286 research outputs found
On wind Turbine failure detection from measurements of phase currents: a permutation entropy approach
This article presents the applicability of Permutation Entropy based
complexity measure of a time series for detection of fault in wind turbines. A
set of electrical data from one faulty and one healthy wind turbine were
analysed using traditional FastFourier analysis in addition to Permutation
Entropy analysis to compare the complexity index of phase currents of the two
turbines over time. The 4 seconds length data set did not reveal any low
frequency in the spectra of currents, neither did they show any meaningful
differences of spectrum between the two turbine currents. Permutation Entropy
analysis of the current waveforms of same phases for the two turbines are found
to have different complexity values over time, one of them being clearly higher
than the other. The work of Yan et. al. in has found that higher entropy values
related to thepresence of failure in rotary machines in his study. Following
this track, further efforts will be put into relating the entropy difference
found in our study to possible presence of failure in one of the wind energy
conversion systems
A modified sequence domain impedance definition and its equivalence to the dq-domain impedance definition for the stability analysis of AC power electronic systems
Representations of AC power systems by frequency dependent impedance
equivalents is an emerging technique in the dynamic analysis of power systems
including power electronic converters. The technique has been applied for
decades in DC-power systems, and it was recently adopted to map the impedances
in AC systems. Most of the work on AC systems can be categorized in two
approaches. One is the analysis of the system in the \textit{dq}-domain,
whereas the other applies harmonic linearization in the phase domain through
symmetric components. Impedance models based on analytical calculations,
numerical simulation and experimental studies have been previously developed
and verified in both domains independently. The authors of previous studies
discuss the advantages and disadvantages of each domain separately, but neither
a rigorous comparison nor an attempt to bridge them has been conducted. The
present paper attempts to close this gap by deriving the mathematical
formulation that shows the equivalence between the \textit{dq}-domain and the
sequence domain impedances. A modified form of the sequence domain impedance
matrix is proposed, and with this definition the stability estimates obtained
with the Generalized Nyquist Criterion (GNC) become equivalent in both domains.
The second contribution of the paper is the definition of a \textit{Mirror
Frequency Decoupled} (MFD) system. The analysis of MFD systems is less complex
than that of non-MFD systems because the positive and negative sequences are
decoupled. This paper shows that if a system is incorrectly assumed to be MFD,
this will lead to an erroneous or ambiguous estimation of the equivalent
impedance
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