APFC低压系统的研究与实现

doi:10.16180/j.cnki.issn1007-7820.2022.04.012

Abstract

Abstract:

In view of the harmonic pollution caused by nonlinear rectifier devices in low-voltage application scenarios such as low-voltage micro-grid, lathe lighting, teaching experiment and temporary residence at construction sites, this study investigates the low-voltage APFC system using single-cycle control. The control principle of single-cycle controller UCC28180 is analyzed in detail, and the parameters of main circuit and control circuit are calculated. Based on the analysis of the average current loop and the voltage loop, the loop compensation of the zero-pole in the loop is carried out by combining the nonlinear current loop gain factor M₁ of the low voltage system, the PWM slope compensation slope M₂ of the voltage loop and the nonlinear gain M₃, and the corresponding Bode diagram is given. Finally, the prototype system is established and the system efficiency, power factor, and total harmonic distortion rate of input current are analyzed. The results show that the low-voltage system meets the design requirements.

Key words: low-voltage micro-grid, harmonic pollution, single-cycle control, slope compensation, pole-zero, loop compensation, power factor, total harmonic distortion

CLC Number:

TN702

Fuzhuan WU,Haoyang LI,Sheng PENG,Mengna CHEN. Research and Implementation of APFC Low Voltage System[J].Electronic Science and Technology, 2022, 35(4): 72-77.

Figures/Tables 12

Figure 1.

Figure 2.

Figure 3.

Figure 4.

Figure 5.

Figure 6.

Figure 7.

Figure 8.

Figure 9.

Figure 10.

Figure 11.

Figure 12.

References 17

[1]	易映萍, 陆志杰. 基于UCC28070的交错并联Boost PFC硬件电路设计[J]. 电子科技, 2017, 30(5):87-90.
	Yi Yingping, Lu Zhijie. Design of interleaved Boost PFC Based on UCC28070[J]. Electronic Science and Technology, 2017, 30(5):87-90.
[2]	姚绪梁, 马赫, 王景芳. PWM整流器控制系统实践教学平台的开发[J]. 实验室研究与探索, 2020, 39(4):63-66.
	Yao Xuliang, Ma He, Wang Jingfang. Development of a practical teaching platform for PWM rectifier control system[J]. Research and Exploration in Laboratory, 2020, 39(4):63-66.
[3]	李明辉, 贾文超, 谢世康. 三相电压型PWM整流器的建模方法[J]. 电子科技, 2016, 29(5):121-123.
	Li Minghui, Jia Wenchao, Xie Shikang. Three-phase voltage PWM rectifier's modeling method[J]. Electronic Science and Technology, 2016, 29(5):121-123.
[4]	赵琴, 金爱娟, 纪晨烨, 等. 多相交错并联Boost功率因数校正器的研究[J]. 电子科技, 2016, 29(5):67-70.
	Zhao Qin, Jin Aijuan, Ji Chenye, et al. Research on multiphase interleaving parallel boost power factor corrector[J]. Electronic Science and Technology, 2016, 29(5):67-70.
[5]	冯兴田, 崔晓, 陶媛媛. 三相三线制Vienna整流器系统仿真与实验平台设计[J]. 实验室研究与探索, 2020, 39(3):102-105.
	Feng Xingtian, Cui Xiao, Tao Yuanyuan. Design of simulation and experimental platform for three-phase three-wire vienna rectifier system[J]. Research and Exploration in Laboratory, 2020, 39(3):102-105.
[6]	Purnama I, Chi P C, Hsieh Y C, et al. One cycle controlled grid-tied differential boost inverter[J]. IET Power Electronics, 2016, 9(11):2216-2222. doi: 10.1049/iet-pel.2015.0611
[7]	郑愫, 龚春英, 韦徵, 等. 基于UCC28019控制的单相PFC工作原理及实现[J]. 电源学报, 2014(5):35-39.
	Zheng Su, Gong Chunying, Wei Zheng, et al. Principle and implementation of single-phase PFC circuit based on UCC28019[J]. Journal of Power Supply, 2014(5):35-39.
[8]	唐智, 夏泽中, 黄刚, 等. 单周期控制的双向半桥AC-DC变换器[J]. 电气传动, 2017, 47(10):29-32.
	Tang Zhi, Xia Zezhong, Huang Gang, et al. One cycle controlled bidirectional half-bridge AC-DC converter[J]. Electric Drive, 2017, 47(10):29-32.
[9]	张国荣, 邹阳阳. 改进型单周控制单相SAPF的研究[J]. 电测与仪表, 2018, 55(3):88-94.
	Zhang Guorong, Zou Yangyang. Research of an improved one-cycle controlled single-phase SAPF[J]. Electrical Measurement & Instrumentation, 2018, 55(3):88-94.
[10]	张兴, 秦会斌, 郭石磊. 基于UCC3818A的600W APFC电源设计[J]. 微型机与应用, 2015, 34(6):23-25.
	Zhang Xing, Qin Huibin, Guo Shilei. The design of 600W switching power supply APFC based on UCC3818A[J]. Information Technology and Network Security, 2015, 34(6):23-25.
[11]	张文文, 刘子龙, 孙洪武, 等. 具有APFC功能的AC-DC开关电源设计[J]. 电子测量技术, 2016, 39(5):22-26.
	Zhang Wenwen, Liu Zilong, Sun Hongwu, et al. Design of AC-DC switching power supply with APFC function[J]. Electronic Measurement Technology, 2016, 39(5):22-26.
[12]	张锦吉, 戴荣东, 毛行奎, 等. 基于L6562A的APFC设计[J]. 电源世界, 2010(2):41-43.
	Zhang Jinji, Dai Rongdong, Mao Xingkui, et al. APFC design with L6562A[J]. The World of Power Supply, 2010(2):41-43.
[13]	韩晓钢, 齐铂金. 基于单周期控制的Boost型APFC电路设计及仿真[J]. 电气技术, 2017(1):8-12.
	Han Xiaogang, Qi Bojin. Single-Phase APFC converter of boost topology based on one cycle control[J]. Electrical Engineering, 2017(1):8-12.
[14]	权保同. 具有PFC的电动汽车车载充电机的研究[D]. 淮南:安徽理工大学, 2019.
	Quan Baotong. Research on vehicle charger for electric vehicle with PFC[D]. Huainan:Anhui University of Science and Technology, 2019.
[15]	冯林凯, 宋桂英. 单周期Boost APFC的稳定性分析[J]. 工业控制计算机, 2017, 30(9):149-150.
	Feng Linkai, Song Guiying. Stability analysis of single cycle boost APFC[J]. Industrial Control Computer, 2017, 30(9):149-150.
[16]	高飞翎, 周子旺, 常鹏, 等. 大功率因数整流器单周期控制的稳定性研究[J]. 电气开关, 2020, 58(1):9-12.
	Gao Feiling, Zhou Ziwang, Chang Peng, et al. Study on stability of one cycle controller in high power factor rectifier[J]. Electric Switchgear, 2020, 58(1):9-12.
[17]	李森, 李翠华, 赵文群. 基于UCC28180的有源功率因数校正(APFC)模块设计[J]. 通信电源技术, 2017, 34(4):103-105.
	Li Sen, Li Cuihua, Zhao Wenqun. Design of active power factor correction (APFC) module based on UCC28180[J]. Telecom Power Technology, 2017, 34(4):103-105.

