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Original Article
Comprehensive Dual Mode Charging Systems for Lead Acid Batteries in Electric Vehicles
Shruti Kumari1
Noorul Islam2
Avinash Kumar3
Shweta Shukla4
Abhay Sharma5
Ayesha khan, Sumit6
1234567Department of Electrical Engineering, Meerut Institute of Engineering & Technology, Meerut, Uttar Pradesh, India.
Published Online: March-April 2025
Pages: 56-61
Cite this article
↗ https://www.doi.org/10.59256/ijire.20250602006
References
[1]. Anderson, P., & Lee, D. (2016). The Role of Charging Systems in the Performance and Lifespan of Lead-Acid Batteries. Journal
of Energy Storage, 13(2), 145-157.
[2]. Arora, P., & Vetter, J. (2006). Sulfation in Lead-Acid Batteries: Causes, Effects, and Mitigation Techniques. Journal of Power
Sources, 156(1), 206-215.
[3]. Linden, D., & Reddy, T. B. (2002). Handbook of Batteries (3rd ed.). McGraw- Hill.
[4]. Mori, T., & Saito, S. (2008). Impact of Overcharging on the Health and Efficiency of Lead-Acid Batteries. Energy & Environmental
Science, 4(3), 311-320.
[5]. Miller, J., & Challenor, J. (2012). Dual- Mode Chargers for Lead-Acid Batteries: A Review of Advances and Applications. Journal
of Battery Technology, 29(4), 299- 310.
[6]. Pletcher, D., & Walsh, F. C. (2009). Industrial Electrochemistry (2nd ed.). Springer.
[7]. Teplyakov, D., &Korobov, M. (2015). Principles of Lead-Acid Battery Operation and Technology. Electrochemical Energy
Storage, 12(1), 45-60.
[8]. Vetter, J., & Jung, R. (2012). The Lead-Acid Battery: State of the Art and Applications. Journal of Power Sources, 195(7), 1-10.
[9]. Yu, H., & Wei, Z. (2015). The Effect of Sulfation on Lead-Acid Batteries and Methods for Reversal. Journal of Power Batteries,
34(6), 291-297.
[10]. Zhao, X., Zhang, Y., & Li, Q. (2013). Environmental Risks of Lead-Acid Batteries: A Review of Recycling and Disposal Methods.
Environmental Science and Technology, 47(18), 10478- 10487.
[11]. Chakraborty, S., & Liu, J. (2017). Optimization of Charging Strategies for Electric Vehicle Batteries: A Comparative Study of
Dual-Mode Chargers. Energy Conversion and Management, 149, 1176- 1186.
[12]. Linden, D., & Reddy, T. B. (2002). Handbook of Batteries (3rd ed.). McGraw- Hill.
[13]. Miller, J., & Challenor, J. (2012). Dual- Mode Chargers for Lead-Acid Batteries: A Review of Advances and Applications.
[14]. Batteries. Journal of Power Sources, 343, 143-152. Mori, T., & Saito, S. (2008). Impact of Overcharging on the Health and
Efficiency of Lead-Acid Batteries. Energy & Environmental Science, 4(3), 311-320.
[15]. Pletcher, D., & Walsh, F. C. (2009). Industrial Electrochemistry (2nd ed.)
of Energy Storage, 13(2), 145-157.
[2]. Arora, P., & Vetter, J. (2006). Sulfation in Lead-Acid Batteries: Causes, Effects, and Mitigation Techniques. Journal of Power
Sources, 156(1), 206-215.
[3]. Linden, D., & Reddy, T. B. (2002). Handbook of Batteries (3rd ed.). McGraw- Hill.
[4]. Mori, T., & Saito, S. (2008). Impact of Overcharging on the Health and Efficiency of Lead-Acid Batteries. Energy & Environmental
Science, 4(3), 311-320.
[5]. Miller, J., & Challenor, J. (2012). Dual- Mode Chargers for Lead-Acid Batteries: A Review of Advances and Applications. Journal
of Battery Technology, 29(4), 299- 310.
[6]. Pletcher, D., & Walsh, F. C. (2009). Industrial Electrochemistry (2nd ed.). Springer.
[7]. Teplyakov, D., &Korobov, M. (2015). Principles of Lead-Acid Battery Operation and Technology. Electrochemical Energy
Storage, 12(1), 45-60.
[8]. Vetter, J., & Jung, R. (2012). The Lead-Acid Battery: State of the Art and Applications. Journal of Power Sources, 195(7), 1-10.
[9]. Yu, H., & Wei, Z. (2015). The Effect of Sulfation on Lead-Acid Batteries and Methods for Reversal. Journal of Power Batteries,
34(6), 291-297.
[10]. Zhao, X., Zhang, Y., & Li, Q. (2013). Environmental Risks of Lead-Acid Batteries: A Review of Recycling and Disposal Methods.
Environmental Science and Technology, 47(18), 10478- 10487.
[11]. Chakraborty, S., & Liu, J. (2017). Optimization of Charging Strategies for Electric Vehicle Batteries: A Comparative Study of
Dual-Mode Chargers. Energy Conversion and Management, 149, 1176- 1186.
[12]. Linden, D., & Reddy, T. B. (2002). Handbook of Batteries (3rd ed.). McGraw- Hill.
[13]. Miller, J., & Challenor, J. (2012). Dual- Mode Chargers for Lead-Acid Batteries: A Review of Advances and Applications.
[14]. Batteries. Journal of Power Sources, 343, 143-152. Mori, T., & Saito, S. (2008). Impact of Overcharging on the Health and
Efficiency of Lead-Acid Batteries. Energy & Environmental Science, 4(3), 311-320.
[15]. Pletcher, D., & Walsh, F. C. (2009). Industrial Electrochemistry (2nd ed.)
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