Topology optimization of thermo‐elastic structures considering stiffness, strength, and temperature constraints over a wide range of temperatures

Meng, Qingxuan; Xu, Bin; Huang, Chenguang; Duan, Zunyi; Han, Peide

doi:10.1002/nme.6909

Cited by 9 publications

(3 citation statements)

References 32 publications

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“…However, the previous researches on temperature constrained topology optimization usually considered the maximal temperature constraint for the fixed space domian. [50][51][52][53][54][55] The topology optimization researches considering the temperature constraint for material are few. For multi-material topology optimization, the materials occupying domain change continuously with iterations.…”

Section: Introductionmentioning

confidence: 99%

“…Therefore, the corresponding temperature constraint should be set to control the maximal temperature of used material. However, the previous researches on temperature constrained topology optimization usually considered the maximal temperature constraint for the fixed space domian 50–55 . The topology optimization researches considering the temperature constraint for material are few.…”

Section: Introductionmentioning

confidence: 99%

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Multi‐material topology optimization method for transient thermal structure with constraint on permissible temperatures

Zhang

Liu

2023

Numerical Meth Engineering

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Excessive temperature may lead material to performance degradation, ablation, and phase change. Thus, controlling the maximum temperature of used material within a safe range is of great significance to the safe operation of thermal structures. In this article, a density‐based multi‐material topology optimization method for transient thermal structures is proposed, in which the maximal temperature for each material is controlled not greater than its permissible temperature. In this method, a projection algorithm based on the PDE (partial differential equation) filter and Heaviside projection is set up and used to identify the domains occupied by each material. The maximal temperature of each specific material occupying domain is approximately expressed by the condensed integrals in the time and space domains. The permissible temperature constraint is satisfied by controlling the condensed integrals not great than a specific threshold value (depending on the corresponding material's permissible temperature). Several examples illustrate that the permissible temperature plays an important role in the selection and the distribution scheme of the candidate materials for the design of multi‐material thermal structures. The proposed method can effectively control the maximal temperature of each material within its constraint range, and achieve the rational design for multi‐material thermal structures. In addition, different thermal loading time may also lead to different material selection of structure. This work has potential applications in the lightweight design of thermal insulation structures.

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Section: Introductionmentioning

confidence: 99%

Section: Introductionmentioning

confidence: 99%

Multi‐material topology optimization method for transient thermal structure with constraint on permissible temperatures

Zhang

Liu

2023

Numerical Meth Engineering

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“…Then, Zhu et al 48 imposed pointwise temperature constraints. Meng et al 49 introduced regional temperature constraints in form of the P‐norm aggregation function. As indicated by Tang et al, 45 temperature can be precisely controlled and the large temperature gradient can be substantially characterized with the help of TDMPs, while CMPs are valid only for small temperature gradient.…”

Section: Introductionmentioning

confidence: 99%

Topology optimization of thermo‐elastic structures with temperature‐dependent material properties under large temperature gradient

Tang

Gao

Zhang

et al. 2023

Numerical Meth Engineering

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In this work, high temperature and large temperature gradient are addressed for the first time in the topology optimization of thermo‐elastic structures. The conventional assumption of constant material properties (CMPs) is broken through with the full consideration of temperature‐dependent material properties (TDMPs) including thermal conductivity, elastic tensor, and coefficient of thermal expansion. Nonlinear heat conduction is thus implemented to give varying temperature fields in thermoelasticity. The maximum displacement of the specified region is taken as the objective function in the formulation of the optimization problem. The Kreisselmeier‐Steinhauser (KS) function is employed to approximate the regional maximum displacement/temperature. Corresponding sensitivity analyses, which are carried out using the adjoint method, theoretically reveal how TDMPs affect the thermo‐elastic optimization problem. Typical numerical examples are investigated to validate the proposed approach. The results show that the use of TDMPs produces optimized structures of high fidelity with displacements precisely predicted and temperature constraints rigorously satisfied under large temperature gradient, while thermo‐elastic analysis and optimization with CMPs lead to undesirable designs with significant inaccuracy.

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Topology Optimization of Electric Vehicle Chassis with Porous Frames and Feature-Deformable Batteries

Lu,

Zhou

2024

Mechanisms and Machine Science

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Topology optimization of thermo‐elastic structures considering stiffness, strength, and temperature constraints over a wide range of temperatures

Cited by 9 publications

References 32 publications

Multi‐material topology optimization method for transient thermal structure with constraint on permissible temperatures

Multi‐material topology optimization method for transient thermal structure with constraint on permissible temperatures

Topology optimization of thermo‐elastic structures with temperature‐dependent material properties under large temperature gradient

Topology Optimization of Electric Vehicle Chassis with Porous Frames and Feature-Deformable Batteries

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