Control of Permanent Magnet Synchronous Generator for large wind turbines

Busca, Cristian; Stan, Ana-Irina; Stanciu, Tiberiu; Stroe, Daniel‐Ioan

doi:10.1109/isie.2010.5637628

Cited by 54 publications

(20 citation statements)

References 4 publications

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“…Grid side control is achieved via active and reactive power control [11,12]. Active and reactive power delivered to the grid is controlled by the means of power decoupling in the synchronous rotating reference frame dq, which is given by Eqs.…”

Section: Grid Side Control Loopmentioning

confidence: 99%

DC-Link Control Schemes in Multilevel Converters for WECS

Reusser¹

2018

Vibration Analysis and Control in Mechanical Structures and Wind Energy Conversion Systems

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The introduction of renewable energy resources since the late 1990s as an alternative to fossil energies has impact the development of wind energy and its integration to the grid. From the early 2000s, the wind energy has positioned itself as the most grown-up energy market in the world. This fact has introduced the need to deal with increasing power demands with limited generation capabilities, in terms of generator power density, for low rotation speeds and medium voltage generation within a grid interconnection in high voltage, and other grid code demands, like THD, power factor regulation, and the requirement of continuous operation under faulty condition. Until today, this issue has been solved using classical power converter topologies, using three-level voltage source converters (3LVSC) or multilevel configurations, such as neutral point clamped and cascaded H-Bridge topologies. In this chapter, the main advantages and drawbacks of classical multilevel converter topologies are analyzed, in terms of their DC-link voltage stability capability and different approaches to DC-link control and to new converter topologies, derived from classical topologies, are presented and compared with simulation results.

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Section: Grid Side Control Loopmentioning

confidence: 99%

DC-Link Control Schemes in Multilevel Converters for WECS

Reusser¹

2018

Vibration Analysis and Control in Mechanical Structures and Wind Energy Conversion Systems

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“…Thus, the Field Oriented Control (FOC) strategy is implemented in the synchronous rotating reference frame for easier control [29]. This type of control also puts the PMSG into high performance.…”

Section: Modeling Of Permanent Magnetic Synchronous Generator Systemmentioning

confidence: 99%

A Novel Dynamic Co-Simulation Analysis for Overall Closed Loop Operation Control of a Large Wind Turbine

Wang

Chiang

2016

Energies

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Abstract:A novel dynamic co-simulation methodology of overall wind turbine systems is presented. This methodology combines aerodynamics, mechanism dynamics, control system dynamics, and subsystems dynamics. Aerodynamics and turbine properties were modeled in FAST (Fatigue, Aerodynamic, Structures, and Turbulence), and ADAMS (Automatic Dynamic Analysis of Mechanical Systems) performed the mechanism dynamics; control system dynamics and subsystem dynamics such as generator, pitch control system, and yaw control system were modeled and built in MATLAB/SIMULINK. Thus, this comprehensive integration of methodology expands both the flexibility and controllability of wind turbines. The dynamic variations of blades, rotor dynamic response, and tower vibration can be performed under different inputs of wind profile, and the control strategies can be verified in the different closed loop simulation. Besides, the dynamic simulation results are compared with the measuring results of SCADA (Supervisory Control and Data Acquisition) of a 2 MW wind turbine for ensuring the novel dynamic co-simulation methodology.

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“…Therefore the AFPM is considered for the development of this research work. The entire simulation is designed in terms of park transformation analysis that is a vector representation of three phase ac circuit models into a dq reference coordinates [10][11][12][13] as shown in Figure 3.…”

Section: Design Of the Three Phases Pmsgmentioning

confidence: 99%

Performance analysis of 20 Pole 1.5 KW Three Phase Permanent Magnet Synchronous Generator for low Speed Vertical Axis Wind Turbine

Khan

Rajkumar

et al. 2013

EPE

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This paper gives performance analysis of a three phase Permanent Magnet Synchronous Generator (PMSG) connected to a Vertical Axis Wind Turbine (VAWT). Low speed wind condition (less than 5 m/s) is taken in consideration and the entire simulation is carried in Matlab/Simulink environment. The rated power for the generator is fixed at 1.5 KW and number of pole at 20. It is observed under low wind speed of 6 m/s, a turbine having approximately 1 m of radius and 2.6 m of height develops 150 Nm mechanical torque that can generate power up to 1.5 KW. The generator is designed using modeling tool and is fabricated. The fabricated generator is tested in the laboratory with the simulation result for the error analysis. The range of error is about 5%-27% for the same output power value. The limitations and possible causes for error are presented and discussed.

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Control of Permanent Magnet Synchronous Generator for large wind turbines

Cited by 54 publications

References 4 publications

DC-Link Control Schemes in Multilevel Converters for WECS

DC-Link Control Schemes in Multilevel Converters for WECS

A Novel Dynamic Co-Simulation Analysis for Overall Closed Loop Operation Control of a Large Wind Turbine

Performance analysis of 20 Pole 1.5 KW Three Phase Permanent Magnet Synchronous Generator for low Speed Vertical Axis Wind Turbine

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