About Inverter current and voltage dual closed loop
A novel dual closed-loop repetitive control strategy based on grid current feedback is proposed. A reference current feedforward link and grid-voltage feedforward link are designed to enhance the system dynamic response.
At SolarMax Energy Solutions, we specialize in comprehensive solar energy storage systems including photovoltaic containers, portable solar systems, solar power generation solutions, and solar storage exports. Our innovative products are designed to meet the evolving demands of the global photovoltaic industry and solar energy storage market.
About Inverter current and voltage dual closed loop video introduction
Our solar energy storage solutions support a diverse range of photovoltaic projects and solar industry applications. We provide advanced solar battery technology that delivers reliable power for various operations, remote industrial sites, emergency backup systems, grid support services, and temporary power requirements. Our systems are engineered for optimal performance in various environmental conditions.
When you partner with SolarMax Energy Solutions, you gain access to our extensive portfolio of solar industry products including complete solar energy storage systems, photovoltaic integration solutions, solar containers for rapid deployment, portable solar systems for mobile applications, solar power generation systems, and export-ready solar storage solutions. Our solutions feature high-efficiency lithium iron phosphate (LiFePO4) batteries, smart hybrid inverters, advanced battery management systems, and scalable solar energy solutions from 20kW to 2MWh capacity. Our technical team specializes in designing custom solar energy storage solutions for your specific project requirements.
6 FAQs about [Inverter current and voltage dual closed loop]
Is there a dual closed-loop repetitive control strategy for single-phase grid-connected inverters?
In this paper, a novel dual closed-loop repetitive control strategy based on grid current feedback is proposed for single-phase grid-connected inverters with LCL filters. The proportional-integral inner loop is stabilized by using an inherent one-beat delay achieved by digital controller.
Can Dual-loop control improve steady-state performance of single-phase inverter power supply?
Secondly, using the pole configuration method, the parameters of the double closed-loop PI can be obtained. Finally, the model is built by SIMULINK. The simulation results verify that the dual-loop control can improve and improve the steady-state performance and dynamic performance of single-phase inverter power supply.
How can a single-phase inverter improve performance?
By establishing the mathematical model of the single-phase inverter, the current inner loop control can obtain rapid dynamic performance, and the voltage outer loop control can improve the steady-state performance of the system. Secondly, using the pole configuration method, the parameters of the double closed-loop PI can be obtained.
How can a dual-loop control structure be achieved?
It is achieved by cascading dual-loop with the VSG power loop. Fig. 4 further shows the voltage and current dual-loop control structure. The output voltage 2E obtained from reactive power control can be the reference command of the outer voltage loop, while phase angle obtained from the active power control is used for the dq0 transform.
What is the circuit topology of a single-phase grid-connected inverter?
The main circuit topology is a single-phase grid-connected inverter with LCL filter. The repetitive dual-loop control method is adopted. The outer loop is controlled by the RC, which makes the grid-connected current ig track the sinusoidal reference iref without a steady-state error.
What is a dual loop control method?
The repetitive dual-loop control method is adopted. The outer loop is controlled by the RC, which makes the grid-connected current ig track the sinusoidal reference iref without a steady-state error. The PI control method is applied in the inner loop, which can increase the damping of the system to suppress the resonance peak.