System Power Quality Analysis under Wind–Hydro Complementary Generation Mode
The highly random and characteristics of wind power generation challenge the power quality of the wind–hydro complementary generation system (WHCGS). Herein, the transient characteristics of power quality under the complementary generating mode are studied. First, a nonlinear hydropower system (HPS)...
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Veröffentlicht in: | Energy technology (Weinheim, Germany) Germany), 2024-05, Vol.12 (5), p.n/a |
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Format: | Artikel |
Sprache: | eng |
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Zusammenfassung: | The highly random and characteristics of wind power generation challenge the power quality of the wind–hydro complementary generation system (WHCGS). Herein, the transient characteristics of power quality under the complementary generating mode are studied. First, a nonlinear hydropower system (HPS) model is innovatively established considering the dynamic characteristics of hydrounits under part load operation, and then a wind power system model including wind speed model, wind turbine and its controller, generator and converter is established. Finally, the applicability of WHCGS model in power quality evaluation is established and verified by IEEE‐9 node model. Combined with active power, frequency, and voltage power quality indicators, the effects of wind–hydro capacity ratio and voltage sag on the system are quantified. The results show that the increase in wind power penetration will deteriorate the power quality of WHCGS. Moreover, when the wind power capacity reaches 60 MW, it will damage the voltage and frequency stability of HPS. Besides, the larger the voltage sag amplitude, the worse the power quality of WHCGS. The longer the voltage sag lasts, the higher the risk of WHCGS instability. This article provides a technical reference for the safe and stable operation of WHCGS.
The increase in wind power penetration will deteriorate the power quality of the wind‐hydro complementary generation system. Besides, the larger the voltage sag amplitude and the longer the voltage sag lasts, the higher the risk of wind‐hydro complementary generation system instability. |
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ISSN: | 2194-4288 2194-4296 |
DOI: | 10.1002/ente.202301170 |