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引用次数: 0
摘要
无储能光伏(PV)逆变器的有功功率控制可以平抑波动功率,支持电网的电压幅值和频率。在电网形成电压控制模式下运行时,由于光伏功率变化快且范围广,光伏逆变器需要快速、精确地跟踪功率指令。传统的方法是通过估计光伏功率曲线或基于 PI 的多回路反馈控制来实现这一目标,但其灵活性、可用性和准确性都不尽如人意。因此,我们提出了一种基于 CC/VC 的功率跟踪 (CVPT) 方法,该方法仅使用单回路控制。该方法无需调整多个回路,响应速度更快,这对电网形成电压控制非常重要。此外,还分析了光伏最大功率限制导致的不同运行模式,并提出了一种模式切换方法。仿真和实验结果表明,光伏逆变器可以应对来自电源侧和电网侧的电力干扰,并保持电网电压质量。
A CC/VC-based power tracking method for photovoltaic inverter operated in voltage control mode
The active power control of photovoltaic (PV) inverters without energy storage can flatten the fluctuating power and support the voltage amplitude and frequency of the grid. When operated in grid-forming voltage-control mode, because the PV power can change rapidly and widely, the PV inverter needs to track the power commands quickly and precisely. Traditionally, this goal is achieved with the estimation of PV power curve or PI-based multiple-loop feedback control, where flexibility, availability and accuracy are not satisfactory. Therefore, a CC/VC-based power tracking (CVPT) method is proposed, which only uses single-loop in control. The proposed method does not need to tune multiple loops and can respond faster, which is important for grid-forming voltage control. Furthermore, the different operating modes due to the limitation of PV maximum power are analysed, and a mode switch method is proposed. Simulation and experimental results demonstrate that the PV inverter can cope with power disturbances from both the power and grid sides and maintain the quality of grid voltage.
期刊介绍:
IET Power Electronics aims to attract original research papers, short communications, review articles and power electronics related educational studies. The scope covers applications and technologies in the field of power electronics with special focus on cost-effective, efficient, power dense, environmental friendly and robust solutions, which includes:
Applications:
Electric drives/generators, renewable energy, industrial and consumable applications (including lighting, welding, heating, sub-sea applications, drilling and others), medical and military apparatus, utility applications, transport and space application, energy harvesting, telecommunications, energy storage management systems, home appliances.
Technologies:
Circuits: all type of converter topologies for low and high power applications including but not limited to: inverter, rectifier, dc/dc converter, power supplies, UPS, ac/ac converter, resonant converter, high frequency converter, hybrid converter, multilevel converter, power factor correction circuits and other advanced topologies.
Components and Materials: switching devices and their control, inductors, sensors, transformers, capacitors, resistors, thermal management, filters, fuses and protection elements and other novel low-cost efficient components/materials.
Control: techniques for controlling, analysing, modelling and/or simulation of power electronics circuits and complete power electronics systems.
Design/Manufacturing/Testing: new multi-domain modelling, assembling and packaging technologies, advanced testing techniques.
Environmental Impact: Electromagnetic Interference (EMI) reduction techniques, Electromagnetic Compatibility (EMC), limiting acoustic noise and vibration, recycling techniques, use of non-rare material.
Education: teaching methods, programme and course design, use of technology in power electronics teaching, virtual laboratory and e-learning and fields within the scope of interest.
Special Issues. Current Call for papers:
Harmonic Mitigation Techniques and Grid Robustness in Power Electronic-Based Power Systems - https://digital-library.theiet.org/files/IET_PEL_CFP_HMTGRPEPS.pdf
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