EVALUASI KINERJA BATERAI PACK LiFePO4 DALAM MENYEDIAKAN ENERGI UNTUK POMPA AIR SHIMIZU PS-135 E

Authors

  • Arnold J. Kastanja Politeknik Negeri Ambon
  • Luwis H. Laisina Politeknik Negeri Ambon
  • Nikodemus Lewier Politeknik Negeri Ambon

Keywords:

Lithium Iron Phosphate (LiFePO4), battery pack design, pump systems, Shimizu PS-135 E

Abstract

Lithium iron phosphate (LiFePO4) dikenal karena stabilitas termal dan siklus hidup yang panjang, Lithium iron phosphate( LiFePO4) is known for its thermal stability and long cycle life, making it ideal for energy storage applications and electric vehicles. This research aims to design and implement a LiFePO4 battery pack for the Shimizu PS-135 E water pump system, replacing conventional energy sources. The research methodology includes a literature review, experimental design, prototyping, and performance testing. The battery pack design uses a 4S- 7P configuration with a capacity of 39.35 Ah and a Daly 4S 60A BMS. The results indicate a charging time of 9.4 hours and a discharging time of 1.3 hours, with a produced water volume of 2,182 liters. This study confirms that the LiFePO4 battery pack can meet the pumps power requirements with high efficiency and provides environmental benefits by reducing greenhouse gas emissions and dependence on fossil fuels.

References

Amrit, Rajendran, Mohamed, Swellam, Müslüm, Cheng, Wensheng, Jang-Yeon, & R. (2020). A state of art review and future viewpoint on advance cooling techniques for Lithium–ion battery system of electric vehicles. Jounal of Energy Storage, Volume 32, Desember 2020, 101771.

Ana, Marta, A., & Carlos. (2023). A review of operational control strategies in water supply systems for energy and cost efficiency. Renewable and SustainableEnergy Reviews, Volume 175, April 2023, 113140.

A., E., M., & R. (2019). Study of energy storage systems and environmental challenges of batteries. Renewable and Sustainable Energy Reviews, Volume 104, April 2019, pages 192-208.

Haifeng, Zhengxia, Qian, & Changqing. (2020). Water-energy nexus and energy efficiency: A systematic analysis of urban water systems. Renewable and Sustainable Energy Reviews, Volume 134, December 2020, 110381

Julian, Peter, & Arno. (2021). Challenges in ecofriendly battery recycling and closed material cycles: a perspective on future lithium battery generations. Journal Metals 2021, 11, 291

Liang, Xiantai, & Xiaosong. (2021). Experimental research and energy consumption analysis on the economic performance of a hybrid-power gas engine heat pump with LiFePO4 battery. Journal Energy Volume 214, 1 January 2021, 118913

M., Md, Azah, & Afida. (2017). Review of energy storage systems for electric vehicle applications: Issues and challenges. Renewable and Sustainable Energy Reviews, Volume 69, March 2017, Pages 771-789

Nurzhan, Aibolat, Marzhana, Indira, Yongguang, Yan, & Zhumabay. (2015). High performance Zn/LiFePO4 aqueous rechargeable battery for large scale applications. Journal Electrochimica Acta, Volume 152, 10 January 2015, Pages 505-511

Oliver, d, Gavin, Peter, Thomas, Anthony, & second-life. (2021). A review on battery market trends, second-life reuse, and recycling. Journals Sustainable Chemistry , Volume 2 , Issue 1

Article in National Science Challenges

Paula, Nicholas, & Benjamin. (2018). Climate change: the cascade effect.

Sujit, Ilenia, Martin, Ruben, Shima, Valentina, Enric, Wen, Sibani, & David. (2023). Lab on a chip for a low-carbon future. This journal is The Royal Society of Chemistry 2023 Lab Chip, 2023, 23, 1358–1375

Tao, Quan, Yuge, Ming, Ziyu, Yuntao, Li, Kang, & Fangde. (2021). A review of technologies and applications on versatile energy storage systems. Renewable and Sustainable Energy Reviews, Volume 148, September 2021, 111263

Tugrul. (2017). A regional technology roadmap to enable the adoption of CO2 heat pump water heater: A case from the Pacific Northwest, USA.

Energy Strategy Reviews, Volume 18, December 2017, Pages 157-174

Yanxue, Fu, & Weijun. (2024). Energy efficiency measures towards decarbonizing Japanese residential sector: Techniques, application evidence and future perspectives. Energy and Buildings, Volume 319, 15 September 2024, 114514

Yi-Li, Peng-Fei, & Meng-Chang. (2018). Energy storage system: Current studies on batteries and power condition system. Renewable and Sustainable Energy Reviews, Volume 82, Part 3, February 2018, Pages 3091-3106

Article in Electrochemical Energy Reviews

Zachary, Aiping, Jun, & Zhongwei. (2019). Automotive Li-ion batteries: current status and future perspectives.

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Published

2024-10-15

How to Cite

Arnold J. Kastanja, Luwis H. Laisina, & Nikodemus Lewier. (2024). EVALUASI KINERJA BATERAI PACK LiFePO4 DALAM MENYEDIAKAN ENERGI UNTUK POMPA AIR SHIMIZU PS-135 E. Prosiding Seminar Nasional Terapan Riset Inovatif (SENTRINOV), 10(1), 424 - 431. Retrieved from https://proceeding.isas.or.id/index.php/sentrinov/article/view/1617