Topology optimization of creeping fluid flows using a Darcy–Stokes finite element

Guest, James K.; Prévost, Jean‐Hérve

doi:10.1002/nme.1560

Cited by 252 publications

(204 citation statements)

References 33 publications

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“…Reference [25] reports the similar result that the wider inlet indicates the lower pressure loss when finer mesh is employed. Although it is thought that this issue comes from the mesh resolution in previous study [25,26], the fundamental cause is not clear because of several unclear factors in previous studies such as whether the width of the flow profile w in Equation (16) is modified adaptively with the change of the inlet length during the optimization.…”

Section: Resultsmentioning

confidence: 99%

Topology optimization of fluid problems using genetic algorithm assisted by the Kriging model

Yoshimura

Shimoyama

Misaka

et al. 2016

Numerical Meth Engineering

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SUMMARYA non-gradient-based approach for topology optimization using a genetic algorithm is proposed in this paper. The genetic algorithm used in this paper is assisted by the Kriging surrogate model to reduce computational cost required for function evaluation. To validate the non-gradient-based topology optimization method in flow problems, this research focuses on two single-objective optimization problems, where the objective functions are to minimize pressure loss and to maximize heat transfer of flow channels, and one multiobjective optimization problem, which combines earlier two single-objective optimization problems. The shape of flow channels is represented by the level set function. The pressure loss and the heat transfer performance of the channels are evaluated by the Building-Cube Method code, which is a Cartesian-mesh CFD solver. The proposed method resulted in an agreement with previous study in the single-objective problems in its topology and achieved global exploration of non-dominated solutions in the multi-objective problems.

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Section: Resultsmentioning

confidence: 99%

Topology optimization of fluid problems using genetic algorithm assisted by the Kriging model

Yoshimura

Shimoyama

Misaka

et al. 2016

Numerical Meth Engineering

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“…For example, the technique could be combined with recent advances in fluid topology optimization 10,11 in order to design maximum efficiency filters with specified pore sizes.…”

Section: Discussionmentioning

confidence: 99%

A Penalty Function for Enforcing Maximum Length Scale Criterion in Topology Optimization

Guest¹,

Prévost²

2006

11th AIAA/ISSMO Multidisciplinary Analysis and Optimization Conference

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[Abstract] Techniques for imposing a minimum length scale, or minimum feature size, in continuum topology optimization have been proposed in literature, with the motivation being stabilization of the maximum stiffness problem and satisfying manufacturing constraints. Imposing an upper bound on feature sizes, however, has not been investigated. This paper proposes a scheme for restricting the maximum length scale in topology optimization. In short, the design domain is searched and structural features larger than the prescribed maximum length scale are penalized. The scheme is implemented in the context of minimum compliance design together with an existing minimum length scale methodology. The resulting optimization problem is continuous and solved using the Method of Moving Asymptotes (MMA). Beam design examples are considered and solutions are shown to be near 0/1 (void/solid) topologies that satisfy the minimum and maximum length scale criteria. The designer thus gains complete control over member sizes and therefore additional influence over cost and manufacturability. Further, restricting maximum length scale can potentially be used to introduce structural redundancy into the design, as loads previously carried by few large members are often redistributed over an interconnected system of smaller members.

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“…This coupling is also important in technological applications involving filtration. In particular, for specific applications, we refer to flow in vuggy porous media appearing in petroleum extraction [1,2], groundwater system in karst aquifers [19,31], reservoir wellbore [3], industrial filtrations [25,32], topology optimization [23], and blood motion in tumors and microvessels [35,38]. We refer to the nice overview [18] and the references therein for its physical background, modelling, and standard numerical methods.…”

Section: Introductionmentioning

confidence: 99%

Residual-Based a Posteriori Error Estimates for a Conforming Finite Element Discretization of the Navier-Stokes/Darcy Coupled Problem

Houédanou¹,

Adetola²,

Ahounou³

2017

Jour. Pure Appl. Math. Adv. Appl.

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We consider in this paper, a new a posteriori residual type error estimator of a conforming mixed finite element method for the coupling of fluid flow with porous media flow on isotropic meshes. Flows are governed by the Navier-Stokes and Darcy equations, respectively, and the corresponding transmission conditions are given by mass conservation, balance of normal forces, and the Beavers-JosephSaffman law. The finite element subspaces consider Bernardi-Raugel and Raviart- KOFFI WILFRID HOUEDANOU et al. 38 Thomas elements for the velocities, piecewise constants for the pressures, and continuous piecewise linear elements for a Lagrange multiplier defined on the interface. The a posteriori error estimate is based on a suitable evaluation on the residual of the finite element solution. It is proven that the a posteriori error estimate provided in this paper is both reliable and efficient. In addition, our analysis can be extended to other finite element subspaces yielding a stable Galerkin scheme.

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Topology optimization of creeping fluid flows using a Darcy–Stokes finite element

Cited by 252 publications

References 33 publications

Topology optimization of fluid problems using genetic algorithm assisted by the Kriging model

Topology optimization of fluid problems using genetic algorithm assisted by the Kriging model

A Penalty Function for Enforcing Maximum Length Scale Criterion in Topology Optimization

Residual-Based a Posteriori Error Estimates for a Conforming Finite Element Discretization of the Navier-Stokes/Darcy Coupled Problem

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