Real-time implementation of sliding-mode field-oriented control for a DFIG-based wind turbine

This paper proposes the decoupling control of direct torque control (DTC) and field orient control (FOC) for doubly fed induction generator (DFIG)-based wind energy system (WES). The proposed technique reduces the transient of system during low voltage ride through (LVRT) as well as voltage dip (VD) with out auxiliary circuit. The combined DTC-FOC regulates both rotor and grid side converters (RGSCs). In particular, DTC controls the generator speed, torque and rotor flux; similarly, FOC regulates the capacitor link voltage and power quality of grid during LVRT and VD. The linear controller is unable to control the nonlinearities of system dynamics with respect to time. Further, the proposed technique is analyzed with sliding mode control (SMC) and conventional controllers independently. The proposed DTC-FOC aims to improve the performance of transient and dynamic behavior of DFIG-based WES during LVRT and VD. It is also tested in real-time environment at 7.5 hp as well as MATLAB/SIMULINK of 5.5 kW rating. Keywords Doubly fed induction generator • Wind energy system • Sliding mode control • Low voltage ride through • Voltage dip • Direct torque control

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“…1. Equation (1) is rewritten by choosing all parameters referring to stator side (Wang et al 2017;Djilali et al 2018).…”

Section: Modeling Of Dfigmentioning

confidence: 99%

Real-Time Simulator of DTC–FOC-Based DFIG During Voltage Dip and LVRT

Jaladi

Sandhu

Bommala

2020

J Control Autom Electr Syst

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“…The state variables are computed by Equations (10) and (11). The _ x 1 , _ x 2 , and _ x 3 are the derivatives of error variables and given by (37), (38), and (39):…”

Section: Inverter Control Based On Integral Sliding Mode Control (Imentioning

confidence: 99%

“…where V s is the source voltage, C is the output filter capacitor, R is the load, and u is the switching function. The derivatives of sliding function ( _ S) obtained by incorporating (37), (38), and (39) is expressed as (40):…”

Section: Inverter Control Based On Integral Sliding Mode Control (Imentioning

confidence: 99%

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Resilient cyber physical infrastructure for single‐phase dual inverter with sliding mode control

Senthilnathan

Annapoorani

2019

Int Trans Electr Energ Syst

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Summary As the need in cyber infrastructure for electrical systems to realize the industry 4.0 revolution, this paper presents a configuration of two‐switch dual‐output voltage source inverter with integral sliding mode control (ISMC) and cyber twin approach to realize the performance of the system. The inverter has the capability of supplying two independent loads of equal voltage at the load end. The virtual model (cyber twin) is developed to realize the operation of the inverter (physical device) with a host system. The cyber‐physical test bench is developed to evaluate the performance of the physical model (inverter prototype) with cyber‐physical capabilities. The coupled computation of the virtual model and prototype model is executed to analyze the performance of the inverter.

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“…In general, the rotor of the DFIG is fed through a back-to-back pulse width modulation (PWM) converter as shown in Figure 3. 4,[25][26][27] The detailed modeling of DFIG is described in Djilali et al 25 and Shihabudheen et al 26 The proposed control approach of the generator/rotor-side and grid/load-side converters for the active and reactive power control loops is shown in Figures 4 and 5, respectively. During frequency events, the net output power (P * wind ) extracted from WTG is the combination of the dynamic deloading power ( p * ref ) and power contribution (ΔP sp ) by the frequency-emulated inertia and droop control, which is shown in Figure 4.…”

Section: Deloading Operation Of Wtgs Using Lipmentioning

confidence: 99%

Lagrange interpolating polynomial–based deloading control scheme for variable speed wind turbines

Senapati

Pradhan

Nayak

et al. 2019

Int Trans Electr Energ Syst

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Summary In this paper, an adaptive deloading scheme is proposed for enhancing the output power from the deloaded variable speed wind turbine generator (VSWTG). The deloading operation of a wind turbine generator (WTG) creates a reserve power margin at its maximum power point operation that can be utilized for stabilizing the frequency deviations of the power system during system contingencies. The output power of the deloaded WTG is regulated dynamically during the system events for improving the primary frequency response. The nonlinear power characteristic curve of the wind turbine is treated with a Lagrange interpolating polynomial (LIP) technique for increasing the output power of the deloaded WTG. Moreover, LIP‐based deloading of WTG contributes a better frequency dynamic performance during different power system scenarios such as the fluctuations in wind speed and change in load than the traditional control scheme. Due to the smoothing in frequency response with a faster settling time, the proposed LIP‐based deloading scheme can comply with the necessities of the grid codes of the wind‐integrated power system. The real‐time hardware‐in‐the‐loop (HIL) simulation results are exhibited to validate the proposed deloading methodology in support of the theory. The HIL platform is realized by using the real‐time simulator manufactured by OPAL‐RT Technologies.

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Real-time implementation of sliding-mode field-oriented control for a DFIG-based wind turbine

Cited by 24 publications

References 24 publications

Real-Time Simulator of DTC–FOC-Based DFIG During Voltage Dip and LVRT

Real-Time Simulator of DTC–FOC-Based DFIG During Voltage Dip and LVRT

Resilient cyber physical infrastructure for single‐phase dual inverter with sliding mode control

Lagrange interpolating polynomial–based deloading control scheme for variable speed wind turbines

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