基于降维模型的翼身融合主承力结构优化方法

doi:10.7527/S1000-6893.2025.32406

Abstract

Abstract:

For topology optimization problems involving large-scale structure features， such as blended wing body aircraft， traditional topology optimization methods face significant computational limitations when dealing with design domains on the order of millions of elements， making it difficult to obtain meaningful load path designs. To address this challenge， this paper proposed a topology optimization method based on reduced-dimensional models. By establishing mapping relationships between three-dimensional solid structures and their reduced-dimensional models， a hierarchical optimization framework is constructed. During the optimization iteration phase， the reduced-dimensional model is employed for optimization and design variable updates， while the mapping functions are used to transfer real-time optimization results to the three-dimensional solid model for high-fidelity mechanical response analysis. This forms a “reduced-dimensional optimization- three-dimensional validation” closed-loop feedback mechanism. Additionally， a size control function is introduced to enhance the manufacturing feasibility of the primary load-bearing structure. Through engineering case， the proposed dimensionality-reduction-based topology optimization method demonstrates its efficiency and stability advantages in solving high-dimensional optimization problems.

Key words: blended wing body, load bearing structure, topology optimization, reduced-dimensional model, manufacturing constraint

CLC Number:

Yan WANG, Liang CHEN, Yongming CAI, Lilong LUO. Optimization method for primary load-bearing structure of blended wing body aircraft using reduced-dimensional models[J]. Acta Aeronautica et Astronautica Sinica, 2025, 46(21): 532406.

Figures/Tables 7

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Table 1

References 20

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优化算法		基于降维模型的拓扑优化方法	传统拓扑优化方法
拓扑优化前处理时长/s	三维模型前处理	62.6	70.12
拓扑优化前处理时长/s	降维模型及映射关系构建	913.18
前处理总时长/s		975.78	70.12
单次优化迭代步时长/s	有限元分析	334.77	331.22
	目标函数、约束函数及其敏度求解	12.04	82.85
	优化计算	0.39	60.34
单次迭代步总时长/s		347.2	474.41
160次迭代步总时长/s		55 552	75 905.6
优化算法总时长/s		56 527.78	75 975.72

Optimization method for primary load-bearing structure of blended wing body aircraft using reduced-dimensional models

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