Topology optimisation of a porous unit cell in a fluid flow considering Forchheimer drag

Akihiro Takezawa; Xiaopeng Zhang; Takuo Tanaka; Mitsuru Kitamura

doi:10.1080/10618562.2019.1705968

Topology optimisation of a porous unit cell in a fluid flow considering Forchheimer drag

Akihiro Takezawa, Xiaopeng Zhang, Takuo Tanaka, Mitsuru Kitamura

Research output: Contribution to journal › Article › peer-review

1 Citation (Scopus)

Abstract

When the Reynolds number exceeds approximately 10, drag from porous media becomes nonlinear and cannot be handled by Darcy's theory. The Darcy–Forchheimer law, which considers drag through porous media as a quadratic function, covers this region up to the Reynolds number of the order (Formula presented.). In this research, we study the optimal shape of a porous unit cell based on this law and topology optimisation. Darcy's permeability and Forchheimer's quadratic drag term are calculated based on the averaging theorem and finite element method. The topology optimisation method is based on classical flow channel optimisation. The pressure drop is considered as the objective function of topology optimisation. By changing the input flow velocity in cell model analysis, the optimal shape becomes accustomed to the specified flow speed. We derive 2D and 3D optimal cell shapes for both low and high velocity regions.

Original language	English
Pages (from-to)	50-60
Number of pages	11
Journal	International Journal of Computational Fluid Dynamics
Volume	34
Issue number	1
DOIs	https://doi.org/10.1080/10618562.2019.1705968
Publication status	Published - 2020 Jan 2
Externally published	Yes

Keywords

Brinkman–Forchheimer equation
Darcy–Forchheimer theory
porous cell design
porous flow
topology optimisation

ASJC Scopus subject areas

Computational Mechanics
Aerospace Engineering
Condensed Matter Physics
Energy Engineering and Power Technology
Mechanics of Materials
Mechanical Engineering

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title = "Topology optimisation of a porous unit cell in a fluid flow considering Forchheimer drag",

abstract = "When the Reynolds number exceeds approximately 10, drag from porous media becomes nonlinear and cannot be handled by Darcy's theory. The Darcy–Forchheimer law, which considers drag through porous media as a quadratic function, covers this region up to the Reynolds number of the order (Formula presented.). In this research, we study the optimal shape of a porous unit cell based on this law and topology optimisation. Darcy's permeability and Forchheimer's quadratic drag term are calculated based on the averaging theorem and finite element method. The topology optimisation method is based on classical flow channel optimisation. The pressure drop is considered as the objective function of topology optimisation. By changing the input flow velocity in cell model analysis, the optimal shape becomes accustomed to the specified flow speed. We derive 2D and 3D optimal cell shapes for both low and high velocity regions.",

keywords = "Brinkman–Forchheimer equation, Darcy–Forchheimer theory, porous cell design, porous flow, topology optimisation",

author = "Akihiro Takezawa and Xiaopeng Zhang and Takuo Tanaka and Mitsuru Kitamura",

note = "Funding Information: This work was partially supported by Japan Society for the Promotion of Science (JSPS) KAKENHI (18K19038) and the National Key R&D Program of China (2017YFB0203604).",

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AU - Takezawa, Akihiro

AU - Zhang, Xiaopeng

AU - Tanaka, Takuo

AU - Kitamura, Mitsuru

N1 - Funding Information: This work was partially supported by Japan Society for the Promotion of Science (JSPS) KAKENHI (18K19038) and the National Key R&D Program of China (2017YFB0203604).

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N2 - When the Reynolds number exceeds approximately 10, drag from porous media becomes nonlinear and cannot be handled by Darcy's theory. The Darcy–Forchheimer law, which considers drag through porous media as a quadratic function, covers this region up to the Reynolds number of the order (Formula presented.). In this research, we study the optimal shape of a porous unit cell based on this law and topology optimisation. Darcy's permeability and Forchheimer's quadratic drag term are calculated based on the averaging theorem and finite element method. The topology optimisation method is based on classical flow channel optimisation. The pressure drop is considered as the objective function of topology optimisation. By changing the input flow velocity in cell model analysis, the optimal shape becomes accustomed to the specified flow speed. We derive 2D and 3D optimal cell shapes for both low and high velocity regions.

AB - When the Reynolds number exceeds approximately 10, drag from porous media becomes nonlinear and cannot be handled by Darcy's theory. The Darcy–Forchheimer law, which considers drag through porous media as a quadratic function, covers this region up to the Reynolds number of the order (Formula presented.). In this research, we study the optimal shape of a porous unit cell based on this law and topology optimisation. Darcy's permeability and Forchheimer's quadratic drag term are calculated based on the averaging theorem and finite element method. The topology optimisation method is based on classical flow channel optimisation. The pressure drop is considered as the objective function of topology optimisation. By changing the input flow velocity in cell model analysis, the optimal shape becomes accustomed to the specified flow speed. We derive 2D and 3D optimal cell shapes for both low and high velocity regions.

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