Economic University

https://doi.org/10.31734/agrarecon2024.01.138

ANNOTATION

Controlled agriculture within urban areas presents a promising solution to meet the growing food demands of urban areas and achieve global climate goals. Vertical farms have emerged as a popular form of controlled agriculture that can bring food production closer to urban centers. However, these farms often rely on significant energy-intensive processes. This article provides an overview of the current practices of automated vertical city farming and potential energy-efficient technologies that can enhance the sustainability and profitability of internal agriculture. The article discusses various sensors and production mechanisms that enable the automation of production processes on city farms. It also highlights successful research on energy systems and management strategies to increase energy efficiency in modern buildings. For instance, implementing an energy management system can help managers and owners reduce energy consumption and benefit from increased energy efficiency. The article explores different management strategies that can be used to achieve energy-saving goals in various types of buildings. The study also emphasizes the importance of training personnel in efficient and rational energy use, as this can lead to a 30% reduction in energy resource costs. Additionally, the article examines consumers' role in energy usage during the operational phase of both residential and non-residential structures. In conclusion, the article outlines forthcoming challenges in enhancing energy efficiency within the management framework of urban farms, alongside strategies to surmount them. By leveraging advancements in automation, energy systems, and personnel training, city farms can navigate toward greater sustainability while meeting the evolving needs of urban populations.

KEYWORDS

energy resources, energy efficiency, energy monitoring, sustainable development, optimization of energy resource usage, urban farming

FULL TEXT

LINK

  1. Ashouri, M. et al. 2019. Development of a ranking procedure for energy performance evaluation of buildings based on occupant behavior. Energy Build, 183, p. 659–671.
  2. Bonilla, D., Samaniego, M. G., Ramos, R. and Campbell, H., 2018. Practical and low-cost monitoring tool for building energy management systems using virtual instrumentation. Sustainable Cities and Society, 39, p. 155–162.
  3. Doukas, H. et al., 2007. Intelligent building energy management system using rule sets. Build. Environ, 42(10), p. 3562–3569.
  4. Dudiak, N.V. and Barylina, I.Yu., 2022. Development of city-farms in Ukraine as a prospect for overcoming food crisis. Tavria Scientific Bulletin. Series: Econoomics, 12, p. 12–28.
  5. Eguaras-Martínez, M. et al., 2014. Simulation and evaluation of Building Information Modeling in a real pilot site. Appl Energy, 114(4), p. 475–484.
  6. European Commission. Directive 2009/125/EC of the European Parliament and of the Council of 21 October 2009 Establishing a Framework for the Setting of Ecodesign Requirements for Energy-Related Products (Recast); European Commission: Brussels, Belgium, 2009.
  7. European Commission. Directive 2012/27/EU of the European Parliament and of the Council of 25 October 2012 on Energy Efficiency, Amending Directives 2009/125/EC and 2010/30/EU and Repealing Directives 2004/8/EC and 2006/32/EC; European Commission: Brussels, Belgium, 2012.
  8. European Commission. Energy Performance of Buildings Directive EU/2010/31 [online] Available at: https://ec.europa.eu/energy/en/topics/energy-efficiency/energy-performance-of-buildings/energy-performance-buildings-directive [Accessed January16, 2024].
  9. European Commission. Regulation (EU) 2017/1369 of the European Parliament and of the Council of 4 July 2017 Setting a Framework for Energy Labelling and Repealing Directive 2010/30/EU; European Commission: Brussels, Belgium, 2017.
  10. Lendiel, M. O., Ivanytskyi, V. P. and Hychka, A., 2021. Energy Management and Energy Audit. Uzhhorod National University. 56 p.
  11. Mariano-Hernández, D., Hernández-Callejo, L., Zorita-Lamadrid, A., Duque-Pérez, O. and García, F. S., 2021. A review of strategies for building energy management system: Model predictive control, demand side management, optimization, and fault detect & diagnosis. Journal of Building Engineering, 33:101692.
  12. Marinakis, V., 2020. Big data for energy management and energy-efficient buildings. Energies, 13 (70), p. 15–55.
  13. Naylor, S., Gillott, M. and Lau, T., 2018. A review of occupant-centric building control strategies to reduce building energy use. Renewable and Sustainable Energy Reviews, 96, p. 1–10.
  14. Podder, A. K., Al Bukhari, A., Islam, S., Mia, S., Mohammed, M. A., Kumar, N. M. and Abdulkareem, K. H., 2021. IoT based smart agrotech system for verification of Urban farming parameters. Microprocessors and Microsystems, 82, 104025.
  15. Saad, M. H. M., Hamdan, N. M. and Sarker, M. R., 2021. State of the art of urban smart vertical farming automation system: Advanced topologies, issues and recommendations. Electronics, 10 (12), p. 14–22.
  16. Seeam, А., Laurenson, D. and Usmani, А., 2018. Evaluating the potential of simulation assisted energy management systems: a case for electrical heating optimization Energy Build, 174, p. 579–586.
  17. State Agency on Energy Efficiency and Energy Saving of Ukraine, 2016. State Agency on Energy Efficiency and Energy Saving plans for the implementation of Energy Management System [online] Available at: https://network.bellona.org/content/uploads/sites/3/2016/05/3d-Forum_SAEE_presentation_3d-EnergyClimate-Dialogue.pdf [Accessed January16, 2024].
  18. Tikhonova, N. O., 2022. Energy management as a component of the «Green Economy», 4 (Pt1), p. 79–81.
  19. Tong, Z. et al., 2016. A case study of air quality above an urban rooftop vegetable farm. Environ Pollut, 208 (Pt A), p. 256–260.