分数阶模糊PI控制器采用粒子群算法改进升压变换器的功率因数

IF 2.2 Q1 MATHEMATICS, APPLIED
M. Demirtas, Farhan Ahmad
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引用次数: 0

摘要

在文献中,许多研究者对具有超前、滞后和单位功率因数的交流电压控制器的电源电路进行了研究。工作在高开关频率下的电路称为功率因数校正器(pfc)。单相升压变换器已成为通用电源中功率因数校正(PFC)最流行的拓扑结构。功率因数校正电路为电力系统提供了传统的优点。其好处是减少了功率因数的损失和公用事业费用和电力损失。因此,本文提出了一种升压变换器功率因数校正方案。采用PI、模糊PI和分数阶PI (FOPI)控制器对电路的输入电流进行有源整形,提高了功率因数。采用粒子群优化算法对控制器参数(系数)进行优化。电路采用平均电流模式控制(ACMC)方法。变换器电路由单相桥式整流器、升压变换器、变压器和负载组成。为了设计PI控制器,需要建立被控对象的数学模型。在MATLAB/Simulink工具箱中建立了功率因数校正电路的模型,并设计了滤波器来降低THD值。利用PI、模糊逻辑和FOPI控制器的组合对所提出的模型进行了仿真。该控制方案应用于600瓦PFC升压变换器,得到400伏直流输出电压和0.99功率因数。输入电压为230 VRMS, 50hz。FOPI和PI控制器的结合是根据PI和模糊控制器控制功率因数的最佳方案。
本文章由计算机程序翻译,如有差异,请以英文原文为准。
Fractional fuzzy PI controller using particle swarm optimization to improve power factor by boost converter
The power circuit of AC voltage controller capable of operating at a leading, lagging, and unity power factor is studied by a lot of researchers in the literature. Circuits working with high switching frequency are known as power factor correctors (PFCs). The single-phase boost converter has become the most popular topology for power factor correction (PFC) in general purpose power supplies. Power factor correction circuit provides conventional benefits to electric power systems. The benefits are the reduction of power factor penalty and utility bill and power loss. Therefore, a boost converter power factor correction scheme is presented in this paper. A PI, fuzzy logic PI and fractional order PI (FOPI) controllers are used to fix an active shaping of input current of the circuit and to improve the power factor. The controller parameters (coefficients) are optimized using the Particle Swarm Optimization (PSO) algorithm. Average current mode control (ACMC) method is used in the circuit. The converter circuit consists of a single-phase bridge rectifier, boost converter, transformer and load. A mathematical model of the plant is required to design the PI controller. A model for power factor correction circuit is formed in MATLAB/Simulink toolbox and a filter is designed to reduce THD value. The proposed model is simulated using a combination of PI, fuzzy logic and FOPI controllers. The control scheme is applied to 600 Watt PFC boost converter to get 400 Volt DC output voltage and 0.99 power factor. The input voltage is 230 VRMS with 50 Hz. The combination of FOPI and PI controller has the best solution to control the power factor according to PI and fuzzy controllers.
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来源期刊
CiteScore
3.30
自引率
6.20%
发文量
13
审稿时长
16 weeks
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