基于参数化设计的蝶翅微纳结构仿生设计及应用

蒋振宇; 王海涛; 李新兆

doi:10.19554/j.cnki.1001-3563.2025.14.028

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包装工程（设计栏目） ›› 2025, Vol. 46 ›› Issue (14) : 277-284. DOI: 10.19554/j.cnki.1001-3563.2025.14.028

设计研讨

基于参数化设计的蝶翅微纳结构仿生设计及应用

蒋振宇¹, 王海涛^2,*, 李新兆¹

作者信息 +

Bionics Design and Application of Butterfly Wing Micro-nano Structure Based on Parametric Design

JIANG Zhenyu¹, WANG Haitao^2,*, LI Xinzhao¹

Author information +

文章历史 +

摘要

目的基于参数化设计技术,精准提取生物微纳结构的特性,探索产品结构仿生设计的多样化方案。方法采用仿生学研究方法,选取具有轻量化和高强度特征的蝶翅微纳结构作为仿生对象;运用数字化软件对模型进行优化,通过数据对比分析,筛选出最优设计方案。结果经过多次建模优化后,最终得出一种兼具轻量化、高强度和美观特征的仿生设计方案,以蝶翅微纳结构的仿生设计为例,验证了该方法的实用性和有效性。结论实现了对仿生结构的精准提取和高效概括,从而提升产品创新研发的效率和质量,为艺术、科学与技术的融合提供了新的思路,并为创新与可持续设计实践开辟了新的方向。

Abstract

The work aims to precisely extract the characteristics of biological micro-nano structures based on parametric design technology to explore diverse solutions for bionic product structure design. The bionic research method was employed to select butterfly wing micro-nano structures characterized by lightweight and high strength as the bionic target. Digital software was utilized to optimize the model, and the optimal design scheme was selected through comparative data analysis. After multiple modeling optimizations, a bionic design scheme featured with lightweight, high strength, and aesthetic appeal was achieved. The case of the butterfly wing micro-nano structure validated the practicality and effectiveness of this method. In conclusion, this approach enables the precise extraction and efficient generalization of bionic structures, thereby improving the efficiency and quality of product innovation and development. It provides new insights into the integration of art, science, and technology and opens up new avenues for innovative and sustainable design practices.

导出引用

蒋振宇, 王海涛, 李新兆. 基于参数化设计的蝶翅微纳结构仿生设计及应用[J]. 包装工程（设计栏目）. 2025, 46(14): 277-284 https://doi.org/10.19554/j.cnki.1001-3563.2025.14.028

JIANG Zhenyu, WANG Haitao, LI Xinzhao¹. Bionics Design and Application of Butterfly Wing Micro-nano Structure Based on Parametric Design[J]. Packaging Engineering. 2025, 46(14): 277-284 https://doi.org/10.19554/j.cnki.1001-3563.2025.14.028

中图分类号： TB472

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