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http://dx.doi.org/10.5762/KAIS.2015.16.5.3391

Development of Hybrid BMS(Battery Management System) Algorithm for Lead-acid and Lithium-ion battery  

Oh, Seung-Taek (Electrical Electronics & Communication Engineering, Korea University of Technology and Education)
Kim, Byung-Ki (Electrical Electronics & Communication Engineering, Korea University of Technology and Education)
Park, Jae-Beom (Electrical Electronics & Communication Engineering, Korea University of Technology and Education)
Rho, Dae-Seok (Electrical Electronics & Communication Engineering, Korea University of Technology and Education)
Publication Information
Journal of the Korea Academia-Industrial cooperation Society / v.16, no.5, 2015 , pp. 3391-3398 More about this Journal
Abstract
Recently, the large scaled lead-acid battery is widely introduced to efficient operation of the photovoltaic system in many islands. but the demand of lithium-ion battery is getting increased by the operation of wind power and replacement of the lead-acid battery. And also, under the renewable portfolio standard(RPS) and energy efficiency resource standard(EERS) policy of Korea government, the introduction of energy storage system(ESS) has been actively increased. Therefore, this paper presents the operation algorithm of hybrid battery management system(BMS) using the lead-acid and lithium-ion batteries, in order to maximize advantage of each battery. In other words, this paper proposed the algorithm of state of charge(SOC) and hybrid operation algorithm to calculate the optimal composition rate considering the fixed cost and operation cost of each battery. From the simulation results, it is confirmed that the proposed algorithms are an effective tool to evaluate SOC and to optimally operate hybrid ESS.
Keywords
Lead-acid battery; Lithium-ion battery; Energy storage system; Hybrid battery management system; State of charge; Operation algorithm;
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  • Reference
1 Jaebum Park and Daeseok Rho, "A Study on the BMS Design of Lithium-ion Battery for Energy Storage System", Journal of KAIS, Vol 14, No 2, pp. 157-159, May, 2013.
2 IEEE $308^{TM}$ -1991, IEEE Standard Criteria for Class 1E Power Systems for Nuclear Power Generating Stations
3 IEEE $323^{TM}$-1983, IEEE Standard for Qualifying Class 1E Equipment for Nuclear Power Generating Stations
4 IEEE $494^{TM}$-1974, IEEE Standard Method for Identification of Documents Related to Class 1E Equipment and Systems for Nuclear Power Generating Stations
5 IEEE $535^{TM}$-1986, IEEE Standard for Qualification of Class 1E Lead Storage Batteries for Nuclear Power Generating Stations
6 Giuk Jang and Gyobeom Jung, "Comparison of Battery Modeling and SOC Estimation Methods", Journal of KIPE, pp. 87-88, July, 2010.
7 Jaebum Park and Daeseok Rho, "A Study on the Technical Guideline for Secondary Battery in Nuclear Power Plant", Journal of KAIS, Vol 15, No 1, pp. 45-47, May, 2014.
8 Seungtaek Oh and Daeseok Rho, "A Study on Analysis of Power Supply System in Nuclear Power Plant", Journal of KAIS, Vol 15, No 1, pp. 48-50, May, 2014.
9 M. Broussely and G. Pistoia, "Industrial applications of batteries", Amsterdam, 2007.
10 Jongyoon Jeong and Daeseok Rho, "A Study on the Optimal Design of Hybrid-typed Electrical Energy Storage System(EESS)", Journal of KAIS, Vol 15, No 1, pp. 587-589, May, 2014.
11 Daeseok Rho, "A Study on Load leveling effect of the distribution system using the Battery Energy Storage Systems", Journal of KIEE, pp. 111-113, October, 2012.
12 "SMART GRID ESS(Electric Energy Storage System)", KSGA, September, 2012.
13 Jukwang Lee and Daeseok Rho, "A Study on the Current Status of Standardization in Electrical Energy Storage System", Journal of KAIS, Vol 14, No 2, pp. 557-559, May, 2013.