Affiliation:
1. Department of Electrical and Computer Engineering, University of Michigan-Dearborn, Dearborn, MI 48128, USA
2. Department of Electrical Engineering, Indian Institute of Technology Jodhpur, Jodhpur 342030, India
Abstract
Second-order ripples occur in the voltage and current during any DC–AC power conversion. These conversions occur in the voltage source inverters (VSIs), current source inverters (CSIs), and various single-stage inverters (SSIs) topologies. The second-order ripples lead to oscillating source node currents and DC bus voltages when there is an interconnection between the AC and DC microgrids or when an AC load is connected to the DC bus of the microgrid. Second-order ripples have various detrimental effects on the sources and the battery storage. In the storage battery, they lead to the depletion of electrodes. They also lead to stress in the converter or inverter components. This may lead to the failure of a component and hence affect the reliability of the system. Furthermore, the second-order ripple currents (SRCs) lead to ripple torque in wind turbines and lead to mechanical stress. SRCs cause a rise in the temperature of photovoltaic panels. An increase in the temperature of PV panels leads to a reduction in the power generated. Furthermore, the second-order voltage and current oscillations lead to a varying maximum power point in PV panels. Hence, the maximum power may not be extracted from it. To mitigate SRCs, oversizing of the components is needed. To improve the lifespan of the sources, storage, and converter components, the SRCs must be mitigated or kept within the desired limits. In the literature, different methodologies have been proposed to mitigate and regulate these second-order ripple components. This manuscript presents a comprehensive review of different effects of second-order ripples on different sources and the methodologies adopted to mitigate the ripples. Different active power decoupling methodologies, virtual impedance-based methodologies, pulse width modulation-based signal injection methodologies, and control methods adopted in distributed power generation methods for DC microgrids have been presented. The application of ripple control methods spans from single converters such as SSIs and VSIs to a network of interconnected converters. Furthermore, different challenges in the field of virtual impedance control and ripple mitigation in distributed power generation environments are discussed. This paper brings a review regarding control methodologies to mitigate and regulate second-order ripples in DC–AC conversions and microgrids.
Subject
Energy (miscellaneous),Energy Engineering and Power Technology,Renewable Energy, Sustainability and the Environment,Electrical and Electronic Engineering,Control and Optimization,Engineering (miscellaneous),Building and Construction
Reference183 articles.
1. Bidirectional three-phase DC–AC converter with embedded DC–DC converter and carrier-based PWM strategy for wide voltage range applications;Wang;IEEE Trans. Ind. Electron.,2018
2. Virtual SVPWM-Based Flexible Power Control for Dual-DC-Port DC–AC Converters in PV–Battery Hybrid Systems;Wang;IEEE Trans. Power Electron.,2021
3. A robust adaptive One Sample Ahead Preview controller for grid-injected currents of a grid-tied power converter with an LCL filter;Milbradt;Int. J. Electr. Power Energy Syst.,2022
4. Hollweg, G.V., de Oliveira Evald, P.D., Tambara, R.V., and Grundling, H.A. (2022). Adaptive super-twisting sliding mode for dc-ac converters in very weak grids. Int. J. Electron.
5. Evald, P.J., Hollweg, G.V., Mattos, E., Borin, L., Tambara, R., and Montagner, V. (2022, January 2–15). A Least-Square-based RMRAC for Grid-tied Voltage Source Inverters with LCL Filter. Proceedings of the 2022 14th Seminar on Power Electronics and Control (SEPOC), Santa Maria, Brazil.
Cited by
7 articles.
订阅此论文施引文献
订阅此论文施引文献,注册后可以免费订阅5篇论文的施引文献,订阅后可以查看论文全部施引文献