DOI: https://doi.org/10.14710/jebt.2022.13442

Perancangan PLTS Rooftop untuk Pemakaian Sendiri (PS) di PLTU Berau 2 × 7 MW

1Magister Energi, Sekolah Pascasarjana, Universitas Diponegoro, Indonesia

2Departemen Teknik Mesin, Fakultas Teknik, Universitas Diponegoro, Indonesia

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Abstract

PLTU Berau 2 × 7 MW terletak di Kelurahan Teluk Bayur Kecamatan Teluk Bayur Kabupaten Berau Provinsi Kalimantan Timur yang Operation & Maintenance-nya di Kelola oleh PT. Indonesia Power. PLTU Berau 2 × 7 MW mensuplai energi listrik ke sistem jaringan isolated 20 KV Tanjung redeb. Konsumsi daya listrik (Pemakaian Sendiri) rata-rata sebesar 10.419.942,030 kWh/tahun. Salah satu program untuk menurunkan konsumsi pemakaian sendiri dan untuk mendukung kebijakan peningkatan Energi Baru Terbarukan (EBT) dalam bauran energi nasional hingga 23% pada tahun 2025 yaitu dengan pemasangan PLTS Rooftop. Kawasan PLTU Berau 2 × 7 MW memiliki nilai radiasi rata-rata sebesar 4,67 kWh/m²/hari sepanjang tahun 2020 dan rata-rata 3,9 kWh/m²/hari dalam rentang 22 tahun. Tujuan dari penelitian ini untuk mengetahui potensi energi surya yang dapat dihasilkan dilokasi Rooftop PLTU Berau 2 × 7 MW dengan menggunakan simulasi software HelioScope. Dari hasil simulasi diperoleh potensi energi listrik yang dapat dihasilkan adalah 570.364 kWh/tahun.

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Keywords: PLTU Berau 2 × 7 MW; PLTS Rooftop; HelioScope

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  28. Umar, N. H., Bora, B., Umar, N., Banerjee, C., & Panwar, B. S. (2018). Study of different PV Technologies under Composite Climates using test beds at NISE View project All-India Survey of Photovoltaic Module Reliability: 2016 View project Comparison of different PV power simulation softwares: case study on performance analysis of 1 MW grid-connected PV solar power plant. www.ijesi.org||Volumewww.ijesi.org
  29. Umer, F., Aslam, M. S., Rabbani, M. S., Hanif, M. J., Naeem, N., & Abbas, M. T. (2019). Design and optimization of solar carport canopies for maximum power generation and efficiency at Bahawalpur. International Journal of Photoenergy, 2019. https://doi.org/10.1155/2019/6372503

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