Research and Implementation of APFC Low Voltage System

RichHTML

PDF (PC)

Like

Knowledge

Abstract

Cite this article

share this article

Figures/Tables 12

References 17

Related Articles 14

Metrics

Comments

Recommended 10

[1]	JIANG Kaiwen,JIN Hai,XU Shen. Design and Simulation of High Power Factor PMSM without Electrolytic Capacitor [J]. Electronic Science and Technology, 2021, 34(12): 13-18.
[2]	GAO Shang,YAO Lei,LI Yang,LI Ruixin. Control Parameter Optimization of Cascaded H-Bridge Power Electronic Transformer [J]. Electronic Science and Technology, 2021, 34(11): 75-80.
[3]	NIU Ganggang,LI Wei,LIU Wentao,ZHAI Yahong. Design of LDO Circuit Based on DynamicFrequency Compensation [J]. Electronic Science and Technology, 2019, 32(2): 61-65.
[4]	GAO Fei，DING Xueming，LI Jian. Design and Implementation of A Small Intelligent Mowing Robot [J]. , 2018, 31(4): 68-.
[5]	LI Yang. Design of A Large Load Peak Current Mode DC-DC Converter [J]. , 2016, 29(7): 128-.
[6]	LI Shaolin,DU Qi,JIN Jing. Research on Single-phase APFC with One Cycle Control [J]. , 2015, 28(8): 50-.
[7]	XIA Minghao,YANG Wenhuan,XIA Tianyu,SHI Jun. Research on and Design of a Fly-back PFC Switching Power Supply [J]. , 2015, 28(6): 133-.
[8]	GUAN Jinzhou,LI Jilei. Design of a Squarer Slope Compensation Circuit for Buck DC-DC Converter [J]. , 2015, 28(6): 192-.
[9]	HE Jun. Design of a Self-adaptable Slope Compensation Circuit for Buck DC-DC Converter [J]. , 2015, 28(3): 126-.
[10]	ZHONG Zhilei,LI Qianyong. Specific Harmonic Improvement of a Single-phase Three-level PWM Rectifier [J]. , 2014, 27(9): 165-.
[11]	OU Jian,HUANG Chong,YUAN Zheng,XUE Chaoyao. A Slope Compensation Circuit with Pulse Skipping Modulation [J]. , 2013, 26(8): 113-.
[12]	WANG Shaowei. PWM-Based Reactive Power Compensation System Design [J]. , 2013, 26(6): 66-.
[13]	LI Shaolin,LIU Hong,LI Zhibin. Research on the VIENNA Rectifier with One Cycle Control Technology [J]. , 2013, 26(1): 115-.
[14]	ZHAO Qi, FANG Zu-Hua. Simulation of Three-phase Full-bridge Control Rectifier Circuit and its Power Factor and Harmonic Analysis [J]. , 2011, 24(6): 4-.