Adaptive Nonlinear Control of Wind Energy Conversion System Involving Induction Generator

Howard

Asian Journal of Control

2018

In this paper, the extension of the Bayesian framework for sensor fault detection of nonlinear systems proposed in [25] is studied utilizing particle filtering and the expectation maximization (EM) algorithm, in which the fault probability is calculated. The proposed algorithm is implemented on a wind turbine benchmark model to detect drivetrain sensor faults, which are one of the most addressed and likely faults in offshore wind turbines. The fault probability estimation effectively eliminates the need for installing identical redundant sensors. Indeed, because of the use of the unknown wind speed estimator, the residual signal, constructed based on the drivetrain estimated states, is not able to clearly signify the fault periods, a situation in which the fault probability accurately does this task. Also, using the proposed algorithm, the fault size for each sensor is estimated via a one‐step calculation, which decreases the complexity of this algorithm. The fault identification is performed using the recursive least square method and two other modifications, including exponentially weighted and windowed estimates. Additionally, in the fault accommodation step, the concept of a virtual sensor is used to remove the need for reconfiguring the current controller, which reduces complexity and expense. In the simulation section, using a real measured wind speed for two different fault scenarios, the proposed algorithm is evaluated and finally, conclusions are stated.

T_{a} = 0.5 italicρAR V_{r}^{2} C_{q} ((),, λ, β), P_{a} = 0.5 italicρA V_{r}^{3} C_{p} ((),, λ, β),

respectively, where ρ is air density, A is swept area, R is blade length and V r is the wind speed at the blade plane, which is not accurately measurable and is considered as a disturbance.…”

Section: Wind Turbine Model and Nominal Controllermentioning

confidence: 99%

Section: Wind Turbine Model and Nominal Controllermentioning

confidence: 99%

Bayesian Fault Probability Estimation: Application in Wind Turbine Drivetrain Sensor Fault Detection

Howard

Asian Journal of Control

2018

“…Boltzmann's constant, represents the ideality factor of P-N junction, and T is the cell temperature in Kelvin. In characteristic equation 1, the reverse saturation current and light-generated current are calculated respectively by (2) and 3where is the reference temperature, denotes the reverse saturation current at , is The reference voltage may be obtained by various search-based algorithms. Such point may be calculated analytically by solving , which yields 5where is defined for notational consistency.…”

Section: Mathematical Modellingmentioning

confidence: 99%

“…Photovoltaic systems have been widely utilized in various applications [1,2] to convert the solar energy, as one of the main renewable energy sources, to electrical power. Due to such advantages as easy maintenance and availability of sunlight, the demand of PV power generation systems for both the industrial and residential applications have been increased in recent years.…”

Section: Introductionmentioning

confidence: 99%

Adaptive robust maximum power point tracking control for perturbed photovoltaic systems with output voltage estimation

Koofigar

2016

ISA Transactions

The problem of maximum power point tracking (MPPT) in photovoltaic (PV) systems, despite the model uncertainties and the variations in environmental circumstances, is addressed. Introducing a mathematical description, an adaptive sliding mode control (ASMC) algorithm is first developed. Unlike many previous investigations, the output voltage is not required to be sensed and the upper bound of system uncertainties and the variations of irradiance and temperature are not required to be known. Estimating the output voltage by an update law, an adaptive-based H∞ tracking algorithm is then developed for the case the perturbations are energy-bounded. The stability analysis is presented for the proposed tracking control schemes, based on the Lyapunov stability theorem. From a comparison viewpoint, some numerical and experimental studies are also presented and discussed.

Asian Journal of Control

“…The robust SMC is used to maintain the dc-link voltage for a variable speed wind turbine system [17]. In [19], authors have designed a multi-loop nonlinear controller based on an adaptive backstepping method for wind energy control system to get speed optimization and power factor correction. In [19], authors have designed a multi-loop nonlinear controller based on an adaptive backstepping method for wind energy control system to get speed optimization and power factor correction.…”

Section: Introductionmentioning

confidence: 99%

Stability analysis and a hybrid controller design of grid‐connected offshore wind farm through a VSC‐HVDC transmission link

Srikakulapu

Vinatha

2019

This paper proposes a hybrid controller which is a combination sliding mode control and PI control techniques for AC grid integrated offshore wind farm (OSWF) with voltage source converter -high voltage direct current system. The controller must be capable of controlling AC voltage, DC-link voltage, reactive power and effective power transfer. To examine the FRT capability, a symmetrical fault is applied at onshore AC grid side and compared the performances of the studied system based on the hybrid and PI controllers. The dynamic modelling and linearized system by state-space modelling for the studied system are explained in detail. The small signal stability analysis and controller stability are observed with the help of the eigenvalue analysis. The analysis of the studied system with a hybrid and conventional controllers are conducted in the software environment of the MATLAB/SIMULINK. The effect of parameter uncertainty on total system stability is examined with the help of eigenmatrix of the studied system.