The Effect of Tilt Angle of 200 WP Polycrystal Type Solar Panels on Output Power and Electrical Energy Efficiency
DOI:
https://doi.org/10.55927/ijsmr.v3i3.114Keywords:
Tilt Angle, Output Power, Efficiency, Solar PanelsAbstract
This research aims to determine the effect of the tilt angle of 200 Wp polycrystal type solar panels on output power and efficiency and to determine the optimal tilt angle in producing output power and efficiency. The data analysis techniques used are descriptive analysis techniques and regression analysis with One Way ANOVA statistics. The results of research on variations in solar panel tilt angles show that the output power and efficiency of 200 Wp polycrystal type solar panels, which have the most optimal solar panel slope angle is 30 degrees with data collection time at 12.00 WITA (Indonesian Central Time). This tilt angle produces the highest power output and efficiency values close to the specifications of the solar panels used
References
Apriyadi, S. D., Ery, D., Sc, D. M., and Sujatmiko, W. (2019). solar radiation measurements for solar factor calculations. 1204.
Arrasyid, A. H. (2017). Analysis of photovoltaic-based public street lighting and garden lighting planning at Bogor Pakuan University. Jurnal Online Mahasiswa (JOM) Bidang Teknik Elektro, 1(1)
Assiddiq, H., and Bastomi, M. (2019). analysis of the effect of temperature changes. IKA: Scientific Journal of Mechanical Engineering, 11(1), 33–38.
Ayu, F., Sugiono, F., Diah Larasati, P., Eriko, D., and Karuniawan, A. (2022). TOP at Mechanical Engineering Workshop, Semarang State Polytechnic. Journal of Energy Engineering , 01(01), 1–8.
Bahari, Laka, & Rosmiati. (2017). The Effect of Changing the Angle of Solar Cells Using Solar Energy, Light Intensity on Voltage. Prosiding Semnastek.
Basuki, Rosadi, M. M., and Hadi, F. S. (2020). Analysis of the Effect of Solar Panel Tilt Angle on the Intensity of Sunlight and the Voltage Produced by Polycrystalline Type Solar Panels. 4th National Seminar on SAINSTEKNOPARK LPPM UNHASY Tebuireng Jombang, 135 - 140
Darwin, Panjaitan, A., and Suwarno. (2020). Analysis of the Effect of Sunlight Intensity on Output Power in Monocrystalline Solar Cells. Mesil Journal (Mesin, Elektro, Sipil), 1(2), 99–106.
Dwisari, V., Sudarti, and Yushardi (2023). Harnessing Solar Energy: The Future of Renewable Energy. OPTIKA: Journal of Physics Education, 7(2), 376 – 384
Emes, Y. F., Kewas, J. C., and Pomalingo, M. F. (2022). Analysis of the Influence of the Tilt Angle of a Monocrystalline Type 10 Wp Solar Panel on Output Power. Actuator Mechanical Engineering Journal, 3 (2), 9-15
Engelbertus, T. (2017). Planning for a Solar Power Plant for Additional Power Supply at the Kini Hotel Pontianak. Journal of Electrical Engineering Universitas Tanjungpura , 1–8.
Fitryah. (2015). Solar Power Plant. Jakarta: Universitas Trisakti
Harahap, P. (2020). The Effect of Solar Panel Surface Temperature on the Power Generated from Various Types of Solar Cells. Electrical And Energy Engineering, 2(2), 73–80.
Hariningrum, R. (2021). Analysis of the Effect of Tilt Angle of 100 Wp Solar Panels on Electrical Power. Marine Science and Technology Journal, 1(2), 67–76.
Hasrul, rahmat. (2021). Analysis of the Efficiency of Solar Panels as Alternative Energy. Journal of Science, Energy, Technology & Industry, 5(2), 79–87.
