Abstract
Maximum power can be extricated when the turbine keeps running at a consistent and constant speed by using all the vitality present in the wind. The turbine can keep running at a steady speed just when the breeze speed is consistent. The wind vitality being wild in nature, maximum power must be achieved by making the turbine to keep running at the specific breeze speed. To achieve most extreme power, distinctive sorts of maximum power point tracking (MPPT) procedures are utilized. So as to comprehend prudent and proficient power age utilizing wind turbines, modification of fuzzy-based MPPT method is displayed and results are compared with different MPPT techniques for wind energy conversion system have been done and are introduced in subtleties.
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- \(\rho\) :
-
Air density (1.2 kg/m3)
- C p :
-
Power coefficient
- \(\beta\) :
-
Incident angle of the blade
- V in :
-
Input voltage
- V o :
-
Output voltage
- P w :
-
Wind power
- η g :
-
Generator efficiency
- η m :
-
Motor efficiency
- I :
-
Current
- P e :
-
Electric power generated
- E :
-
Error
- DP:
-
Deviation of power over a small time interval
- DV:
-
Deviation of voltage over a small time interval
- DI:
-
Deviation of current over a small time interval
- CE:
-
Deviation in error
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Govinda Chowdary, V., Udhay Sankar, V., Mathew, D., Hussaian Basha, C., Rani, C. (2020). Hybrid Fuzzy Logic-Based MPPT for Wind Energy Conversion System. In: Das, K., Bansal, J., Deep, K., Nagar, A., Pathipooranam, P., Naidu, R. (eds) Soft Computing for Problem Solving. Advances in Intelligent Systems and Computing, vol 1057. Springer, Singapore. https://doi.org/10.1007/978-981-15-0184-5_81
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DOI: https://doi.org/10.1007/978-981-15-0184-5_81
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