Assessment and Performance Evaluation of a Wind Turbine Power Output

Abolude, Akintayo T.; Zhou, Wen

doi:10.3390/en11081992

Cited by 13 publications

(8 citation statements)

References 41 publications

(54 reference statements)

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“…However, the actual wind power output is usually more than the theoretically calculated power, as in Equation 2, which may produce an estimation error of about 3%. This is because the gained momentum by the rotating turbine blades sustains the continual rotation when a sudden decrease in wind speed occurs with no major change in the angular wind direction [32]. The output power P(t) quantifies the variable turbine power at each time point t (in minutes).…”

Section: Wind Energy Calculationmentioning

confidence: 99%

Wind-Energy-Powered Electric Vehicle Charging Stations: Resource Availability Data Analysis

et al. 2020

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The integration of large-scale wind farms and large-scale charging stations for electric vehicles (EVs) into electricity grids necessitates energy storage support for both technologies. Matching the variability of the energy generation of wind farms with the demand variability of the EVs could potentially minimize the size and need for expensive energy storage technologies required to stabilize the grid. This paper investigates the feasibility of using the wind as a direct energy source to power EV charging stations. An interval-based approach corresponding to the time slot taken for EV charging is introduced for wind energy conversion and analyzed using different constraints and criteria, including the wind speed averaging time interval, various turbines manufacturers, and standard high-resolution wind speed datasets. A quasi-continuous wind turbine’s output energy is performed using a piecewise recursive approach to measure the EV charging effectiveness. Wind turbine analysis using two years of wind speed data shows that the application of direct wind-to-EV is able to provide sufficient constant power to supply the large-scale charging stations. The results presented in this paper confirm that the potential of direct powering of EV charging stations by wind has merits and that research in this direction is worth pursuing.

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Section: Wind Energy Calculationmentioning

confidence: 99%

Wind-Energy-Powered Electric Vehicle Charging Stations: Resource Availability Data Analysis

et al. 2020

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“…Therefore, the high penetration level of wind turbines and power electronics interfaces will decrease the total system inertia and lower the voltage/frequency stabilization compared to conventional synchronous generating units. The large voltage/frequency deviation might result in separation of the power system [1][2][3][4].…”

Section: Introductionmentioning

confidence: 99%

“…In order to improve the operation characteristics of BDFIG in the case of symmetrical grid faults, Equation (11) and (12) are utilized to calculate the compensation term i * cz, and the total reference current i * cd = i * cw + i * cz is finally obtained for the inner CW current controller. Additionally, according to the first equation in (4), E 0 can be obtained as:…”

mentioning

confidence: 99%

Virtual Synchronous Control Based on Control Winding Orientation for Brushless Doubly Fed Induction Generator (BDFIG) Wind Turbines Under Symmetrical Grid Faults

et al. 2019

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The Brushless Doubly Fed Induction Generator (BDFIG) has huge potential for wind power systems due to its high reliability and low maintenance cost. To add inertia for system stability enhancement, as well as to maintain the uninterrupted operation during symmetrical grid faults, this study proposes a Virtual Synchronous Control (VSC) with a transient current compensation strategy for BDFIG. The proposed VSC is realized by regulating the virtual inner electrical potential and angular velocity of BDFIG under Control Winding (CW) current oriented vector control, and compensating for the transient CW current to weaken the transient inner electrical potential under symmetrical grid faults. Modeling and analysis of such a VSC strategy are presented in this paper, and a simulation is also made to compare the performances of existing and proposed VSC strategies. It is shown that the merits of the proposed VSC can enhance the fault ride through the ability of the BDFIG system and support the recovery of grid voltage.

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“…Wind turbine power output has been studied under themes such as performance characterization [21][22][23], assessment and management [24], estimation/forecast errors [25], and power curves [26][27][28].…”

Section: Introductionmentioning

confidence: 99%

“…One common conclusion is the presence of deviations of the actual farm or turbine output from that of the supplied power curve using the words errors, dispersion belly and/or variations interchangeably. Abolude & Zhou [24] observed deviations of actual output from the turbine power curve for an 800 kW WT, while Villaneuva & Feijoo [29] argue for a "true power curve" to minimize estimation errors observed from WT real time performance data. In another related study, Whale et al [30] noted deviations of the actual power from manufacturer WTPC for small wind turbines at high wind speeds, and Cooney et al [21] reported similar differences during a performance characterization study for an urban-sited wind turbine.…”

Section: Introductionmentioning

confidence: 99%

A Comparative Computational Fluid Dynamic Study on the Effects of Terrain Type on Hub-Height Wind Aerodynamic Properties

Abolude

Zhou

2018

Energies

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The increased adoption of wind power has generated global discourse in wind energy meteorology. Studies based on turbine performances show a deviation of actual output from power curve output, thereby yielding errors irrespective of the turbine site. Understanding the cause of these errors is essential for wind power optimization, thus necessitating investigation into site-specific effects on turbine performance and operation. Therefore, Computational Fluid Dynamics simulations of hub-height wind aerodynamic properties were conducted based on the k-ε turbulence closure model Reynolds Averaged Navier Stokes equations for three terrains. To isolate terrain-induced effects, the same 40 m above mean sea level wind climatology was imposed on all three terrains. For the four wind directions considered, turbulence intensity (TI) was least in the offshore terrain at about 5–7% but ranged considerably higher from 4–18% for the coastal and island terrain. TI on crests also increased significantly by up to 15% upstream of wind direction for the latter terrains. Inflow angle ranged from −15° to +15° in both coastal and island terrains but remained at <+1° in the offshore terrain. Hellman exponent increased from between factors of 2–4 in the other two terrains relative to that of the offshore terrain. Wind speed-up varied from about 1.06–1.13, accounting for a range of 17–30% difference in power output from a hypothetical operational 2 MW turbine output placed in the three different terrains. Turbine loading, fatigue, efficiency, and life cycle can also be impacted by the variations noted. While adopting a site-specific power curve may help minimize errors and losses, collecting these aerodynamic data alongside wind speed and direction is the future for wind power optimization under big data and machine learning.

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Assessment and Performance Evaluation of a Wind Turbine Power Output

Cited by 13 publications

References 41 publications

Wind-Energy-Powered Electric Vehicle Charging Stations: Resource Availability Data Analysis

Wind-Energy-Powered Electric Vehicle Charging Stations: Resource Availability Data Analysis

Virtual Synchronous Control Based on Control Winding Orientation for Brushless Doubly Fed Induction Generator (BDFIG) Wind Turbines Under Symmetrical Grid Faults

A Comparative Computational Fluid Dynamic Study on the Effects of Terrain Type on Hub-Height Wind Aerodynamic Properties

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