2021
DOI: 10.1002/nme.6883
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A stabilized parametric level‐set XFEM topology optimization method for thermal‐fluid problem

Abstract: This article presents a stabilized level-set topology optimization method for the design of a thermal-fluid system. The steady-state laminar Navier-Stokes equation and the convection-diffusion equation are used to model the thermal-fluid problem. The compactly supported radial basis functions are employed to describe the fluid-solid interfaces. The extended finite element method is used to interpolate the material domain and the non-slip interface conditions are weakly enforced by the Nitsche's method. To over… Show more

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Cited by 7 publications
(7 citation statements)
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“…The LSF is set to be zero at the interface, and the nodal values of LSF can be solved based on a governing equation or interpolated on the computational domain by a space function called "basis functions". The LSM has also been applied in the TO of HXs [96], [104], [114]- [123]. Feppon et al [117] even used the LSM to deal with the 2D and 3D HXs involving two fluids.…”
Section: Level Set Methodsmentioning
confidence: 99%
See 1 more Smart Citation
“…The LSF is set to be zero at the interface, and the nodal values of LSF can be solved based on a governing equation or interpolated on the computational domain by a space function called "basis functions". The LSM has also been applied in the TO of HXs [96], [104], [114]- [123]. Feppon et al [117] even used the LSM to deal with the 2D and 3D HXs involving two fluids.…”
Section: Level Set Methodsmentioning
confidence: 99%
“…As a very valuable attempt, Coffin and Maute [120] combined the XFEM and the LSM in the TO for the 2D and 3D, steady-state and transient single-flow heat transfer problems dominated by natural convection. Recently, Lin et al [123] performed a topology optimization using the LSM-XFEM coupling to optimize the channel topology for a 2D heat sink under steady-state conditions. Thanks to the features of XFEM and LSM, the interface is well captured during the iterative optimization process, while the computational burden increases at the same time.…”
Section: Extended Finite Element Methods (Xfem)mentioning
confidence: 99%
“…Among structural topology optimization (STO) methods, the level set method (LSM) could be a superior for description of boundaries [3,4]. Farther, parametric methods are proposed to alleviate the difficulty of solving level-set equations [5][6][7]. The discrete adjoint method is used to deal with sensitive boundaries to gain sensitivity with greater precision [8].…”
Section: Introductionmentioning
confidence: 99%
“…Regarding the former, the XFEM approach was introduced in [28] to perform TopO based on the level-set approach for 2D laminar flow problems. Recently, it has been utilized to increase the accuracy of TopO solvers in laminar [29] and turbulent flows [20], including heat transfer. In FVM methods for TopO, [30] utilized a ghost-cell immersed boundary method to apply wall boundary conditions for turbulent flow problems, without having to modify the background mesh.…”
Section: Introductionmentioning
confidence: 99%