Optimization of wind farm layout considering wake effect and multiple parameters

Markarian, Shant; Fazelpour, Farivar; Markarian, Elin

doi:10.1002/ep.13193

Cited by 14 publications

(9 citation statements)

References 48 publications

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“…This approach is called a genetic algorithm; it extracts a maximum output power at a minimum cost per unit value. For the same algorithm applied by Mosetti, several works employed GA and its variants [4] - [12]. Referring to [13], the authors attempted to solve the power produced by a wind farm using the particle swarm optimization approach (PSO).…”

Section: Introductionmentioning

confidence: 99%

Enhanced Chaotic Manta Ray Foraging Algorithm for Function Optimization and Optimal Wind Farm Layout Problem

et al. 2022

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Manta ray foraging optimization (MRFO) algorithm is relatively a novel bio-inspired optimization technique directed to given real-world engineering problems. In this present work, wind turbines layout (WTs) inside a wind farm ,is considered as a real nonlinear optimization problem. In spite of the better convergence of MRFO, it gets stuck into local optima for large problems. The chaotic sequences are among the performed techniques used to tackle this shortcoming and improve the global search ability. Therefore, ten chaotic maps have been embedded into MRFO. To affirm the performance of the suggested chaotic approach CMRFO, it was first assessed using the IEEE CEC-2017 benchmark functions. This examination has been systematically compared to eight well-known optimization algorithms and the original MRFO. The non-parametric Wilcoxon statistical analysis significantly demonstrates the superiority of CMRFO as it ranks first in most test suites. Secondly, the MRFO and its best enhanced chaotic version were tested on the complex problem of finding the optimal locations of wind turbines within a wind farm. Besides, The application of the CMRFO to the wind farm layout optimization (WFLO) issue aims to minimize the cost per unit power output, and increase the electrical power engendered by all WTs and wind-farm efficiency. Two representative scenarios of the problem have been dealt with a square-shaped farm installed on an area of 2x2km, including variable wind direction with steady wind speed, and both wind direction and speed are variable. The WFLO outcomes reveal the CMRFO capability to find the optimal locations of WTs, that generate a maximum power for a minimum cost compared to three stochastic approaches and other previous studies. At last, the suggested CMRFO with Singer chaotic sequence has been successfully enhanced by accelerating the convergence, and providing better accuracy to find the global optimum.

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Section: Introductionmentioning

confidence: 99%

Enhanced Chaotic Manta Ray Foraging Algorithm for Function Optimization and Optimal Wind Farm Layout Problem

et al. 2022

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“…10 The African and Middle East wind power markets are expected to grow by 10.9 GW capacity over next 5 years with particular contributions of 3.5, 1.8, 1.2, and 1.2 GW from South Africa, Egypt, Morocco, and Saudi Arabia. 10 Keeping in view the necessity of safeguarding our environment and hence the planet, wind power related research and development, [11][12][13][14][15] resource assessment and potential site selection, [16][17][18][19][20] wind speed and power characteristics, [21][22][23][24][25][26] technoeconomic feasibilities, 27,28 wind farm layout and energy output optimization studies, 29,30 grid connectivity and storage issues, 31,32 wind power economics, 22,33,34 renewable energy policy development, [35][36][37] and various other important aspects are being addressed and reported in the literature. Accurate wind power resource assessment is the key for selecting a potential and profitable site for wind farm development.…”

Section: Introductionmentioning

confidence: 99%

Wind power resources assessment at 10 different locations using wind measurements at five heights

Rehman

2022

Env Prog and Sustain Energy

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Globally, people from all walks of life are working towards a sustainable globe and the availability of energy to all human beings using clean, self-renewed, freely available, and distributive sources. Present study utilizes wind speed data measured at 40, 60, 80, 98, and 100 m above ground level and other meteorological parameters near ground level to analyze the wind characteristics, energy yield, cost of energy, and greenhouse gasses reduction at chosen locations. The data analysis showed an increasing trend of wind shear exponent with longitude and a decreasing trend of ambient temperature with latitude. The analysis recommends Yanbu North, Hafar Al-Batin, Sharourah, and Turaif sites with annual energy delivered to the grid of 213.5, 179.4, 167.1, and 166.7 GWh from a wind farm of 49.5 MW installed capacity as the first, second, third, and fourth choice for wind power deployment in the Kingdom of Saudi Arabia. On an average, 28.45 thousand tons CO 2 equivalent greenhouse gasses can be avoided from entering into the local atmosphere at each site with a maximum of 41.1 thousand tons at Yanbu North site alone.

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“…However, there are still some challenges facing these applications. The main issue associated with wind energy is that the actual power generated by wind farms is less than its theoretical power capacity due to the wake effect, wind velocity variations, angle variations, wind turbine inefficiencies, and transmission line problems [14][15][16]. The wake effect can be characterized as wind speed reduction and turbulent flow creation downstream of wind turbines [17][18][19][20].…”

Section: Introductionmentioning

confidence: 99%

“…As a result, this impact can reduce power generation by 10-20%. An enhanced layout of wind turbines can significantly improve power output and reduce its associated charges [14,21]. The power generated in a wind turbine is related to the perfect square of the receiving wind speed.…”

Section: Introductionmentioning

confidence: 99%

Wind Farm Layout Optimization with Different Hub Heights in Manjil Wind Farm Using Particle Swarm Optimization

et al. 2021

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Nowadays, optimizing wind farm configurations is one of the biggest concerns for energy communities. The ongoing investigations have so far helped increasing power generation and reducing corresponding costs. The primary objective of this study is to optimize a wind farm layout in Manjil, Iran. The optimization procedure aims to find the optimal arrangement of this wind farm and the best values for the hubs of its wind turbines. By considering wind regimes and geographic data of the considered area, and using the Jensen’s method, the wind turbine wake effect of the proposed configuration is simulated. The objective function in the optimization problem is set in such a way to find the optimal arrangement of the wind turbines as well as electricity generation costs, based on the Mossetti cost function, by implementing the particle swarm optimization (PSO) algorithm. The results reveal that optimizing the given wind farm leads to a 10.75% increase in power generation capacity and a 9.42% reduction in its corresponding cost.

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Optimization of wind farm layout considering wake effect and multiple parameters

Cited by 14 publications

References 48 publications

Enhanced Chaotic Manta Ray Foraging Algorithm for Function Optimization and Optimal Wind Farm Layout Problem

Enhanced Chaotic Manta Ray Foraging Algorithm for Function Optimization and Optimal Wind Farm Layout Problem

Wind power resources assessment at 10 different locations using wind measurements at five heights

Wind Farm Layout Optimization with Different Hub Heights in Manjil Wind Farm Using Particle Swarm Optimization

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