Magrissa. (2015). Effect of Light Intensity on Solar Cell Efficiency 49 in MonoCrystalline Silicon Solar Cells. Jurnal Jurusan Kimia Universitas Negeri Padang
Napitupulu, dkk. (2017). The Influence of Monocrystalline and Polycrystalline Materials on the Characteristics of 20 Wp Solar Cells Using a Two-Axis Tracking System. Medan: Research Report, HKBP Nomensen University
Pagan, P. E. S., Sara, D. I., and Hasan, H. (2018). Comparison of the Performance of Monocrystalline and Polycrystalline Solar Panels, Banda Aceh Weather Case Study. KITEKTRO: Online Journal of Electrical Engineering, 3(4), 19–23.
Pandria, dkk. (2021). Determination of Optimum Tilt Angle Based on Solar Panel Energy Output. Jurnal Serambi Engineering, 6(1).
Pradona, Y. (2019). Angle Slope Variations on the Effectiveness of Solar Panel Performance. Universitas Muhammadiyah Sumatera Utara.
Priatam, D. T. P. putu, Zambak, F. M., and Harahap, P. (2021). Analysis of Solar Radiation on 50 WP Solar Panels. Electrical and Energy Engineering, 4(1), 48–54.
Purwoto, H. B., Jatmiko, F, A. M., and Huda, F. I. (2018). Efficiency of Using Solar Panels as an Alternative Energy Source. Emitter: Journal of Electrical Engineering, 18(1), 10–14.
Putriani, Basyir, M., and Muhaimin. (2019). Microcontroller Based Solar Panel Characteristics Test Equipment Monitoring System. Tectro Journal, 3(2).
Ramadhan, I. A., Diniardi, E., and Mukti, H. (2016). Analysis of Solar Power Generation System Design with Capacity 50 Wp. Teknik, 37(2), 59.
Sariman, S. (2021). Analysis of the Use of Monocrystalline Solar Cells as a Source of Electrical Energy in a 12 Volt Direct Current (DC) Water Pump with a Power of 180 Watts. Journal of Health Science, 2(5), 902–918.
Sarna, S., Murniati, R., & Nojeng, S. (n.d.). The Effect of Surface Temperature on the Conversion Efficiency of Mono-Crystaline Photovoltaic Types in Tropical Areas.
Shalih & Suratno. (2019). The Influence of the Direction of Solar Panel Installation Position on the Power Output. Just Ti (Jurnal Sains Terapan Teknologi Informasi), 11(2), 12-17.
Sihite. (2021). Study of the Effect of Slope Angle Solar Panels Against Light Intensity Solar Panels.
Suharta, P. N., Hendrawati, D., and Aulia, F. N. (2021). Analysis of Solar Panel Power Optimization Calculations Viewed from the Slope Angle of Solar Panel Irradiation Reception. SNTEM, 1, 846–855.
Sunardi, su’udy, hamim, ahmad, cundoko, anang, & istiantara, tri, dedik. (2021). Optimizing the Utilization of SHM (Solar Home System) as an Environmentally Friendly Electric Energy Generator. Journal of Energy Engineering , 17(2), 76–85.
Suryana, D. (2016). The Effect of Temperature on the Voltage Produced by Monocrystalline Solar Panels (Case Study: Baristand Industri Surabaya). Journal of Process Technology and Industrial Innovation, 1(2)
Suwarti, Wahyono, and Prasetiyo, B. (2018). Analysis of the Effect of Sun Intensity, Surface Temperature & Directional Angle on Solar Panel Performance. EXERGY Journal of Energy Engineering, 14(3), 78–85.
Widayana, gede. (2018). Utilization of Solar Energy. JFTK, Undiksha, 9(1), 37
Yassir, Y. (2019). Optimizing the Deviation Angle of Solar Panels Against Latitude Using Genetic Algorithm Methods, Case Study: Lhokseumawe State Polytechnic Campus. In Prosiding Seminar Nasional Politeknik Negeri Lhokseumawe (Vol. 3, No. 1, p. 52).
