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24 V锂电池充电器系统设计 被引量:1

Design of a 24 V Lithium Battery Charger System
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摘要 本文设计了一款工业设备用24 V锂电池充电器系统。系统以STM32F03为主控芯片,采用Buck电路拓扑和半桥驱动芯片IR2104,驱动电路中开关管的导通。同时配有保护电路模块、采样调理电路模块、辅助电源模块等。软件程序采用逐波控制框架,将逐次积分控制与PI控制结合,优化了充电的启动过程。此外,利用电压滞回区间作为判据,实现恒流充电模式与恒压充电模式的切换,平稳了充电电流。最后通过分析锂电池充电器系统的损耗,为进一步提高系统的效率打下基础。 A 24 V lithium battery charger system is designed in this paper.STM32F03 as the main control chip,the system adopts Buck circuit topology,and half-bridge driver IR2104 is used to drive the on-off of switch in Buck circuit.At the same time,it is equipped with protection circuit module,sampling and conditioning circuit module,auxiliary power supply module,etc.The software program uses a wave-by-wave control framework,which combines successive integral control with PI control to optimize the start-up process of charging.In addition,the switching between constant current charging mode and constant voltage charging mode is judged by the voltage hysteresis interval,which stabilizes the charging current.Finally,the efficiency of the system is further improved by analyzing the loss of the system.
作者 王玕 王智东 张紫凡 陈志峰 WANG Gan;WANG Zhi-dong;ZHANG Zi-fan;CHEN Zhi-feng(School of Electrical Engineering,Guangzhou College of South China University of Technology,Guangzhou 510800;College of Electric Power,South China University of Technology,Guangzhou 510640)
机构地区 华南理工大学广州学院电气工程学院 华南理工大学电力学院
出处 《环境技术》 2020年第1期103-107,131,共6页 Environmental Technology
关键词 锂电池充电器 Buck电路拓扑 保护电路 逐波控制 PI控制 lithium-ion batteries charger Buck circuit topology protection circuit wave-by-wave control PI control
分类号 TM912.9 [电气工程—电力电子与电力传动]
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  • 1SALAS V, OLIAS E, BARRADO A, et al. Review of the maximum power point tracking algorithms for stand-alone photovoltaic systems[J]. Solar Energy Materials & Solar Cells, 2006 ( 90 ) : 1555-1578.
  • 2HUA C, LIN J. An on-line MPPT algorithm for rapidly changing illuminations of solar arrays[J]. Renewable Energy, 2003(28): 1129-1142.
  • 3Cheng P T, Bhattacharya S, Divan D. Line harmonics reduction in high power systems using square-wave inverters[C]. Proc. IEEE PESC'96,Baveno, Italy. 1996.
  • 4Cheng P T, Bhattacharya S. Control of square-wave inverters in high power hybrid active filter systems[J]. IEEE Trans. on Ind. Applicat.,1998, 34(1): 458-472.
  • 5Cheng P T, Bhattacharya S. Experimental verification of dominant harmonic active filter (D H A F) for high power applications[C]. Conf.Rec. IEEE-IAS Annu. Meeting, 1998.
  • 6Buso S, Malesani L, Mattavelli P, et al. Design and fully digital control of parallel active filters for thryristor rectifiers to comply with IEC 1000-3-2[J]. IEEE Trans. on Ind. Applicat., 1998, 34(2): 508-517.
  • 7Buso S, Malesani L, Mattavelli P. Comparison of current control techniques for active filter applications[J]. IEEE Trans. on Ind.Electron., 1998, 45(3): 722-729.
  • 8Schauder A D, Moran S A. Multiple reference frame controller for active power filters and power line conditioners[P]. United States Patent: 5309353, May 1994.
  • 9Bojyup M, Karlsson P, Alakula M, et al. A multiple rotating integrator controller for active filters[C]. Proceedings of the EPE Conference,1999, Lausanne, CD-Rom.
  • 10Blasko V. Adaptive filtering for selective elimination of higher harmonics from line currents of a voltage source converter[C]. Proceedings of the IEEE IAS Annual Meeting, St. Louis,Missouri, 1998.

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