Evaluating the Effects of AC Ripples on the Degradation of Lead Acid Battery

Show simple item record

dc.contributor.author Rahman, Toukir
dc.contributor.author Punny, Mahruba Jannat
dc.contributor.author Tabassum, Rayaa
dc.date.accessioned 2024-01-17T09:41:52Z
dc.date.available 2024-01-17T09:41:52Z
dc.date.issued 2023-05-30
dc.identifier.citation [1] I. Batarseh and K. Alluhaybi, “Emerging opportunities in distributed power electronics and battery integration: Setting the stage for an energy storage revolution,” IEEE Power Electron. Mag., vol. 7, no. 2, pp. 22–32, 2020. [2] P. K. Pathak and A. R. Gupta, “Battery energy storage system,” in 2018 4th International Conference on Computational Intelligence & Communication Technology (CICT), 2018, pp. 1–9. [3] S. Kitaronka, “LEAD-ACİD BATTERY,” Researchgate.net, Jan-2022. [Online]. Available: https://www.researchgate.net/publication/357913548_LEAD ACID_BATTERY. [4] S. Petrovic, Battery Technology Crash Course: A Concise Introduction. Cham: Springer International Publishing, 2021. [5] M. J. Lencwe, S. P. Daniel Chowdhury, and T. O. Olwal, “Performance studies of lead acid batteries for transport vehicles,” in 2017 IEEE PES PowerAfrica, 2017, pp. 528– 532. [6] E. M. Valeriote, T. G. Chang, and D. M. Jochim, “Fast charging of lead-acid batteries,” in Proceedings of 9th Annual Battery Conference on Applications and Advances, 2002, pp. 33–38. [7] D. J. Becker, “Lead-acid battery charge process in photovoltaic applications,” in INTELEC - 1979 International Telecommunications Energy Conference, 1979, pp. 242–247. [8] D. J. Deepti and V. Ramanarayanan, “State of charge of lead acid battery,” in 2006 India International Conference on Power Electronics, 2006, pp. 89–93. [9] H. J. Schaetzle and D. P. Boden, “Lead-acid storage batteries for uninterrupted power supply (UPS) applications,” in INTELEC - 1979 International Telecommunications Energy Conference, 1979, pp. 226–230. 38 [10] S. Khan, M. U. Zaman Chowdhury, M. Rabbi, and A. Khatun, “The million improvised electric rickshaws in Bangladesh: Preliminary survey and analysis,” in 2022 IEEE International IOT, Electronics and Mechatronics Conference (IEMTRONICS), 2022, pp. 1–7. [11] P. Nambisan, S. Bansal, and M. Khanra, “Economic performance of solar assisted battery and supercapacitor based E-rickshaw,” in 2020 IEEE International Conference on Power Electronics, Smart Grid and Renewable Energy (PESGRE2020), 2020, pp. 1– 6. [12] Y. Li, Y. Sun, K.-J. Li, K. Sun, Z. Liu, and Q. Xu, “Harmonic modeling of the series connected multi-pulse rectifiers under unbalanced conditions,” IEEE Trans. Ind. Electron., vol. 70, no. 7, pp. 1–10, 2022. [13] A. Bessman, R. Soares, O. Wallmark, P. Svens, and G. Lindbergh, “Aging effects of AC harmonics on lithium-ion cells,” J. Energy Storage, vol. 21, pp. 741–749, 2019. [14] P. G. Horkos, E. Yammine, and N. Karami, “Review on different charging techniques of lead-acid batteries,” in 2015 Third International Conference on Technological Advances in Electrical, Electronics and Computer Engineering (TAEECE), 2015, pp. 27–32. [15] N. Vitkov, “Environmental and health challenges in battery recycling in Bulgaria,” in 2022 14th Electrical Engineering Faculty Conference (BulEF), 2022, pp. 1–5. [16] S. Bala, T. Tengner, P. Rosenfeld, and F. Delince, “The effect of low frequency current ripple on the performance of a Lithium Iron Phosphate (LFP) battery energy storage system,” in 2012 IEEE Energy Conversion Congress and Exposition (ECCE), 2012, pp. 3485–3492. [17] M. Uno and K. Tanaka, “Influence of high-frequency charge–discharge cycling induced by cell voltage equalizers on the life performance of lithium-ion cells,” IEEE Trans. Veh. Technol., vol. 60, no. 4, pp. 1505–1515, 2011. [18] P. J. Osswald et al., “Current density distribution in cylindrical Li-Ion cells during impedance measurements,” J. Power Sources, vol. 314, pp. 93–101, 2016. 