Improving the Performance of Controllers for Wind Turbines on Semi-Submersible Offshore Platforms: Fuzzy Supervisor Control

Zambrana, Pablo; Fernández-Quijano, Javier; Lozano, Juan Jesús Fernández; Rubio, Pedro M. Mayorga; García-Cerezo, Alfonso J.

doi:10.3390/en14196222

Cited by 4 publications

(2 citation statements)

References 67 publications

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“…However, to mitigate the over-integration problems when the controller output is saturated, [27]- [29], the PI integrative part must be set to zero, i.e., I = 1/Ti vdc = 0, and therefore k1 vdc = 1 and k2 vdc = -1. As the active power is already defined, the reactive power (qs) can be set as a function of the desired power factor (pf) as follow:…”

Section: ) Power Controlmentioning

confidence: 99%

A Novel Global Maximum Power Point Tracking Method Based on Measurement Cells

Morales¹,

Rohten²,

Garbarino³

et al. 2022

IEEE Access

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Solar power generation has become a solution to mitigate the severe effects on the everyday higher prices of fossil fuels. Additionally, renewable energies operation -as solar-results in a non-polluting way to supply energy, being of special interest into highly contaminated cities and/or countries. The solar energy efficiency injection system is known to be high and mainly due to the power converters effectiveness, which is over of 95% for low and medium voltage. However, this efficiency is reduced when the solar array is partially shaded because traditional maximum power point tracking (MPPT) algorithms are not able to find the maximum power point (MPP) under irregular radiation. This work presents a new algorithm to find the global MPP (GMPP) based upon two MPPTs algorithms used regularly in uniform solar condition (USC), these are the Measuring Cell (MC) and the Perturb and Observe (P&O) methods. The MC ensures to find the surroundings of every local MPP (LMPP) faster and then choose among them the surroundings of the GMPP. Once the surroundings of GMPP are found, the P&O is used to get closer to the GMPP but reducing the DC voltage oscillation to zero hence overcoming the main issue of the P&O. Thus, the proposed algorithm finds the GMPP in two main steps and eliminates the oscillations around the GMPP in steady state, despite the utilization of the P&O. The algorithm is detailed mathematically, illustrated by means of a block diagram, and validated in simulated and experimental results.

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Section: ) Power Controlmentioning

confidence: 99%

A Novel Global Maximum Power Point Tracking Method Based on Measurement Cells

Morales¹,

Rohten²,

Garbarino³

et al. 2022

IEEE Access

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show abstract

“…Based on a project involving the construction of a 2000-ton offshore wind power installation platform, the risk characteristics of offshore platforms during the design stage have been systematically studied [ 3 ], and a significant stabilization of these platforms in terms of pitching angle and nacelle acceleration due to the installation of a gyro has been achieved [ 4 ]. Previous studies have analyzed the dynamic characteristics of offshore platforms [ 5 , 6 ], summarized the key technologies of offshore platforms [ 7 ], proposed that one of the most relevant cost items is the floating substructure [ 8 ], and presented the fuzzy control method as an alternative solution for the installation platform [ 9 ]. Takagi proposed an innovative jack-up seawall as an effective countermeasure to protect the port and its hinterland from tsunamis [ 10 ].…”

Section: Introductionmentioning

confidence: 99%

Research on Pneumatic Control of a Pressurized Self-Elevating Mat for an Offshore Wind Power Installation Platform

Cui,

Shi,

Lin

et al. 2023

Sensors

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Efficient deep-water offshore wind power installation platforms with a pressurized self-elevating mat are a new type of equipment used for installing offshore wind turbines. However, the unstable internal pressure of the pressurized self-elevating mat can cause serious harm to the platform. This paper studies the pneumatic control system of the self-elevating mat to improve the precision of its pressure control. According to the pneumatic control system structure of the self-elevating mat, the pneumatic model of the self-elevating mat is established, and a conventional PID controller and fuzzy PID controller are designed and established. It can be seen via Simulink simulation that the fuzzy PID controller has a smaller adjustment time and overshoot, but its anti-interference ability is relatively weak. The membership degree and fuzzy rules of the fuzzy PID controller are optimized using a neural network algorithm, and a fuzzy neural network PID controller based on BP neural network optimization is proposed. The simulation results show that the overshoot of the optimized controller is reduced by 9.71% and the stability time is reduced by 68.9% compared with the fuzzy PID. Finally, the experiment verifies that the fuzzy neural network PID controller has a faster response speed and smaller overshoot, which improves the pressure control accuracy and robustness of the self-elevating mat and provides a scientific basis for the engineering applications of the self-elevating mat.

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Development and Evaluation of Fuzzy Logic Controllers for Improving Performance of Wind Turbines on Semi-Submersible Platforms under Different Wind Scenarios

Zambrana

Fernández-Quijano²,

Rubio³

et al. 2023

Applied Sciences

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Among renewable energy technologies, wind energy features one of the best possibilities for large-scale integration into power systems. However, there are specific restrictions regarding the installation areas for this technology, thus resulting in a growing, yet restricted, rate of penetration of the technology because of the limited viable sites onshore or in shallow waters. In this context, the use of offshore semi-submersible platforms appears as a promising option, which additionally enables the incorporation of other elements, such as wave energy converters or aquaculture. Nevertheless, this kind of offshore facility involves interactions between platform movements and the wind turbine, increasing the complexity of the system, causing traditional control techniques to not be able to fully cope with the dynamics of the system, and thus limiting the efficiency of energy extraction. On the contrary, the use of intelligent control techniques is an interesting option to take full account of the said interactions and to improve energy capture efficiency through the control of the pitch of the blades, especially under turbulent, above-rated wind profiles. This work presents an original fuzzy logic controller that has been validated by comparing it with previously validated controllers, following a developed methodology that allows comparison of controllers for wind turbines in semi-submersible platforms using performance indexes.

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Improving the Performance of Controllers for Wind Turbines on Semi-Submersible Offshore Platforms: Fuzzy Supervisor Control

Cited by 4 publications

References 67 publications

A Novel Global Maximum Power Point Tracking Method Based on Measurement Cells

A Novel Global Maximum Power Point Tracking Method Based on Measurement Cells

Research on Pneumatic Control of a Pressurized Self-Elevating Mat for an Offshore Wind Power Installation Platform

Development and Evaluation of Fuzzy Logic Controllers for Improving Performance of Wind Turbines on Semi-Submersible Platforms under Different Wind Scenarios

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