Modeling and simulation of permanent magnet synchronous generator wind power generation system using boost converter circuit

Tammaruckwattana, Sirichai; Ohyama, Kazuhiro

doi:10.1109/epe.2013.6634358

Cited by 5 publications

(3 citation statements)

References 7 publications

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“…The differences must be compensated because wind velocity, V 0 , always changes. The difference can be compensated by the following equation: [9], [10] Fig . 7 shows the duty ratio control system for BCC.…”

Section: B Mechanical Modelmentioning

confidence: 99%

See 1 more Smart Citation

Experimental Assessment with Wind Turbine Emulator of Variable-Speed Wind Power Generation System using Boost Chopper Circuit of Permanent Magnet Synchronous Generator

Tammaruckwattana¹,

Ohyama²,

Yue³

2015

Journal of Power Electronics

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This paper presents experimental results and its assessment of a variable-speed wind power generation system (VSWPGS) using permanent magnet synchronous generator (PMSG) and boost chopper circuit (BCC). Experimental results are obtained by a test bench with a wind turbine emulator (WTE). WTE reproduces the behaviors of a windmill by using servo motor drives. The mechanical torque references to drive the servo motor are calculated from the windmill wing profile, wind velocity, and windmill rotational speed. VSWPGS using PMSG and BCC has three speed control modes for the level of wind velocity to control the rotational speed of the wind turbine. The control mode for low wind velocity regulates an armature current of generator with BCC. The control mode for middle wind velocity regulates a DC link voltage with a vector-controlled inverter. The control mode for high wind velocity regulates a pitch angle of the wind turbine with a pitch angle control system. The hybrid of three control modes extends the variable-speed range. BCC simplifies the maintenance of VSWPGS while improving reliability. In addition, VSWPGS using PMSG and BCC saves cost compared with VSWPGS using a PWM converter.

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Section: B Mechanical Modelmentioning

confidence: 99%

“…Therefore, wind generator systems using PMSG and a diode bridge rectifier to charge the battery are mainly operated at the rated wind velocity because the induced voltage is sufficiently high [8], [9]. These wind generator systems are low-cost converters.…”

Section: Introductionmentioning

confidence: 99%

Experimental Assessment with Wind Turbine Emulator of Variable-Speed Wind Power Generation System using Boost Chopper Circuit of Permanent Magnet Synchronous Generator

Tammaruckwattana¹,

Ohyama²,

Yue³

2015

Journal of Power Electronics

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“…Therefore, power converters are used in wind generators to provide a constant output. The high capacity of a wind turbine indicates that the corresponding generator and power converter must operate at higher voltage levels to achieve maximum efficiency and optimum size, volume, and form-factor [8][9]. The output voltages of wind generators are excessively high for using insulated gate bipolar transistor (IGBT)-based converters.…”

Section: Introductionmentioning

confidence: 99%

Use of Three-Level Power Converters in Wind-Driven Permanent-Magnet Synchronous Generators with Unbalanced Loads

Chen

2015

Electronics

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This paper describes the design and implementation of three-level power converters for wind-driven permanent-magnet synchronous generators with unbalanced loads. To increase voltage stress and reduce current harmonics in the electrical power generated by a wind generator, a three-phase, three-level rectifier is used. Because a synchronous rotating frame is used on the AC-input side, the use of a neutral-point-clamped controller is proposed to increase the power factor to unity and reduce current harmonics. Furthermore, a novel six-leg inverter is proposed for transferring energy from the DC voltage to a three-phase, four-wire AC source with a constant voltage and a constant frequency. The power converters also contain output transformers and filters for power buffering and filtering, respectively. All three output phase voltages are fed back to control the inverter output during load variations. A digital signal processor is used as the core control device for implementing a 1.5 kV, 75 kW drive system. Experimental data show that the power factor is successfully increased to unity and the total current harmonic distortion is 3.2% on the AC-input side. The entire system can attain an efficiency of 91%, and the voltage error between the upper and lower capacitors is approximately zero. Experimental results that confirm the high performance of the proposed system are presented.

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Micro Grid: An Energy Efficient Approach for Modern Power System

Kevin

Modi

Philipose

2019

2019 IEEE International Conference on Distributed Computing, VLSI, Electrical Circuits and Robotics (DISCOVER)

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Modeling and simulation of permanent magnet synchronous generator wind power generation system using boost converter circuit

Cited by 5 publications

References 7 publications

Experimental Assessment with Wind Turbine Emulator of Variable-Speed Wind Power Generation System using Boost Chopper Circuit of Permanent Magnet Synchronous Generator

Experimental Assessment with Wind Turbine Emulator of Variable-Speed Wind Power Generation System using Boost Chopper Circuit of Permanent Magnet Synchronous Generator

Use of Three-Level Power Converters in Wind-Driven Permanent-Magnet Synchronous Generators with Unbalanced Loads

Micro Grid: An Energy Efficient Approach for Modern Power System

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