KONFIGURACIJA SONČNE ELEKTRARNE NA RAVNI STREHI ZA MAKSIMALNO PROIZVODNJO ELEKTRIČNE ENERGIJE
Povzetek
Komercialne sončne elektrarne se velikokrat postavljajo na večje industrijske, skladiščne in trgovske objekte. Moderne montažne konstrukcije tovrstnih objektov narekujejo arhitekturne rešitve v izvedbi ravnih streh, ki so posebej primerne za postavitev večjih sončnih elektrarn. Tako je cilj članka raziskati optimalno konfiguracijo sončnih modulov na ravni strehi z namenom doseganja maksimalne proizvodnje električne energije. V tem delu je izvedena raziskava glede tega, katera orientacija sončnih modulov in kateri nakloni so primerni za izvedbo na ravni strehi s ciljem, da bo dosežena maksimalna letna proizvodnja električne energije. Gre za določitev maksimalne letne proizvodnje na površino in na inštalirano moč modulov. Simulacijski rezultati so izvedeni za vse mesece leta ter za geografsko širino in dolžino mesta Lenart v Sloveniji.
Prenosi
Literatura
D. H. Meadows et al.: The Limits to Growth, Universe Books, 1972
Directorate-General for Structural Reform Support: Technical support for implementing the European Green Deal, Publication Office of the European Union in Luxembourg, 2020
M. Borowiecki et al.: Accelerating the EU’s green transition, OECD Economics Department Working Papers, No. 1777, 2023
A. M. Reveshti et al.: Investigating the effect of new and old weather data on the energy consumption of buildings affected by global warming in different climates, International Journal of Thermofluids, No. 19, 2023
A. A. Ahmed: Global warming potential, water footprint, and energy demand of shared autonomous electric vehicles incorporating circular economy practices, Sustainable Production and Consumption, No. 36, 2023
Editorial: Sustainable development of energy, water and environment systems in the critical decade for climate action, Energy Conversion and Managementtle, No. 296, 2023
P. Jain et al.: Agrovoltaics: Step towards sustainable energy-food combination, Bioresource Technology Reports, No. 15, 2021
C. J. Torrente et al.: Simulation model to analyze the spatial distribution of solar radiation in agrivoltaic Mediterranean greenhouses and its effect on crop water needs, Applied Energy, No. 353, 2024
International Code Council: International Building Code, USA, 2021
D. Kastelec et al.: Sončna energija v Sloveniji, Ljubljana, 2007
E. Golubovska et al.: Analytical estimation of the optimal PV panel tilt based on a clear sky irradiance model, Journal of Energy Technology, Vol. 16, Iss. 4, 2023
S. Seme: Optimalno sledenje fotonapetostnega sistema soncu ob upoštevanju izgub pogonskega sklopa, doctoral dissertation, UM FERI, 2011
Solarific. Available: https://solarific.co/si (date of last access: 13. 8. 2024)
A. Dudek: Equity research: SolarEdge Technologies, INC., University of Algarve, 2023
Energy Simulation Validation: SolarEdge Designer Review, 2019. Available: https://knowledge-center.solaredge.com/sites/kc/files/se-designer-simulation-validation-dnv-gl-report.pdf (last access: 13. 8. 2024)
Huasun. Available: G10-182-108-DS_EN (huasunsolar.com) (last access: 13. 8. 2024)
Huason. Available: se-three-phase-inverter-extended-power-datasheet.pdf (solaredge.com) (last access 13. 8. 2024)
Y. Yang et al.: Potential analysis of roof-mounted solar photovoltaics in Sweden, Applied Energy, No. 279, 2020
SolarPower Europe: Rooftop PV Fire Safety Factsheet. Available: https://api.solarpowereurope.org/uploads/Factsheet_Rooftop_PV_Fire_Safety_vfinal_33eaab8bb3.pdf?updated_at=2024-03-18T15:38:06.684Z (last access: 13. 8. 2024)
