航天器用材料应用验证技术体系

doi:10.11896/cldb.22050332

材料导报

2022, Vol. 36

Issue (22): 22050332-5 https://doi.org/10.11896/cldb.22050332

宇航材料

航天器用材料应用验证技术体系

高鸿^1,*, 邢焰¹, 孙明¹, 余斌², 李岩¹, 刘泊天¹, 吴冰¹, 于利夫¹, 樊彦艳¹

1 中国空间技术研究院,北京 100094
2 中国航天科技集团公司,北京 100048

Application Verification Technology System for Aerospace Advance Materials

GAO Hong^1,*, XING Yan¹, SUN Ming¹, YU Bin², LI Yan¹, LIU Botian¹, WU Bing¹, YU Lifu¹, FAN Yanyan¹

1 China Aerospace of Space Technology(CAST), Beijing 100094, China
2 China Aerospace Science and Technology Corporation(CASC), Beijing 100048, China

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摘要本文基于钱学森的“综合集成方法论”,结合我国航天器材料的研制及应用特点,阐述了应用验证技术体系基本原理,并总结工程实践经验,提出建设要点。该体系通过材料特性表征及应用情况的宏观与微观研究,利用试验验证、专家决策支持、计算仿真、归纳演绎、信息处理等方法,形成了多指标评价、多角度分析、综合评判的材料工程应用质量控制系统,发挥了人机结合、定性与定量结合、理论与实践结合以及多学科融合的系统工程优势,为我国航天装备自主发展奠定基础。

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	高鸿
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	刘泊天
	吴冰
	于利夫
	樊彦艳

关键词: 航天器材料应用验证技术体系

Abstract: Based on Qian Xuesen's “comprehensive integration methodology”, and combined with the characteristics of spacecraft materials development and application in China, the basic principles of application verification technology are described in this paper. The new material engineering application quality control system has been formed with multi-index evaluation, multi-angle analysis and comprehensive evaluation by means of macro and micro material research of material characterization and application, using the methods of experimental verification, expert decision support, computational simulation, induction and deduction, information processing and so on. The system gave full play to the advantages of man-machine integration, qualitative and quantitative integration, theory and practice integration and multidisciplinary integration of systems engineering, laying a quality assurance foundation for the independent development of China's space equipment.

Key words: spacecraft material application verification technology system

出版日期: 2022-11-25 发布日期: 2022-11-25

ZTFLH:

TB302

通讯作者: * gaohong_cast@sina.com

作者简介: 高鸿,研究员。2008年吉林大学化学学院博士毕业后,于日本东京工业大学高分子物理专业做访问学者。2010年就职中国空间技术研究院宇航物资保障事业部。目前主要从事航天器材料需求规划研究,材料空间复杂使役环境测试与评价技术,材料应用研制技术体系研究,以及宇航材料工程技术体系研究。已发表文章70余篇。

引用本文:

高鸿, 邢焰, 孙明, 余斌, 李岩, 刘泊天, 吴冰, 于利夫, 樊彦艳. 航天器用材料应用验证技术体系[J]. 材料导报, 2022, 36(22): 22050332-5.
GAO Hong, XING Yan, SUN Ming, YU Bin, LI Yan, LIU Botian, WU Bing, YU Lifu, FAN Yanyan. Application Verification Technology System for Aerospace Advance Materials. Materials Reports, 2022, 36(22): 22050332-5.

链接本文:

http://www.mater-rep.com/CN/10.11896/cldb.22050332 或 http://www.mater-rep.com/CN/Y2022/V36/I22/22050332

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