Sistem Photovoltaic (PV) Di Gedung ITS PKU Muhammadiyah Surakarta
DOI:
https://doi.org/10.61132/jupiter.v1i6.291Keywords:
photovoltaic (PV) system, renewable energy, PV simulinkAbstract
To support green energy and reduce the effects of greenhouse gases, it is necessary to conceptualize and explore the use of renewable energy. In this research, the use of new renewable energy, especially photovoltaics (PV), will be applied to educational buildings, especially at ITS PKU Muhammadiyah Surakarta. This system is intended to reduce the use of conventional electrical energy. This system will be installed on the roofs of campus buildings with installation plans to meet the power requirement of 4.8 kW. This photovoltaic (PV) system will be modeled to determine the number of PV panels needed. Based on the simulation results, the number of panels required is 36 panels (2 series, 18 parallel) to produce 4.85kWh of power. Modeling and analysis of this system was carried out using RETScreen and MATLAB SIMULINK software.
References
A. Garrod, S. N. Hussain, A. Ghosh, S. Nahata, C. Wynne, and S. Paver, “Results in Engineering An assessment of floating photovoltaic systems and energy storage methods : A comprehensive review,” Results Eng., vol. 21, no. January, p. 101940, 2024.
A. Qamili and S. Kapia, “Evaluation and integration of photovoltaic ( PV ) systems in Albanian energy landscape,” Sol. Compass, vol. 10, no. February, p. 100070, 2024.
BMKG, “Fungsi BMKG,” 2018. [Online]. Available: https://www.bmkg.go.id/profil/?p=tugas-fungsi.
C. Toledo, A. Ramos-escudero, L. Serrano-luján, and A. Urbina, “Photovoltaic technology as a tool for ecosystem recovery : A case study for the Mar Menor coastal lagoon,” vol. 356, no. August 2023, 2024.
G. Di Giovanni, M. Rotilio, L. Giusti, and M. Ehtsham, “Energy & Buildings Exploiting building information modeling and machine learning for optimizing rooftop photovoltaic systems,” Energy Build., vol. 313, no. December 2023, p. 114250, 2024.
G. El, N. Sami, A. Mahmoud, and C. Jung, “Analyzing the effectiveness of building integrated Photovoltaics ( BIPV ) to reduce the energy consumption in Dubai,” vol. 15, no. January, 2024.
I. Khele, “Developments in the Built Environment A review of the effect of semi-transparent building-integrated photovoltaics on the visual comfort indoors,” vol. 17, no. January, 2024.
J. Ruelas, F. Muñoz, J. Palomares, and J. Castro, “A dataset for photovoltaic energy potential of the Yaqui Valley , Sonora , México,” vol. 52, 2024.
L. Riondet, M. Rio, V. Perrot-bernardet, and P. Zwolinski, “ScienceDirect Towards ecodesign for upscaling : an illustrative case study on photovoltaic technology in France,” Procedia CIRP, vol. 122, pp. 407–412, 2024.
M. M. S. P. Rana, “Demarcation of suitable site for solar photovoltaic power plant installation in Bangladesh using geospatial techniques,” Next Energy, vol. 3, no. July 2023, p. 100109, 2024.
R. Galvin, “How photovoltaics make energy refurbishment more affordable in apartment buildings,” J. Clim. Financ., vol. 7, no. April, p. 100039, 2024.
S. A. Shibly, M. N. Akand, K. M. A. Salam, and H. A. Rahman, “A model of a renewable electricity system for telecom base stations in rural Bangladesh,” pp. 1–5, 2014.
X. Li, Y. Zhao, W. Zhang, F. Wang, W. Yin, and K. Liu, “Photovoltaic potential prediction and techno-economic analysis of China railway stations,” Energy Reports, vol. 10, no. October, pp. 3696–3710, 2023.
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