39 [19] K. Uddin, A. D. Moore, A. Barai, and J. Marco, “The effects of high frequency current ripple on electric vehicle battery performance,” Appl. Energy, vol. 178, pp. 142–154, 2016. [20] L. W. Juang, P. J. Kollmeyer, A. E. Anders, T. M. Jahns, R. D. Lorenz, and D. Gao, “Investigation of the influence of superimposed AC current on lithium-ion battery aging using statistical design of experiments,” J. Energy Storage, vol. 11, pp. 93–103, 2017. [21] M. A. Fatullah, A. Rahardjo, and F. Husnayain, “Analysis of discharge rate and ambient temperature effects on lead acid battery capacity,” in 2019 IEEE International Conference on Innovative Research and Development (ICIRD), 2019, pp. 1–5. [22] H. A. Serhan and E. M. Ahmed, “Effect of the different charging techniques on battery life-time: Review,” in 2018 International Conference on Innovative Trends in Computer Engineering (ITCE), 2018, pp. 421–426. [23] I. Lahbib, A. Lahyani, A. Sari, and P. Venet, “Performance analysis of a lead-acid battery/supercapacitors hybrid and a battery stand-alone under pulsed loads,” in 2014 First International Conference on Green Energy ICGE 2014, 2014, pp. 273–278. [24] C. Protogeropoulos and J. Nikoletatos, “Examination of ripple current effects on lead acid battery ageing and technical and economical comparison between ‘solar’ and sli batteries,” Cres.gr. [Online]. Available: http://www.cres.gr/kape/publications/photovol/batt-bar.pdf. [25] S. Okazaki, S. Higuchi, O. Nakamura, and S. Takahashi, “Influence of superimposed alternating current on capacity and cycle life for lead-acid batteries,” J. Appl. Electrochem., vol. 16, no. 6, pp. 894–898, 1986. [26] X. Tan et al., “Real-time state-of-health estimation of lithium-ion batteries based on the equivalent internal resistance,” IEEE Access, vol. 8, pp. 56811–56822, 2020. [27] S. Barcellona, S. Colnago, G. Dotelli, S. Latorrata, and L. Piegari, “Aging effect on the variation of Li-ion battery resistance as function of temperature and state of charge,” J. Energy Storage, vol. 50, no. 104658, p. 104658, 2022. 40 [28] B. O. Agudelo et al., “Experimental analysis of capacity degradation in lithium-ion battery cells with different rest times,” in 2020 2nd IEEE International Conference on Industrial Electronics for Sustainable Energy Systems (IESES), 2020, vol. 1, pp. 44– 49. [29] “BU-902: How to measure internal resistance,” Battery University, 07-Feb-2011. [Online]. Available: https://batteryuniversity.com/article/bu-902-how-to-measure internal-resistance. [30] N. Meddings et al., “Application of electrochemical impedance spectroscopy to commercial Li-ion cells: A review,” J. Power Sources, vol. 480, no. 228742, p. 228742, 2020 en_US
dc.identifier.uri http://hdl.handle.net/123456789/2048
dc.description Supervised by Mr. Fahim Faisal, Assistant Professor, Department of Electrical and Electronics Engineering (EEE) Islamic University of Technology (IUT) Board Bazar, Gazipur-1704, Bangladesh en_US
dc.description.abstract The growing use of battery-powered electric cars and equipment has sparked worries about the possible influence of charging station harmonics on battery deterioration. The lead acid battery is a well-known alternative among the different types of consumer batteries available. Despite having a low energy density, it is nonetheless commonly utilized due to its ease of use and inexpensive cost. Lead acid batteries are widely used in electric rickshaws, uninterruptible power supply (UPS), and home appliances in Bangladesh. Recognizing the rising concern about the impact of AC ripples on battery health, we conducted a thorough experimental analysis in our study to explore the impacts of different frequency harmonics on gel-type lead acid batteries. On lead acid batteries, frequencies of 100Hz, 1kHz, and pure DC have been measured. The experiment is repeated 35 cycles in constant current charging circumstances until a substantial change in battery performance is seen. For a more accurate conclusion, the deterioration is compared to numerous characteristics, such as internal resistance and discharge capacity. The effect of AC harmonics on battery deterioration was shown to be more pronounced at the lower frequency of 100Hz, as internal resistance rose from 71m to 96m and discharge capacity decreased from 3.682Ah to 2.721Ah. Significant increases in both measurements showed faster aging and deterioration in the battery charged at 100 en_US
dc.language.iso en en_US
dc.publisher Department of Electrical and Elecrtonics Engineering(EEE), Islamic University of Technology(IUT), Board Bazar, Gazipur-1704, Bangladesh en_US
dc.title Evaluating the Effects of AC Ripples on the Degradation of Lead Acid Battery en_US
dc.type Thesis en_US


Files in this item

This item appears in the following Collection(s)

Show simple item record

Search IUT Repository


Advanced Search

Browse

My Account

Statistics