High-Order Sliding Mode control for DFIG-based Wind Turbine Fault Ride-Through

Benbouzid, Mohamed; Beltran, Brice; Yao, Gang; Han, Jingang; Mangel, Hervé

doi:10.1109/iecon.2013.6700411

Cited by 11 publications

(16 citation statements)

References 11 publications

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“…This controller is designed from the SOSM theoretical framework which is very appropriate to deal with systems described by uncertain non-linear dynamic models subjected to external perturbations. In particular, this technique generates robust and simple controllers with reduced chattering effects on the sliding surfaces and, in the specific case of STwA realisations, synthesising continuous control actions [17,18,21]. The resultant controllers do not depend on the system parameter values and naturally assimilate their bounded temporal drifts.…”

Section: Control Designmentioning

confidence: 99%

“…This theoretical framework presents a set of attractive advantages that cover most of the requirements necessary for this case. Briefly, the resultant controllers have a high robustness degree to unmodelled dynamics and continuous bounded perturbations, present a bounded and finite reaching time, have a very simple structure with a low computational burden, are very appropriate to successfully deal with the control design for non-linear complex systems and, ideally, they do not present ripple (chattering) on the sliding surfaces [17][18][19].…”

Section: Introductionmentioning

confidence: 99%

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Multiple‐input–multiple‐output high‐order sliding mode control for a permanent magnet synchronous generator wind‐based system with grid support capabilities

Valenciaga

Fernández

2015

IET Renewable Power Generation

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This study presents a control design for a grid connected wind energy conversion system based on a gearless PMSG. The generation system structure comprises a three blade turbine, a 2 MW multi-pole PMSG and a full-scale backto-back frequency converter linked to the utility grid. The proposed control scheme allows following dynamical specifications taking into account operational requirements and ancillary services imposed by the recent grid connection codes, that is, reactive power regulation and fault ride-through (FRT) capabilities. The control actions to be applied during normal grid operation are designed through second-order sliding mode techniques using a two-stage cascade structure. The multi-variable controller designed attains to regulate the active and reactive powers delivered to the grid, minimising the resistive losses into the generator and maintaining important internal variables into the desired range. This controller presents attractive advantages such as robustness against unmodelled dynamics and external perturbations, finite time convergence to the sliding surfaces and chattering mitigation. To endorse the controlled system with FRT capabilities, a switching control scheme based on voltage grid measurements is also proposed. The performance of the whole control approach is analysed through representative simulations which include parameter variations, external perturbations and three-phase voltage dips.

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Section: Control Designmentioning

confidence: 99%

Section: Introductionmentioning

confidence: 99%

Multiple‐input–multiple‐output high‐order sliding mode control for a permanent magnet synchronous generator wind‐based system with grid support capabilities

Valenciaga

Fernández

2015

IET Renewable Power Generation

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“…To ensure the sliding manifolds convergence to zero in finite times, the gains B 1 , B 2 , B 3 , and B 4 can be chosen as follows [19][20] (15) In this context, it can be asserted that there exist finite times t Tem and t Ird leading to (16). This means that the control objective is achieved.…”

Section: Hosm Control Strategymentioning

confidence: 99%

“…Therefore and in this particular context, this paper proposes the use of high-order sliding mode control as an improved solution that handles the classical sliding mode chattering problem and particularly avoids using additional devices and converter oversizing. Indeed, the main and attractive features of HOSMs are robustness against external disturbances (grid faults) and chattering-free behavior (no extra mechanical stress on the drive train) [14][15][16]. The proposed control strategy combines an MPPT using a second-order sliding mode for the DFIG control [17][18].…”

Section: Introductionmentioning

confidence: 99%

Second-order sliding mode control for DFIG-based wind turbines fault ride-through capability enhancement

et al. 2014

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This paper deals with the fault ride-through capability assessment of a doubly fed induction generator-based wind turbine using a high-order sliding mode control. Indeed, it has been recently suggested that sliding mode control is a solution of choice to the fault ride-through problem. In this context, this paper proposes a second-order sliding mode as an improved solution that handle the classical sliding mode chattering problem. Indeed, the main and attractive features of high-order sliding modes are robustness against external disturbances, the grids faults in particular, and chattering-free behavior (no extra mechanical stress on the wind turbine drive train). Simulations using the NREL FAST code on a 1.5-MW wind turbine are carried out to evaluate ride-through performance of the proposed high-order sliding mode control strategy in case of grid frequency variations and unbalanced voltage sags.

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“…[2] A high-order sliding mode(HOSM) control is proposed to handle the chattering problem with the chattering-free behavior and robustness against external disturbances. [4] A robust discretetime SMC algorithm coupled with an uncertainty estimator based on sliding modes is used for a planar robotic manipulator. Good tracking performance and robustness are obtained when payload perturbations and inaccuracies disturbances exist.…”

Section: Introductionmentioning

confidence: 99%

Sliding Mode Control of Double Inverted Pendulum Based on a Novel Approach Law

Sun¹,

Fu²

2015

Proceedings of the 2015 International Conference on Industrial Technology and Management Science

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In this paper, a sliding mode controller based on new type of approach law is applied to double inverted pendulum(DIP) in order to weaken the chattering and shorten the approaching time, ensure the system to achieve better dynamic quality and stabilize the DIP system around equilibrium states. Further, theoretical proof is given to demonstrate the feasibility of the proposed method. Experimental results of implementing proposed controller show a high performance of it in comparison to traditional exponential approach law. KEYWORD: inverted pendulum; sliding mode; approach law; chattering

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High-Order Sliding Mode control for DFIG-based Wind Turbine Fault Ride-Through

Cited by 11 publications

References 11 publications

Multiple‐input–multiple‐output high‐order sliding mode control for a permanent magnet synchronous generator wind‐based system with grid support capabilities

Multiple‐input–multiple‐output high‐order sliding mode control for a permanent magnet synchronous generator wind‐based system with grid support capabilities

Second-order sliding mode control for DFIG-based wind turbines fault ride-through capability enhancement

Sliding Mode Control of Double Inverted Pendulum Based on a Novel Approach Law

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