ABSTRAK

Baterai merupakan bagian penting dari sistem PLTS off-grid. Kendala yang sering terjadi pada baterai adalah siklus yang pendek dan rugi-rugi karena pengaruh internal resistance sehingga tidak optimal pada saat charging atau discharging. Pada penelitian ini dilakukan pengujian untuk membandingkan karakteristik jenis baterai Lead-Acid 12 Ah dan baterai Lithium-Ion 12 Ah pada sistem Off-Grid panel surya 120 Wp. Pengujian charging maksimal 5 jam, discharging dengan beban adjustable resistor 12 Ohm dengan maksimal pengujian 12 jam (Cut Off). Metode yang digunakan adalah modified Coulomb Counting, dan Pendekatan SoC dengan Simulasi Constant Current. Berdasarkan hasil penelitian, untuk menjaga siklus hidup baterai, waktu terbaik untuk mencegah deep discharge, SoC baterai Lead Acid 57,833% dan Lithium-Ion 42,839%. Charging baterai Lead Acid memiliki Constant Voltage 13,1 V dan baterai Lithium Ion memiliki Constant Current 2,4 A, saat discharging.

Kata kunci: Lead Acid, Lithium Ion, modified Coulomb Counting, SoC.

 

ABSTRACT

Batteries are an important part of the off-grid PLTS system. Constraints that often occur in batteries are short cycles and losses due to the influence of internal resistance so it is not optimal when charging or discharging. In this study, a test was conducted to compare the characteristics of a 12 Ah Lead-Acid battery and a 12 Ah Lithium-Ion battery in a 120 Wp off-grid solar panel system. Maximum charging test of 5 hours, Discharging with a 12 Ohm adjustable resistor load with a maximum of 12 hours of testing (Cut Off). The method used is modified Coulomb Counting and SoC Approach with Constant Current Simulation. Based on the research results, to maintain the life cycle of the battery, the best time to prevent deep discharge, SoC is 57.833% Lead-Acid battery and 42.839% Lithium-Ion battery. Charging Lead Acid batteries has a Constant Voltage of 13.1 V and Lithium on batteries have a Constant Current of 2.4 A when discharging.

Keywords: Lead Acid, Lithium Ion, modified Coulomb Counting, SoC.

Danko, Matúš, Juraj Adamec, Michal Taraba, dan Peter Drgona. (2019). Overview of Batteries State of Charge Estimation Methods. Transportation Research Procedia, 40, 186–92. https://doi.org/10.1016/j.trpro.2019.07.029.

Faturahman, Burhanudin Mukhamad. (2021). Peningkatan Porsi Energi Hijau Pada RUPTL 2021-2030. Pusat Penelitian Badan Keahlian DPR RI XIII: 19.

Gumintang, M Afkar, M Faizal Sofyan, dan Ilham Sulaeman. (2020). Design and Control of PV Hybrid System in Practice. Deutsche Gesellschaft für Internationale Zusammenarbeit (GIZ) GmbH, atas nama Kementerian Federal Jerman untuk Kerja sama Ekonomi dan Pembangunan, Juni, 71.

Haq, Muhamad Amirul, Muhammad Rivai, dan Tasripan Tasripan. (2019). Rancang Bangun Sistem Pengisian Baterai Nirkabel Menggunakan Mikrokontroler Teensy. Jurnal Teknik ITS, 7(2), 368–73. https://doi.org/10.12962/j23373539.v7i2.31323.

Leksono, Edi, Irsyad Nashirul Haq, Muhammad Iqbal, F X Nugroho Soelami, dan I G N Merthayasa. (2013). State of Charge (SoC) Estimation on LiFePO4 Battery Module Using Coulomb Counting Methods with Modified Peukert. Dalam 2013 Joint International Conference on Rural Information & Communication Technology and Electric-Vehicle Technology (RICT & ICeV-T), 3. Bandung, Indonesia: IEEE. https://doi.org/10.1109/rICT-ICeVT.2013.6741545.

Limuria, Stevanny. (2020). Kolaborasi Menuju Transisi Energi Berkelanjutan. disunting oleh Heri Susanto, 6. APLSI.

M, Umesh, Krishnashree Achuthan, Saneesh P. Francis, dan Balakrishnan Shankar. (2018). Battery Capacity Computation Using Peukert’s Equation in a Virtual Environment. Dalam 2018 IEEE 18th International Conference on Advanced Learning Technologies (ICALT), (pp. 403–4). Mumbai: IEEE. https://doi.org/10.1109/ICALT.2018.00117.

Ningrum, Puspita, dan Novie Ayub Windarko. (2019). Aplikasi Battery Management System (BMS) dengan State of Charge (SOC) Menggunakan Metode Modified Coulomb Counting, 1(1).

Rahmawan, Zainul. (2018). Estimasi State Of Charge (SOC)Pada Baterai Lead-Acid Menggunakan Metode Coulomb Counting Pada PV HYBRID. 17, Institut Teknologi Sepuluh Nopember Surabaya.

Rizaldi, Sony, Slamet Suhartono, Syofyan Hadi, dan Tomy Michael. (2022). Role of Head of States at G20 High Level Conference in Utilizing Environmental of Sustainable Development on Electricity in Indonesia. Technium Social Sciences Journal, 38, 197– 203. https://doi.org/10.47577/tssj.v38i1.7850.

Sianipar, Rafael. (2017). Dasar Perancangan Pembangkit Listrik Tenaga Surya. https://ejournal.trisakti.ac.id/index.php/jetri/article/view/1445.

Wang, Liye, Lifang Wang, dan Yong Li. (2013). A Novel State-of-Charge Estimation Algorithm of EV Battery Based on Bilinear Interpolation.†Dalam 2013 IEEE Vehicle Power and Propulsion Conference (VPPC), 26. Beijing, China: IEEE. https://doi.org/10.1109/VPPC.2013.6671658.

Won, Il-Kuen, Do-Yun Kim, Jun-Ha Hwang, Jung-Hyo Lee, dan Chung-Yuen Won. (2015). Lifetime Management Method of Lithium-Ion Battery for Energy Storage System. Dalam 2015 18th International Conference on Electrical Machines and Systems (ICEMS), (pp. 1173). Pattaya, Thailand: IEEE. https://doi.org/10.1109/ICEMS.2015.7385253.

Yahya, Najmuddin. (2020). Pemantau Tegangan Baterai Ion Litium dalam Rangkaian Empat Seri pada Aplikasi Penyimpan Energi Berdaya Tinggi.

Ye, Min, Xun Song, Rui Xiong, dan Fengchun Sun. (2019). A Novel Dynamic Performance Analysis and Evaluation Model of Series-Parallel Connected Battery Pack for Electric Vehicles. IEEE Access, 7, 14256–65. https://doi.org/10.1109/ACCESS.2019.2892394.