DC-DC变换补偿网络PI近似工程设计

doi:10.16180/j.cnki.issn1007-7820.2023.05.003

摘要/Abstract

摘要：

针对DC-DC变换补偿网络设计中试凑法的盲目性和理论分析的复杂性,文中根据状态空间平均法,以Buck为例对DC-DC变换系统进行建模。在满足幅值裕度和相位裕度的情况下,推导出补偿网络k_p、k_i与系统参数占空比D、电感L和电容C之间的关系,并在此基础上提出了一种工程近似的方法。通过PSIM仿真和基于DSP搭建的样机平台对所提方法进行验证,结果表明无论是在电压单闭环的情况下还是在电压外环电流内环的情况下,此工程近似法与理论分析法即传统控制方法得出的结果基本一致。此工程近似法避免了试凑法的盲目性和理论分析的复杂性,为实际工程中快速设计补偿网络提供了一种快捷的方法和思路。

关键词: DC-DC变换, 补偿网络, 试凑法, 工程近似, 状态空间平均法, 幅值裕度, 相位裕度, PSIM仿真

Abstract:

In view of the blindness of the trial-and-error method in the design of DC-DC transform compensation network and the complexity of theoretical analysis, based on the state space average method, this study takes Buck as an example to model the DC-DC transformation system. Under the condition that the amplitude margin and phase margin are satisfied, the relationship between the compensation network k_p, k_i and the system parameter duty ratio D, inductance L and capacitance C is derived, and on this basis, an engineering approximation method is proposed. The proposed method is verified by PSIM simulation and a prototype platform based on DSP. The results show that the results obtained by this engineering approximation method are basically consistent with the theoretical analysis method, that is, the traditional control method, no matter in the case of voltage single closed loop or in the case of voltage outer loop and current inner loop. This engineering approximation method avoids the blindness of trial and error and the complexity of traditional control methods, which is the complexity of traditional control methods, and provides a quick method and idea for the rapid design of compensation networks in actual projects.

Key words: DC-DC conversion, compensation network, trial and error method, engineering approximation, state space averaging method, amplitude margin, phase margin, PSIM simulation

中图分类号:

TN702

巫付专,向乃皇,周元浩,陈蒙娜. DC-DC变换补偿网络PI近似工程设计[J]. 电子科技, 2023, 36(5): 16-22.

WU Fuzhuan,XIANG Naihuang,ZHOU Yuanhao,CHEN Mengna. PI Approximate Engineering Design of DC-DC Conversion Compensation Network[J]. Electronic Science and Technology, 2023, 36(5): 16-22.

