harmonic analysis of a dfig for a wind energy conversion system
DESCRIPTION
Harmonic Analysis of a DFIG for a Wind Energy Conversion System. Lingling Fan, Ph.D., P.E. Assistant Professor Dept. Electrical Engineering University of South Florida Tampa, FL 33620 [email protected] April 20, 2010. 2010 IEEE Transmission & Distribution Conference and Exhibition - PowerPoint PPT PresentationTRANSCRIPT
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Harmonic Analysis of a DFIG for a Wind Energy Conversion System
Lingling Fan, Ph.D., P.E.Assistant ProfessorDept. Electrical EngineeringUniversity of South FloridaTampa, FL [email protected]
April 20, 2010
2010 IEEE Transmission & Distribution Conference and Exhibition New Orleans, LA
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Outline
Objective Principle Case studies
– Rotor injection– Unbalanced stator conditions
Conclusion
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Objective
Develop a steady-state circuit to give quantitative analysis for harmonics in DFIG
The work is useful for understanding of– DFIG behavior during non-sinusoidal rotor
injection– DFIG under unbalanced grid conditions (fault
ride through)
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Frequency components in rotor voltage and stator current
Stator currents– (6n+1)fr+fm, -(6n-1)fr+fm,
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Electromagnetic torque Interaction of stator and rotor currents
Stator Is1 (60 Hz) Is2(-24*5 +36 Hz) Is3 (24*7 +36 Hz)
Rotor Ir1(24 Hz) Ir2 (-24*5 Hz) Ir3 (24*7 Hz)
Ex: Is1, Ir2 torque (60- (-120 +36)) = 144 Hz = 6*24 Hz 6fr
Is1, Ir3 torque (60- (168 +36)) = -144 Hz = -6*24 Hz 6fr
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Case study 2 – unbalanced stator conditions Rotor injection – programmable power
source –sinusoidal 3-phase Stator phase a resistance is reduced
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Analysis
13
Unbalanced stator currents
Positive sequence(fe)
Negative sequence(-fe)
Zero sequence
Ir: fe-fm=sfe
Rotor currents
Ir: -fe-fm=-(2-s)fe
s: slip = 1-fm/fe
fm: electric frequency corresponding to rotating speed.
fe: nominal frequency
60 Hz (stator) – 50 Hz (rotating speed) = 10 Hz
-60 Hz (stator) – 50 Hz (rotating
speed) = -110 Hz
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Torque
Positive Negative
Stator Is1 (+60 Hz) Is2 (-60 Hz)
Rotor Ir1 (10 Hz) Ir2 (-110 Hz)
1. Te1 Te2 – dc components2. Te3, Te4 – pulsating components 120 Hz
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Conclusion
This paper develops– A generalized steady-state DFIG circuit for
harmonic analysis– A systematic method to compute torque by
computing the interactions of stator and rotor currents
– The sequence network based on DFIG pos, neg circuits which facilitates the analysis under unbalanced stator conditions.