On Surrogate-Based Optimization of Truly Reversible Blade Profiles for Axial Fans

Angelini, Gino; Bonanni, Tommaso; Corsini, Alessandro; Delibra, Giovanni; Tieghi, Lorenzo; Volponi, David

doi:10.3390/designs2020019

Cited by 7 publications

(2 citation statements)

References 36 publications

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“…Regardless of the chosen technique, it is necessary to minimize the number of parameters while covering a broad range of airfoils. In this study, sixth degree B-splines are used for the parameterization (Angelini et al (2018)). The upper surface of the hydrofoil is represented by a B-spline curve with six control points, as illustrated in Fig.…”

Section: Hydrofoil Parameterizationmentioning

confidence: 99%

Optimization of hydrofoils for a bidirectional tidal stream turbine

Giljarhus

2024

Preprint

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Tidal stream turbines present an appealing approach for consistent renewable energy generation. Capitalizing on the periodic nature of tidal streams, these turbines can be designed to function bidirectionally, eliminating the need for a yaw control system. Although airfoils and hydrofoils in general have been extensively studied, there is less work available on bidirectional designs. Through the use of optimization methods, this work introduces bidirectional hydrofoils of varying thicknesses with improved performance compared to elliptic profiles. The optimization was performed using the hydrodynamic efficiency as the objective function, with simulations performed using 2D computational fluid dynamics. The optimized hydrofoil was then used in a turbine design, which is simulated using blade element momentum theory. The hydrofoils showed an improvement in hydrodynamic efficiency of up to 10 %. In the turbine design, this resulted in an improvement of 5.3 % in power coefficient and a reduction in thrust coefficient of 13.2 %. The new line of hydrofoils are promising for use in cost-effective and reliable tidal stream turbine designs.

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Section: Hydrofoil Parameterizationmentioning

confidence: 99%

Optimization of hydrofoils for a bidirectional tidal stream turbine

Giljarhus

2024

Preprint

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“…[4][5][6] In this number, recent contributions have proposed and assessed the use of surrogate models in multi-objective optimization to reduce the massive use of simulation processes. 7,8 Although tip geometry optimization established as a common practice, available strategies lack of generality. Those strategies typically refer to problem-specific solutions, with use of simplified objective functions, and results of the optimization are largely affected by the initial choice of the shape representation.…”

Section: Introductionmentioning

confidence: 99%

Machine-learnt topology of complex tip geometries in gas turbine rotors

Angelini

Corsini

Lavagnoli

2020

Proceedings of the Institution of Mechanical Engineers, Part A:

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The work presents a data driven based strategy to develop a new statistical model of complex tip shape for high-pressure turbine stages exploiting an existing dataset of optimized squealer-like rotor tips. Using the exploratory data analysis (EDA), a set of statistical methods were used to improve the quality of previous CFD-based optimization dataset, as an aid in reducing outliers, data skewness and avoiding the presence of redundant information. The pre-processed dataset was analyzed by unsupervised learning method in order to gain insight on the correlation between tip geometry and single stage axial turbine performance. Utilizing the Principal Component Analysis (PCA), we developed a new continuous, dimensionality-reduced parametrization which allows overcoming the limitations of discrete topology approaches. The novel statistical shape model, coupled with genetic operators into a NSGA-II optimization strategy, was used to explore the design space of optimal solutions generating new designs to enrich the available Pareto front in terms of aero-thermodynamic performance metrics. Two metamodels for performance prediction, respectively based on Artificial Neural Network (ANN) and Gradient Boosting Regressor (GBR) have been developed in order to guide the Pareto front exploration avoiding the use of computationally intensive CFD simulations. New tip designs were carried out to spread the previous optimal front and, successively, aiming to design individuals able to reduce macroscopic not uniformity of the flow keeping optimal aerodynamic performance.

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