基于可视化计算数字孪生的功能工件快速原型鲁棒性优化。

4区 计算机科学 Q1 Arts and Humanities
Jinghua Xu, Kunqian Liu, Linxuan Wang, Hongshuai Guo, Jiangtao Zhan, Xiaojian Liu, Shuyou Zhang, Jianrong Tan
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引用次数: 1

摘要

提出了一种基于可视化计算数字孪生(VCDT)的功能工件快速成型鲁棒性优化方法。首先建立了方案设计原型RP的广义多目标鲁棒性优化模型,该模型可集成热、结构和多学科知识进行可视化。为了实现可视化计算,采用遗传算法对模糊决策的隶属函数进行优化。进行了瞬态热力学、结构静力学和流场分析,特别是对具有高强度、耐腐蚀、耐温度、尺寸稳定和电绝缘等特点的玻璃纤维复合材料进行了分析。通过测量RP过程中的温度和温度变化,进行了电热实验。利用热场测量获得了红外热像图,确定了温度分布。通过对一种轻量化肋形人体工程学伪制品的数值分析,说明了VCDT的有效性。此外,基于热固耦合有限元分析验证了可制造性。物理实验和实践证明,所提出的VCDT为混合不确定性下电热调节和制造效率之间的稳定平衡分层RP提供了稳健的设计范式。
本文章由计算机程序翻译,如有差异,请以英文原文为准。

Robustness optimization for rapid prototyping of functional artifacts based on visualized computing digital twins.

Robustness optimization for rapid prototyping of functional artifacts based on visualized computing digital twins.

Robustness optimization for rapid prototyping of functional artifacts based on visualized computing digital twins.

Robustness optimization for rapid prototyping of functional artifacts based on visualized computing digital twins.

This study presents a robustness optimization method for rapid prototyping (RP) of functional artifacts based on visualized computing digital twins (VCDT). A generalized multiobjective robustness optimization model for RP of scheme design prototype was first built, where thermal, structural, and multidisciplinary knowledge could be integrated for visualization. To implement visualized computing, the membership function of fuzzy decision-making was optimized using a genetic algorithm. Transient thermodynamic, structural statics, and flow field analyses were conducted, especially for glass fiber composite materials, which have the characteristics of high strength, corrosion resistance, temperature resistance, dimensional stability, and electrical insulation. An electrothermal experiment was performed by measuring the temperature and changes in temperature during RP. Infrared thermographs were obtained using thermal field measurements to determine the temperature distribution. A numerical analysis of a lightweight ribbed ergonomic artifact is presented to illustrate the VCDT. Moreover, manufacturability was verified based on a thermal-solid coupled finite element analysis. The physical experiment and practice proved that the proposed VCDT provided a robust design paradigm for a layered RP between the steady balance of electrothermal regulation and manufacturing efficacy under hybrid uncertainties.

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来源期刊
Visual Computing for Industry, Biomedicine, and Art
Visual Computing for Industry, Biomedicine, and Art Arts and Humanities-Visual Arts and Performing Arts
CiteScore
5.60
自引率
0.00%
发文量
28
审稿时长
5 weeks
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