Airfoil Shape Optimization: Comparative Study of Meta-heuristic Algorithms, Airfoil Parameterization Methods and Reynolds Number Impact

Hoyos, J.D.; Jímenez, Jesús H.; Echavarría, Camilo; Perilla, Juan Pablo Alvarado

doi:10.1088/1757-899x/1154/1/012016

Cited by 5 publications

(4 citation statements)

References 7 publications

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“…Predictably PSO has been used for airfoil shape design as well as other algorithms. The results show better performance and convergence speed for PSO compared to GA [458]. Naumann et al have also used a modified version of CS to optimize airfoil shape in order to maximize the lift/drag ratio [459].…”

Section: Wing and Tail Designmentioning

confidence: 99%

“…Publication Year Application Algorithm [455] 2018 Airfoil design GA, SA [456] 2001 Wing and blade airfoil design ES [457] 2019 Airfoil design FFO [458] 2021 Airfoil design PSO, GA [459] 2016 Airfoil design CS [460] 2015 Blade design ABC [461] 2017 Airfoil design GSA [462] 2022 Airfoil design HS [463] 2013 Aerodynamic shape optimization HS [382] 2016 Aerodynamic shape optimization SCA [466] 1999 Wing design GA [467] 2004 Wing design PSO [468] 2011 Wing design ACO [469] 2019 Wing design DE [470] 2019 Wing design FSO [471] 2017 Wing tip design ABC [474] 2016 Equipment placement in body GA [475] 2017 Equipment placement in body BA [476] 2017 Body shape design GA [478] 2017 Body shape design PSO [479] 2012 Body sizing DE…”

Section: Referencementioning

confidence: 99%

See 1 more Smart Citation

Nature-Inspired Algorithms from Oceans to Space: A Comprehensive Review of Heuristic and Meta-Heuristic Optimization Algorithms and Their Potential Applications in Drones

Darvishpoor,

Darvishpour,

Escarcega

et al. 2023

Drones

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This paper reviews a majority of the nature-inspired algorithms, including heuristic and meta-heuristic bio-inspired and non-bio-inspired algorithms, focusing on their source of inspiration and studying their potential applications in drones. About 350 algorithms have been studied, and a comprehensive classification is introduced based on the sources of inspiration, including bio-based, ecosystem-based, social-based, physics-based, chemistry-based, mathematics-based, music-based, sport-based, and hybrid algorithms. The performance of 21 selected algorithms considering calculation time, max iterations, error, and the cost function is compared by solving 10 different benchmark functions from different types. A review of the applications of nature-inspired algorithms in aerospace engineering is provided, which illustrates a general view of optimization problems in drones that are currently used and potential algorithms to solve them.

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Section: Wing and Tail Designmentioning

confidence: 99%

Section: Referencementioning

confidence: 99%

Nature-Inspired Algorithms from Oceans to Space: A Comprehensive Review of Heuristic and Meta-Heuristic Optimization Algorithms and Their Potential Applications in Drones

Darvishpoor,

Darvishpour,

Escarcega

et al. 2023

Drones

View full text Add to dashboard Cite

show abstract

“…One of the main inputs that composed the global model is the aerodynamic data associated with each airfoil located over the propeller span-wise section. Therefore, a parameterization method with a few parameters that are available to describe a wide range of geometries is required and that is the main reason why the 4-digit NACA method is selected for this study [10]. The 4-digit NACA airfoil shape is defined by the thickness t in chord hundredths, the maximum camber z in chord hundredths, and the maximum camber position x z p in chord tenths.…”

Section: Airfoil Aerodynamic Datamentioning

confidence: 99%

“…For the optimization method, a Particle Swarm Optimization (PSO) routine is developed, which guarantees the fulfilment of the target performance and the constraints, including the allowable stress where a structural model based on the Euler-Bernoulli beam theory is used to evaluate the structural viability of the candidate propellers. The PSO methodology has been employed for propeller optimization in different researches [6][7][8][9], and it also has been reported to be faster than other algorithms such as Generic Algorithms or sine-cosine optimizers [10,11].…”

Section: Introductionmentioning

confidence: 99%

Aircraft Propeller Design through Constrained Aero-Structural Particle Swarm Optimization

et al. 2022

Self Cite

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An aero-structural algorithm to reduce the energy consumption of a propeller-driven aircraft is developed through a propeller design method coupled with a Particle Swarm Optimization (PSO). A wide range of propeller parameters is considered in the optimization, including the geometry of the airfoil at each propeller section. The propeller performance prediction tool employs a convergence improved Blade Element Momentum Theory fed by airfoil aerodynamic characteristics obtained from XFOIL and a validated OpenFOAM. A stall angle correction is estimated from experimental NACA 4-digits data and employed where convergence issues emerge. The aerodynamic data are corrected to account for compressibility, three-dimensional, viscous, and Reynolds number effects. The coefficients for the rotational corrections are proposed from experimental data fitting. A structural model based on Euler-Bernoulli beam theory is employed and validated against Finite Element Analysis, while the impact of centrifugal forces is discussed. A case of study is carried out where the chord and pitch distributions are compared to minimal losses distribution from vortex theory. Wind tunnel tests were performed with printed propellers to conclude the feasibility of the entire routine and the differences between XFOIL and CFD optimal propellers. Finally, the optimal CFD propeller is compared against a commercial propeller with the same diameter, pitch, and operational conditions, showing higher thrust and efficiency.

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Optimal airfoil design through particle swarm optimization fed by CFD and XFOIL

Echavarría

Hoyos

Jímenez

et al. 2022

J Braz. Soc. Mech. Sci. Eng.

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Airfoil Shape Optimization: Comparative Study of Meta-heuristic Algorithms, Airfoil Parameterization Methods and Reynolds Number Impact

Cited by 5 publications

References 7 publications

Nature-Inspired Algorithms from Oceans to Space: A Comprehensive Review of Heuristic and Meta-Heuristic Optimization Algorithms and Their Potential Applications in Drones

Nature-Inspired Algorithms from Oceans to Space: A Comprehensive Review of Heuristic and Meta-Heuristic Optimization Algorithms and Their Potential Applications in Drones

Aircraft Propeller Design through Constrained Aero-Structural Particle Swarm Optimization

Optimal airfoil design through particle swarm optimization fed by CFD and XFOIL

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