ANALISIS POTENSI ATAP BANGUNAN KAMPUS SEBAGAI LOKASI PENEMPATAN PANEL SURYA SEBAGAI SUMBER LISTRIK
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Abstract
Penelitian ini dilakukan dengan simulasi untuk mengetahui potensi pemanfaatan area atap bangunan kampus Universitas Surabaya untuk tempat pemasangan sistem Pembangkit Listrik Tenaga Surya (PLTS). Atap bangunan perpustakaan disimulaskan dan menjadi representasi perhitungan untuk atap bangunan yang lain. Sistem PLTS grid-connected dipakai dalam perhitungan energi listrik PLTS. Hasil penelitian menunjukkan bahwa tersedia area atap bangunan seluas 10.353 m2 yang dapat dimanfaatkan untuk instalasi panel surya. Total kapasitas listrik yang dihasilkan untuk area seluas itu adalah 2.030 kWp atau 2,03 MWp. Kapasitas sebanyak itu terbagi empat, yaitu 630 kWp dari atap yang menghadap Timur Laut, 535 kWp dari arah Barat Laut, 668 kWp pada arah Barat Daya dan 553 kWp dari arah Tenggara.
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References
Benatiallah, A. et al., 2007. A simulation model for sizing PV installations. Desalination, 209(1),
pp.97–101.
Bergamasco, L. & Asinari, P., 2011. Scalable methodology for the photovoltaic solar energy
potential assessment based on available roof surface area: Application to Piedmont Region
(Italy). Solar Energy, 85(5), pp.1041–1055.
Kandpal T.C. and Garg H.P., 2003. Financial evaluation of renewable energy technologies,
Ko, L. et al., 2015. Evaluation of the development potential of rooftop solar photovoltaic in
Taiwan. Renewable Energy, 76, pp.582–595.
Kuchler, S., 2013. Solar Energy Assesment Based on Weather Station Data for Direct Site
Monitoring in Indonesia. Dalarna University.
Marcel S. & Tomáš C., 2012. New Web-Based Service Offering Solar Radiation Data and PV
Simulation Tools for Europe, North Africa and Middle East. In Eurosun.
Ord????ez, J. et al., 2010. Analysis of the photovoltaic solar energy capacity of residential
rooftops in Andalusia (Spain). Renewable and Sustainable Energy Reviews, 14(7),
pp.2122–2130.
Orioli, A. & Di Gangi, A., 2014. Review of the energy and economic parameters involved in the
effectiveness of grid-connected PV systems installed in multi-storey buildings. Applied
Energy, 113, pp.955–969. Available at: http://dx.doi.org/10.1016/j.apenergy.2013.08.014.
Redweik, P., Catita, C. & Brito, M., 2013. Solar energy potential on roofs and facades in an
urban landscape. Solar Energy, 97, pp.332–341. SolarGis, SolarGis PVPlanner. Available
at: http://solargis.info/pvplanner [Accessed June 20, 2006].
Tarigan, E., Djuwari & Kartikasari, F.D., 2015. Techno-economic Simulation of a Gridconnected PV System Design as Specifically Applied to Residential in Surabaya,
Indonesia. Energy Procedia, 65, pp.90–99.
Vardimon, R., 2011. Assessment of the potential for distributed photovoltaic electricity
production in Israel. Renewable Energy, 36(2), pp.591–594.
Wiginton, L.K., Nguyen, H.T. & Pearce, J.M., 2010. Quantifying rooftop solar photovoltaic
potential for regional renewable energy policy. Computers, Environment and Urban
Systems, 34(4), pp.345–357.