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Optimization of the shape of a hydrokinetic turbine's draft tube and hub assembly using Design-by-Morphing with Bayesian optimization

Optimization of the shape of a hydrokinetic turbine's draft tube and hub assembly using Design-by-Morphing with Bayesian optimization
Optimization of the shape of a hydrokinetic turbine's draft tube and hub assembly using Design-by-Morphing with Bayesian optimization

Finding the optimal design of a hydrodynamic or aerodynamic surface is often impossible due to the expense of evaluating the cost functions (say, with computational fluid dynamics) needed to determine the performances of the flows that the surface controls. In addition, inherent limitations of the design space itself due to imposed geometric constraints, conventional parameterization methods, and user bias can restrict all of the designs within a chosen design space regardless of whether traditional optimization methods or newer, data-driven design algorithms with machine learning are used to search the design space. We present a 2-pronged attack to address these difficulties: we propose (1) a methodology to create the design space using morphing that we call Design-by-Morphing (DbM); and (2) an optimization algorithm to search that space that uses a novel Bayesian Optimization (BO) strategy that we call Mixed variable, Multi-Objective Bayesian Optimization (MixMOBO). We apply this shape optimization strategy to maximize the power output of a hydrokinetic turbine. Applying these two strategies in tandem, we demonstrate that we can create a novel, geometrically-unconstrained, design space of a draft tube and hub shape and then optimize them simultaneously with a minimum number of cost function calls. Our framework is versatile and can be applied to the shape optimization of a variety of fluid problems.

Bayesian optimization, Design-by-Morphing, Draft-tubes, Hydro-kinetic turbines, MixMOBO, Shape optimization
0045-7825
Sheikh, Haris Moazam
631e12be-9394-41fd-8e90-6ab416df0d76
Callan, Tess A.
9613ecb9-b390-436f-97f8-a57c7f5ce8e9
Hennessy, Kealan J.
5fc142e4-a617-49aa-8d07-b48afe05c7b7
Marcus, Philip S.
71925db3-fc73-4df3-93ea-fecc0bd6412b
Sheikh, Haris Moazam
631e12be-9394-41fd-8e90-6ab416df0d76
Callan, Tess A.
9613ecb9-b390-436f-97f8-a57c7f5ce8e9
Hennessy, Kealan J.
5fc142e4-a617-49aa-8d07-b48afe05c7b7
Marcus, Philip S.
71925db3-fc73-4df3-93ea-fecc0bd6412b

Sheikh, Haris Moazam, Callan, Tess A., Hennessy, Kealan J. and Marcus, Philip S. (2022) Optimization of the shape of a hydrokinetic turbine's draft tube and hub assembly using Design-by-Morphing with Bayesian optimization. Computer Methods in Applied Mechanics and Engineering, 401 (Pt. B), [115654]. (doi:10.1016/j.cma.2022.115654).

Record type: Article

Abstract

Finding the optimal design of a hydrodynamic or aerodynamic surface is often impossible due to the expense of evaluating the cost functions (say, with computational fluid dynamics) needed to determine the performances of the flows that the surface controls. In addition, inherent limitations of the design space itself due to imposed geometric constraints, conventional parameterization methods, and user bias can restrict all of the designs within a chosen design space regardless of whether traditional optimization methods or newer, data-driven design algorithms with machine learning are used to search the design space. We present a 2-pronged attack to address these difficulties: we propose (1) a methodology to create the design space using morphing that we call Design-by-Morphing (DbM); and (2) an optimization algorithm to search that space that uses a novel Bayesian Optimization (BO) strategy that we call Mixed variable, Multi-Objective Bayesian Optimization (MixMOBO). We apply this shape optimization strategy to maximize the power output of a hydrokinetic turbine. Applying these two strategies in tandem, we demonstrate that we can create a novel, geometrically-unconstrained, design space of a draft tube and hub shape and then optimize them simultaneously with a minimum number of cost function calls. Our framework is versatile and can be applied to the shape optimization of a variety of fluid problems.

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More information

Accepted/In Press date: 14 September 2022
e-pub ahead of print date: 30 September 2022
Published date: 30 September 2022
Keywords: Bayesian optimization, Design-by-Morphing, Draft-tubes, Hydro-kinetic turbines, MixMOBO, Shape optimization

Identifiers

Local EPrints ID: 493433
URI: http://eprints.soton.ac.uk/id/eprint/493433
DOI: doi:10.1016/j.cma.2022.115654
ISSN: 0045-7825
PURE UUID: 0ecdc308-31ce-4e39-9528-68761fd5cc5c
ORCID for Haris Moazam Sheikh: ORCID iD orcid.org/0000-0002-3154-0494

Catalogue record

Date deposited: 03 Sep 2024 16:32
Last modified: 04 Sep 2024 02:10

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Contributors

Author: Haris Moazam Sheikh ORCID iD
Author: Tess A. Callan
Author: Kealan J. Hennessy
Author: Philip S. Marcus

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