A 3-PHASE ACTIVE POWER FILTER OPERATING WITH FIXED SWITCHING FREQUENCY FOR REACTIVE POWER AND CURRENT HARMONIC COMPENSATION

被引：158

作者：

MORAN, LA

DIXON, JW

WALLACE, RR

机构：

[1] Department of Electrical Engineering, University of Concepción, Concepción

[2] Department of Electrical Engineering, Universidad Católica de Chile, Santiago

[3] Department of Electrical Engineering, University of Concepción, Concepción

来源：

IEEE TRANSACTIONS ON INDUSTRIAL ELECTRONICS | 1995年 / 42卷 / 04期

关键词：

Number:; 416; Acronym:; -; Sponsor:; FONDECYT; Sponsor: Fondo Nacional de Desarrollo CientÃfico y TecnolÃ³gico; ICA; Sponsor: International Copper Association;

D O I：

10.1109/41.402480

中图分类号：

TP [自动化技术、计算机技术];

学科分类号：

0812 ;

摘要：

The performance and dynamic characteristics of a three-phase active power filter operating with fixed switching frequency is presented and analyzed in this paper, The proposed scheme employs a PWM voltage-source inverter and has two important characteristics. First, it operates with fixed switching frequency, and second, it can compensate the reactive power and the current harmonic components of nonlinear loads. Reactive power compensation is achieved without sensing and computing the reactive component of the load current, thus simplifying the control system. Current harmonic compensation is done in time domain. The principles of operation of the proposed active power filter along with the design criteria of the power and control circuit components are discussed in detail, Finally, experimental results obtained from a 5-kVA prototype confirm the feasibility and the features of the proposed system.

引用

页码：402 / 408

页数：7

共 11 条

[1]

Grady W.M., Samotyj M.J., Noyola A.H., Survey of active power line conditioning methodologies, Trans. Power Delivery, 5, 3, pp. 1536-1542, (1990)

[2]

Gyugyi L., Strycula E.C., Active ac power filters, Conf. Rec. IEEE Ind. Applicat. Soc. Annu. Meeting, pp. 529-535, (1976)

[3]

Kawahira H., Nakamura T., Nakazawa S., Nomura M., Active power filter, Proc. JIEE IPEC, pp. 981-992, (1983)

[4]

Akagi H., Kanazawa Y., Nabae A., Instantaneous reactive power compensators comprising switching devices without energy storage components, IEEE Trans. Ind. Applicat., IA-20, 3, pp. 625-630, (1984)

[5]

Akagi H., Nabae A., Atoh S., Control strategy of active power filters using multiple voltage-source PWM converters, IEEE Trans. Ind. Applicat., IA-22, 3, pp. 460-465, (1986)

[6]

Malesani L., Rossetto L., Tenti P., Active filters for reactive power and harmonic compensation, Proc. IEEE PESC, pp. 321-330, (1986)

[7]

Wu R., Dewan S., Slemon G., A PWM ac to dc converter with fixed switching frequency, IEEE Trans. Ind. Applicat., 26, 5, pp. 880-885, (1990)

[8]

Kazerani M., Ziogas P.D., Joos G., A novel active current waveshaping technique for solid-state input power factor conditioners, IEEE Trans. Ind. Electron., 38, 1, pp. 72-78, (1991)

[9]

Moran L., Ziogas P.D., Joos G., Analysis and design of a novel three-phase solid-state power factor compensator and harmonic suppressor system, IEEE Trans. Ind. Applicat., 25, 4, pp. 609-619, (1989)

[10]

Moran L., Ziogas P.D., Joos G., Performance analysis of a PWM inverter var compensator, IEEE Trans. Power Electron., 6, 3, pp. 380-391, (1991)

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