风力发电
光伏系统
最大功率点跟踪
可再生能源
汽车工程
独立电源系统
混合动力
电力系统
发电
电
环境科学
分布式发电
计算机科学
电气工程
功率(物理)
工程类
电压
逆变器
物理
量子力学
作者
A. Rama Krishna,A. Vijay Kumar,A. Gopala Krushna,J. Shanmugapriyan,C. Keertana
标识
DOI:10.1051/e3sconf/202454703009
摘要
The Hybrid power system integrates a PV station and wind park via an AC-bus to optimize overall attainment. Employing Maximum power point Tracking (MPPT) technology, both in PV systems and wind farms, ensures efficient operation of the hybrid system amid changing environmental conditions. Simulation using Simulink software allows for thorough assessment of the MPPT technology and control strategies in various environmental scenarios, encompassing solar effulgence and wind speed variations. The conceal after effect underscore the persuasiveness of the MPPT knack in maximizing power extirpation from hybrid power systems across diverse environmental conditions. Attaining unity power factor, the hybrid system synchronously injects current into the grid, maintaining phase alignment with the voltage. This control approach ensures grid voltage stability irrespective of external factors or injected electricity from the hybrid system. The solar and wind power system demonstrates commendable performance, leveraging renewable energy sources to produce electricity. While solar panels harness sunlight for electricity generation and wind turbines utilizes wind power, their environmental advantages include miniaturized carbon emissions and receded credence on fossil fuels. Nonetheless, remonstrance arise due to the intermittent nature of these energy sources, heavily reliant on weather conditions. To mitigate such challenges, advanced technologies like energy storage systems play a pivotal role. Continuous monitoring of system efficiency, coupled with advancements in weather forecasting and technical enhancements, is imperative for bolstering reliability and augmenting the contributions of PV and wind power to maintainable energy systems.
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