Abstract:This paper is concerned with modeling and simulation of a wind energy system with different topologies for the power converters, namely a matrix converter and a multilevel converter. We use pulse modulation by space vector modulation associated with sliding mode for controlling the converters, and we introduce power factor control at the output of the converters. Finally, we present the electric behavior for the power and the current at the output of the converters.Index Terms--Modeling and simulation, power c… Show more
“…An integrated model of the wind turbine system was developed with a variable speed turbine, two-mass drive train model, PMSG and two power converters. Matrix converter can convert the variable AC from the generator to constant AC for the grid and uses nine bidirectional IGBT switches [110]. A three-phase active network was used for modeling the network and state space equations were written for the network and the respective converter [110].…”
Section: ) Fractional-order Control Of Variable-speed Wind Turbinementioning
confidence: 99%
“…Matrix converter can convert the variable AC from the generator to constant AC for the grid and uses nine bidirectional IGBT switches [110]. A three-phase active network was used for modeling the network and state space equations were written for the network and the respective converter [110]. A fractional PI µ controller is used which is controlled using space vector PWM associated with sliding mode.…”
Section: ) Fractional-order Control Of Variable-speed Wind Turbinementioning
The power electronics industry is undergoing a revolution driven by an industry 4.0 perspective, with smart and green/hybrid energy management systems being the requirement of the future. There is a need to highlight the potential of fractional order control in power electronics for the highly efficient systems of tomorrow. This paper reviews the developments in fractional order control in power electronics ranging from stand-alone power converters, industrial drives and electric vehicles to renewable energy systems and management in smart grids and microgrids. Various controllers used in power electronics such as the fractional order PI/PID (FOPI/FOPID) and fractional-order sliding mode controllers have been discussed in detail. This review indicates that the plug-and-play type of intelligent fractional order systems needs to be developed for our sustainable future. The review also points out that there is tremendous scope for the design of modular fractional-order intelligent controllers. Such controllers can be embedded into power converters, resulting in smart power electronic systems that contribute to the faster and greener implementation of industry 4.0 standards. INDEX TERMS Fractional calculus, power electronic converters, fractional order control, industrial drives, electric vehicles, renewable energy applications, smart grids and microgrids, industry 4.0.
“…An integrated model of the wind turbine system was developed with a variable speed turbine, two-mass drive train model, PMSG and two power converters. Matrix converter can convert the variable AC from the generator to constant AC for the grid and uses nine bidirectional IGBT switches [110]. A three-phase active network was used for modeling the network and state space equations were written for the network and the respective converter [110].…”
Section: ) Fractional-order Control Of Variable-speed Wind Turbinementioning
confidence: 99%
“…Matrix converter can convert the variable AC from the generator to constant AC for the grid and uses nine bidirectional IGBT switches [110]. A three-phase active network was used for modeling the network and state space equations were written for the network and the respective converter [110]. A fractional PI µ controller is used which is controlled using space vector PWM associated with sliding mode.…”
Section: ) Fractional-order Control Of Variable-speed Wind Turbinementioning
The power electronics industry is undergoing a revolution driven by an industry 4.0 perspective, with smart and green/hybrid energy management systems being the requirement of the future. There is a need to highlight the potential of fractional order control in power electronics for the highly efficient systems of tomorrow. This paper reviews the developments in fractional order control in power electronics ranging from stand-alone power converters, industrial drives and electric vehicles to renewable energy systems and management in smart grids and microgrids. Various controllers used in power electronics such as the fractional order PI/PID (FOPI/FOPID) and fractional-order sliding mode controllers have been discussed in detail. This review indicates that the plug-and-play type of intelligent fractional order systems needs to be developed for our sustainable future. The review also points out that there is tremendous scope for the design of modular fractional-order intelligent controllers. Such controllers can be embedded into power converters, resulting in smart power electronic systems that contribute to the faster and greener implementation of industry 4.0 standards. INDEX TERMS Fractional calculus, power electronic converters, fractional order control, industrial drives, electric vehicles, renewable energy applications, smart grids and microgrids, industry 4.0.
“…A threephase active symmetrical circuit in series models the electrical grid. The model for the multilevel converter used in this paper was reported by the authors in [13].…”
This paper is on wind energy conversion systems with full-power converter and permanent magnet synchronous generator. Different topologies for the power-electronic converters are considered, namely two-level and multilevel converters. Also, a new fractional-order control strategy is proposed for the variable-speed operation of the wind turbines. Simulation studies are carried out in order to adequately assess the quality of the energy injected into the electrical grid. Conclusions are duly drawn.
This paper presents new integrated model for variable-speed wind energy conversion systems, considering a more accurate dynamic of the wind turbine, rotor, generator, power converter and filter. Pulse width modulation by space vector modulation associated with sliding mode is used for controlling the power converters. Also, power factor control is introduced at the output of the power converters. Comprehensive performance simulation studies are carried out with matrix, two-level and multilevel power converter topologies in order to adequately assert the system performance. Conclusions are duly drawn. (c)
scite is a Brooklyn-based organization that helps researchers better discover and understand research articles through Smart Citations–citations that display the context of the citation and describe whether the article provides supporting or contrasting evidence. scite is used by students and researchers from around the world and is funded in part by the National Science Foundation and the National Institute on Drug Abuse of the National Institutes of Health.