Resumen
Leakage currents reduction and elimination process is important task during the development of photovoltaic (PV) inverters and their associated control and modulation schemes. Compared to existing solutions, doubly grounded (DG) PV inverters represent vital solution for total cancellation of existing common mode voltages and hence their resulting leakage current components. This paper presents a new DG PV inverter topology with boosting capability of PV voltages, outputting seven level output voltage, having continuous current from PV side, and possessing reduced component count and elements. Moreover, a model predictive controller (MPC) is proposed for the proposed topology for controlling multiple objectives without the need for cascaded linear control loops, and with achieving fast tracking and response. The simulation results are provided in this paper with performance comparisons with existing DG PV inverter topologies in literature. The results also prove superior output and control characteristics of the proposed topology with reduced control complexity and reduced component counts.
Idioma original | Inglés |
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Título de la publicación alojada | COBEP 2023 - 17th Brazilian Power Electronics Conference and SPEC 2023 - 8th IEEE Southern Power Electronics Conference, Proceedings |
Editorial | Institute of Electrical and Electronics Engineers Inc. |
ISBN (versión digital) | 9798350321128 |
ISBN (versión impresa) | 9798350321128 |
DOI | |
Estado | Publicada - 2024 |
Evento | 8th Southern Power Electronics Conference and the 17th Brazilian Power Electronics Conference, SPEC / COBEP 2023 - Florianopolis, Brasil Duración: 2023 → 2023 |
Serie de la publicación
Nombre | COBEP 2023 - 17th Brazilian Power Electronics Conference and SPEC 2023 - 8th IEEE Southern Power Electronics Conference, Proceedings |
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Conferencia
Conferencia | 8th Southern Power Electronics Conference and the 17th Brazilian Power Electronics Conference, SPEC / COBEP 2023 |
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País/Territorio | Brasil |
Ciudad | Florianopolis |
Período | 26/11/23 → 29/11/23 |
Nota bibliográfica
Publisher Copyright:© 2023 IEEE.
Áreas temáticas de ASJC Scopus
- Ingeniería energética y tecnologías de la energía
- Ingeniería eléctrica y electrónica
- Ingeniería mecánica
- Control y optimización