Abstract
This paper presents the development and experimental verification of the mathematical model of wind turbine and Doubly Fed Induction Generator (DFIG) using the current control and voltage estimation method between the DC link. The rotor of the induction generator (IG) is rotated with the wind turbine at a specific speed. The DFIG is directly coupled with a grid station and the synchronization between DFIG and the grid station is controlled by setting two converters: Machine Side Converter (MSC) implemented with the rotor side and Grid Side Converter (GSC) implemented with the grid. PI controllers have been utilized in the control loops and the parametric range is extracted to maximize the mechanical power transferred to the IG rotor. The model is tested under three conditions DFIG running at super synchronous speed, synchronous speed, and under synchronous speed using MATLAB Simulink. In the end, the same model is also tested through a series of experiments using lab modules. The results show that the proposed model is much simplified and accurate as compared to previous versions available in the literature.
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Abbreviations
- \(A\) :
-
Turbine swept area
- \(\beta\) :
-
Blade Pitch angle
- \({\uppsi }_{\mathrm{r}}\) :
-
Rotor side flux
- \({\uppsi }_{\mathrm{s}}\) :
-
Stator side Flux
- \({C}_{P}\) :
-
Performance factor
- \({C}_{p}\) :
-
Power coefficient
- DFIG:
-
Doubly fed induction generator
- DSL:
-
Dynamic simulation language
- \({E}_{wind}\) :
-
Wind energy
- GSC:
-
Grid Side converter
- H :
-
Motor inertia
- IG:
-
Induction generator
- \({i}_{\mathrm{s}}\) :
-
Stator current
- \({i}_{r}\) :
-
Rotor current
- \({I}_{abc}\) :
-
Three phase line current
- \({L}_{m}\) :
-
Mutual inductance
- \({L}_{r}\) :
-
Rotor side inductance
- \({L}_{s}\) :
-
Stator side inductance
- \(\lambda\) :
-
Tip speed ratio
- \({P}_{g}\) :
-
Grid active power
- \(P\) :
-
Number of poles
- \({P}_{m}\) :
-
Mechanical power
- \({Q}_{g}\) :
-
Grid reactive power
- \({R}_{r}\) :
-
Rotor resistance
- \({R}_{s}\) :
-
Stator resistance
- \({T}_{e}\) :
-
Induced torque
- \({T}_{m}\) :
-
Mechanical torque
- \({V}_{DC}\) :
-
DC voltage
- \({V}_{abc}\) :
-
Three phase line voltage
- \({V}_{r}\) :
-
Rotor side voltage
- \({V}_{s}\) :
-
Stator side voltage
- \({V}_{wind}\) :
-
Wind velocity
- \({\theta }_{e}\) :
-
Synchronously rotating angle
- \({\omega }_{r}\) :
-
Rotor angular velocity (rev/min)
- \({\omega }_{s}\) :
-
Synchronous speed (rev/min
- \(\mathrm{MSC}\) :
-
Machine side converter
- \(\mathrm{NREL}\) :
-
National Renewable Energy Laboratory
- \(\mathrm{t}\) :
-
Time
- \(\mathrm{THD}\) :
-
Total harmonic distortion
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Ahmad, H., Khalid, H., Amin, A. et al. Improved Current Controlled Doubly Fed Induction Generator Model with Grid Integration Under Sub and Super Synchronous Conditions. J. Electr. Eng. Technol. 16, 141–153 (2021). https://doi.org/10.1007/s42835-020-00572-w
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DOI: https://doi.org/10.1007/s42835-020-00572-w