Selective harmonic mitigation-pulse-width modulation technique with variable DC-link voltages in single and three-phase cascaded H-bridge inverters

• Published in: IET power electronics Vol. 7; no. 4; pp. 924 - 932
• Main Authors: Moeini, Amirhossein, Iman-Eini, Hossein, Bakhshizadeh, Mohamadkazem
• Format: Journal Article
• Language: English
• Published: Stevenage The Institution of Engineering and Technology 01.04.2014; The Institution of Engineering & Technology
• Subjects: CHB inverters; CIGRE WG 36‐05 grid codes; degree of freedom; Degrees of freedom; Electric potential; EN 50160 grid codes; Harmonics; harmonics suppression; high‐power electronic converters; Inverters; Mathematical analysis; Modulation; modulation indices; modulation techniques; power quality requirements; power supply quality; PWM invertors; selective harmonic mitigation‐pulse‐width modulation technique; SHM‐PWM technique; single‐phase cascaded H‐bridge inverters; Switching; switching transitions; three‐phase cascaded H‐bridge inverters; triplen harmonics; variable DC‐link voltages; Voltage; CHB inverters; selective harmonic mitigation-pulse-width modulation technique; switching transitions; modulation indices; single-phase cascaded H-bridge inverters; three-phase cascaded H-bridge inverters; modulation techniques; power quality requirements; triplen harmonics; power supply quality; high-power electronic converters; PWM invertors; CIGRE WG 36-05 grid codes; EN 50160 grid codes; degree of freedom; SHM-PWM technique; variable DC-link voltages; harmonics suppression
• ISSN: 1755-4535; 1755-4543; 1755-4543
• DOI: 10.1049/iet-pel.2013.0315

There are different modulation techniques that can be used in medium-voltage and high-power electronic converters, but a few of them provide high efficiency and satisfy power quality requirements. This study presents a modified selective harmonic mitigation pulse-width modulation (SHM-PWM) technique which employs variable DC-link voltages as a degree of freedom in cascaded H-bridge (CHB) inverters. This degree of freedom increases the range of acceptable modulation indices, reduces the number of switching transitions and increases the number of harmonics that can be removed in selective harmonic elimination (SHE) (or SHM) techniques. Hence, in addition to efficiency improvement, a huge number of harmonics can be mitigated in AC side of the converter. Using this approach, triplen harmonics can be restricted to standard limits, in single-phase inverters. In addition, the proposed SHM-PWM approach employs the least number of switching transitions in a fundamental period to limit the specific number of harmonics compared to the alternative SHE or SHM techniques. In this study, the requirements of two well-known grid codes EN 50160 and CIGRE WG 36-05 are well satisfied and the validity of proposed method is verified by several simulations and experiments on a seven-level CHB inverter in single-phase and three-phase operating modes.