DSVPWM with Open-Leg Switching state for Two-Level Three-Phase Voltage Source Inverters

• Autorzy: Boonsomchuae Kanitphan , Tunyasrirut Satean

Identyfikatory

DOI

10.15199/48.2020.10.04

Warianty tytułu

PL

Nowa metoda modulacji szerokości impulsów w dwupoziomowym, trójfazowym przekształtniku

• Języki publikacji: EN

Abstrakty

EN

A new discontinuous space vector pulse width modulation (DSVPWM) method was proposed by utilizing the open-leg switching state in the space vector method. The proposed method was investigated by MATLAB simulation, and experimental methods. Results were compared with the space vector pulse width modulation (SVPWM) method and the 60o discontinuous space vector (60DSVPWM) method. Total harmonic distortion (THD) value of the proposed method was close to the THD value of SVPWM in the high modulation index. In addition, magnitude of the fundamental output current of the proposed method was higher than for the two existing methods.

PL

Zaproponowano nową metodę modulacji szerokości impulsów w płaszczyźnie wektorowej. Zaproponowana metoda była sprawdzona jako symulacja z wykorzystaniem Matlab oraz eksperymentalnie. Otrzymane wyniki były porównane z innymi dotychczas stosowanymi metodami jak na przykład SVP/WM.

Słowa kluczowe

EN

Discontinuous Space Vector Pulse Width Modulation; Open-leg Switching State; Delay Time; Dead Time

PL

modulacja szerokości impulsów; DSVOWM; SVPWM; przekształtnik

• Wydawca: Wydawnictwo SIGMA-NOT
• Czasopismo: Przegląd Elektrotechniczny
• Rocznik: 2020
• Tom: R. 96, nr 10
• Strony: 25--31
• Opis fizyczny: Bibliogr.13 poz., rys., tab.

Twórcy

autor

Boonsomchuae Kanitphan

• Pathumwan Institute of Technology, Faculty of Engineering, Bangkok, 10330, Thailand

autor

Tunyasrirut Satean

• Pathumwan Institute of Technology, Faculty of Engineering, Bangkok, 10330, Thailand

Bibliografia

• [1] Mokhtar B., Mohamed B. and Abdelmadjid G., Design and Implementation of Three-phase IPM Inverter based on SVPWM for AC Motor Applications using dsPIC30f4011, PRZEGLAD ELEKTROTECHNICZNY, ISSN 0033-2097, R.95 NR 7/2019.
• [2] Ahmet M. H., Russel J. K. and Thomas A. L., A Highperformance Generalized Discontinuous PWM Algorithm, IEEE Trans. Industry Applications, (1998), Vol.34, No.5, Sep./Oct., 1059-1079.
• [3] Vladimar B., Analysis of a Hybrid PWM based on Modified Space-vector and Triangle-comparison Methods, IEEE Trans. Industry Applications, (1997), Vol.33, No.3, May/Jun., 756-764.
• [4] Andrzej M. T. and Stanislaw L., Minimum-Loss Vector PWM Strategy for Three-Phase Inverters, IEEE Trans. Power Electronics, (1994), Vol.9, No.1, Jan., 26-34.
• [5] Shao-Liang A., Xiang-Dong S., Qi Z. Y. Z. and Bi-Ying R., Study on The Novel Generalized Discontinuous SVPWM Strategies for Three-Phase Voltage Source Inverters, IEEE Trans. Industrial Informatics, (2013), Vol. 9, No. 2, May, 781-78.
• [6] Mohamed H. S., M. Z. Mostafa, T. M. Abdel-Moneim and H. A. Yousef, New 13-space Vector Diagram for The Three-phase Six-switches Voltage Source Inverter, (2012), in Proceeding of IEEE IES ISIE2012 Conference, May.
• [7] Kai C., Shi-Ming J. and Li Z., Two-level Three-phase Voltage Source Inverter Fed Low-power AC Induction Motor based on Unipolar Pulse-width Modulation Method, IET Power Electronics, (2016), Vol.9, Iss. 3, Mar., 435-440.
• [8] Ahmet M. H., Seung-Ki S., Russel J. K. and Thomas A. L., Dynamic Overmodulation Characteristics of Triangle Intersection PWM Method, IEEE Trans. Industry Applications, (1999), Vol.35, No.4, Jul./Aug., 896-907.
• [9] G. Narayanan and V. T. Ranganathan, Two Novel Synchronized Bus-clamping PWM Strategies based on Space Vector Approach for High Power Drives, IEEE Trans. Power Electronics, (2002), Vol.17, No.1,Jan., 84-93.
• [10] Atif I., Adoum L., Imtiaz A. and Mohibullah, MATLAB/SIMULINK Model of Space Vector PWM for Three-phase Voltage Source Inverter, (2006), in Proceeding of UPEC2006 Conference, September.
• [11] Yoshihiro M., Tomofumi W. and Harumitu I., Waveform Distortion and Correction Circuit for PWM Inverters with Switching Lag-time, IEEE Trans. Industry Applications, (1987), Vol.IA-23, No.5, Sep./Oct., 881-886.
• [12] Seung-Gi J. and Min-Ho P., The Analysis and Compensation of Dead-time Effect in PWM Inverter, IEEE Trans. Industrial Electronics, (1991), Vol.38, No.2, Apr., 108-114.
• [13] Ning J., Shunliang W., Tianqi L., Yanbo W. and Zhe C., Harmonic Quantitative Analysis for Dead-Time Effects in SPWM Inverter, IEEE Access, (2019), Vol.7, 43143-43152.

Uwagi

Opracowanie rekordu ze środków MNiSW, umowa Nr 461252 w ramach programu "Społeczna odpowiedzialność nauki" - moduł: Popularyzacja nauki i promocja sportu (2020).