Browse > Article
http://dx.doi.org/10.5370/JEET.2016.11.4.839

Energy Management of a Grid-connected High Power Energy Recovery Battery Testing System  

Zhang, Ke (School of Mechanical, Electronic, and Industrial Engineering, University of Electronic Science and Technology of China)
Long, Bo (School of Mechanical, Electronic, and Industrial Engineering, University of Electronic Science and Technology of China)
Yoo, Cheol-Jung (Department of Software Engineering, Chonbuk National University)
Noh, Hye-Min (Department of Software Engineering, Chonbuk National University)
Chang, Young-Won (Department of Software Engineering, Chonbuk National University)
Publication Information
Journal of Electrical Engineering and Technology / v.11, no.4, 2016 , pp. 839-847 More about this Journal
Abstract
Energy recovery battery testing systems (ERBTS) have been widely used in battery manufactures. All the ERBTS are connected in parallel which forms a special and complicated micro-grid system, which has the shortcomings of low energy recovery efficiency, complex grid-connected control algorithms issues for islanded detection, and complicated power circuit topology issues. To solve those shortcomings, a DC micro-grid system is proposed, the released testing energy has the priority to be reutilized between various testing system within the local grid, Compared to conventional scheme, the proposed system has the merits of a simplified power circuit topology, no needs for synchronous control, and much higher testing efficiency. The testing energy can be cycle-used inside the local micro-grid. The additional energy can be recovered to AC-grid. Numerous experimental comparison results between conventional and proposed scheme are provided to demonstrate the validity and effectiveness of the proposed technique.
Keywords
Energy recovery; Battery testing system; Islanded detection; Micro-grid;
Citations & Related Records
Times Cited By KSCI : 1  (Citation Analysis)
연도 인용수 순위
1 Bo. Long, Chong. K.T. “Parameter Design and Power Flow Control of Energy Recovery Power Accumulator Battery Pack Testing System,” J Electr Eng Technol, vol.8, pp.787-798, 2013.   DOI
2 Long. Bo. Ryu. J. H. Lim. S.T and Chong. K.T. “Design and Control of a Multi-Functional Energy Recovery Power Accumulator Battery Pack Testing System for Electric Vehicles,” Energies, vol.7, pp. 1376-1392, 2014.   DOI
3 Long. Bo, Kil. T. C. “Modeling and Direct Power Control of Energy Recovery Power Battery Testing System under Charging Mode - A New Approach,” Int Rev Electr Eng-I vol. 7, pp.5993-6004, 2012.
4 Loh. P.C. Ding, L.Yi Kang. And C. Blaabjerg. F. “Autonomous Operation of Hybrid Micro-grid With AC and DC Subgrids,” IEEE Transactions on Power Electronics, 28, pp. 2214-2223, 2013.   DOI
5 Long, Bo, Ryu. J.H, Chong. K.T. “Optimal Switching Table-Based Sliding Mode Control of an Energy Recovery Li-Ion Power Accumulator Battery Pack Testing System,” Energies, vol. 6, pp. 5200-5218, 2013.   DOI
6 Yunjie.G, Xin.X, Wuhua L and Xiangning. “H. Mode-Adaptive Decentralized Control for Renewable DC Micro-grid With Enhanced Reliability and Flexibility,” IEEE Transactions on Power Electronics, vol. 29, pp. 5072-5080, 2014.   DOI
7 Eghtedarpour. N, Farjah, “E. Power Control and Management in a Hybrid AC/DC Micro-grid,” IEEE Transactions on Smart Grid, vol. 5, pp.1494-1505, 2014.   DOI
8 Hemmati. M, Amjady. N and Ehsan. M. “System modeling and optimization for islanded micro-grid using multi-cross learning-based chaotic differential evolution algorithm,” International Journal of Electric Power and System, vol. 56, pp.349-360, 2014.   DOI
9 Blaabjerg. F. Teodorescu.R,Liserre. M and Timbus, A.V. “Overview of Control and Grid Synchronization for Distributed Power Generation Systems,” IEEE Trans on Industry Electronics, vol. 53, pp.1398-1409, 2006.
10 Rocabert. J, Luna. A, Blaabjerg. F and Rodriguez. P. “Control of Power Converters in AC Micro-grid,”. IEEE Transactions on Power Electronics,vol, 27, pp. 4734-4749, 2012.   DOI
11 Anand.S, Fernandes B.G. “Reduced-Order Model and Stability Analysis of Low-Voltage DC Micro-grid,” IEEE Transactions on Industrial Electronics, vol. 60, pp.5040-5049, 2013.   DOI
12 Guerrero. J.M, Chandorkar, M, Lee, T.L and Loh, P.C. Advanced Control Architectures for Intelligent Micro-grids-Part I: Decentralized and Hierarchical Control. IEEE Transactions on Industry Electronics vol. 60, pp.1254-1262, 2013.   DOI
13 He. J. W, Li. Y. W and Munir, M. S. “A Flexible Harmonic Control Approach through Voltage-Controlled DG-Grid Interfacing Converters,” IEEE Transactions on Industry Electronics, vol. 59, pp. 444-455, 2012.   DOI
14 Kakigano, H , Miura, Y. Ise . T. “Low-Voltage Bipolar-Type DC Micro-grid for Super High Quality Distribution,” IEEE Transactions on Power Electronics, vol. 25, 3066-3075, 2010.   DOI
15 Guerrero, J.M, Loh, P.C, Lee, T.L and Chandorkar, M. “Advanced Control Architectures for Intelligent Micro-grids-Part II: Power Quality, Energy Storage, and AC/DC Micro-grids,” IEEE Transactions on Industry Electronics, vol. 60, pp.1263-1270, 2013.
16 Kim. J, Guerrero. J. M, Rodriguez. P, Teodorescu, R and Na. K. “Mode Adaptive Droop Control with Virtual Output Impedances for an Inverter-Based Flexible AC Micro-grid,” IEEE Transactions on Power Electronics, vol.26, pp.689-701, 2011.   DOI
17 Sanchez. S, Molinas. M, Degano, M and Zanchetta. P. “Stability evaluation of a DC micro-grid and future interconnection to an AC system,” Renewable Energy, vol. 62, pp.649-656, 2014.   DOI
18 Rodriguez, M.; Stahl, G.; Corradini, L.; Maksimovic, D. “Smart DC Power Management System Based on Software-Configurable Power Modules,” IEEE Transactions on Power Electronics, vol. 28, pp. 1571-1586, 2013.   DOI
19 Ito. Y, Zhongqing. Y and Akagi. H. “In DC micro-grid based distribution power generation system,” Power Electronics and Motion Control Conference, 2004. IPEMC 2004. The 4th International, 14-16 Aug. 2004, pp. 1740-1745.
20 Lie. X, Dong. C. “Control and Operation of a DC Micro-grid With Variable Generation and Energy Storage,” IEEE Transactions on Power Delivery, vol. 26, pp.2513-2522, 2011.   DOI