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Auteurs principaux: Smink, Jan Siemen, Hagmeijer, Rob, Venner, Cornelis Henricus, Visser, Claas Willem
Format: Preprint
Publié: 2025
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Accès en ligne:https://arxiv.org/abs/2501.08999
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author Smink, Jan Siemen
Hagmeijer, Rob
Venner, Cornelis Henricus
Visser, Claas Willem
author_facet Smink, Jan Siemen
Hagmeijer, Rob
Venner, Cornelis Henricus
Visser, Claas Willem
contents Power minimisation in branched fluidic networks has gained significant attention in biology and engineering. The optimal network is defined by channel radii that minimise the sum of viscous dissipation and the volumetric energetic cost of the fluid. For limit cases including laminar flows, high Reynolds number turbulence, or smooth channel approximations, optimal solutions are known. However, no single optimisation approach captures these limit cases. Furthermore, realistic fluidic networks exhibit intermediate points in the parameter space that can hardly be optimised. Here, we present a unifying optimisation approach based on the Darcy friction factor, which has been determined for a wide range of flow regimes and fluid models. We optimise fluidic networks for the entire parameter space: Laminar and turbulent flows, including networks that exhibit both flow types; Non-Newtonian fluid models (power-law, Bingham, and Herschel-Bulkley); and Networks with arbitrary wall roughness, including non-uniform relative roughness. The optimal channel radii are presented analytically and graphically. Finally, the parameter $x$ in the optimisation relationship $Q\propto R^x$ was approximated as a function of the Reynolds number, revealing that previously-determined values of $x$ hardly apply to realistic turbulent flows. Our approach can be extended to other configurations for which the friction factor is known, such as different channel curvatures or wall slip conditions, enabling optimisation of a wide range of fluidic networks.
format Preprint
id arxiv_https___arxiv_org_abs_2501_08999
institution arXiv
publishDate 2025
record_format arxiv
spellingShingle Optimising branched fluidic networks: A unifying approach including laminar and turbulent flows, rough walls, and non-Newtonian fluids
Smink, Jan Siemen
Hagmeijer, Rob
Venner, Cornelis Henricus
Visser, Claas Willem
Fluid Dynamics
Power minimisation in branched fluidic networks has gained significant attention in biology and engineering. The optimal network is defined by channel radii that minimise the sum of viscous dissipation and the volumetric energetic cost of the fluid. For limit cases including laminar flows, high Reynolds number turbulence, or smooth channel approximations, optimal solutions are known. However, no single optimisation approach captures these limit cases. Furthermore, realistic fluidic networks exhibit intermediate points in the parameter space that can hardly be optimised. Here, we present a unifying optimisation approach based on the Darcy friction factor, which has been determined for a wide range of flow regimes and fluid models. We optimise fluidic networks for the entire parameter space: Laminar and turbulent flows, including networks that exhibit both flow types; Non-Newtonian fluid models (power-law, Bingham, and Herschel-Bulkley); and Networks with arbitrary wall roughness, including non-uniform relative roughness. The optimal channel radii are presented analytically and graphically. Finally, the parameter $x$ in the optimisation relationship $Q\propto R^x$ was approximated as a function of the Reynolds number, revealing that previously-determined values of $x$ hardly apply to realistic turbulent flows. Our approach can be extended to other configurations for which the friction factor is known, such as different channel curvatures or wall slip conditions, enabling optimisation of a wide range of fluidic networks.
title Optimising branched fluidic networks: A unifying approach including laminar and turbulent flows, rough walls, and non-Newtonian fluids
topic Fluid Dynamics
url https://arxiv.org/abs/2501.08999