PERFORMANCE OF ROOFTOP PHOTOVOLTAIC SYSTEM WITH ADDITIONAL WATER COOLING SYSTEM
Subur Priyono(1*), Wahyu Wilopo(2), Mohammad Kholid Ridwan(3)
(1) Universitas Gadjah Mada
(2) Universitas Gadjah Mada
(3) Universitas Gadjah Mada
(*) Corresponding Author
Abstract
Improving solar power plant performance is considered quite important for existing and prospective users of rooftop solar power plants in Indonesia due to its unattractive economic value. One of the efforts to optimize the performance is the application of an additional cooling system on the plant's photovoltaic module. This study aimed to determine the effectiveness of temperature reduction of the applied cooling system on solar panel productivity. The research was performed on the existing rooftop solar power plant with a capacity of 3 kWp, located in Depok City with coordinates of 6°38'03.40" South Latitude and 106°82'03.49" East Longitude.
The results showed that the additional water cooling system with a closed-loop pumping method on the installed solar module’s entire surface could improve the rooftop solar power plant performance with an average production increase of 15.7% in 7 days of study. Meanwhile, from an economic point of view, this cooling system installation payback period was 2 years.
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ABB SACE, A Division of ABB S.p.A. (2010). Technical Application Papers No.10 Photovoltaic Plants. Retrieved from
Adjat Sudrajat - BPPT. (2019). Overview Sistem PLTS. Pelatihan SIstem PLTS - Overview SIstem PLTS. Tangerang Selatan, Banten, Indonesia: Balai Besar Teknologi Konversi Energi - BPPT.
Afriandi, I. Y. (2017). Implementasi Water Cooling System untuk Menurunkan Temperature Losses pada Panel Surya.
Bagus Ramadhani - GIZ GmbH. (2018). Instalasi Pembangkit Listrik Tenaga Surya: Dos & Don'ts. Jakarta: Deutsche GIZ GmbH Energising Development (EnDev) Indonesia.
ESDM One Map. (2020, July 16). Retrieved from Solar Potensial: https://geoportal.esdm.go.id/
Haris Isyanto, B. F. (2017). Pendingin untuk Peningkatan Daya Keluaran Panel Surya.
Hasbi Assiddiq S, M. B. (2019). Analisis Pengaruh Perubahan Temperatur Panel terhadap Daya dan Efisiensi Keluaran Sel Surya Polycrystalline.
Joko Sumbodo, M. R. (2018). Effectiveness of Thermoelectric Cooling on Solar Panel. e-Proceeding of Engineering: Vol.5, No.3 Desenber 2018, (p. 3895).
Matthew Muller - NREL. (2010). Measuring and Modeling Nominal Operating Cell Temperature (NOCT). Alburquerque: NREL/PR-520-49505.
NREL. (2015). Best Practices Handbook for the Collection and Use of Solar Resources Data for Solar Energy Applications. Golden, Colorado: National Renewable Energy Laboratory.
Palumbo, A. (2013). Design and Analysis of Cooling Methods for Solar Panels. Research Gate
Rifaldo Pido, S. H. (2019). Analisa Pengaruh Pendinginan Sel Surya terhadap Daya Keluaran dan Efisiensi. UNM Online Journal, Vol.19.
Sunarno. (2019). Sistem Pendingin Pasif untuk Meningkatkan Daya Keluaran Panel Sel Surya. Repositori Institusi Universitas Sumatera Utara.
DOI: https://doi.org/10.22146/ajse.v4i2.63343
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