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参考文献 19

[1]	张晓超, 李虹, 苏文哲, 等. DC-DC变换器分数阶PI^λ控制与稳定性分析研究[J]. 电工电能新技术, 2019, 38(5):21-31.
	Zhang Xiaochao, Li Hong, Su Wenzhe, et al. Study on fractional-order PI^λ control and stability analysis of DC-DC converter[J]. Advanced Technology of Electrical Engineering and Energy, 2019, 38(5):21-31.
[2]	杨超, 苑红, 余岱玲, 等. 变论域模糊PID控制在改善DC-DC变换器非线性非最小相位系统的性能研究[J]. 电工电能新技术, 2017, 36(1):30-37.
	Yang Chao, Yuan Hong, Yu Dailing, et al. Research on performance of variable universe fuzzy PID control in improving nonlinear non-minimum phase system for DC-DC converter[J]. Advanced Technology of Electrical Engineering and Energy, 2017, 36(1):30-37.
[3]	岳舟. 高电压增益混合型DC-DC变换器研究[J]. 电力系统保护与控制, 2021, 49(21):113-122.
	Yue Zhou. A hybrid DC-DC converter with higher voltage gain[J]. Power System Protection and Control, 2021, 49(21):113-122.
[4]	徐梦然, 陈思哲, 范元亮, 等. 一种新型两开关高增益DC/DC变换器[J]. 电力电子技术, 2021, 55(7):120-122.
	Xu Mengran, Chen Sizhe, Fan Yuanliang, et al. A novel two-switch high step-up DC/DC converter[J]. Power Electronics, 2021, 55(7):120-122.
[5]	杨玉岗, 甘汶桦. DC-DC Boost变换器控制算法的研究[J]. 电工电能新技术, 2015, 34(3):72-75.
	Yang Yugang, Gan Wenhua. Research on control algorithm of DC-DC Boost converters[J]. Advanced Technology of Electrical Engineering and Energy, 2015, 34(3):72-75.
[6]	刘文琪, 丁稳房. 适用于光伏发电系统的新型高增益DC/DC变换器[J]. 电源技术, 2021, 45(10):1330-1332.
	Liu Wenqi, Ding Wenfang. New high voltage gain DC/DC converter suitable for photovoltaic power generation system[J]. Chinese Journal of Power Sources, 2021, 45(10):1330-1332.
[7]	师翔, 张在涌, 赵永瑞, 等. 一种用于DC-DC变换器中的斜坡补偿电路[J]. 半导体技术, 2021, 46(5):349-353.
	Shi Xiang, Zhang Zaiyong, Zhao Yongrui, et al. A slope compensation circuit for DC-DC converter[J]. Semiconductor Integrated Circuits, 2021, 46(5):349-353.
[8]	吴涵涵, 卜刚. 基于开关电容DC-DC转换器的两路主从输出策略[J]. 电子科技, 2020, 33(6):35-39.
	Wu Hanhan, Bu Gang. Dual master-slave output strategy based on switching capacitor DC-DC converter[J]. Electronic Science and Technology, 2020, 33(6):35-39.
[9]	罗艳蕾, 屠松庭, 石立明. 基于液压调平大阻尼系统的模糊PID控制研究[J]. 机床与液压, 2020, 48(15):118-121. doi: 10.3969/j.issn.1001-3881.2020.15.025
	Luo Yanlei, Tu Songting, Shi Liming. Research on fuzzy PID control for large damping system based on hydraulic leveling[J]. Machine Tool & Hydraulics, 2020, 48(15):118-121. doi: 10.3969/j.issn.1001-3881.2020.15.025
[10]	刘洪波, 邸睿. 基于Clark变换的VSC-HVDC系统控制器设计及其PI参数整定[J]. 东北电力大学学报, 2019, 39(1):22-28.
	Liu Hongbo, Di Rui. Design of VSC-HVDC system controller based on clark transform and PI parameter tuning[J]. Journal of Northeast Electric Power University, 2019, 39(1):22-28.
[11]	陈景芳, 单春贤, 蔡健. 基于爬虫算法的无刷直流电机PI参数的整定研究[J]. 通信电源技, 2019, 36(1):28-31.
	Chen Jingfang, Shan Chunxian, Cai Jian. Study on PI parameter tuning of brushless DC motor based on crawler algorithm[J]. Telecom Power Technology, 2019, 36(1):28-31.
[12]	蒋捷, 张兴华. 基于改进差分进化算法的PMSM转速PI参数整定[J]. 电力电子技术, 2020, 54(9):39-43.
	Jiang Jie, Zhang Xinghua. PI paremeters tuning based on differential evolution algorithm for speed loop of PMSM[J]. Power Eletronics, 2020, 54(9):39-43.
[13]	闫君, 王明东, 李忠文. 静止无功补偿器变论域模糊PI控制研究[J]. 电工电能新技术, 2021, 40(9):64-70.
	Yan Jun, Wang Mingdong, Li Zhongwen. Research on variable universe fuzzy PI control of static var compensators[J]. Advanced Technology of Electrical Engineering and Energy, 2021, 40(9):64-70.
[14]	李明, 张兴, 郭梓暄, 等. 弱电网下基于D分割法的逆变器PI参数设计及稳定域分析[J]. 电力系统自动化, 2020, 44(15):139-147.
	Li Ming, Zhang Xing, Guo Zixuan, et al. Proportionnal integral parameter design for inverter based on D-partition method and its stability region analysis in weak grid[J]. Automation of Electric Power Systems, 2020, 44(15):139-147.
[15]	茆美琴, 张中洋, 丁勇, 等. 基于解析计算的CSC-PMSG-WGS控制器PI参数设计[J]. 电工技术学报, 2017, 32(20):205-212.
	Mao Meiqin, Zhang Zhongyang, Ding Yong, et al. Analytical-method-based design of PI parameters of controller used in CSC-PMSG-WGS[J]. Transactions of China Electrotechnical Society, 2017, 32(20):205-212.
[16]	王兆安, 刘进军. 电力电子技术[M]. 5版. 北京: 机械工业出版社, 2009:10-36.
	Wang Zhaoan, Liu Jinjun. Power electronics[M]. 5th ed. Beijing: China Machine Press, 2009:10-36.
[17]	赵慧, 金海. 一种开关磁阻电机模糊PI的直接瞬时转矩控制[J]. 电子科技, 2019, 32(11):58-63.
	Zhao Hui, Jin Hai. Direct instantaneous torque control of switched reluctance motor based on fussy self-tuning PI[J]. Electronic Science and Technology, 2019, 32(11):58-63.
[18]	巫付专, 沈虹. 电能变换与控制[M]. 北京: 电子工业出版社, 2014:52-77.
	Wu Fuzhuan, Shen Hong. Electric energy conversion and control[M]. Beijing: Publishing House of Electronics Industry, 2014:52-77.
[19]	徐德鸿. 电力电子系统建模及控制[M]. 北京: 机械工业出版社, 2005:63-90.
	Xu Dehong. Modeling and control of power electronic system[M]. Beijing: China Machine Press, 2005:63-90.

参数	数值
滤波电感L/mH	3
滤波电容C/μF	100
负载电阻R/Ω	10
输入电压U_in/V	36
输出电压U_out/V	24
占空比D	0.67

PI参数名称	理论分析	工程近似	误差
k_p	0.56	0.67	0.11
k_i	117.23	140.11	22.88

PI参数名称	理论分析	工程近似	误差
k_ip	0.480	0.670	0.190
k_ii	100.480	140.110	39.630
k_vp	1.180	1.000	0.180
k_vi	74.104	62.800	11.304

闭环方式	PI参数名称	PI参数值
单闭环	k_p k_i k_ip	0.670 0 0.004 7 0.670 0
双闭环	k_ii k_vp k_vi	0.004 7 1.000 0 0.001 6